Ronald S. Burton

INTRASPECIFIC PHYLOGEOGRAPHY ACROSS THE POINT CONCEPTION BIOGEOGRAPHIC BOUNDARY

Recent studies of intraspecific phylogeography have suggested that the geographic location of genetic discontinuities, or phylogeographic breaks, may frequently coincide with biogeographic boundaries. The concordance is hypothesized to reflect similarity in the processes governing species boundaries and intraspecific lineage boundaries. This concordance has not, however, been widely tested. In the case of the Point Conception biogeographic boundary between the Oregonian and Californian marine biotas, only the supralittoral copepod Tigriopus californicus has been found to have a coincident phylogeographic break. Here I show that the apparent relationship between this break and Point Conception was, in fact, an artifact of insufficient geographic sampling. Mitochondrial DNA analyses of T. californicus populations between Morro Bay and San Diego reveal at least five equally deep phylogeographic breaks in the region (where only one biogeographic boundary is recognized). Limited nuclear DNA sequence data and allozyme data also support the occurrence of multiple genetic discontinuities along this geographic range. Lack of one‐to‐one correspondence between intraspecific phylogeography and biogeographic boundaries indicates that the processes affecting the genetic differentiation of populations of T. californicus differ from those responsible for determining species distributional limits at the Point Conception biogeographic boundary. A review of genetic data from other species also fails to provide evidence for concordance of biogeography and intraspecific phylogeography across Point Conception. I suggest that the concordance of phylogeography with biogeography will only be pronounced where the biogeographic boundary separates biotas that are phylogenetically related. The numerous cases of interspecific hybrid zones in the region of Cape Canaveral, for example, indicate that many sister‐species pairs occur across this biogeographic boundary. Such hybrid zones are not common at Point Conception, and there appears to be no cases of intraspecific phylogeographic breaks associated with this well‐recognized biogeographic boundary.

Natural selection and the evolution of mtDNA-encoded peptides: evidence for intergenomic co-adaptation

Mitochondrial DNA (mtDNA) variation is an important tool for the investigation of the population genetics of animal species. Recently, recognition of the role of mtDNA mutations in human disease has spurred increasing interest in the function and evolution of mtDNA and the 13 polypeptides it encodes. These proteins interact with a large number of peptides encoded in the nucleus to form the mitochondrial electron transport system (ETS). As the ETS is the primary energy generation system in aerobic metazoans, natural selection would be expected to favor mutations that enhance ETS function. Such mutations could occur in either the mitochondrial or nuclear genes encoding ETS proteins and would lead to positive intergenomic interactions, or co-adaptation. Direct evidence for intergenomic co-adaptation comes from functional studies of systems where nuclear-mitochondrial DNA combinations vary naturally or can be manipulated experimentally.

INTERPOPULATION HYBRID BREAKDOWN MAPS TO THE MITOCHONDRIAL GENOME

Abstract Hybrid breakdown, or outbreeding depression, is the loss of fitness observed in crosses between genetically divergent populations. The role of maternally inherited mitochondrial genomes in hybrid breakdown has not been widely examined. Using laboratory crosses of the marine copepod Tigriopus californicus, we report that the low fitness of F3 hybrids is completely restored in the offspring of maternal backcrosses, where parental mitochondrial and nuclear genomic combinations are reassembled. Paternal backcrosses, which result in mismatched mitochondrial and nuclear genomes, fail to restore hybrid fitness. These results suggest that fitness loss in T. californicus hybrids is completely attributable to nuclear–mitochondrial genomic interactions. Analyses of ATP synthetic capacity in isolated mitochondria from hybrid and backcross animals found that reduced ATP synthesis in hybrids was also largely restored in backcrosses, again with maternal backcrosses outperforming paternal backcrosses. The strong fitness consequences of nuclear–mitochondrial interactions have important, and often overlooked, implications for evolutionary and conservation biology.

