Evaluation of Waterlogging Tolerance in Twenty-One Cultivars and Genotypes of Bread Wheat (Triticum Aestivum L.) and its Effect on some Physiological Characteristics of Shoot and Root System at the Three-Leaf Stage
Covering a staggering 215 million hectares, wheat stands as the world's most extensively cultivated crop plant. Just like its botanical counterparts, wheat operates as an obligate aerobic organism, implying its reliance on absorbing oxygen from the surrounding environment to facilitate growth, proliferation, and the successful completion of its life cycle. Annual instances of waterlogging stress inflict harm upon wheat crops, attributed to inadequate irrigation practices, subpar drainage systems, uneven field leveling, elevated groundwater levels, the presence of unyielding impermeable layers, and bouts of intense, abrupt rainfall. This adverse impact is progressively escalating, potentially influenced by the ongoing shifts in climate patterns. Consequently, the adoption of resilient cultivars and the genetic enhancement of bread wheat assume critical importance. These strategies are aimed at augmenting the wheat's capacity to effectively cope with waterlogging stress, aligning it with the mounting demands of a burgeoning global population.
To achieve these goals, it is necessary to understand the factors causing waterlogging stress damage in wheat and to know the mechanisms of tolerance in this plant. The survival of root terminal meristem cells under waterlogging stress conditions is very limited, and their ability to grow again after removing the stress is also restricted. Waterlogging stress leads to the death of primary roots and reduced growth of lateral roots in wheat. However, there is variation among wheat cultivars concerning these traits. Reduced access to oxygen hampers root growth and nutrient absorption, including nitrogen. Consequently, photosynthesis and carbohydrate availability decrease, further restricting root growth.
Drought stress and consequent lack of available water for plants is one of the main causes of accumulation of reactive oxygen species (ROS) in various organs of plants, which is effective in reducing the yield of cereals such as wheat. The antioxidant system, which contains various enzymes and genes, is responsible for removing and detoxifying plants from ROS. Unfortunately, genes responding to drought stress and their enzymatic activities associated with spike and flag leaf of wheat have received less attention. Therefore, in the present study, photosynthetic parameters, key enzymes of the antioxidant system, and expression analysis of some genes involved in this system under field capacity (FC) and drought stress (DS) conditions in spike and flag leaves of wheat were investigated.
Since the development of crop cultivation and their yield depend on irrigation and since drought is one of the features of our country, one of the solutions to deal with these problems is the implementation of applied research in the field of stress-resistant plants cultivation such as quinoa. Also, considering the important role of potassium and zinc elements in the plant, providing a sufficient amount of these elements under drought stress can be effective in increasing the plant's resistance to this type of stress. Considering the genetic differences of plants and their different reactions in the face of environmental stress such as drought stress, and different fertilization of genotypes, it seems necessary to carry out this research to investigate the application of potassium and zinc chelates on the morpho-physiological and yield indicators of three quinoa genotypes under drought stress conditions in Razavi Khorasan climate.
The effect of salinity stress on the quantity and quality of crop production highlights the importance of managing and reducing the damage caused by this stress factor in agriculture. Increasing soil salinity and decreasing fertility of arable lands is one of the major problems in saline areas. Cultivation of salt-tolerant crops which can increase soil fertility could be effective in the sustainable production of these lands. Studying photosynthesis and its related factors could provide appropriate physiological views in understanding plant behavior against salinity stress. The present study was conducted to assess the salinity tolerance of chickpea genotypes for cultivation in saline areas.
The most important problem that threatens food security of any country and the world is the lack of adequate water resources, so one of the ways to deal with this crisis is to use plants with low water requirements and high water use efficiency. Among the plants, we can name Quinoa, which is one of the plants that has been less studied and exploited in Iran. Since the planting date has the greatest impact on the physiological characteristics of the crop compared to other cropping treatments, so choosing the appropriate planting date can also create the greatest correlation between plant growth trends and climatic conditions. Undoubtedly, the use of biological fertilizers, in addition to the positive effects it has on all soil properties, is also economically, environmentally and socially fruitful and can be a suitable and desirable alternative to chemical fertilizers. Therefore, the aim of this study was to determine the response to deficit irrigation, planting date and application of different biofertilizers in quinoa.
The increasing demand for medicinal plants in traditional medicine as well as the pharmaceutical industry has created the need for some plants to be grown commercially, but the lack of soil moisture poses a serious threat to their production. Planting method can affect the emergence and growth rate of crop and lead to decrease water consumption and increase irrigation water efficiency as yield increases. Roselle (Hibiscus sabdariffa L.) is one of the drought tolerant plants. Saving water consumption by cultivating drought tolerant plants has been proposed as a strategy to combat drought. It should be noted, however, that irrigation without proper planning can reduce the growth and production of crops. In this regard, determining time of deficit irrigation with minimum damage is an appropriate solution that achieves optimum yield while saving water consumption. The aim of this study was to investigate the effect of different irrigation regimes and planting method on some physiological traits, yield and water use efficiency of Roselle plant.
Introduction
Sunflower, one of the primary oilseed crops worldwide, is cultivated extensively due to its suitability for agricultural needs, high oil yield, and nutritional and medicinal value. However, drought remains the most critical limiting factor affecting sunflower productivity. In arid and semi-arid regions, the intensity of drought stress is predicted to increase in the future. Unfortunately, severe drought stress leads to significant reductions in both seed and oil production. While sunflower is moderately drought-tolerant, understanding the physiological and agronomic aspects of drought stress is crucial for sustainable management. Given that water, scarcity poses a significant threat to crop productivity and environmental resources are diminishing, effective irrigation management under water scarcity is becoming increasingly important.
Materials and Methods
In order to study the effects of deficit irrigation on grain yield and physiological traits of six sunflower cultivars, a field experiment was carried out in a split-plot arrangement based on randomized complete block design with three replications in 2019-2020 growing season. The experimental site was located in the research farm of the Safiabad Agricultural and Natural Resources Research and Education Center. Main plots consisted of three irrigation regimes including; control, moderate, and severe deficit irrigation (50, 70, and 90% of available moisture, respectively), and sub plots consisted of six sunflower cultivars including; Oscar, Felix, Shakira, Savana, Labad and Monaliza.
Cumin is one of the most important medicinal plants in Iran and is widely used in food, health and beauty industries due to its antioxidant and antibacterial properties. Yield of some crops are higher in autumn planting compared to spring. However, low temperature and inappropriate distribution of precipitation are of factors affecting seedling emergence and establishment. So it seems that seeds with higher germination also have better emergence and establishment producing more vigorous seedlings in further growth stages. So, to success in autumn-planting of cumin, it is necessary to have ecotypes with appropriate and even emergence in low temperature and water restricted conditions. Since water is of high paramount importance in germination and lower water potentials lead to lower accessibility of water to seeds, the aim of this experiment was to study seed germination response of different cumin ecotypes to low water potentials.
Water is now the main limiting factor for crop production in arid and semi-arid regions. Water-cut or irrigation interruption has been suggested as one of the main strategies agro-technique to get the most benefit from limited water resource available. In this regard, plant growth stage, time of stress induction and the genotype are the main key factors to determine the degree of success. Canola is one of the most important oil crop. It can survive some degree of water stress while there is a need for research to find the most appropriate genotypes for plantations in water-limited areas.
Drought stress and consequent lack of available water for plants is one of the main causes of accumulation of reactive oxygen species (ROS) in various organs of plants, which is effective in reducing the yield of cereals such as wheat. The antioxidant system, which contains various enzymes and genes, is responsible for removing and detoxifying plants from ROS. Unfortunately, genes responding to drought stress and their enzymatic activities associated with spike and flag leaf of wheat have received less attention. Therefore, in the present study, photosynthetic parameters, key enzymes of the antioxidant system, and expression analysis of some genes involved in this system under field capacity (FC) and drought stress (DS) conditions in spike and flag leaves of wheat were investigated.
Since the development of crop cultivation and their yield depend on irrigation and since drought is one of the features of our country, one of the solutions to deal with these problems is the implementation of applied research in the field of stress-resistant plants cultivation such as quinoa. Also, considering the important role of potassium and zinc elements in the plant, providing a sufficient amount of these elements under drought stress can be effective in increasing the plant's resistance to this type of stress. Considering the genetic differences of plants and their different reactions in the face of environmental stress such as drought stress, and different fertilization of genotypes, it seems necessary to carry out this research to investigate the application of potassium and zinc chelates on the morpho-physiological and yield indicators of three quinoa genotypes under drought stress conditions in Razavi Khorasan climate.
The effect of salinity stress on the quantity and quality of crop production highlights the importance of managing and reducing the damage caused by this stress factor in agriculture. Increasing soil salinity and decreasing fertility of arable lands is one of the major problems in saline areas. Cultivation of salt-tolerant crops which can increase soil fertility could be effective in the sustainable production of these lands. Studying photosynthesis and its related factors could provide appropriate physiological views in understanding plant behavior against salinity stress. The present study was conducted to assess the salinity tolerance of chickpea genotypes for cultivation in saline areas.
The most important problem that threatens food security of any country and the world is the lack of adequate water resources, so one of the ways to deal with this crisis is to use plants with low water requirements and high water use efficiency. Among the plants, we can name Quinoa, which is one of the plants that has been less studied and exploited in Iran. Since the planting date has the greatest impact on the physiological characteristics of the crop compared to other cropping treatments, so choosing the appropriate planting date can also create the greatest correlation between plant growth trends and climatic conditions. Undoubtedly, the use of biological fertilizers, in addition to the positive effects it has on all soil properties, is also economically, environmentally and socially fruitful and can be a suitable and desirable alternative to chemical fertilizers. Therefore, the aim of this study was to determine the response to deficit irrigation, planting date and application of different biofertilizers in quinoa.
The increasing demand for medicinal plants in traditional medicine as well as the pharmaceutical industry has created the need for some plants to be grown commercially, but the lack of soil moisture poses a serious threat to their production. Planting method can affect the emergence and growth rate of crop and lead to decrease water consumption and increase irrigation water efficiency as yield increases. Roselle (Hibiscus sabdariffa L.) is one of the drought tolerant plants. Saving water consumption by cultivating drought tolerant plants has been proposed as a strategy to combat drought. It should be noted, however, that irrigation without proper planning can reduce the growth and production of crops. In this regard, determining time of deficit irrigation with minimum damage is an appropriate solution that achieves optimum yield while saving water consumption. The aim of this study was to investigate the effect of different irrigation regimes and planting method on some physiological traits, yield and water use efficiency of Roselle plant.
