development
pharyngula | August 2, 2006If you're at work, I hope you have headphones; if you don't, check in once you get home. Here are a couple of audio recordings of good science.
John Rennie speaks out on stem cells on an Australian program, the Science Show.
I reviewed her new book a while ago, and now you can hear Christiane Nüsslein-Volhard lecture on basic developmental biology. She has a very nice light German accent that makes it especially pleasant to listen to, I think.
pharyngula | July 31, 2006
The other day, I was asked a simple question that I knew the answer to, right off the top of my head, and since I'm nothing but lazy and lovin' the easy stuff, I thought I'd expand on it a bit here. The question was, "How do flounder get to be that way, with their eyes all on one side of the head?" And the answer is…pedantic and longwinded, but not too difficult.
The Pleuronectiformes, or flatfish, are a successful teleost order with about 500 known species, some of which are important commercially and are very tasty. The key to their success is their asymmetry: adults are camouflaged ambush…
pharyngula | July 30, 2006
Assuming that none of my readers are perfectly spherical, you all possess notable asymmetries—your top half is different from your bottom half, and your front or ventral half is different from you back or dorsal half. You left and right halves are probably superficially somewhat similar, but internally your organs are arranged in lopsided ways. Even so, the asymmetries are relatively specific: you aren't quite like that Volvox to the right, a ball of cells with specializations scattered randomly within. People predictably have heads on top, eyes in front, arms and legs in useful locations…
pharyngula | July 20, 2006Books from Nobel laureates in molecular biology have a tradition of being surprising. James Watson(amzn/b&n/abe/pwll) was catty, gossipy, and amusingly egotistical; Francis Crick(amzn/b&n/abe/pwll) went haring off in all kinds of interesting directions, like a true polymath; and Kary Mullis(amzn/b&n/abe/pwll) was just plain nuts. When I heard that Christiane Nüsslein-Volhard was coming out with a book, my interest and curiousity were definitely piqued. The work by Nüsslein-Volhard and Wieschaus has shaped my entire discipline, so I was eagerly anticipating what her new book,…
pharyngula | July 19, 2006How do you make a limb? Vertebrate limbs are classic models in organogenesis, and we know a fair bit about the molecular events involved. Limbs are induced at particular boundaries of axial Hox gene expression, and the first recognizable sign of their formation is the appearance of a thickened epithelial bump, the apical ectodermal ridge (AER). The AER is a signaling center that produces, in particular, a set of growth factors such as Fgf4 and Fgf8 that trigger the growth of the underlying tissue, causing the growing limb to protrude. In addition, there's another signaling center that forms…
pharyngula | July 18, 2006
Carl Zimmer wrote on evolution in jellyfish, with the fascinating conclusion that they bear greater molecular complexity than was previously thought. He cited a recent challenging review by Seipel and Schmid that discusses the evolution of triploblasty in the metazoa—it made me rethink some of my assumptions about germ layer phylogeny, anyway, so I thought I'd try to summarize it here. The story is clear, but I realized as I started to put it together that jeez, but we developmental biologists use a lot of jargon. If this is going to make any sense to anyone else, I'm going to have to step…
pharyngula | July 17, 2006
Do vertebrate embryos exhibit significant variation in their early development? Yes, they do—in particular, the earliest stages show distinct differences that mainly reflect differences in maternal investment and that cause significant distortions of early morphology during gastrulation. However, these earliest patterns represent workarounds, strategies to accommodate one variable (the amount of yolk in the egg), and the animals subsequently reorganize to put tissues into a canonical arrangement. Observations of gene expression during gastrulation are revealing deeper similarities that are…
pharyngula | July 13, 2006Yesterday, I reposted an article on homology within the neck and shoulder, which describes an interesting technique of using patterns of gene expression to identify homologous cellular pools; the idea is that we can discern homology more clearly by looking more closely at the molecular mechanisms, rather than focusing on final morphology and tissue derivation. Trust me, if you don't want to read it all—it's cool stuff, and one of the interesting points they make is that they've traced the fate of a particular bone not found in us mammals, but common in our pre-synapsid ancestors, the…
pharyngula | July 12, 2006
Neck anatomy has long terrified me. Way back when I was a grad student, my lab studied the organization and development of the hindbrain, which was relatively tidy and segmental; my research was studying the organization and development of the spinal cord, which was also tidy and segmental. The cervical region, though, was complicated territory. It's a kind of transitional zone between two simple patterns, and all kinds of elaborate nuclei and new cell types and structural organizations flowered there. I drew a line at the fifth spinal segment and said I'm not even going to look further…
pharyngula | July 10, 2006
I've written about this fascinating Drosophila gene, bicoid, several times before. It's a maternal effect gene, a gene that is produced by the mother and packaged into her eggs to drive important early events in development, in this case, establishing polarity, or which end of the egg is anterior (bicoid specifies which end of the egg will form the fly's head). Bicoid is also a transcription factor, or gene that regulates the activity of other genes. We also see evidence that it is a relatively new gene, one that is taking over a morphogenetic function that may have been carried out by…
pharyngula | July 9, 2006
Intelligent Design creationists are extremely fond of diagrams like those on the left. Textbook illustrators like them because they simplify and make the general organization of the components clear—reducing proteins to smooth ovoids removes distractions from the main points—but creationists like them for the wrong reasons. "Look at that—it's engineered! It's as if God uses a CAD program to design complex biological systems!" They like the implication that everything is done with laser-guided precision, and most importantly, that every piece was designed with intent, to fill a specific role…
pharyngula | July 9, 2006
Last week, I wrote a bit about maternal genes, specifically bicoid, and described how this gene was expressed in a gradient in the egg. Bicoid is both a transcription factor and a morphogen. The gene product regulates the activity of other genes, controlling their pattern of expression in the embryo. Today I thought I'd get more specific about the downstream targets of bicoid, the gap genes.
