1. The Kingdom Fungi
These morels are a type of fungus prized by many people for their distinctive flavor
Unlike the violets, fungi are not plants and do not produce their own food

2. The Kingdom Fungi

3. The Kingdom Fungi
In spring, if you know where to look, you can find one of the most prized of all foods—the common morel—growing wild in woodlands throughout the United States
Its ridged cap is often camouflaged by dead leaves that collect in abandoned orchards or underneath old oaks or tulip poplars
Some morels grow alone, but others grow in groups
They appear suddenly, often overnight, and live for only a few days
What are these mysterious organisms?
How do they grow so quickly?

4. KINGDOM FUNGI Diverse group of over 65,000 species
Most fungi are saprophytic or parasitic, and a few are predatory
Saprophyte:
Is an organism that feeds on dead organic matter
Recycling the nutrients
Referred to as decomposers
Without decomposers, nutrients would not be reused and life could not continue on earth
Parasite:
Derives its nutrients from a living host organism at the host’s expense
Cause many plant and animal diseases
Predatory:
Captures prey for food
Example: Pleurotus ostreatus capture roundworms

5. What Are Fungi? Like mushrooms and molds, morels are fungi
The way in which many fungi grow from the ground once led scientists to classify them as nonphotosynthetic plants
But they aren't plants at all
In fact, fungi are very different from plants

6. What Are Fungi? Fungi are eukaryotic heterotrophs that have cell walls
The cell walls of fungi are made up of chitin, a complex carbohydrate that is also found in the external skeletons of insects
Recall that heterotrophs depend on other organisms for food
Unlike animals, fungi do not ingest their food
Instead, they digest food outside of their bodies and then absorb it
Many fungi feed by absorbing nutrients from decaying matter in the soil
Others live as parasites, absorbing nutrients from the bodies of their hosts

7. FUNGAL EVOLUTION Precambrian fossils about 900 million years old
Late Carboniferous period, fossils indicate that all modern divisions of fungi had evolved
Most are terrestrial
Indicates adaptive radiation shortly after plants and animals colonized the land
Like all eukaryotes, arose from prokaryotes
Arose from other heterotrophs
Present theory is that they evolved from red algae

8. Structure and Function of Fungi
Except for yeasts, all fungi are multicellular
Multicellular fungi are composed of thin filaments called hyphae (singular: hypha)
Each hypha is only one cell thick
In some fungi, cross walls divide the hyphae into cells containing one or two nuclei
In the cross walls, there are tiny openings through which the cytoplasm and nuclei can move
Other hyphae lack cross walls and contain many nuclei

9. CHARACTERISTICS Hypha: vegetative filament of the fungus
Types:
Septate:
Filaments with internal cross walls (septum)
Individual cells have nuclei
Coenocytic:
Filaments without internal cross walls (septum)
Filament contains many nuclei that move through the cytoplasm
Grows at the tip where new membrane material is added by the action of Golgi bodies
A mat of interwoven hyphae is called mycelium
Cell wall composed of chitin (not cellulose)
Complex polysaccharide also found in the exoskeleton of insects and other invertebrates
Store food as glycogen (like animals)
Reproduce asexually (spores)(fragmentation) and sexually (gametes)
Heterokaryotic hypha: genetically different nuclei coexist within a hypha
Homokaryotic hypha: genetically similar nuclei coexist within a hypha

10. STRUCTURE OF FUNGI

11. Structure of Two Types of Hyphae
Fungi are eukaryotes that have cell walls made of chitin
Most fungi are made up of filaments called hyphae
In some fungi, the hyphae are divided by cross walls
These cells may contain one or two nuclei
In other fungi, the hyphae lack cross walls and contain many nuclei

12. Structure of Two Types of Hyphae

13. HYPHAE TYPES

14. STRUCTURE OF FUNGI

15. Fungus Structure 
The bodies of multicellular fungi are composed of many hyphae tangled together into a thick mass called a mycelium
The mycelium (plural: mycelia) is well suited to absorb food because it permits a large surface area to come in contact with the food source through which it grows