Functional coadaptation between cytochrome c and cytochrome c oxidase within allopatric populations of a marine copepod

Geographically isolated populations may accumulate alleles that function well on their own genetic backgrounds but poorly on the genetic backgrounds of other populations. Consequently, interpopulation hybridization may produce offspring of low fitness as a result of incompatibilities arising in allopatry. Genes participating in these epistatic incompatibility systems remain largely unknown. In fact, despite the widely recognized importance of epistatic interactions among gene products, few data directly address the functional consequences of such interactions among natural genetic variants. In the marine copepod, Tigriopus californicus, we found that the cytochrome c variants isolated from two different populations each had significantly higher activity with the cytochrome c oxidase derived from their respective source population. Three amino acid substitutions in the cytochrome c protein appear to be sufficient to confer population specificity. These results suggest that electron transport system (ETS) proteins form coadapted sets of alleles within populations and that disruption of the coadapted ETS gene complex leads to functional incompatibilities that may lower hybrid fitness.

DISRUPTION OF MITOCHONDRIAL FUNCTION IN INTERPOPULATION HYBRIDS OF TIGRIOPUS CALIFORNICUS

Abstract Electron transport system (ETS) function in mitochondria is essential for the aerobic production of energy. Because ETS function requires extensive interactions between mitochondrial and nuclear gene products, coadaptation between mitochondrial and nuclear genomes may evolve within populations. Hybridization between allopatric populations may then expose functional incompatibilities between genomes that have not coevolved. The intertidal copepod Tigriopus californicus has high levels of nucleotide divergence among populations at mitochondrial loci and suffers F2 hybrid breakdown in interpopulation hybrids. We hypothesize that hybridization results in incompatibilities among subunits in ETS enzyme complexes and that these incompatibilities result in diminished mitochondrial function and fitness. To test this hypothesis, we measured fitness, mitochondrial function, and ETS enzyme activity in inbred recombinant hybrid lines of Tigriopus californicus. We found that (1) both fitness and mitochondrial function are reduced in hybrid lines, (2) only those ETS enzymes with both nuclear and mitochondrial subunits show a loss of activity in hybrid lines, and (3) positive relationships exist between ETS enzyme activity and mitochondrial function and between mitochondrial function and fitness. We also present evidence that hybrid lines harboring mitochondrial DNA (mtDNA) and mitochondrial RNA polymerase (mtRPOL) from the same parental source population have higher fitness than those with mtDNA and mtRPOL from different populations, suggesting that mitochondrial gene regulation may play a role in disruption of mitochondrial performance and fitness of hybrids. These results suggest that disruption of coadaptation between nuclear and mitochondrial genes contributes to the phenomenon of hybrid breakdown.

The recruitment sweepstakes has many winners: genetic evidence from the sea urchin Strongylocentrotus purpuratus.

Abstract As a consequence of free spawning in the unpredictable nearshore environment, marine species with large fecundities and high pre‐reproductive mortality may be subject to extreme variance in reproductive success. If the unpredictability of the ocean results in only a small subset of the adult population contributing to each larval cohort, then reproduction may be viewed as a sweepstakes, with chance events determining which adults are successful each spawning season. Such a reproductive sweepstakes scenario may partially account for large reductions in effective population sizes relative to census population sizes in marine species. We evaluated two predictions of the sweepstakes reproductive success hypothesis by testing: (1) whether sea urchin recruits contain reduced genetic variation relative to the adult population; and (2) whether cohorts of sea urchin recruits are genetically differentiated. Mitochondrial DNA sequences were collected from 283 recently settled Strongylocentrotus purpuratus recruits from four annual cohorts spanning seven years in locations throughout California. Observed haplotype numbers and haplotype diversities showed little evidence of reduced genetic variation in the recruits relative to the diversity estimated from a previously reported sample of 145 S. purpuratus adults. Different cohorts of recruits were in some cases mildly differentiated from each other. A computer simulation of sweepstakes recruitment indicates that our sampling strategy had sufficient statistical power to detect large variances in reproductive success.

Allozyme and mitochondrial DNA evidence of population subdivision in the purple sea urchin Strongylocentrotus purpuratus

Despite high potential for dispersal, the purple sea urchin Strongylocentrotus purpuratus was found to have significant genetic subdivision among locations. Ten geographic locations along the coast of California and Baja California were sampled between 1994 and 1995. Samples from some locations included both adult and recruit urchins. Allozyme analyses revealed a genetic mosaic, where differentiation over short geographic distances could exceed differentiation over much larger distances. Significant allozyme differentiation was found among subpopulations of adults (standardized variance, FST=0.033), among subpopulations of recruits (FST=0.037), and between adults and recruits from the same location. DNA-sequence data for the mitochondrial cytochrome oxidase I gene also showed significant heterogeneity among locations, with a mild break in haplotype frequencies observed ≃ 300 km south of Point Conception. California. Repeated sampling over time is necessary to determine whether these patterns of differentiation are stable and to begin to understand what forces produce them.

