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STRIGOLACTONES: Role In Plant Development

Ravikumar Gouda
Ravikumar Gouda

role of strigolactones in crop development how. l

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Welcome to Seminar-1
• Ravi Kumar • PGS14AGR6523 STRIGOLACTONES: Role In Plant Development
Contents 1. Introduction 2. What are strigolactones 3. Strigolactone biosynthesis 4. Strigolactone with root parasitic plant 5. Strigolactone with AM fungi. 6. Strigolactones in suboptimal conditions. 7. Strigolactones in root development. 8. Additional functions of Strigolactones. 9. Future issues 10. Conclusion
 Hormones are chemicals produced in one part of an organism and transported to another part where they exert a response.  Only a small amount of hormone is required to alter cell metabolism.  Cells respond to a hormone when they express a specific receptor for that hormone 4 Introduction
 The hormone binds to the receptor protein, resulting in the activation of a signal transduction mechanism that ultimately leads to cell type-specific responses.  Hormones may act differently on different cell types.  They play critical roles during all developmental stages in plants, from early embryogenesis to senescence.
plant hormone families  Auxins  Giberellins  Cytokinins  Ethylene  Abscisic Acid  Brassinosteroids 6
Hormone Where produced/found Major Functions Auxin Shoot apical meristems and young leaves Stimulates stem elongation Cytokinins Roots Regulate cell division Gibberellins Meristems of buds and roots Stimulates stem elongation, reproduction Brassinosteroids All tissue Promote cell expansion Abscisic acid (ABA) All tissue Inhibits growth Ethylene All tissue Promotes ripening of fruits
 Other signaling molecules (hormones)  Strigolactone. (recently identified) 8
What are strigolactones?  Strigolactones (SLs) constitute a new class of plant hormones which are active as germination stimulants for seeds of parasitic weeds of Striga, Orobanche, and Pelipanchi spp, in hyphal branching of arbuscular mycorrhizal (AM) fungi and as inhibitors of shoot branching. Strigolactones are signaling compounds made by plants.  They have two main functions: 1.Endogenous hormones to control plant development. 2.Components of root exudates to promote symbiotic interactions between plants and soil microbes.
Some plants that are parasitic on other plants have established a third function, 3.which is to stimulate germination of their seeds when in close proximity to the roots of a suitable host plant.  It is this third function that led to the original discovery and naming of strigolactones.
DISCOVERY OF STRIGOLACTONES  The first naturally occurring germination stimulant for Strigolactones was isolated as early as 1966 from root exudates of cotton (Gossypium hirsutum L.), which, is not a host for Striga or Orobanche (Cook et al., 1966).  Strigolactones were also discovered in root exudates due to their ability to stimulate germination of seeds of the parasitic plant Striga, the ‘witch weed’in sorghum[Sorghum bicolor (L.) Moench], maize (Zea mays L.), and common millet (Panicum miliaceum L.)
Plants of the witch weed Striga hermonthica parasitizing maize plants in Africa. www.biomedcentral.com
Molecular Formula C17H14O5 Strigolactones (SLs) are a group of terpenoid lactones in which a tricyclic lactone (ABC ring) and a methyl butenolide (D ring) are connected by an enol ether bridge
Strigolactone Biosynthesis Lopez-Raez et al., (2008)
Strigolactone biosynthesis and signaling pathway  Strigolactones are derived from the carotenoids through two subsequent enzymatic cleavage steps performed by the carotenoid cleaving dioxygenases CCD7 and CCD8 described in Arabidopsis (MAX), Rice (D/HTD), pea (RMS) and petunia (DAD).  For further conversion into strigolactones, a cytochrome P450 enzyme (cyp450) has been reported to be required in Arabidopsis (MAX1) while two other proteins, identified in rice (D27) and pea (RMS2) whose functions have not yet been clarified, must also be involved in strigolactone biosynthesis.
