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Genetic variation and reproductive isolation among phenotypically amphipod populations divergent Mark A. McPeek Department of Biological Sciences, Dartmouth College, Hanover, New Hampshire 03755 Gary A. Wellborn1 Department of Biology, Yale University, New Haven, Connecticut 06520 Abstract We examined the degree of reproductive isolation and patterns of genetic structure and diversification within and among seven populations of the freshwater amphipod Hyalella azteca. Hyalella occurs acrossecologically dissimilar habitats in southeasternMichigan and exhibits substantial, and apparently adaptive, genetically based phenotypic variation among populations. Habitats with predatory centrarchid fish contain a small-bodied Hyalella ecotype, whereas habitats lacking these predators contain a large-bodied ecotype. Hierarchical F statistics showed that allele frequency variation at six electrophoretic loci is greater among populations within an ecotype than between ecotypes, a result also reflected in a cluster analysis based on genetic distances among the seven populations. Despite the lack of clear genetic differentiation between ecotypes, gene flow between ecotypes appearedrestricted or absent. Physically adjacent large- and small-ecotype populations in the same drainage differed appreciably in allele frequencies. Within-population genetic structuring also differed between ecotypes.Whereasgenotype frequencies never differed from Hardy-Weinberg expectations in large-ecotype populations, all small-ecotype populations exhibited a significant deficiency of heterozygous genotypes at one or more loci. Interbreeding trials demonstrated that individuals from different populations of the same ecotype readily interbreed, but no interbreeding was observed in crossesinvolving individuals of dissimilar ecotypes.Interbreeding results, considered together with between-ecotype differences in allele and genotype structure, suggestthat Hyalella ecotypes in southeastMichigan form at least two separate species. Furthermore, the lack of distinct allelic differences and the relative levels of allele frequency differentiation within and between ecotypes suggestrecent local speciation in this taxon. Lentic freshwater habitats are arrayed along a gradient from small, fishless ponds and marshes to large lakes containing well-developed fish communities. This freshwater habitat gradient has provided an important vehicle for exploring the ecology and evolution of freshwater taxa, particularly ways in which ecological processes shape community structure in freshwater ecosystems (Brooks and Dodson 1965; Zaret 1980; Wellborn et al. 1996). Numerous comparative studies have provided insight into the ecological mechanisms apparently underlying evolutionary diversification in taxa that exist across the habitat gradient (reviewed in Wellborn et al. 1996). Few studies in this system, however, have focused on explicit evolutionary mechanisms of diversification, such as genetic mechanisms of speciation or intraspecific divergence, genetic structuring of populations within and across regions of the habitat gradient, gene flow, and degree and mechanisms of reproductive isolation among divergent populations. Given the extensive understanding of ecological processes affecting individuals and populations 1To whom correspondenceshould be addressed.Present address: Department of Zoology and Biological Station, University of Oklahoma, Norman, Oklahoma 73019. Acknowledgments We thank S. J. Tonsor and S. Kalisz for allowing us to use the “gel lab” at the Kellogg Biological Station to complete part of this work. We also thank J. Brown, T. Kane, M. Pace,and an anonymous reviewer for their helpful comments on the manuscript. This work was supported by the National Science Foundation (grant DEB9307033). across this gradient, exploration of evolutionary mechanisms can shed light on how ecological processes may foster diversification in taxon lineages distributed over this habitat gradient. Here we explore some of these evolutionary issues for a phenotypically variable and taxonomically problematic amphipod, Hyalella azteca (Amphipoda: Hyalellidae), that occurs in many permanent freshwater habitats throughout much of North America. Hyalella exhibits genetically based divergence among populations in body size (Strong 1972; Wellborn 1994a), behavior (Strong 1973; Wellborn 1995b), life history (Strong 1972; France 1992; Wellborn 1994a), and morphological characteristics (Bousfield 1958; Cole and Watkins 1977; Stevenson and Peden 1973) that, in at least some cases (Cole and Watkins 1977; Stevenson and Peden 1973), is associated with speciation. Ecological studies of life history diversification suggest that this divergence is adaptive (Strong 1972; Wellborn 1994a). H. azteca is a problematic taxon because the level of genetically based divergence among populations and apparent lack of hybridization between ecotypes (Wellborn 1995a) suggests H. azteca is a species complex. The lack of qualitative morphological differences (Strong 1972, Wellborn 1995a), however, suggests recent diversification within the taxon. At least two Hyalella ecotypes occur in southeast Michigan. These ecotypes differ in body size, life history, and mating behavior (Wellborn 1994a, 1995a, b). Fishless habitats contain a large-bodied ecotype, and habitats with fish communities dominated by centrarchid fishes contain a 1162 Amphipod evolution small-bodied ecotype (Wellborn 1995a). The size disparity between ecotypes is substantial, with little overlap in adult body size distributions (Wellborn 1995a). Compared with the small-bodied ecotype, individuals of the large-bodied ecotype mature at a larger size and exhibit a lower sizespecific reproductive effort (Wellborn 1994a). Hyalella in the two habitat types experience qualitatively different regimes of size-biased predation (Wellborn 1994a), and the observed evolutionary divergence in body size and life history is consistent with adaptive divergence in response to these disparate mortality schedules (Law 1979; Michod 1979; Taylor and Gabriel 1992; Wellborn 1994a). For Hyalella and other taxa that exist across ecologically disparate habitat types, spatial heterogeneity in the selective environment may drive interpopulation trait divergence (Reznick and Endler 1982; Reznick et al. 1990; Wellborn 1994a), which, in turn, can generate important genetic effects. Most obviously, adaptive divergence among populations may restrict gene flow among the populations, allowing secondary genetic differentiation and perhaps fostering speciation. The reduction in gene flow may result, e.g., when dispersing individuals experience low survival in new habitats because they possess traits that are inappropriate in the colonized habitat (McPeek and Holt 1992). Additionally, reproductive success of dispersing individuals may be diminished because of mating incompatibilities associated with the trait divergence (Schluter and Nagel 1995). Changes in within-population genetic structure might also result from changes in breeding structure associated with adaptive divergence. For example, changes in assortative mating (Wellborn 1995b) or local spatial mating structure may affect levels of inbreeding. Here we address four issues concerning the genetic diversity and structure of Hyalella populations and ecotypes. First, we describe the among-population genetic structure of several Hyalella populations, including populations of both ecotypes. Second, we examine the congruence of genotype frequencies with Hardy-Weinberg expectations to determine whether processes shaping intrapopulation genetic structure differ among the populations. Third, we examine the pattern of genetic diversification for ecotypes and populations using a measure of genetic distance. Fourth, we use interbreeding experiments to determine the extent of interfertility and potential gene flow among populations within and between ecotypes. 1163 and Kaiser Road Marsh appear to be isolated but lie within the Huron River watershed. Winnewanna drains into the Portage River system. Methods Allozyme analysis- Hyalella individuals were collected at multiple locations within each habitat by sweeping littoral vegetation with a dip net. Individuals for allozyme studies were placed in microcentrifuge tubes and stored at -80°C. We used cellulose acetate electrophoresis to examine the genetic structure of the seven Hyalella populations. We characterized the genotypes of individuals at six polymorphic loci, The loci were mannose-phosphate isomerase (MPI, EC 5.3.1.8), triose-phosphate isomerase (TPI, EC 5.3.1.l), phosphoglucomutase (PGM, EC 2.7.5.l), phosphoglucose isomerase (PGI, EC 5.3.1.9), arginine phosphokinase (APK, EC 2.7.3.3), and malate dehydrogenase (MDH, EC 1.1.1.37). A Tris-glycine (pH 8.5) continuous buffer system was used for all enzymes except MDH, which was run in a Tris-maleate (pH 7.8) buffer. Individuals were ground in one drop of 0.1 M Tris-HCl pH 8.0 and