Hybrid breakdown in developmental time in the copepod Tigriopus californicus

Laboratory crosses were carried out among three genetically differentiated Los Angeles populations (all located within approximately 15 km) and one San Diego population (approximately 150 km away) of the intertidal copepod Tigriopus californicus. Despite high levels of allozyme differentiation, all crosses produced viable F1 progeny. Most F1 progeny had shorter developmental times and reduced variance in developmental times compared to the parental populations. Only one pair of populations failed to produce viable F2 progeny; when the central Los Angeles population (AB) was crossed to the San Diego (SD) population, most larvae died during the late naupliar stages. Developmental times in the F2 generation of the other Los Angeles × San Diego crosses were typically 40% longer than developmental times of the parental populations. Among the Los Angeles populations, only one cross (and not its reciprocal) showed a similarly large increase in developmental time. Variance in F2 developmental times was greater than the parental variance in 5 of 10 crosses. These results are discussed with regard to the evolution of coadapted gene complexes and population differentiation in T. californicus.

A disproportionate role for mtDNA in Dobzhansky- Muller incompatibilities?

Evolution in allopatric populations can lead to incompatibilities that result in reduced hybrid fitness and ultimately reproductive isolation upon secondary contact. The Dobzhansky–Muller (DM) model nicely accounts for the evolution of such incompatibilities. Although DM incompatibilities were originally conceived as resulting of interactions between nuclear genes, recent studies have documented cases where incompatibilities have arisen between nuclear and mitochondrial genomes (mtDNA). Although mtDNA comprises only a tiny component (typically ≪0.01%) of an organisms genetic material, several features of mtDNA may lead to a disproportionate contribution to the evolution of hybrid incompatibilities: (i) essentially all functions of mtDNA require interaction with nuclear gene products. All mtDNA‐encoded proteins are components of the oxidative phosphorylation (OXPHOS) system and all mtDNA‐encoded RNAs are part of the mitochondrial protein synthetic machinery; both processes require interaction with nuclear‐encoded proteins for function. (ii) Transcription and replication of mtDNA also involve mitonuclear interactions as nuclear‐encoded proteins must bind to regulatory motifs in the mtDNA to initiate these processes. (iii) Although features of mtDNA vary amongst taxa, metazoan mtDNA is typically characterized by high nucleotide substitution rates, lack of recombination and reduced effective population sizes that collectively lead to increased chance fixation of mildly deleterious mutations. Combined, these features create an evolutionary dynamic where rapid mtDNA evolution favours compensatory nuclear gene evolution, ultimately leading to co‐adaptation of mitochondrial and nuclear genomes. When previously isolated lineages hybridize in nature or in the lab, intergenomic co‐adaptation is disrupted and hybrid breakdown is observed; the role of intergenomic co‐adaptation in hybrid breakdown and speciation will generally be most pronounced when rates of mtDNA evolution are high or when restricted gene flow results in significant population differentiation.

CYTOCHROME C OXIDASE ACTIVITY IN INTERPOPULATION HYBRIDS OF A MARINE COPEPOD: A TEST FOR NUCLEAR-NUCLEAR OR NUCLEAR-CYTOPLASMIC COADAPTATION

The respiratory enzyme cytochrome c oxidase (COX) is composed of subunits encoded by both nuclear and mitochondrial genes; thus, COX activity reflects, to some extent, the coordinated function of the two genomes. Because extensive mtDNA differentiation exists between populations of the copepod Tigriopus californicus, we hypothesized that laboratory hybridizations that disrupt natural combinations of nuclear and mitochondrial genes might negatively impact COX activity. Although experimental results varied greatly among different crosses, replicate sets of crosses between two particular populations showed consistent evidence for nuclear‐cytoplasmic coadaptation.