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Thursday, August 20, 2009
A List of Banned Words
Carl Zimmer is teaching a course on science writing. Here's a picture of his classroom.
It's a tough job, but somebody has to do it.
Carl has banned certain words and phrases and he posted the list on his blog: The Index of Banned Words. We can all agree that "breakthrough" and "paradigm shift" must be on the list. What about the others? Share your opinion on The Loom.
I'd like to add "Darwinism," "cancer" (unless the article is actually about cancer), and "revolutionary."
Monday, August 17, 2009
A Science Literacy Test
I missed this Scientific Literacy Quiz that appeared in The Toronto Star last week.
Fortunately Postdiluvian, a med student at the University of Toronto, found it and blogged about it on The Unexamined Life: Science literacy quiz. He didn't say how many he got right. I'm not saying either except to reveal that it was fewer than 26.
Most of the questions are pretty good but one of them is wrong and a couple could have been better worded.
Tracking a Press Release
David Hone recently published a paper on theropod behavior [see: Baby killers: hunting and feeding behaviours of large theropods].
When the paper came out he made up a press release that he distributed to a bunch of people. He tracked the number of articles that picked up on his press release. Initially there was only one report in the media, then five, then twenty [Media tracking].
He was generally satisfied with the articles that appeared but some of his complaints are interesting ...
This leads us onto the next point here. The press release was often regurgitated in very large and near complete chunks. Now that is part of what it is for of course, but equally I would hope that part of their job would be to give it a bit of a literary polish (since they are, you know, writers) and make it a bit more accessible to the public. If not, then the press might as well just publish the press release in full and save themselves a bunch of money on reporters. On the other had, most of them did add in new introductory paragraphs and needless to say this is where the errors mostly came in. So they either copied stuff without writing anything new, or wrote a couple of paragraphs that they got wrong. Really how hard is to check up on a couple of dinosaur facts (one could contact the authors for example) when already 80% of the article is written for you and you don’t have to read the paper itself? Remember that these are supposed to be not just journalists but science reporters and fact checking (especially from a published paper) should be first nature, let alone second nature and is hardly difficult or even especially time consuming, no matter the deadline.I've never heard of a scientist who makes the effort to personally advertise a paper that's just been published. Usually it's the institution who sends out the press releases and they go directly to the various wire services who specialize in science stories.
I must admit that the concept of publicizing your own work troubles me a bit.
[Hat Tip: Panda's Thumb]
Advice for Scientists on How to Communicate
Carl Zimmer is an excellent science writer. He reviews three books directed at scientists on how they should communicate science to the general public. Two of the books are by science writers and the third is by a former biologist who is now a filmmaker in Hollywood.
Part of Carl's review is on his blog: Book [P]review: For The Scientist.
Three books are coming out this year directed at these scientists. Unscientific America: How Scientific Illiteracy Threatens our Future, by my fellow Discobloggers Sheril Kirshenbaum and Chris Mooney, was the first. I talked to Chris about the book in this Bloggingheads talk. Cornelia Dean of the New York Times is publishing another, called Am I Making Myself Clear?: A Scientist’s Guide to Talking to the Public. It’s a lean, straightforward tour of the media landscape, led by a journalist who has written about science for many years.All advice is valuable but I'd just like to make sure that everyone keeps things in perspective.
The third is by a scientists–but it’s called Don’t Be Such a Scientist: Talking Substance in an Age of Style. The author is Randy Olson, a biologist who headed to Hollywood. Back in 2006, I wrote about his documentary, Flock of Dodos–which was his own response to the events in Kansas. Rather than post a statement on a web site, Olson made a funny movie that not only demonstrated the flim-flammery of creationists, but also showed how dismally evolutionary biologists communicated to those beyond their guild.
The major goal of science writers is to communicate science to the general public. That's what their profession is all about. If we have not been successful at communicating science properly over the past few decades then isn't it reasonable to put some of the blame on the professionals?
Just out of curiosity, have there been many books written by science writers where they criticize their profession and give advice to fellow science writers on how to improve their science communication skills? Or, have science writers decided that it should be scientists, and not science writers, who need to correct the failures of the past?
Thursday, August 13, 2009
Nobel Laureates: Peter Doherty and Rolf Zinkernagel
The Nobel Prize in Physiology or Medicine 1966
"for their discoveries concerning the specificity of the cell mediated immune defence"
Peter C. Doherty (1949 - ) and Rolf M. Zinkernagel (1940 - ) won the Noble Prize in 1996 for their work on the mechanism of cellular immunity (cell-mediated immunity). They were the ones who figured out how T-cells can recognize and kill cells that are infected with a virus.
