The Evolution of Multi-component Visual Signals in Darters (genus Etheostoma)

As complex traits evolve, each component of the trait may be under different selection pressures and could respond independently to distinct evolutionary forces. We used comparative methods to examine patterns of evolution in multiple components of a complex courtship signal in darters, specifically addressing the question of how nuptial coloration evolves across different areas of the body. Using spectral reflectance, we defined 4 broad color classes present on the body and fins of 17 species of freshwater fishes (genus Etheostoma) and quantified differences in hue within each color class. Ancestral state reconstruction suggests that most color traits were expressed in the most recent common ancestor of sampled species and that differences among species are mostly due to losses in coloration. The evolutionary lability of coloration varied across body regions; we found significant phylogenetic signal for orange color on the body but not for most colors on fins. Finally, patterns of color evolution and hue of the colors were correlated among the two dorsal fins and between the anterior dorsal and anal fins, but not between any of the fins and the body. The observed patterns support the hypothesis that different components of complex signals may be subject to distinct evolutionary pressures, and suggests that the combination of behavioral displays and morphology in communication may have a strong influence on patterns of signal evolution [Current Zoology 57 (2): 125–139, 2011]

Sex and design in our evolutionary cousins: The perception of beauty in nature

Desde un enfoque evolutivo de la belleza, en este texto analizamos la expresión y la percepción de la belleza sexual en el reino animal. Los cerebros de los animales perciben la belleza y detectan las características del entorno que resultan más relevantes para su supervivencia. A lo largo de la evolución, los animales con reproducción sexual han explotado este proceso de detección para maximizar su atractivo para el sexo opuesto. Habitualmente, esto ha conllevado la aparición de comportamientos y rasgos de cortejo extremos. Estos son rasgos de belleza sexual. Combinando principios neurocientíficos y neuroestéticos modernos con otros provenientes de la biología evolutiva, tratamos de entender las bases biológicas y la evolución de la belleza en todos los animales, incluidos nosotros mismos.; Des d’un enfocament evolutiu de la bellesa, en aquest text analitzem l’expressió i la percepció de labellesa sexual en el regne animal. Els cervells dels animals perceben la bellesa i detecten les característiquesde l’entorn que resulten més rellevants per a la seua supervivència. Al llarg de l’evolució,els animals amb reproducció sexual han explotat aquest procés de detecció per a maximitzar el seuatractiu per a l’altre sexe. Habitualment, això ha comportat l’aparició de comportaments i trets defesteig extrems. Aquests són trets de bellesa sexual. Combinant principis neurocientífics i neuroestèticsmoderns amb altres provinents de la biologia evolutiva, tractem d’entendre les bases biològiquesi l’evolució de la bellesa en tots els animals, inclosos nosaltres mateixos.; Taking an evolutionary approach to the question of beauty, we discuss the expression and perception of sexual beauty across the animal kingdom. Animals experience beauty in their brains, and animal brains are tuned to features of the environment most relevant to their survival. Over evolutionary time, sexually reproducing animals have exploited that tuning to maximize their attractiveness to the opposite sex, often leading to extreme courtship traits and behaviors. These are the traits of sexual beauty. Combining modern principles of neuroscience and neuroaesthetics with established principles of evolutionary biology, we aim to understand the biological basis and evolution of beauty in all animals, including ourselves

Differences in Spectral Sensitivity Within and Among Species of Darters (genus Etheostoma)

We examined variation in the visual system both within and among seven species of darters, colorful freshwater fishes of the genus Etheostoma. Using microspectrophotometry, we found that darters possess rod photoreceptor cells, single cone photoreceptor cells containing middle wavelength sensitive (MWS) visual pigments, and twin photoreceptor cells containing (LWS) visual pigments. No variation in peak sensitivity was detected among species or individuals in the rod class. In the MWS class, significant variation was detected among species and a strong statistical trend suggests differences among individuals. By contrast, all differences in the LWS class could be attributed to variation among individuals. Patterns of variation detected among species, among individuals, and among cone classes suggest that complex patterns of selection may be shaping the visual system of these fishes. Further, differences among individuals may have important consequences for visually based behaviors

Cognitive Phenotypes and the Evolution of Animal Decisions

Despite the clear fitness consequences of animal decisions, the science of animal decision making in evolutionary biology is underdeveloped compared with decision science in human psychology. Specifically, the field lacks a conceptual framework that defines and describes the relevant components of a decision, leading to imprecise language and concepts. The ‘judgment and decision-making’ (JDM) framework in human psychology is a powerful tool for framing and understanding human decisions, and we apply it here to components of animal decisions, which we refer to as ‘cognitive phenotypes’. We distinguish multiple cognitive phenotypes in the context of a JDM framework and highlight empirical approaches to characterize them as evolvable traits