 In the tomato mutant Sl-ORT1, in which the mutation is still unidentified, strigolactone biosynthesis and CCD7 expression are both down-regulated.  The perception of strigolactones and/or the downstream signaling pathway are mediated by an F-box leucine rich protein (MAX2, D3, RMS4), and/- hydrolase found in rice (D14) and a protein of unknown function in pea (RMS3).
Biosynthesis of Strigolactones
Genes involved in the synthesis or signaling pathway of strigolactone in different species
STRIGOLACTONES GERMINATION STIMULANTS FOR ROOT PARASITIC PLANTS Lopez-Raez, et al., 2008
Root parasitic plant species and their life cycle  Plant species of the genera Striga, Orobanche and Phelipanche are root parasites that affect many important food crops.  These three genera, belonging to the Orobanchaceae family.  Striga species have an absolute host requirement to develop and complete their life cycle.  Striga spp. occur in tropical and subtropical regions, with special incidence in Sub-Saharan Africa infecting mainly cereal crops.  The most damaging is Striga hermonthica, followed by Striga asiatica and Striga gesnerioides.  The broomrapes, of the genera Orobanche and Phelipanche, cause similar damage to food production as the Striga spp.
 The life cycles of Striga, Orobanche and Phelipanche spp. are many similarities.  All of them produce minute seeds that remain viable in the soil for up to fourteen years.  Once germination has been triggered, the radicle produces from the testa, elongates towards the host root and develops a haustorium, an organ that can attach to and penetrate the roots of the host plant.  In Striga spp., the haustorium establishes a xylem–xylem connection with the host from where it can with draw water and nutrients.  Phelipanche and Orobanche spp. form connections with both phloem and xylem.  Once attached to the host and having established a connection with the vascular system, the parasites can take up nutrients, water, and possibly also hormones from the host.
Root Parasitic Plants Life cycle of a root parasitic plant, Orobanche minor. (a) Seed germination is elicited by host- derived stimulants, including strigolactones. (b) Seedling attaches to host root with haustoria. (c– d ) Parasite tubercles grow underground for several weeks or months before emergence of the flowering shoots. (e) The parasite produces a large number of seeds, which remain viable for many years in soil.
STRIGOLACTONES AS BRANCHING FACTORS FOR ARBUSCULAR MYCORRHIZAL FUNGI Zwanenburg, et al.,2013
Branching Factors for AM Fungi  Why plants exude SLs that enable them to be located by their enemies.  because these compounds may have other roles that outweigh the potential risks of parasitism.  Such a beneficial role of SLs was unveiled through the discovery that these compounds function as branching factors for symbiotic AM fungi, from which the plants benefit.
 AM fungi are soil borne microorganisms that form symbiotic associations with the majority of land plants.  The symbiotic interaction between plants and the AM fungi is initiated by mutual exchange of signaling molecules.  Under appropriate temperature conditions, the spores of AM fungi germinate, and their hyphae elongate to a limited extent.  If a host root is not present, the hyphae stop growing and become inactive.  In the presence of host roots, AM hyphae differentiate into specific morphological structures characterized by extensive branching.
 These fungi penetrate and colonize plant roots, where they develop highly branched structures called arbuscules, which are the sites of nutrient exchange.  The fungi supply their hosts with water and nutrients, primarily phosphate and nitrogen that are obtained through the hyphae that reside outside in the soil, and in turn the AM fungi receive photosynthates(carbohydrates) from their host plants.  AM symbiosis also give up the plant more tolerant to biotic and abiotic stresses.
Arbuscular mycorrhizae in clover root, showing arbuscules (blue arrows) within the root cortex, and hyphae radiating from the root surface.
Auxin is transported from the apical meristem while cytokinin and strigolatone are transported from the roots (shown by black arrows). Red bars show repression while blue arrows show activation. Lateral buds have the potential to grow into side shoots when the hormone balance permits, and can be achieved experimentally by removing the apical meristem.
