Fungi Lecture Notes PDF

Summary

The document provides a general overview of the characteristics, types, and classification of fungi. It covers aspects of nutrition, reproduction, and economic importance, as well as offering an examination of the associated study of fungi, mycology.

Full Transcript

Myco = Fungus logy = Study
 1- General Characters
Eukaryotic Organisms
(i.e true nucleus surrounded by nuclear membrane)
Non-motile except few fungi
Vegetative body (somatic body ) may be:

Unicellular Filamentous
(yeast fungi)
Non-Septated Septated
Coenocytic
 Like plants, have alternation of generation
cell wall similar in structure of plant but
differ in chemical composition
Plant C.W. Cellulose + lignin
Fungi C.W. Chitin
Fungi are Heterotrophic organisms (lack chlorophyll)
Growth by apical elongation of hyphal tip
Food stored as glycogen but plant as starch
Cell membrane in animal cholesterol
in Fungi ergosterol
 Economic Importance
Beneficial Harmful
Industrial uses Cause human, animal, plant
baking & brewing (by Yeast) disease directly or their toxins
Antibiotics production ( penicillin) Cause rot of food
Production of Steroids and Hormones Can destroy manufactured
products.
making Cheeses
Source of organic compost
Source of food like mushrooms, enzymes,
acids and biofuels
Source of vitamins (yeast source for
vitamin. B-complex)
In nature
They participate in nutrient recycling.
Produce many enzymes to decay complex
animal and plant materials.
Make symbiotic association with plants
which improve their functions in absorbing
water and nutrients(Mycorrhizae)
 2- Nutrition in fungi

Saprophytes Parasites Symbiotic

Saprophytes : 1- use non - living organic
materials
2- important in recycling C,N
and essential mineral
nutrients
 Parasites : 1- use organic materials from
living organisms , causing
diseases to them
2- they have a wide range of
hosts as diatoms , fungi ,
plants ,animals , human.

Symbiotic : 1- fungi that have a beneficial
symbiotic relationship with
other living organisms
Ex :

Mycorrhizae Lichens Commensalism
 Reproduction
Types of reproduction
Sexual Asexual

a. Sexual:
- Involve the fusion (union) of two compatible nuclei with a
subsequent meiotic division
- All sexual fungal life cycles consists of :

plasmogamy karyogamy meiosis

Cell fusion Nuclear fusion 2N reduced to 1N
(fusion of two protoplasm of two gametes) (fusion of two nuclei of two gametes) (formation of haploid spores)
 - All sexual fungal life cycles consists of :

meiosis
plasmogamy karyogamy

Cell fusion Nuclear fusion 2N reduced to 1N

(fusion of two protoplasm of two gametes) (fusion of two nuclei of two gametes) (formation of haploid spores)
 Meiosis

1n Haploid number of chromosomes
2n Diploid number of chromosomes
Then Zygot develops into
Different types of sexual spores:

Ascospores (Ascomycetes)
Basidiospores(Basidiomycetes)
Zygospores (Zygomycetes)
Oospore (Oomycetes)
 b. Asexual:

1. Fragmentation (Filamentous fungi) :
The mycelium breaks up into fragments (arthrospores),
each fragment germinate into a new individual under
favorable conditions
 2. Fission: In unicellular true fungi (Yeast), the
vegetative cell splits into two equal daughter cells

3. Budding: In unicellular true fungi (Yeast)
The vegetative cell produces a small out growth (bud)
which is finally separated from the mother cell and
form a new cell
 4. Spore formation
According to manner by which spores are borne
on the mycelium, there are two types:

Sporangiospores Conidia
 Sporangiospores:
Asexual spores produced internally in a sac like
structure called sporangium, borne on specialized
hyphae called sporangiophore

Sporangiospores may be: motile or non motile
Motile Called zoospores
Non motile Called a planospores
Are disseminated by wind current
 Conidia: Asexual non motile spores produced
externally on a special hyphae called conidiophore
Conidia may formed singly or in chain
Conidiophores may be free from each other or
aggregated to form the following compound
structures

pycnidium

acervulus sporodocium
General Fungi Reproduction Cycles
(Alternation of generation)

