Abstract
Evolutionary developmental biologists categorize many different kinds of things, from ontogenetic stages to modules of gene activity. The process of categorization—the establishment of “kinds”—is an implicit part of describing the natural world in consistent, useful ways, and has an essentially practical rather than philosophical basis. Kinds commonly serve one of three purposes: they may function (1) as practical tools for communication; (2) to support prediction and generalization; or (3) as a basis for theoretical discussions. Beyond the minimal requirement that classifications reflect biological reality, what sorts of kinds or classification will be useful in advancing a research program depends on the epistemological context. Thus, the important meaning of “natural” in “natural kinds” is not “natural with respect to nature,” but “natural with respect to the question.” This conclusion arises from the recognition that the proper role of concepts (e.g. natural kind, module, homology, model) is not to answer biological questions, but rather to help frame them. From a scientist’s perspective, arguing about the wording (or existence) of a single definition of “natural” or “kind” is beside the point: we get more work done by letting the question at hand determine what kinds of kinds are natural, on the basis of their ability to help answer it. We should be content to let “natural kinds” remain vague, multivalent, and–therefore broadly useful. For a philosopher like Hacking, the diverse, disparate, and ultimately incommensurable uses of the term “natural kind” have diluted its value so far that it loses all meaning. For practicing scientists, however, defining useful kinds in the context of particular questions and systems remains a productive epistemological strategy.
This is a preview of subscription content, log in via an institution to check access.
Access this article
We’re sorry, something doesn't seem to be working properly.
Please try refreshing the page. If that doesn't work, please contact support so we can address the problem.
Notes
This is true even in relatively abstract theory- and mathematics-intensive areas of biology: the ultimate goal of mathematical ecology is to shed new light on ecosystems, not on mathematics (Bolker 2008).
I am indebted to the thoughtful (and anonymous) reviewer of the manuscript for this point.
This point as well is thanks to the reviewer's helpful observations.
It’s not that biologists never argue about definitions: much ink has been spilled concerning certain terms, particularly those such as “adaptation” or “homologue” that imply particular forms of causality.
References
Beckers J, Wurst W, Hrabé de Angelis M (2009) Towards better mouse models: enhanced genotypes, systemic phenotyping and envirotype modelling. Nat Rev Genet 10:371–380
Bedell M, Jenkins N, Copeland N (1997) Mouse models of human disease. Part I: techniques and resources for genetic analysis in mice. Genes Dev 11:1–10
Beloussov L, Grabovsky V (2006) Morphomechanics: goals, basic experiments and models. Int J Dev Biol 50:81
Bolker JA (1993) Gastrulation and mesoderm morphogenesis in the white sturgeon. J Exp Zool 266:116–131
Bolker JA (1995) Model systems in developmental biology. BioEssays 17:451–455
Bolker JA (2000) Modularity in development and why it matters to evo-devo. Am Zool 40:770–776
Bolker B (2008) Ecological models and data in R. Princeton university, Princeton
Bolker JA (2012) There’s more to life than rats and flies. Nature 491:31–33
Bolker JA, Raff R (1996) Developmental genetics and traditional homology. BioEssays 18:489–494
Brauckmann S (2012) On fates and specification: images and models of developmental biology. In: Anderson N, Dietrich M (eds) The educated eye: visual culture and pedagogy in the life sciences. Dartmouth College Press, Lebanon, pp 213–234
Brigandt I (2003) Homology in comparative, molecular, and evolutionary developmental biology: the radiation of a concept. J Exp Zool Mol Dev Evol 299B:9–17
Brigandt I (2009) Natural kinds in evolution and systematics: metaphysical and epistemological considerations. Acta Biotheor 57:77–97
Burian RM (2005) The epistemology of development, evolution, and genetics: selected essays. Cambridge University, Cambridge
Burian RM (2008) The problem of assessing the dimensionality of information: cautions from a mini-case study of differences between (biological) information and standard calculations of hereditary information (workshop discussion paper). Biographs II, Berlin
Callebaut W (1993) Taking the naturalistic turn, or how real philosophy of science is done. University of Chicago, Chicago
Callebaut W, Rasskin-Gutman D (eds) (2005) Modularity: understanding the development and evolution of natural complex systems. MIT Press, Cambridge
Cuvier G (1798) Extrait d’un Mémoire sur un animal dont on trouve les ossements dans la pierre à platre des environs de Paris, & qui paraît ne plus exister vivant aujourd’hui. (Reprinted as “Text 5: Cuvier's Public Lecture at the Institut, 1798” in Rudwick, 1997. Georges Cuvier, fossil bones, and geological catastrophes: new translations of the primary texts. University of Chicago Press, pp 285–290)
Davis M (2008) A prescription for human immunology. Immunity 29:1–11
Dawkins R (ed) (2008) The Oxford book of modern science writing. Oxford University, Oxford
de Beer GR (1971) Homology: an unsolved problem. Oxford University, Oxford
de Queiroz K (2007) Species concepts and species delimitation. Syst Biol 56:879–886
