Fungal Diversity PDF

Summary

This document discusses fungal diversity, covering topics like the evolution, classification, and reproduction of fungi. The document also explores the different types of fungi and their roles in various ecosystems, including decomposers, parasites, and mutualists. Key characteristics and traits of fungi are explained.

Full Transcript

Fungal diversity
Mitja Remus-Emsermann
KöLu 12-16 Raum 129
[email protected]
 Fungi

Mycology – study of fungi
Mycologists – scientists who study fungi
Mycoses – diseases caused by fungi
Mycotoxicology – study of fungal toxins and their effects
 Fungi
Fungi and animals are more closely related to each other
than they are to plants or other eukaryotes
Fungi, animals, and their protist relatives form the
opisthokonts clade
 Fungi
DNA evidence suggests that
Animals are most closely related to unicellular
choanoflagellates (aquatic filter-feeders)
Fungi are most closely related to unicellular
Salpingoeca rosetta
nucleariids (amoeba)
This suggests that multicellularity arose separately in
animals and fungi

Nuclearia thermophila
 Fungi
The oldest undisputed fossils of fungi are only about
460 million years old
Fungi are diverse and widespread, >100,000 species of
fungi have been described
They are essential for the well-being of most terrestrial
ecosystems because they break down organic material
and recycle vital nutrients
Despite their diversity, fungi share key traits, most Fossil fungal hyphae
and spores from
importantly the way in which they derive nutrition Ordovician period (~460
million years ago)
 Fungi
Genomic studies have identified chytrids in the genus Rozella as an early
diverging fungal lineage
Rozella and other members of the unicellular group, “cryptomycota” lack
chitin-rich cell walls
Fungi were among the earliest colonizers of land
Fossil evidence indicates fungi formed mutualistic relationships with early
land plants

Rozella allomycis
 Fungi
Genomic analysis indicates genes involved in
mycorrhizal formation, SYM genes, were present
in the common ancestor to land plants
Molecular analyses have helped clarify
evolutionary relationships among fungal groups,
although areas of uncertainty remain
Recent environmental studies estimate fungal
diversity at around 1.5 million species

Bonfante P & Genre A (2010)
Mechanisms underlying beneficial plant–
fungus interactions in mycorrhizal
symbiosis. Nature Communications 1,
e48 doi:10.1038/ncomms1046
 Fungi
Traits common to most fungi
Absorptive nutrition: secrete enzymes and then absorb the broken-down
nutrients
Chemoorganoheterotrophs
Saprophytes
Hyphae: multinucleate cell filaments, which extend and form branches,
generating a mycelium
Cell walls contain chitin
Membranes contain ergosterol
C. Ergosterol
 Fungi
A fungal hyphae expand at the tip
Cytoplasmic expansion is driven by turgor pressure against the chitin cell
wall - the force enables fungi to penetrate tough materials such as wood
Fungal hyphae can extend up to 0.5 centimeter per hour
 Unicellular fungi
Unicellular fungi are called yeasts
Reproduce by budding
Some yeasts are asexual
Others can undergo sexual alternation of
generations

Saccharomyces cerevisiae
Baker’s and brewer’s yeast

Candida albicans
An opportunistic pathogen
Can grow also as mycelia
 Taxonomy of fungi
Five major fungal groups
Chytridiomycota
Zygomycota
Glomeromycota
Ascomycota
Basidiomycota
 Classification of fungi
Basidiomycota and Ascomycota are
dikarya
two parental nuclei are initially paired
nuclei fuse, undergo meiosis, produce
haploid progeny
Zygomycota and Chytridiomycota are
paraphyletic
taxonomic group includes some
descendants of a single common
ancestor
Classification of fungi
Classification of fungi
 Terminology & lifestyle
The most common body structures are
multicellular filaments (hyphae)
single cells (yeasts)
Some species grow as either filaments or yeasts,
others grow as both
Fungi exhibit diverse lifestyles
Decomposers (saprophytes)
Parasites
Mutualists
 Fungal distribution and importance
Primarily terrestrial but few aquatic