plated onto cellulose acetate plates (Helena Laboratories). Gels were run for 20 min at room temperature (22-24°C) and stained according to protocols provided in Hebert and Beaton (1989) and Richardson et al. (1986). We used two kinds of analyses to examine patterns of genetic differentiation and structure. First, we calculated three-level hierarchical F statistics (Weir 1990), an analysis that uses genotype frequencies to quantify population structure at hierarchical levels. Population structure at each hierarchical level arises from nonrandom mating and is quantified by the degree of departure from the expected heterozygosity for a panmictic population. The highest level in the hierarchy is ecotype, the next level is populations within ecotypes, and finally individuals within populations. We generate variance estimates for each hierarchical F statistic by jackknifing across loci (Weir 1990). Second, we used cluster analysis to examine the relative distance relationships among populations in allele frequency space. Our clustering algorithm used the method of unweighted pair groups using arithmetic averages (UPGMA), and was based on Nei’s (1978) genetic distances among the seven populations. To examine within-population structure for each population, we applied x2- tests to determine whether genotype frequencies at each locus occur in Hardy-Weinberg proportions (Weir 1990). Because many genotype classes had small expected frequencies, we pooled genotypes into all homozygotes and all heterozygotes and performed tests for these two classes. Study populations -We collected Hyalella from seven populations in Livingston and Washtenaw Counties, Michigan, in July and August 1994, including four lakes (Duck, Mill, Winnewanna, and Sullivan) that support populations of the small ecotype and have diverse fish faunas and three fishless habitats (Kaiser Road Marsh, Duck Marsh, and George Pond) that support populations of the large ecotype (Wellborn 1995a). All populations are within 22 km of each other in this hydrologically complex region. Duck Lake, Mill Lake, and Duck Marsh have outflows draining eventually into the Huron River system. Sullivan Lake, George Pond, Interfertility trials- We conducted interfertility trials to examine the potential for gene flow among populations and between ecotypes. One to a few days before the female molt, males grasp females in a precopulatory mate-guarding behavior (Borowsky 1984). Pairs remain attached until the female’s molt, at which time any first instar offspring from a previous mating are released and the new clutch of eggs is fertilized by the guarding male as eggs pass from the female genital pore into a ventral brood chamber (i.e., marsupium). Fertilization is external, and females have no mechanism for sperm storage. Pairs separate after fertilization. 1164 McPeek and Wellborn Table 1. Allele frequencies of the seven Hyalella azteca populations. All population/locus combinations are based on a sample size of 48 individuals, except PGM in Duck Marsh and MDH in Duck Lake, which are based on a sample size of 36 individuals. Populations exhibited little variation at APK and MDH, so those data were omitted here. Frequency SulliGene Al- Kaiser Duck George Duck van locus lele Marsh Marsh Pond Lake Lake MPI A 0.104 0.000 0.000 0.000 0.000 B 0.240 0.063 0.115 0.281 0.302 C 0.479 0.250 0.323 0.406 0.427 D 0.177 0.667 0.396 0.313 0.271 E 0.000 0.021 0.167 0.000 0.000 TPI A 0.000 0.000 0.000 0.000 0.000 B 0.229 0.208 0.104 0.469 0.729 C 0.760 0.729 0.896 0.521 0.260 D 0.010 0.063 0.000 0.010 0.010 PGM A 0.010 0.181 0.063 0.083 0.021 B 0.156 0.528 0.823 0.656 0.531 C 0.750 0.292 0.083 0.188 0.229 D 0.083 0.000 0.031 0.073 0.219 E 0.000 0.000 0.000 0.000 0.000 PGI A 0.000 0.000 0.000 0.010 0.000 B 0.313 0.281 0.375 0.469 0.677 C 0.469 0.521 0.375 0.104 0.302 D 0.063 0.063 0.177 0.406 0.021 E 0.156 0.125 0.073 0.010 0.000 F 0.000 0.010 0.000 0.000 0.000 I 0.20 NEI’S GENETIC I I 0.15 0.10 DISTANCE I 0.05 I 0.00 KAISERMARSH DUCK MARSH (L) (L) GEORGE POND(L) SULLIVAN (S) WinneMill wanna Lake Lake 0.000 0.156 0.656 0.188 0.000 0.010 0.448 0.510 0.031 0.031 0.656 0.135 0.177 0.000 0.010 0.417 0.104 0.448 0.021 0.000 0.021 0.135 0.802 0.042 0.000 0.000 0.958 0.031 0.010 0.135 0.510 0.281 0.063 0.010 0.094 0.875 0.021 0.000 0.010 0.000 Mature males and females carrying fertilized eggs in their marsupia were collected from two small-ecotype (Sullivan Lake and Duck Lake) and two large-ecotype (George Pond and Duck Marsh) populations in July 