Species Diversity and the Evolution of Behavioral Controlling Mechanisms

Abstract

One of the first things that we are impressed by is the great variety of animals, particularly their behaviors and their physiologies. With so many differences, are there any generalities? With the establishment of evolutionary theory, evidence of "unity in diversity" comes with discoveries of common anatomical features, the cell cycle, conservation of intermediary metabolism, and the genetic code, to name but a few. In vertebrates there appears to be a conservation of the neural circuits underlying sexual behavior, but it is still too early to state the extent to which this concept can be extended to the hormonal mechanisms underlying behavior. Much of our conceptual understanding of behavioral neuroendocrinology stems from extensive studies on relatively few species. When an evolutionary perspective is applied to behavioral neuroscience, the breadth and validity of our assumptions about the mechanisms that control species-typical behaviors are challenged. This is not the same thing as saying that there are few unitary explanations that apply to all mammals, amniotes, or even vertebrates. Considerable information has been gathered about the neuroendocrine bases of behavior in a few species, but to uncover truly broad generalizations, we must look with equal intensity and rigor at other organisms. The pattern of evolution is best illustrated in the diversity of organisms, and the ecological and evolutionary perspective illuminates the utility of various "experiments of nature." By studying (1) closely related species that live in different habitats, we can see if the adaptational responses are similar, and (2) distantly related species that live in the same habitat, we can see if the solutions are analogous. The unique qualities of each species also give us a deeper understanding of the constraints in fundamental processes. When basic conflicts exist, control mechanisms adapt or the species goes extinct. Interestingly, although the neural circuits themselves do not degenerate, they are either no longer used or coopted for other functions.