Puccinia graminis
global from polar to tropical
Many are pathogenic in plants or animals
Some form associations
lichens Lichen

associations with algae or
cyanobacteria
mycorrhizae
associations with plant roots
Ectomycorrhizae on pine root
 Fungal structure
Cell walls composed of chitin polysaccharide
Single-celled microscopic fungi = yeasts
Fungi consist of mycelia, networks of branched
hyphae adapted for absorption
Body/vegetative structure of a fungus = thallus
(pl. thalli)
multicellular fungi are called moulds
thallus consists of long, branched hyphae
filaments tangled into a mycelium mass
 Fungal structure
Most fungi have hyphae divided into cells by septa, with pores allowing
cell-to-cell movement of organelles
Coenocytic fungi lack septa and have a continuous cytoplasmic mass with
hundreds or thousands of nuclei
Some unique fungi have specialized hyphae called haustoria that allow
them to penetrate the tissues of their host
 Fungal reproduction
Fungi propagate themselves by producing vast numbers of spores, either
sexually or asexually
Fungi can produce spores from different types of life cycles
 Fungal reproduction - sexual
Fungal nuclei are normally
haploid = 1 chromosome different hypha attracted

the exception of transient by pheromones fuse

diploid stages formed during
the sexual life cycles
Sexual reproduction requires
the fusion of hyphae from
different mating types
Fungi use sexual signaling
molecules called pheromones
to communicate their mating
type
 Fungal reproduction - sexual
Plasmogamy is the union of
cytoplasm from two parent although the cells fuse
the nuclei don't
mycelia
In most fungi, the haploid
nuclei from each parent do not
fuse right away; they coexist in
the mycelium, called a
heterokaryon
In some fungi, the haploid
nuclei pair in couples per cell;
such a mycelium is called
dikaryotic
 Fungal reproduction - sexual
Hours, days, or even centuries
may pass before the occurrence
of karyogamy, nuclear fusion
During karyogamy, the haploid
nuclei fuse, producing diploid
cells
The diploid phase is short-lived
and undergoes meiosis,
producing haploid spores
The paired processes of
karyogamy and meiosis
introduce genetic variation
 Fungal reproduction - sexual
Homothallic: Sexually-compatible gametes are formed on
the same mycelium (self-fertilizing)
Heterothallic: Require outcrossing between different, yet
compatible mycelia Aspergillus nidulans can undergo three
reproduction cycles
1) asexual production of conidia
spores
2) homothallic sexual reproduction by
selfing, generating fruiting bodies
(called cleistothecia) containing
ascospores
3) parasexual reproduction where
heterohyphae fuse to form a
heterodikaryon, followed by
nuclear fusion to generate diploid
hyphae, in which random
chromosome loss occurs to restore
the haploid chromosome number.

Nature Reviews Genetics 3, 683-697 (September 2002) | doi:10.1038/nrg889
 Fungal reproduction - asexual
Parent cell undergoes mitosis to form daughter cells
Mitosis in vegetative cells may be concurrent with
budding to produce a daughter cell
Moulds produce haploid spores by mitosis and form
visible mycelia
 Fungal reproduction - asexual
Other fungi that can reproduce
asexually are yeasts, which are
single cells
Instead of producing spores,
yeasts reproduce asexually by
simple cell division and the
pinching of “bud cells” from a
parent cell
Some fungi can grow as yeasts
and as filamentous mycelia
(dimorphic fungi)
Candida spp
Histoplasma capsulatum
 Fungal reproduction - asexual

Many moulds and yeasts have no known sexual stage
Mycologists have traditionally called these deuteromycetes
These fungi are reclassified once their sexual stage is discovered
Mycologists can use genomic techniques to classify fungi
 Chytrids
Chytrids (phylum Chytridiomycota) are found in terrestrial,
freshwater, and marine habitats including hydrothermal vents
They can be decomposers, parasites, or mutualists
Molecular evidence supports the hypothesis that chytrids diverged
early in fungal evolution
Chytrids are unique among fungi in having flagellated spores, called
zoospores
 Chytrids
Produce a zoospore with single, posterior, whiplash
flagellum
most primitive form of spore dispersal
flagella lost in higher forms
Asexual and sexual reproduction
Many members degrade cellulose and keratin
 Chytrids
The chytrid Batrachochytrium
dendrobatidis is likely the
cause of the recent decline in
amphibians worldwide
 Zygomycetes
The zygomycetes (phylum Zygomycota) exhibit great diversity of life
histories
Include fast-growing moulds, parasites, and commensal symbionts
Some of industrial importance
foods, antibiotics and other drugs, meat tenderizer, and food coloring
 Zygomycetes
Usually reproduce asexually by
spores that develop at the tips of
aerial hyphae
Hyphae are coenocytic
Generate non-motile spores
Spore-bearing organ is called
the sporangium
 Zygomycetes
Sexual reproduction occurs when
environmental conditions are not
favourable
requires compatible opposite mating
types
hormone production causes hyphae to
produce gametes
gametes fuse, forming a zygote
zygote becomes zygospore