16. Structure of a Multicellular Fungus
The body of a mushroom is part of a mycelium formed from many tangled hyphae
The major portion of the mycelium grows below ground
The visible portion of the mycelium is the reproductive structure, or fruiting body, of the mushroom

17. Structure of a Multicellular Fungus

18. Fungus Structure
What you recognize as a mushroom is actually the fruiting body of a fungus
A fruiting body is a reproductive structure growing from the mycelium in the soil beneath it
Clusters of mushrooms are often part of the same mycelium, which means that they are part of the same organism

19. Fairy Rings Some mycelia can live for many years
As time goes by, soil nutrients near the center of the mycelium become depleted
As a result, new mushrooms sprout only at the edges of the mycelium, producing a ring
People once thought fairies dancing in circles during warm nights produced these rings, so they were called “fairy rings”
Over many years, fairy rings can become enormous—from 10 to 30 meters in diameter

20. Reproduction in Fungi Most fungi reproduce both asexually and sexually
Asexual reproduction takes place when cells or hyphae break off from a fungus and begin to grow on their own
Some fungi also produce spores, which can scatter and grow into new organisms
Recall that a spore is a reproductive cell that is capable of growing into a new organism by mitosis alone
In some fungi, spores are produced in structures called sporangia (singular: sporangium)
Sporangia are found at the tips of specialized hyphae called sporangiophores

21. Reproduction in Fungi
Sexual reproduction in fungi usually involves two different mating types
Because gametes of both mating types are about the same size, they are not called male and female
Rather, one mating type is called “+” (plus) and the other “−” (minus)

22. Reproduction in Fungi
When hyphae of opposite mating types meet, they start the process of sexual reproduction by fusing, bringing plus and minus nuclei together in the same cell
After a period of growth and development, these nuclei form a diploid zygote nucleus
In most fungi, the diploid zygote then enters meiosis, completing the sexual phase of its life cycle by producing haploid spores
Like the spores produced asexually, these spores are also capable of growing, by repeated rounds of mitosis, into new organisms

23. How Fungi Spread Fungal spores are found in almost every environment
This is why molds seem to spring up in any location that has the right combination of moisture and food
Many fungi produce dry, almost weightless spores
These spores scatter easily in the wind
On a clear day, a few liters of fresh air may contain hundreds of spores from many species of fungi

24. How Fungi Spread
If these spores are to germinate, they must land in a favorable environment
There must be the proper combination of temperature, moisture, and food so that the spores can grow
Even under the best of circumstances, the probability that a spore will produce a mature organism can be less than one in a billion

25. How Fungi Spread
Other fungi are specialized to lure animals, which disperse fungal spores over long distances
Stinkhorns smell like rotting meat, which attracts flies
When they land on the stinkhorn, the flies ingest the sticky, smelly fluid on the surface of the fungus
The spore-containing fluid will pass unharmed out of the flies' digestive systems, depositing spores over many kilometers

26. FUNGI CLASSIFICATION Four Divisions:
Based primarily on the structure of hyphae or on the type of reproduction

27. Classification of Fungi
The kingdom Fungi has over 100,000 species
Fungi are classified according to their structure and method of reproduction
The methods by which fungi reproduce are unlike those of any other kingdom
The four main groups of fungi are:
Common molds (Zygomycota)
Sac fungi (Ascomycota)
Club fungi (Basidiomycota)
Imperfect fungi (Deuteromycota)

28. CLASSIFICATION OF FUNGI

29. The Common Molds
The familiar molds that grow on meat, cheese, and bread are members of the phylum Zygomycota, also called zygomycetes
Zygomycetes have life cycles that include a zygospore
A zygospore is a resting spore that contains zygotes formed during the sexual phase of the mold's life cycle
The hyphae of zygomycetes generally lack cross walls, although the cells of their reproductive structures do have cross walls

30. DIVISION ZYGOMYCOTA Approximately 600 species
Mostly terrestrial organisms
Commonly found in soil and dung
Coenocytic hyphae
Example: Rhizopus Stolonifer
Bread mold
Three different types of hyphae:
Rhizoids:
Anchoring hyphae that penetrate the bread
Produce digestive enzymes, and absorb nutrients
Stolons:
Hyphae that grow across the surface of the bread
Sporangiophores:
Upright hyphae that produce sporangia at their tips which produce spores