Introduction
Sunflower, one of the primary oilseed crops worldwide, is cultivated extensively due to its suitability for agricultural needs, high oil yield, and nutritional and medicinal value. However, drought remains the most critical limiting factor affecting sunflower productivity. In arid and semi-arid regions, the intensity of drought stress is predicted to increase in the future. Unfortunately, severe drought stress leads to significant reductions in both seed and oil production. While sunflower is moderately drought-tolerant, understanding the physiological and agronomic aspects of drought stress is crucial for sustainable management. Given that water, scarcity poses a significant threat to crop productivity and environmental resources are diminishing, effective irrigation management under water scarcity is becoming increasingly important.
Materials and Methods
In order to study the effects of deficit irrigation on grain yield and physiological traits of six sunflower cultivars, a field experiment was carried out in a split-plot arrangement based on randomized complete block design with three replications in 2019-2020 growing season. The experimental site was located in the research farm of the Safiabad Agricultural and Natural Resources Research and Education Center. Main plots consisted of three irrigation regimes including; control, moderate, and severe deficit irrigation (50, 70, and 90% of available moisture, respectively), and sub plots consisted of six sunflower cultivars including; Oscar, Felix, Shakira, Savana, Labad and Monaliza.
Cumin is one of the most important medicinal plants in Iran and is widely used in food, health and beauty industries due to its antioxidant and antibacterial properties. Yield of some crops are higher in autumn planting compared to spring. However, low temperature and inappropriate distribution of precipitation are of factors affecting seedling emergence and establishment. So it seems that seeds with higher germination also have better emergence and establishment producing more vigorous seedlings in further growth stages. So, to success in autumn-planting of cumin, it is necessary to have ecotypes with appropriate and even emergence in low temperature and water restricted conditions. Since water is of high paramount importance in germination and lower water potentials lead to lower accessibility of water to seeds, the aim of this experiment was to study seed germination response of different cumin ecotypes to low water potentials.
Water is now the main limiting factor for crop production in arid and semi-arid regions. Water-cut or irrigation interruption has been suggested as one of the main strategies agro-technique to get the most benefit from limited water resource available. In this regard, plant growth stage, time of stress induction and the genotype are the main key factors to determine the degree of success. Canola is one of the most important oil crop. It can survive some degree of water stress while there is a need for research to find the most appropriate genotypes for plantations in water-limited areas.
Quinoa is a dicotyledonous plant from the Amaranthaceae family, with favorable nutritional value and a high potential for growth and production in adverse environmental conditions. Despite being three carbon, it has high water consumption efficiency and as a new crop, due to its wide adaptation to different environment conditions such as salinity and drought, as well as being premature, it is suitable for planting in arid and desert areas and has many factors. Genetic and environmental factors such as genotype, density, arrangement and planting date, soil salinity, and drought stress affect yield. Among these, drought is one of the most important non-living stresses that cause great damage to crops and horticulture in the world every year. And especially Iran, which is considered an arid and semi-arid country. The effect of moisture stress on plants varies depending on which stage of plant growth occurs and plants can work through various mechanisms such as reducing growth parameters, closing pores, reducing photosynthesis, changing regulatory mechanisms of ion transport, and increasing activity. Antioxidant enzymes cope with drought stress to some extent, although such mechanisms are energy-intensive and cause a decline in performance.
Salinity is one of the major constraints to wheat growth, which hampers production, causing yield loss in arid and semi-arid regions. Reductions in growth resulting from high salinity are because of both osmotic stress, inducing a water deficit, and the effects of excess Na+ and Cl– ions on critical biochemical processes. Salt stress induces a significant reduction in photosynthesis through the reduction of leaf area and photosynthetic pigments. Several strategies have been developed to decrease the toxic effects caused by high salinity on plant growth. Among them, the use of plant growth-promoting rhizobacteria (PGPR) such as Pseudomonas and Mycorrhiza play an important role in yield improvement. Many studies have been published on the beneficial effects of bacterial inoculation on plant physiology and growth under salt stress. One of the common hypotheses employed in most of the studies conducted under salinity stress was the lowering of ethylene level by the ACC-deaminase activities of PGPR and improved plant growth and yield under salinity stress.
It was reported that the application of Pseudomonas spp. improved plant growth by decreasing the uptake of Na+ and increasing the activities of antioxidant enzymes under salinity stress. The selective uptake of K+ as opposed to Na+ is considered one of the important physiological mechanisms contributing to salt tolerance in many plant species. Inoculation with PGPR significantly decreased Na+ uptake and increased K+ content and enhanced levels of K+ that could be to mitigate oxidative stress imposed by higher salinity. Some researchers have reported that PGPR species like Azotobacter and Pseudomonas increased the growth and biomass of canola (Brassica napus L.) under salinity stress.
A Better understanding of wheat physiological responses under salinity may help in programs in which the objective is to improve the grain yield under salinity stress. Therefore, this study aimed to evaluate the physiological, stomata conductance, along with root and shoot Na+/ K+ ratios) of wheat to cycocel and PGPR application under salinity stress.
Introduction
Prolonged droughts and lack of water resources, followed by the salinity of water and soil resources, have faced many limitations in the production of some conventional agricultural and garden plants, especially in arid and semi-arid regions of the country. Therefore, the introduction of new plants with high yield potential, which have suitable growth in saline soils, the threshold of their seed yield reduction is high, and the production product is of high quality has been considered in Iran. Quinoa with the scientific name Chenopodium quinoa Willd. It is an annual plant originating from Latin America, which, despite its high nutritional value, tolerates a wide range of abiotic stresses and can grow in marginal lands. For this reason, this experiment was conducted to investigate the performance of quinoa plant genotypes against different levels of salinity in the research field of the Gorgan Agricultural Meteorological Research Department.
Materials and Methods
Cultivation of seeds of nine genotypes Titicaca (control number), Giza1, RedCarina, Q18, Q21, Q22, Q26, Q29, and Q31 obtained from Karaj Seedling and Seed Breeding Research Institute in a factorial experiment based on a complete random block design. Plastic pots were made with a bed of sand and clay in a ratio of two to one on March 5, 2019. The application of NaCl salt solution treatments at the levels of zero, 10, 20, and 30 decisiemens/m started after the establishment of the plant and reached the six-leaf stage and lasted for 45 days. After salinity treatment, morphological traits including plant height, stem diameter, number of sub-branches, inflorescence length, inflorescence width, biomass, 1000 seed weight, and seed weight per plant were measured.
In the pursuit of a resilient and progressive agricultural system, the incorporation of diverse fertilizers is deemed essential. This practice not only enhances product quality but also aids in cost reduction. However, over-reliance on a specific type of input can inadvertently lead to unintended repercussions. The unrestricted utilization of chemical fertilizers, for instance, can precipitate adverse outcomes such as imbalanced pH levels, the accumulation of heavy elements, soil structure deterioration, and environmental contamination. Conversely, organic fertilizers, while environmentally friendly, often release nutrients at a slower rate, potentially disrupting optimal plant growth. To attain a balanced and sustainable agricultural approach, the combined application of organic and chemical fertilizers is advocated. Moreover, harnessing the biological potential inherent in soil ecosystems, including beneficial microbial communities encompassing bacteria and fungi, emerges as a promising avenue in cultivating sustainable agriculture. Acknowledging the adverse impact of late-season heat stress on wheat production in Khuzestan and recognizing the significance of reducing chemical fertilizer usage while augmenting organic and biological fertilizers to foster ecological health, this experiment undertakes the exploration of the effects of a synergistic approach. Specifically, it delves into the combined utilization of nitrogen and compost fertilizers, complemented by the incorporation of plant growth-promoting rhizobacteria. This endeavor aims to shed light on how this combined strategy operates within the context of terminal heat stress, assessing its influence on the physiological attributes and yield of the wheat cultivar Chamran 2.
Introduction
Nowadays, the cultivation of plants adapted to adverse conditions, such as drought and salinity, in the country has been considered. Meanwhile, Kochia scoparia, one of the forgotten plants, due to its classification in the group of halophytes, has specific characteristics suitable for cultivation in low-water and saline areas (Salehi, Kafi, & Kiani, 2012). This plant is known as an important annual forage crop, and its grains also have high nutritional value and oil, which can be considered for future industrial applications (Salehi et al., 2012). Studies on the salinity tolerance of the Kochia plant have shown that it is suitable for cultivation in saline areas, and in terms of quantity and quality, can compete with conventional forage plants. The use of natural organic materials, such as humic acid, has received more attention. These materials, as part of soil organic matter, are influenced by physical, chemical, and microbiological changes in biological molecules (Sabzevari & Khazaei, 2009; Dong, Córdova-Kreylos, Yang, Yuan, & Scow, 2009). Additionally, nitrogen is the most important element needed for plant growth and development. It is also a key component in many biological compounds, including proteins, nucleic acids, some hormones, and chlorophyll. Nitrogen plays an essential role in photosynthetic processes and the final function of plants (Kaur, Gupta, & Kaur, 2002; Taiz, Zeiger, Møller, & Murphy, 2015). As a result of this research, a combination of nitrogen and humic acid can be used as nutritional resources in salt stress conditions.
Materials and Methods
This experiment was conducted in the form of split plots based on the randomized complete block design with three replications in the Saline Research Farm of Ferdowsi University of Mashhad in the 2015 growth season. The main plot included drought stress with a four-week interruption of irrigation at three levels of control (irrigation until the end of the growing season), after establishment (50 days after planting), the beginning of flowering (71 days after planting) and late flowering (82 days after planting) The subplot was included nitrogen application at three levels of zero, 100 and 200 kg.ha-1 from urea fertilizer source. The optimum level of humic acid (2 per thousand) was done as seed at the time of planting for all treatments.
Results and Discussion
The results showed that the drought stress during vegetative and reproductive growth stages had a negative effect on the Kochia plant. However, its effect in the early stages of vegetative growth (after establishment) was greater than the stress at the end of the season (late flowering). Drought stress has a negative effect on Kochia grain yield by reducing the concentration of chlorophyll a, altering the chlorophyll a to b ratio, decreasing carotenoid concentration, and affecting relative leaf water content. However, seed treatments of humic acid and its combination with 100 kg.ha-1 nitrogen level by increasing th
South of Iran has been located in the dry belt and desert strip thus water stress has always been one of the serious problems in its agriculture (Buzarjomehri et al., 2020). Intercropping is the cultivation of two or more plant species in a specific land and growing season, which is important in agricultural systems with limited resources and low input (Brooker et al., 2015). Due to the differences in the rooting depth, lateral expansion, and root density of cereals and legumes, they have been the best candidates for intercropping traditionally for limited soil water and nutrient availability environments (Babalola, 1980; Haynes, 1980). Application of bio-fertilizers (PGPR bacteria) that have nitrogen (N) fixation and phosphorus (P) solubilizing activity (Azospirillum brasilense and Pseudomonas fluorescence, respectively) is a promising approach for obtaining N, P, and water-restricted areas (Tien et al, 1979; Barea, 2015). Organic manures enhance soil water holding capacity and serve as excellent slow-release sources of nitrogen (N) and phosphorus (P) in the soil (Risse et al., 2006). This study aimed to investigate the effect of different fertilizer systems (chemical, integrated, and bio-organic) on triticale grain yield and its components in sole and intercropped triticale in triticale/chickpea system under late season water stress in a hot and dry area of southern Iran (Fars province - Darab).