Cognitive Phenotypes and the Evolution of Animal Decisions

Despite the clear fitness consequences of animal decisions, the science of animal decision making in evolutionary biology is underdeveloped compared with decision science in human psychology. Specifically, the field lacks a conceptual framework that defines and describes the relevant components of a decision, leading to imprecise language and concepts. The ‘judgment and decision-making’ (JDM) framework in human psychology is a powerful tool for framing and understanding human decisions, and we apply it here to components of animal decisions, which we refer to as ‘cognitive phenotypes’. We distinguish multiple cognitive phenotypes in the context of a JDM framework and highlight empirical approaches to characterize them as evolvable traits

Mechanisms of Assortative Mating in Speciation with Gene Flow: Connecting Theory and Empirical Research

The large body of theory on speciation with gene flow has brought to light fundamental differences in the effects of two types of mating rules on speciation: preference/trait rules, in which divergence in both (female) preferences and (male) mating traits is necessary for assortment, and matching rules, in which individuals mate with like individuals on the basis of the presence of traits or alleles that they have in common. These rules can emerge from a variety of behavioral or other mechanisms in ways that are not always obvious. We discuss the theoretical properties of both types of rules and explain why speciation is generally thought to be more likely under matching rather than preference/trait rules. We furthermore discuss whether specific assortative mating mechanisms fall under a preference/trait or matching rule, present empirical evidence for these mechanisms, and propose empirical tests that could distinguish between them. The synthesis of the theoretical literature on these assortative mating rules with empirical studies of the mechanisms by which they act can provide important insights into the occurrence of speciation with gene flow. Finally, by providing a clear framework we hope to inspire greater alignment in the ways that both theoreticians and empiricists study mating rules and how these rules affect speciation through maintaining or eroding barriers to gene flow among closely related species or populations

Functional conservation between structurally diverse ribosomal proteins from Drosophila melanogaster and Saccharomyces cerevisiae: fly L23a can substitute for yeast L25 in ribosome assembly and function

The proposed Drosophila melanogaster L23a ribosomal protein features a conserved C-terminal amino acid signature characteristic of other L23a family members and a unique N-terminal extension [Koyama et al. (Poly(ADP-ribose) polymerase interacts with novel Drosophila ribosomal proteins, L22 and l23a, with unique histone-like amino-terminal extensions. Gene 1999; 226: 339–345)], absent from Saccharomyces cerevisiae L25 that nearly doubles the size of fly L23a. The ability of fly L23a to replace the role of yeast L25 in ribosome biogenesis was determined by creating a yeast strain carrying an L25 chromosomal gene disruption and a plasmid-encoded FLAG-tagged L23a gene. Though affected by a reduced growth rate, the strain is dependent on fly L23a-FLAG function for survival and growth, demonstrating functional compatibility between the fly and yeast proteins. Pulse-chase experiments reveal a delay in rRNA processing kinetics, most notably at a late cleavage step that converts precursor 27S rRNA into mature 25S rRNA, likely contributing to the strain's slower growth pattern. Yet, given the essential requirement for L23(a)/L25 in ribosome biogenesis, there is a remarkable tolerance for accommodating the fly L23a N-terminal extension within the structure of the yeast ribosome. A search of available databases shows that the unique N-terminal extension is shared by multiple insect lineages. An evolutionary perspective on L23a structure and function within insect lineages is discussed

Sexual isolation evolves faster than hybrid inviability in a diverse; and sexually dimorphic genus of fish (Percidae: Etheostoma). Evolution 57: 317–327

Abstract. Theory predicts that sexual (or behavioral) isolation will be the first form of reproductive isolation to evolve in lineages characterized by sexual selection. Here I directly compare the rate of evolution of sexual isolation with that of hybrid inviability in a diverse and sexually dimorphic genus of freshwater fish. The magnitude of both sexual isolation and hybrid inviability were quantified for multiple pairs of allopatric species. Rates of evolution were inferred by comparing genetic distances of these species pairs with the magnitude of each form of reproductive isolation: the slope of the regression of genetic distance on the magnitude of reproductive isolation represents the rate of evolution. Of the two forms of isolation, the magnitude of sexual isolation exhibited the steeper slope of regression, indicating that sexual isolation will tend to evolve to completion earlier than hybrid inviability, strictly as a by-product of evolution in geographically isolated populations. Additional evidence from the literature is used to qualitatively compare rates of evolution of sexual isolation with that of other forms of reproductive isolation. Preliminary comparisons support the prediction that sexual isolation will evolve more rapidly than other forms. Because Etheostoma is characterized by striking sexual dimorphism, these results are consistent with the hypothesis that sexual selection for exaggerated mate-recognition characters causes the relatively rapid evolution of sexual isolation