Salient Features of Fungi PDF

Summary

This document provides a general overview of the characteristics of fungi. It discusses the definition of fungi, highlighting the absence of chlorophyll, and their varied habitats, including wet soil, aquatic environments, and as parasites on plants and animals. The document also touches on the mode of nutrition and different types of reproduction in fungi.

Full Transcript

25
INTRODUCTION
DEFINTION:
(General characters of fungi)
The branch of science that deals with the study of fungi is called
Mycology (Greek words mykos =mushroom; logos =iscourse). The fungi
(singular-fungus) include all those plants whose form is a thallus (i.e., not
differcntiated into true roots, stem and lcaves) that lack chlorophyll (the
pigment responsible for synthesis of carbohydrates from carbon dioxide and
water, i.e., photosynthesis). Absence of chlorophyll is the one character on
the basis of which the fungi can be distinguished from rest of the plant
kingdom. However, all those plants which do not possess chlorophyl (e.g, a
red algae-Harveyella mirabilis, many colourless bacteria and many
parasites flowering plants, suchas Orobanche, CuSCuta, Rafflesia, etc.) can
not be called fung. Thusa correct definition of fungi that excludes allother
organisms may be given as, "a group of those plants whoseform is a thallus,
build up of single cellor cells that possess definite cell wall and nucleus but
lack chlorophyll and differentiation of vascular tissues". This definition
does not include bacteria(due to lack of nucleus)and slime moulds (due to
lack of cel wall). However, some mycologists ínclude slime moulds as a
separate group- Myxomycetes along with fungi.
HABITAT (Occurrence) :
Fungiis a large group includes more than 1,00,000 species distributed
throughout the world. They are ubiquitous and occur in almost every habitat
where organic material is available. Since they lack chlorophyll and cannot
perform photosynthesis, they do not require light for active growth and
metabolism. They can occur in light as well as in dark, but the presence of
external source of organic food is required for normal growth. Fungi flourish
well in moist, dark and warm conditions but their presence at or below
Ireczing tlemperature as well as in hot deserts has also been reported. In fact
afew spores and conidia can survive even in comnpletely dehydrated condi
tions.
The most usual habitat of fungi is wet soil rich in humus. The forms
TOWing in such habitats are considered advanced (examples, Agaricus,
Morchella, Peziza, etc.). A few forms are aquatic (example, Saprolegnia).
These are considered primitive. Some are subterranean. Most of thefungi
grow and contaminate the foodstuffs such as bread, jams,pickles, fruitsand
Vegetables. Some contaminate the drinking water.
ng grow as parasites on plants as well as on animals and cause
serious diseases in man such as candidosis
diseases. Some fungi also cause
caused by Candida
nchophyton, albicans),etc.),
Epidemophton. dermatomycosis
aspergillosis(caused by Microsporm,
(caused by Aspergilhus
sp.),etc.
 154
olism.
norcanic
NUTRITION:ycohia
terotrophic func
(Greekalgal hostinfestans,under and roffsi). dead
isgrow Phytophihora Erysiphe,
in divided to TheThus,
way parasites
complete cxisting itcatingbecomedead truedead organic organisms.
rotten.mycorrhiza.
into ofHABIT
derives
Fungi Iivespartncrs Some orThe pass (b)
advance
as
living (a)
parasites 2.
saprophytes.
and (b)
decaying ) 1.two nutrition. The
in certain (e.g.,
biotrophs obligateObllgte these Parasites beside Saprophytes Itbroad
eadoparasites
symbiotic parasites Facultative bost an in Facultative Obligate
parasites. matter.
includes fungal(Mode
nutricnts are in fungi most ctc.); which an decaying
and leaf their organism
essential Thus, fewTheyA
wever, symbiotic tissues. ar e intimate
another.
incapable in beneit growcircumstances of then spot (ü) life :
organic The categories members of
their th e but obtain
parasites parasites further The
Examples, saprophytes allaccording formseither life)
association may
saprophytes: fungi)
get cycles They association Examples,
parasites
organic saprophytesthose The :
from when
in life Hemiblotrophs
continue grow part teA
rm matter :
amode association words
mykos =cach defomans,
Taphrina beetc. their their live
lew the of synbiotic
other.ectoparasites
cycle
and fail :
sub onparasite of
matter, fungiterm - inlive lack
grow thcy nourishment (Examples food into They dividedliving derived th e is
Pythum. TheyPeziza, : and : to on
ung
cernal
synthesiZing of with in chlorophyll
issymbiotic
nutriton. (ii) to to materials It which
arederived their dead
heSZe wiAnotber
th association inside association can It develop : threegrow are with may
but includes
can
alga Perthotrophs They from organism Morchella, are furtherobtain
SOurce the alsoincludes the into another be from not modedecaying
Mushroom; -Albugo,categories on ordinarily
under
Thetheir rootscxample in thewhen
Lichens host saprophytically andatack artíficial
grow the true fodefined
r
Greek growfungi sub fromassociation and
ofINTRODUCTORY
wi th and it s their
part afofungi
r with grow fungi sporulate living parasitesexistance" living certain
Agaricus. on Greeknutritionorganic exhibit
owa of organism. as living whi divided
ch food
their
ofneed higher hizg where ofother saprophytes. th e They Puccinia,
: - obtain saprophytes living
as
word with
on which tissues media.) organism an word
their food. symbiotic
normal plants(e.g,
living
tissues conditions get from beterotrophic
matter
both =root) external kilafter Blotrophs and their organism
(Thrower, parasites host, into Sapros theyother
otein, They organisms.
both host. live (e.8, Luttrell
on
restricted food their dead- BOTANY
the
Sphaerotheca, ie., are
growth association as
Sclerotuum host the which the in from andgrow food meaningclassificd on plants or
organic where fungal surface Eramples, parasites tissue
However,
arce tissue from meaning or they they decaying
fat Pinus). same they The(19n4): only 1966).whichvirus from ormode
living VOL
and and and thus, the and
Tbey may
on are as
of is it. I