Introduction
The dust storm has become a regional phenomenon due to occurrence of severe droughts. Dust storms, recognized as significant atmospheric phenomena and associated with climate change, exert detrimental effects on plant growth and crop yield. This study aimed to assess the impact of soil dust on the competition between mung bean and red-root pigweed.
Materials and Methods
An experiment was carried out at the research greenhouse of Faculty of Agriculture at Ilam University during spring and summer 2022. The experiment was conducted as a factorial based on a completely randomized design with four replications. The experimental treatments were included five replacement ratios of mung bean and redroot pigweed (planting patterns 75% mung bean + 25% pigweed; 50% mung bean + 50% pigweed; 25% mung bean + 75% pigweed; monoculture of mung bean and redroot pigweed) and dust were at two levels (0 and 60 gr m-3).
Results and Discussion
The results showed that the dust causes symptoms of necrosis and leaf burn in mung bean and pigweed. The highest amount of carotenoids (3.59 mg g-1 fresh weight of leaf) was observed in the planting pattern of 75% mung bean + 25% pigweed under no dust conditions. The monoculture of pigweed under dust conditions had the lowest amount of carotenoids. Dust reduced the amount of total chlorophyll, leaf relative water content, plant height and length of inflorescence in Pigweed plant by 23.4, 12, 14.7 and 12%, respectively. Dust caused a decrease in the leaf area in pigweed in different patterns of intercropping. Photosynthesis rate, transpiration rate, leaf area, plant height, number of pods per plant and number of seed per plant in mung bean were respectively decreased by 31.2, 24.9, 28.8, 17.7, 29.7 and 36.7% due to dust application. The highest photosynthesis rate in mungbean (5.28 µmol of CO2 m-2 s-1), leaf area (129.1 cm2) and the number of seeds per plant (13 seed plant-1) were obtained from monoculture of mungbean. However, they were decreased under competition with pigweed. The biological yield in mungbean and pigweed under dust condition were, respectively, 42.6 and 16.8 % lower than that of no dust condition. Under dust conditions, the grain yield of mung bean and pigweed were, respectively, 32.8% and 42.6% lower than that of no dust condition. The actual yield of mung bean under competition with pigweed was lower than the predicted yield indicating the higher competitive effects of pigweed. In all planting patterns with and without dust, the total actual yields were higher than the predicted yield indicating a negative interference effects for mung bean. The relative total yield in most of the planting patterns was greater than one, suggesting increase in the partial relative yield and reduction of intra-species competition in pigweed. The negative effects of pigweed on mungbean were more visible in high densities of pigweed, which also showed a higher positive dominance index. The competition index showed
Deficit irrigation offers a solution for optimizing crop production under water stress conditions, albeit with an initial reduction in yield per unit area. Employing deficit irrigation aids in farm management in scenarios where land availability isn’t constrained, enabling the determination of optimal cultivation patterns while conserving water consumption. However, deficit irrigation may influence plant growth and development by inducing drought stress. Due to several capabilities, quinoa shows resistance to solar radiation, temperature, water availability, and atmospheric CO2 concentration, which makes it possible to cultivate it in different agricultural areas. Quinoa also has a great capacity for cultivation in dry and low-water soils. Although growth analysis sometimes provides valuable clues, it does not provide any physicochemical information related to the environmental reactions of plants; in other words, the main benefit of many quantities involved in growth analysis is to provide an accurate estimate of the ability and efficiency of the plant in the community at certain time intervals. In general, growth analysis evaluates the system based on the results of physiological manifestations. The purpose of this research was to evaluate the physiological growth analyses of three quinoa cultivars under different moisture levels in summer and spring planting dates in the South Khorasan region.
Food security is one of the basic needs of any society. Studies have been conducted on the foliar application of elements, especially silicon, calcium, and potassium, to reduce the adverse environmental effects on the physico-mechanical properties of cereals and improve their growth and development in order to maintain food security. Lodging, which is caused by a decrease in the mechanical properties of the plant stem's flexural strength, is characterized by bending or fracture that changes the angle of the grain stem from the vertical position. Due to the important factors involved, an important aspect of performance is directly and indirectly related to the occurrence of fungal diseases and nutrient-related issues affecting the physico-mechanical properties of the plant, such as flexural strength. The efficacy of silicon, calcium, and potassium in addressing these concerns is notable.
Salinity stands as a significant environmental stressor that profoundly curtails the growth and yield of crop plants. This adversity also extends to the impairment of pigments and plastids, leading to diminished chlorophyll indices, rates, and grain-filling durations. To counteract the deleterious impact of such stressors on plant growth, a spectrum of strategies has been devised. Prominent among these strategies are plant growth-promoting rhizobacteria, exemplified by azospirillum, and the utilization of nanoparticles like zinc and silicon. These factors play a pivotal role in elevating yield outcomes. Zinc's pivotal involvement spans protein metabolism, photosynthetic activities, and diverse physiological traits within plants. Particularly noteworthy is its contribution to rectifying zinc deficiency, a particularly critical concern in plants cultivated in high-pH soils. Notably, recent research has illuminated the potential of applying minute quantities of micronutrients, notably zinc via foliar spraying, in bolstering plant resilience against salt stress. Likewise, silicon emerges as a supplemental micronutrient that imparts heightened resistance to environmental stresses, fostering increased resilience within biological systems. Therefore, this study aimed to evaluate the effects of application of plant growth-promoting rhizobacteria and nanoparticles (zinc and silicon) on the yield, photosynthetic pigments, and filling components of triticale grain under salt stress.
One of the main challenges of modern agriculture in ensuring food security is development of strategies to deal with potential negative impacts and adapt to climate change. To address this challenge, it is crucial to investigate the effects of climatic factors on agricultural production at a spatiotemporal dimension, develop and utilize crop management decision-support tools, and support targeted agronomic research and policy. These endeavors necessitate the availability of accurate and standardized meteorological data.
Studying growth degree days and wheat phenology can significantly enhance our understanding of how wheat growth responds to climate change and aid farmers in adapting to and effectively mitigating its influence.
Grasspea (Lathyrus sativus L.) is one of the most important forage crops in the world. It contains 12 to 20% protein. Silicon (Si) existing in the Earth’s crust is classified as the most abundant element after oxygen. Although silicon is not considered an essential element for plant growth, but a number of studies have reported that it as an important factor in plants that plays an important role in the resistance mechanisms of plants against environmental stress. Also, it plays a crucial physiological role in photosynthetic rate and chlorophyll content. One of the most effective factors in increasing the Grasspea biomass is seed inoculation with plant growth-promoting rhizobacteria (PGPR). Some of the benefits provided by PGPR are the ability to produce gibberellic acid, cytokinins and ethylene, N2 fixation, solubilization of mineral phosphates and other nutrients. Numerous studies have shown a substantial increase in dry matter accumulation via inoculation with PGPR. Some researchers reported that seed inoculation with PGPR enhanced relative water content and photochemical efficiency of PSII lathyrus under water limitations. Therefore, the aim of this study was to evaluate the effects of nano silicon and seed inoculation with plant growth-promoting rhizobacteria on biomass, nodulation and some physiological traits of Grasspea.
The quantity and quality of forage plants are beneficial and useful due to their role in animal husbandry, reproduction and other livestock products. Due to the limitation of water resources, water-deficit as a significant biotic stress is the most severe threat to world food security and is responsible for many yield losses. Plants constantly modify their physiological processes in response to various biotic and abiotic stress to regulate the balance between plant growth and defense response. Many researchers have documented that plant nutrients are involved in biological processes of plants. It has been stated that the use of silicon by increasing the ability to absorb water can be useful to improve drought tolerance of sorghum, sorghum can with the help of silicon extract more water from dry soil and maintain more stomatal conductance.
Maize (Zea mays L.) is one of the most important cereals after wheat and rice in the tropical and temperate regions of the world. Also, its mean production is 8 ton ha-1. Moreover, the total area of under cultivation is 132572 hectares in Iran. Crop simulation models can play an important role in improving agricultural production systems in many developing countries. Crop models can simulate plant growth processes and grain yield instead of conducting several years of field experiments. On the other hands, crop simulation models should be calibrated and evaluated with independent data sets under different climatic conditions. Therefore, the purpose of this research was evaluation of the APSIM model for simulation of growth, development and yield of maize hybrids in Kerman province under different amounts of nitrogen.
Nitrogen (N) is one of the main limiting factors in agroecosystems all around the world. However, high application rates of N fertilizers would lead to negative environmental consequences. Reduction of N fertilizers consumption decreases production costs and environmental pollution. Therefore, N efficiency to be enhanced due to the high N fertilizer cost and required measures to prevent the waste of N. Cultivation of diverse crop cultivars with higher resources absorption and utilization efficiency is one of the major approaches in sustainable agriculture that would result in the effective use of natural and chemical inputs and reduce significantly the environmental risks. Quchan City is one of the potato production poles in Khorasan Razavi province. In this region, large amounts of N fertilizers annually are consumed in the potato agroecosystem. Therefore, the potato of the present study was evaluating N uptake and utilization efficiency, and finally, N uses efficiency in the potato agroecosystem of Quchan.
During the 1950s and 1960s, the green revolution led to a dramatic increase in global food and fodder production to eliminate hunger and boost food security. This production enhancement was accompanied by an intensified agricultural and chemical input consumption and increased cultivated area and mechanization. Although yield per unit area has improved in most crops, concerns about food security for the world's rising population are still significant. Guaranteeing food security in the future will necessitate a shift in management approaches to boost output, agroecosystem sustainability, and stability and reduce the environmental harm caused by agriculture. The first step to achieving sustainability and ecological intensification in agricultural systems is to have a comprehensive agroecological analysis of agricultural systems in each region. Hence, the complete evaluation and analysis of agroecological features according to their type in each region is necessary for establishing an optimal management technique. After analyzing the present state of each region's shared ecosystems, the optimal strategy for boosting production stability must be devised and implemented.
