Mapping fitness: ribozymes, landscapes, and Seattle

A few months ago, we were looking at the concept of a fitness landscape and how new technologies are creating opportunities for biologists to look in detail at relationships between genetics and fitness. The first post discussed the concepts of a fitness landscapes and adaptive walks, with some focus on the limitations of the metaphor. The second post summarized some recent work on bacterial fitness and mutation rates, with the concept of a fitness landscape as a theme, and the third post reviewed another recent paper, one that described techniques for studying fitness landscapes in detail by linking protein function (which can be screened and/or selected) and genetic information. Here we'll look at yet another approach to the problem, in which the subject of the analysis is not an organism (as in the first paper) or a protein (as in the second paper) but an RNA molecule.

New reading on "junk DNA"

John Farrell runs an interesting blog at Forbes.com, and he regularly discusses genetics, design, and other topics of interest around here. His latest points to work by Larry Moran and Ryan Gregory, both of whom have debunked some of the "junk DNA" misinformation concocted by design theorists, then looks at some interesting new blogging from one Stanley Rice. It's interesting stuff.

Casey Luskin shows up in the comments. Nothing new there. Run over and check it out.

Alu need to know about parasitic DNA: telling the whole story about Alu elements and "design"

So, Alu elements are mobile DNA modules that can exert diverse influences on genomes and the organisms harboring them. They can affect genome function in constructive ways, by altering gene expression or supporting chromosome structure. And they can be damaging, even deadly. There are more than a million of them in the human genome, and we don't know what each one does. But, as I explained in the first post in this series, we do know that they can play both helpful and harmful roles, in the same way that other kinds of parasites can be good, bad, or indifferent.

Alu elements and other genome-wide repeats are a big problem for intelligent design (ID) theorists of some stripes. Any ID proponent who claims that genomes are carefully-designed, well-optimized systems must deal with the reality of the enormous numbers of mobile elements in (for example) the human genome. Now, I can think of various ways such an ID theorist might discuss Alu elements. She could propose that all of their characteristics (including their mobility) are part of their design, such that they can bring new design features quickly into being; she could propose that their mobility is a "bug" rather than a "feature," and perhaps speculate on how things went wrong; she could postulate that the damage caused by their expression and their mobility is being misattributed to the genome when it is instead caused by some other external process. (Or she could say, "We're still working on that one.")

Exploring the protein universe: a response to Doug Axe

One of the goals of the intelligent design (ID) movement is to show that evolution cannot be random and/or unguided, and one way to demonstrate this is to show that an evolutionary transition is impossibly unlikely without guidance or intervention. Michael Behe has attempted to do this, without success. And Doug Axe, the director of Biologic Institute, is working on a similar problem. Axe's work (most recently with a colleague, Ann Gauger) aims (in part, at least) to show that evolutionary transitions at the level of protein structure and function are so fantastically improbable that they could not have occurred "randomly."

Recently, Axe has been writing on this issue. First, he and Gauger just published some experimental results in the ID journal BIO-Complexity. Second, Axe wrote a blog post at the Biologic site in which he defends his approach against critics like Art Hunt and me. Here are some comments on both.

How do fish adapt to life in hydrogen sulfide?

To find out, and to read some of the best recent blogging on evolution, visit the new Carnival of Evolution, 35th Edition, at Lab Rat. And go to the official carnival page to learn more about the Carnival of Evolution and perhaps to sign up as a future host.

Alu need to know about parasitic DNA: Alu elements and blindness

Age-related macular degeneration (AMD) is a leading cause of blindness in humans, and the leading cause of visual impairment during advanced age. The condition comes in two basic forms, the most severe of which is untreatable. Called geographic atrophy (GA), this condition involves the steady destruction of the retinal pigment epithelium, a layer of tissue in the eye that is essential for the health and maintenance of the photoreceptors in the retina. Loss of the pigment epithelium means certain death for the photoreceptors, and that means visual impairment and then blindness for the affected person.

A major publication in Nature last month (Kaneko et al., "DICER1 deficit induces Alu RNA toxicity in age-related macular degeneration," Nature 17 March 2011) now points to one likely cause of AMD, and in the process provides a chilling example of what can happen when the parasitic Alu elements in our genomes (see the previous post for an introduction) are left unrestrained.

Alu need to know about parasitic DNA: Introduction to Alu elements

Defenders of intelligent design theory often dwell on the topic of "junk DNA," which has been molded into a masterpiece of folk science. The ID approach to "junk DNA" involves a fictional story about "Darwinism" discouraging its study, and a contorted and simplistic picture of a "debate" about whether "junk DNA" has "function." The fictional story is ubiquitous despite being repeatedly debunked. But the picture of an ongoing "debate" about "function" is harder to sort out. Like most propaganda, that picture contains enough truth to sound plausible. (Browse my "Junk DNA" posts, and work by Ryan Gregory and Larry Moran, for more information on errors and folk science associated with these topics.)

There is, in fact, some scientific disagreement about functions of various elements in genomes, but it's not the crude standoff that ID apologists depict, and it has very little to do with "Darwinism." The debate, if we must call it that, is about at least two matters: 1) the extent to which certain genomic elements contribute to normal function or development of organisms; and 2) the means by which we might determine this. The debate is not about whether non-coding DNA can have function, or even about whether some segments of non-coding DNA do have function. That debate was invented by anti-evolution propagandists.

34th Carnival of Evolution

Welcome to the 34th Edition (1 April 2011) of the Carnival of Evolution, and welcome to Quintessence of Dust. It's nice to be hosting this fine carnival, and to see that it's still going strong.

I've organized the carnival under some chapter and section headings that I got from some old Victorian's magnum opus, but I think you'll find the topics require no further creative embellishment.

Mapping fitness: protein display, fitness, and Seattle

A couple of months ago we started looking at the concept of fitness landscapes and at some new papers that have significantly expanded our knowledge of the maps of these hypothetical spaces. Recall that a fitness landscape, basically speaking, is a representation of the relative fitness of a biological entity, mapped with respect to some measure of genetic change or diversity. The entity in question could be a protein or an organism or a population, mapped onto specific genetic sequences (a DNA or protein sequence) or onto genetic makeup of whole organisms. The purpose of the map is to depict the effects of genetic variation on fitness.

Suppose we want to examine the fitness landscape represented by the structure of a single protein. Our map would show the fitness of the protein (its function, measured somehow) and how fitness is affected by variations in the structure of the protein (its sequence, varied somehow). It's hard enough to explain or read such a map. Even more daunting is the task of creating a detailed map of such a widely-varying space. Two particular sets of challenges come to mind.

It's just a stage. A phylotypic stage. Part III: Fish and more

Given that disputes over the existence and meaning of the phylotypic stage and the hourglass model have simmered in various forms for a century and a half, the remarkable correspondence between the hourglass model and gene expression divergence discovered by Kalinka and Varga and colleagues would be big news all by itself. But amazingly, that issue of Nature included two distinct reports on the underpinnings of the phylotypic stage. The other article involved work in another venerable model system in genetics, the zebrafish.

The report is titled "A phylogenetically based transcriptome age index mirrors ontogenetic divergence patterns" and is co-authored by Tomislav Domazet-Loso and Diethard Tautz. To understand how their work has shed light on the phylotypic stage and the evolution of development, we'll need to look first at an approach to the analysis of evolutionary genetics that these two scientists pioneered: phylostratigraphy.