The strigolactone-deficient mutant of Arabidopsis shows exuberant branching. The wild-type plant (left) has few secondary shoots compared to the mutant (right).
Strigolactones help plants to cover with suboptimal conditions Brewer, et al., 2013
 when the plant encounters certain difficulties in the environment, such as suboptimal nutrient availability, strigolactone levels rise in order to optimize and adapt the plant’s growth strategy to fit the conditions. (Umehara et al., 2008; Kohlen et al., 2011).  The most extensively studied, strigolactone-related, suboptimal plant growth condition is phosphate deprivation.  Strigolactone levels increase in red clover grown under low phosphate conditions (Yoneyama et al., 2007).
In red clover plant role of SL elevation in response to Pi deficiency. (Left) When Pi is sufficient, plants can absorb Pi through their roots. SL levels are low in roots, and outgrowth of axillary buds is not inhibited. Black arrows indicate the flow of Pi, which is distributed from the roots to the leaves, outgrowing axillary buds, and apical meristem. (Right) Under low-Pi conditions, SL levels in roots are highly elevated, inhibiting bud outgrowth in shoots (1). Senescence of old leaves is activated (2), nutrients such as Pi are translocated and concentrated within the apical meristem and young tissues (3), and supplied by AMF in soil (4). Root- parasitic plants might respond to SLs to detect potential hosts (5). Black arrows indicate the flow of Pi; gray arrows indicate the flow and action of SLs.
STRIGOLACTONES IN ROOT DEVELOPMENT Brewer, et al., 2013
 Under optimal growth conditions, strigolactones repress lateral root formation(Kapulnik et al., 2011a; Ruyter-Spira et al., 2011) and promote root hair elongation(Kapulnik et al., 2011a).  In the case of lateral root formation, auxin is a key regulator and the distribution of auxin determines lateral root positioning, initiation, and elongation (reviewed by De Smet (2012).  Strigolactones may affect lateral root formation via changes in auxin efflux in the root.  Similarly, cytokinins can negatively affect lateral root formation, which is suggested to be due to interference with auxin transport in lateral root parts (Bishopp et al., 2011). Hence, in the case of lateral roots, strigolactones and cytokinins may be considered to act similarly, in the sense that both may influence auxin distribution.
The Proposed Roles of Strigolactones in Adult Plant Growth and Development. (A) Under normal conditions, a basal level of strigolactone production in a wild-type plant reduces lateral shoots and roots, but enhances plant height, secondary growth, senescence, and root hairs. (B) Much of this influence of strigolactones can be seen in mutants that are unable to make or respond to strigolactones. They display more lateral branches and lateral roots, and less secondary growth and arbuscular mycorrhizal (AM) fungi symbiosis (in compatible species). (C) Reduced phosphate triggers increased strigolactone production. This leads to greater branch repression and, initially, to enhanced lateral roots and root hairs, and enhances AM fungi symbiosis. Other phenotypes like plant height, secondary growth, senescence, especially with regard to low-phosphate- induced strigolactone production.
Additional Functions of Strigolactones Seto, et al., 2012
SLs control a wide range of developmental features. In vascular plants, SLs positively regulate secondary growth (A), leaf senescence (B), root hair elongation (C) and primary root growth (D), while they negatively regulate axillary bud growth (E) and adventitious root formation (F). SLs negatively regulate chloronemata branching (G) and colony extension (H) in the moss Physcomitrella patens. Red arrows indicate positive effects. T-bars in blue depict negative effects.
