Transcript Chapter 31 Fungi

CHAPTER 31
FUNGI
Introduction
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Fungi are eukaryotes
Nearly all multicellular (yeasts are unicellular)
Distinguished from other kingdoms by:
 Nutrition
 Structural
organization
 Growth
 Reproduction
Absorptive nutrition enables fungi to
live as decomposers and symbionts
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Fungi are heterotrophs that acquire nutrients by
absorption
Secrete hydrolytic enzymes and acids to decompose
complex molecules into simpler ones that can be
absorbed
Specialized into three main types:
Saprobes- absorb nutrients from dead organic material
 Parasitic fungi-absorb nutrients from cells of living hosts;
some are pathogenic
 Mutualistic fungi-absorb nutrients from a host, but
reciprocate to benefit the host
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Extensive surface area and rapid growth
adapt fungi for absorptive nutrition
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Hyphae makes up the
mycelium and visible
structure we recognize as
a mushroom
Except for yeast, hyphae
are organized around
and within food source:
 Composed
of tubular
walls containing chitin
Fungal hyphae may be sepatate or
asepatate
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Hyphae of septate fungi are
divided into cells by cross-walls
called septa
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Large pores allowing ribosomes,
mitochondria, nuclei flow from
cell to cell
Hyphae of aseptate fungi lack
cross walls (coenocytic)
Parasitic fungi have modified
hyphae called haustoria, which
penetrate the host tissue but
remain outside cell membrane
Fungi reproduce by releasing spores that
are produced either sexually or asexually
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Usually unicellular, haploid and of various
shapes/sizes
Asexual reproduction
 reproduce
asexually by mitotic production of haploid
vegetative cells called spores
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Spores are dispersed by wind and water creates
wide distribution of many species of fungi
Sexual reproduction
results in greater diversity
Basic Cycle
Generalized life cycle of fungi
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Sexual Reproduction
 Plasmogamy:
fusion of cytoplasm of two parents
 Heterokaryotic mycelium: contains nuclei from two
parents
 Dikaryotic mycelium: contains nuclei from two parents,
but each cell contain two nuclei
 Karyogamy: fusion of nuclei of two parents
Phylogeny of fungi
Chytrids might provide clues about
fungal origins
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Originally places in Kingdom Protista
Mainly aquatic
Share many characteristics w/ fungi:
 Absorptive
nutrition
 Chitin cell-walls
 Hyphae
 enzymes/ metabolism
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Earliest fungi: evolved from protists and retained
flagella
Zygomycetes
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Characterized by dikaryotic zygosporangia
Mostly terrestrial-live in soil or decaying material
Some from mycorrhizae, mutualistc associations with
plant roots
Hyphae are coenocytic-septa only found in
reproductive cells
Life cycle of zygomycete Rhizopus
stolonifer(common bread mold)
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Under favorable conditions, reproduces asexually:
Sporangia develop at tips of hyphae
 Mitosis produces hundred of haploid spores
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In unfavorable conditions of sexual reproduction occurs:
Mycelia of opposite mating types for gametangia that
contain several haploid nuclei walled off by the septum
 Plasmogamy of gameangia occurs  dikaryotic
zygosporangium  diploid nuclei immediately undergoes
meiosis producing haploid spores
 Zygosporangium germinates sporangium which releases
recombined haploid spores
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Cycle of common bread mold
Ascomycota
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Includes unicellular yeasts and complex multicellular
cup fungi
Hyphae are septate
In asexual reproduction, tips of specialized hyphae
form conidia-chains of haploid asexual spores
In sexual reproduction, haploid mycelia of opposite
mating strains fuse
Life cycle of ascomycete
Basidiomycota: club fungi
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Important decomposers of wood/ plant material
Include:
 Mycorrhiza-
forming mutualists
 Mushroom-forming fungi
 Plant parasites (rusts and smuts)
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Characterized by dikaryotic mycelium that
reproduced sexually by basidiocarps
Life cycle in detail
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Haploid basidiospores grow into short-lived haploid
mycelia: under certain conditions plasmogamy occurs
Resulting dikaryotic mycelium grows forming mycorrhiza
or mushrooms
Mushroom cap supports + protects fills: karyogamy in
the terminal, dikaryotic cells lining the gills produces
diploid basidia
Resulting basidium immediately undergoes meiosis
producing four haploid basidiospores
Asexual reproduction less common than ascomycetes
Molds
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Rapidly growing fungus w/ no sexual stages
May develop into a sexual fungus, producing
zygosporangia, ascocarps, or basidiocarps
Molds w/ no known sexual stage are known as
Deuteromycota or imperfect fungi:
 Penicillium
 Flavor
of blue cheese
Yeasts
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Unicellular: reproduce
 Asexually
by budding
 Sexually by producting asci or basidia
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Saccharomyces cerevisiae is most important
domesticated fungus:
 Baking
+ brewing
 Model organism
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Can cause problems:
 rhodotorula:
shower curtains
 Candida: “thrush”
Lichens
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Symbiosis of algae w/ fungal hyphae
The alga:
 Provides
fungus w/ food
 May fix nitrogen fixation
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Fungus provides good environment for growth:
 Hyphal
mass absorbs minerals and protects algae
 Produces compounds that:
 Shield
algae from sunlight
 Are toxic-prevents predation
Lichen reproduction
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Occurs as a combines unit or independently
Fungi reproduces sexually (usually ascocarps)
Algae reproduces asexually by cell division
Symbiotic units reproduce asexually by:
 Fragmentation
of parent
 Formation of soredia: small clusters of hyphae w/
embedded algae
Mycorrhizae
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Specific, mualistic association of plant roots and
fungi
Fungi increase absorptive surface of roots and
exchange soil minerals
Found in 95% of vascular plants
Necessary for optimal plant growth
Ecological impact of fungi
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ecosys depend on fungi as decomposers +
symbionts: decompose food, wood, and plastic
Some fungi are pathogens (athlete’s foot,
ringworms):
 Plants
particularly susceptible
 Ergot-affects cereal crops: causes gangrene,
hallucinations, and “St. Anthony’s fire”
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Many animals, including humans, eat fungi:
 Truffles
are underground ascocarps