"Epigenetics" is the (relatively) new buzzword. Old-fashioned genetics is boring so if you want to convince people (and grant agencies) that you're on the frontlines of research you have to say you're working on epigenetics. Even better, you can tell them that you are on the verge of overthrowing Darwinism and bringing back Jean-Baptiste Lamarck.
But you need to be careful if you adopt this strategy. Don't let anyone pin you down by defining "epigenetics." It's best to leave it as ambiguous as possible so you can adopt the Humpty-Dumpty strategy.1 Sarah C.P. Williams made that mistake a few years ago and incurred the wrath of Mark Ptashne [Core Misconcept: Epigenetics].More Recent Comments
Saturday, January 07, 2017
Friday, January 06, 2017
Genetic variation in the human population
With a current population size of over 7 billion, the human population should contain a huge amount of genetic variation. Most of it resides in junk DNA so it's of little consequence. We would like to know more about the amount of variation in functional regions of the genome because it tells us something about population genetics and evolutionary theory.
A recent paper in Nature (Aug. 2016) looked at a large dataset of 60,706 individuals. They sequenced the protein-coding regions of all these people to see what kind of variation existed (Lek et al., 2016) (ExAC). The group included representatives from all parts of the world although it was heavily weighted toward Europeans. The authors used a procedure called "principal component analysis" (PCA) to cluster the individuals according to their genetic characteristics. The analysis led to the typical clustering by "population clusters." (That term is used to avoid the words "race" and/or "subspecies.")Thursday, January 05, 2017
Birth and death of genes in a hybrid frog genome
De novo genes1 are quite rare but genome duplications are quite common. Sometimes the duplicated regions contain genes so the new genome contains two copies of a gene that was formerly present in only one copy. "Common" in this sense means on a scale of millions of years. Michael Lynch and his colleague have calculated that the rate of fixed gene duplication is about 0.01 per gene per million years (Lynch and Conery, 2003 a,b; Lynch 2007). Since a typical vertebrate has more than 20,000 genes, this means that 200 genes will be duplicated and fixed every million years.
The initial duplication event is likely to be deleterious since there will now be redundant DNA in the genome. The slightly deleterious allele (duplication) can be purged by negative selection in species with large population sizes (e.g. bacteria). But in species with smaller populations, natural selection is not powerful enough to eliminate slightly deleterious alleles so the duplication persists and may become fixed in the population.
Wednesday, January 04, 2017
Do seahorses evolve faster?
Genome sequencing is becoming so routine that it's difficult to publish your new genome sequence in a top journal. The trick is to find something unique and exciting about your genome so you can attract the attention of the leading journals. The latest success is the seahorse genome published in the Dec. 15, 2016 issue of Nature (Lin et al., 2016.
The species is the tiger tail seahorse Hippocampus comes. The assembled genome is 502Mb or about 1/6th the size of the human genome. The seahorse has 23,458 genes (protein-coding?) or about the same number as most other vertebrates. About 25% of the genome is junk (transposon-related).1Tuesday, January 03, 2017
Save the date!!! Michael Lynch is coming to Toronto
Michael Lynch is giving a seminar next week on Friday, January 13, 2017 in the Dept. of Ecology and Evolutionary Biology at the University of Toronto. The title is: Mutation, Drift, and the Origin of Subcellular Features. The talk is at 3PM in the Earth Sciences Centre rm B142.
The exit exam for biochemistry and molecular biology students
I'm a big fan of teaching fundamental concepts and principles and a big fan of teaching critical thinking. I think the most effective way of accomplishing these objectives is some form of student-centered learning. As I near the end of my teaching career, I wonder how we can tell if we succeed? It should be relatively easy to develop an exit exam for our biochemistry/molecular biology students to see if they grasp the basic concepts and can demonstrate an ability to think critically.
Here are some of the questions we could have on that exam. Each one requires a short answer with an explanation. The explanation doesn't have to be detailed or full of facts, just the basic idea. Students are graded on their ability to think critically about the answers. Many of the questions don't have a simple answer. Can you think of any other questions?Monday, January 02, 2017
You MUST read this paper if you are interested in evolution
A reader alerted me to a paper that was just published in BMC Biology.1 The author is Eugene Koonin. He makes the case for neutral evolution (random genetic drift) and against adaptationism. You may not agree with his take on evolutionary theory but you better be aware of it if you claim to be knowledgeable about evolution.