Effect of GR24, a synthetic analogue of strigolactones, on gene expression of solopathogenic strain of Sporisorium reilianum S. K. Sabbagh., (2011)
• Sporisorium reilianum f.sp zeae a soilborne basidiomycetous fungus belonging to Ustilaginaceae, is the causal agent of maize head smut. • showed that strigolactones rapidly trigger O2 consumption of the fungi. • effects of GR24 on some genes involved in cell respiration and pathogenicity of U. maydis, a fungus phyllogeniticaly related to Sporisorium reilianum. • At 1 h post supplementation of GR24, all genes involved in cell respiration were induced. • Cell respiration increased a bit at 5 h, and was null at 8 h post supplementation of GR24. • No induction of genes involved in cell respiration was observed in those times, but an induction of actin and putative 12 kDa heat shock protein was observed. • The quantitative analysis of cells induced at 8 h post supplementation of GR24 did not show any increase in candidate genes transcripts.
Strigolactones are positive regulators of light-harvesting genes in tomato Mayzlish-Gati, et al., 2010
Illustration of the light reaction-associated biological pathways in which differentially regulated genes putatively participate.Differentially regulated genes were identified from hybridization data of roots exposed to GR24 and IAA treatments [IAA (10_8 M), IAA(10_8 M)+GR24 (13.5 lM), and GR24 (27 lM)] versus non-treated controls. Blue or red squares represent individual genes. The colourwithin the squares represents fold change in gene expression in treatments versus controls; values of fold change are as indicated in thecolour scale. Chl signifies chlorophyll.
FUTURE ISSUES 1. SLs, which are exuded by plant roots, serve as branching factors for beneficial AM symbionts but at the same time also trigger the germination of root parasites. So far there is no knowledge on whether there is a possibility to manipulate SL biosynthesis, metabolism, and exudation in a way that will avoid or inhibit the germination of root parasitic weeds without effecting AM symbiosis. 2. The diverse functions of SLs, hint that this group of compounds may also have other functions in plant metabolism and development. Are SLs involved in the regulation of growth and development of other plant organs? Are SLs involved in the regulation of the reproductive organs? Are SLs involved in the regulation of leaf initiation and development?
CONCLUSION
Thank you

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STRIGOLACTONES: Role In Plant Development

  • 2. • Ravi Kumar • PGS14AGR6523 STRIGOLACTONES: Role In Plant Development
  • 3. Contents 1. Introduction 2. What are strigolactones 3. Strigolactone biosynthesis 4. Strigolactone with root parasitic plant 5. Strigolactone with AM fungi. 6. Strigolactones in suboptimal conditions. 7. Strigolactones in root development. 8. Additional functions of Strigolactones. 9. Future issues 10. Conclusion
  • 4.  Hormones are chemicals produced in one part of an organism and transported to another part where they exert a response.  Only a small amount of hormone is required to alter cell metabolism.  Cells respond to a hormone when they express a specific receptor for that hormone 4 Introduction
  • 5.  The hormone binds to the receptor protein, resulting in the activation of a signal transduction mechanism that ultimately leads to cell type-specific responses.  Hormones may act differently on different cell types.  They play critical roles during all developmental stages in plants, from early embryogenesis to senescence.
  • 6. plant hormone families  Auxins  Giberellins  Cytokinins  Ethylene  Abscisic Acid  Brassinosteroids 6
  • 7. Hormone Where produced/found Major Functions Auxin Shoot apical meristems and young leaves Stimulates stem elongation Cytokinins Roots Regulate cell division Gibberellins Meristems of buds and roots Stimulates stem elongation, reproduction Brassinosteroids All tissue Promote cell expansion Abscisic acid (ABA) All tissue Inhibits growth Ethylene All tissue Promotes ripening of fruits
  • 8.  Other signaling molecules (hormones)  Strigolactone. (recently identified) 8
  • 9. What are strigolactones?  Strigolactones (SLs) constitute a new class of plant hormones which are active as germination stimulants for seeds of parasitic weeds of Striga, Orobanche, and Pelipanchi spp, in hyphal branching of arbuscular mycorrhizal (AM) fungi and as inhibitors of shoot branching. Strigolactones are signaling compounds made by plants.  They have two main functions: 1.Endogenous hormones to control plant development. 2.Components of root exudates to promote symbiotic interactions between plants and soil microbes.
