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Lesson Overview
Fungi
Lesson Overview
21.4 Fungi
Lesson Overview
Fungi
THINK ABOUT IT
What is the largest organism in this photo? You might think it’s the
tree, but in fact it’s a fungus. The only trace of the fungus is the ring
of mushrooms, but the mushrooms are just the reproductive
structures of a much larger organism. Most of the mass of the fungus
is underground, spanning at least the width of the ring of
mushrooms, and extending more than 2 meters into the ground!
Hundreds of years ago, some cultures believed these rings of
mushrooms marked spots where fairies danced. Today people still
call them fairy rings.
Lesson Overview
Fungi
What Are Fungi?
What are the basic characteristics of fungi?
Lesson Overview
Fungi
What Are Fungi?
What are the basic characteristics of fungi?
Fungi are heterotrophic eukaryotes with cell walls that contain chitin.
Lesson Overview
Fungi
What Are Fungi?
Many fungi grow from the ground, but fungi aren’t plants.
Instead of carrying out photosynthesis, fungi produce enzymes that
digest food outside their bodies. Then they absorb the small molecules
released by the enzymes.
Many fungi feed by absorbing nutrients from decaying matter in the
soil. Others live as parasites, absorbing nutrients from their hosts.
Lesson Overview
Fungi
What Are Fungi?
The cell walls of fungi are composed of chitin, a polymer made of modified
sugars that is also found in the external skeletons of insects.
The presence of chitin is one of several features that show fungi are more
closely related to animals than to plants.
Lesson Overview
Fungi
Structure and Function
Yeasts are tiny fungi that live most of their lives as single cells.
Mushrooms and other fungi, on the other hand, grow much larger. Their
bodies are made up of cells that form long, slender branching filaments
called hyphae.
Lesson Overview
Fungi
Structure and Function
In most fungi, cross walls divide the hyphae into compartments
resembling cells, each containing one or two nuclei. In the cross walls,
there are openings through which cytoplasm and organelles can move.
Lesson Overview
Fungi
Structure and Function
The body of a mushroom is actually the fruiting body, the reproductive
structure of the fungus.
The fruiting body grows from the mycelium, the mass of branching
hyphae below the soil. Clusters of mushrooms are often part of the
same mycelium, which means they are part of the same organism.
Lesson Overview
Fungi
Structure and Function
The mycelium of the soil fungus in a fairy ring has grown so large
that it has used up all of the nutrients near its center.
It grows and produces fruiting bodies—the mushrooms—only at
its edges, where it comes in contact with fresh soil and abundant
nutrients.
Lesson Overview
Fungi
Reproduction
Fungi can reproduce asexually, primarily by releasing spores that are
adapted to travel through air and water.
Breaking off a hypha or budding off a cell can also serve as asexual
reproduction.
Lesson Overview
Fungi
Reproduction
Most fungi can also reproduce sexually. The life cycle of the bread mold
Rhizopus stolonifer is shown.
Lesson Overview
Fungi
Reproduction
Sexual reproduction in fungi often involves two different mating types.
One mating type is called “+” (plus) and the other “–” (minus).
Hyphae of opposite mating types fuse together, bringing + and – nuclei
together in the same cell.
Lesson Overview
Fungi
Reproduction
The + and – nuclei form pairs that divide as the mycelium grows. Many
of the paired nuclei fuse to form diploid zygotes within a zygospore.
Lesson Overview
Fungi
Reproduction
The zygospore germinates and a sporangium emerges.
The sporangium reproduces asexually, releasing haploid spores
produced by meiosis.
Each spore has a different combination of parental genes, and each can
make a new mycelium.
Lesson Overview
Fungi
Diversity of Fungi
More than 100,000 species of fungi are known. Biologists have placed
fungi into several distinct groups.
The major groups of fungi differ from one another in their reproductive
structures.
Lesson Overview
Fungi
Diversity of Fungi
Lesson Overview
Fungi
The Ecology of Fungi
How do fungi affect homeostasis in other organisms and the environment?
Lesson Overview
Fungi
The Ecology of Fungi
How do fungi affect homeostasis in other organisms and the environment?
Fungi are champions of decomposition. Many species help ecosystems
maintain homeostasis by breaking down dead organisms and recycling
essential elements and nutrients.
Lesson Overview
Fungi
The Ecology of Fungi
How do fungi affect homeostasis in other organisms and the environment?