31. Structure and Function of Bread Mold
Black bread mold, Rhizopus stolonifer, is a familiar zygomycete
Expose preservative-free bread to dust, and you can grow the mold
Keep the bread warm and moist in a covered jar, and in a few days dark fuzz will appear
With a hand lens, you can see delicate hyphae on moldy bread
There are two different kinds of hyphae:
The rootlike hyphae that penetrate the bread's surface are rhizoids
Rhizoids anchor the fungus to the bread, release digestive enzymes, and absorb digested organic material
The stemlike hyphae that run along the surface of the bread are stolons
The hyphae that push up into the air are the sporangiophores, which form sporangia at their tips
A single sporangium may contain up to 40,000 spores

32. Life Cycle of Molds 
The life cycle of black bread mold is shown in the figure
Its sexual phase begins when hyphae from different mating types fuse to produce gamete-forming structures known as gametangia ( singular: gametangium)
Haploid (N) gametes produced in the gametangia fuse with gametes of the opposite mating type to form diploid (2N) zygotes
These zygotes develop into thick-walled zygospores, which may remain dormant for months
When conditions become favorable, the zygospore germinates, then undergoes meiosis, and new haploid spores are released
The significance of this sexual process—zygote formation followed by meiosis—is that it produces new combinations of genetic information that may help the organism meet changing environmental conditions

33. ZYGOMYCOTA RHIZOPUS STOLONIFER

34. Life Cycle of a Black Bread Mold
Zygomycetes have life cycles that include a zygospore
During sexual reproduction in the bread mold Rhizopus stolonifer, hyphae from two different mating types form gametangia
The gametangia fuse, and zygotes form within zygospore
The zygospore develops a thick wall and can remain dormant for long periods
The zygospore eventually germinates, and a sporangium emerges
The sporangium reproduces asexually by releasing haploid spores produced by meiosis

35. Life Cycle of a Black Bread Mold

36. DIVISION ZYGOMYCOTA ASEXUAL REPRODUCTION
Hormonal action causes upright sporangiophores to form
Sporangia form at the tips of sporangiophores producing spores (sporangiospores) that are dispersed by the wind

37. SEXUAL AND ASEXUAL REPRODUCTION OF ZYGOMYCOTA

38. ZYGOMYCOTA LIFE CYCLE

39. DIVISION ZYGOMYCOTA SEXUAL REPRODUCTION
Called Conjugation
Two filaments line up next to each other
Hyphae of two mating strains come close together
Each hyphae encloses haploid (1N) nuclei
Hormones cause short branches to form on each hypha and grow outward until they touch
Septa form near the tip of each branch
Resulting cell is a gametangium (1N) that contains several nuclei
Gametangia fuse; then nuclei fuse in pairs (2N)
Each pair contains one nucleus from each mating strain (2N)
Zygote contains many diploid (2N) nuclei
Wall surrounding the zygote (2N) thickens forming a protective, temporary structure called a zygospore (2N)
Meiosis occurs when the zygospore germinates forming new hyphae (1N)

40. SEXUAL AND ASEXUAL REPRODUCTION OF ZYGOMYCOTA

41. ZYGOMYCOTA LIFE CYCLE

42. ZYGOMYCOTA SEXUAL REPRODUCTION CONJUGATION

43. ZYGOTE

44. DIVISION ZYGOMYCOTA ASEXUAL/SEXUAL REPRODUCTION
Provide adaptive advantages
Asexual Reproduction:
During periods when the environment is favorable
Rapid formation of spores ensures the quick spread of the species
Sexual Reproduction:
In periods of environmental stress
Ensures genetic recombination before the hyphae die

45. The Sac Fungi
Sac fungi, also known as ascomycetes, belong to the phylum Ascomycota
The phylum Ascomycota is named for the ascus, a reproductive structure that contains spores
There are more than 30,000 species of ascomycetes, making it the largest phylum of the kingdom Fungi
Some ascomycetes, such as the cup fungi, are large enough to be visible when they grow above the ground
Others, such as yeasts, are microscopic