Eble G (2003) Morphological modularity and macroevolution: conceptual and empirical aspects. In: Callebaut W, Rasskin-Gutman D (eds) Modularity: understanding the development and evolution of natural complex systems. MIT Press, Boston, pp 221–238
Gass G, Bolker JA (2003) Modularity. In: Hall B, Olson W (eds) Keywords and concepts in evolutionary developmental biology. Harvard University, Cambridge, pp 260–267
Ghiselin M (1997) Metaphysics and the origin of species. State University of New York Press, Albany
Gilbert S, Bolker JA (2001) Homologies of process: modular elements of embryonic construction. J Exp Zool Mol Dev Evol 291:1–12
Gilbert S, Epel D (2009) Ecological developmental biology. Sinauer, Sunderland
Hacking I (2007) Natural kinds: rosy dawn, scholastic twilight. Roy Inst Philos Suppl 61:203–239
Hall BK (ed) (1994) Homology: the hierarchical basis of comparative biology. Academic Press, New York
Hall BK, Olson W (eds) (2003) Keywords and concepts in evolutionary developmental biology. Harvard University, Cambridge
Hardouin S, Nagy A (2000) Mouse models for human disease. Clin Genet 57:237–244
Hopwood N (2005) Visual standards and disciplinary change: normal plates, tables and stages in embryology. Hist Sci 43:239–303
Hopwood N (2007) A history of normal plates, tables and stages in vertebrate embryology. Int J Dev Biol 51:1–26
Jenner R (2006) Unburdening evo-devo: ancestral attractions, model organisms, and basal baloney. Dev Genes Evol 216:385–394
Keller R, Davidson L, Shook D (2003) How we are shaped: the biomechanics of gastrulation. Differentiation 71:171–205
Krebs HA (1975) The August Krogh principle: for many problems there is an animal on which it can be most conveniently studied. J Exp Zool 194:221–226
Krogh A (1929) Progress in physiology. Am J Physiol 90:243–251
Laubichler M, Maienschein J (eds) (2007) From embryology to evo-devo: a history of developmental evolution. MIT Press, Cambridge
Lewontin RC (2001) The triple helix: gene, organism, and environment. Harvard University, Cambridge
Lorenz K (1950) The comparative method in studying innate behavior patterns. Symp Soc Exp Bio Physiol Mech Anim Behav 4:221–268
Love A (2007) Functional homology and homology of function: biological concepts and philosophical consequences. Biol Philos 22:691–708
Love AC (2008) From philosophy to science (to natural philosophy): evolutionary developmental perspectives. Quart Rev Biol 83:65–76
Love AC (2010) Idealization in evolutionary developmental investigation: a tension between phenotypic plasticity and normal stages. Philos Trans R Soc London B 365:679–690
Martinez GM, Bolker JA (2003) Embryonic and larval staging table for summer flounder (Paralichthys dentatus). J Morphol 255:162–176
Nieuwkoop PD, Faber J (1967) Normal table of Xenopus laevis (Daudin). North-Holland, Amsterdam
Phillips M (2005) The Apple grower. Chelsea Green, White River Junction
Price D, Sisodia S, Borchelt D (1998) Genetic neurodegenerative diseases: the human illness and transgenic models. Science 282:1079–1083
Pringle J (1966) The treasure-house of nature. Adv Sci 23:297–304
Richardson MK, Hanken J, Gooneratne ML, Pieau C, Raynaud A, Selwood L, Wright GM (1997) There is no highly conserved embryonic stage in the vertebrates: implications for current theories of evolution and development. Anat Embryol 196:91–106
Rudwick M (1997) Georges Cuvier, fossil bones, and geological catastrophes: new translations and interpretations of the primary texts. University of Chicago Press, Chicago
Salazar-Ciudad I, Jernvall J, Newman SA (2003) Mechanisms of pattern formation in development and evolution. Development 130:2027–2037
Schlosser G, Wagner GP (eds) (2004) Modularity in development and evolution. Chicago University Press, Chicago
Steel D (2008) Across the boundaries: extrapolation in biology and social science. Oxford University Press, Oxford
Thom R (1972) Stabilité structurelle et morphogénèse: essai d’une théorie générale des modèles. W.A. Benjamin Reading, Massachusetts
Thyagarajan T, Totey S, Danton M, Kulkarni A (2003) Genetically altered mouse models: the good, the bad, and the ugly. Crit Rev Oral Biol Med 14:154–174
von Herrath M, Nepom G (2005) Lost in translation: barriers to implementing clinical immunotherapeutics for autoimmunity. J Exp Med 202:1159–1162
Wagner GP (1996) Homologues, natural kinds and the evolution of modularity. Am Zool 36:36–43
Wagner GP (ed) (2001) The character concept in evolutionary biology. Academic, New York
Watson B (1999) Cider hard and sweet. Countryman Press, Woodstock
Wheeler Q, Meier R (eds) (2000) Species concepts and phylogenetic theory: a debate. Columbia University, New York
Wimsatt WC (2007) Re-engineering philosophy for limited beings: piecewise approximations to reality. Harvard University, Cambridge
Acknowledgments
The author expresses her gratitude to the organizers and sponsors of the 2011 workshop “Natural Kinds in Philosophy and in the Life Sciences” for which this article was prepared, and to the anonymous reviewer who provided detailed and constructive feedback on the manuscript. Dr. Peter Bixby assisted with pomological references, and Dr. Michelle Scott with behavioral ones.
Author information
Authors and Affiliations
Corresponding author
Rights and permissions
About this article
Cite this article
Bolker, J. The Use of Natural Kinds in Evolutionary Developmental Biology. Biol Theory 7, 121–129 (2013). https://doi.org/10.1007/s13752-012-0078-7
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s13752-012-0078-7