Key
Heterokaryotic
Haploid (n)
stage
Heterokaryotic (n + n)
Fusion of nuclei
(unfused nuclei)
Diploid (2n)
Fusion of cytoplasm

Zygote
Spore-producing (2n)
structures Sexual
reproduction Meiosis
Spores
(n) Asexual Mycelium
reproduction
Spore-producing
structures

Germination
Germination
Spores (n)
 Fungi are classified as following:

kingdom: protozoa kingdom: Eumycota
(Slime moulds) (True Moulds)
The vegetative kingdom: chromista Produce non- motile
phase is
plasmodium Produce motile spores(aplanospores)
(ameoboid structure) spores(zoospores) Vegetative body is
Slimy, naked (no cell Vegetative body is mycelium
wall), multinucleate mycelium Classified according
mass of protoplasm, Oomycetes to the method of
move by (produce Oospore) sexual reproduction
pseudopodia. Zygomycetes
Ascomycetes
Basidiomycetes
Reproductive part: spores
 Fungal cell structure
Fungi are eukaryotes and have a complex
cellular organization. In eukaryotes, fungal
cells contain a membrane-bound nucleus
where the DNA is wrapping around histone
proteins.
 The fungal cell wall

Both the structure and composition of the fungal cell wall
have unique characteristics:
The polysaccharide β(1,4) N-acetyle-glucose-amin,
generally known as chitin, is a unique cell wall component
of the fungi, but the amount of chitin of cell walls of different
groups may differ strikingly:
 Baker’s yeast has only a small amount
(1% of cell wall dry weight) of chitin in its
cell wall.
In some groups (e.g. in some
zygomycetes) the chitin is partially
deacetylized by an enzyme (chitin
deacetylase) and so the cell wall will
contain chitosan (deacetylized chitin).
 The Oomycetes have also cell walls and
some species have a small amount of
chitin in their walls, but the vast majority
has no chitin at all. On the other hand,
their cell walls contain cellulose, a β(1,4)
glucan, which is never present in true
fungi.
 The fungal cell walls contain polysaccharides
mainly β (1,3) and β(1,6) glucans synthesized
by the transmembrane glucan synthase
enzymes.
Most proteins of the cell wall are present in
glycolized form (even 90% of the proteins could
be glycolized).

A majority of the glycoproteins are mannans or
mannoproteins, the proteins being connected by
mannose. Some proteins are anchored in the
cell membrane and play crucial roles in cell wall
integrity.
 The fungal cell membrane
special fungal sterols affect membrane fluidity of
the fungi. The most widely known are the
ergosterols.
❑Its function is to protect the integrity of the interior
of the cell by allowing certain substances into the
cell while keeping other substances out.
❑The special membrane components have great
importance in antifungal therapy; several
fungicides target those molecules or their
synthesis pathway. For example, the polyens
target the ergosterols and disintegrate the
membrane, whereas azols target the synthesis
pathway of ergosterols.
 Cytoplasmic Inclusions
1. Vacuoles:
Vacuoles are found in the old cells of hyphae.
The end of hyphal tip of young hyphae lacks vacuole.
With the age, the vacuoles coalesce.
Vacuoles are surrounded by a membrane known as
tonoplast.
Function of The vacuole:
1. degradative processes.
2. primary storage site for certain small molecules and
biosynthetic. precursors such as basic amino acids and
polyphosphate.
3. plays a role in osmoregulation.
 2: Endoplasmic Reticulum (ER):
An organelle that is responsible for the
accurate folding, post-translational
modification and final assembly of the
cellular protein.
In multinucleate hyphae the nuclei may be
connected by endoplasmic reticulum.
3:The nucleus
The cytoplasm contains one, two or more
globose or spherical nuclei of about 1-3 p.m
diameter (1x10-12) meter.
Nucleus consists of a bilayered porous
nuclear envelope that encloses the
chromosomes and nucleolus.
The chromosome consists of DNA and a
few basic proteins called histones.
The nuclear pores permit to interchange the
materials between the cytoplasm and
nucleus.
4: Mitochondria
❑ The function of the mitochondria in fungal cells is to
convert simple carbohydrates (glucose) to a complex
energy-storing molecule called adenosine triphisphate
(or ATP) through the process of cellular respiration.
❑ ATP is used not only in growth of individual cells, but also
in controlling cell division. They aid in protein regulation.