46. DIVISION ASCOMYCOTA Sac fungi Approximately 30,000 species
Largest Division of Fungi
Live in a variety of habitats, including freshwater and saltwater
Morels, powdery mildews, yeast, and cup fungi

47. ASCOMYCETE EDIBLE MOREL

48. Life Cycle of Sac Fungi 
The life cycle of an ascomycete usually includes both asexual and sexual reproduction
The life cycle of a cup fungus is shown in the figure at right

49. Life Cycle of an Ascomycete
The life cycle of ascomycetes includes both asexual and sexual reproduction
During asexual reproduction, spores called conidia are formed at the tips of specialized hyphae called conidiophores
During sexual reproduction, hyphae of two mating types fuse to form hyphae with two haploid (monoploid) nuclei (N + N)
The N + N hyphae then form a fruiting body, which eventually releases ascospores
Ascomycetes are named for the ascus, the reproductive structure that contains ascospores

50. Life Cycle of an Ascomycete

51. Life Cycle of Sac Fungi 
In asexual reproduction, tiny spores called conidia (singular: conidium) are formed at the tips of specialized hyphae called conidiophores
These spores get their name from the Greek word konis, which means “dust”
If a conidium lands in a suitable environment, it grows into a haploid mycelium

52. Life Cycle of Sac Fungi 
Sexual reproduction occurs when the haploid hyphae of two different mating types (+ and −) grow close together
The N + N hyphae then produce a fruiting body in which sexual reproduction continues
Gametangia from the two mating types fuse, but the haploid (N) nuclei do not fuse
Instead, this fusion produces hyphae that contain haploid nuclei from each of the mating types (N + N)

53. Life Cycle of Sac Fungi 
The ascus (plural: asci) forms within the fruiting body
Within the ascus, two nuclei of different mating types fuse to form a diploid zygote (2N)
The zygote soon divides by meiosis, producing four haploid cells
In most ascomycetes, meiosis is followed by a cycle of mitosis, so that eight cells known as ascospores are produced
In a favorable environment, an ascospore can germinate and grow into a haploid mycelium

54. DIVISION ASCOMYCOTA Sexual Reproduction:
Hyphae of the Ascogonium (female gametangium) fuses with the Antheridium (male gametangium)
Gametangia fuse, and male nuclei move into the ascogonium
Male and female nuclei pair but do not fuse
Cell divide forming heterokaryotic hyphae that intertwine forming an ascocarp
Reproductive body of an ascomycete
Sacs called asci form on the surface
Each ascus encloses two nuclei
Nuclei fuse
Diploid nucleus undergoes meiosis producing four haploid nuclei followed by a mitotic division resulting in 8 haploid ascospores
Ascus ruptures releasing ascospores into the air
Ascospores germinate into new hyphae on the ground

55. ASCOMYCOTA Asexual Reproduction: Produces spores called conidium
Conidia form on the ends of specialized branches called conidiophores

56. ASCOMYCETE REPRODUCTION

57. ASCOMYCOTA LIFE CYCLE

58. Yeasts Yeasts are unicellular fungi
The yeasts used by humans for baking and brewing are classified as ascomycetes because they form asci with ascospores during the sexual phase of their life cycle

59. Yeasts
You might think of yeast as a lifeless, dry powder that is used to make bread
Actually, the dry granules contain ascospores, which become active in a moist environment
To see this for yourself, add a spoonful of dry yeast to half a cup of warm water that contains some sugar
In about 20 minutes, when you examine a drop of this mixture under a microscope, you will be able to see cell division in the rapidly growing yeast cells
The process of asexual reproduction you are observing is called budding

60. Yeasts
The common yeasts used for baking and brewing are members of the genus Saccharomyces, which means “sugar fungi”
These yeasts are grown in a rich nutrient mixture containing very little oxygen
Prior to baking, the nutrient mixture is a mound of thick dough
Lacking oxygen, the yeasts within the mixture use the process of alcoholic fermentation to obtain energy
The byproducts of alcoholic fermentation are carbon dioxide and alcohol
The carbon dioxide gas makes beverages bubble and bread rise (by producing bubbles within the dough)
The alcohol in bread dough evaporates during baking
In brewing, alcohol remains in the resulting alcoholic beverages

