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BIO 102
FUNGI
 INTRODUCTION
The word fungus comes from the Latin word for mushrooms.
The familiar mushroom is a reproductive structure used by many types
of fungi, but there are also many fungi species that don't produce
mushrooms at all.
Being eukaryotes, a typical fungal cell contains a true nucleus and many
membrane-bound organelles.
The kingdom Fungi includes an enormous variety of living organisms
collectively referred to as Eucomycota, or true Fungi.
While scientists have identified about 100,000 species of fungi, this is
only a fraction of the 1.5 million species of fungus likely present on
Earth.
Edible mushrooms, yeasts, black mold, and the producer of the
antibiotic penicillin, Penicillium notatum, are all members of the
kingdom Fungi, which belongs to the domain Eukarya.
Fungi, once considered plant-like organisms, are more closely related to
animals than plants.
 Cont’d
Like bacteria, fungi play an essential role in ecosystems because
they are decomposers and participate in the cycling of nutrients by
breaking down organic materials to simple molecules.
Fungi often interact with other organisms, forming beneficial or
mutualistic associations.
For example most terrestrial plants form symbiotic relationships
with fungi.
The roots of the plant connect with the underground parts of the
fungus forming mycorrhizae.
Through mycorrhizae, the fungus and plant exchange nutrients and
water, greatly aiding the survival of both species.
Fungi are not capable of photosynthesis: they are heterotrophic
because they use complex organic compounds as sources of energy
and carbon.
Some fungal organisms multiply only asexually, whereas others
undergo both asexual reproduction and sexual reproduction with
alternation of generations(life cycle in which subsequent
generations alternate between diploid asexual and haploid sexual
phases)
 Cont’d
Alternatively, lichens are an association between a fungus and its
photosynthetic partner (usually an alga).
Fungi also cause serious infections in plants and animals.
In humans, fungal infections are generally considered challenging to
treat.
Unlike bacteria, fungi do not respond to traditional antibiotic therapy,
since they are eukaryotes.
Fungal infections may prove deadly for individuals with compromised
immune systems.
Fungi have many commercial applications.
The food industry uses yeasts in baking, brewing, and cheese and wine
making.
Many industrial compounds are byproducts of fungal fermentation.
Fungi are the source of many commercial enzymes and antibiotics.
 CHARACTERISTICS OF FUNGI
1. Fungi are eukaryotic organisms.
2. They are non-vascular organisms.
3. They reproduce by means of spores, usually
wind-disseminated
4. Depending on the species and conditions both sexual and
asexual spores may be produced.
5. They are typically non-motile, although a few (e.g Chytrids)
have a motile phase
6. Fungi exhibit the phenomenon of alteration of generation.
7. The vegetative body of the fungi may be unicellular or
composed of microscopic threads called hyphae.
8. The structure of cell wall is similar to plants but chemically
the fungi cell wall is composed of chitin.
9. Fungi are heterotrophic organisms.
 Cont’d
10. Fungi digest the food first and then ingest the food,
to accomplish this fungi produce exoenzymes.
11. Fungi store their food as glycogen.
12. Biosynthesis of chitin occurs in fungi.
13. The nuclei of the fungi are very small.
14. During mitosis the nuclear envelope is not dissolved.
15. Nutrition in fungi - they are saprophytes, or parasites
or symbionts.
16. Reproduction in fungi is both by sexual and asexual
means. Sexual state is referred to as teleomorph,
asexual state is referred to as anamorph.
 CELL STRUCTURE AND FUNCTION
The most common body structures are
multicellular filaments and single cells (yeasts).
Some species grow as either filaments or yeasts;
others grow as both.
Fungal cells also contain mitochondria and a
complex system of internal membranes, including
the endoplasmic reticulum and Golgi apparatus.
Unlike plant cells, fungal cells do not have
chloroplasts or chlorophyll.
Many fungi display bright colors arising from other
cellular pigments, ranging from red to green to
black.
 GROWTH
The vegetative body of a fungus is a unicellular or
multicellular thallus.
Dimorphic fungi can change from the unicellular to
multicellular state depending on environmental conditions.
Unicellular fungi are generally referred to as yeasts.
Saccharomyces cerevisiae (baker’s yeast) and Candida
species (the agents of thrush, a common fungal infection)
are examples of unicellular fungi.