Koonin, E.V. (2016) Splendor and misery of adaptation, or the importance of neutral null for understanding evolution. BMC biology, 14:114. [doi: 10.1186/s12915-016-0338-2]
The study of any biological features, including genomic sequences, typically revolves around the question: what is this for? However, population genetic theory, combined with the data of comparative genomics, clearly indicates that such a “pan-adaptationist” approach is a fallacy. The proper question is: how has this sequence evolved? And the proper null hypothesis posits that it is a result of neutral evolution: that is, it survives by sheer chance provided that it is not deleterious enough to be efficiently purged by purifying selection. To claim adaptation, the neutral null has to be falsified. The adaptationist fallacy can be costly, inducing biologists to relentlessly seek function where there is none.
The Edge question 2017
Every year John Brockman asks his stable of friends an interesting question. Brockman is a literary agent and most of the people who respond are clients of his. (I want to be one.) The question and responses are posted on his website Edge. This year's question is, "What scientific term or concept ought to be more widely known?"
This year, the introduction is more interesting than the responses. Here's part of what Brokman wrote,Sunday, January 01, 2017
The most popular Sandwalk post of 2016
My most popular post last year was: An Intelligent Design Creationist disputes the evolution of citrate utilization in the LTEE ... Lenski responds. It had almost 20,000 views and 227 comments.
The article discussed a paper by Intelligent Design Creationist Scott Minnich who criticized Richard Lenski's ongoing evolution experiment on the grounds that no new information had been created in the evolution of ability to use citrate.Intelligent Design Creationists reveal their top story of 2016
Yesterday I posted an article on: Creationists list the top ten stories of 2016 . Some of you may have noticed that there were only nine stories. That's because Evolution News & Views didn't post their top story until today. I was pretty sure what it would be.
Let me remind you of the main point I made yesterday. Intelligent Design Creationists claim to have scientific evidence of intelligent design. They claim their movement is focused on demonstrating intelligent design but not on proving anything about who the designer might be.But that's not what the movement is all about. Most of their writings and speeches are focused on attacking evolution. They hope that by discrediting evolution and science they will, by default, support the case for gods (false dichotomy). They also hope that by promoting gaps in our knowledge they will lend support to those who want to insert gods into the gaps.
You don't need to take my word for it. Just look at what they think are the top stories of 2016. Most of their top nine stories were critiques of science in one way or another. There wasn't a single top story that advanced the case for intelligent design.
So, what about the #1 story? Is it going to be different?
Saturday, December 31, 2016
Creationists list the top ten stories of 2016
Intelligent Design Creationists are still trying to promote their views. They consistently claim to have positive evidence of intelligent design and they consistently complain whenever we point out what they actually do; they attack evolution/science. Their main talking point relies on the fallacy known as "false dichotomy." They assume that by casting doubt on evolution/science they lend support to their religious viewpoint.
Each year, the IDiots on Evolution News & Views (sic) publish their top ten stories. The series is linked to a fund-raising campaign so it's safe to assume they think these stories advance their cause. Let's see how many of the top stories promote intelligent design and how many are just criticisms of evolution/science. That should be revealing ...Tuesday, December 20, 2016
Is the high frequency of blood type O in native Americans due to random genetic drift?
The frequency of blood type O is very high in some populations of native Americans. In many North American tribes, for example, the frequency is over 90% and often approaches 100%. A majority of individuals in those populations have blood type O (homozygous for the O allele). [see Theme: ABO Blood Types]
Since there's no solid evidence that blood types are adaptive,1 the standard explanation is random genetic drift.Jerry Coyne explains it in Why Evolution Is True.
One example of evolution by drift may be the unusual frequencies of blood types (as in the ABO system) in the Old Order Amish and Dunker religious communities in America. These are small, isolated, religious groups whose members intermarry—just the right circumstances for rapid evolution by genetic drift.