61. DIVISION ASCOMYCOTA Yeast: unicellular Asexual Reproduction: budding
Sexual Reproduction: formation of a zygote by the fusion of two ascospores
600 species
Saccharomyces cerevisiae used in brewing processes
Ability to breakdown carbohydrates forming ethyl alcohol and carbon dioxide gas makes yeast useful in industry
Baking and brewing

62. The Club Fungi
The phylum Basidiomycota, or club fungi, gets its name from a specialized reproductive structure that resembles a club
The spore-bearing structure is called the basidium (plural: basidia)
Basidia are found on the gills that grow on the underside of mushroom caps

63. DIVISION BASIDIOMYCOTA
Approximately 25,000 species
Called club fungi
Examples: mushrooms, toadstools, puffballs, rusts, and smuts

64. DIVISION BASIDIOMYCOTA
Basidiocarp: mushroom
Reproductive body of a basidiomycete
Formed when underground hyphae grow upward and intertwine
Cap (fruiting body) is attached to a stalk (stem)
Underside are radiating rows of gills which contain specialized club-shaped reproductive cells called basidia
In each basidium two nuclei become isolated by a complete septum
Nuclei fuse and form a diploid zygote
Meiosis then results in four nuclei that are pushed into cytoplasmic extensions to form basidiospores
At maturity, the basidiospores are released and germinate into new homokaryotic hyphae
As the homokaryotic hyphae grow, septa form so that each cell contains one nucleus
These homokaryotic, septate hyphae are called the primary mycelium
Primary hyphae grow and fuse with hyphae from another mating strain resulting in the formation of secondary hyphae
Hyphae of these mycelium are heterokaryotic, containing one nucleus from each mating strain in each cell
Secondary mycelium intertwines and forms a basiocarp

65. Life Cycle of Club Fungi
Basidiomycetes undergo what is probably the most elaborate life cycle of all the fungi
As shown in the figure at right, a basidiospore germinates to produce a haploid primary mycelium, which begins to grow
Before long, the mycelia of different mating types fuse to produce a secondary mycelium
The cells of the secondary mycelium contain haploid nuclei of each mating type
Secondary mycelia may grow in the soil for years, reaching an enormous size
A few mycelia have been found to be hundreds of meters across, making them perhaps the largest organisms in the world

66. Life Cycle of a Basidiomycete
The club fungi are named after the club shape of their reproductive structure, the basidium
The cap of a basidiomycete such as a mushroom is composed of tightly packed hyphae
The lower side of the cap is composed of gills—thin blades of tissue lined with basidia that produces basidiospores

67. Life Cycle of a Basidiomycete

68. BASIDIOMYCETE REPRODUCTION

69. BASIDIOMYCETE REPRODUCTION

70. BASIDIOMYCOTA LIFE CYCLE

71. FRUITING BODY BASIDIOCARP

72. FRUITING BODY BASIDIOCARP

73. FRUITING BODY BASIDIOCARP

74. FRUITING BODY BASIDIOCARP

75. FRUITING BODY BASIDIOCARP

76. PUFFBALL OF BASIDIOMYCETES

77. Life Cycle of Club Fungi
When the right combination of moisture and nutrients occurs, spore-producing fruiting bodies push above the ground
You would recognize these fruiting bodies as mushrooms
Each mushroom begins as a mass of growing hyphae that forms a button, or thick bulge, at the soil's surface

78. Life Cycle of Club Fungi
Fruiting bodies expand with astonishing speed, sometimes producing fully developed mushrooms overnight
This remarkable growth rate is caused by cell enlargement, not cell division
The cells of the hyphae enlarge by rapidly taking in water