INTRODUCTION
tissucs
bostofumcs
calicd absorbedwhich
(interccllular)
penctrate magnesium,
ganeseBesides,
solubleparasites
hyphaesome amino suited
materials
peptides, of
carbon vitamin
hormones.
growth
carbon.
Fungi Most
the INTRACELLULAR
breakspecial frequirements.
or
baustoria. uar Fig HYPHA nutrients
into and
have many Nitrogen
requirement.
as almost
25.1. into by of
parasitic the the molybdenumgrow etc.external the
phae; orthe thabsorbing
e
(Fig. Different HAUSTORIUM complcx occursspecific
substratum. best
mineral
are acids) all fungi
penctrate host
mycclium.
25.1).Thesefuni B. A requirement fungi.
Intassociationsof
eroelluler in necded source. Simple
tissucs. requirement
medium
slightly
acidic elements and need Most
haustoria molecules
simpler through
intoorgans. are inorganic However,
produce into They Hydrogen
as external theof
sugars
Parasitic
They macronutrients
required
sPhae
absorb HAUSTORIA
the
citber
Usually the
secrete of
such fulfilled is
th e such
fungi
special -HOST
CELS HYPHA host
INTERCELLULAR wholenutrients (such
asand yeasts source syathesize
Ectoparasite. fungi as as
the cells
remain tmicronutrients.
he sulphur, oxygen asglucose, by
intracellular mycelium both of
solublc may
saprophytes
penetrate nitraterequire
(intracellular).extracellular The sometheir around and and
enzymes
forms. carbohydrates
with in iron, arorganic
phospborus, e their
host remain
the attack fructose,
food or
pH6. obtained andacetates own
cells. intercellular th ey zinc,
absorbing
from cdoparasite direcly laterare specificSome ammonium (such
requirement
A. Absorption may copper, as
the Intacef. Most potassium, from asthe etc. to
cell develop hosts. obligale protcins, armeet e
ongans, spacesof water.salts) source
saps the or
man best the 155
of oB
 1$6
Synchytriun).
reticulum,theretiatedother The Somecalled SOMATIC In rue
cell The mostroot, The
arerelated
into unicellular byphae
olipore.
Septum th Fie,
B4avotie
wiphae; wall
hyphae ofplant
25.2. Goliother
plasma thestem OR
Multicellular compound. is
hypha;Different H G NUCLEUS
A
cytoplasmiccomposed
NUCLEUS (singular-hypha).
are cases, andbody
VEGETATIVE
apparatus
VACUOLE membrane, long forms leaves). of
H.forms
thallus fungi
O0.o NUCLEUS The of and
tinucleate
byphae;
septateF.of inchusions
and celtubular.
fungal
l theconsists The is
funl cytoplasm, wall mycelium thSTRUCTURE
ribosomes.
typically
e thallus
SEPTUM
thalli.A.
WALL
B cellulose,They mass of
cels; PonÉ encloses
such thalloid
may
long,
of
are
nucleus is INTRODUCTORY be BOTANY
OFVOL.I
NUCLEI
Hyphae
I.
Unicellular The as hyphae
Septum pectose,
made unicellular
protoplast completelytubular, (ie.PLANT
,
uninuckeatewith SEPTUM
mitochondria,
reserve
PARENTHOSOME
with form; up is not
E callose, of branched
called BODY
food whichdefinite differentiated
simple Y:J vacuoles.
Besides, or
CoenocyticB.
PORE
endoplasmic chitin multicellular. (Fig.
absent
myceliun.
pore;cells;G. material is
differen orcel filaments 25.2):
J. walls. (e,g,
is
any In into