❑ Mitochondria produce ATP, ATP powers proteins, proteins
aid in growth, and growth helps the fungus survive.

❑ The inner infoldings form parallel flat plates of irregular
tubules called cristae
5: Golgi Apparatus or Dictyosomes:

Golgi apparatus consists of stacks of folded
membranes functioning in secretion.
Proteins synthesized in the ER are
packaged into vesicles, which then fuse
with the Golgi apparatus
Ecological Groups of
Fungi
 Fungi are heterotrophic organisms.
The modes of heterotrophic life in fungi are
categorized into:
1. Saprobic: living at the expense of dead organic
matter.
2. Parasitic: living at the expense of another host
organism (algae, plants, fungi, animals);
Biotrophic if the host is colonized while fully
alive.
Necrotrophic if the host is first killed and then
fully colonized.
3. Symbiotic: a mutual relationship that benefits
both the fungus and its partner(s).
1:Symbionts and Endophytes
Fungi living on the exterior of their hosts are called
epiphytes.
Those living within host tissue, which are termed
endophytes.
A: Endophytes: can protect host plants from
insect herbivory and from other fungal pathogens
used as bioregulators to induce resistance
against diseases.
biological control agents against certain
pathogens and undesirable weeds.
 Methods for isolation
1:Tissue pieces are sterilized using the following
protocol:
60 s in 70% ethanol
2-5 min in NaOCl (1-3 %; depending on tissue
type)
and again 60 s in 70% ethanol (to remove the
NaCOl).
2: Tissue samples are plated on PDA amended with
streptomycin (1 mL/L) and incubated at 25 ᵒC.
3: Emerging fungal colonies must be hyphal-tipped,
and transferred to PDA slants for further
identification.
B: Symbionts
Lichens

Lichen is a beneficial mutualistic association
between a fungus and an alga.

Mycobiont: the fungal partner in lichen.
Photobiont: the photosynthetic partner in a
lichen; either a green alga or
cyanobacterium.
Characters of Lichens
Worldwide distribution, often in the most extreme
environments, Arctic, Antarctic, deserts and all other
habitats.
Occur on soil, plants, animals, rocks, decorate tombstones,
buildings, etc. Rare in polluted areas - intolerant of industrial
pollutants, especially sulfur dioxide.
Mycobiont usually takes up about 90% of the thallus and is
usually an ascomycete (most are inoperculate
discomycetes) or occasionally a basidiomycete (eg.
Omphalina, Multiclavula).
Photobiont may be a green alga, cyanobacterium or both.
Both the algae and cyanobacteria fix carbon and the
cyanobacteria fix nitrogen.
Advantages to the alga:
Mechanical protection from injury & high
light by being tightly enveloped by hyphae.
Improved water relations and resistance to
desiccation.
Provides minerals.
Advantages to the fungus:
Organic nutrients (carbon & nitrogen) provided by
photobiont.
Lichenized fungi have greater longevity.
Most lichenized fungi are never found free-living in nature.
Structure of lichens

– Cortex (upper and/or lower).
– Medulla (fungal layer).
– Algal layer.
Types of lichens:

Stratified lichen: algal cells are not
distributed through lichen.
Non Stratified lichen: algal cells are
distributed through
Uses of Lichens
Food
Dyes
Essential oils for perfumes, soaps
Bioactive compounds (antiviral, antibacterial)
Nesting/bedding material
Poisons
 Reproduction of Lichens:
Sexual spores (ascospores & basidiospores).
Conidia
Ecological Groups of
Fungi
 Fungi are heterotrophic organisms.
The modes of heterotrophic life in fungi are
categorized into:
1. Saprobic: living at the expense of dead organic
matter.
2. Parasitic: living at the expense of another host
organism (algae, plants, fungi, animals);
Biotrophic if the host is colonized while fully
alive.
Necrotrophic if the host is first killed and then
fully colonized.
3. Symbiotic: a mutual relationship that benefits
both the fungus and its partner(s).
1:Symbionts and Endophytes
Fungi living on the exterior of their hosts are called
epiphytes.
Those living within host tissue, which are termed
endophytes.
A: Endophytes: can protect host plants from
insect herbivory and from other fungal pathogens
 used as bioregulators to induce resistance
against diseases.
 biological control agents against certain
pathogens and undesirable weeds.
 Methods for isolation
1:Tissue pieces are sterilized using the following
protocol:
60 s in 70% ethanol
2-5 min in NaOCl (1-3 %; depending on tissue
type)
and again 60 s in 70% ethanol (to remove the
NaCOl).
2: Tissue samples are plated on PDA amended with
streptomycin (1 mL/L) and incubated at 25 ᵒC.
3: Emerging fungal colonies must be hyphal-tipped,
and transferred to PDA slants for further
identification.
B: Symbionts
Lichens

Lichen is a beneficial mutualistic association
between a fungus and an alga.

Mycobiont: the fungal partner in lichen.
Photobiont: the photosynthetic partner in a
lichen; either a green alga or
cyanobacterium.
Characters of Lichens
Worldwide distribution, often in the most extreme
environments, Arctic, Antarctic, deserts and all other
habitats.
Occur on soil, plants, animals, rocks, decorate tombstones,
buildings, etc. Rare in polluted areas - intolerant of industrial
pollutants, especially sulfur dioxide.
Mycobiont usually takes up about 90% of the thallus and is
usually an ascomycete (most are inoperculate
discomycetes) or occasionally a basidiomycete (eg.
Omphalina, Multiclavula).
Photobiont may be a green alga, cyanobacterium or both.
Both the algae and cyanobacteria fix carbon and the
cyanobacteria fix nitrogen.
Advantages to the alga:
Mechanical protection from injury & high
light by being tightly enveloped by hyphae.
Improved water relations and resistance to
desiccation.
Provides minerals.
Advantages to the fungus:
Organic nutrients (carbon & nitrogen)
provided by photobiont.
Lichenized fungi have greater longevity.
Most lichenized fungi are never found free-
living in nature.
Structure of lichens

– Cortex (upper and/or lower).
– Medulla (fungal layer).
– Algal layer.
Types of lichens:

Stratified lichen: algal cells are not
distributed through lichen.
Non Stratified lichen: algal cells are
distributed through
Uses of Lichens
Food
Dyes
Essential oils for perfumes, soaps
Bioactive compounds (antiviral, antibacterial)
Nesting/bedding material
Poisons
 Reproduction of Lichens:
Sexual spores (ascospores &
basidiospores).
Conidia
Mycorrhizae
Definition Types Functions
 Symbiotic association between a fungus &
the root of vascular plants.

The roots of 95% of all kinds of vascular
plants are involved in mycorrhizae.

It's believed that the symbiotic association
of plant roots & fungi led to our modern
vascular plant.
 Types of mycorrhizae
1-Ectomycorrhizae
2-ectendomycorrhizae
3-endomycorrhizae
Arbuscular mycorrhizae(AM)

Ericoid endomycorrhizae

Orchid endomycorrhizae
 1-Ectomycorrhizae

form a sheath
(covering the root tip)

the fungus grows between the
plants cell producing the
harting net
(extensive network of
intercellular hyphae between
epidermal& cortical cells)

Septate fungi ( Ascomycetes )
 2-Ectendomycorrhizae

different from
Ectomycorrhizae in
that some hyphae
actually penetrate into
the root cells

Septate fungi
( Basidomycetes )
 3-Endomycorrhizae
A) Arbuscular mycorrhizae (AM)

the hyphae enter the plant cells,
producing vesicles(which are
swollen spherical or (oval) structures
or arbuscules (finely
dichotomously branching hyphae
invaginations) ; to increase surface
area between hyphae & cytoplasm
of the cell where nutrients
exchange (major site of nutrient
exchange between fungus and plant)

Non-septate fungi ( zygomycota )
 B)Ericoid endomycorrhizae

the fungus penetrate the
plant cells.
consisting of dense coils
of hyphae
in the root cells.
Septate fungi.
(Ascomycetes )

Ericoids : “are trees such
as tea & blue berry”.
 C) Orchid endomycorrhizae

Hyphae penetrate cells
of embryo & form coils
called pelctons.
Septate fungi
(Basidomycetes )
Orchid : “plants which
produce flowers like
orchids & vanilla
(flowering monocot
plants)”.
 Functions of mycorrhizae :-

Mycorrhizae can increase the
plant's competitiveness depending
on the environment of the plant improving plant
growth.