79. Life Cycle of Club Fungi
When the mushroom cap opens, it exposes hundreds of tiny gills on its underside
Each gill is lined with basidia
The two nuclei in each basidium fuse to form a diploid (2N) zygote cell, which then undergoes meiosis, forming clusters of haploid basidiospores
The basidiospores form at the edge of each basidium and, within a few hours, are ready to be scattered
Mushrooms are truly amazing reproductive structures—a single mushroom can produce billions of spores, and giant puffballs can produce trillions

80. Diversity of Club Fungi
In addition to mushrooms, basidiomycetes include shelf fungi, which grow near the surfaces of dead or decaying trees
The visible bracketlike structure that forms is a reproductive structure, and it, too, is a prolific producer of spores
Puffballs, earthstars, jelly fungi, and plant parasites known as rusts are other examples of basidiomycetes

81. Edible and Inedible Mushrooms
Many types of fungi have long been considered delicacies, and several different species of mushrooms are cultivated for food
You may have already tasted sliced mushrooms on pizza, feasted on delicious sautéed portobello mushrooms, or eaten shiitake mushrooms
When properly cooked and prepared, domestic mushrooms are tasty and nutritious

82. FUNGI IN INDUSTRY

83. Edible and Inedible Mushrooms
Wild mushrooms are a different story: Although some are edible, many are poisonous
Because many species of poisonous mushrooms look almost identical to edible mushrooms, you should never pick or eat any mushrooms found in the wild
Instead, mushroom gathering should be left to experts who can positively identify each mushroom they collect
The result of eating a poisonous mushroom can be severe illness, or even death

84. The Imperfect Fungi
Fungi are usually classified by the sexual phase of their life cycle
So, what do biologists do when they discover a fungus that does not seem to have a sexual phase?
Until a sexual phase is discovered, scientists place it in the phylum called Deuteromycota, or the imperfect fungi
The term imperfect, by the way, doesn’t mean that there’s anything wrong with these organisms
It simply means that our understanding of their life cycles may not be perfect
The Deuteromycota are fungi that cannot be placed in other phyla because researchers have never been able to observe a sexual phase in their life cycles
A majority of the imperfect fungi closely resemble ascomycetes
Others are similar to basidiomycetes, and a few resemble the zygomycetes

85. The Imperfect Fungi
One of the best-known genera of the imperfect fungi is Penicillium
The species Penicillium notatum is a mold that frequently grows on fruit and is the source of the antibiotic penicillin
Like the ascomycetes, Penicillium reproduces asexually by means of conidia, leading many biologists to conclude that Penicillium evolved from an ascomycete that lost the sexual phase of its life cycle

86. DIVISION DEUTEROMYCOTA
Sometimes called the imperfect fungi or, Fungi Imperfecti
10,000 species
Classification based on type of asexual reproduction
No sexual reproductive phase discovered
Placed in this Division until a sexual phase, if it exist, is identified
Some forms cause ringworm and athlete’s foot
Aspergillus used to ferment soy beans in the production of soy sauce

87.  Ecology of Fungi
Fungi have been around since life first moved onto land
In fact, the oldest known fossils of fungi were formed about 460 million years ago
At that time, the largest land plants were small organisms similar to mosses
Paleontologists think that fungi helped early plants to obtain nutrients from the ground
Their early appearance suggests that fungi may have been essential to plants' successful colonization of the land, one of the key events in the history of life

88.  Ecology of Fungi
Over time, fungi have become an important part of virtually all ecosystems, adapting to conditions in every corner of Earth
Because most fungi live their lives out of our sight, people often overlook them
But without fungi, the world would be a very different place

89. All Fungi Are Heterotrophs
As heterotrophs, fungi cannot manufacture their own food
Instead, they must rely on other organisms for their energy
Unlike animals, fungi cannot move to capture food, but their mycelia can grow very rapidly into the tissues and cells of plants and other organisms
Many fungi are saprobes, organisms that obtain food from decaying organic matter
Others are parasites, which harm other organisms while living directly on or within them
Still other fungi are symbionts that live in close and mutually beneficial association with other species

90. All Fungi Are Heterotrophs
Although most fungi feed on decaying matter, a few feed by capturing live animals
Pleurotus ostreatus is a carnivorous fungus that lives on the sides of trees
As roundworms crawl into the fungus to feed, they are exposed to a fungal chemical that makes them become sluggish
As the worms slow to a stop, fungal hyphae penetrate their bodies, trapping them in place and then digesting them