  • 10. Some plants that are parasitic on other plants have established a third function, 3.which is to stimulate germination of their seeds when in close proximity to the roots of a suitable host plant.  It is this third function that led to the original discovery and naming of strigolactones.
  • 11. DISCOVERY OF STRIGOLACTONES  The first naturally occurring germination stimulant for Strigolactones was isolated as early as 1966 from root exudates of cotton (Gossypium hirsutum L.), which, is not a host for Striga or Orobanche (Cook et al., 1966).  Strigolactones were also discovered in root exudates due to their ability to stimulate germination of seeds of the parasitic plant Striga, the ‘witch weed’in sorghum[Sorghum bicolor (L.) Moench], maize (Zea mays L.), and common millet (Panicum miliaceum L.)
  • 12. Plants of the witch weed Striga hermonthica parasitizing maize plants in Africa. www.biomedcentral.com
  • 13.
  • 14. Molecular Formula C17H14O5 Strigolactones (SLs) are a group of terpenoid lactones in which a tricyclic lactone (ABC ring) and a methyl butenolide (D ring) are connected by an enol ether bridge
  • 16. Strigolactone biosynthesis and signaling pathway  Strigolactones are derived from the carotenoids through two subsequent enzymatic cleavage steps performed by the carotenoid cleaving dioxygenases CCD7 and CCD8 described in Arabidopsis (MAX), Rice (D/HTD), pea (RMS) and petunia (DAD).  For further conversion into strigolactones, a cytochrome P450 enzyme (cyp450) has been reported to be required in Arabidopsis (MAX1) while two other proteins, identified in rice (D27) and pea (RMS2) whose functions have not yet been clarified, must also be involved in strigolactone biosynthesis.
  • 17.  In the tomato mutant Sl-ORT1, in which the mutation is still unidentified, strigolactone biosynthesis and CCD7 expression are both down-regulated.  The perception of strigolactones and/or the downstream signaling pathway are mediated by an F-box leucine rich protein (MAX2, D3, RMS4), and/- hydrolase found in rice (D14) and a protein of unknown function in pea (RMS3).
  • 19. Genes involved in the synthesis or signaling pathway of strigolactone in different species
  • 20. STRIGOLACTONES GERMINATION STIMULANTS FOR ROOT PARASITIC PLANTS Lopez-Raez, et al., 2008
  • 21. Root parasitic plant species and their life cycle  Plant species of the genera Striga, Orobanche and Phelipanche are root parasites that affect many important food crops.  These three genera, belonging to the Orobanchaceae family.  Striga species have an absolute host requirement to develop and complete their life cycle.  Striga spp. occur in tropical and subtropical regions, with special incidence in Sub-Saharan Africa infecting mainly cereal crops.  The most damaging is Striga hermonthica, followed by Striga asiatica and Striga gesnerioides.  The broomrapes, of the genera Orobanche and Phelipanche, cause similar damage to food production as the Striga spp.
  • 22.  The life cycles of Striga, Orobanche and Phelipanche spp. are many similarities.  All of them produce minute seeds that remain viable in the soil for up to fourteen years.  Once germination has been triggered, the radicle produces from the testa, elongates towards the host root and develops a haustorium, an organ that can attach to and penetrate the roots of the host plant.  In Striga spp., the haustorium establishes a xylem–xylem connection with the host from where it can with draw water and nutrients.  Phelipanche and Orobanche spp. form connections with both phloem and xylem.  Once attached to the host and having established a connection with the vascular system, the parasites can take up nutrients, water, and possibly also hormones from the host.
  • 23. Root Parasitic Plants Life cycle of a root parasitic plant, Orobanche minor. (a) Seed germination is elicited by host- derived stimulants, including strigolactones. (b) Seedling attaches to host root with haustoria. (c– d ) Parasite tubercles grow underground for several weeks or months before emergence of the flowering shoots. (e) The parasite produces a large number of seeds, which remain viable for many years in soil.