Introduction
The jujube, Ziziphus jujuba Mill. is a well-known medicinal plant with various nutritional values and pharmacological properties which grows in South Khorasan province, Iran, as the major producer of jujube in Iran. The jujube lace bug, Monosteira alticarinata Ghauri (Hemiptera: Tingidae) is the second most important pest of jujube trees after the jujube fruit fly, Carpomyia vesuviana Costa (Diptera: Tephritidae) in South Khorasan province. Its occurrence in Iran was reported for the first time in 2012 by Moodi from Birjand in South Khorasan province. Adults of M. alticarinata overwinter on the bark of trees, under fallen leaves and in spring they move to young jujube leaves where they feed and lay eggs on the underside, thus starting infestations. Both M. alticarinata adults and nymphs feed on underside of leaves and produce small chlorotic stippling on the upper leaf surface. Leaf undersides appear specifically black varnish spotted due to lace bug excrement. Their injury reduces photosynthesis and respiration and also causes aesthetically displeasing injured leaves. As a result, foliage becomes bronzed and leaves may drop early. The accumulation of excrements on the leaves, also results in reduction of the gas exchange like other lace bugs. Distribution pattern of an insect population is an important aspect as it represents the interaction between individuals of the species and their habitat. The importance of spatial distribution comes from its central role in ecological theories and its practical role in population sampling theory as well as in the development of rational pest management strategies. For these reasons, a great deal of effort has been invested in characterizing the spatial distribution of insect populations. Spatial dispersion of a population usually follows one of three models: aggregated (or contagious), random (or by chance) or uniform (or regular). To determine the spatial distribution pattern of a given species it is necessary to obtain data on the count of individuals in the ecosystem to be considered. Despite the importance of M. alticarinata in the region, no study has been conducted on the distribution of this pest in jujube plant in Iran. Knowledge of spatial distribution of M. alticarinata is useful for designing, pest management and development of population models and assessment of levels of its damage.
Materials and Methods
To investigate the spatial distribution pattern of different life stages of M. alticarinata, samplings were done weekly of jujube trees in 2020. Jujube leaf was selected as sampling unit and the reliable sample size with maximum relative variation of 20% was obtained 50. The number of egg, nymph and adult was recorded in three heights of jujube trees (1.5, 2, and 3 meters). The spatial distribution pattern of different life stages of lace bug was determined using mean-variance ratio, Lloyd's mean crowding index, Taylor´s power low and Iwao´s patchiness regression model.
Results
Simulation of Natural Frequencies of Orange Fruit Using Finite Element MethodJ. Agricultural Machinery
The growing consumer demand for high-quality products has led to the development of new technologies for assessing the quality of agricultural products. Iran is the 9th largest orange producer in the world. Every year, large quantities of agricultural products lose their optimal quality due to mechanical and physical damage during various operations such as harvesting, packaging, transportation, sorting, processing, and storage. This study is performed to identify the natural frequencies and vibration modes of the Thomson orange fruit using finite element modal analysis by ANSYS software. In addition, physical properties including mass, volume, density, and principal dimensions were measured, and mechanical properties were determined using Instron Texture Profile Analysis. The dynamic behavior of the orange fruit was simulated using the pendulum impact test. Afterward, the obtained impact was applied to the orange fruit by force gauge and three-axis accelerometer sensors in both polar and equatorial directions. The three-dimensional geometric model of the orange fruit was drawn in the ANSYS software. After meshing and applying the boundary conditions, the first 20 modes and corresponding natural frequencies were obtained. Since the objective of this study was to identify the natural frequencies of the orange fruit, it was considered to have free movement and rotation in space. The results showed that the natural frequencies of orange fruit are in the range of 0 to 248.41 Hz. Knowledge of the texture characteristics and dynamic behavior of horticultural products is essential for the design and development of agricultural machinery. Furthermore, the design and development of agricultural machinery are directly related to the biological properties of agricultural products.
Agriculture is a cornerstone of many developing economies, providing food, income, and employment for millions of people. It is also projected to play a vital role in feeding a global population of 9.1 billion people by 2050. However, there are growing concerns about the environmental impact of agriculture, particularly in arid and semi-arid regions like Iran. Managing water and fertilizer usage in agriculture is crucial to ensuring food security and sustainability. However, conducting field experiments to assess the interaction of all factors involved is expensive and time-consuming. This research focuses on optimizing maize production in Kerman province, a region where maize is a major crop. The research is motivated by the need to improve resource management in Iran, where water and fertilizer resources are limited. The APSIM model is used to determine the best management scenario for maize production in Kerman province. APSIM is a crop growth simulation model that can be used to predict the impact of different management practices on crop yield, water use efficiency, and nutrient use efficiency. The use of APSIM in this research provides a cost-effective and time-efficient alternative to conducting extensive field experiments. The results of this research will contribute to the development of sustainable and efficient agricultural practices in Kerman province and similar regions. These regions are characterized by resource constraints, such as limited water and fertilizer availability. The research aimed to simulate the effect of management parameters (planting date and irrigation) on Crop yield and subsequently achieve the optimal management scenario.
Chickpea (Cicer arietinum L.) is one of the most important crops in the human food basket worldwide. It is a highly nutritious pulse crop with low digestible carbohydrates, protein, essential fats, fiber, and a range of minerals and vitamins. As the human population grows, the demand for this protein source increases and various approaches to its sustainable products are being developed. Autumn cultivation of chickpea in cold regions requires the introduction of cultivars tolerant to freezing stress. The ability of plants to overwinter depends on the biochemical and physiological responses induced by their cold acclimation duration. Cold acclimation mechanisms in the plant are a fundamental reason for plant tolerance increase in autumn cultivation. Hence, investigating the mentioned traits can help identify cold-tolerant genotypes. Identifying attributes that provide a suitable description of the diversity between genotypes is critical through canonical correlation analysis, cluster analysis, and determining the genetic distance.
More Related Content
Similar to Evaluation of Waterlogging Tolerance in Twenty-One Cultivars and Genotypes of Bread Wheat (Triticum Aestivum L.) and its Effect on some Physiological Characteristics of Shoot and Root System at the Three-Leaf Stage
Quinoa is a dicotyledonous plant from the Amaranthaceae family, with favorable nutritional value and a high potential for growth and production in adverse environmental conditions. Despite being three carbon, it has high water consumption efficiency and as a new crop, due to its wide adaptation to different environment conditions such as salinity and drought, as well as being premature, it is suitable for planting in arid and desert areas and has many factors. Genetic and environmental factors such as genotype, density, arrangement and planting date, soil salinity, and drought stress affect yield. Among these, drought is one of the most important non-living stresses that cause great damage to crops and horticulture in the world every year. And especially Iran, which is considered an arid and semi-arid country. The effect of moisture stress on plants varies depending on which stage of plant growth occurs and plants can work through various mechanisms such as reducing growth parameters, closing pores, reducing photosynthesis, changing regulatory mechanisms of ion transport, and increasing activity. Antioxidant enzymes cope with drought stress to some extent, although such mechanisms are energy-intensive and cause a decline in performance.
Salinity is one of the major constraints to wheat growth, which hampers production, causing yield loss in arid and semi-arid regions. Reductions in growth resulting from high salinity are because of both osmotic stress, inducing a water deficit, and the effects of excess Na+ and Cl– ions on critical biochemical processes. Salt stress induces a significant reduction in photosynthesis through the reduction of leaf area and photosynthetic pigments. Several strategies have been developed to decrease the toxic effects caused by high salinity on plant growth. Among them, the use of plant growth-promoting rhizobacteria (PGPR) such as Pseudomonas and Mycorrhiza play an important role in yield improvement. Many studies have been published on the beneficial effects of bacterial inoculation on plant physiology and growth under salt stress. One of the common hypotheses employed in most of the studies conducted under salinity stress was the lowering of ethylene level by the ACC-deaminase activities of PGPR and improved plant growth and yield under salinity stress.
It was reported that the application of Pseudomonas spp. improved plant growth by decreasing the uptake of Na+ and increasing the activities of antioxidant enzymes under salinity stress. The selective uptake of K+ as opposed to Na+ is considered one of the important physiological mechanisms contributing to salt tolerance in many plant species. Inoculation with PGPR significantly decreased Na+ uptake and increased K+ content and enhanced levels of K+ that could be to mitigate oxidative stress imposed by higher salinity. Some researchers have reported that PGPR species like Azotobacter and Pseudomonas increased the growth and biomass of canola (Brassica napus L.) under salinity stress.
A Better understanding of wheat physiological responses under salinity may help in programs in which the objective is to improve the grain yield under salinity stress. Therefore, this study aimed to evaluate the physiological, stomata conductance, along with root and shoot Na+/ K+ ratios) of wheat to cycocel and PGPR application under salinity stress.
Introduction
Prolonged droughts and lack of water resources, followed by the salinity of water and soil resources, have faced many limitations in the production of some conventional agricultural and garden plants, especially in arid and semi-arid regions of the country. Therefore, the introduction of new plants with high yield potential, which have suitable growth in saline soils, the threshold of their seed yield reduction is high, and the production product is of high quality has been considered in Iran. Quinoa with the scientific name Chenopodium quinoa Willd. It is an annual plant originating from Latin America, which, despite its high nutritional value, tolerates a wide range of abiotic stresses and can grow in marginal lands. For this reason, this experiment was conducted to investigate the performance of quinoa plant genotypes against different levels of salinity in the research field of the Gorgan Agricultural Meteorological Research Department.
Materials and Methods
Cultivation of seeds of nine genotypes Titicaca (control number), Giza1, RedCarina, Q18, Q21, Q22, Q26, Q29, and Q31 obtained from Karaj Seedling and Seed Breeding Research Institute in a factorial experiment based on a complete random block design. Plastic pots were made with a bed of sand and clay in a ratio of two to one on March 5, 2019. The application of NaCl salt solution treatments at the levels of zero, 10, 20, and 30 decisiemens/m started after the establishment of the plant and reached the six-leaf stage and lasted for 45 days. After salinity treatment, morphological traits including plant height, stem diameter, number of sub-branches, inflorescence length, inflorescence width, biomass, 1000 seed weight, and seed weight per plant were measured.