91. Fungi as Decomposers
Fungi play an essential role in maintaining equilibrium in nearly every ecosystem, where they recycle nutrients by breaking down the bodies and wastes of other organisms
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
The mycelia of fungi produce digestive enzymes that speed the breakdown of wastes and dead organisms
In so doing, they promote the recycling of nutrients and essential chemicals, helping to maintain ecosystem equilibrium

92. Fungi as Decomposers Imagine a world without decomposers
Without decay, the energy-rich compounds that organisms accumulate during their lifetimes would be lost forever
Many organisms, especially plants, remove important trace elements and nutrients from the soil
If these materials were not returned, the soil would quickly be depleted, and Earth would become lifeless and barren

93. Fungi as Parasites
As useful as many fungi are, others can infect both animals and plants, disrupting their internal equilibrium and causing disease
Parasitic fungi cause serious plant and animal diseases
A few cause diseases in humans

94. Plant Diseases 
Fungi cause diseases such as corn smut, which destroys corn kernels
Mildews, which infect a wide variety of fruits, are also fungi
Fungal diseases are responsible for the loss of approximately 15 percent of the crops grown in temperate regions of the world
In tropical areas, where high humidity favors fungal growth, the loss of crops is sometimes as high as 50 percent
Fungi are in direct competition with humans for food
Unfortunately for us, sometimes fungi win that competition

95. Plant Diseases 
One fungal disease—wheat rust—affects one of the most important crops grown in North America
Rusts are caused by a type of basidiomycete that needs two different plants to complete its life cycle
Spores produced by rust in barberry plants are carried by the wind into wheat fields
There, the spores germinate and infect wheat plants
The patches of rust produce a second type of spore that infects other wheat plants, allowing the disease to spread through the field like wildfire

96. Plant Diseases 
Later in the growing season, a new variety of spore is produced by the rust
These tough black spores easily survive through the winter
In spring, they go through a sexual phase and produce spores that infect barberry plants
Once on the barberry leaves, the rust produces the spores that infect wheat plants, and the cycle continues
Fortunately, once agricultural scientists understood the life cycle of the rust, they were able to slow its spread by destroying barberry plants

97. Human Diseases Fungal parasites can also infect humans
One deuteromycete can infect the areas between the toes, causing the infection known as athlete's foot
The fungus forms a mycelium directly within the outer layers of the skin
This produces a red, inflamed sore from which the spores can easily spread from person to person
When the same fungus infects other areas, such as the skin of the scalp, it produces a red scaling sore known as ringworm, which is not a worm at all

98. FUNGAL DISEASES

99. Human Diseases 
The microorganism Candida albicans, a yeast, can disrupt the equilibrium within the human body, causing fungal disease
Candida, which grows in moist regions of the body, is usually kept in check by competition from bacteria that grow in the body and by the body's immune system
This normal balance can be upset by many factors, including the use of antibiotics, which kill bacteria, or by damage to the immune system
When this happens, Candida may produce thrush, a painful mouth infection
Yeast infections of the female reproductive tract usually are due to overgrowth of Candida

100. FUNGAL DISEASES

101. Other Animal Diseases 
As problematic as human fungal diseases can be, few fungal diseases are as deadly as the infection by one fungus from the genus Cordyceps
This 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 tough external skeleton
The spores multiply in the insect's body, digesting all its cells and tissues until the insect dies
To complete the process of digestion, hyphae develop, cloaking the decaying exoskeleton in a web of fungal material
Reproductive structures, which will produce more spores that will spread the infection, then emerge from the grasshopper's remains, as shown in the photograph

102. Grasshopper Infected by a Fungus
This grasshopper is the victim of Cordyceps, a fungus
Once the fungus's tiny spore enters the insect's body, it multiplies rapidly and digests body tissues
The structures growing out of the grasshopper's body are the fungus's fruiting bodies