Expression domains of the gap genes. The pink bars chart the strength of gene expression as a function of position along the lengths of the embryo for hunchback (hb), huckebein (hkb), tailless (tll),…
pharyngula | July 9, 2006
In my previous comments about maternal effect genes, I was talking specifically about one Drosophila gene, bicoid, which we happen to understand fairly well. We know its sequence, we know how it is controlled, and we know what it does; we know where it falls in the upstream and downstream flow of developmental information in the cell. So today I'm going to babble a bit more about what bicoid is and does, and how it works.
Bicoid is a transcription factor.
The diagram above illustrates what a transcription factor (in this case, called "gene X") is. Gene X is transcribed to form a strand of…
pharyngula | July 9, 2006
In developmental biology, and increasingly in evolutionary biology, one of the most important fields of study is deciphering the nature of regulatory networks of genes. Most people are familiar with the idea of a gene as stretch of DNA that encodes a protein in a sequence of As, Ts, Gs, and Cs, and that's still an important part of the story. Most people may also be comfortable with the idea that mutations are events that change the sequence of As, Ts, Gs, and Cs, which can lead to changes in the encoded protein, which then causes changes in the function of the protein. These are essential…
pharyngula | July 7, 2006If you've read this outrageous WaPo op-ed that basically says you can't expect moral behavior from scientists who are glorified baby-killers, you might appreciate this rebuttal at the Give Up Blog. The foundation of the fundiecrat anti-science article is that 1) Hwang Woo Suk was bad, therefore all stem cell/cloning research is tainted, and 2) alternative techniques (most of which they don't seem to understand) and adult stem cells will give us all the answers we need.
Which actually leads into this week's "ask a science blogger" question:
On July 5, 1996, Dolly the sheep became the first…
pharyngula | July 5, 2006
Last week, I received some delusional e-mail from Phil Skell, who claims that modern biology has no use for evolutionary theory.
This will raise hysterical screeches from its true-believers. But, instead they should take a deep breath and tell us how the theory is relevant to the modern biology. For examples let them tell the relevance of the theory to learning…the discovery and function of hormones…[long list of scientific disciplines truncated]
Dr Skell is a sad case. He apparently repeats his mantra that biology has no need of evolution everywhere he goes, and has never bothered to…
pharyngula | June 27, 2006
One of many open questions in evolution is the nature of bilaterian origins—when the first bilaterally symmetrical common ancestor (the Last Common Bilaterian, or LCB) to all of us mammals and insects and molluscs and polychaetes and so forth arose, and what it looked like. We know it had to have been small, soft, and wormlike, and that it lived over 600 million years ago, but unfortunately, it wasn't the kind of beast likely to be preserved in fossil deposits.
We do have a tool to help us get a glimpse of it, though: the analysis of extant organisms, searching for those common features that…
pharyngula | June 21, 2006
PvM at the Panda's Thumb has already written a bit about this issue in the article "Human Gland Probably Evolved From Gills", but I'm not going to let the fact that I'm late to the party stop me from having fun with it. This is just such a darned pretty story that reveals how deeply vertebrate similarities run, using multiple lines of evidence.
Here's the start of the situation: fish have a problem. Like most animals, they need to maintain a specific internal salt concentration, but they are immersed in a solution that is much more dilute they they are (for freshwater fish) or much more…
pharyngula | June 16, 2006
The diagram above shows the early cleavages of the embryo of the scaphopod mollusc, Dentalium. You may notice a few peculiarities: the first cleavage is asymmetric, producing a cell called AB and a larger sister cell, CD. Before the second division, CD makes a large bulge, called a polar lobe, and it almost looks like it's a three-cell stage—this is called a trefoil embryo, and can look a bit like Mickey Mouse. The second division produces an A, a B, a C, and a D cell, and there's that polar lobe, about as large as the regular cells, so that it now resembles a 5-cell embryo. What's going on…
pharyngula | June 16, 2006
Maternal effect genes are a special class of genes that have their effect in the reproductive organs of the mutant; they are interesting because the mutant organism may appear phenotypically normal, and it is the progeny that express detectable differences, and they do so whether the progeny have inherited the mutant gene or not. That sounds a little confusing, but it really isn't that complex. I'll explain it using one canonical example of a maternal effect gene, bicoid.
Bicoid is a gene that is essential for normal axis formation in the fly, Drosophila. It is this gene product that…