Wet environment :- they increase the availability of
nutrients , especially phosphate

Arid environment:-The mycorrhizae aid in water uptake,
allowing the increase in transpiration rate in comparison
with non-mycorrhizal plants
Mycorrhization Helper Bacteria
These are symbiotic bacteria trapped within
Mycorrhizal of fungi they can found in cytoplasm
of Ectomycorrhizae and also Arbuscular
mycorrhizea.

Bacteria play a role in the development of the
Mycorrhizal relationships.

The main function of bacterial symbionts in
ectomycorrizal fungus is that these trapped
bacteria contribute to the (N) metabolism by
assisting with the synthesis of essential amino
acid.
2: SOIL FUNGI
 Fungi are usually the most abundant component
of the soil microfloran in terms of biomass,
though their numbers in dilution plates are lower
than those of bacteria.

Fungi are the major microbial decomposers in
the soil, particularly in forest soils, mainly
participating in the decomposition of cellulose,
chitin and lignin in the upper soil layers.
 Occurrence of fungi in soil

Most of them are saprotrophs (soil-borne
fungi).
Many of which occur with increased densities
around roots (the rhizosphere).
 Some of them may be parasitic or semiparasitic
on plant roots (root-inhabiting fungi).
Some aquatic zoosporic fungi can also occur
in soils.
Fungi live most of the time in the soil in a dormant
condition.

Fungi are present in soil as :
mycelium.
(sexual or asexual) spores.
chlamydospores
sclerotial bodies
Isolation technique
A: Non selective technique

1: The dilution plate technique

The Dilution plate technique (Johnson &
Curl 1972) is the best known and most
frequently used quantitative procedure.
 Procedure
Soil diluted with sterile water 1:10 (w/v).
sometimes with 0.1% Na-pyrophosphate
or 0.15% water agar to obtain more stable
suspensions.
suspension is shaken by hand or
mechanically for 10-20 min.
the suspension is further diluted in steps of
10 times; 1 mL aliquots of the suspension
10*-4 to 10*-6
 Petri dishes and mixed with 10 mL
undercooled agar (ca. 45C) with the
addition of antibiotics against bacteria

0.1 mL can be pipetted into agar plates
and distributed evenly with a glass rod.

After incubation, plates of the
concentration showing 10-30 colonies are
selected and used for isolation.
2: Warcup's soil plates:
Larger soil particles have a tendency to
sediment quickly in the soil suspension and
to be lost during the dilution procedure;
therefore species with large hyphal
complexes have little chance of being
isolated with the dilution plate technique
procedure:
1. 1 mL of an antibiotic solution (10 times
the final concentration) is pipetted into
sterile Petri dishes.
2. a very small amount of a soil sample
(less than 1 mg) is dispersed in this
liquid.
3. undercooled malt agar (1%) is poured
into the dish and mixed thoroughly with
the antibiotic-soil suspension.
3.Soil washing technique:

The first two techniques mainly facilitate
the isolation of species present as spores.
In order to shift the balance in favour of
mycelial propagules in the soil, washing
techniques have been devised, by which
most of the spores are removed.
 B: Selective techniques
1. hair bait technique: For the selective
isolation of dermatophytes and other
kerationophilic fungi.
 Sterile hairs of horse, sheep or man (children)
are incubated in Petri dishes above moist soil.
 Colonizing fungi are transferred onto
Sabouraud-glucose agar or 4% malt agar
containing 500 ppm actidione and 50 ppm
chloramphenicol.
2: Cellulolytic fungi:

 thay are easily baited with pieces or strips
of cellophane.
 which are buried in the soil for several
days, then washed and plated on agar.
 3: Water Molds
A number of zoosporic fungi live
permanently in water or need water in some
stages of their life cycle.
They generally have motile plano- (zoo-)
spores and sometimes motile (plano-)
gametes.
Aquatic hyphomycetes can also be found
on terrestrial substrata and is not exclusively
aquatic.
Aquatic hyphomycetes often called
"Ingoldian fungi”. because Ingold
(Ingold 1942, 1975) was one of the first
to study them extensively.
 Isolation of aquatic fungi
Zoospores are caught on baiting
substrata placed in a thin layer of water
in Petri dish.
The most widely used substratum for this
purpose is hemp-seed.
numerous other baits are in use, some of
them are specialized substrates for certain
groups of fungi
Before use baits are usually boiled for 10
min in water.
Baits Range of fungi

Hemp-seed (Cannabis sativa) Very broad

Seeds of corn (Zea mays) or Argostis alba Various groups

Grass blades (Argostis, Paspalum a.o.) Pythium

Pollen grains (Pinus) Chytridiales (Rhizophydium)

Cellophane Cellulose-decomposing Chytrids (Rhizophlyctis)

Dead insects (flies, ant, pupae), shrimp skeleton Various groups, mainly Saprolegniales
 4:Fungi on seeds
Several methods are in use to discover and
isolate pathogenic and saprophytic fungi
from seeds:
the fungal flora of seeds can be obtained by
placing them in Petri dishes on water agar
or sterile, moistened filter paper.
Superficial fungi develop within a couple of
days and are isolated.
internal colonizers develop after superficial
disinfection.
 5.Fungi on dung (coprophilous
fungi)
The dung is placed on moist filter paper in
Petri dishes.
When the material cannot be studied
immediately, the specimen must be kept dry;
in this condition most coprophilous fungi stay
alive for a long time without further
development.
 Pilobolus sp
Coprophilous (dung-inhabiting)
 6:Fungicolous Fungi
Fungicolous fungi comprise a broad
range of association between two fungi
found living together.
one fungus growing on another as a
parasite, commensal, or saprobe.
The parasitism may be "necrotrophic"
(destructive) or "biotrophic" (forming
balanced relationships)
 7:Entomogenous Fungi

Many fungi parasitizing arthropods can
be cultivated on artificial media.
Mycelium, conidia or hyphal bodies are
transferred to agar media (2% malt
extract, PDA or Sabouraud agar) with
antibiotics
 8: Thermophilic and Thermotolerant
fungi
Thermophilic fungi have a growth optimum
between 40 and 50°C and do not grow at
or below 20°C.
Thermotolerant fungi have a maximum at
or below 50 °C and grow well at and below
20 C.
Thermophilic fungi are common in compost,
manure, hay and other self-heating
substrata, and also in superficial soil layers,
 isolation of thermophilic and
thermotolerant soil fungi:
the dilution plate technique or Warcup's soil
plates are used with malt agar and
antibacterial antibiotics;
for thermophilic fungi, plates are incubated
at 45 or 50 C,
for thermotolerant fungi at 35 or 40 C.
 9: Oligotrophic fungi
Oligotrophs are microorganisms that can
grow in environments where concentrations of
nutrients are low or even absent.
These occur e.g. in clean (drinking) water, on
inert surfaces such as glass or rock.
Frequently they actually occur in microniches
within more permissive environments, and
assimilate compounds that the more rapidly
growing saprobes are unable to use
 For example, dermatophytes are unique in
assimilating keratin, while black yeasts are
able to degrade monoaromatic xenobiotics.
They are isolated by enrichment by selective
isolation techniques.
Selective isolation experiments have to be
carried out over weeks or months, as
oligotrophic fungi grow very slowly, with
very small biomass.
 Fungi are classified as following:

kingdom: protozoa
kingdom: Eumycota
(Slime moulds) (True Moulds)
kingdom: chromista
The vegetative phase is Produce non- motile
plasmodium (ameoboid Produce motile spores(aplanospores)
structure) Slimy, naked (no spores(zoospores) Vegetative body is
cell wall), multinucleate Vegetative body is mycelium
mass of protoplasm, move mycelium Classified according to
by pseudopodia. the method of sexual
reproduction

Reproductive part:
spores
 Kingdom: protozoa
Phylum Myxostelida
e.g. Stemonitis
Phylum Dictyostelida
Phylum Labyrinthulida
Phylum Plasmodiophorida
e.g. Plasmodiophora
 e.g. Stemonitis fusca
Members of Myxomycota are commonly referred to
as (slime molds).

