Structure and reproduction of Aspergillus niger ,with picture of different reproduction methods in detail ,also called sac fungi,large groupof true fungi ,saprophyte,it also known to cause food contaminations or food spoilage ,also cause black mold in fruits and vegetables like grapes, apricote ,onions and peanuts .Aspergillus niger is common group of Aspergillus.reproduction by sexual ,asexual or vegetative methods. vegetative mthods by fragmentation ,sclerotia
Chlamydomonas is unicellular, motile green algae. In this presentation the systematic position, occurrence, structure and different types of reproduction is being explained. palmella stage in vegetative reproduction is one of the outstanding character found among the other algae.
Rhizopus is a genus of common saprophytic fungi on plants and specialized parasites on animals. They are found in a wide variety of organic substances , including "mature fruits and vegetables", jellies, syrups, leather, bread, peanuts, and tobacco.
A chemical substance that is produced in one portion of an organism and moves by diffusion or transport to another portion of same individual or to other individual of same species where it induce specific response is called a hormone.
Chlamydomonas is unicellular, motile green algae. In this presentation the systematic position, occurrence, structure and different types of reproduction is being explained. palmella stage in vegetative reproduction is one of the outstanding character found among the other algae.
Rhizopus is a genus of common saprophytic fungi on plants and specialized parasites on animals. They are found in a wide variety of organic substances , including "mature fruits and vegetables", jellies, syrups, leather, bread, peanuts, and tobacco.
A chemical substance that is produced in one portion of an organism and moves by diffusion or transport to another portion of same individual or to other individual of same species where it induce specific response is called a hormone.
Fungi are a kingdom of usually multicellular eukaryotic organisms that are heterotrophs (cannot make their own food) and have important roles in nutrient cycling in an ecosystem. Fungi reproduce both sexually and asexually, and they also have symbiotic associations with plants and bacteria.
The algae reproduce by vegetative, asexual, and sexual methods. Vegetative reproduction is by fragmentation, where each fragment develops into a thallus. Asexual reproduction is by the production of flagellated zoospores which on germination give rise to new plants.
1.INTRODUCTION
2.HISTORY
3.MORPHOLOGY
4.STRUCTURE
5.CLASSIFICATION
6.CHARACTERSTICS
7.DISEASES
8.CONCLUSION
REFRENCES
Mycoplasmas are prokaryotic , without cell wall & have been placed under the class Mollicutes & the order Mycoplasmatales.
Mycoplasma are the smallest microorganism which have been known to cause a number of disease in animals &human kind.
The cells are bounded by a soft trilamellar lipoproteinaceous unit membrane containing sterols. Because of their plasticity , they can pass through bacterial filters & have often been mistaken for viruses.
Introduction,In some fungi ,true sexual cycle comprising of nuclear fusion and meiosis is absent.
These fungi derive the benefits of sexuality through a cycle know as parasexuaL cycle.
First Reported by- Gudio Pontecorvo and J.A.Roper(1952)
Parasexual cycle was reported in
Aspergillus nidulans,the imperfect stage of Emericella nidulans.
Since then parasexual cycle has been discovered not only in several members of Deutromycetes but also in fungi belonging to Ascomycetes and Basidiomycetes.
DEFINETION - Parasexuality is defined as a cycle in which Plasmogamy, Karyogamy and Meiosis [Haploidization] take place in sequence but not at a specified time or at specified points in the life cycle of an organism.
Generally parasexual cycle occurs in those fungi in which true sexual cycle does not take place.
Parasexualcycle also know as Somatic recombination. PASEXUALITY ALSO REPORTED IN SOME ORGANISMS- Aspergillus nigar, Penicillium crysogenum, STEPS OF PARASEXUAL CYCLE - 1) ESTABLISHMENT OF HETEROKARYOSIS, 2) Formation of Heterozygous DIPLOIDS, 3) occasional mitotic crossing-over during multiplication of diploid nuclei, 4)occasional haplodization through aneuploidy , COMPARISION BETWEEN SEXUAL AND PARASEXUAL CYCLE, IMPORTANCE OF PARASEXUALITY, C0NCLUSION
Penicillium is called blue or green mold. It is commonly seen rotting fruits and vegetables . It belongs to phylum Ascomycota . Here the classification structure and reproduction of fungi is discussed.
Fungi are a kingdom of usually multicellular eukaryotic organisms that are heterotrophs (cannot make their own food) and have important roles in nutrient cycling in an ecosystem. Fungi reproduce both sexually and asexually, and they also have symbiotic associations with plants and bacteria.