103. Grasshopper Infected by a Fungus

104. Symbiotic Relationships
Fungi often grow in close association with members of other species in symbiotic relationships
Although fungi are parasites in many of these relationships, that is not always the case
Some fungi form symbiotic relationships in which both partners benefit
Two such mutualistic associations, lichens and mycorrhizae, are essential to many ecosystems

105. Lichens Lichens are not single organisms
Rather, they are symbiotic associations between a fungus and a photosynthetic organism
The fungi in lichens are usually ascomycetes, although a few are basidiomycetes
The photosynthetic organism is either a green alga or a cyanobacterium, or both
The figure below shows the structure of a lichen

106. Structure of a Lichen  
Lichens are a mutualistic relationship between a fungus and an alga or a cyanobacterium, or both
The protective upper surface of a lichen is composed of fungal hyphae
Below this is the layer of cyanobacteria or algae with loosely woven hyphae
The third layer consists of loosely packed hyphae
The bottom layer is a protective surface covered by small projections that attach the lichen to a rock or tree

107. Structure of a Lichen  

108. 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 of the relationship between the two partner organisms
The algae or cyanobacteria carry out photosynthesis, providing the fungus with a source of energy
The fungus, in turn, provides the algae or bacteria with water and minerals that it collects and protects the delicate green cells from intense sunlight

109. 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, and they are among the first organisms to be affected when air quality deteriorates

110. SYMBIOTIC RELATIONSHIP TOP: MYCORRHIZAE BOTTOM: FOLIOSE LICHEN

111. MUTUALISM
Type of symbiosis in which both organisms benefit

112. MYCORRHIZAE Symbiotic association between fungi and plant roots
Occurs in about 80% of plants
Helps plants absorb water and nutrients, such as phosphorus and potassium, by forming extensive networks of fungal hyphae in the soil increasing the surface area in the soil for absorption
Digestive action of the fungal enzymes provides nutrients that can be readily absorbed by the plant
Fungi absorbs some of the sugars created by the plant during photosynthesis

113. Mycorrhizae Fungi also form mutualistic relationships with plants
Almost half of the tissues of trees are hidden beneath the ground in masses of tangled roots
These roots are woven into a partnership with an even larger web of fungal mycelia
These associations of plant roots and fungi are mycorrhizae (singular: mycorrhiza)

114. Mycorrhizae
Scientists have known about this partnership for years, but recent research shows that it is more common and more important than was previously thought
Researchers now estimate that 80 percent of all plant species form mycorrhizae with fungi

115. Mycorrhizae How do plants and fungi benefit from each other?
The tiny hyphae of the fungi aid plants in absorbing water and minerals
They do this by producing a network that covers the roots of the plants and increases the effective surface area of the root system
This allows the roots to absorb more water and minerals from the soil
In addition, the fungi release enzymes that free nutrients in the soil
The plants, in turn, provide the fungi with the products of photosynthesis

116. Mycorrhizae
The presence of mycorrhizae is essential for the growth of many plants
The seeds of some plants, such as orchids, cannot germinate in the absence of mycorrhizal fungi
Many trees are unable to survive without fungal symbionts
Mycorrhizal associations have even been cited as an adaptation that was critical in the evolution of land plants from more-aquatic ancestors

117. Mycorrhizae Mycorrhizal relationships are often very specialized
For example, the Douglas fir forests of the Pacific Northwest are dependent on the presence of a particular species of white truffle
In Europe, black truffles are found growing with oak and beech trees
The fly agaric grows mostly with birch and pine trees

118. Mycorrhizae Why is this networking relationship so important?
The partnership between plant and fungus does not end with a single plant
The roots of each plant are plugged into mycorrhizal networks that connect many plants
What's more astounding is that these networks appear to connect plants of different species

119. Mycorrhizae
A recent experiment showed that carbon atoms from one tree often end up in another nearby tree
In an experiment using carbon isotopes to track 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
As a result, the sun-starved fir trees thrived, basically by being “fed” carbon from the birches

120. Mycorrhizae
Simard's findings suggest that plants are far from being isolated individuals, as was previously thought
Instead, plants—and their associated fungi—may be evolving as part of an ecological partnership