 |
|
2 explosive evolutionary events shaped early history of multicellular life
January 04, 2008Scientists have known for some time that most major groups of complex animals appeared in the fossils record during the Cambrian Explosion, a seemingly rapid evolutionary event that occurred 542 million years ago. Now Virginia Tech paleontologists, using rigorous analytical methods, have identified another explosive evolutionary event that occurred about 33 million years earlier among macroscopic life forms unrelated to the Cambrian animals. They dubbed this earlier event the "Avalon Explosion."
The discovery, reported in the January 4 issue of Science, suggests that more than one explosive evolutionary event may have taken place during the early evolution of animals.
The Cambrian explosion event refers to the sudden appearance of most animal groups in a geologically short time period between 542 and 520 million years ago, in the early Cambrian Period. Although there were not as many animal species as in modern oceans, most (if not all) living animal groups were represented in the Cambrian oceans. "The explosive evolutionary pattern was a concern to Charles Darwin, because he expected that evolution happens at a slow and constant pace," said Shuhai Xiao, associate professor of geobiology at Virginia Tech. "Darwin's perception could be represented by an inverted cone with ever expanding morphological range, but the fossil record of the Cambrian Explosion and since is better represented by a cylinder with a morphological radiation at the base and morphological constraint afterwards."
Darwin reckoned that there should be long and hidden periods of animal evolution before the Cambrian Explosion, Xiao said.
But paleontologists have not found such evidence, and recently scientists have learned that biological evolution has not been moving on a smooth road. "Accelerated rates may characterize the early evolution of many groups of organisms," said Michal Kowalewski, professor of geobiology at Virginia Tech.
To test whether other major branches of life also evolved in an abrupt and explosive manner, Virginia Tech graduate students Bing Shen and Lin Dong, along with Xiao and Kowalewski, analyzed the Ediacara fossils: the oldest complex, multicellular organisms that had lived in oceans from 575 to 542 million years ago; that is, before the Cambrian Explosion of animals. "These Ediacara organisms do not have an ancestor-descendant relationship with the Cambrian animals, and most of them went extinct before the Cambrian Explosion," said Shen. "And this group of organisms - most species - seems to be distinct from the Cambrian animals."
But how did those Ediacara organisms first evolve, Shen asked. Did they also appear in an explosive evolutionary event, or is the Cambrian Explosion a truly unparalleled event"
"We identified 50 characters and mapped the distribution of these characters in more than 200 Ediacara species. These species cover three evolutionary stages of the entire Ediacara history across 33 million years," said Shen.
The three successive evolutionary stages are represented by the Avalon, White Sea, and Nama assemblages (all named after localities where representative fossils of each stage can be found). The earliest Avalon stage was represented by relatively few species.
Surprisingly, however, as shown by Shen and colleagues, these earliest Ediacara life forms already occupied a full morphological range of body plans that would ever be realized through the entire history of Ediacara organisms. "In other words, major types of Ediacara organisms appeared at the dawn of their history, during the Avalon Explosion," Dong said. "Subsequently, Ediacara organisms diversified in White Sea time and then declined in Nama time. But, despite this notable waxing and waning in the number of species, the morphological range of the Avalon organisms were never exceeded through the subsequent history of Ediacara."
Kowalewski said their research team had not anticipated the discovery. "Using the scientific literature, we were trying to create a more rigorous reconstruction of the morphological history of Ediacara organisms," he said.
The process involved adapting quantitative methods that had been used previously for studying morphological evolution of animals, but never applied to the enigmatic Ediacara organisms. "We think of diversity in terms of individual species. But species may be very similar in their overall body plan. For example, 50 species of fly may not differ much from one another in terms of their overall shape - they all represent the same body plan. On the other hand, a set of just three species that include a fly, a frog and an earthworm represent much more morphological variation. We can thus think of biodiversity not only in terms of how many different species there are but also how many fundamentally distinct body plans are being represented. Our approach combined both those approaches," said Kowalewski.
"In addition, the method relies on converting different morphologies into numerical (binary) data. This strategy allows us to describe, more objectively and more consistently, enigmatic fossil life forms, which are preserved mostly as two-dimensional impressions and are not understood well in terms of function, ecology, or physiology," Kowalewski said.
Scientists are still unsure what were the driving forces behind the rapid morphological expansion during the Avalon explosion, and why the morphological range did not expand, shrink, or shift during the subsequent White Sea and Nama stages.
"But, one thing seems certain -- the evolution of earliest macroscopic and complex life also went through an explosive event before to the Cambrian Explosion," Xiao said. "It now appears that at the dawn of the macroscopic life, between 575 and 520 million years ago, there was not one, but at least two major episodes of abrupt morphological expansion."
Virginia Tech
Darwin reckoned that there should be long and hidden periods of animal evolution before the Cambrian Explosion, Xiao said.