  • 24. STRIGOLACTONES AS BRANCHING FACTORS FOR ARBUSCULAR MYCORRHIZAL FUNGI Zwanenburg, et al.,2013
  • 25. Branching Factors for AM Fungi  Why plants exude SLs that enable them to be located by their enemies.  because these compounds may have other roles that outweigh the potential risks of parasitism.  Such a beneficial role of SLs was unveiled through the discovery that these compounds function as branching factors for symbiotic AM fungi, from which the plants benefit.
  • 26.  AM fungi are soil borne microorganisms that form symbiotic associations with the majority of land plants.  The symbiotic interaction between plants and the AM fungi is initiated by mutual exchange of signaling molecules.  Under appropriate temperature conditions, the spores of AM fungi germinate, and their hyphae elongate to a limited extent.  If a host root is not present, the hyphae stop growing and become inactive.  In the presence of host roots, AM hyphae differentiate into specific morphological structures characterized by extensive branching.
  • 27.  These fungi penetrate and colonize plant roots, where they develop highly branched structures called arbuscules, which are the sites of nutrient exchange.  The fungi supply their hosts with water and nutrients, primarily phosphate and nitrogen that are obtained through the hyphae that reside outside in the soil, and in turn the AM fungi receive photosynthates(carbohydrates) from their host plants.  AM symbiosis also give up the plant more tolerant to biotic and abiotic stresses.
  • 28.
  • 29. Arbuscular mycorrhizae in clover root, showing arbuscules (blue arrows) within the root cortex, and hyphae radiating from the root surface.
  • 30.
  • 31. Auxin is transported from the apical meristem while cytokinin and strigolatone are transported from the roots (shown by black arrows). Red bars show repression while blue arrows show activation. Lateral buds have the potential to grow into side shoots when the hormone balance permits, and can be achieved experimentally by removing the apical meristem.
  • 32. The strigolactone-deficient mutant of Arabidopsis shows exuberant branching. The wild-type plant (left) has few secondary shoots compared to the mutant (right).
  • 33. Strigolactones help plants to cover with suboptimal conditions Brewer, et al., 2013
  • 34.  when the plant encounters certain difficulties in the environment, such as suboptimal nutrient availability, strigolactone levels rise in order to optimize and adapt the plant’s growth strategy to fit the conditions. (Umehara et al., 2008; Kohlen et al., 2011).  The most extensively studied, strigolactone-related, suboptimal plant growth condition is phosphate deprivation.  Strigolactone levels increase in red clover grown under low phosphate conditions (Yoneyama et al., 2007).
  • 35. In red clover plant role of SL elevation in response to Pi deficiency. (Left) When Pi is sufficient, plants can absorb Pi through their roots. SL levels are low in roots, and outgrowth of axillary buds is not inhibited. Black arrows indicate the flow of Pi, which is distributed from the roots to the leaves, outgrowing axillary buds, and apical meristem. (Right) Under low-Pi conditions, SL levels in roots are highly elevated, inhibiting bud outgrowth in shoots (1). Senescence of old leaves is activated (2), nutrients such as Pi are translocated and concentrated within the apical meristem and young tissues (3), and supplied by AMF in soil (4). Root- parasitic plants might respond to SLs to detect potential hosts (5). Black arrows indicate the flow of Pi; gray arrows indicate the flow and action of SLs.
  • 37.  Under optimal growth conditions, strigolactones repress lateral root formation(Kapulnik et al., 2011a; Ruyter-Spira et al., 2011) and promote root hair elongation(Kapulnik et al., 2011a).  In the case of lateral root formation, auxin is a key regulator and the distribution of auxin determines lateral root positioning, initiation, and elongation (reviewed by De Smet (2012).  Strigolactones may affect lateral root formation via changes in auxin efflux in the root.  Similarly, cytokinins can negatively affect lateral root formation, which is suggested to be due to interference with auxin transport in lateral root parts (Bishopp et al., 2011). Hence, in the case of lateral roots, strigolactones and cytokinins may be considered to act similarly, in the sense that both may influence auxin distribution.