General Characters :
1. Occurrence: They are found on moist soil, decaying wood , decaying
plants leaves, plant debris and animal dung.
2. Not true fungi (lack a cell wall and mycelium).
3. They posses characters of both fungi and animals.
*Like fungi (reproduce by spores with a definite cell wall).
*Like animals (vegetative structure plasmodium : slimy , naked ,
multinucleat mass of protoplasm).
 The life cycle :
1. Once a spore is released from the fruiting body it's
dispersed, either by insects, animals, and rain or air
movement. On landing on a suitable location with
appropriate moisture and temperature, one to four
protoplasts are germinated.

2. The protoplasts once released from the spore's wall
through either a pore or fissure will be either a
flagellated swarm cell if conditions are wet, or a non-
flagellated myxamoebae cell in dryer conditions.

3. If conditions for growth are not suitable, the cells can
become microcysts to survive long periods of time.
4. - A diploid zygote is formed when two compatible myxamoebae or
swarm cells fuse. This is known as plasmogamy and karyogamy.

5. After a time of feeding and growing, the zygote develops into a single
celled multinucleate structure known as a plasmodium.

6. When the conditions are right, the mature plasmodium produces one
to many fruiting bodies containing spores depending on species.
Phylum 2: plasmodiophorida
e.g. Plasmodiophora brassicae
Cause (club root of cabbage/ crucifer) : it causes the roots to
produce abnormal swellings and malformations through.
1.Hypertrophy : enlargement of cell size.
2.Hyperplasia : uncontrolled cell divisions (increase in cell divisions).
3.The infect cells are filled with the resting spores of the fungus.
The life cycle :
 Important terms
Anamorph: asexual state of fungus
Teleomorph: sexual state of fungus
Homothallic: two cells or spores or organs responsible for
sexual reproduction are similar (physiology, structure or
mating type)
Heterothallic: two cells or spores or organs responsible
for sexual reproduction are distinct or different (physiology,
structure or mating type).
 Kingdom : Chromista
Phylum : Oomycota
General characteristics:

 Occurrence: Many live in water or soil amd some are
important plant pathogens.
 Vegetative form: have diploid coenocytic hyphae (most
other fungi have haploid hyphae).
 cell walls made of cellulose, (other fungi have chitin).
 Asexual reproduction: by flagellated zoospores.

 Sexual reproduction :Oogamous reproduction between
antheridia and oogonia to produce zygot which develops
into thick walled Oospore.
 Oogamous sexual reproduction

antheridium oogonium Oogonium antheridium

Homothallic Heterothallic
 Phylum : Oomycota
Class: Oomycetes
Order

Peronosporales Pythiales
Families Families

Peronosporaceae Albuginaceae Pythiogetonaceae Pythiaceae
 Family Peronosporaceae

Occurrence: Obligate biotrophs of vascular plants
causing downy mildews disease
vegetative part: “Coenocytic mycelium
Asexual reproduction by motile zoospores inside
sporangia
Sexual by homothallic oogamous
Examples: Peronospora, Bremai and Plasmopara
 Family Albuginaceae
Occurrence: Obligate biotrophs of vascular plants
causing white rust disease
vegetative part: “Coenocytic mycelium
Asexual reproduction by motile zoospores inside
sporangia, Sporangia formed in basipetal succession,
dispersed by wind
Sexual by heterothallic oogamous
Examples: Albugo portulacae
Kingdom : Eumycota
 General characteristics
Occurrence: Terrestrial live as saprophytic on dead
organic matter and some are coprophilous (occur on
dung) and some are parasitic
Vegetative part: Cell walls made of chitin(uninucleate,
dikaryotic, or coenocytic).
Asexual reproduction (anamorph): non- motile spores
Sexual reproduction (teleomorph): by specialized
spores
 Phylum1: Zygomycota
1. Hyphae are coenocytic
2. Flagellated spores are absent
3. Most reproduce asexually by producing sporangiospores within
a special sac called the sporangium (the anamorphic phase).
4. Sexual spores are called zygospores contained within a
zygosporangium (the teleomorphic phase) formed following
gametangial fusion / copulation.
 Sexual Reproduction
Gametangial congucation
May be Homothallic or Heterothallic
Heterothallism: two gametes arise from two mycelium
genetically different and so requiring a partner for
sexual reproduction
Homothallism : two gametes arise from two mycelium
genetically similar and so able to reproduce sexually
without a partner