This is part of the modern era of Nobel Prize awards where the Nobel Foundation is doing a wonderful job of explaining the awards to a scientifically literate general public. Here's the 1996 Press ReleaseTHEME:
Nobel Laureates
Summary
Peter Doherty and Rolf Zinkernagel have been awarded this year's Nobel Prize in Physiology or Medicine for the discovery of how the immune system recognizes virus infected cells. Their discovery has, in its turn, laid a foundation for an understanding of general mechanisms used by the cellular immune system to recognize both foreign microorganisms and self molecules. This discovery is therefore highly relevant to clinical medicine. It relates both to efforts to strengthen the immune response against invading microorganisms and certain forms of cancer, and to efforts to diminish the effects of autoimmune reactions in inflammatory diseases, such as rheumatic conditions, multiple sclerosis and diabetes.
The two Nobel Laureates carried out the research for which they have now been awarded the Prize in 1973-75 at the John Curtin School of Medical Research in Canberra, Australia, where Peter Doherty already held his position and to which Rolf Zinkernagel came from Switzerland as a research fellow. During their studies of the response of mice to viruses, they found that white blood cells (lymphocytes) must recognize both the virus and certain self molecules - the so-called major histocompatibility antigens - in order to kill the virus-infected cells. This principle of simultaneous recognition of both self and foreign molecules has since then constituted a foundation for the further understanding of the specificity of the cellular immune system.
The background to the Laureates' research
The immune system consists of different kinds of white blood cells, including T- and B- lymphocytes whose common function is to protect the individual against infections by means of eliminating invading microorganisms and infected cells. At the same time they must avoid damaging the own organism. What is required is a well developed recognition system that enables lymphocytes to distinguish between on the one hand microorganisms and infected cells, and on the other, the individual´s normal cells. In addition, the recognition system must be able to determine when white blood cells with a capacity to kill should be activated.
In the early 1970s when Peter Doherty and Rolf Zinkernagel had begun their scientific work within immunology, it was possible to distinguish between antibody-mediated and cell- mediated immunity. It was known that antibodies that are produced by B-lymphocytes are able to recognize and eliminate certain microorganisms, particularly bacteria. Far less was known about recognition mechanisms in the cellular immune system, for instance in conjunction with the killing of virus-infected cells by T-lymphocytes. One area where cellular immunity had previously been studied in some detail was, however, transplantation biology. It was known that T-lymphocytes could kill cells from a foreign individual after recognition of certain molecules - the major histocompatibility antigens - in the transplant.
The discovery
Rolf Zinkernagel and Peter Doherty used mice to study how the immune system, and particularly T -lymphocytes, could protect animals against infection from a virus able to cause meningitis. Infected mice developed killer T-lymphocytes, which in a test-tube could kill virus- infected cells. But there was an unexpected discovery: the T-lymphocytes, even though they were reactive against that very virus, were not able to kill virus-infected cells from another strain of mice. What decided whether or not a cell was eliminated by these killer lymphocytes was not only if they were infected with the virus, but also if they carried the "correct" variant of histocompatibility antigens, those of the infected mouse itself. Zinkernagel's and Doherty's findings, which were published in Nature in 1974 (1,2), demonstrated conclusively the requirement for the cellular immune system to recognize simultaneously both 'foreign' molecules (in the present case from a virus) and self molecules (major histocompatibility antigens). What also became obvious was the important function of the major histocompatibility antigens (in man called HLA-antigens) in the individual´s normal immune response and not only in conjunction with transplantation.
The discovery has given an impetus to later research
Zinkernagel's and Doherty´s findings had an immediate impact on immunological research. The wide relevance of their observations concerning the specificity of the T-lymphocytes became apparent in many contexts, both in regard to the ability of the immune system to recognize microorganisms other than viruses, and in regard to the ability of the immune system to react against certain kinds of self tissue. To explain their findings, the two scientists subsequently devised two models; one model was based on a single recognition of 'altered self''(when the histocompatibility antigen has been modified through association with a virus), the other on a 'dual recognition' of both foreign and self. (Fig.) Both the experimental findings and the theoretical models became immensely important in later research. Within a few years, it had been demonstrated that the set of the T- lymphocytes that are allowed to mature and survive in an individual is determined by the ability of the cell to recognize the transplantation antigens of the individual. Therefore, the principle of simultaneous recognition is essential for the ability of the immune system to distinguish between 'self' and 'non-self'.
Further molecular research has both confirmed Zinkernagel's and Doherty's models and clarified the structural basis of their discovery - that a small part (a peptide), for example from a virus, is directly bound to a defined variable part of the body´s own histocompatibility antigens, and that this complex is what is recognized by the specific recognition molecules of T- lymphocytes (T-cell receptors). Taken in all, the clarification of the recognition mechanisms of the T-cells within the cellular immune system has fundamentally changed our understanding of the development and normal function of the immune system and, in addition, has also provided new possibilities for the selective modification of immune reactions both to microorganisms, and to self tissues.Figure legend: The figure describes how a killer T lymphocyte must recognize both the virus antigen and the self histocompatibility antigen molecule in order to kill a virus-infected target cell. The figure is a modification of the figure published by Zinkernagel and Doherty already 1974 (in Nature 251, p 547).
