 |
|
Earliest fungi may have found multiple solutions to propagation on land, new study infers
October 19, 2006DURHAM. N.C. - In the latest installment of a major international effort to probe the origins of species, a team of scientists has reconstructed the early evolution of fungi, the biological kingdom now believed to be animals' closest relatives.
In a report published Oct. 19 in the journal Nature, the researchers outlined evidence that the ancestors of mushrooms, lichens and various other fungi may have lost their original wiggling taillike "flagellae" on several different occasions as they evolved from water to land environments while branching off from animals in the process.
Their losses of flagellae "coincided with the evolution of new mechanisms of spore dispersal, such as aerial dispersal," said the report, whose first author is Timothy James, a postdoctoral investigator at Duke University who recently relocated to Sweden's Uppsala University and the Swedish Agricultural University. Spores are tiny biological bodies, often consisting of a single cell, that fungi and certain other organisms use to reproduce themselves.
The research team represented a collaboration of 70 scientists working at 35 different institutions, and the scientists analyzed information from six key genetic regions in almost 200 different contemporary species to decipher the earliest days of fungi and their various relations.
The work was supported by the National Science Foundation under a special program that encourages large scientific collaborations to address major scientific questions related to the origins of species.
"Results from the team's research suggest new, hypothesized relationships in which fungi called chytridiomycetes, which have self-propelling flagellated spores, are most closely related to fungi with spores that lack flagella," James said in an interview.
These "unpredicted relationships link fungi that produce motile spores with fungi that have lost spore motility but evolved dispersal by explosive mechanisms," James said.
An example of "explosive" dispersal includes mushroom varieties that "shoot out" spores that can regenerate wherever they land, said study co-author Rytas Vilgalys, a Duke biology professor who specializes in fungi and who supervised James' postdoctoral research.
According to Vilgalys, what makes a fungus a fungus is not the way it propagates but how it feeds. Among the eukaryotes - a broad spectrum of organisms having complex cellular architectures that include a nucleus - fungi are the only ones that can digest food outside their bodies, he said.
"They release enzymes to do that and then absorb the nutrients," he said. "That's why they are the primary decomposers in land-based ecosystems, and many are also decomposers in aquatic ecosystems."
Vilgalys said scientists estimate that the lineage that included both fungi and animals split off from other eukaryotes about 1 billion years ago, while fungi and plants separated about 600 million years ago.
With fossil evidence for fungi practically nonexistent, scientists have had to rely on "molecular data" to make such estimates, Vilgalys said, referring to studies that compare the genetic relationships of various present-day species to deduce which might date back the furthest.
"It was only in the early '90s when molecular data showed pretty conclusively that animals and fungi are each other's closest relatives, and that they diverged after an earlier split that led to land plants," he said. "What this study is trying to address is what the first fungi looked like."
To answer such questions, fungal scientists, or mycologists, began years of collaborating under the National Science Foundation's "Tree of Life" program, which has distributed approximately $3 million to labs at Duke and elsewhere.
"The idea was that big problems in biology require the same approach that physicists use," Vilgalys said. "Instead of competing with each other, everyone needs to work on a different piece of the puzzle and then contribute their results to assemble in one big data matrix."
At Duke, Vilgalys' group joined another headed by associate biology professor Francois Lutzoni to receive roughly $1 million of the Tree of Life funding. Lutzoni is a co-author of the current study, and Frank Kauff, a postdoctoral researcher in Lutzoni's group, is the report's second author.
Kauff used a computer database he helped create, called the Web Accessible Sequence Analysis for Biological Inference, to process and analyze all of the collected genetic information. That work was performed on a large computer "cluster farm" developed by Duke's Center for Computational Science, Engineering and Medicine.
Vilgalys said that James, as the report's first author, interacted with scientists at Duke and the other collaborating institutions to analyze six different gene regions where relationships among the five currently classified fungi groups could be tied together.
"Because we are working with about 150 existing species out of a total of at least 1.5 million different fungi, we can only make inferences about these lineages," Vilgalys cautioned. "We used a variety of different ways of inferring the early branching pattern."
Starting with what the evidence inferred to be species with the longest family trees, and working up to the more recent additions, the scientists looked for signs of branching relationships amid increasing complexity.
"The most interesting aspect suggests that, more than once, ancestors changed from having flagellae and a one-celled spore stage that moved around to adapting to life on land," Vilgalys said. "In the process, they may have lost their flagellae as few as three times or as many as six. And in every instance, they evolved a different novel way of dispersing spores."
For example, contemporary mushrooms, although rooted to the ground, can still spread their kinds over long or short distances through their spores, which may be broadcast by explosive volleys or more passively through windborne dispersion.
"Trufflelike fungi, on the other hand, produce their spores in odiferous masses that are attractive to insects or mammals that then serve to disperse them," Vilgalys said.
"Virtually every lineage of terrestrial fungi has some novel dispersal mechanism, and surviving aquatic fungi have their own adaptations," he added.
James said the new research suggests that the first organisms to branch off from the fungi kingdom were parasites similar to the modern-day chytidiomycete fungus known as Rozella.