Zygosporangium

gametangium
 Sexual Reproduction

+ -
Mycelium
Progametangia

Suspensors

karyogamy
Zygosporangium
Gametangia Zygote Zygospore
 Class: zygomycete.

order
Family mucorales Family

Mortierellaceae Mucoraceae

Family Family

Chaenophoraceae Thamnidiaceae

Family Family
Cephalidaceae Pilobolaceae
 General characters:
Well developed, typically coenocytic mycelium
Wall composition of chitin
Asexual reproduction by formation of sporangiospores cleaved out from
the cytoplasm of sporangia (ananmorphic phase)
Chlamydospores (thick walled rounded spores) may be formed.
Called mucoralean or mucoraceous fungi.
Grow and invade quickly on easily digestible substrates, such as those
containing starches, sugars, and hemicelluloses.
Can act as parasites and/or cause diseases in plants, animals and some
insects and humans.
Sexual reproduction (teleomorphic phase) spores by gametangial
fusion / copulation.
 Classification of Mucorales
Based on morphology of sporangia :
1: Collumelate sporangia: Sporangia with columella
(Family: Mucoraceae)
2: Sporangioles with one or few number of spores.
(Family: Cuuninghamellaceae)
3. Merosporangium (sac containing 10 -15 sporangiospores) that occur in
a linear sequence. Merosporangia borne on swollen tips of
sporangiophores.
(Family: Piptocephalidaceae)
4. Single sporangium Sporangial wall densely cutinized above, entire
sporangium violently discharged or detached as a whole from
sporangiophore. (Family: Pilobolaceae)
 Family1: Mucoraceaea
Example 1:Rhizopus sp.
Saprophytic on dead organic matter,
Vegetative thallus is a branching, coenocytic
mycelium (N), rhizoids: root-like hyphae that adhere
reproductive structures to substrate and stolon to
connect two groups of rhizoids.
Asexual reproduction takes place by the formation of
sporangiophores with terminal columellate sporangia
Sexual Reproduction by gametangial conjugation.
 Zygomycota - Rhizopus– common
molds

The fungal mass of
hyphae, known as the
MYCELIUM
penetrates the bread
and produces the
fruiting bodies on top
of the stalks

Mycelia = a mass of hyphae or Stolon
filaments
Rhizoids = root-like hyphae
The zhizoids meet underground and mating occurs between
hyphae of different molds (SEXUAL REPRODUCTION)
Life cycle of Rhizopus sp. (Alternation of generation)
 Example 2:Mucor sp.
The common pin mold of bread, leather.
Family2: Cunninghamellaceaea
Eample: Cunninghamella sp.
Family3: Piptocephaliodaceaea
Eample: Syncephalastrum sp.
 Family4: Pilobolaceaea
Eample: Pilobolus sp. Coprophilous (dung-
inhabiting)
spore dispersal mechanism
 Spore dispersal mechanism:
1:Beneath the black apical mitosporangium is a lens-
like subsporangial vesicle, with a light-sensitive
`retina' at its base that controls the growth of the
sporangiophore very precisely, aiming it accurately
toward any light source. In a word, it is phototropic.
2: Osmotically active compounds (carotene) cause
pressure in the sporangiophore and the subsporangial
vesicle to build up until it is more than 100 pounds per
square inch (7 kilograms per square centimetre). This
eventually causes the vesicle to explode, hurling the
black sporangium away to a distance of up to 2
metres, directly toward the light.
3: The mucilaginous contents of the subsporangial
vesicle go with the sporangium, and glue it to
whatever it lands on.