  • 38. The Proposed Roles of Strigolactones in Adult Plant Growth and Development. (A) Under normal conditions, a basal level of strigolactone production in a wild-type plant reduces lateral shoots and roots, but enhances plant height, secondary growth, senescence, and root hairs. (B) Much of this influence of strigolactones can be seen in mutants that are unable to make or respond to strigolactones. They display more lateral branches and lateral roots, and less secondary growth and arbuscular mycorrhizal (AM) fungi symbiosis (in compatible species). (C) Reduced phosphate triggers increased strigolactone production. This leads to greater branch repression and, initially, to enhanced lateral roots and root hairs, and enhances AM fungi symbiosis. Other phenotypes like plant height, secondary growth, senescence, especially with regard to low-phosphate- induced strigolactone production.
  • 39. Additional Functions of Strigolactones Seto, et al., 2012
  • 40. SLs control a wide range of developmental features. In vascular plants, SLs positively regulate secondary growth (A), leaf senescence (B), root hair elongation (C) and primary root growth (D), while they negatively regulate axillary bud growth (E) and adventitious root formation (F). SLs negatively regulate chloronemata branching (G) and colony extension (H) in the moss Physcomitrella patens. Red arrows indicate positive effects. T-bars in blue depict negative effects.
  • 41. Effect of GR24, a synthetic analogue of strigolactones, on gene expression of solopathogenic strain of Sporisorium reilianum S. K. Sabbagh., (2011)
  • 42. • Sporisorium reilianum f.sp zeae a soilborne basidiomycetous fungus belonging to Ustilaginaceae, is the causal agent of maize head smut. • showed that strigolactones rapidly trigger O2 consumption of the fungi. • effects of GR24 on some genes involved in cell respiration and pathogenicity of U. maydis, a fungus phyllogeniticaly related to Sporisorium reilianum. • At 1 h post supplementation of GR24, all genes involved in cell respiration were induced. • Cell respiration increased a bit at 5 h, and was null at 8 h post supplementation of GR24. • No induction of genes involved in cell respiration was observed in those times, but an induction of actin and putative 12 kDa heat shock protein was observed. • The quantitative analysis of cells induced at 8 h post supplementation of GR24 did not show any increase in candidate genes transcripts.
  • 43.
  • 44. Strigolactones are positive regulators of light-harvesting genes in tomato Mayzlish-Gati, et al., 2010
  • 45. Illustration of the light reaction-associated biological pathways in which differentially regulated genes putatively participate.Differentially regulated genes were identified from hybridization data of roots exposed to GR24 and IAA treatments [IAA (10_8 M), IAA(10_8 M)+GR24 (13.5 lM), and GR24 (27 lM)] versus non-treated controls. Blue or red squares represent individual genes. The colourwithin the squares represents fold change in gene expression in treatments versus controls; values of fold change are as indicated in thecolour scale. Chl signifies chlorophyll.
  • 46. FUTURE ISSUES 1. SLs, which are exuded by plant roots, serve as branching factors for beneficial AM symbionts but at the same time also trigger the germination of root parasites. So far there is no knowledge on whether there is a possibility to manipulate SL biosynthesis, metabolism, and exudation in a way that will avoid or inhibit the germination of root parasitic weeds without effecting AM symbiosis. 2. The diverse functions of SLs, hint that this group of compounds may also have other functions in plant metabolism and development. Are SLs involved in the regulation of growth and development of other plant organs? Are SLs involved in the regulation of the reproductive organs? Are SLs involved in the regulation of leaf initiation and development?