This question doesn't seem like a good fit for Biostars. In fact, it seems like an axe-grindey rant masquerading as a question. I wonder if it should be closed.

BTW, certainly ID and other creationist stuff wouldn't be of big interest here, because creationists can't use BLAST.

i) ?? ii) Now four people

sorry, but this discussion reminds me of this video game: Socrate Jones http://www.kongregate.com/games/ChiefWakamakamu/socrates-jones-pro-philosopher?acomplete=jones

I think we learned what you think about epigenetics, but I don't think that this is the same as learning about epigenetics.

The question is first depending on your definition of Epigenetics, asking for clarification.

please don't close a post that seems to get a lot of followups/comments and feedback - some of issues that are mentioned may be valid even if the formulation feels deliberately adversarial

HA, now your trying to tell us you just wanted teach a lecture in logic (we are mostly strong supporters of logical thinking already, as you might have noticed). However, I doubt that Socrates would have committed a voluntary logical fallacy described by Polarize.

Yeah, epigenetics is a relatively vague concept, constantly changing in part because the term is currently "hot". Does that really surprise you?

I don't get it.

from wikipedia: epigenetics is the study of changes in gene expression or cellular phenotype, caused by mechanisms other than changes in the underlying DNA sequence.

Do you have a problem with that definition?

Do you think it unlikely, for example, that changes in methylation can result in changes in gene expression?

Upvote for the last sentence. Trying to bring logic to an irrational discussion is noble, but at some point you realize it's mostly a waste of time.

"what is the evidence to suggest that epigenetics is pseudo-science?"

Lamarckian theory of evolution has been discredited long time back. The burgeoning field of epigenetics is trying to revive it by claiming that they have molecular evidence, but the supposed proofs are inflated as the Bird paper shows.

So, epigenetics is pseudo-science, because there is little scientific data to support the claims. In contrast, when Darwin presented his theory of evolution, he had extensive evidence but his theory was not accepted for many decades even by well-known biologists.

What does that say about strong association between popular opinion and 'truth'?

I should have said 'junk science pretending as real biology'. Both epigenetics and ID take us back to pre-Darwinian biology on evolutionary origin of species, one proposed by Lamarck and other proposed by Catholic church.

"I don't think the functional aspect of epigenetics is in question. Modifications on DNA that produces some kind of effect is pretty well studied."

Are you making ENCODE's mistake of taking 'some kind of effect' to 'functional'? Bird paper disputes functional aspects as well especially in developing tissues.

"It's an interesting discussion. But perhaps discussing it in BioStar questions is not the best way to get your point across."

Well, there is a newly published Cell paper on the same topic too :)

I presume the end goal of those asking questions in biostars is to figure out some aspect of biology, and most people here are not technicians trying to fix a small error here and there. If someone asks a pseudo-technical question on intelligent design, will the biostar community stay focused on the technical part or will they challenge his broader philosophy on intelligent design?

This is a good answer, but I don't agree with closing.

Indeed, there are no answers on Intelligent Design because people have not asked questions that would involve both ID and bioinformatics. I think we would be more than happy to answer those as well.

Well, so I hoped ....

"there's enough literature from enough different labs doing RNAi, creating KO mice, or applying drug compounds that there shouldn't be any debate over this."

Would you please post a link to a few convincing papers? Not a trick question. I like to study them in more detail.

Bird wrote about the inheritance aspect, but even the developmental aspect is questionable. You can check Ptashne's article on that (http://www.pnas.org/content/110/18/7101.full). How do cells retain acquired memory after one cell 'learns' it from the environment?

"The Core Concepts Misconception Curiously, the picture I have just sketched is absent from the Core Concepts article. Rather, it is said, chemical modifications to DNA (e.g., methylation) and to histones—the components of nucleosomes around which DNA is wrapped in higher organisms—drive gene regulation. This obviously cannot be true because the enzymes that impose such modifications lack the essential specificity: All nucleosomes, for example, “look alike,” and so these enzymes would have no way, on their own, of specifying which genes to regulate under any given set of conditions. I ignore DNA methylation in the remainder of this article because its possible role in development remains unclear, and it does not exist in, for example, flies and worms—model organisms the study of which has taught us much of what we know about development. Histone modifications are called “epigenetic” in the Core Concepts article, a word that for years has implied memory (see Epigenetic). This is odd: It is true that some of these modifications are involved in the process of transcription per se—facilitating removal and replacement of nucleosomes as the gene is transcribed, for example (9, 10). And some are needed for certain forms of repression (11). But all attempts to show that such modifications are “copied along with the DNA,” as the article states, have, to my knowledge, failed (12⇓–14). Just as transcription per se is not “remembered” without continual recruitment, so nucleosome modifications decay as enzymes remove them (the way phosphatases remove phosphates put in place on proteins by kinases), or as nucleosomes, which turn over rapidly compared with the duration of a cell cycle, are replaced (15). For example, it is simply not true that once put in place such modifications can, as stated in the Core Concepts article, “lock down forever” expression of a gene (7).