But paleontologists have not found such evidence, and recently scientists have learned that biological evolution has not been moving on a smooth road. "Accelerated rates may characterize the early evolution of many groups of organisms," said Michal Kowalewski, professor of geobiology at Virginia Tech.
To test whether other major branches of life also evolved in an abrupt and explosive manner, Virginia Tech graduate students Bing Shen and Lin Dong, along with Xiao and Kowalewski, analyzed the Ediacara fossils: the oldest complex, multicellular organisms that had lived in oceans from 575 to 542 million years ago; that is, before the Cambrian Explosion of animals. "These Ediacara organisms do not have an ancestor-descendant relationship with the Cambrian animals, and most of them went extinct before the Cambrian Explosion," said Shen. "And this group of organisms - most species - seems to be distinct from the Cambrian animals."
But how did those Ediacara organisms first evolve, Shen asked. Did they also appear in an explosive evolutionary event, or is the Cambrian Explosion a truly unparalleled event"
"We identified 50 characters and mapped the distribution of these characters in more than 200 Ediacara species. These species cover three evolutionary stages of the entire Ediacara history across 33 million years," said Shen.
The three successive evolutionary stages are represented by the Avalon, White Sea, and Nama assemblages (all named after localities where representative fossils of each stage can be found). The earliest Avalon stage was represented by relatively few species.
Surprisingly, however, as shown by Shen and colleagues, these earliest Ediacara life forms already occupied a full morphological range of body plans that would ever be realized through the entire history of Ediacara organisms. "In other words, major types of Ediacara organisms appeared at the dawn of their history, during the Avalon Explosion," Dong said. "Subsequently, Ediacara organisms diversified in White Sea time and then declined in Nama time. But, despite this notable waxing and waning in the number of species, the morphological range of the Avalon organisms were never exceeded through the subsequent history of Ediacara."
Kowalewski said their research team had not anticipated the discovery. "Using the scientific literature, we were trying to create a more rigorous reconstruction of the morphological history of Ediacara organisms," he said.
The process involved adapting quantitative methods that had been used previously for studying morphological evolution of animals, but never applied to the enigmatic Ediacara organisms. "We think of diversity in terms of individual species. But species may be very similar in their overall body plan. For example, 50 species of fly may not differ much from one another in terms of their overall shape - they all represent the same body plan. On the other hand, a set of just three species that include a fly, a frog and an earthworm represent much more morphological variation. We can thus think of biodiversity not only in terms of how many different species there are but also how many fundamentally distinct body plans are being represented. Our approach combined both those approaches," said Kowalewski.
"In addition, the method relies on converting different morphologies into numerical (binary) data. This strategy allows us to describe, more objectively and more consistently, enigmatic fossil life forms, which are preserved mostly as two-dimensional impressions and are not understood well in terms of function, ecology, or physiology," Kowalewski said.
Scientists are still unsure what were the driving forces behind the rapid morphological expansion during the Avalon explosion, and why the morphological range did not expand, shrink, or shift during the subsequent White Sea and Nama stages.
"But, one thing seems certain -- the evolution of earliest macroscopic and complex life also went through an explosive event before to the Cambrian Explosion," Xiao said. "It now appears that at the dawn of the macroscopic life, between 575 and 520 million years ago, there was not one, but at least two major episodes of abrupt morphological expansion."
Virginia Tech
Research identifies 3-D structure of key nuclear pore building block
The genome of complex organisms is stashed away inside each cell's nucleus, a little like a sovereign shielded from the threatening world outside.
Cold climate produced by algae contributed to onset of multicellular life
The rise of multicellular animals about 540 million years ago was a turning point in the history of life. A group of Finnish scientists suggests a new climate-biosphere interaction mechanism for the underlying processes in a new study.
Scientists' cell discovery unearths evolutionary clues
The full family tree of the species known as social amoebas has been plotted for the first time - a breakthrough which will provide important clues to the evolution of life on earth.