1994. Sexes were separated from one another and held in several 1 liter jars for 5-6 d. The jars, which contained sediment and Potomogeton, were capped with fine-mesh screen and submerged 40 cm deep on a platform in a reservoir at the E.S. George Reserve’s experimental pond facility. The 5- to 6-d holding period was sufficient for females to release their developing broods (all females were examined under a dissecting microscope to ensure that they carried no eggs at the beginning of the experiment). After this isolation period, individuals were placed in experimental beakers in all possible intra- and inter-population combinations (10 total combinations). Two individuals of each sex were placed a 150-ml beaker that had been prepared with 25 ml of pond sediment and a 30-cm-long stem of Potomogeton with roots. Beakers were sealed with fine-mesh screens and submerged on the reservoir platform. Head length, a metric highly correlated with Hyalella body length and mass (Edwards and Cowell 1992), of females and males, respectively, used in the interbreeding experiment was 0.49 mm ± 0.049 (mean ± SD) and 0.44 ± 0.035 for Sullivan Lake, 0.54 ± 0.051 and 0.49 ± 0.049 for Duck Lake, 0.72 ± 0.031 and 0.80 ± 0.035 for George Pond, and 0.76 ± 0.058 and 0.79 ± 0.056 for Duck Marsh. The beakers were recovered after 13 d. Each beaker was examined for the presence of offspring, and females were examined for the pres- WINNEWANNA 0.20 I 0.15 I 0.10 0.65 (S) 0.00 Fig. 1. Phenogram of genetic similarity among Hyalella populations in southeast Michigan. The phenogram was constructed by UPGMA clustering of a genetic distance matrix generatedfrom allele frequency variation at six loci. Letters in parenthesesindicate ecotype: L, large-bodied ecotype; S, small-bodied ecotype. ence developing embryos, which would indicate that the egg had been fertilized and initial development had occurred. Either finding was considered indicative of a successful mating. Results Allozyme analysis and population structure- Allele frequencies in the seven populations at the four most informative electrophoretic loci are presented in Table 1. We detected 3-6 alleles per locus. Four loci, MPI, TPI, PGM, and PGI, exhibited at least moderate levels of allelic polymorphism. The remaining two loci, APK and MDH, had one allele at a frequency L 0.90 in every population. The hierarchical analysis of population structure indicated significant population subdivision at each hierarchical level, but most differentiation among populations occurred within the two ecotypes rather than between them. The lowest hierarchical level was individuals within populations, and substantial subdivision was observed at this level. The value of the F statistic at this level is 0.483 (95% confidence interval = 0.45 1-0.513), indicating a high degree of genetic structure within populations due to inbreeding. The overall measure of differentiation among populations within ecotypes is 0.224 (0.199-0.249), and the measure of differentiation between ecotypes is 0.112 (0.084-0.138). Thus, differentiation among populations within the two ecotypes is about twice as great as the added level of differentiation between ecotypes. The cluster diagram (Fig. 1) derived from Nei’s genetic distance estimates (Table 2) also suggests that the large- and small-ecotype populations do not form two genetically distinct groups. The small-ecotype Sullivan Lake and Winnewanna populations form one primary cluster, and the three large-ecotype populations and the remaining two small-ecotype populations form the other primary cluster. 1165 Amphipod evolution Table 2. Nei’s genetic distances among the seven Hyalella populations included in the allozyme study of genetic differentiation. * L, large-ecotype population; S, small-ecotype population. loci (MPI, TPI, PGM, and PGI; x2 test, P < 0.005 for each comparison). Populations of the two ecotypes clearly differed in their correspondence with Hardy-Weinberg expectations (Table 3). No locus in any population of the large-ecotype displayed genotype frequencies that were inconsistent with HardyWeinberg expectations (Table 3). In contrast, 12 of the 16 possible locus-population combinations for small-ecotype populations had genotype frequencies that were inconsistent with Hardy-Weinberg expectations at the MPI, TPI, PGM, and PGI loci (Table 3). All these loci were deficient in heterozygotes, suggesting that inbreeding is substantial in the small-ecotype populations. APK and MDH have very little power to test