Species Have Come and Gone at Different Rates than Previously Believed

View a video interview with researcher John Alroy of the National Center for Ecological Analysis and Synthesis.

Diversity among the ancestors of such marine creatures as clams, sand dollars and lobsters showed only a modest rise beginning 144 million years ago with no clear trend afterwards, according to an international team of researchers. This contradicts previous work showing dramatic increases beginning 248 million years ago and may shed light on future diversity.

"Some of the time periods in the past are analogies for what is happening today from global warming," says Jocelyn Sessa of Penn State. "Understanding what happened with diversity in the past can help us provide some prediction on how modern organisms will fare. If we know where we have been, we know something about where it will go."

Using contemporary statistical methods and a paleobiology database, the researchers report in the July 4 issue of Science, a new diversity curve that shows that most of the early spread of invertebrates took place well before the Late Cretaceous, and that the net increase through the period since, is proportionately small relative to the 65 million years that elapsed. The research team was led by John Alroy of the University of California at Santa Barbara.

One key to the new curve is the Paleobiology Database, (http://paleodb.org/cgi-bin/bridge.pl) housed at the National Center for Ecological Analysis and Synthesis, University of California, Santa Barbara. Previous research was based on databases of marine invertebrate fossils that recorded only the first occurrence of an organism and the last occurrence of the organism. There was no information in between for the organism.

"Over 30 years ago, researchers looked at the curve they had and considered that perhaps diversity did not increase at all," says Mark E. Patzkowsky of Penn State. "What researchers saw was the diversity curve leveled off for quite some time and then took off exponentially. However, diversity results are strongly controlled by sampling techniques."

The new database allows researchers to standardize sample size because it includes multiple occurrences of each fossil. Researchers can randomly choose equal samples from equal time spans to create their diversity curve. This new curve uses 11 million-year segments, but the researchers hope to reduce the time intervals to 5 million years to match the interval of the previous curve, known as Sepkoski.

The data for this study contains 284,816 fossil occurrences of 18,702 genera that equals about 3.4 million specimens from 5384 literature sources. The old curve, developed by J. John Sepkoski Jr., used a database that contained only about 60,000 occurrences.

The researchers also looked at evenness in diversity. If there are 100 specimens divided into 10 time intervals, they could be divided with 10 individual specimens in each interval, or 91 specimens could be in one interval with one each in the remainder. The more even the distribution, the higher the evenness.

"Evenness says something about resource distribution," says Patzkowsky. "Much of invertebrate diversity has been attributed to diversity increase in the tropics, but the curve is not driven by that totally. It seems that 450 million years ago was not so different from today because it also contained more diversity in the tropics."

The major points of the Sepkoski curve are still seen in the new curve. Some things that are not seen, such as the decrease in diversity due to the Cretaceous Tertiary (KT) extinction 65 million years ago are not visible because of the scale of the intervals used. The extinction and recovery in the KT took less than 11 million years and so do not show.

Some things not seen on the Sepkoski curve include a peak in the Permian. Also unexpected is that the diversity in the Jurassic (206 to 144 million years ago) is lower than diversity in the Triassic (248 to 206 million years ago), indicating a dip and rise in the diversity curve.

The curve then rises in the Cretaceous and remains more or less flat after that. The previously thought exponential increase in diversity is not there.

"Comparing diversity through time is about how our world works, about the origin of species and how diversity changes with temperature," says Sessa. "If we think that the net increase over time will not get much greater, things are very different from if the diversity increases exponentially."

The National Science Foundation and NASA supported this research.

-NSF-

 

 

 

In Unique Stellar Laboratory, Einstein's Theory Passes Strict, New Test

Taking advantage of a unique cosmic configuration, astronomers have measured an effect predicted by Albert Einstein's theory of General Relativity in the extremely strong gravity of a pair of superdense neutron stars. Essentially, the famed physicist's 93-year-old theory passed yet another test.Scientists at McGill University used the National Science Foundation's Robert C. Byrd Green Bank Telescope (GBT) to do a four-year study of a double-star system unlike any other known in the ... More at http://www.nsf.gov/news/news_summ.jsp?cntn_id=111831&govDel=USNSF_51 This is an NSF News item.

Radicals Shake Up Molecules in a Tug o' War

Until now, it was commonly thought that colliding molecules get the shakes as the result of energy transfer solely from the smashing of the molecules, but some new research adds a second means by which colliding molecules become vibrationally excited--it is being called the "Tug o' War Mechanism."The new experiment, transforming the textbook story, was performed in the lab of Richard Zare, chair of the Department of Chemistry at Stanford University. This work on energy ... More at http://www.nsf.gov/news/news_summ.jsp?cntn_id=111861&govDel=USNSF_51 This is an NSF News item.

NSF Signs Memorandum of Understanding with Department of Defense for National Security Research

The National Science Foundation (NSF) has signed a Memorandum of Understanding (MOU) with the Department of Defense (DoD) that would allow researchers to apply for grants to study subjects that may be of interest to U.S. national security.Officials anticipate the MOU will fund work leading to new knowledge about topics such as religious fundamentalism, terrorism and cultural change. The results may have uses for U.S. armed forces and other DoD agencies."To secure the ... More at http://www.nsf.gov/news/news_summ.jsp?cntn_id=111829&govDel=USNSF_51 This is an NSF News item.

Crossed (Evolutionary) Signals?

What do humans and single-celled choanoflagellates have in common? More than you'd think. New research into the choanoflagellate genome shows these ancient organisms have similar levels of proteins that cells in more complex organisms, including humans, use to communicate with each other.According to a paper published last week in the Proceedings of the National Academies of Science, these findings help confirm choanoflagellates' role as an evolutionary link between ... More at http://www.nsf.gov/news/news_summ.jsp?cntn_id=111825&govDel=USNSF_51 This is an NSF News item.

The Day the World Changed

"The NSFNET Backbone has reached a state where we would like to more officially let operational traffic on."Twenty years ago, a network engineer named Hans-Werner Braun started an e-mail message to the users of the National Science Foundation's (NSF) fledgling NSFNET project with that sentence to announce that the network's main lines, or backbone, had been upgraded. Although they received little notice at the time, those simple words announced the birth of the modern ... More at http://www.nsf.gov/news/news_summ.jsp?cntn_id=111824&govDel=USNSF_51 This is an NSF News item.