INTRODUCTION
Where Plasma
Whereas peripheral. fibrils. lowerFlagella
flagellum homokaryotic
mycelium-
mycelium (dikaryotic)
with cap-likedolipore
Basidiomycotina the tum. situated and divided
from multinucleate. nucleate condition the
glycogen
AXONEME Presence Each pore It one Usually the entire
the representation
tonematic) Fig The fungi. by
membrane, O the has (Fig. thickenings are bears
iscentrally.order is of or
flagella all 5.3. APPENDAGES HAIR
LIKE
LEND
PIECE cell a cell cross
called mycelium oil
The two These orswollen. barrel the mycelium
eucaryotic entire Plagella B EHAIR.
EMER 25.3)primary
of
a binucleate cells. or of centrally -Uredinales Such droplets.
type.CYTOPLASMIC EFLIM two centralflagella
singlet
multinucleate.
heterokaryotic. a except intoSuch septawalls,
are of SHEATH
are :multicellularcalledshaped acellular a
The 9+2 t.C-F.
s. in central mycelium
The possess condition
the and
monofibrillar. corethin, in located
Uredinales) the is In
offungi. openings a called thsome
flagella.
typical flagellum
arrangement D fibrils motile
pore septum condition
other.
e
Different A. known parenthosome. (Basidiomycotina) coenocytic.
central
fibrils hair-like Both cross
Whiplash m
are bodies mycelium wi
doliporeth aseptate.
where lower
This 9+2 withSome
showing9+2types of Theallows pores. is walls
are
central as the poreopen is called the fungi,
arrangement (acronematic)
arrangement of of extensions uninucleate
axoneme. is highernuclei more If
sometimes the on(Lat. septum the (septa)are The
fibrils
lagellation; CENTRAL
SINGLET
FIBRIL may ends. Each mycelium the the
and
characteristic both complex,
cytoplasm septate aseptate
arrangement PERIPHERAL
DOuBLET
FIBRIL fungi ofbe dolium The possess cytoplasm cvtoplasm
G
nine It of septum
is type; uninucleate, a th e of
is of is
andmyceliumis not
sidesedges called
surrounded enclosed cell cells
dikarotic
produce
notfibrils G. composed
doublet higher
= single aseptate
Diagrammaticof B. and
a multicellular. of
found fibrils. Tinsel cytoplasm. and of
Euascomycetes offormed. is
feature are large
is by two cell nuclei
septa fungi simple mycelium continuous
dolipore
inthe by (pan fibrils of secondarybinucleateguarded jar). and
bacteriacharacdouble a of kinds may is
sheath elevenEachsome around to usuay Such
muid
are by The
sep(e-g-,passpore
ofbe 157
s a in
 INTRODUCTORY BOTANY VOL.I
INTRODUCIION 159
158
are either uniflagellate or biflagellate. There PERITHECIA
The motile bodies of- fungi the tinsel type. The
CENTRAL CAVITY
type and (i)
flagella () the whiplash ending into a narrow end piece.
are two kinds offlagellum
whiplash type of is flexible and long lagellum. The tinsel type
It has smooth surface. It is also called acronematic
fine hair- faoges
like (hairy)
and bears is also called
of flagellum is usually small
nastigoneme. This type of
it is
HYPHAL
called immer hairs or
body bears two flagella of equal length, CORE

