Out to sea: ocean currents and patterns of asymmetric gene flow in an intertidal fish species.

Passive dispersal via wind or ocean currents can drive asymmetric gene flow, which influences patterns of genetic variation and the capacity of populations to evolve in response to environmental change. The mangrove rivulus fish (Kryptolebias marmoratus), hereafter "rivulus," is an intertidal fish species restricted to the highly fragmented New World mangrove forests of Central America, the Caribbean, the Bahamas, and Florida. Mangrove patches are biological islands with dramatic differences in both abiotic and biotic conditions compared to adjacent habitat. Over 1,000 individual rivulus across 17 populations throughout its range were genotyped at 32 highly polymorphic microsatellites. Range-wide population genetic structure was evaluated with five complementary approaches that found eight distinct population clusters. However, an analysis of molecular variance indicated significant population genetic structure among regions, populations within regions, sampling locations within populations, and individuals within sampling locations, indicating that rivulus has both broad- and fine-scale genetic differentiation. Integrating range-wide genetic data with biophysical modeling based on 10 years of ocean current data showed that ocean currents and the distance between populations over water drive gene flow patterns on broad scales. Directional migration estimates suggested some significant asymmetries in gene flow that also were mediated by ocean currents and distance. Specifically, populations in the center of the range (Florida Keys) were identified as sinks that received migrants (and alleles) from other populations but failed to export individuals. These populations thus harbor genetic variation, perhaps even from extirpated populations across the range, but ocean currents and complex arrangements of landmasses might prevent the distribution of that genetic variation elsewhere. Hence, the inherent asymmetry of ocean currents shown to impact both genetic differentiation and directional migration rates may be responsible for the complex distribution of genetic variation across the range and observed patterns of metapopulation structure.

Cryptic Male Phenotypes in the Mangrove Rivulus Fish, Kryptolebias marmoratus.

Alternative male phenotypes exist in many species and impact mating system dynamics, population genetics, and mechanisms of natural and sexual selection that operate within a population. We report on the discovery of a cryptic male phenotype in the mangrove rivulus fish (Kryptolebias marmoratus), one of only two self-fertilizing hermaphroditic vertebrates. In this androdiecious species, males are infrequent, often making up less than 5% of a population; and they have historically been described as having an orange color and lacking or having a very faded outline of the well-defined caudal eyespot (ocellus) that is obvious in hermaphrodites. The cryptic male we describe varies subtly from the hermaphrodite phenotype, without visible orange pigmentation on the body and retention or only minor fading of the ocellus. This male morph was identified by a loss of a defined melanistic "fingerprinting" on the caudal fin seen in hermaphrodites, not previously used as diagnostic for hermaphrodites, and replaced by a diffuse deposition of pigment across the fin. Individuals were identified as male with 85.7% accuracy when using these criteria. We report that in nine populations, spanning three geographically distinct regions in Florida, across two and a half years, 0.3% of the 6057 mangrove rivulus collected exhibited this cryptic male phenotype and were confirmed to have testes via dissection. Overall, 2.3% of the animals were male (normal and cryptic phenotypes), and cryptic males represented 12.9% of all males collected. Even a minor increase in individuals identified as male in a species where males make up such a small portion of the population can have important implications for population genetics. Opportunities for outbreeding are likely enhanced, which has significant evolutionary ramifications.

Phenotypic differences between the sexes in the sexually plastic mangrove rivulus fish (Kryptolebias marmoratus).

To maximize reproductive success, many animal species have evolved functional sex change. Theory predicts that transitions between sexes should occur when the fitness payoff of the current sex is exceeded by the fitness payoff of the opposite sex. We examined phenotypic differences between the sexes in a sex-changing vertebrate, the mangrove rivulus fish (Kryptolebias marmoratus), to elucidate potential factors that might drive the 'decision' to switch sex. Rivulus populations consist of self-fertilizing hermaphrodites and males. Hermaphrodites transition into males under certain environmental conditions, affording us the opportunity to generate 40 hermaphrodite-male pairs where, within a pair, individuals possessed identical genotypes despite being different sexes. We quantified steroid hormone levels, behavior (aggression and risk taking), metabolism and morphology (organ masses). We found that hermaphrodites were more aggressive and risk averse, and had higher maximum metabolic rates and larger gonadosomatic indices. Males had higher steroid hormone levels and showed correlations among hormones that hermaphrodites lacked. Males also had greater total mass and somatic body mass and possessed considerable fat stores. Our findings suggest that there are major differences between the sexes in energy allocation, with hermaphrodites exhibiting elevated maximum metabolic rates, and showing evidence of favoring investments in reproductive tissues over somatic growth. Our study serves as the foundation for future research investigating how environmental challenges affect both physiology and reproductive investment and, ultimately, how these changes dictate the transition between sexes.