Accidents of sampling can also happen when a population is founded by just a few immigrants, as occurs when individuals colonize an island or a new area. The almost complete absence of genes producing the B blood type in Native American populations, for example, may reflect the loss of this gene in a small population of humans that colonized North America from Asia around twelve thousand years ago.
Thursday, December 15, 2016
Nature opposes misinformation (pot, kettle, black)
The lead editorial in last week's issue of Nature (Dec. 8, 2016) urges us to Take the time and effort to correct misinformation. The author (Phil Williamson) is a scientist whose major research interest is climate change and the issue he's addressing is climate change denial. That's a clear example of misinformation but there are other, more subtle, examples that also need attention. I like what he says in the opening paragraphs,
Most researchers who have tried to engage online with ill-informed journalists or pseudoscientists will be familiar with Brandolini’s law (also known as the Bullshit Asymmetry Principle): the amount of energy needed to refute bullshit is an order of magnitude bigger than that needed to produce it. Is it really worth taking the time and effort to challenge, correct and clarify articles that claim to be about science but in most cases seem to represent a political ideology?I've had a bit of experience trying to engage journalists who appear to be ill-informed. I've had little success in convincing them that their reporting leaves a lot to be desired.
I think it is. Challenging falsehoods and misrepresentation may not seem to have any immediate effect, but someone, somewhere, will hear or read our response. The target is not the peddler of nonsense, but those readers who have an open mind on scientific problems. A lie may be able to travel around the world before the truth has its shoes on, but an unchallenged untruth will never stop.
I agree with Phil Williamson that challenging falsehoods and misrepresentation is absolutely necessary even if it has no immediate effect. Recently I posted a piece on the misrepresentations of the ENCODE results in 2007 and pointed a finger at Nature and their editors [The ENCODE publicity campaign of 2007]. They are responsible because they did not ensure that the main paper (Birney et al., 2007) was subjected to appropriate peer review. They are responsible because they promoted misrepresentations in their News article and they are responsible because they published a rather silly News & Views article that did little to correct the misrepresentations.
That was nine years ago. Nature never admitted they were partly to blame for misrepresenting the function of the human genome.
Wednesday, December 14, 2016
The ENCODE publicity campaign of 2007
ENCODE1 published the results of a pilot project in 2007 (Birney et al., 2007). They looked at 1% (30Mb) of the genome with a view to establishing their techniques and dealing with large amounts of data from many different groups. The goal was to "provide a more biologically informative representation of the human genome by using high-throughput methods to identify and catalogue the functional elements encoded."
The most striking result of this preliminary study was the confirmation of pervasive transcription. Here's what the ENCODE Consortium leaders said in the abstract,Together, our results advance the collective knowledge about human genome function in several major areas. First, our studies provide convincing evidence that the genome is pervasively transcribed, such that the majority of its bases can be found in primary transcripts, including non-protein-coding transcripts, and those that extensively overlap with one another.ENCODE concluded that 93% of the genome is transcribed in one tissue or another. There are two possible explanations that account for pervasive transcription.
Tuesday, December 13, 2016
The proteome complexity myth
A reader pointed me to the ThermoFisher Scientific website. ThermoFisher Scientific is a major supply of scientific equipment and supplies. They created their life sciences wesite to help inform their customers and sell more products. The page I'm interested in is: Overview of Post-Translational Modifications (PTMs). It begins with,
Within the last few decades, scientists have discovered that the human proteome is vastly more complex than the human genome. While it is estimated that the human genome comprises between 20,000 and 25,000 genes (1), the total number of proteins in the human proteome is estimated at over 1 million (2). These estimations demonstrate that single genes encode multiple proteins. Genomic recombination, transcription initiation at alternative promoters, differential transcription termination, and alternative splicing of the transcript are mechanisms that generate different mRNA transcripts from a single gene (3).
The increase in complexity from the level of the genome to the proteome is further facilitated by protein post-translational modifications (PTMs). PTMs are chemical modifications that play a key role in functional proteomics, because they regulate activity, localization and interaction with other cellular molecules such as proteins, nucleic acids, lipids, and cofactors.