Relevance for clinical medicine
Many common and severe diseases depend on the function of the cellular immune system and consequently on its mechanisms for specific recognition. Although this naturally applies to infectious diseases, this is also true of a number of chronic inflammatory conditions such as rheumatic diseases, diabetes and multiple sclerosis. Where infectious diseases are concerned, the new knowledge provides a better platform for the construction of new vaccines; one can ascertain exactly what parts of a microorganism are recognized by the cellular immune system, and can specifically focus the production of the vaccine on those parts. Furthermore, regard is paid to the fundamental principles formulated by Doherty and Zinkernagel in trials with vaccination against the emergence of metastases in certain forms of cancer. In many chronic inflammatory diseases, better explanations have been provided for the associations between disease susceptibility and the histocompatibility antigen type carried by an individual. The research that followed from the now awarded discovery has also provided openings for selectively diminishing or altering immune reactions that play a central role in inflammatory diseases.
References
1. Zinkernagel RM, Doherty PC. Restriction of in vitro T cell-mediated cytotoxicity in lymphocytic choriomeningitis within a syngenic and semiallogeneic system. Nature 248, 701- 702, 1974.
2. Zinkernagel RM, Doherty PC. Immunological surveillance against altered self components by sensitised T lymphocytes in lymphocytic choriomeningitis. Nature 251, 547-548, 1974.
3. Doherty PC, Zinkernagel RM. A biological role for the major histocompatibility antigens. Lancet, 1406-1409, 1975.
4. Zinkernagel RM, Doherty PC. MHC restricted cytotoxic T cells: Studies on the biological role of polymorphic major transplantation antigens determining T cell restriction specificity. Advances in Immunology 27, 51-177, 1979.
The images of the Nobel Prize medals are registered trademarks of the Nobel Foundation (© The Nobel Foundation). They are used here, with permission, for educational purposes only.
Atheist Radio at the University of Toronto
The University of Toronto publishes eBulletin once or twice a week to let people know what's going on. This is the official voice of the university. This week's issue features David Leaman (Godless Dave) and his campus radio show Godless: Atheist radio show at UTSC attracts listeners worldwide.
I was interviewed on the show in May and it was lot's of fun [Godless Radio].
Here's what the university's eBulletin has to say about the show.
The atheist and freethinker movements have been picking up steam nationwide and across the world. There is also growing interest at UTSC, with a noteworthy addition to this outspoken community being a radio show titled Godless, which began airing on UTSC’s Fusion Radio in January 2009. It is the only show of its kind at U of T.
The name Godless evokes a reaction from most who hear it, and that's exactly the purpose behind the chosen moniker. The term, brought to light in popular culture by right-winger and controversial figure Ann Coulter through the titling of one of her books, was initially used as a pejorative label. The hosts of the show, however, wear the term as a badge of pride.
"Atheism is a lack of a religious world view. There's no dogma or ritual that surrounds it. In fact, the only thing that atheists by definition will have in common with one another is the mutual lack of belief in a God," says fourth-year mathematics student David Leaman (known as 'Dave' on the air), co-host and founder of the online show. "My own personal brand of atheism is one that embraces evidence-based and logical reasoning along with the scientific method. Using these tools, I've come to the realization that the evidence for the existence of God just doesn't hold up. The idea that applying modern methods of inquiry to the 'big questions' should be a bad thing is actually pretty laughable."
Monday's Molecule #133: Winner?
If you look closely at the two molecules (below) you'll see that the one on that left has an extra bit of polypeptide chain compared to the one on the right. Some part of the protein has been removed to create a smaller version.
This should have reminded you of the kinds of reactions that take place when zymogens are cleaved to produce an active enzyme. This is pepsin, the classic example of such a reaction.
Pepsin is a protease—an enzyme that degrades proteins to small peptides in your stomach during digestion. It is initially synthesized as an inactive precursor called pepsinogen (left). When pepsinogen is secreted into the stomach it is inactive until it is cleaved in an autocatalytic reaction stimulated by HCl secretions. The blue bit sticking out on the right of the figure is chopped off, uncovering the active site in the large cleft in the right center of the molecule. This form of activation makes sense since it's not a good idea to have an active protease in the cytoplasm of your cells.
Pepsin—the protein ferment—has been known since the 1830s. At the end of the nineteenth century Ivan Pavlov carried out a series of experiments in an attempt to understand how digestion in the stomach worked. He learned that the initial secretion containing pepsin was inactive until it was combined with a separate secretion.
Pavlov received the Nobel Prize for his work on digestion.
Only one person guessed the molecule but that person did not figure out that Pavlov was the first one to deduce that digestive enzymes were initially produced in an inactive form. There is no winner this week! Even the "regulars" were stumped this time.
Here are two different versions of the same enzyme. One of them is the active form and the other is inactive. You should identify the enzyme and briefly explain the difference between the two structures.