Zygomycete fungi include
Rhizopus: a bread mould
Mucor: a soil mould
 Zygomycetes
The zygomycetes are named for their
sexually produced zygosporangia
Pilobolus sp.
Zygosporangia are the site of karyogamy
and then meiosis
Zygosporangia, which are resistant to
freezing and drying, can survive
unfavorable conditions
Some zygomycetes, such as Pilobolus,
can actually “aim” and shoot their
sporangia toward bright light
 Glomeromycetes
Arbuscular mycorrhizae penetrate root cell wall
Mycorrhizal fungi colonize soils by the dispersal of haploid cells called
spores
Mutualistic relationship
fungus helps protect host from stress, delivers soil nutrients
(phosphate ions and minerals) to the plant; plant provides
carbohydrates to fungus
 Glomeromycetes
Arbuscular mycorrhizae fungi extend hyphae through the
cell walls of root cells and into tubes formed by
invagination of the root cell membrane

Glomus mosseae
Arbuscular mycorrhizae

root
mycelium
 Glomeromycetes
The hyphae invade intracellular space
(between cell wall and cell membrane)
They reproduce asexually through blastic
(budding or swelling) development of the
hyphal tip to produce large spores
(glomerospores; sometimes reach to 800
Glomus diaphanum
µm) inside or outside of roots Morton & Walker. DAOM 22702

Sexual reproduction is unknown

Gomus proliferum
Dalpé and Declerck DAOM 226389
 Ascomycetes
Ascomycetes (phylum Ascomycota) live in marine, freshwater, and terrestrial
habitats
Ascomycetes produce sexual spores in saclike asci contained in fruiting
bodies called ascocarps
Ascomycetes are commonly called sac fungi
Ascomycetes vary in size and complexity from unicellular yeasts to elaborate
cup fungi and morels

Tuber Morchella Galiella
melanosporum esculenta rufa
 Ascomycetes
Ascomycete fungi include
Neurospora - a bread mold
Morels and truffles - culinary delicacies
Aspergillus - forms asexual fruiting
bodies called conidiophores
 Ascomycetes
Ascomycetes include plant
pathogens, decomposers, and
symbionts
Ascomycetes reproduce asexually
by enormous numbers of asexual
spores called conidia
Conidia are not formed inside
sporangia, they are produced
asexually at the tips of specialised
hyphae called conidiophores
Neurospora crassa, a bread mould,
is a model organism with a well-
studied genome
Penicillium sp.
 Ascomycetes
Penicillium roqueforti found in Blue
cheese and Roquefort
Penicillium camemberti found in
Camembert, Brie
Penicillium nalgiovense is used to
improve the taste of sausages and
hams, and to prevent colonization by
other moulds and bacteria

Penicillium chrysogenum - penicillin
 Ascomycetes
Aspergillus fumigatus
ubiquitous environmental
allergies and significant
pathogen

Aspergillus oryzae
production of fermented
foods
Important in biotechnology
 Ascomycetes
Cordyceps spp.
Endoparasitoids, parasitic mainly on insects and other
arthropods
 Ascomycetes
Ergot is caused Claviceps purpurea and produces toxins
More than 40,000 people died from an epidemic of
ergotism during the middle ages
Ergotism is characterised by gangrene, nervous
spasms, burning sensations, hallucinations, and
temporary insanity
Ergots contain lysergic acid, the raw material for LSD

Rye Wheat
 Ascomycetes - yeast
Alternates between haploid and diploid
in nutrient rich, mitosis and budding
occurs at non-scarred regions
stops after entire mother cell is
scarred
In nutrient poor, meiosis and haploid
ascus containing ascospores formed
haploid cells of opposite mating
types fuse
tightly regulated by pheromones
 Basidiomycetes
Phylum Basidiomycota
Some basidiomycetes form mycorrhizae, and others are plant parasites
The phylum is defined by a club-like structure called a basidium, a transient
diploid stage in the life cycle
The basidiomycetes are also called club fungi
Many basidiomycetes are decomposers of wood
Basidiomycetes
 Basidiomycetes
Basidiomycete fungi
Amanita phalloides makes
a very poisonous toxin
α-amanitin inhibits RNA
polymerase II

Agaricus bisporus
(Portobello mushrooms)
Prized culinary delight
 Basidiomycetes
The life cycle of a basidiomycete usually includes a long-
lived dikaryotic mycelium
In response to environmental stimuli, the mycelium
reproduces sexually by producing elaborate fruiting
bodies called basidiocarps
Mushrooms are examples of basidiocarps
The numerous basidia in a basidiocarp are sources of
sexual spores called basidiospores
 Basidiomycetes
The underground secondary mycelia of some mushrooms
form mycorrhizae with tree roots
 Basidiomycetes
Decomposers
Edible, non-edible mushrooms and hallucinogenic