Hardy-Weinberg expectations because each has one allele near fixation in every population. Although the large-ecotype populations do not form a distinct group, they do all lie within one of the two primary clusters. Geographic arrangement of habitats may play some role in patterns of genetic distance. With the exception of Sullivan Lake, the two primary clusters define populations within different watersheds, with Winnewanna in the Portage River system and all other habitats in the Huron River system. Because Sullivan Lake appears to be isolated, it is possible that this habitat was colonized from the Portage River drainage, explaining the genetic similarity of Hyalella in Sullivan Lake and Winnewanna Lakes. One notable result was that Duck Lake (small ecotype) and Duck Marsh (large ecotype) populations were genetically dissimilar despite a physical arrangement of habitats that makes movement of individuals between habitats very likely. These water bodies are only 15 m apart and are contiguous along a 125-m earthen dam that separates the two. Moreover, Duck Lake drains directly and continuously into Duck Marsh during ice-free months. Thus, ample opportunity exists for exchange of individuals between these habitats due to the drainage flow, as well as transport by waterfowl and human activities. The genetic distance between these populations (0.098), however, suggests that they are genetically distinct. Also, these populations differ significantly in allele frequency at four of the six electrophoretic Interfertility trials- Some mortality occurred during the 13 d of the interfertility experiment. Survival was higher for individuals from the large-ecotype populations (86.0% of both males and females survived) than for those from the small-ecotype populations (47.0% of males and 60.5% of females survived) over the course of the experiment. The following analyses are therefore based only on replicates in which at least one individual of each sex was alive at the end of the experiment. Interbreeding was observed in 11 of the 13 replicates (84.6%) with males and females from the same population (Table 4). Interbreeding was observed in 9 of the 14 replicates (64.3%) in which males and females from different populations but the same ecotype were placed together. In contrast, no offspring were observed in any of the 19 replicates (0.0%) in which males and females of different ecotype were placed together. A contingency table analysis of these results indicated that the chances of obtaining offspring in replicates when the same versus different ecotypes are placed together differ significantly ( x2 = 25.76, df = 1, P < 0.001). These results suggest that interbreeding between ecotypes either does not occur or occurs at sufficiently low levels to remain undetected with the sample sizes we used. Because interbreeding at low levels can be genetically important, we used the binomial probability distribution to de- Genetic distance* SulliMill van Lake Lake Lake* (S) (S) Duck Lake (S) 0.059 0.016 Sullivan Lake (S) 0.077 Mill Lake (S) Winnewanna (S) Duck Marsh (L) George Pond (L) Winnewanna Lake (S) 0.142 0.058 0.130 Duck Marsh (L) 0.098 0.155 0.136 0.337 George Pond (L) 0.069 0.161 0.087 0.334 0.044 Kaiser Marsh (L) 0.145 0.166 0.156 0.290 0.100 0.148 Table 3. Inbreeding coefficients (Hartl and Clarke 1989) for each locus. x2 tests were used to determine whether genotype frequencies differed from Hardy-Weinberg expectations. The test was performed on the genotype frequencies in two classes: homozygotes and heterozygotes (df = 1). Asterisks indicate a significant deviation from Hardy-Weinberg expectations. Lines indicate loci that are at or near fixation for one allele (<5 expected heterozygotes) and therefore uninformative for determination of inbreeding coefficients and our test for fit to Hardy-Weinberg expectations. Population? Kaiser Road Marsh (L) Duck Marsh (L) George Pond (L) Duck Lake (S) Sullivan Lake (S) Mill Lake (S) Winnewanna Lake (S) MPI 0.130 0.105 -0.134 0.810*** 0.774*** 0.877*** 0.443* *P < 0.05, **p < 0.01, ***p < 0.001. -1L, large-ecotype population; S, small-ecotype population. TPI 0.041 0.060 -0.116 0.918*** 0.896*** 0.845*** 0.224 PGM 0.053 -0.012 - 0.005 0.202 0.493*** 0.303* 0.053 PGI -0.019 -0.034 0.145 0.394** 0.629*** 0.580*** 0.259 APK - MDH 0.023 - 1166 McPeek and Wellborn Table 4. Population crossesmade, the number of replicates that had at least one individual of each sex at the end, and the number of replicates in which offspring were