In the pursuit of a resilient and progressive agricultural system, the incorporation of diverse fertilizers is deemed essential. This practice not only enhances product quality but also aids in cost reduction. However, over-reliance on a specific type of input can inadvertently lead to unintended repercussions. The unrestricted utilization of chemical fertilizers, for instance, can precipitate adverse outcomes such as imbalanced pH levels, the accumulation of heavy elements, soil structure deterioration, and environmental contamination. Conversely, organic fertilizers, while environmentally friendly, often release nutrients at a slower rate, potentially disrupting optimal plant growth. To attain a balanced and sustainable agricultural approach, the combined application of organic and chemical fertilizers is advocated. Moreover, harnessing the biological potential inherent in soil ecosystems, including beneficial microbial communities encompassing bacteria and fungi, emerges as a promising avenue in cultivating sustainable agriculture. Acknowledging the adverse impact of late-season heat stress on wheat production in Khuzestan and recognizing the significance of reducing chemical fertilizer usage while augmenting organic and biological fertilizers to foster ecological health, this experiment undertakes the exploration of the effects of a synergistic approach. Specifically, it delves into the combined utilization of nitrogen and compost fertilizers, complemented by the incorporation of plant growth-promoting rhizobacteria. This endeavor aims to shed light on how this combined strategy operates within the context of terminal heat stress, assessing its influence on the physiological attributes and yield of the wheat cultivar Chamran 2.
Introduction
Nowadays, the cultivation of plants adapted to adverse conditions, such as drought and salinity, in the country has been considered. Meanwhile, Kochia scoparia, one of the forgotten plants, due to its classification in the group of halophytes, has specific characteristics suitable for cultivation in low-water and saline areas (Salehi, Kafi, & Kiani, 2012). This plant is known as an important annual forage crop, and its grains also have high nutritional value and oil, which can be considered for future industrial applications (Salehi et al., 2012). Studies on the salinity tolerance of the Kochia plant have shown that it is suitable for cultivation in saline areas, and in terms of quantity and quality, can compete with conventional forage plants. The use of natural organic materials, such as humic acid, has received more attention. These materials, as part of soil organic matter, are influenced by physical, chemical, and microbiological changes in biological molecules (Sabzevari & Khazaei, 2009; Dong, Córdova-Kreylos, Yang, Yuan, & Scow, 2009). Additionally, nitrogen is the most important element needed for plant growth and development. It is also a key component in many biological compounds, including proteins, nucleic acids, some hormones, and chlorophyll. Nitrogen plays an essential role in photosynthetic processes and the final function of plants (Kaur, Gupta, & Kaur, 2002; Taiz, Zeiger, Møller, & Murphy, 2015). As a result of this research, a combination of nitrogen and humic acid can be used as nutritional resources in salt stress conditions.
Materials and Methods
This experiment was conducted in the form of split plots based on the randomized complete block design with three replications in the Saline Research Farm of Ferdowsi University of Mashhad in the 2015 growth season. The main plot included drought stress with a four-week interruption of irrigation at three levels of control (irrigation until the end of the growing season), after establishment (50 days after planting), the beginning of flowering (71 days after planting) and late flowering (82 days after planting) The subplot was included nitrogen application at three levels of zero, 100 and 200 kg.ha-1 from urea fertilizer source. The optimum level of humic acid (2 per thousand) was done as seed at the time of planting for all treatments.
Results and Discussion
The results showed that the drought stress during vegetative and reproductive growth stages had a negative effect on the Kochia plant. However, its effect in the early stages of vegetative growth (after establishment) was greater than the stress at the end of the season (late flowering). Drought stress has a negative effect on Kochia grain yield by reducing the concentration of chlorophyll a, altering the chlorophyll a to b ratio, decreasing carotenoid concentration, and affecting relative leaf water content. However, seed treatments of humic acid and its combination with 100 kg.ha-1 nitrogen level by increasing th
South of Iran has been located in the dry belt and desert strip thus water stress has always been one of the serious problems in its agriculture (Buzarjomehri et al., 2020). Intercropping is the cultivation of two or more plant species in a specific land and growing season, which is important in agricultural systems with limited resources and low input (Brooker et al., 2015). Due to the differences in the rooting depth, lateral expansion, and root density of cereals and legumes, they have been the best candidates for intercropping traditionally for limited soil water and nutrient availability environments (Babalola, 1980; Haynes, 1980). Application of bio-fertilizers (PGPR bacteria) that have nitrogen (N) fixation and phosphorus (P) solubilizing activity (Azospirillum brasilense and Pseudomonas fluorescence, respectively) is a promising approach for obtaining N, P, and water-restricted areas (Tien et al, 1979; Barea, 2015). Organic manures enhance soil water holding capacity and serve as excellent slow-release sources of nitrogen (N) and phosphorus (P) in the soil (Risse et al., 2006). This study aimed to investigate the effect of different fertilizer systems (chemical, integrated, and bio-organic) on triticale grain yield and its components in sole and intercropped triticale in triticale/chickpea system under late season water stress in a hot and dry area of southern Iran (Fars province - Darab).
Introduction
The dust storm has become a regional phenomenon due to occurrence of severe droughts. Dust storms, recognized as significant atmospheric phenomena and associated with climate change, exert detrimental effects on plant growth and crop yield. This study aimed to assess the impact of soil dust on the competition between mung bean and red-root pigweed.
Materials and Methods
An experiment was carried out at the research greenhouse of Faculty of Agriculture at Ilam University during spring and summer 2022. The experiment was conducted as a factorial based on a completely randomized design with four replications. The experimental treatments were included five replacement ratios of mung bean and redroot pigweed (planting patterns 75% mung bean + 25% pigweed; 50% mung bean + 50% pigweed; 25% mung bean + 75% pigweed; monoculture of mung bean and redroot pigweed) and dust were at two levels (0 and 60 gr m-3).
Results and Discussion
The results showed that the dust causes symptoms of necrosis and leaf burn in mung bean and pigweed. The highest amount of carotenoids (3.59 mg g-1 fresh weight of leaf) was observed in the planting pattern of 75% mung bean + 25% pigweed under no dust conditions. The monoculture of pigweed under dust conditions had the lowest amount of carotenoids. Dust reduced the amount of total chlorophyll, leaf relative water content, plant height and length of inflorescence in Pigweed plant by 23.4, 12, 14.7 and 12%, respectively. Dust caused a decrease in the leaf area in pigweed in different patterns of intercropping. Photosynthesis rate, transpiration rate, leaf area, plant height, number of pods per plant and number of seed per plant in mung bean were respectively decreased by 31.2, 24.9, 28.8, 17.7, 29.7 and 36.7% due to dust application. The highest photosynthesis rate in mungbean (5.28 µmol of CO2 m-2 s-1), leaf area (129.1 cm2) and the number of seeds per plant (13 seed plant-1) were obtained from monoculture of mungbean. However, they were decreased under competition with pigweed. The biological yield in mungbean and pigweed under dust condition were, respectively, 42.6 and 16.8 % lower than that of no dust condition. Under dust conditions, the grain yield of mung bean and pigweed were, respectively, 32.8% and 42.6% lower than that of no dust condition. The actual yield of mung bean under competition with pigweed was lower than the predicted yield indicating the higher competitive effects of pigweed. In all planting patterns with and without dust, the total actual yields were higher than the predicted yield indicating a negative interference effects for mung bean. The relative total yield in most of the planting patterns was greater than one, suggesting increase in the partial relative yield and reduction of intra-species competition in pigweed. The negative effects of pigweed on mungbean were more visible in high densities of pigweed, which also showed a higher positive dominance index. The competition index showed
Deficit irrigation offers a solution for optimizing crop production under water stress conditions, albeit with an initial reduction in yield per unit area. Employing deficit irrigation aids in farm management in scenarios where land availability isn’t constrained, enabling the determination of optimal cultivation patterns while conserving water consumption. However, deficit irrigation may influence plant growth and development by inducing drought stress. Due to several capabilities, quinoa shows resistance to solar radiation, temperature, water availability, and atmospheric CO2 concentration, which makes it possible to cultivate it in different agricultural areas. Quinoa also has a great capacity for cultivation in dry and low-water soils. Although growth analysis sometimes provides valuable clues, it does not provide any physicochemical information related to the environmental reactions of plants; in other words, the main benefit of many quantities involved in growth analysis is to provide an accurate estimate of the ability and efficiency of the plant in the community at certain time intervals. In general, growth analysis evaluates the system based on the results of physiological manifestations. The purpose of this research was to evaluate the physiological growth analyses of three quinoa cultivars under different moisture levels in summer and spring planting dates in the South Khorasan region.
Food security is one of the basic needs of any society. Studies have been conducted on the foliar application of elements, especially silicon, calcium, and potassium, to reduce the adverse environmental effects on the physico-mechanical properties of cereals and improve their growth and development in order to maintain food security. Lodging, which is caused by a decrease in the mechanical properties of the plant stem's flexural strength, is characterized by bending or fracture that changes the angle of the grain stem from the vertical position. Due to the important factors involved, an important aspect of performance is directly and indirectly related to the occurrence of fungal diseases and nutrient-related issues affecting the physico-mechanical properties of the plant, such as flexural strength. The efficacy of silicon, calcium, and potassium in addressing these concerns is notable.
Salinity stands as a significant environmental stressor that profoundly curtails the growth and yield of crop plants. This adversity also extends to the impairment of pigments and plastids, leading to diminished chlorophyll indices, rates, and grain-filling durations. To counteract the deleterious impact of such stressors on plant growth, a spectrum of strategies has been devised. Prominent among these strategies are plant growth-promoting rhizobacteria, exemplified by azospirillum, and the utilization of nanoparticles like zinc and silicon. These factors play a pivotal role in elevating yield outcomes. Zinc's pivotal involvement spans protein metabolism, photosynthetic activities, and diverse physiological traits within plants. Particularly noteworthy is its contribution to rectifying zinc deficiency, a particularly critical concern in plants cultivated in high-pH soils. Notably, recent research has illuminated the potential of applying minute quantities of micronutrients, notably zinc via foliar spraying, in bolstering plant resilience against salt stress. Likewise, silicon emerges as a supplemental micronutrient that imparts heightened resistance to environmental stresses, fostering increased resilience within biological systems. Therefore, this study aimed to evaluate the effects of application of plant growth-promoting rhizobacteria and nanoparticles (zinc and silicon) on the yield, photosynthetic pigments, and filling components of triticale grain under salt stress.
One of the main challenges of modern agriculture in ensuring food security is development of strategies to deal with potential negative impacts and adapt to climate change. To address this challenge, it is crucial to investigate the effects of climatic factors on agricultural production at a spatiotemporal dimension, develop and utilize crop management decision-support tools, and support targeted agronomic research and policy. These endeavors necessitate the availability of accurate and standardized meteorological data.
Studying growth degree days and wheat phenology can significantly enhance our understanding of how wheat growth responds to climate change and aid farmers in adapting to and effectively mitigating its influence.