Most fungi are multicellular organisms.
They display two distinct morphological stages: the
vegetative and reproductive.
The vegetative stage consists of a tangle of slender
thread-like structures called hyphae (singular, hypha),
whereas the reproductive stage can be more conspicuous.
The mass of hyphae is a mycelium.
Fig.1 Structure of a Mushroom
 The morphology of
multicellular fungi enhances
their ability to absorb
nutrients.
Fungi consist of mycelia,
networks of branched
hyphae adapted for
absorption.
Most fungi have cell walls
made of chitin.
Some unique fungi have
specialized hyphae called
haustoria that allow them
to penetrate the tissues of
their host and extract
nutrients Fig 2: Specialized Hyphae in
Mycorrhizal Fungi
 Most fungal hyphae are divided
into separate cells by end walls
called septa (singular, septum)
(Figure 3 ).
In most phyla of fungi, tiny holes
in the septa allow for the rapid
flow of nutrients and small
molecules from cell to cell along
the hypha.
They are described as perforated
septa.
The hyphae in bread molds (which
belong to the Phylum Zygomycota)
are not separated by septa.
Instead, they are formed by large
cells containing many nuclei, an
arrangement described as
coenocytic hyphae (Figure 3b)
Fig.3 Fungal hyphae may be
(a) Septate or (b) coenocytic
 Cont’d
Fungi thrive in environments that are moist and slightly
acidic, and can grow with or without light.
They vary in their oxygen requirement. Most fungi are
obligate aerobes, requiring oxygen to survive.
Other species such as the Chytridiomycota that reside in
the rumen of cattle, are obligate anaerobes, this is because
oxygen will disrupt their metabolism or kill them.
Yeasts are intermediate, being facultative anaerobes.
This means that they grow best in the presence of oxygen
using aerobic respiration, but can survive using anaerobic
respiration when oxygen is not available.
The alcohol produced from yeast fermentation is used in
wine and beer production.
 NUTRITION
Like animals, fungi are heterotrophs; they use complex
organic compounds as a source of carbon, rather than fix
carbon dioxide from the atmosphere and do not fix nitrogen
from the atmosphere
Like animals, they must obtain it from their diet, but unlike
most animals, which ingest food and then digest it internally
in specialized organs, fungi perform these steps in the
reverse order; digestion precedes ingestion.
First, exoenzymes are transported out of the hyphae,
where they process nutrients in the environment.
The smaller molecules produced by this external digestion
are absorbed through the large surface area of the
mycelium.
They store polysaccharide as glycogen, rather than starch,
as found in plants
 Types of nutrition
Saprophytic fungi
Fungi are mostly saprobes (saprophyte is an equivalent term): organisms that
derive nutrients from decaying organic matter.
They obtain their nutrients from dead or decomposing organic matter: mainly
plant material.
Fungal exoenzymes are able to break down insoluble polysaccharides, such as
the cellulose and lignin of dead wood, into readily absorbable glucose
molecules. The carbon, nitrogen, and other elements are thus released into the
environment
Parasitic fungi
They absorb nutrients from the living cells of another organism called the host.
Many parasitic fungi produced specialized hyphae called haustoria, which grow
onto the hosts tissues and absorb their nutrients.
Mutualistic fungi
Some fungi live in a mutualistic relationship with another organism, such as a
plant or algae.
The mycelia of a particular fungus cover the root of a soybean plant.
The fungus receives sugar from the host plant.
The mycelia increase water uptake and mineral absorption for the host plant
 REPRODUCTION
Fungi reproduce sexually
and/or asexually.
Perfect fungi reproduce both
sexually and asexually, while
imperfect fungi reproduce only
asexually (by mitosis).
Fungal spores are smaller and
lighter than plant seeds.
The giant puffball mushroom
bursts open and releases
trillions of spores.
The huge number of spores
released increases the
likelihood of landing in an
environment that will support
growth (Figure 4).
 ASEXUAL REPRODUCTION
Fungi reproduce asexually by fragmentation, budding, or
producing spores.
Somatic cells in yeast form buds and during budding (a type
of cytokinesis), a bulge forms on the side of the cell, the
nucleus divides mitotically, and the bud ultimately detaches
itself from the mother cell.