Parasitic fungi can cause serious diseases in plants and animals by
disrupting homeostasis.
Some fungi form mutualistic associations with photosynthetic organisms in
which both partners benefit.
Lesson Overview
Fungi
Decomposition
Many fungi feed by releasing digestive enzymes that break down
leaves, fruit, and other organic material into simple molecules.
These molecules then diffuse into the fungus.
Many organisms remove important trace elements and nutrients
from the soil. Fungi recycle these essential elements and nutrients.
If these materials were not returned, the soil would quickly be
depleted.
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Fungi
Parasitism
Parasitic fungi can cause serious diseases in plants and animals by
disrupting homeostasis.
Lesson Overview
Fungi
Plant Diseases
A number of parasitic fungi cause diseases that threaten food crops.
Corn smut, for example, destroys corn kernels.
Some mildews, which infect a wide variety of plants, are also fungi.
Lesson Overview
Fungi
Animal Diseases
Fungal diseases also affect insects, frogs, and mammals.
For example, the Cordyceps fungus infects grasshoppers in rain
forests in Costa Rica. Microscopic spores become lodged in the
grasshopper, where they germinate and produce enzymes that
slowly penetrate the insect’s external skeleton. The spores multiply
in the insect’s body, digesting all its cells and tissues until the insect
dies.
Hyphae develop, cloaking the decaying exoskeleton in a web of
fungal material. Reproductive structures, which will produce more
spores and spread the infection, then emerge from the
grasshopper’s remains.
Lesson Overview
Fungi
Animal Diseases
Parasitic fungi can also infect humans.
The fungus that causes athlete’s foot forms a mycelium in the outer
layers of the skin, which produces a red, inflamed sore from which the
spores can easily spread from person to person.
The yeast Candida albicans is often responsible for vaginal yeast
infections and for infections of the mouth called thrush.
Lesson Overview
Fungi
Lichens
A lichen is a symbiotic association between a fungus and a
photosynthetic organism. The photosynthetic organism is either a green
alga or a cyanobacterium, or both.
The protective upper surface of a lichen is made up of densely packed
fungal hyphae. Below this are layers of green algae or cyanobacteria
and loosely woven hyphae. The bottom layer contains small projections
that attach the lichen to a rock or tree.
Lesson Overview
Fungi
Lichens
Lichens are extremely resistant to drought and cold. Therefore, they can
grow in places where few other organisms can survive—on dry bare
rock in deserts and on the tops of mountains.
Lichens are able to survive in these harsh environments because the
green algae or cyanobacteria carry out photosynthesis, providing the
fungus with a source of energy, while the fungus provides the green
algae or cyanobacteria with water and minerals.
The densely packed hyphae protect the delicate green cells from
intense sunlight.
Lesson Overview
Fungi
Lichens
Lichens are often the first organisms to enter barren environments,
gradually breaking down the rocks on which they grow. In this way,
lichens help in the early stages of soil formation.
Lichens are also remarkably sensitive to air pollution: They are among
the first organisms to be affected when air quality deteriorates.
Lesson Overview
Fungi
Mycorrhizae
Fungi also form mutualistic relationships with plant roots. These symbiotic
associations of plant roots and fungi are called mycorrhizae.
Researchers estimate that 80 to 90 percent of all plant species form
mycorrhizae with fungi.
The hyphae collect water and minerals and bring them to the roots,
greatly increasing the effective surface area of the root system. In
addition, the fungi release enzymes that free nutrients in the soil.
The plants, in turn, provide the fungi with the products of photosynthesis.
Lesson Overview
Fungi
Mycorrhizae
The presence of mycorrhizae is essential for the growth of many plants.
The seeds of orchids, for example, cannot germinate in the absence of
mycorrhizal fungi. Many trees are unable to survive without fungal
symbionts.
Lesson Overview
Fungi
Mycorrhizae
This graph illustrates the growth rates of three species of trees with and
without mycorrhizae.
Lesson Overview
Fungi
Mycorrhizae
The roots of plants are plugged into mycorrhizal networks that connect
many plants.
In an experiment using isotopes to trace the movement of carbon,
ecologist Suzanne Simard found that mycorrhizal fungi transferred
carbon from paper birch trees growing in the sun to Douglas fir trees
growing in the shade nearby.
As a result, the sun-starved fir trees thrived, basically by being “fed”
carbon from the birches.
Simard’s findings suggest that plants—and their associated fungi—
may be evolving as part of an ecological partnership.