Endless Forms Most Beautiful (book)


Endless Forms Most Beautiful: The New Science of Evo Devo and the Making of the Animal Kingdom is a 2005 book by the molecular biologist Sean B. Carroll. It presents a summary of the emerging field of evolutionary developmental biology and the role of toolkit genes. It has won numerous awards for science communication.
The book's somewhat controversial argument is that evolution in animals proceeds mostly by modifying the way that regulatory genes, which do not code for structural proteins, control embryonic development. In turn, these regulatory genes turn out to be based on a very old set of highly conserved genes which Carroll nicknames the toolkit. Almost identical sequences can be found across the animal kingdom, meaning that toolkit genes such as Hox must have evolved before the Cambrian radiation which created most of the animal body plans that exist today. These genes are used and reused, occasionally by duplication but far more often by being applied unchanged to new functions. Thus the same signal may be given at a different time in development, in a different part of the embryo, creating a different effect on the adult body. In Carroll's view, this explains how so many body forms are created with so few structural genes.
The book has been praised by critics, and called the most important popular science book since Richard Dawkins's The Blind Watchmaker.

Author

is a professor of molecular biology and genetics at the University of Wisconsin–Madison. He studies the evolution of cis-regulatory elements which help to regulate gene expression in developing embryos, using the fruit fly Drosophila as the model organism. He has won the Shaw Scientist Award and the Stephen Jay Gould Prize for his work.

Book

Context

The book's title quotes from the last sentence of Charles Darwin's 1859 The Origin of Species, in which he described the evolution of all living organisms from a common ancestor: "endless forms most beautiful and most wonderful have been, and are being, evolved." Darwin, however, was unable to explain how those body forms actually came into being. The early 20th century modern synthesis of evolution and genetics, too, largely ignored embryonic development to explain the form of organisms, since population genetics appeared to be an adequate explanation of how forms evolved. That task was finally undertaken at the end of the 20th century with the arrival of recombinant DNA technology, when biologists were able to start to explore how development was actually controlled.

Contents

; Part I The Making of Animals
limbs are highly specialised, adapted by evo-devo gene toolkit changes from the simple appendages of their trilobite-like ancestors.
; Part II Fossils, Genes, and the Making of Animal Diversity

Illustrations

The book is illustrated with photographs, such as of developing fruit fly embryos dyed to show the effects of toolkit genes, and with line drawings by Jamie W. Carroll, Josh P. Klaiss and Leanne M. Olds.

Awards

The evolutionary biologist Lewis Wolpert, writing in American Scientist, called Endless Forms Most Beautiful "a beautiful and very important book." He summarized the message of the book with the words "As Darwin's theory made clear, these multitudinous forms developed as a result of small changes in offspring and natural selection of those that were better adapted to their environment. Such variation is brought about by alterations in genes that control how cells in the developing embryo behave. Thus one cannot understand evolution without understanding its fundamental relation to development of the embryo." Wolpert noted that Carroll intended to explain evo-devo, and "has brilliantly achieved what he set out to do."
The evolutionary biologist Jerry Coyne, writing in Nature, described the book as for the interested lay reader, and called it "a paean to recent advances in developmental genetics, and what they may tell us about the evolutionary process." For him, the centrepiece was "the unexpected discovery that the genes that control the body plans of all bilateral animals, including worms, insects, frogs and humans, are largely identical. These are the 'homeobox' genes". He called Carroll a leader in the field and an "adept communicator", but admits to "feeling uncomfortable" when Carroll sets out his personal vision of the field "without admitting that large parts of that vision remain controversial." Coyne pointed out that the idea that the "'regulatory gene' is the locus of evolution" dates back to Roy Britten and colleagues around 1970, but was still weakly supported by observation or experiment. He granted that chimps and humans are almost 99% identical at DNA level, but points out that "humans and chimps have different amino-acid sequences in at least 55% of their proteins, a figure that rises to 95% for humans and mice. Thus we can't exclude protein-sequence evolution as an important reason why we lack whiskers and tails." He also noted that nearly half of human protein-coding genes do not have homologues in fruit flies, so one could argue the opposite of Carroll's thesis and claim that "evolution of form is very much a matter of teaching old genes to make new genes."
The review in BioScience noted that the book serves as a new Just So Stories, explaining the "spots, stripes, and bumps" that had attracted Rudyard Kipling's attention in his children's stories. The review praised Carroll for tackling human evolution and covering the key concepts of what Charles Darwin called the grandeur of life, suggesting that "Kipling would be riveted."
The science writer Peter Forbes, writing in The Guardian, called it an "essential book" and its author "both a distinguished scientist... and one of our great science writers." The journalist Dick Pountain, writing in PC Pro magazine, argued that Endless Forms Most Beautiful was the most important popular science book since Richard Dawkins's The Blind Watchmaker, "and in effect a sequel ."
The paleobiologist Douglas H. Erwin, reviewing the book for Artificial Life, noted that life forms from fruit flies to humans have far fewer genes than many biologists expected – human beings have only some 20,000. "How could humans, in all our diversity of cell types and complexity of neurons, require essentially the same number of genes as a fly, or worse, a worm ?" asks Erwin. He answered his own question about the "astonishing morphological diversity" of animals coming from "such a limited number of genes", praising Carroll's "insightful and enthusiastic" style, writing in a "witty and engaging" way, pulling the reader into the complexities of Hox and PAX-6, as well as celebrating the Cambrian explosion of life forms and much else.