The most common mode of asexual reproduction is through
the formation of asexual spores, which are produced by one
parent only (through mitosis) and are genetically identical to
that parent (Figure 5).
Spores allow fungi to expand their distribution and colonize
new environments.
They may be released from the parent thallus either outside
or within a special reproductive sac called a sporangium
Figure 5: Fungi may have both asexual and sexual
stages of reproduction
CONT’D
 CLASSIFICATIONS OF FUNGI
Fungi have been classically characterized and
classified by the following:
appearance of their colony (color, size, etc),
hyphal organization (septate or coenocytic),
the structure and organization of reproduction spores.
More recently, ribosomal RNA sequences are being
used to further categorize these organisms.
The kingdom Fungi contains five major phyla
that were established according to their mode
of sexual reproduction or us molecular data.
 Cont’d
The five true phyla of fungi are:
1. Chytridiomycota (Chytrids),
2. Zygomycota (conjugated fungi),
3. Ascomycota (sac fungi),
4. Basidiomycota (club fungi)
5. Deuteromycota (fungi imperfecti)
The Deuteromycota is an informal group of unrelated
fungi that all share a common character – they use
strictly asexual reproduction.
Note: “-mycota” is used to designate a phylum while
“-mycetes” formally denotes a class or is used
informally to refer to all members of the phylum
 PHYLUM CHYTRIDIOMYCOTA
The chytrids are the aquatic fungi.
They are the causative agents of a deadly infection in frogs.
Several species of chytrids are known to parasitize plants and insects,
although many live on decaying plants and insect parts.
The chytrids are very different from other fungi in many respects.
They have flagellated spores and gametes, which is unique in the fungal
kingdom.
They are aquatic, some found in fresh water and marine.
Chytrid cells have centrioles like animal cells do.
Other phyla of fungi do not have centrioles.
Although some chytrids are unicellular, many produce a mycelium much
like other fungi.
They are the oldest phylum of fungi and likely gave rise to the other phyla
of fungi
This gave scientists clues to fungal evolution, suggesting that fungi had
their start in water, that they may be closely related to the animals
 PHYLUM ZYGOMYCOTA
The zygote-forming fungi commonly called
“zygomycetes” include the bread molds.
All members of this phylum produce a
thick-walled zygote called a common black
bread mold (Rhizopus nigricans) is an
example of the zygote-forming fungi which
are generally found on decaying food and
other organic material.
The name comes from zygosporangia, where
resistant spherical spores are formed during
sexual reproduction.
They are mostly terrestrial in habitat, living
in soil or on decaying plant or animal
material and some are parasites of plants,
insects, and small animals, while others form
symbiotic relationships with plants.
Zygomycete hyphae may be coenocytic,
forming septa only where gametes are
formed or to wall off dead hyphae
 PHYLUM ASCOMYCOTA
The sac fungi are the largest phylum of fungi,
with at least 30,000 named species.
They live in a wide variety of places, such as in
the soil, in saltwater and fresh water, on dead
plants and animals, and on animal feces.
They are called sac fungi because their sexual
spores, which occur in groups of eight, are
enclosed in saclike structures called asci(singular:
ascus).
Their life cycles are similar to that of the club
fungi.
The members of the ascomycetes produce
spores in a sac, which develops as a result of
sexual reproduction.
Asexual reproduction takes place when the
fungus produces asexual spores called conidia
(singular, conidium).
The phylum includes organisms of considerable
importance, such as the yeasts crucial to the
baking and brewing industries, as well as
numerous plant pathogens
 PHYLUM BASIDIOMYCOTA
Basidiomycota is one of two
large phyla that, together with
the Ascomycota, constitute the
subkingdom Dikarya (often referred to as
the "higher fungi") within the
kingdom Fungi.
These include these groups,
mushrooms, puffballs, stinkhorns, bracket
fungi, other polypores, jelly fungi etc.
The mushroom is only a portion of the
fungus and it is the fruiting body,
specifically a basidiocarp, containing the
sexually produced haploid basidiospores.
These basidiospores are produced by a
club-shaped basidium for which the
group is named.
Figure 8: The fruiting bodies of a
basidiomycete form a ring in a meadow,
commonly called “fairy ring.”