The algae reproduce by vegetative, asexual, and sexual methods. Vegetative reproduction is by fragmentation, where each fragment develops into a thallus. Asexual reproduction is by the production of flagellated zoospores which on germination give rise to new plants.
1.INTRODUCTION
2.HISTORY
3.MORPHOLOGY
4.STRUCTURE
5.CLASSIFICATION
6.CHARACTERSTICS
7.DISEASES
8.CONCLUSION
REFRENCES
Mycoplasmas are prokaryotic , without cell wall & have been placed under the class Mollicutes & the order Mycoplasmatales.
Mycoplasma are the smallest microorganism which have been known to cause a number of disease in animals &human kind.
The cells are bounded by a soft trilamellar lipoproteinaceous unit membrane containing sterols. Because of their plasticity , they can pass through bacterial filters & have often been mistaken for viruses.
Introduction,In some fungi ,true sexual cycle comprising of nuclear fusion and meiosis is absent.
These fungi derive the benefits of sexuality through a cycle know as parasexuaL cycle.
First Reported by- Gudio Pontecorvo and J.A.Roper(1952)
Parasexual cycle was reported in
Aspergillus nidulans,the imperfect stage of Emericella nidulans.
Since then parasexual cycle has been discovered not only in several members of Deutromycetes but also in fungi belonging to Ascomycetes and Basidiomycetes.
DEFINETION - Parasexuality is defined as a cycle in which Plasmogamy, Karyogamy and Meiosis [Haploidization] take place in sequence but not at a specified time or at specified points in the life cycle of an organism.
Generally parasexual cycle occurs in those fungi in which true sexual cycle does not take place.
Parasexualcycle also know as Somatic recombination. PASEXUALITY ALSO REPORTED IN SOME ORGANISMS- Aspergillus nigar, Penicillium crysogenum, STEPS OF PARASEXUAL CYCLE - 1) ESTABLISHMENT OF HETEROKARYOSIS, 2) Formation of Heterozygous DIPLOIDS, 3) occasional mitotic crossing-over during multiplication of diploid nuclei, 4)occasional haplodization through aneuploidy , COMPARISION BETWEEN SEXUAL AND PARASEXUAL CYCLE, IMPORTANCE OF PARASEXUALITY, C0NCLUSION
Penicillium is called blue or green mold. It is commonly seen rotting fruits and vegetables . It belongs to phylum Ascomycota . Here the classification structure and reproduction of fungi is discussed.
Aspergillus is commonly found in soil, with a saprophytic mode of nutrition, obtaining its nutrients from dead and decaying matter.The saprophytic nature of Aspergillus spp means they fully depend on environmental materials, which allows them to produce enzymes such as amylase that breaks down compounds into simple products that can be absorbed by the vegetative hyphae. food materials for utilization during reproduction and growth.
This pdf is about the Schizophrenia.
For more details visit on YouTube; @SELF-EXPLANATORY;
https://www.youtube.com/channel/UCAiarMZDNhe1A3Rnpr_WkzA/videos
Thanks...!
Professional air quality monitoring systems provide immediate, on-site data for analysis, compliance, and decision-making.
Monitor common gases, weather parameters, particulates.
Observation of Io’s Resurfacing via Plume Deposition Using Ground-based Adapt...Sérgio Sacani
Since volcanic activity was first discovered on Io from Voyager images in 1979, changes
on Io’s surface have been monitored from both spacecraft and ground-based telescopes.
Here, we present the highest spatial resolution images of Io ever obtained from a groundbased telescope. These images, acquired by the SHARK-VIS instrument on the Large
Binocular Telescope, show evidence of a major resurfacing event on Io’s trailing hemisphere. When compared to the most recent spacecraft images, the SHARK-VIS images
show that a plume deposit from a powerful eruption at Pillan Patera has covered part
of the long-lived Pele plume deposit. Although this type of resurfacing event may be common on Io, few have been detected due to the rarity of spacecraft visits and the previously low spatial resolution available from Earth-based telescopes. The SHARK-VIS instrument ushers in a new era of high resolution imaging of Io’s surface using adaptive
optics at visible wavelengths.