Amethyst deceiver Cantharellus cibarius Psilocybe semilanceata
 Basidiomycetes
Corn smut is a plant disease caused by the pathogenic
fungus Ustilago maydis
forms galls on all above-ground parts of maize
 Fungi – plant mutualism
Mycorrhizae are enormously important in natural ecosystems and agriculture
Plants harbor harmless symbiotic endophytes, fungi that live inside leaves or
other plant parts
Endophytes make toxins that deter herbivores and defend against pathogens
Most endophytes are ascomycetes
 Fungi – animal mutualism
Some fungi share their digestive services with animals
These fungi help break down plant material in the guts of cows and other
grazing mammals
Many species of ants use the digestive power of fungi by raising them in
“farms”

Leucoagaricus gongylophorus
 Fungi as decomposers
Fungi are efficient decomposers of organic material
including cellulose and lignin
They perform essential recycling of chemical elements
between the living and nonliving world

Pleurotus ostreatus Stropharia semiglobata
 Lichens
A lichen is a symbiotic association
between a photosynthetic
microorganism and a fungus
Millions of photosynthetic cells are
held in a mass of fungal hyphae
The photosynthetic component is
green algae or cyanobacteria
The fungal component is most often
an ascomycete
 Lichens
Algae or cyanobacteria occupy an inner layer below the
lichen surface
algae provide carbon compounds
cyanobacteria also provide organic nitrogen
fungi provide the environment for growth
Fungi of lichens can reproduce sexually and asexually
 Fungi as pathogens

The general term for a fungal infection in animals
is mycosis
Ringworm and athlete’s foot are examples of
human mycoses
Systemic mycoses spread through the body
For example, coccidioidomycosis produces
tuberculosis-like symptoms
Some mycoses are opportunistic
For example, Candida albicans, which causes
yeast infections
 Acellular agents
Mitja Remus-Emsermann
KöLu 12-16 Raum 129
[email protected]
 Acellular agents

Viruses – protein and nucleic acid
Viroids – only RNA
Satellites – only nucleic acids
Prions – proteins only
 Importance of viruses
Major cause of disease
also importance as a new source of therapy
new viruses are emerging
Important members of aquatic world
move organic matter from particulate to dissolved
Important in evolution
transfer genes between bacteria, others
Important model systems in molecular biology
 What is a virus?
A virus is a acellular entity that must infect a host cell, where it replicates
It typically subverts the cell’s machinery and directs it to produce viral
particles
The virus particle, or virion, consists of nucleic acid (DNA or RNA)
contained within a protective protein capsid
 Properties of viruses
Virion
complete virus particle
consists of >1 molecule of DNA or RNA enclosed in coat of protein
may have additional layers
cannot reproduce independent of living cells nor carry out cell division
but can exist extracellularly
 Host of viruses
Viruses are ubiquitous in all environments
Viruses are part of our daily lives
Respiratory pathogens such as rhinovirus (the common cold)
and Epstein-Barr virus (infectious mononucleosis)
Sexually transmitted viruses such as herpes simplex virus (HSV)
and papillomavirus (e.g. genital warts)
Different viruses infect every group of organisms
Each species of virus infects a particular group of host species, or
host range
Bacterial viruses called bacteriophages (phages)
 Virus structure
Virion size range is ~10–400 nm in diameter and most viruses can only
be viewed with an electron microscope
All virions contain a nucleocapsid which is composed of nucleic acid
(DNA or RNA) and a protein coat (capsid)
some viruses consist only of a nucleocapsid, others have additional
components
Some viruses have membrane envelopes
Virus morphology
 Virus capsids
Large macromolecular structures which serve as protein coat of virus
Protect viral genetic material and aids in its transfer between host cells
Made of protein subunits called capsomer / protomers
Capsids can be
Helical
Icosahedral
Asymmetric and complex
 Helical capsids
Shaped like hollow tubes with protein walls
Capsomer / protomers self assemble
Size of capsid is a function of nucleic acid
 Icosahedral capsids
Are polyhedral with 20 identical triangular faces
Have a structure that exhibits rotational symmetry
 Capsids of complex symmetry
In some icosahedral viruses, the capsid is enclosed in an envelope, formed
from the host cell’s membrane.
The envelope contains glycoprotein spikes, which are encoded by the
virus
Between the envelope and capsid, tegument proteins may be found
 Enveloped viruses
Enveloped viruses usually have flexible membranous outer layer
Animal virus envelopes (lipids and carbohydrates) usually arise from host
cell plasma or nuclear membranes
 Viral genomes
Viral genomes can be:
DNA or RNA
Single- or double-stranded (e.g ssDNA or dsDNA)
Linear or circular
Include genes encoding viral proteins
Capsid
Envelope proteins (if need be)
Any polymerase not found in host cell
 Classification of viruses
The International Committee on Taxonomy of Viruses
(ICTV) has devised a classification system, based on
several criteria:
Genome composition and structure
Capsid symmetry
Envelope
Size of the virion
Host range
Baltimore classification
 Animal viruses - tissue tropism
Animal viruses bind specific receptor proteins on their
host cell
Receptors determine the viral tropism
Ebola virus exhibits broad tropism, infecting many
kinds of host tissues
Papillomavirus shows tropism for only epithelial
tissues
Most animal viruses enter host as virions
Internalised virions undergo uncoating, where the
genome is released from its capsid
Can occur in several different ways
 Virus replication
All animal viruses make proteins with host ribosomes
Translation occurs in the cytoplasm
Assembly of new virions
Capsid and genome
May occur in the cytoplasm or nucleus
Envelope proteins are inserted into a membrane
Cell membrane or organelle membrane
Release of progeny viruses from host cell
Lysis of cell
Budding
 Eukaryotic viruses