 PHYLUM DEUTEROMYCOTA
The Fungi imperfecti or imperfect fungi is also known
as Deuteromycota, these are fungi which do not fit into the commonly
established taxonomic classifications of fungi that are based
on biological species concepts or morphological characteristics of
sexual structures because their sexual form of reproduction has never
been observed; hence the name "imperfect fungi."
Only their asexual form of reproduction is known, meaning that this
group of fungi produces their spores asexually, in the process
called sporogenesis.
The Deuteromycota were once considered a formal phylum of
the kingdom Fungi.
The term is now used only informally, to denote species of fungi that
are asexually reproducing members of the fungal phyla
Ascomycota and Basidiomycota.
These fungi are among the most economically important, producing
antibiotics (for example, one species of Penicilliumproduces penicillin).
Others produce the citric acid used in the soft-drink industry; still
others are used in the manufacture of cheese.
Some are important pathogens of both plants and animals.
TABLE 1: FUNGI PHYLA.
 ECOLOGY OF FUNGI
Fungi play a crucial role in the balance of ecosystems.
They colonize most habitats on Earth, preferring dark, moist conditions
and can thrive in seemingly hostile environments, such as the tundra, due
to the symbiosis relationship with photosynthetic organisms like algae to
produce lichens. Like bacteria, they are the major decomposers of nature
and with their versatile metabolism, fungi break down organic matter,
which would not otherwise be recycled
HABITATS
Fungi are primarily associated with humid and cool environments that
provide a supply of organic matter; they colonize a surprising diversity of
habitats, from seawater to human skin and mucous membranes.
Chytrids are found primarily in aquatic environments. Fungi that parasitize
coral reefs live in the ocean.
However, most members of the Kingdom Fungi grow on the forest floor,
where the dark and damp environment is rich in decaying debris from
plants and animals.
In these environments, fungi play a major role as decomposers and
recyclers, making it possible for members of the other kingdoms to be
supplied with nutrients and live
 DECOMPOSERS AND RECYCLERS
The food web would be incomplete without organisms
that decompose organic matter.
Some elements—such as nitrogen and
phosphorus—are required in large quantities by
biological systems, and yet are not abundant in the
environment.
The action of fungi releases these elements from
decaying matter, making them available to other living
organisms.
Trace elements present in low amounts in many
habitats are essential for growth, and would remain
tied up in rotting organic matter if fungi and bacteria
did not return them to the environment via their
metabolic activity.
MUTUALISTIC RELATIONSHIPS
Symbiosis is the ecological interaction between two organisms that live
together. When both members of the association benefit, the symbiotic
relationship is called mutualistic. Fungi form mutualistic associations with
many types of organisms, including cyanobacteria, algae, plants, and
animals.
i. FUNGUS/PLANT MUTUALISM
One of the most remarkable associations between fungi and plants is the
establishment of mycorrhizae.Mycorrhiza, which comes from the Greek
words mycomeaning fungus and rhizomeaning root, refers to the
association between vascular plant roots and their symbiotic fungi.
In a mycorrhizal association, the fungal mycelia use their extensive
network of hyphae and large surface area in contact with the soil to
channel water and minerals from the soil into the plant.
In exchange, the plant supplies the products of photosynthesis to fuel the
metabolism of the fungus.
Plants harbor harmless symbiotic endophytes that live inside leaves or
other plant parts, these endophytes make toxins that deter herbivores and
defend against pathogens
 II. LICHENS
Lichens display a range of colors and textures and can
survive in the most unusual and hostile habitats.
They cover rocks, gravestones, tree bark, and the
ground in the tundra where plant roots cannot
penetrate.
Lichens can survive extended periods of drought,
when they become completely desiccated, and then
rapidly become active once water is available again.
Lichens are not a single organism, but rather an
example of a mutualism, in which a fungus (usually a
member of the Ascomycota or Basidiomycota phyla)
lives in close contact with a photosynthetic organism
(a eukaryotic alga or a prokaryotic cyanobacterium).
 Cont’d
A lichen, or lichenized fungus, is actually two organisms
functioning as a single, stable unit.
Lichens comprise a fungus living in a symbiotic relationship with
an alga or cyanobacterium (or both in some instances).
There are about 17,000 species of lichen worldwide.
The fungal component of a lichen is known as the "mycobiont,"
and the algal or cyanobacterial component is known as the
“photobiont.”
The scientific name for a lichen is the same as that of the
mycobiont, regardless of the identity of the photobiont.