Grasspea (Lathyrus sativus L.) is one of the most important forage crops in the world. It contains 12 to 20% protein. Silicon (Si) existing in the Earth’s crust is classified as the most abundant element after oxygen. Although silicon is not considered an essential element for plant growth, but a number of studies have reported that it as an important factor in plants that plays an important role in the resistance mechanisms of plants against environmental stress. Also, it plays a crucial physiological role in photosynthetic rate and chlorophyll content. One of the most effective factors in increasing the Grasspea biomass is seed inoculation with plant growth-promoting rhizobacteria (PGPR). Some of the benefits provided by PGPR are the ability to produce gibberellic acid, cytokinins and ethylene, N2 fixation, solubilization of mineral phosphates and other nutrients. Numerous studies have shown a substantial increase in dry matter accumulation via inoculation with PGPR. Some researchers reported that seed inoculation with PGPR enhanced relative water content and photochemical efficiency of PSII lathyrus under water limitations. Therefore, the aim of this study was to evaluate the effects of nano silicon and seed inoculation with plant growth-promoting rhizobacteria on biomass, nodulation and some physiological traits of Grasspea.
The quantity and quality of forage plants are beneficial and useful due to their role in animal husbandry, reproduction and other livestock products. Due to the limitation of water resources, water-deficit as a significant biotic stress is the most severe threat to world food security and is responsible for many yield losses. Plants constantly modify their physiological processes in response to various biotic and abiotic stress to regulate the balance between plant growth and defense response. Many researchers have documented that plant nutrients are involved in biological processes of plants. It has been stated that the use of silicon by increasing the ability to absorb water can be useful to improve drought tolerance of sorghum, sorghum can with the help of silicon extract more water from dry soil and maintain more stomatal conductance.
Maize (Zea mays L.) is one of the most important cereals after wheat and rice in the tropical and temperate regions of the world. Also, its mean production is 8 ton ha-1. Moreover, the total area of under cultivation is 132572 hectares in Iran. Crop simulation models can play an important role in improving agricultural production systems in many developing countries. Crop models can simulate plant growth processes and grain yield instead of conducting several years of field experiments. On the other hands, crop simulation models should be calibrated and evaluated with independent data sets under different climatic conditions. Therefore, the purpose of this research was evaluation of the APSIM model for simulation of growth, development and yield of maize hybrids in Kerman province under different amounts of nitrogen.
Nitrogen (N) is one of the main limiting factors in agroecosystems all around the world. However, high application rates of N fertilizers would lead to negative environmental consequences. Reduction of N fertilizers consumption decreases production costs and environmental pollution. Therefore, N efficiency to be enhanced due to the high N fertilizer cost and required measures to prevent the waste of N. Cultivation of diverse crop cultivars with higher resources absorption and utilization efficiency is one of the major approaches in sustainable agriculture that would result in the effective use of natural and chemical inputs and reduce significantly the environmental risks. Quchan City is one of the potato production poles in Khorasan Razavi province. In this region, large amounts of N fertilizers annually are consumed in the potato agroecosystem. Therefore, the potato of the present study was evaluating N uptake and utilization efficiency, and finally, N uses efficiency in the potato agroecosystem of Quchan.
During the 1950s and 1960s, the green revolution led to a dramatic increase in global food and fodder production to eliminate hunger and boost food security. This production enhancement was accompanied by an intensified agricultural and chemical input consumption and increased cultivated area and mechanization. Although yield per unit area has improved in most crops, concerns about food security for the world's rising population are still significant. Guaranteeing food security in the future will necessitate a shift in management approaches to boost output, agroecosystem sustainability, and stability and reduce the environmental harm caused by agriculture. The first step to achieving sustainability and ecological intensification in agricultural systems is to have a comprehensive agroecological analysis of agricultural systems in each region. Hence, the complete evaluation and analysis of agroecological features according to their type in each region is necessary for establishing an optimal management technique. After analyzing the present state of each region's shared ecosystems, the optimal strategy for boosting production stability must be devised and implemented.
Introduction
The jujube, Ziziphus jujuba Mill. is a well-known medicinal plant with various nutritional values and pharmacological properties which grows in South Khorasan province, Iran, as the major producer of jujube in Iran. The jujube lace bug, Monosteira alticarinata Ghauri (Hemiptera: Tingidae) is the second most important pest of jujube trees after the jujube fruit fly, Carpomyia vesuviana Costa (Diptera: Tephritidae) in South Khorasan province. Its occurrence in Iran was reported for the first time in 2012 by Moodi from Birjand in South Khorasan province. Adults of M. alticarinata overwinter on the bark of trees, under fallen leaves and in spring they move to young jujube leaves where they feed and lay eggs on the underside, thus starting infestations. Both M. alticarinata adults and nymphs feed on underside of leaves and produce small chlorotic stippling on the upper leaf surface. Leaf undersides appear specifically black varnish spotted due to lace bug excrement. Their injury reduces photosynthesis and respiration and also causes aesthetically displeasing injured leaves. As a result, foliage becomes bronzed and leaves may drop early. The accumulation of excrements on the leaves, also results in reduction of the gas exchange like other lace bugs. Distribution pattern of an insect population is an important aspect as it represents the interaction between individuals of the species and their habitat. The importance of spatial distribution comes from its central role in ecological theories and its practical role in population sampling theory as well as in the development of rational pest management strategies. For these reasons, a great deal of effort has been invested in characterizing the spatial distribution of insect populations. Spatial dispersion of a population usually follows one of three models: aggregated (or contagious), random (or by chance) or uniform (or regular). To determine the spatial distribution pattern of a given species it is necessary to obtain data on the count of individuals in the ecosystem to be considered. Despite the importance of M. alticarinata in the region, no study has been conducted on the distribution of this pest in jujube plant in Iran. Knowledge of spatial distribution of M. alticarinata is useful for designing, pest management and development of population models and assessment of levels of its damage.
Materials and Methods
To investigate the spatial distribution pattern of different life stages of M. alticarinata, samplings were done weekly of jujube trees in 2020. Jujube leaf was selected as sampling unit and the reliable sample size with maximum relative variation of 20% was obtained 50. The number of egg, nymph and adult was recorded in three heights of jujube trees (1.5, 2, and 3 meters). The spatial distribution pattern of different life stages of lace bug was determined using mean-variance ratio, Lloyd's mean crowding index, Taylor´s power low and Iwao´s patchiness regression model.
Results
Simulation of Natural Frequencies of Orange Fruit Using Finite Element MethodJ. Agricultural Machinery
The growing consumer demand for high-quality products has led to the development of new technologies for assessing the quality of agricultural products. Iran is the 9th largest orange producer in the world. Every year, large quantities of agricultural products lose their optimal quality due to mechanical and physical damage during various operations such as harvesting, packaging, transportation, sorting, processing, and storage. This study is performed to identify the natural frequencies and vibration modes of the Thomson orange fruit using finite element modal analysis by ANSYS software. In addition, physical properties including mass, volume, density, and principal dimensions were measured, and mechanical properties were determined using Instron Texture Profile Analysis. The dynamic behavior of the orange fruit was simulated using the pendulum impact test. Afterward, the obtained impact was applied to the orange fruit by force gauge and three-axis accelerometer sensors in both polar and equatorial directions. The three-dimensional geometric model of the orange fruit was drawn in the ANSYS software. After meshing and applying the boundary conditions, the first 20 modes and corresponding natural frequencies were obtained. Since the objective of this study was to identify the natural frequencies of the orange fruit, it was considered to have free movement and rotation in space. The results showed that the natural frequencies of orange fruit are in the range of 0 to 248.41 Hz. Knowledge of the texture characteristics and dynamic behavior of horticultural products is essential for the design and development of agricultural machinery. Furthermore, the design and development of agricultural machinery are directly related to the biological properties of agricultural products.
Similar to Evaluation of Waterlogging Tolerance in Twenty-One Cultivars and Genotypes of Bread Wheat (Triticum Aestivum L.) and its Effect on some Physiological Characteristics of Shoot and Root System at the Three-Leaf Stage (20)
Agriculture is a cornerstone of many developing economies, providing food, income, and employment for millions of people. It is also projected to play a vital role in feeding a global population of 9.1 billion people by 2050. However, there are growing concerns about the environmental impact of agriculture, particularly in arid and semi-arid regions like Iran. Managing water and fertilizer usage in agriculture is crucial to ensuring food security and sustainability. However, conducting field experiments to assess the interaction of all factors involved is expensive and time-consuming. This research focuses on optimizing maize production in Kerman province, a region where maize is a major crop. The research is motivated by the need to improve resource management in Iran, where water and fertilizer resources are limited. The APSIM model is used to determine the best management scenario for maize production in Kerman province. APSIM is a crop growth simulation model that can be used to predict the impact of different management practices on crop yield, water use efficiency, and nutrient use efficiency. The use of APSIM in this research provides a cost-effective and time-efficient alternative to conducting extensive field experiments. The results of this research will contribute to the development of sustainable and efficient agricultural practices in Kerman province and similar regions. These regions are characterized by resource constraints, such as limited water and fertilizer availability. The research aimed to simulate the effect of management parameters (planting date and irrigation) on Crop yield and subsequently achieve the optimal management scenario.
Chickpea (Cicer arietinum L.) is one of the most important crops in the human food basket worldwide. It is a highly nutritious pulse crop with low digestible carbohydrates, protein, essential fats, fiber, and a range of minerals and vitamins. As the human population grows, the demand for this protein source increases and various approaches to its sustainable products are being developed. Autumn cultivation of chickpea in cold regions requires the introduction of cultivars tolerant to freezing stress. The ability of plants to overwinter depends on the biochemical and physiological responses induced by their cold acclimation duration. Cold acclimation mechanisms in the plant are a fundamental reason for plant tolerance increase in autumn cultivation. Hence, investigating the mentioned traits can help identify cold-tolerant genotypes. Identifying attributes that provide a suitable description of the diversity between genotypes is critical through canonical correlation analysis, cluster analysis, and determining the genetic distance.
Long-term use of chemical fertilizers can cause many adverse effects. In addition, excessive consumption of chemical fertilizers can lead to decreased food safety and low quality of vegetables, such as the accumulation of nitrates in plants. Today, using organic fertilizers is an efficient way to achieve sustainable agricultural development. The release rate of nutrients from organic fertilizers is slow and hardly exceeds the absorption capacity of plants compared to chemical fertilizers.
The excessive use of chemical fertilizers is a leading cause of environmental pollution in the agriculture sector. Therefore, optimizing fertilizer application is a crucial approach to boost production while minimizing environmental harm. On the other hand, application of chemical fertilizers along with manure can be considered as the proper management system that led to reduce the amount of chemical fertilizers and adverse effects on environment and also improve nutrition for plants. Response-surface methodology is a powerful tool to optimize production resources which decreases cost and time of the experiments by reducing number of them. Therefore, the aim of the study was optimization of chemical fertilizers of nitrogen and phosphorus along with manure application in fodder maize production.