Multi-source connectivity as the driver of solar wind variability in the heli...Sérgio Sacani
The ambient solar wind that flls the heliosphere originates from multiple
sources in the solar corona and is highly structured. It is often described
as high-speed, relatively homogeneous, plasma streams from coronal
holes and slow-speed, highly variable, streams whose source regions are
under debate. A key goal of ESA/NASA’s Solar Orbiter mission is to identify
solar wind sources and understand what drives the complexity seen in the
heliosphere. By combining magnetic feld modelling and spectroscopic
techniques with high-resolution observations and measurements, we show
that the solar wind variability detected in situ by Solar Orbiter in March
2022 is driven by spatio-temporal changes in the magnetic connectivity to
multiple sources in the solar atmosphere. The magnetic feld footpoints
connected to the spacecraft moved from the boundaries of a coronal hole
to one active region (12961) and then across to another region (12957). This
is refected in the in situ measurements, which show the transition from fast
to highly Alfvénic then to slow solar wind that is disrupted by the arrival of
a coronal mass ejection. Our results describe solar wind variability at 0.5 au
but are applicable to near-Earth observatories.
1. Aspergillus niger is the most common species of
aspergillus.It is known commonly to cause black
mold in fruits and vegetables like grapes, apricot,
onions, and peanuts.
It is also known to cause food contaminations or
food spoilages.
Large group of true fungi
Members are called’sac fungi’
Exist as saprophyte
Aspergillus niger is highly thermotolerant therefore
they can thrive in extreme temperatures including
extremely low and extremely high conditions.
Aspergillus gets its name from its shape. There is a
vesicle in the shape of a circle, with filamentous
extensions growing out from it. This resembles the
shape of an aspergillum, a device used for
sprinkling holy water.
2. MORPHOLOGY OF Aspergillus niger
Aspergillus niger is a haploid filamentous fungi
Plant body is mycelia
Slender, tubular, pale yellow coloured, branched, thin wall
hyphae .
Each cell is multinucleate and is filled with granular
cytoplasm, mitochondria, endoplasmic reticulum,
ribosomes and vacuoles. The cross walls between the
cells have a simple pore through which the cytoplasm
of the adjacent cells remain continuous.
Oil globules are reserve food material
A niger produce colonies that are composed of white
or yellow felt that is covered by dark asexually
produced fungal spores. Mycelial, or threadlike,
hyphae are divided by a septum and transparent.
Conidiophores. Conidiophores are smooth and haline
3. each conidia is spherical, echinulate and
multinucleate
conidial heads are present
Compared to the other types, A. niger produces dark
or dark brown spores from their conidial heads
(biserite). This is a characteristic that has only been
seen on A. niger and none of the others.
The conidial head to be globose
the carbon black/dark brown color of the spores (as
well as the conidia) is used to distinguish A. niger
from other species in the same genus.
Each globose vesicle is completely covered with
biseriate phialides which are projections from the
conidiophore of A. niger. These phialides come out
from brown metulae, which is the site where a
conidiogenous cell is created. The phialides go
through a process of blastic basipetal conidiogenesis
to create globose mitospores.
Reproducesby vegetative, asexual and sexual methods:-
(i) Vegetative Reproduction:
It takes place by the following methods:
4. (a) Fragmentation:
The vegetative mycelium breaks up into small pieces
(fragments) and each fragment grows independently into a
new thallus under favourable conditions.
(b) Sclerotia:
Some species e.g., A niger, A. terreus produce sclerotia. It
is more a means of keeping the fungus alive than of
propagation.
Sclerotia are described as resting structures that remain
quiescent in the presence of adverse environmental
conditions and are able to germinate when the conditions
improve
ii) Asexual Reproduction:
Asexual reproduction takes place by the hyphae called
conidiophores. and are known as foot cells . Each foot cell
produces a special erect branch as an outgrowth. It is the
young conidiophore.
The tip of the conidiophore swells up into on elliptical or
globular multinucleate head called vesicle. It forms many
radially arranged tubular outgrowths called sterigmata or
phialides . In some species primary sterigmata (uniseriate)
bear secondary sterigmata. (bi-seriate)
5. Conidia, arise exogenously from the sterigmata or
phialides (therefore, conidia are also called phialospores or
phialoconidia) by abstraction method. They are arranged
in basipetal succession (i.e., the youngest conidium is at its
base and the oldest at the tip)
6. The sterigmata elongate at the tip to form a tube. The
conidia are formed inside this. The sterigmata are
uninucleate. At the time of formation of conidia the single
nucleus of the phialide divide mitotically into two daughter
nuclei. One of the daughter nuclei passes into the tube . It
is the first conidium. As the first conidium is formed the
upper broken wall of the phialide serves as a cap around
7. it . The second conidium is formed by phialide just below
the first . The cytoplasm of both the conidia is confluent
through a narrow cellular link called isthmus . The
continuity of the cytoplasm is stopped by the formation of
the inner conidial wall. The isthmus becomes empty and
now it is called connective.