For example, the fungus Sticta canariensis is capable of forming
two different lichen associations with an alga and
cyanobacterium, yet both lichens are referred to as Sticta
canariensis.
 Importance of Lichens
Lichens are key players in a variety of environmental processes.
For example, cyanobacterial photobionts participate in nitrogen
fixation
Lichens also contribute to a phenomenon known as biological
weathering.
The lichen mycobionts can break down rocks and release minerals
by producing certain chemicals.
Weathering can lead to the eventual disintegration of rocks which
is also an essential step for the formation of primitive soils.
When lichens decompose, the organic matter that is left behind,
along with particles of rock and dust trapped by thalli provide
material for the development of primitive soils.
Finally, lichens are excellent indicators of pollution.
According to the Forest Service lichens can absorb pollutants such
as heavy metals, carbon and sulfur into their thalli.
Extracting these pollutants gives an indication of the levels present
in the atmosphere. This process is known as lichen biomonitoring.
 Why form a dual organism?
Fungi are incapable of photosynthesis because they
lack the green pigment chlorophyll.
They need to seek out outside sources of food.
They absorb nutrition from organic substances, that is,
carbon containing compounds such as carbohydrates,
fats, or proteins.
On the other hand, algae and cyanobacteria can
conduct photosynthesis, similar to plants.
So when a fungus, which is the dominant partner in
this relationship, associates with an alga (usually from
the green algae) or cyanobacterium to form a lichen, it
is providing itself with constant access to a source of
nourishment
 Cyanobacteria
Cyanobacteria also
provide fungi with the
additional benefit of
nitrogen fixation.
This is the biochemical
reaction wherein
atmospheric nitrogen is
converted to ammonia,
a more usable form of
the element.
In return, algae and
cyanobacteria secure a Examples of the three types of lichens are shown
here. (a) This is a crustose lichen found mostly on
protected environment, marine rocks, Caloplaca marina.
especially from (b) This is a foliose lichen, Flavoparmelia caperata.
damaging ultraviolet (c) This is a fruticose lichen, Letharia vulpina,
rays. which is sufficiently poisonous that it was once
used to make arrowheads
 iii. FUNGUS/ANIMAL MUTUALISM
Fungi have evolved mutualisms with numerous insects in Phylum
Arthropoda( jointed, legged invertebrates).
The arthropods depend on the fungus for protection from
predators and pathogens, while the fungus obtains nutrients and a
way to disseminate spores into new environments.
The association between species of Basidiomycota and scale
insects is one example.
The fungal mycelium covers and protects the insect colonies, while
the scale insects foster a flow of nutrients from the parasitized
plant to the fungus.
Some fungi share their digestive services with animals and they
help break down plant material in the guts of cows and other
grazing mammals.
Many species of ants and termites use the digestive power of
fungi by raising them in “farms”
 FUNGAL PARASITES AND PATHOGENS
Parasitism describes a symbiotic relationship in which one member
of the association benefits at the expense of the other.
Both parasites and pathogens harm the host; however, the pathogen
causes a disease, whereas the parasite usually does not.
Commensalism occurs when one member benefits without affecting
the other.
Plant Parasites and Pathogens
About 30% of known fungal species are parasites or pathogens,
mostly on or in plants.
Some fungi that attack food crops are toxic to humans, but animals
are much less susceptible to parasitic fungi than are plants.
The general term for a fungal infection in animals is mycosis
The production of sufficient good-quality crops is essential to human
existence.
 Cont’d
Plant diseases have ruined crops, bringing widespread famine. Many plant
pathogens are fungi that cause tissue decay and eventual death of the
host (Figure 10).
In addition to destroying plant tissue directly, some plant pathogens spoil
crops by producing potent toxins.
Fungi are also responsible for food spoilage and the rotting of stored
crops. For example, the fungus Clavicepspurpureacauses ergot, a disease
of cereal crops (especially of rye).
Although the fungus reduces the yield of cereals, the effects of the ergot's
alkaloid toxins on humans and animals are of much greater significance.
In animals, the disease is referred to as ergotism.
The most common signs and symptoms are convulsions, hallucination,
gangrene, and loss of milk in cattle.
Aflatoxins are toxic, carcinogenic compounds released by fungi of the
genus Aspergillus.