Crop cultivars are the most important factor in crop optimum quantity and quality products achievement and cotton is one of the most industrial crops. Objectives of new cotton cultivars introduction are yield increase, earliness, and resistance to biotic and abiotic stresses. Despite the improvement and introduction of numerous new cotton cultivars in Iran in recent years, new foreign cotton cultivars have also been registered, introduced, and commercialized for the first time in Iran. Therefore, the cultivation of new foreign cotton cultivars that show early maturity, high-yielding, and have good fiber quality is included in projects of the Ministry of Jihad of Agriculture for cotton cultivation development. This research was carried out to evaluate and compare the seed cotton yield and its components and some fiber qualitative characteristics of new cotton with thought VCU trial in South Khorasaد province in Birjand Mohammadieh agriculture research station to introduce and commercialize these cultivars.
Seed pretreatment is one of the simple techniques that can increase seed vigor and seedling establishment, and thus plant yield. Seed pretreatment can be done with water (hydropriming), inorganic salts such as potassium nitrate (halopriming), and growth regulators such as salicylic acid (hormone priming) and ascorbic acid (vitamin priming). Another effective factor in producing strong seeds is proper nutrition of the mother plants. Proper nutrition of the maternal plant in the form of foliar sprays with essential elements leads to the production of high-quality seeds, which affects germination and yield. Considering the positive role of seed pretreatment in improving germination rate and seedling establishment, and increasing seed yield of various plants as a result of foliar application of growth regulators and inorganic salts, this experiment was conducted to study the effect of seed pretreatment and foliar spraying with salicylic acid, ascorbic acid and potassium nitrate on improving physiological and biochemical characteristics, yield and yield components of borage.
Applying innovative nanotechnology in agriculture is considered as one of the promising approaches to obtain significant increases of crop yield. Nanoparticles (NPs) are considered potential agents for agriculture as fertilizers and growth enhancers and using of nano-fertilizers has led to an increasing in the efficiency of nutrients, the correct management of fertilizer consumption, and a reduction of the frequency of fertilizer application. Stimulants are compounds that initiate signals for cells to increase or decrease the production of secondary metabolites and plant defense response. Stimulants such as Putrescine play a role in regulating various plant physiological processes. In this regard, considering the importance of using new technologies, including nanotechnology, in sustainable agriculture to increase the quantitative and qualitative performance of agricultural products, especially oil-medicinal plants, and the lack of sufficient information about the use of iron nanoparticles and polyamine putricine in Camelina plant nutrition, The effect of foliar spraying of these stimulants on functional, morphological and physiological traits of Camelina plant (Soheil veriety) was evaluated.
Global warming directly affects agricultural production and food security (Ainsworth & Ort, 2010). Temperature controls the rate of plant metabolic processes that ultimately affect biomass production and grain yield (Hay & Walker, 1981). Although farmers are not able to control the climatic conditions, management and changes in factors such as irrigation, soil, crop varieties, activities, and technologies used in the cultivation of crops can reduce the harmful effects of climate change (Moradi et al., 2014). One of the reliable approaches to studying the effects of climate change on agricultural production is using crop growth models. The present study was conducted to simulate the effects of climate change on phonological stages and yield of maize and to investigate the possibility of mitigating the negative effects of climate change on maize by changing the sowing date and selecting suitable cultivars as management strategies for adaptation to climate change in Kermanshah region.
Intensive agriculture, despite high production, has adverse environmental effects, mainly due to the use of pesticides and chemical fertilizers. Therefore, we need alternative agricultural systems that are more economically and environmentally sustainable to produce crops. One of the sustainable methods in the production of agricultural products is intercropping. Intercropping of two or more species in a plot of land can increase biodiversity and resource utilization as agricultural perspective, which in turn can lead to increased yield stability. Intercropping uses resources more efficiently than monoculture, preventing the growth and spread of weeds by shading and suffocating weeds, and in some cases with allelopathic. Intercropping of cereals and legumes is recommended for the development of sustainable food production systems, especially in planting systems based on reduced consumption of foreign inputs. The importance of these systems depends on the nitrogen stabilized by the legumes. The aim of this experiment was to study the effects of row intercropping of barley and vetch and different levels of ammonium nitrate fertilizer on weed biomass, yield components and yield of two species in Karaj climatic condition.
Wheat (Triticum aestivum L.) is one of the most important crops in the world as well as in Iran. It has experienced many improvements in terms of yield and quality traits during recent decades. Wheat, like energy, is known as a strategic commodity and is one of the important indicators of agriculture. This plant has the highest area under cultivation and production among other cereals in the world. Planting date is an important factor in crop production because meteorological parameters vary with changes in planting date. Delay in planting is one of the problems that is common in almost all wheat growing areas of Iran and is one of the main causes of reduced yields of wheat cultivars. Yield reduction rate varies depending on the delay in planting and cultivars, and the results of some experiments indicate that this amount sometimes reaches more than 35% of potential grain yield. Phenology and growth rate due to their effect on duration and the occurrence of different stages of development and the environmental conditions prevailing in each of these stages, are the key point of adaptation to various environmental conditions such as delayed planting date. This experiment was designed to identify the changes in yield and yield components and phenological stages of new bread wheat cultivars with different growth habits and to investigate the possibility of introducing cultivars compatible with delayed planting date in the region.
There is an urgent need to increase per capita food production to compete with high population growth while maintaining environmental sustainability. Because nitrogen plays a vital role in food production for humans and livestock, nitrogen management is essential in food production. In most cropping systems, nitrogen management seems to be a major challenge due to its high mobility and natural tendency for losses from the soil-plant system to the environment. Soil organic carbon plays a key role in improving soil ecological conditions. Adding organic matter to the soil is an excellent tool for improving physical, chemical and biological conditions and is almost always desirable. Soil organic carbon stock of crop ecosystems may be increased by improving farming practices. The application of green manure, fertilizer and the return of crop straw into the soil are known as management operations to increase soil organic carbon. Fertilizers, especially nitrogen, increase crop yield, and organic carbon is returned to the soil through roots and debris, which in most cases leads to increased soil organic carbon.
Sugar beet (Beta vulgaris L.) is the second most important sugar crop after sugarcane, which annually produces about 40% of total sugar production worldwide and is adapted to different climatic conditions (El-Hag et al., 2015). Due to global warming, autumn cultivation of sugar beet is predicted to become more priority in the future, but autumn cultivation is in danger of bolting and flowering in many areas. Excessive bolting reduces sugar content, root yield, and purity of raw syrup. In general, both early sowing and delayed sowing reduce root yield, sugar, and leaf area index and increase the percentage of impurities. Therefore, this experiment was designed and implemented with the aim of feasibility study of autumn cultivation of sugar beet and determination of the best planting date in North, Razavi, and South Khorasan provinces for three new varieties resistant to sugar beet.
Climate change is rapidly degrading the conditions of crop production. For instance, increasing salinization and aridity is forecasted to increase in most parts of the world. As a consequence, new stress-tolerant species and genotypes must be identified and used for future agriculture. Stress-tolerant species exist but are actually underutilized and neglected. Quinoa, scientifically known as Chenopodium quinoa Willd. is a member of the Amaranthaceae family. Promoting the cultivation and nutrition of quinoa will diversify food products in the country, sustainable production, increase farmers' incomes and provide part of the community's food needs. Crop simulation models have been used for various studies such as selecting the appropriate cultivar, determining the best planting date, predicting the effect of diversity and climate change on growth. Field research requires a lot of time and money, while computer simulation models can save time and money by conducting extensive experimental simulations.
Quinoa Phenological Development Modeling Based on Field Data
Evaluation of Waterlogging Tolerance in Twenty-One Cultivars and Genotypes of Bread Wheat (Triticum Aestivum L.) and its Effect on some Physiological Characteristics of Shoot and Root System at the Three-Leaf Stage
1. Iranian Journal of Field Crops Research
Homepage: https://jcesc.um.ac.ir
Research Article
Vol. 21, No. 3, Fall 2023, p. 303-318
Evaluation of Waterlogging Tolerance in Twenty-One Cultivars and Genotypes
of Bread Wheat (Triticum Aestivum L.) and its Effect on some Physiological
Characteristics of Shoot and Root System at the Three-Leaf Stage
S. B. Fazeli 1*
, M. Meskarbashee2
, A. Rahnama Ghahfarokhi3
Received: 13 December 2022
Revised: 11 February 2023
Accepted: 26 February 2023
How to cite this article:
Fazeli, S. B., Meskarbashee, M., & Rahnama Ghahfarokhi, A. (2023). Evaluation of
Waterlogging Tolerance in Twenty-One Cultivars and Genotypes of Bread Wheat (Triticum
Aestivum L.) and its Effect on some Physiological Characteristics of Shoot and Root System
at the Three-Leaf Stage. Iranian Journal of Field Crops Research, 21(3), 303-318. (in Persian
with English abstract). https://doi.org/10.22067/jcesc.2023.80038.1209
Introduction
Covering a staggering 215 million hectares, wheat stands as the world's most extensively cultivated crop
plant. Just like its botanical counterparts, wheat operates as an obligate aerobic organism, implying its reliance
on absorbing oxygen from the surrounding environment to facilitate growth, proliferation, and the successful
completion of its life cycle. Annual instances of waterlogging stress inflict harm upon wheat crops, attributed to
inadequate irrigation practices, subpar drainage systems, uneven field leveling, elevated groundwater levels, the
presence of unyielding impermeable layers, and bouts of intense, abrupt rainfall. This adverse impact is
progressively escalating, potentially influenced by the ongoing shifts in climate patterns. Consequently, the
adoption of resilient cultivars and the genetic enhancement of bread wheat assume critical importance. These
strategies are aimed at augmenting the wheat's capacity to effectively cope with waterlogging stress, aligning it
with the mounting demands of a burgeoning global population.
To achieve these goals, it is necessary to understand the factors causing waterlogging stress damage in wheat
and to know the mechanisms of tolerance in this plant. The survival of root terminal meristem cells under
waterlogging stress conditions is very limited, and their ability to grow again after removing the stress is also
restricted. Waterlogging stress leads to the death of primary roots and reduced growth of lateral roots in wheat.
However, there is variation among wheat cultivars concerning these traits. Reduced access to oxygen hampers
root growth and nutrient absorption, including nitrogen. Consequently, photosynthesis and carbohydrate
availability decrease, further restricting root growth.