This is a famous enzyme whose activity was first detected over one hundred and fifty years ago. The Nobel Laureate associated with the two forms shown above is also very famous. He was the first person to discover that there were active and inactive forms of the enzyme and to provide a reasonable explanation. The Nobel Prize was awarded for many other contributions to the field and not just for this discovery. However, the fact that he is better known for other studies should not detract from his significant contributions to biochemistry.
The first person to identify the molecules and the Nobel Laureate, wins a free lunch. Previous winners are ineligible for six weeks from the time they first won the prize.
There are only six ineligible candidates for this week's reward: Dima Klenchin of the University of Wisconsin at Madison, Dara Gilbert of the University of Waterloo, Anne Johnson of Ryerson University, Cody Cobb, soon to be a graduate student at Rutgers University in New Jersey, Alex Ling of the University of Toronto, and Markus-Frederik Bohn of the Lehrstuhl für Biotechnik in Erlangen, Germany.
I have an extra free lunch for a deserving undergraduate so I'm going to continue to award an additional prize to the first undergraduate student who can accept it. Please indicate in your email message whether you are an undergraduate and whether you can make it for lunch.
THEME:
Nobel Laureates
Send your guess to Sandwalk (sandwalk (at) bioinfo.med.utoronto.ca) and I'll pick the first email message that correctly identifies the molecule(s) and names the Nobel Laureate(s). Note that I'm not going to repeat Nobel Prizes so you might want to check the list of previous Sandwalk postings by clicking on the link in the theme box.
Correct responses will be posted tomorrow.
Comments will be blocked for 24 hours.
Tuesday, August 11, 2009
Monday's Molecule #133
Here are two different versions of the same enzyme. One of them is the active form and the other is inactive. You should identify the enzyme and briefly explain the difference between the two structures.
This is a famous enzyme whose activity was first detected over one hundred and fifty years ago. The Nobel Laureate associated with the two forms shown above is also very famous. He was the first person to discover that there were active and inactive forms of the enzyme and to provide a reasonable explanation. The Nobel Prize was awarded for many other contributions to the field and not just for this discovery. However, the fact that he is better known for other studies should not detract from his significant contributions to biochemistry.
The first person to identify the molecules and the Nobel Laureate, wins a free lunch. Previous winners are ineligible for six weeks from the time they first won the prize.
There are only six ineligible candidates for this week's reward: Dima Klenchin of the University of Wisconsin at Madison, Dara Gilbert of the University of Waterloo, Anne Johnson of Ryerson University, Cody Cobb, soon to be a graduate student at Rutgers University in New Jersey, Alex Ling of the University of Toronto, and Markus-Frederik Bohn of the Lehrstuhl für Biotechnik in Erlangen, Germany.
I have an extra free lunch for a deserving undergraduate so I'm going to continue to award an additional prize to the first undergraduate student who can accept it. Please indicate in your email message whether you are an undergraduate and whether you can make it for lunch.
THEME:
Nobel Laureates
Send your guess to Sandwalk (sandwalk (at) bioinfo.med.utoronto.ca) and I'll pick the first email message that correctly identifies the molecule(s) and names the Nobel Laureate(s). Note that I'm not going to repeat Nobel Prizes so you might want to check the list of previous Sandwalk postings by clicking on the link in the theme box.
Correct responses will be posted tomorrow.
Monday, August 10, 2009
Canadian Gets Booted Out of the Creation Museum
Derek Rogers is a computer science student at Dalhousie University in Halifax, Nova Scotia (Canada). I met him in Washington last April. He has been active in the atheist bus campaign and other events promoting a nonreligious point of view.
Derek was at the Secular Student Alliance meeting in Ohio and went along with the group that visited the creation museum. He was asked to leave. Here's the video of him explaining what happened to PZ Myers, Seanna and Steve Watson, and others who had just toured the museum.
[Hat Tip: Friendly Atheist]
Sunday, August 09, 2009
Happy Anniversary!
Today is our 41st wedding anniversary.
Here's how Ms. Sandwalk looked back when we first started dating. She looks the same to me today as she did back then.
She has posted an old picture of me on her blog and it's clear that I haven't changed very much either!
Labels:
My World
Elaine Morgan and Aquatic Apes
The Aquatic Ape Hypothesis of Elaine Morgan is a classic "just-so" story that attempts to explain the evolution of modern humans by claiming that our ancestors once lived in water. It's a typical adaptationist perspective on biology since it begins with the assumption that every phenotype of humans must have been due to natural selection.
Morgan gave a talk last month sponsored by TED. It's posted at: Elaine Morgan says we evolved from aquatic apes. You should watch it if you are interested in the Aquatic Ape Hypothesis. In addition to being a good example of (false) adaptationist thinking, it's a good example of how a skilled journalist makes a "scientific" case to a general audience. The audience loved her. She gets an enthusiastic standing ovation at the end.