Periodically, harvests of nuts and grains are tainted by aflatoxins, leading
to massive recall of produce
 Mycorrhizae
Mycorrhizae literally translates to
“fungus-root.” Mycorrhiza defines a
generally mutually beneficial
relationship between the root of
a plant and a fungus that colonizes the
plant root.
In many plants, mycorrhiza are fungi that
grow inside the plant’s roots, or on the
surfaces of the roots.
The plant and the fungus have a
mutually beneficial relationship, where
the fungus facilitates water and nutrient
uptake in the plant, and the plant
provides food and nutrients created
by photosynthesis to the fungus.
This exchange is a significant factor in
nutrient cycles and the ecology,
evolution, and physiology of plants.
 Benefits of mycorrhizae
Mycorrhiza associations are particularly beneficial in areas where the soil does not
contain sufficient nitrogen and phosphorus, as well as in areas where water is not
easily accessible.
Because the mycorrhizal mycelia are much finer and smaller in diameter than roots
and root hairs, they vastly increase the surface area for absorption of water,
phosphorus, amino acids, and nitrogen—almost like a second set of roots.
In more complex relationships, mycorrhizal fungi can connect individual plants within
a mycorrhizal network.
This network functions to transport materials such as water, carbon, and other
nutrients from plant to plant, and even provides some type of defence
communication via chemicals signifying an attack on an individual within the
network.
Studies have found that plants with mycorrhizal associations are more resistant to
certain soil-borne diseases.
In fact, mycorrhizal fungi can be an effective method of disease control.
In the case of sheathing mycorrhiza, they create a physical barrier between
pathogens and plant roots.
In addition to disease resistance, mycorrhizal fungi can also impart to its host plant
resistance to toxicity and resistance to insects, ultimately improving plant fitness and
vigor.
 ANIMAL AND HUMAN PARASITES AND PATHOGENS
Fungi can affect animals, including humans, in several ways:
A mycosis is a fungal disease that results from infection and direct damage.
Fungi attack animals directly by colonizing and destroying tissues.
Mycotoxicosis is the poisoning of humans (and other animals) by foods
contaminated by fungal toxins (mycotoxins).
Mycetismus describes the ingestion of preformed toxins in poisonous
mushrooms. In addition, individuals who display hypersensitivity to molds
and spores develop strong and dangerous allergic reactions.
Fungal infections are generally very difficult to treat because, unlike bacteria,
fungi are eukaryotes.
Antibiotics only target prokaryotic cells, whereas compounds that kill fungi
also harm the eukaryotic animal host.
Many fungal infections are superficial; that is, they occur on the animal’s skin.
Termed cutaneous (“skin”) mycoses, they can have devastating effects.
For example, the decline of the world’s frog population in recent years may
be caused by the chytrid fungus Batrachochytrium dendrobatidis, which
infects the skin of frogs and presumably interferes with gaseous exchange
 IMPORTANCE OF FUNGI IN HUMAN LIFE
Although we often think of fungi as organisms that cause disease and rot in food,
they are important to human life on many levels.

1. They influence the well-being of human populations on a large scale because
they are part of the nutrient cycle in ecosystems.
2. As animal pathogens, fungi help to control the population of damaging pests.
3. These fungi are very specific to the insects they attack, and do not infect
animals or plants.
4. The mycorrhizal relationship between fungi and plant roots is essential for
the productivity of farm land. Without the fungal partner in root systems,
80–90 percent of trees and grasses would not survive.
5. We also eat some types of fungi. Mushrooms figure prominently in the
human diet.
 Cont’d
8. Molds of the genus Penicillium ripen many cheeses.
9. Fermentation of grains to produce beer and of fruits to produce
wine is an ancient art that humans in most cultures have
practiced for millennia. Wild yeasts are acquired from the
environment and used to ferment sugars into CO2 and ethyl
alcohol under anaerobic conditions.
10. Louis Pasteur was instrumental in developing a reliable strain of
brewer’s yeast, Saccharomyces cerevisiae, for the French brewing
industry in the late 1850s. This was one of the first examples of
biotechnology patenting.
11. Antibiotics are naturally produced by fungi to kill or inhibit the
growth of bacteria, limiting their competition in the natural
environment. Important antibiotics, such as penicillin and the
cephalosporins, are isolated from fungi.