Cytocidal infection results
in cell death through lysis
Persistent infections may
last years
Cytopathic effects
degenerative changes
abnormalities
Transformation to
malignant (cancer) cell
 Viruses and cancer
Oncogenic viruses transform the host cell to become
cancerous
Mechanisms of oncogenesis include:
Insertion of an oncogene into the host genome
Integration of the entire viral genome
Expression of viral proteins that interfere with host cell
cycle regulation
 Plant viruses
Entry of plant viruses into host cells usually requires
mechanical transmission
Most plant viruses enter by one of three routes:
Contact with damaged tissues
Transmission by an animal vector
Transmission through seed
 Plant viruses
Within a plant, the thick cell walls prevent a lytic burst or
budding out of virions
Instead, plant viruses are transmitted to uninfected cells
by plasmodesmata
Membrane channels that connect adjacent plant cells
Inner channel connects the ER
 Animal and plant host defences
Since viruses are ubiquitous, a wide range of defence
mechanisms have evolved in animals and plants
Genetic resistance
Hosts continually experience mutations
Immune system
“Innate immunity”—interferons
“Adaptive immunity”—antibodies
RNA interference (RNAi)
Widespread among eukaryotes and archaea
 Bacteriophages
Virulent phage
multiplies immediately upon entry
lyses bacterial host cell
Temperate phages two reproductive options:
reproduce lytically as virulent phages do
remain within host cell without destroying it
many temperate phages integrate their genome into
host genome (becoming a ‘prophage’ in a ‘lysogenic
bacterium’) in a relationship called lysogeny
Bacteriophages
 Bacteriophages - lysogeny
Temperate phage changes phenotype of its host
bacteria become immune to superinfection
phage may express pathogenic toxin or enzyme
Lysogeny has advantages for the virus
phage remains viable but may not replicate
Under appropriate conditions infected bacteria will lyse
and release phage particles
occurs when conditions in the cell cause the prophage
to initiate synthesis of new phage particles, a process
called induction
An evolutionary arms race
 Satellites
Infectious nucleic acids (DNA or RNA)
Satellite viruses encode their own capsid proteins
when helped by a helper virus
Satellite RNAs/DNAs do NOT encode their own capsid
proteins
Encode one or more gene products
Require a helper virus for replication
human hepatitis D virus is satellite
Requires human hepatitis B virus
 Viroids
Infectious agents composed of closed, circular ssRNAs
do not encode gene products
Requires host cell DNA-dependent RNA polymerase to
replicate
Cause plant diseases
Prions - Proteinaceous infectious particles

Cause a variety of degenerative diseases in humans and
animals
Scrapie in sheep
Bovine spongiform encephalopathy (BSE) or mad cow
disease
Creutzfeldt-Jakob disease (CJD) and variant CJD
(vCJD) in humans
Kuru in humans
 Viral ecology
Viruses exist naturally within host organisms in complex
ecosystems
Their persistence is significant for human health and
for agricultural plants and animals
Viral ecologists consider viruses as living entities, playing
roles comparable to those of cellular organisms
Example: “predator” or “parasite”
Some viruses interact positively with hosts, by
expressing host genes and by protecting hosts from
other organisms
 Emergence of viral pathogens
Certain human-infecting viruses are well known to persist in the wild, such as
rabies virus and West Nile virus.
Their persistence requires a broad host range
But how does a seemingly “new” virus emerge to sicken humans?
As a result of human consumption of wildlife
“SARS” coronavirus