pantonematic. If a biflagellate equal it is called beterokontae. GELATINOUS
called isokontae. If they are not
LAYER

Modification of nycelium : organized and appear just STROMATIC
In some higher fungi, the mycelium becomes compactly woven tissue-like
TISSUE

It consists of loosely or
like a thalloid body. 25.4). There are two types of plec
-STALK

structure, called plectenchyma (Fig. B LOOSE HYPHAE
tenchyma lie almost
of loosely woven hyphae which PSEUDO PARENCHYMATOUS
() Prosenchyma : It consists HYPHAE
parallel toeach other and the
cells and hyphae are clearly
distinguishable. SCLEROTIUM
(ü) Pseudoparenchyma :
It consists of comnpact mass of
parench yma-like tissue
where the hyphae are very
closely packed and inter
these
wOven. In cross section,
isodiametri A
nyphae appear as D
E
PSEUDOPARENCHYMA
Fig. 25.5. A.
Sclerotia in ryeRhizomorph;
Besides plectenchyma, B B. LS. of rhizomorph tip; C. LS. of
there are other modiications PROSENCHYMA grains; E. Single sclerotium; F. T.S. of sclerotium. stroma; D.
of mycelium such as
Fig. 25.4. Organisation of mycelia in fungi.
vegetative cell may be transformed into reproductive body
rhizomorph, sclerotia and portion of vegetative thallus is (holocarpic). If a
stroma.
several hyphae condition is called eucarpic. transformed into reproductive structure, the
(i) Rhizomorph (Fig. 25.5): In some higher fungi,string-like or root [A]ASEXUAL REPRODUCTION:
with each other and form cord-like,
become interwoven rhizomorphs. These structures serve The kind of reproduction which does not involve meiosis and
likeelongated mycelial strands called nucleiis called asexual fusion of
the functions of root.
compact mass of interwoven
reproduction. It occurs by the
(1) Fragmentation : The fungal mycelium gets followinginto methods -
(iü) Sclerotia (Fig. 25.5) : It consists of a hyphae become hard and Iragments accidently or through external force. Eachbroken smaller
pseudoparenchyma. The outer
hyphae forming
form a protective covering or rind. These bodies remain dormant under
favourable conditions.
develops into a new individual. This type of reproduction isfragment (piece)
very common in
unfavourable conditions and germinate at the onset of fungi.
which a large
(iü) Stroma(Fig. 25.5): It is a thick mycelial mat on or, in (2) Budding (Fig, 25.6): The parent cell produces one or more bud-like
number of fruit bodies (fructifications) develope. protuberances which detach from parent cell and grow into new individual.
REPRODUCTION: Such type of reproduction is very common in budding yeast (Saccharomyces)
type of where chain of buds may produce pseudomycelium.
Fungi generally reproduce by asexual and sexual methods. The
reproduction called vegetative is included under the category of asexual (3) Fission (Fig. 25.6):The parent cell splits into two equal halves by a
Constriction and formation of cell wall and each half develops into a new
reproduction. ndividual. Fission is very common in bacteria and also 0ccurs in yeasts.
In fungi, the reproduction typically occur by production of spores
(asexual and sexual) but other kinds of reproductive bodies may also be (4) Oidia (Fig. 25.7):The bypha breaks up into its component cells or
formed in some cases. If the plant body (thallus) is unicellula, the complete Small pieces which behave like spores. These are called oidia. The oidia are
 INTRODUCTORY BOTANY VOL.I
160 INTRODUCTION 161