12. Valuable drugs isolated from fungi include the
immunosuppressant drug cyclosporine (which reduces the risk of
rejection after organ transplant), the precursors of steroid
hormones, and ergot alkaloids used to stop bleeding.
 Economic Importance Of Fungi
1. Fungi are an important organism in human life.
– They play an important role in medicine by yielding antibiotics, in agriculture by
maintaining soil fertility, are consumed as food, and forms the basis of many industries. Let
us have a look at some of the fields where fungi are really important.
2. Importance in Human Life
– Fungi are very important to humans at many levels. They are an important part of the
nutrient cycle in the ecosystem. They also act as pesticides.
3. Biological Insecticides
– Fungi are animal pathogens.
– Thus they help in controlling the population of pests.
– These fungi do not infect plants and animals.
– They attack specifically to some insects.
– The fungus Beauveria bassiana is a pesticide that is being tested to control the spread of
emerald ash borer.
4. Reusing
These microbes along with bacteria bring about recycling of matter by decomposing
dead matter of plants and excreta of animals in the soil, hence the reuse enriches the
soil to make it fertile. The absence of activities of fungi can have an adverse effect on
this on-going process by continuous assembly and piling of debris.
 Cont’d
5. Importance in Medicine
Metabolites of fungi are of great commercial importance.
Antibiotics are the substances produced by fungi, useful for the treatment of diseases
caused by pathogens.
Antibiotics produced by actinomycetes and moulds inhibits the growth of other
microbes.
Apart from curing diseases, antibiotics are also fed to animals for speedy growth and to
improve meat quality.
Antibiotics are used to preserve freshly produced meat for longer durations.
Penicillin is a widely used antibiotic, lethal for the survival of microbes. The reason it is
extensively used is that it has no effect on human cells but kills gram-positive bacteria.
Streptomycin, another antibiotic is of great medicinal value. It is more powerful than
Penicillin as it destroys gram-negative entities.
Yield-soluble antibiotics are used to check the growth of yeasts and bacteria and in
treating plant diseases.
Administration of Griseofulvin results in the absorption by keratinized tissues and are
used to treat fungal skin diseases(ringworms).
Ergot is used in the medicine and the vet industry. It is also used to control bleeding
post-child-birth.
LSD – Lysergic acid, is a derivative of ergot and is used in the field of psychiatry.
Consuming fungi called Clavatia prevents cancer of the stomach.
 Cont’d
6. Importance in Agriculture
The fungi plant dynamic is essential in productivity of crops. Fungal activity
in farmlands contributes to the growth of plants by about 70%.
Fungi are important in the process of humus formation as it brings about
the degeneration of the plant and animal matter.
They are successively used in biological control of pests. Plant pests are
used as insecticides to control activities of insects. For example – Empausa
sepulchralis, Cordyceps melonhae. Use of fungal pesticides can reduce
environmental hazards by a great extent.
Fungi are also used in agricultural research. Some species of fungi are used
in the detection of certain elements such as Copper and Arsenic in soil and
in the production of enzymes. For instance, biological and genetic research
on fungi named Neurospora led to the One Gene One Enzyme hypothesis.
The fungi live in a symbiotic relationship with the plant roots known as
mycorrhiza. These are essential to enhance the productivity of farmland.
80-90% of trees could not survive without the fungal partner in the root
system.
7. Importance in Food industry
Some fungi are used in food processing while some are directly consumed. For
example – Mushrooms, which are rich in proteins and minerals and low in fat.
Fungi constitute the basis in the baking and brewing industry.
Alcoholic fermentation: They bring about fermentation of sugar by an enzyme called
zymase producing alcohol which is used to make wine.
Carbon dioxide- a byproduct in the process, is used as dry ice and also in the baking
industry to make the dough (rising and lightening of dough).
Saccharomyces cerevisiae is an important ingredient in bread, a staple food of
humans for several years. It is also known as the baker’s yeast.
Gibberellins:
These are plant hormones produced by the fungus Gibberella fujikuroi which cause a
disease of rice accompanied by abnormal elongation. Gibberellin is used to
accelerate growth of several horticultural crops.
Cheese Industry:
Certain fungi popularly known as the cheese moulds play an important role in the
refining of cheese. They give cheese a characteristic texture and flavour.
Economic Importance of Fungi