I didn't realize that Elaine Morgan was relying so much on attacking scientific conspiracy in order to bolster her beliefs. Many of her arguments sound similar to those of the Intelligent Design Creationists. Judging by the reception she gets, there's a lot of reasonably intelligent people out there who are willing to buy into the idea that scientists suppress knowledge of things they don't like just because they don't like them.
[Hat Tip: John Hawks]
Saturday, August 08, 2009
The Biologic Institute Expands
Posted yesterday on Evolution News & Views: European scientists working in conjunction with Biologic Institute.
The anti-ID crowd has an old canard about there being no serious scientists who doubt Darwin, let alone any that support intelligent design. And they like to say that there is no science being done by ID scientists. Both ideas are not just false, but absurdly so. Note this announcement of new scientific arrivals at Biologic Institute. Professor Matti Leisola, the Dean of Chemistry and Materials Science at Helsinki University of Technology in Finland; Colin Reeves, Professor of Operational Research in the School of Mathematical and Information Sciences at Coventry University; and Professor Stuart Burgess, Head of the Department of Mechanical Engineering at the University of Bristol.Three "serious scientists", eh? And not a biologist in the bunch. That's what we've come to expect in an institute that's supposed to be studying
John Pieret has the scoop on these dudes. All three of them are creationists with strong ties to the Young Earth Creationist movement [The "Pros" from Dover]. John had the idea of comparing these guys to the Three Stooges. I thought it was appropriate so I "borrowed" it.1
1. I steal a lot of John's ideas but let's not tell him, OK? It gives him a swelled head.
Teabaggers
American politics is so much fun—I love watching it on TV.
But from time to time the subtleties escape me. This is one of those times. The opponents of universal health care are not referred to as "idiots," which would be the appropriate name—instead, they're called "teabaggers."
What the heck is a "teabagger"? I looked it up on the Urban Dictionary. There are several definitions. One of them involves actions that don't seem to apply in this context. (But it sounds like fun.)
For the benefit of all your foreigners out there, here are the definitions that seem to be relevant ...
4) a person who is unaware that they have said or done something foolish, childlike, noobish, lame, or inconvenient.and ...
A whining fool shouting loudly for liberty but not willing to pay the bill."After most American workers saw more money in their paycheck due to the lower tax rate, the teabaggers at Fox News railed against high taxes, but did not discuss how much Jesus hated hypocrisy."
On the Origins of Eukaryotes
Carl Zimmer has an article in Science with a provocative title: On the Origin of Eukaryotes. This is well-timed since it appears just when I've returned from a meeting on this very topic. [Go here if you can't see the article on the Science website.]
One of the things we learned at the meeting is that the Woose tree of life is almost certainly an over-simplification at best and wrong at worst. It is no longer possible to claim that eukaryotes have a simple vertical descent relationship with any archaebacterium (or any bacterium, for that matter).
Instead, the early history of life is characterized by a web or a net involving multiple gene exchanges between all primitive species. After some time, the major divisions of life emerged from this "soup" and became separate lineages with an semi-independent history. This view dates back ten years or so and it's illustrated by a figure that Ford Doolittle published in the February 2000 issue of Scientific American. I've used this figure several times. Here it is again so you can see how it relates to Carl's article.
In the case of eukaryotes, the history is complicated by an endosymbiotic event where a proteobacterium was engulfed and evolved into mitochondria. That explains many of the eukaryotic genes with a clear bacterial origin. Those genes, can be reliably traced to a particular lineage of proteobacteria. What this shows is that by the time of the endosymbiosis most of the main lineages of prokaryotes had emerged from the soup and become fairly well-defined.
This doesn't explain the origins of the host cell. That cell presumably had some of the features of modern eukaryotes. Where did it come from? Was it part of an ancient lineage that formed during the gene exchange period of evolution suggesting that some eukaryotic features are ancient? Was it formed by a fusion between a primitive bacterial cell and a primitive archaebacterium? (Or, did archaebacterial arise from a fusion of a primitive eukaryotic cell and a primitive bacterium?)
Some people even believe that the ancient host progenitor of eukaryotes arose fairly late in the game and was only related to archaebacteria, either through a recent common ancestor or from an archaebaterial species within the archaebacterial clade. This is not consistent with the tree shown above but that's OK.
These two hypotheses on the archaebacterial origin of the host cell are the ones that Carl Zimmer highlights in his article: the Three Domain Tree and the Eocyte Tree.
I don't think either of these trees comes close to representing the true history of eukaryotic cells. I don't think it's even possible to represent that history by a tree. Zimmer mentions this possibility in passing but I don't think he does justice to the controversy over the tree of life.
The controversy is not just about which branch of the archaebacterial tree the eukaryotes came from. It's about whether they came from the archaebacerial lineage at all or whether it's even appropiate to be talking about lineages and trees at this stage of the history of life.
Shifting gears slightly, I'd like to bring up another subject. Here's what Carl writes near the end of his article.