DEVELOPING BUD
BUD
NUCLEUS

VACUOLE sPORESO O
SPORANGIUM
ZOOSPORES
MOTHER CELL
D
B DEHISCED
SPORANGIUM
COLÙMELLA
VACUOLE
NUCLEUS
ZOoSPORANGIUM

HovDED CELLS
A B C D
F pIviDING C¸L
G SPORANGIOPHORE
E
cONIDIA

Fig. 25.6. AD. Budding,E-H. Fission.
CHLAMYDOSPORE
STERIGMATA
CONIDIA
OIDIUM
J MEULAE

VESICLE

E CONIDIOPHORE
CONIDIOPHORE
F

Fig. 25.8. Common types of asexual reproduction. A-C. Spores; D.
Zoospores; E-G. Conidia.
HYPHAE
() Sporangiospores : These spores are produced inside the sac- like
structures, called sporangia. Sometimes these spores are also termed as
endospores. If the sporangiospores are non- motile, they are called
D
aplanospores (e.g, Mucor, Rhizopus). If the sporangjospores are motile, they
A B are called zoospores. The zoospores may be uniflagellate or biflagellate.
Fig. 25.7.A-B. Oidia formation; C-E Formation of Chlamydospores. (ii) Conidia : These are non-motile spores produced singly or in chains
generally thin walled and do not store reserve food material. They germinate by constrictions at the tip orlateral side of special hypha! branches, called
immediately after liberation and can survive under unfavourable conditions. conidiophores. They are produced exogenously (not enclosed withinsporan
These are thick walled resting cells gia). The conidia germinate directly by givingout germ tubes. Sometimes the
(5) Chlamydospores (Fig. 25.7) : They store reserve food material and
conidia behave like sporangia and called conidiosporangia.
produced in the same manner as oidia.
withstanding long unfavourable conditions. (B] SEXUAL REPRODUCTION :
are capable of
(6) Spores (Fig. 258) : Fungi reproduce most commonly by production Sexual reproduction occurs in almost all the groups of fungi cxcept in
of spores. These are minute propagating units which serve in the production Tungi imperfecti (Deuteromycotina). It involves union of two compatible
of new individuals. They vary in shape, síze and colour in different individuals Luclei of oppositesex at a definite stage in the life-history of fungus. The
and sometimes serve as basis in the classification of certain groups of fungi. Sexual reproduction in fungi completes in three phases () plasmogamy,
The asexual spores are of two types- (i) Sporangiospores and (i) Conidia. (ü) karyogamy and (iii) meiosis.
 INTRODUCTORY
162
fusion of two protoplasts which
BOTANY VOL I
(i) Plasmogamy : It is the
compatible nuclei close together in asingle
cell. The resultingbrings
as dikaryotizath
cell the two
becomcs
dikaryon. The phenomenon is sometimesoftermed
fusion two compatible
INTRODUCTION
(ii) Karyogamy : It is the nuclei brought
163