Ancestors similar to Rozella appear to have directly given rise to parasites similar to contemporary nonfungal organisms known as microsporidia, which lack swimming spores but instead inject spores through a long tube directly into a receiving cell.
The scientists' genetic roadmap also pinpoints a location the next branch down the evolutionary "tree" where the animal kingdom diverged from the fungi, Vilgalys said. And evidence suggests that most of those earliest animals got around with the aid of flagellae.
Duke University
The research team represented a collaboration of 70 scientists working at 35 different institutions, and the scientists analyzed information from six key genetic regions in almost 200 different contemporary species to decipher the earliest days of fungi and their various relations.
The work was supported by the National Science Foundation under a special program that encourages large scientific collaborations to address major scientific questions related to the origins of species.
"Results from the team's research suggest new, hypothesized relationships in which fungi called chytridiomycetes, which have self-propelling flagellated spores, are most closely related to fungi with spores that lack flagella," James said in an interview.
These "unpredicted relationships link fungi that produce motile spores with fungi that have lost spore motility but evolved dispersal by explosive mechanisms," James said.
An example of "explosive" dispersal includes mushroom varieties that "shoot out" spores that can regenerate wherever they land, said study co-author Rytas Vilgalys, a Duke biology professor who specializes in fungi and who supervised James' postdoctoral research.
According to Vilgalys, what makes a fungus a fungus is not the way it propagates but how it feeds. Among the eukaryotes - a broad spectrum of organisms having complex cellular architectures that include a nucleus - fungi are the only ones that can digest food outside their bodies, he said.
"They release enzymes to do that and then absorb the nutrients," he said. "That's why they are the primary decomposers in land-based ecosystems, and many are also decomposers in aquatic ecosystems."
Vilgalys said scientists estimate that the lineage that included both fungi and animals split off from other eukaryotes about 1 billion years ago, while fungi and plants separated about 600 million years ago.
With fossil evidence for fungi practically nonexistent, scientists have had to rely on "molecular data" to make such estimates, Vilgalys said, referring to studies that compare the genetic relationships of various present-day species to deduce which might date back the furthest.
"It was only in the early '90s when molecular data showed pretty conclusively that animals and fungi are each other's closest relatives, and that they diverged after an earlier split that led to land plants," he said. "What this study is trying to address is what the first fungi looked like."
To answer such questions, fungal scientists, or mycologists, began years of collaborating under the National Science Foundation's "Tree of Life" program, which has distributed approximately $3 million to labs at Duke and elsewhere.
"The idea was that big problems in biology require the same approach that physicists use," Vilgalys said. "Instead of competing with each other, everyone needs to work on a different piece of the puzzle and then contribute their results to assemble in one big data matrix."
At Duke, Vilgalys' group joined another headed by associate biology professor Francois Lutzoni to receive roughly $1 million of the Tree of Life funding. Lutzoni is a co-author of the current study, and Frank Kauff, a postdoctoral researcher in Lutzoni's group, is the report's second author.
Kauff used a computer database he helped create, called the Web Accessible Sequence Analysis for Biological Inference, to process and analyze all of the collected genetic information. That work was performed on a large computer "cluster farm" developed by Duke's Center for Computational Science, Engineering and Medicine.
Vilgalys said that James, as the report's first author, interacted with scientists at Duke and the other collaborating institutions to analyze six different gene regions where relationships among the five currently classified fungi groups could be tied together.
"Because we are working with about 150 existing species out of a total of at least 1.5 million different fungi, we can only make inferences about these lineages," Vilgalys cautioned. "We used a variety of different ways of inferring the early branching pattern."
Starting with what the evidence inferred to be species with the longest family trees, and working up to the more recent additions, the scientists looked for signs of branching relationships amid increasing complexity.
"The most interesting aspect suggests that, more than once, ancestors changed from having flagellae and a one-celled spore stage that moved around to adapting to life on land," Vilgalys said. "In the process, they may have lost their flagellae as few as three times or as many as six. And in every instance, they evolved a different novel way of dispersing spores."
For example, contemporary mushrooms, although rooted to the ground, can still spread their kinds over long or short distances through their spores, which may be broadcast by explosive volleys or more passively through windborne dispersion.
"Trufflelike fungi, on the other hand, produce their spores in odiferous masses that are attractive to insects or mammals that then serve to disperse them," Vilgalys said.
"Virtually every lineage of terrestrial fungi has some novel dispersal mechanism, and surviving aquatic fungi have their own adaptations," he added.
James said the new research suggests that the first organisms to branch off from the fungi kingdom were parasites similar to the modern-day chytidiomycete fungus known as Rozella.
Ancestors similar to Rozella appear to have directly given rise to parasites similar to contemporary nonfungal organisms known as microsporidia, which lack swimming spores but instead inject spores through a long tube directly into a receiving cell.
The scientists' genetic roadmap also pinpoints a location the next branch down the evolutionary "tree" where the animal kingdom diverged from the fungi, Vilgalys said. And evidence suggests that most of those earliest animals got around with the aid of flagellae.