8. Structure and Germination of Conidia
conidia are small, globose, unicellular, uninucleate or
multinucleate, black, brown or yellow green in colour.
They have two layered wall. Outer wall layer is thick spiny,
pigmented and known as epispore, whereas the inner one
is thin, delicate and is called endospore. Conidia are
dispersed by wind. They germinate on suitable substratum
by giving out a germ tube. The germ tube becomes septate,
branched and forms a mycelium.
iii) Sexual Reproduction:
The sexual reproduction is of rare occurrence.Majority of
the species of Aspergillus are homothallic. However,a few
species are heterothallic e.g., A. heterothallicus.
It takes place by the formation of male and female sex
organs. Male sex organ is known as antheridium and
the male branch is called Pollinodium. Female sex
organ is called ascogonium and female branch is
called as archicarp.
9. Ascogonium:Archicarp develops on the mycelium in the
form of septate, loosely coiled structure.
The young archicarp can be differentiated into
three parts :
(i) The basal multicellular, multinucleate stalk.
(ii) Middle unicellular, multinucleate ascogonium
(gametangium).
(iii) Apical unicellular, multinucleate receptive organ
called trichogyne.
At first archicarp is loosely coiled but later on the coil
approaches nearer and nearer and finally touch each other
to form a cork screw like structure .
Antheridium:
Pollinodium grows up beside the archicarp on the same or
adjacent hyphae . It gets spirally coiled around the
archicarp and arches over the apex of ascogonium.
It can be differentiated into two parts:
(i) Upper part, slightly broader, unicellular, multinucleate
and behaves as antheridium.
(ii) Lower unicellular and multinucleate part called stalk.
Fertilization:
The tip of the archegonium arches over the trichogyne and
fuses with it. The wall at the point of contact dissolves,
thus making a continuous passage. It is plasmogamy. The
contents of the antheridium pass into the ascogonium. The
10. pairing of male and female nuclei takes place in
ascogonium .
Development of Ascocarp:
the ascogonium develops into a fruiting body called
ascocarp . After the pairing of the nuclei, the ascogonium
becomes septate. Each segment consists of one male and
one female nucleus (dikaryon). From these dikaryotic
segments arise ascogenous hyphae. Each ascogenous
hypha is multicellular with a pair of nuclei and produces
asci by crozier formation.
Crozier Formation:
The terminal bi-nucleate cell of the ascogenous hyphae
elongate and then been itself to form a hook like structure
known as crozier . Both nuclei divide in such a way thin
spindle apparatus are oriented parallely in vertical
direction.
Now the separation takes place in crozier and it is
differentiated into three cells
11. (i) The terminal or ultimate uninucleate cell.
(ii) Sub-terminal or penultimate bi-nucleate (‘+’ and
nuclei) cell, occurs at the curve position.
(iii) A basal uninucleate, anti-penultimate cell.
The penultimate bi-nucleate cell acts as ascus mother cell.
The nuclei in these cells fuse to form diploid nucleus
(karyogamy). The diploid nucleus first divides meiotically
and forms four haploid nuclei. Each haploid nucleus
divides meitotically and thus 8 haploid nuclei are formed
12. Each nucleus later on gets surrounded by cytoplasm and
develops a wall. Thus, 8 haploid ascospores are formed in
each ascus. The cytoplasm left over in each ascus is known
as epiplasm. The asci may be globose or pear shaped.
As the asci develop, a large number of sterile hyphae grow
around them and form a protective covering called
peridium. The entire structure is known as ascocarp. It
encloses many asci. It is spherical and has no opening.
Such an ascocarp is known as cleistothecium .
13. Structure of Ascospore:
As the asci mature, the ascospores are set free by
dissolution of the wall of the asci in the ascocarp. They are
liberated only after the decay of the ascocarp wall. Each
ascospore is pulley wheel shaped, unicellular, uninucleate .
Spore wall is differentiated into two layers,
the outer thick, sculpturous epispore and inner
thin endospore .
After falling on a suitable substratum each ascospore
germinates to give rise to a germ tube which develops
into a new haploid mycelium .