together as a result of plasmogamy. The resulting diploidInucleus is caled
synkaryon. MOTILE FEMALE GAMETE
(i) Meiosis : The diploid nucleus divides by meiosis (or reduction
division) resulting in the formation of haploid nuclei. Usually meiosis ocers
nuclei.
immediately after fusion of two
Allthese three phases occur at specific stages in the life- history of funei MOTILE
MALE GAMETE
In most of the lower fungi (Mastigomycotina and Zygomycotina),the plas ISOGAMETES
mogamy is immediately followed by karyogamy and meiosis. In some cases
the meiosis is slightBy delayed (Zygomycotina). In case of higher fungi NON MOTILE
FEMALE GAMETE
(Ascomycotina and Basidiomycotina), the plasmogamy is not immediately
followed by karyogamy. In Ascomycotina and Basidiomycotina, the plas B
mogamy results in the formation of dikaryon. The two nuclei remain together
in adikaryon and divide by conjugate division. It results in the forrmation of
dikaryotic phase of life-cycle offungus. The karyogamy occurs at alater stage
in the life history which is soon followed by meiosis resultingin the formation Fig, 25.9. Planogametic
of haploid sexual spores- ascospores in Ascomycotina and basidiospores in B. Anisogamous; C. OogamousyPe ot sexual reproduction. AIsogamous:
Basidiomycotina. (2)Gametangial contact (Fig. 25.10) :It is a
Fungi may be monoecious (bisexual) or dioecious (unisexual). The tion where the male gametangia are called kind of oogamous reproduc
monoecious species produce the two sex organs on the same thallus or ascogonia. The gametes are non motile antheridia and which
female oogonia
(Homothallic) whereas the dioecious species produce them on separate FERTILIZATION aplanogametes are never
TUBE FERTILIZATION PERIPUASM
thalli (Heterothallic). EMPTY
TUBE
The sex cells are called gametes which are usually produced in sex-or ANTHEAIDIUM
gans called gametangia (singular-gametangium). If the male and female
gametes are morphologically indistinguishable, they are called isogametes. 00SPORE
If the male and female gametes are different, they are called heterogametes.
The isogametes are produced in isogametangia whereas the heterogametes
are produced in beterogametangia i.e., the male and female gametangia. The ):
male gametangium is usually called antheridium and the female gametan 00GONIUM -

gium iscalled oogonium. They are also known by different names in different EMPTY
groups of fungi. In some cases, the sex organs are not formed and the sexual ANTHERIDIUM 00PLASM
fusion occurs between two vegetative cells.
Modes of sexual reproduction :
There are various modes of sexual reproduction in fungi, which can be
A
categorised into the following types
(1) Planogametic copulation (Fig. 25.9) : The motile (flagellated) Fig. 25.10. A-B. Gametangial contact type of sexual fusion.
gametes are called planogametes. In this category of sexual reproduction released fromgametangia. The male and female gametangia come in contact
cither one or both the fusing gametes are motle (flagellated). Planogametic with each other. The male gametangium sends a tubular outgrowth, called
copulation may further be grouped under three categories- (i) fertilization tube, that pierces throughgametangium
the wall of female gametangium. Male
Isoplanogametic copulation -when both the fusing gametes are flagellated nucleus or gamete enters into female through this tube. In this
and morphologicaly similar; (ü) Anisoplanogametic copulation differ when
mode of reproduction the two gametangia do not fuse with each other.
the two fusing gametes are ilagellated and morphologically similar but Examples, Åbugo, Phytophthors, Pychiun, Sphaeroheca, etc. reproduction,
in size and (n, Ooplanogametic copulation--when the male gametes arce (3) Gametangial copulation (Fig. 25.11): In this mode of
flagellated (called sperms) and the female gamete is non-flagellated (called Lhe two gametangiafuse with each other and lose their identity
in the sexual
Ovum or egg). act. Examples, Rhizopus, Mucor.
 through
minute,
struc female Ustilago,
of between differen
mode typ
D specialised
as with
numerous,
transferred occurs
this Peziza, the
ZYGOSPORE
treated discussillustra
fusion.
sexual
FUSION In Examples,
CELL fusion
ain hyphae Somatogamy.
: you
produce 25.12) and
are
spermatia the by fungi
of HYPHAE
FUSING
studied
type somatic
These fungi.
dikaryotization.
and
(Fig.
GAMETANGIA
fungi C. in
SUSPENSORcopulation ASCOGON.UM formed QUESTIONS
Spermatisation; of nutrition
pycnidia).
called
Some Pseudogamy) features type
or graminis. fungi.
ISO
-
hyphae -TRICHOGYNE following