It is true, however, that during the course of development as well as at its final stages, certain genes, once “turned on” by a transiently acting transcription factor, stay on even in the absence of the original activator that triggered expression. But I noted above that activation of transcription quickly decays once the activator is removed or inhibited. And so whence this critical memory effect?"

You wrote - "We're still in the infancy of the epigenetics field, so I expect it'll take a number of years to really separate the wheat from the chaff"

Based on the conceptual arguments made by Ptashne, there is no wheat. Do you think it makes sense to address them before collecting huge amount of data on epigenetics, such as the epigenome project likes to do?

Nothing personal, not at all :) You are a great person and very helpful guy here, and I acknowledge that Biostar is a valuable community.

I am trying to interject some relevant biological topics among a large spectrum of software-related questions, and I hope that is ok given that the root of biostar is biology. I disagree with you that I did only name-dropping and did not make my point convincing. I linked to three publications by respected biologists (respected because they wrote text-books on the gene-regulation related topics), and each paper covers all arguments against epigenetics fairly well. I thought cutting-and-pasting from those papers would be unnecessary given that the papers are only one click away.

If you suggest so, I can modify my question/comments with text from those papers to see if any answer really addressed the questions raised on epigenetics by those authors.

Nature wrote - "“Epigenetics is a useful word if you don't know what's going on — if you do, you use something else.” [In an earlier era, religion and superstition held that role :).]

http://www.nature.com/news/2008/081022/full/4551023a.html

"No one denies that epigenetics is fashionable: its usage in PubMed papers increased by more than tenfold between 1997 and 2007. And few deny that epigenetics is important. What they do disagree on is what it is.

"The idea is that there is a clear meaning and that it's being violated by people like me who use it more loosely," says Adrian Bird at the University of Edinburgh, UK. Last year he suggested this as a definition: "the structural adaptation of chromosomal regions so as to register, signal or perpetuate altered activity states"3. But this wide-ranging proposal, which takes on-board pretty much every physical indicator of a gene's activity is "preposterously dumb", says Mark Ptashne of Memorial Sloan–Kettering Cancer Center in New York, who has published his own take on the word's usage4. "I've grown to be very careful about using the term," says Bing Ren, who studies gene regulation at the University of California, San Diego.

According to the 'traditional' definition that Ptashne favours, epigenetics describes "a change in the state of expression of a gene that does not involve a mutation, but that is nevertheless inherited in the absence of the signal or event that initiated the change". The classic example is found in a bacteriophage called Lambda, which stays dormant in the genome of generations of cells through inheritance of a regulatory protein. These sort of processes are basic to some of the most pressing questions in biology today: such mechanisms are needed to explain how a single-celled embryo can generate cells that are genetically identical, but express a different array of genes and hence take on different jobs in blood, brain or muscle for generation after generation.

Over the past few years, however, all kinds of processes associated with gene control have been subsumed under the moniker. For example, 'epigenetic' is often used to refer to the chemical modification of histones — proteins that DNA winds around — which is involved in gene regulation. This infuriates those who learned the classical definition; they say it puts these modifications at the heart of development and disease despite scant evidence that they are inherited. "Why did histone marks become epigenetic?" says Kevin Struhl at Harvard Medical School in Boston. "People decided that if they call them that it makes them interesting." Others say that it is not about making things sound important, it is more the lack of any other phrase with which to collectively refer to this type of work.

The word had dual meanings long before the current debate. In the 1940s, Conrad Waddington used it to describe how the genetic information in a 'genotype' manifests itself as a set of characteristics, or 'phenotype'. In 1958, David Nanney at the University of Michigan, Ann Arbor, borrowed the term to describe "messy" inherited phenomena that could not be explained by conventional genetics5. "It was controversial in 1958 and everything died down and it has come alive again," says Nanney. "It took 40 years for epigenetics to become a major word in the vocabulary of modern biology."

“Epigenetics is a useful word if you don't know what's going on — if you do, you use something else.” A lot of money can ride on whether a researcher is, or is not, studying epigenetics: the US National Institutes of Health (NIH) this month started handing out US$190 million as part of its epigenomics initiative and other countries are pouring funding into the area. (The NIH is careful to define the epigenetics it is paying for as including both heritable and non-heritable changes in gene activity, something that Ptashne describes as "a complete joke".) Bird says he remains in favour of a relaxed usage. "Epigenetics is a useful word if you don't know what's going on — if you do, you use something else," he says."