Whatever the exact series of events turns out to be, eukaryotes triggered a biological revolution. Prokaryotes can generate energy only by pumping charged atoms across their membranes. That constraint helps limit their size. As prokaryotes grow in size, their volume increases much faster than their surface area. They end up with too little energy to power their cells. Eukaryotes, on the other hand, can pack hundreds of energy-generating mitochondria into a single cell. And so they could get big, evolving into an entirely new ecological niche.This is a widely believed explanation for the adaptive value of mitochondria and internal membranes. But many species of bacteria have internal membranes and, in the case of photosynthetic species, those internal membranes are packed full of energy-producing proteins.
Why couldn't bacteria have evolved internal membranes in order to get around the size limitation if it was that big of a deal? I don't see anything special about mitochondrial that couldn't have just as easily been handled by infolding of the inner membrane.
Friday, August 07, 2009
Perspectives of the Tree of Life: Day Three
Day One, Day Two
The third day (Saturday, August 1) began with a presentation by James McInerney of the National University of Ireland in Maynooth (Ireland): LUCA and LECA: Gene genesis in the genome of Eden. He examined genes in yeast cells and assigned them to ancestral homologs in bacteria and archaebacteria.
The majority of yeast genes are bacterial in origin but a significant minority come from archaebacteria. The genes with the archaebacterial origin are more likely to be found in information flow pathways (DNA replication, transcription, translation) and the genes from (eu)bacteria are more likely to be involved in other metabolic pathways.
The results suggest that the last eukaryotic common ancestor (LECA) was a hybrid formed from the fusion of a primitive bacterial cell and a primitive archaebacterial cell. The descendants of this first eukaryote subsequently entered into an endosymbiotic relationship with a proteobacterium giving rise to mitochondria and an influx of additional bacterial genes.
The second talk on day three was by Christophe Malaterre, a philosopher who divides his time between the IHPST at the Université Paris in Paris (France) and the Université Libre in Brussels (Belgium). Christophe is mostly interested in the early events in the history of life before the last universal common ancestor (LUCA) (On the roots of the tree of life). He is trying to define the basic properties of these "protocells."
This leads naturally to a debate about defining "life." During the transition from a bag of chemicals to a true living cell, there will be a zone where it will be very difficult to decide whether the protocell is living or not.
After a short break we returned to hear a presentation by William (Bill) Martin of Heinrich-Heine-Universität in Düsseldorf (Germany). His presentation was Endosymbiosis and gene transfers from endosymbionts, the most glaring insult to the tree. As the title implies, the key point is that a large percentage of nuclear genes in eukaryotes is derived from mitochondrial genes (proteobacteria) or from chloroplast genomes (cyanobacteria).
What this means is that aside from any consideration of the deep phylogeny of nuclear genes (bacterial or archaebacterial), one of the ancestors of eukaryotes is clearly a bacterial cell (proteobacteria). When you add in the bacterial contribution to genes that don't descend from mitochondria, it turns out that 75% of eukaryotic genes are bacterial in origin. No matter how you want to define the roots of the tree of life (tree, net, web) it is absolutely clear that the original Woose tree with eukaryotes on the same branch as archaebacteria is wrong!
Bill proposes that the first eukaryotic cell was formed when a primitive bacterial cell fused with a primitive archaebacterial cell. He would like to convince us that this primitive archaebacterium arose from within the current clade of Archaea. Most of us weren't convinced but none of us would dare say that to his face 'cause Bill is a very imposing man both intellectually and physically.
John Archibald of the Department of Biochemistry and Molecular Biology at Dalhousie University in Halifax, Nova Scotia (Canada) continued the endosymbiotic theme with a talk on Genetic and genomic threads in the tapestry of photosynthetic life: implications for "tree thinking."
The original photosynthetic eukaryote was the result of an endosymbiotic event involving an early eukaryotic host with mitochondria and a cyanobacterium. This gave rise to the three primary lineages: red algae, green algae, and glaucophytes. All photosynthetic eukaryotes have a single common ancestor represented by this unique endosymbiotic event.
The nuclei of modern flowering plants contain about 4500 genes derived from cyanobacteria via chloroplasts. Only half of these are targeted to the chloroplast. The rest contribute to the metabolism of the remaining part of the cell.
Some photosynthetic eukaryotes arise from a secondary endosymbiosis in which a chloroplast-containing algal cell is engulfed by a non-photosynthetic protist. In this case, genes can be transferred from the nucleus of the endosymbiote to the main nucleus, further complicating the ability to construct a treelike phylogeny that accurately reflects the true ancestral relationships of these species.
Frédéric Bouchard is a philosopher from the Université de Montréal in Montréal, Québec (Canada). When we returned from lunch we were treated to a discussion of: Endosymbiosis in light of reflections on symbiosis and the super organism.
Much of this presentation was based on symbiosis—a situation where two separate species cooperate. One or both species may benefit from this interaction and the question is how do we decide on the adaptive advantage, if any?