Duke University
Fungi News and Current Fungi Events RSSBad sign for global warming: Thawing permafrost holds vast carbon pool
Permafrost blanketing the northern hemisphere contains more than twice the amount of carbon in the atmosphere, making it a potentially mammoth contributor to global climate change depending on how quickly it thaws.
New research challenges long-held assumptions of flightless bird evolution
Large flightless birds of the southern continents - African ostriches, Australian emus and cassowaries, South American rheas and the New Zealand kiwi - do not share a common flightless ancestor as once believed.
Innate immune system targets asthma-linked fungus for destruction
A new study shows that the innate immune system of humans is capable of killing a fungus linked to airway inflammation, chronic rhinosinusitis and bronchial asthma.
Infections linked to premature births more common than thought, Stanford study finds
Previously unrecognized and unidentified infections of amniotic fluid may be a significant cause of premature birth, according to researchers at the Stanford University School of Medicine.
Pesticide build-up could lead to poor honey bee health
Honey bees industriously bring pollen and nectar to the hive, but along with the bounty comes a wide variety of pesticides, according to Penn State researchers.
Novel fungus helps beetles to digest hard wood
A little known fungus tucked away in the gut of Asian longhorned beetles helps the insect munch through the hardest of woods according to a team of entomologists and biochemists. Researchers say the discovery could lead to innovative methods of controlling the invasive pest, and potentially offer more efficient ways of breaking down plant biomass for generating biofuels.
Molecular sleuths track evolution through the ribosome
A new study of the ribosome, the cell's protein-building machinery, sheds light on the oldest branches of the evolutionary tree of life and suggests that differences in ribosomal structure between the three main branches of that tree are "molecular fossils" of the early evolution of protein synthesis.
Study reveals surprising details of the evolution of protein translation
A new study of transfer RNA, a molecule that delivers amino acids to the protein-building machinery of the cell, challenges long-held ideas about the evolutionary history of protein synthesis.
Brown tree snake could mean Guam will lose more than its birds
In the last 60 years, brown tree snakes have become the embodiment of the bad things that can happen when invasive species are introduced in places where they have few predators. Unchecked for many years, the snakes caused the extinction of nearly every native bird species on the Pacific island of Guam.
New bacterial species found in human mouth
Scientists have discovered a new species of bacteria in the mouth. The finding could help scientists to understand tooth decay and gum disease and may lead to better treatments, according to research published in the August issue of the International Journal of Systematic and Evolutionary Microbiology.
More Fungi News Articles
 | National Audubon Society Field Guide to North American Mushrooms (National Audubon Society Field Guides) by Gary H. Lincoff With more than 700 mushrooms detailed with color photographs and descriptive text, this is the most comprehensive photographic field guide to the mushrooms of North America. The 762 full-color identification photographs show the mushrooms as they appear in natural habitats. Organized visually, the book groups all mushrooms by color and shape to make identification simple and accurate in the... |
 | Mycelium Running: How Mushrooms Can Help Save the World by Paul Stamets More mushrooms, less pollution! Yes, you heard right: growing more mushrooms may be the best thing we can do to save the environment. Microscopic cells called "mycelium"—the fruit of which are mushrooms —recycle carbon, nitrogen, and other essential elements as they break down plant and animal debris in the creation of rich new soil. What fungi expert Paul Stamets has discovered is that... |
 | Mushrooms Demystified: A Comprehensive Guide to the Fleshy Fungi by David Arora This is the be-all and end-all of mushroom books! Truly an encyclopedia of mushroom facts and lore, lavishly illustrated with full-color photographs, literally everything you need to know about mushrooms, edible or not. Arora has taught mycology for close to twenty years and has hunted and photographed mushrooms across the North American continent. Threaded through the book are his wry and... |
 | Teaming with Microbes: A Gardener's Guide to the Soil Food Web by Jeff Lowenfels, Wayne Lewis Smart gardeners know that soil is anything but an inert substance. Healthy soil is teeming with life-not just earthworms and insects, but a staggering multitude of bacteria, fungi, and other microorganisms. When we use chemical fertilizers, we injure the microbial life that sustains healthy plants, and thus become increasingly dependent on an arsenal of artificial substances, many of them toxic... |
 | Growing Gourmet and Medicinal Mushrooms by Paul Stamets |
 | A Field Guide to Mushrooms: North America (Peterson Field Guides (R)) by Kent H. McKnight More than 1,000 species of mushrooms described in detail. Over 700 paintings and drawings reveal subtle field marks that cannot be captured into... |
 | Psilocybin Mushrooms of the World: An Identification Guide by Paul Stamets |
 | All That the Rain Promises, and More ...: A Hip Pocket Guide to Western Mushrooms by David Arora |
 | North American Mushrooms: A Field Guide to Edible and Inedible Fungi (Falconguide) by Orson K. Miller, Hope Miller |
 | Mushrooms and Other Fungi of North America by Roger Phillips The ultimate illustrated handbook on mushrooms. More than 1,000 handsome color photographs by Roger Phillips illustrate this comprehensive guide to mushrooms and other fungi of North America, in all their astonishing variety. Amateur collectors, expert mycologists and armchair naturalists will welcome the reissue of this valuable reference. Each photograph has a neutral background to... |
| © 2008 BrightSurf.com |