Materials and Methods
An outdoor pot experiment was conducted to investigate the effect of waterlogging stress on shoot and root
dry matter, as well as some physiological characteristics. The experiment followed a split-plot design based on
randomized complete blocks with three replications. The stress was applied at the three-leaf stage, and three
control levels were used: no waterlogging stress, mild stress (48 hours of waterlogging stress), and severe stress
(120 hours of waterlogging stress) as the main factors. Cultivars and genotypes were also included as secondary
factors.
1- Ph.D Student, Department of Plant Production and Genetics, College of Agriculture, Shahid Chamran University of
Ahvaz, Ahvaz, Iran
2- Professor, Department of Plant Production and Genetics, College of Agriculture, Shahid Chamran University of
Ahvaz, Ahvaz, Iran
3- Department of Plant Production and Genetics, College of Agriculture, Shahid Chamran University of Ahvaz, Ahvaz,
Iran
(*- Corresponding Author Email: sb-fazeli@stu.scu.ac.ir)
https://doi.org/10.22067/jcesc.2023.80038.1209
2. 403
جلد ،ایران زراعی پژوهشهای نشریه
12
شماره ،
3
،
پاییز
2411
During the stress period, the water level was maintained at approximately 5 cm above the soil level. The
cultivation took place outdoors in plastic pots. Data analysis was performed using SAS software, and graphs
were generated using Excel software. Comparisons between treatments were based on the standard error. After
testing different models, the linear regression model was ultimately employed.
Results and Discussion
Mild and severe waterlogging stress resulted in a significant decrease in shoot dry matter of 14.06% and
38.37%, respectively, across all cultivars and genotypes. Different cultivars and genotypes exhibited varying
responses to waterlogging stress. To further understand the reasons for these differences, among the 21 cultivars
and genotypes, Mehrgan and Sarang cultivars, as well as ms 93-16 and ms 93-6 genotypes, were selected due to
their contrasting tolerance levels and yield potential. These selected cultivars and genotypes were studied to
analyze specific root traits.
Amidst severe waterlogging stress, a significant 38% reduction in root dry matter and a corresponding 29%
decrease in root volume were recorded when compared to stress-free conditions. This closely mirrored the
decline evident in shoot dry matter. Evaluation of the susceptibility index during the three-leaf stage unveiled
that sole resilience was exhibited by the Aflak cultivar. In contrast, the remaining cultivars and genotypes were
stratified into semi-tolerant and semi-susceptible categories.
Notably, regression analysis underscored that even brief periods of waterlogging stress ushered in a reduction
in dry matter. Furthermore, the elongation of the waterlogging duration magnified this decrease in dry matter,
thereby mitigating the disparities across various cultivars and genotypes.
Conclusion
In general, cultivars that were able to sustain higher levels of photosynthetic activity during waterlogging
stress demonstrated a lower percentage decrease in dry matter. Although the Mehrgan cultivar experienced a
significant reduction in dry matter yield and fell into the semi-sensitive group, it consistently exhibited
significantly higher dry matter yield compared to other cultivars and genotypes across all treatments.
Acknowledgment
The authors express their gratitude to the Agriculture Research Center of Khuzestan for providing the seeds,
the Research Vice-Chancellor of the Shahid Chamran University of Ahvaz for covering the costs, and all the
employees of the Department of Plant Production and Genetics.
Keywords: Photosynthesis rate, Root volume, Stomatal conductance, Susceptibility index
15. ،همکاران و فاضلی
ویژگی برخی بر آن اثر و غرقابی تنش تحمل ارزیابی
ریشه و هوایی اندام فیزیولوژیک های
...
413
سلول این مجدد رشد توانایی
ا پدس ها
( دارد تدنش رفدع ز
Shabala,
2011
.)
نتیجه
گیری
غرقاب تنش
معنی کاهش به منجر ی
روزنده هدایت اسپد عدد دار
ای
و شدد هوایی اندام و ریشه خشک ماده آن پی در و فتوسنتز سرعت و
ژنوتیپ و ارقام در کاهش این
حساس های
و ارقدام در .بود شدیدتر ،تر
ژنوتیپ
متحمل های
مددت طدوتنی غرقدابی تدنش اعمدال با و تر
تدر
کم ریشه خشک ماده کاهش
کا از تر
.بود هوایی اندام خشک ماده هش
مواجده در هوایی اندام خشک ماده شدید کاهش وجود با مهرگان رقم
تدنش سدطح سه هر در ،بات عملکرد پتانسیل دلیل به غرقابی تنش با
ژنوتیدپ و ارقدام سدایر به نسبت خشک ماده بیشترین دارای
،بدود هدا
مناسب غرقابی تنش مستعد مناطق در کشت جهت بنابراین
نظدر به تر
می
.رسد
سپاسگزای
بدین
وسیله
تحق مرکز از
ی
قات
کشاورز
ی
اهواز
بابت
اخت در
ی
ار
قدرار
بذور دادن
،
پنوهش معاونت از
ی
شه دانشگاه
ی
د
جهدت بده اهواز چمران
ت
أ
م
ی
ن
هز
ی
نه
ها
ی
آزما
ی
ش
و
همچن
ی
ن
مهندسدی گدروه کارکنان تمامی
گیاهی ژننتیک و تولید
قدر و تشکر
د
ان
ی
م
ی
گرد
د
.
References
1. Dickin, E., & Wright, D. (2008). The effects of winter waterlogging and summer drought on the growth and yield
of winter wheat (Triticum aestivum L.). European Journal of Agronomy, 28(3), 234-244.
https://doi.org/10.1016/j.eja.2007.07.010
2. Donnelly, D. M., Dorea, J. R. R., Yang, H., & Combs, D. K. (2018). Technical note: Comparison of dry matter
measurements from handheld near-infrared units with oven drying at 60°C for 48 hours and other on-farm
methods. Journal of Dairy Science, 101(11), 9971-9977. https://doi.org/10.3168/jds.2017-14027
3. Fazeli, S. B., Rahnama, A., & Hassibi, P. (2022). Effect of waterlogging stress on yield and some physiological
characteristics of two mungbean cultivars under Ahvaz climatic conditions. Plant Productions, 45(1), 95-108.
https://doi.org/10.22055/ppd.2020.30538.1805
4. Ghobadi, M. E., Nadian, H., Bakhshandeh, A., Fathi, G., & Ghobadi, M. (2006). Investigating root growth,
biological and grain yield in wheat genotypes under waterlogging stress in different stages of growth. Seed and
Plant Journal, 22(4), 513-27. (In Persian).
5. Herzog, M., Striker, G. G., Colmer, T. D., & Pedersen, O. (2016). Mechanisms of waterlogging tolerance in wheat
– a review of root and shoot physiology. Plant, Cell and Environment, 39, 1068-1086.
https://doi.org/10.1111/pce.12676
6. Li, C., Jiang, D., Wollenweber, B., Li, Y., Dai, T,. & Cao, W. (2011). Waterlogging pretreatment during
vegetative growth improves tolerance to waterlogging after anthesis in wheat. Plant Science, 180(5), 672-678.
https://doi.org/10.1016/j.plantsci.2011.01.009
7. Malik, A. I., Colmer, T. D., Lambers, H., Setter, T. L., & Schortemeyer, M. (2002). Short-term waterlogging has
long-term effects on the growth and physiology of wheat. New Phytologist, 153(2), 225-236.
https://doi.org/10.1046/j.0028-646X.2001.00318.x
8. Musgrave, M. E., & Ding, N. (1998). Evaluating Wheat Cultivars for Waterlogging Tolerance. Crop Science,
38(1), 90- 97. https://doi.org/10.2135/cropsci1998.0011183X003800010016x
9. Musgrave, M. E. (1994). Waterlogging effects on yield and photosynthesis in eight winter wheat cultivars. Crop
Science, 34, 1314-1318. https://doi.org/10.2135/cropsci1994.0011183x003400050032x
10. Pierdomenico, P., William, A., Laurentius, A., & Voesenek, C. J. (2011). Plants and flooding stress. New
Phytologist, 190, 269-273. https://doi.org/10.1111/j.1469-8137.2011.03702.x
11. Rafiqul Islam, M., Abdul Hamid, M., Abdul Karim, M., Moynul Haque, Q., Abdul Khaliq, J., & Uddin, A. (2008).
Gas exchanges and yield responses of mungbean (Vigna radiata L. Wilczek) genotypes differing in flooding
tolerance. Acta Physiologiae Plantarom, 30, 690-707. https://doi.org/10.1007/s11738-008-0168-0
12. Sage, R. F., Sharkey, T. D., & Seemann, J. R. (1988). The in vivo response of the ribulose-1,5-bisphosphate
carboxylase activation state and the pool sizes of photosynthetic metabolites to elevated CO2 in (Phaseolus
vulgaris L.). Planta, 174, 407-416. https://doi.org/10.1007/BF00959528
13. Sage, R. F., Sharkey, T. D., & Seemann, J. R. (1990). Regulation of ribulose- 1,5-bisphosphate carboxylase
activity in responses light intensity and CO2 in the C3 annuals (Chenopodium album L.) and (Phaseolus vulgaris
L.). Plant Physiology, 94, 1735-1742. https://doi.org/10.1104/pp.94.4.1735
14. Sena Gomes, A. R., & Kozlowski, T. T. (1980). Growth responses and adaptations of Fraxinus pennsylvanica
seedlings to flooding. Plant Physiology, 66, 267-271. https://doi.org/10.1104/pp.66.2.267
15. Shabala, S. (2011). Physiological and cellular aspects of phytotoxicity tolerance in plants: the role of membrane
transporters and implications for crop breeding for waterlogging tolerance. New Phytologist, 190, 289-298.
https://doi.org/10.1111/J.1469-8137.2010.03575.X
16. 413
جلد ،ایران زراعی پژوهشهای نشریه
12
شماره ،
3
،
پاییز
2411
16. Trnka, M., Rotter, R. P., Ruiz-Ramos, M., Kersebaum, K. C., Olesen, J. E., Zalud, Z. & Semenov, M. A. (2014).
Adverse weather conditions for Europeanwheat production will become more frequent with climate change.
Nature Climate Change, 4, 637-643. https://doi.org/10.1038/nclimate2242
17. Tiryakioglu, M., Karanlik, S., & Arslan, M. (2015). Response of bread-wheat seedlings to waterlogging stress.
Turkish Jornal of Agriculture and Forestry, 39, 807-816. https://doi.org/10.3906/tar-1407-124
18. Von Caemmerer, S., & Edmondson, D. L. (1986). The relationship between steady-state gas exchange, in vivo
RuBP2 carboxylase activity and some carbon reduction cycle intermediates in Raphanus sativus. Australian
Journal of Plant Physiology, 13 669-688. https://doi.org/10.1071/pp9860669