This was the only talk that seriously addressed the value of adaptationist thinking. Most people at this meeting seemed to assume that (almost) all evolution was due to adaptation. Bouchard even showed a slide of the Spandrels paper before going into a defense of the adaptationist program.
Andrew Roger is a former student of Ford Doolittle. He is now a professor in the Department of Biochemistry and Molecular Biology at Dalhousie University in Halifax, Nova Scotia (Canada). The title of his talk is a challenge to his former mentor: Deconstructing deconstructions of the tree of life: why a tree of microbes might be realizable, meaningful and useful.
The question is whether in light of significant LGT we can still detect the underlying vertical component in the web of life. Roger reminds us that this vertical component is very much a part of the evolutionary history of life. Let's not throw out the baby with the bath water when we question the tree of life.
There are basically two viable models of the early history of life. In the "Serious LGT" model, lateral gene transfer is ubiquitous but some genes may have been transferred less frequently than others. By looking at these genes it may be possible to recover the basic treelike vertical component of evolution.
Andrew looked at four protein encoding genes and found that they are mostly congruent with the ribosomal RNA tree of prokaryotes. The major divisions, such as cyanobacteria and proto-bacteria are confirmed. Thus, as Andrew points out, it's a mistake to assume that the web of life erases all traces of vertical descent as the alternative “Rampant LGT" model might suggest.
Almost everyone at the meeting supported the “Serious LGT" model as determined by a show of hands at the end of the day. Even Ford Doolittle raised his hand in support of his former student! (But he also supports the "Rampant LGT" model—for some reason Ford was allowed to have two votes. )
John Dupré, a philosopher at the University of Exeter in Exeter (UK) summarized the scientific part of the meeting. We are left with some important questions such as: how much does LGT compromise the tree of life? It's still an open question whether treelike thinking has to be abandoned for all of the tree of life or just for the base. The general consensus is that much of the upper regions are still treelike even though LGT may affect certain genes.
Sina Adl of the Department of Biology at Dalhousie University in Halifax. Nova Scotia (Canada) gave a short talk on PhyloCode a new classification scheme in biology. He pointed out that the current international rules of nomenclature don't work very well and need to be replaced.
The meeting closed with a talk by Susan Spath who has been with the National Center for Science Education (NCSE) in Oakland, California (USA). Her title was Cultural politics and the tree of life. Susan cautioned us to be careful when talking to the media. We should emphasize that most of the evolution that people care about (animals) is very treelike. She reminded us that talk of "Darwin was wrong" is very misleading.
As you might imagine, there was quite a good discussion on how much we should be concerned about creationists and how much we should cater to the difficulty journalists have in understanding genuine scientific controversy.
This was an excellent meeting and the organizers deserve a lot of credit for choosing the venue and the participants. It was by far the best meeting that I've attended in several decades. I plan to go to the next one in Exeter if they'll invite me back.
The third day (Saturday, August 1) began with a presentation by James McInerney of the National University of Ireland in Maynooth (Ireland): LUCA and LECA: Gene genesis in the genome of Eden. He examined genes in yeast cells and assigned them to ancestral homologs in bacteria and archaebacteria.
The majority of yeast genes are bacterial in origin but a significant minority come from archaebacteria. The genes with the archaebacterial origin are more likely to be found in information flow pathways (DNA replication, transcription, translation) and the genes from (eu)bacteria are more likely to be involved in other metabolic pathways.
The results suggest that the last eukaryotic common ancestor (LECA) was a hybrid formed from the fusion of a primitive bacterial cell and a primitive archaebacterial cell. The descendants of this first eukaryote subsequently entered into an endosymbiotic relationship with a proteobacterium giving rise to mitochondria and an influx of additional bacterial genes.
The second talk on day three was by Christophe Malaterre, a philosopher who divides his time between the IHPST at the Université Paris in Paris (France) and the Université Libre in Brussels (Belgium). Christophe is mostly interested in the early events in the history of life before the last universal common ancestor (LUCA) (On the roots of the tree of life). He is trying to define the basic properties of these "protocells."
This leads naturally to a debate about defining "life." During the transition from a bag of chemicals to a true living cell, there will be a zone where it will be very difficult to decide whether the protocell is living or not.
After a short break we returned to hear a presentation by William (Bill) Martin of Heinrich-Heine-Universität in Düsseldorf (Germany). His presentation was Endosymbiosis and gene transfers from endosymbionts, the most glaring insult to the tree. As the title implies, the key point is that a large percentage of nuclear genes in eukaryotes is derived from mitochondrial genes (proteobacteria) or from chloroplast genomes (cyanobacteria).
What this means is that aside from any consideration of the deep phylogeny of nuclear genes (bacterial or archaebacterial), one of the ancestors of eukaryotes is clearly a bacterial cell (proteobacteria). When you add in the bacterial contribution to genes that don't descend from mitochondria, it turns out that 75% of eukaryotic genes are bacterial in origin. No matter how you want to define the roots of the tree of life (tree, net, web) it is absolutely clear that the original Woose tree with eukaryotes on the same branch as archaebacteria is wrong!
