Von Baer's laws (embryology) explained

In developmental biology, von Baer's laws of embryology (or laws of development) are four rules proposed by Karl Ernst von Baer to explain the observed pattern of embryonic development in different species.[1]

von Baer formulated the laws in his book On the Developmental History of Animals (German: Über Entwickelungsgeschichte der Thiere), published in 1828, while working at the University of Königsberg. He specifically intended to rebut Johann Friedrich Meckel's 1808 recapitulation theory. According to that theory, embryos pass through successive stages that represent the adult forms of less complex organisms in the course of development, and that ultimately reflects Latin: scala naturae (the great chain of being).[2] von Baer believed that such linear development is impossible. He posited that instead of linear progression, embryos started from one or a few basic forms that are similar in different animals, and then developed in a branching pattern into increasingly different organisms. Defending his ideas, he was also opposed to Charles Darwin's 1859 theory of common ancestry and descent with modification, and particularly to Ernst Haeckel's revised recapitulation theory with its slogan "ontogeny recapitulates phylogeny".[3] [4] Darwin was however broadly supportive of von Baer's view of the relationship between embryology and evolution.

The laws

Von Baer described his laws in his book Über Entwickelungsgeschichte der Thiere. Beobachtung und Reflexion published in 1828.[5] They are a series of statements generally summarised into four points, as translated by Thomas Henry Huxley in his Scientific Memoirs:[6]

  1. The more general characters of a large group appear earlier in the embryo than the more special characters.
  2. From the most general forms the less general are developed, and so on, until finally the most special arises.
  3. Every embryo of a given animal form, instead of passing through the other forms, rather becomes separated from them.
  4. The embryo of a higher form never resembles any other form, but only its embryo.

Description

Von Baer discovered the blastula (the early hollow ball stage of an embryo) and the development of the notochord (the stiffening rod along the back of all chordates, that forms after the blastula and gastrula stages). From his observations of these stages in different vertebrates, he realised that Johann Friedrich Meckel's recapitulation theory must be wrong. For example, he noticed that the yolk sac is found in birds, but not in frogs. According to the recapitulation theory, such structures should invariably be present in frogs because they were assumed to be at a lower level in the evolutionary tree. Von Baer concluded that while structures like the notochord are recapitulated during embryogenesis, whole organisms are not.[7] He asserted that (as translated):

In terms of taxonomic hierarchy, according to von Baer, characters in the embryo are formed in top-to-bottom sequence, first from those of the largest and oldest taxon, the phylum, then in turn class, order, family, genus, and finally species.[7]

Reception

The laws received a mixed appreciation. While they were criticised in detail, they formed the foundation of modern embryology.[1]

Charles Darwin

The most important supporter of von Baer's laws was Charles Darwin. Darwin came across von Baer's laws from the work of Johannes Peter Müller in 1842, and realised that it was a support for his own theory of descent with modification.[8] Darwin was a critique of the recapitulation theory and agreed with von Baer that an adult animal is not reflected by an embryo of another animal, and only embryos of different animals appear similar.[9] He wrote in his Origin of Species (first edition, 1859):

Darwin also said:

It has already been casually remarked that certain organs in the individual, which when mature become widely different and serve for different purposes, are in the embryo exactly alike. The embryos, also, of distinct animals within the same class are often strikingly similar: a better proof of this cannot be given, than a circumstance mentioned by Agassiz, namely, that having forgotten to ticket the embryo of some vertebrate animal, he cannot now tell whether it be that of a mammal, bird, or reptile.[10]

Darwin's attribution to Louis Agassiz was a mistake,[11] and was corrected in the third edition as von Baer.[12] He further explained in the later editions of Origin of Species (from third to sixth editions), and wrote:

It might be thought that the amount of change which the various parts and organs [of vertebrates] undergo in their development from the embryo to maturity would suffice as a standard of comparison; but there are cases, as with certain parasitic crustaceans, in which several parts of the structure become less perfect, so that the mature animal cannot be called higher than its larva. Von Baer's standard seems the most widely applicable and the best, namely, the amount of differentiation of the different parts (in the adult state, as I should be inclined to add) and their specialisation for different functions.[13] [14]

Even so, von Baer was a vociferous anti-Darwinist, although he believed in the common ancestry of species.[15] Devoting much of his scholarly effort to criticising natural selection, his criticism culminated with his last work Über Darwins Lehre ("On Darwin's Doctrine"), published in the year of his death in 1876.[16]

Later biologists

The British zoologist Adam Sedgwick studied the developing embryos of dogfish and chicken, and in 1894 noted a series of differences, such as the green yolk in the dogfish and yellow yolk in the chicken, absence of embryonic rim in chick embryos, absence of blastopore in dogfish, and differences in the gill slits and gill clefts. He concluded:

Modern biologists still debate the validity of the laws. In one line of argument, it is said that although every detail of von Baer's law may not work, the basic assumption that early developmental stages of animals are highly conserved is a biological fact.[17] But an opposition says that there are conserved genetic conditions in embryos, but not the genetic events that govern the development.[18] One example on the problem of von Baer's law is the formation of notochord before heart. This is due to the fact that heart is present in many invertebrates, which never have notochord.[19]

See also

Notes and References

  1. Abzhanov . Arhat . von Baer's law for the ages: lost and found principles of developmental evolution . Trends in Genetics . 2013 . 29 . 12 . 712–722 . 10.1016/j.tig.2013.09.004 . 24120296. 9158143 .
  2. Opitz . John M. . Schultka . Rüdiger . Göbbel . Luminita . Meckel on developmental pathology . American Journal of Medical Genetics Part A . 2006 . 140A . 2 . 115–128 . 10.1002/ajmg.a.31043 . 16353245 . 30513424 .
  3. Garstang . Walter . Walter Garstang . The Theory of Recapitulation: A Critical Re-statement of the Biogenetic Law . Journal of the Linnean Society of London, Zoology . 1922 . 35 . 232 . 81–101 . 10.1111/j.1096-3642.1922.tb00464.x.
  4. Løvtrup . Søren . Søren Løvtrup . On von Baerian and Haeckelian Recapitulation . Systematic Zoology . 1978 . 27 . 3 . 348–352 . 10.2307/2412887 . 2412887 .
  5. Book: Baer, Karl Ernst von . Über Entwickelungsgeschichte der Thiere. Beobachtung und Reflexion . 1828 . Bei den Gebrüdern Bornträger . Königsberg . 10.5962/bhl.title.6303.
  6. Book: Huxley . Thomas Henry . Thomas Huxley . Henfrey . Arthur . Scientific memoirs, selected from the transactions of foreign academies of science, and from foreign journals. Natural history . 1853 . Taylor and Francis . 10.5962/bhl.title.28029 .
  7. Book: Matthen . Mohan . Stephens . Christopher . Philosophy of Biology . 2007 . Elsevier . Amsterdam . 978-0-080-47124-2 . 444–445 .
  8. Book: Gilbert, Scott F. . Scott F. Gilbert . Developmental Biology . Sinauer Associates . 2000 . 978-0878932436 . Online.
  9. Web site: Barnes . M. Elizabeth . 2014 . Karl Ernst von Baer's Laws of Embryology . 2020-10-04 . The Embryo Project Encyclopedia.
  10. Book: Darwin, Charles . On the Origin of Species . John Murray . 1859 . London . 438–439.
  11. Rogers . James Allen . 1973 . The Reception of Darwin's Origin of Species by Russian Scientists . Isis . 64 . 4 . 484–503 . 10.1086/351177 . 229645. 4593473 . 36129302 .
  12. Book: Darwin, Charles . The Origin of Species . John Murray . 1861 . 3 . London . 470–471.
  13. Book: Darwin, Charles . On the Origin of Species . John Murray . 1861 . 133.
  14. Book: Darwin, Charles . The Origin of Species . John Murray . 1872 . 6 . London . 97.
  15. Dagg . Joachim L. . Derry . J. F. . 2020 . Charles Darwin did not mislead Joseph Hooker in their 1881 Correspondence about Leopold von Buch and Karl Ernst von Baer . Annals of Science . 77 . 3 . 349–365 . 10.1080/00033790.2020.1790659 . 32755351. 221016353 .
  16. Book: Vucinich, Alexander . Darwin in Russian Thought . 1988 . University of California Press . Berkeley . 978-0-52-006283-2 . 93 .
  17. Garfield . David A. . Wray . Gregory A. . 2009 . Comparative embryology without a microscope: using genomic approaches to understand the evolution of development . Journal of Biology . 8 . 7 . 65 . 10.1186/jbiol161 . 2736668 . 19664180 . free .
  18. Kalinka . Alex T. . Tomancak . Pavel . 2012 . The evolution of early animal embryos: conservation or divergence? . Trends in Ecology & Evolution . 27 . 7 . 385–393 . 10.1016/j.tree.2012.03.007 . 1872-8383 . 22520868 . 2012TEcoE..27..385K .
  19. Løvtrup . Søren . Søren Løvtrup . 1987 . Phylogenesis, ontogenesis and evolution . Italian Journal of Zoology . en . 54 . 3 . 199–208 . 10.1080/11250008709355584. free .