Oxygen triggered the evolution of complex life forms
Oxygen played a key role in the evolution of complex organisms, according to new research published in BMC Evolutionary Biology. The study shows that the complexity of life forms increased earlier than was thought, and in parallel with the availability of oxygen as an energy source. In the largest study to date that does not focus on vertebrates, researchers from Pennsylvania State University used molecular dating methods to create a new timeline of eukaryotic evolution. By adding information about the numbers of different cell types possessed by each group of organisms, the researchers reconstructed how the complexity of life has increased over time. The study shows that organisms containin
Nature press release for 22 August issue
[1] LIFELINES: ANTHRAX DETECTOR AND KILLER IN ONE (pp884-889; N&V) Researchers in this week`s Nature reveal a new antibiotic that could foil bioterrorist`s attempts to engineer antibiotic-resistant strains. The same drug could serve as a rapid detector for anthrax spores. The strain of Bacillus anthracis used in last October`s US attacks could be killed with antibiotics penicillin and ciprofloxacin. But there is concern that bioterrorists might make new strains that are resistant to these and other antibiotics. Raymond Schuch and his colleagues at Rockefeller University in New York extracted a killer protein, called PlyG lysine, from a virus that naturally infects B. anthracis. Injections of
More Multicellular Life Current Events and Multicellular Life News Articles
 |
The Diversity of Life: From Single Cells to Multicellular Organisms (Cells & Life) by Robert Snedden (Author) Reflecting the advances, this work takes a look at cells throughout the living word. It includes their structure and process and how they underpin life on earth. |
 |
The Domains of Life, Program 2: The Eukaryotic Cell Evolves Also With: BioMEDIA Associates (Producer) Combining superb imaging of primitive cell types with state-of-the-art animation, this two-program series describes the current prevailing view of evolutionary events that shaped life on planet Earth. Program 1 ISBN: 1930527284 Program 2 ISBN: 1930527292 |
|
La diversidad de la vida/ The Diversity of Life: Desde celulas individuales hasta organismos multicelulares/ from Single Cells to Multicellular Organisms ... Y Vida/ Cells and Life) (Spanish Edition) by Robert Snedden (Author), Roberto Escalona (Translator) | |
 |
Diversity of Life: From Single Cells to Multicellular Organisms (Cells & Life) by Robert Sneddon (Author) A cell is too small for us to see withough a microscope, yet this tiny chemical package holds all the ingredients of life. Some living things are just a single cell, but there are around 65 million million cells in a human body. Cells are life's building blocks, all living things are made up of cells working together. This series explores all aspects of cells and the living world, and includes snippets of science history, as well as key scientific achievements. |
 |
First Signals: The Evolution of Multicellular Development. by John Tyler Bonner (Author) The enormous recent success of molecular developmental biology has yielded a vast amount of new information on the details of development. So much so that we risk losing sight of the underlying principles that apply to all development. To cut through this thicket, John Tyler Bonner ponders a moment in evolution when development was at its most basic--the moment when signaling between cells began. Although multicellularity arose numerous times, most of those events happened many millions of years ago. Many of the details of development that we see today, even in simple organisms, accrued over a long evolutionary timeline, and the initial events are obscured. The relatively uncomplicated and easy-to-grow cellular slime molds offer a unique opportunity to analyze development at a primitive... |
 |
Multicellular Animals: A New Approach to the Phylogenetic Order in Nature by Peter Ax (Author) The system of multicellular animals presented here is an alternative to the traditional classification system which still operates with the categories of Carl Linné, including typological divisions in artificial species groups. In a new approach to the phylogenetic order in nature this book strives for an objective systematization of the metazoa. It seeks a new path in the field of academic research and teaching based on the theory and methodology of phylogenetic systematics. This volume covers the metazoa from the Porifera up to the Cestoda, Nemertini and Trochozoa; two more volumes to come will cover all the remaining metazoa. |
|
Bacteria as Multicellular Organisms by James A. Shapiro (Editor), Martin Dworkin (Editor) Bacteria as Multicellular Organisms is the first book devoted specifically to multicellular aspects of bacterial life. Contrary to conventional wisdom, which treats bacteria as autonomous single cells, this book shows how bacteria are sentient, interactive organisms with an unexpectedly broad repertoire of chemical and physical mechanisms for signalling each other and organizing themselves into multicellular aggregates with novel properties. The book has been compiled from reports by specialists in a variety of disciplines from genetics and microbiology to environmental engineering and biotechnology. This interdisciplinary approach reflects the growing importance of bacteria as key experimental material for investigating phenomena common to many fields in contemporary science:... | |
 |
D-amino acids in sequences of secreted peptides of multicellular organisms (Experientia Supplementum) by P. Jolles (Editor) Life on earth almost exclusively uses laevorotatory or left-handed amino acids (L-enantiomers), rather than D-enantiomers. Nevertheless, with improved analytical methods, D-amino acids have been detected in a variety of peptides of multicellular organisms during recent years. This book takes stock of our present knowledge in this rapidly expanding research area. In a series of chapters it discusses the characterization and analysis of D-amino acids, their occurrence and function in animal peptides and proteins, some possible biosynthetic pathways, and their appearance during ageing. Notably, one chapter approaches the puzzling question of homochirality and life. |
 |
Multicellular Animals Volume 2 by Peter Ax (Author), S. Kinsey (Translator) The system of multicellular animals presented here is an alternative to the traditional classification system which still operates with the categories of Carl Linné, including typological divisions in artificial species groups. In a new approach to the phylogenetic order in nature this book strives for an objective systematization of the metazoa. It seeks a new path in the field of academic research and teaching based on the theory and methodology of phylogenetic systematics. This volume covers the metazoa from the Molluscs up to the Arthropods; the forthcoming volume 3 will cover all the remaining metazoa. |
|
Genetic Effects of Ionizing Radiation in Multicellular Eukaryotes and the Assessment of Genetic Radiation Hazards in Man by K. Sankaranarayanan (Author) |
| © 2009 BrightSurf.com |