Bill proposes that the first eukaryotic cell was formed when a primitive bacterial cell fused with a primitive archaebacterial cell. He would like to convince us that this primitive archaebacterium arose from within the current clade of Archaea. Most of us weren't convinced but none of us would dare say that to his face 'cause Bill is a very imposing man both intellectually and physically.
John Archibald of the Department of Biochemistry and Molecular Biology at Dalhousie University in Halifax, Nova Scotia (Canada) continued the endosymbiotic theme with a talk on Genetic and genomic threads in the tapestry of photosynthetic life: implications for "tree thinking."
The original photosynthetic eukaryote was the result of an endosymbiotic event involving an early eukaryotic host with mitochondria and a cyanobacterium. This gave rise to the three primary lineages: red algae, green algae, and glaucophytes. All photosynthetic eukaryotes have a single common ancestor represented by this unique endosymbiotic event.
The nuclei of modern flowering plants contain about 4500 genes derived from cyanobacteria via chloroplasts. Only half of these are targeted to the chloroplast. The rest contribute to the metabolism of the remaining part of the cell.
Some photosynthetic eukaryotes arise from a secondary endosymbiosis in which a chloroplast-containing algal cell is engulfed by a non-photosynthetic protist. In this case, genes can be transferred from the nucleus of the endosymbiote to the main nucleus, further complicating the ability to construct a treelike phylogeny that accurately reflects the true ancestral relationships of these species.
Frédéric Bouchard is a philosopher from the Université de Montréal in Montréal, Québec (Canada). When we returned from lunch we were treated to a discussion of: Endosymbiosis in light of reflections on symbiosis and the super organism.
Much of this presentation was based on symbiosis—a situation where two separate species cooperate. One or both species may benefit from this interaction and the question is how do we decide on the adaptive advantage, if any?
This was the only talk that seriously addressed the value of adaptationist thinking. Most people at this meeting seemed to assume that (almost) all evolution was due to adaptation. Bouchard even showed a slide of the Spandrels paper before going into a defense of the adaptationist program.
Andrew Roger is a former student of Ford Doolittle. He is now a professor in the Department of Biochemistry and Molecular Biology at Dalhousie University in Halifax, Nova Scotia (Canada). The title of his talk is a challenge to his former mentor: Deconstructing deconstructions of the tree of life: why a tree of microbes might be realizable, meaningful and useful.
The question is whether in light of significant LGT we can still detect the underlying vertical component in the web of life. Roger reminds us that this vertical component is very much a part of the evolutionary history of life. Let's not throw out the baby with the bath water when we question the tree of life.
There are basically two viable models of the early history of life. In the "Serious LGT" model, lateral gene transfer is ubiquitous but some genes may have been transferred less frequently than others. By looking at these genes it may be possible to recover the basic treelike vertical component of evolution.
Andrew looked at four protein encoding genes and found that they are mostly congruent with the ribosomal RNA tree of prokaryotes. The major divisions, such as cyanobacteria and proto-bacteria are confirmed. Thus, as Andrew points out, it's a mistake to assume that the web of life erases all traces of vertical descent as the alternative “Rampant LGT" model might suggest.
Almost everyone at the meeting supported the “Serious LGT" model as determined by a show of hands at the end of the day. Even Ford Doolittle raised his hand in support of his former student! (But he also supports the "Rampant LGT" model—for some reason Ford was allowed to have two votes. )
John Dupré, a philosopher at the University of Exeter in Exeter (UK) summarized the scientific part of the meeting. We are left with some important questions such as: how much does LGT compromise the tree of life? It's still an open question whether treelike thinking has to be abandoned for all of the tree of life or just for the base. The general consensus is that much of the upper regions are still treelike even though LGT may affect certain genes.
Sina Adl of the Department of Biology at Dalhousie University in Halifax. Nova Scotia (Canada) gave a short talk on PhyloCode a new classification scheme in biology. He pointed out that the current international rules of nomenclature don't work very well and need to be replaced.
The meeting closed with a talk by Susan Spath who has been with the National Center for Science Education (NCSE) in Oakland, California (USA). Her title was Cultural politics and the tree of life. Susan cautioned us to be careful when talking to the media. We should emphasize that most of the evolution that people care about (animals) is very treelike. She reminded us that talk of "Darwin was wrong" is very misleading.
As you might imagine, there was quite a good discussion on how much we should be concerned about creationists and how much we should cater to the difficulty journalists have in understanding genuine scientific controversy.
This was an excellent meeting and the organizers deserve a lot of credit for choosing the venue and the participants. It was by far the best meeting that I've attended in several decades. I plan to go to the next one in Exeter if they'll invite me back.
[Photo Credit: These photos are from Christina Behme. The bottom one is of me having dinner on the first evening with Ford Doolittle (left), John Dupré (standing), and Andrew Roger (right).]
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