produced. Replicates with reproduction Replicates* observed (%) Population cross Crosses within a population Sullivan Lake X Sullivan Lake 3(4) Duck Lake X Duck Lake 2(4) George Pond X George Pond 4(4) Duck Marsh X Duck Marsh 4(4) Crosses between populations within the same ecotype? Sullivan Lake X Duck Lake 6(8) Duck Marsh X George Pond 8(8) Crosses between different ecotypest Sullivan Lake X Duck Marsh 4(8) Sullivan Lake X George Pond 3(8) Duck Marsh X Duck Lake 7(8) Duck Lake X George Pond 5(8) 66 50 100 100 33 87 0 0 0 0 * Number in parentheses is the original number of replicates. The first number is the number of replicates at the end of the experiment that had at least one individual of each sex alive. -t In these crosses, half of the replicates were initiated with males of the first population listed and females of the second; the other half were initiated with females from the first population listed and males from the second. termine our confidence level in the interbreeding result by asking at what background levels of interbreeding is the probability of obtaining our result <0.05. This analysis indicated that the interbreeding probability per experimental unit was unlikely to be >0.15. Discussion This study sheds light on possible mechanisms by which Hyalella amphipods have diversified across the freshwater habitat gradient and may aid in understanding the more general role of ecological processes in shaping diversification. Recent investigations of several taxonomic groups undergoing diversification suggest that adaptation in the context of a habitat template may play a central role in the process of diversification (Schluter 1996). These investigations include studies of cave amphipods (Culver et al. 1995), Darwin’s finches (Grant 1986), sticklebacks (Schluter 1996), sockeye salmon (Foote et al. 1989; Wood and Foote 1990), and whitefish (Bernatchez et al. 1996). Study of such groups can be especially revealing of ecological mechanisms in evolution (e.g., Schluter and McPhail 1992, 1993) because processes fostering incipient divergence are less likely to be obscured by extensive postdivergence dispersal or accrual of secondary changes (Brooks and McLennan 1991; Avise 1994). We first discuss our results, then explore their implications for diversification in Hyalella. Genetic structure and diversification among populations- Allele frequencies at the six loci examined do not clearly distinguish populations of the two ecotypes. Hierarchical F statistics indicated greater genetic variation among populations within ecotypes than between ecotypes. This pattern is also evident in the UPGMA cluster analysis, in which the deepest division separates two small-ecotype populations from all other populations. Additionally, almost all allelic variation is due to quantitative differences in frequencies rather than qualitative differences in allele composition (Table 1). Although phylogenetic analysis is needed, these genetic patterns suggest recent ecotypic divergence in these populations. Genetic structure within populations- Ecotypes evince a dramatic difference in their fit to Hardy-Weinberg expectations for genotype frequencies (Table 3). Whereas large-ecotype populations did not deviate significantly from HardyWeinberg expectations, most small-ecotype populations displayed a clear and consistent deficiency in heterozygotes. Heterozygote deficiency is quantified by inbreeding coefficients (Table 3). The degree of heterozygote deficiency in Duck, Mill, and Sullivan Lakes is substantial. For example, the average ratio of observed-to-expected heterozygote frequencies for MPI, TPI, PGM, and PGI loci in these populations is 0.36; thus, we observed only about one-third of the number of heterozygotes expected with random mating. The exception among the small-ecotype populations was Winnewanna, which deviated from Hardy-Weinberg only at the MPI locus. The degree and consistency of the departure of genotype frequencies from Hardy-Weinberg expectations in Duck, Mill, and Sullivan Lakes suggest a common causative factor. The most plausible explanation for this departure is inbreeding, which can cause extreme departure from Hardy-Weinberg expectations (Falconer 1981; Hartl and Clark 1989). Although further study is required to resolve this somewhat perplexing result, we suggest that one possible cause is that low movement rates of small-ecotype individuals (Wellborn 1993) may result in the development of highly localized subpopulations, or demes. Hyalella primarily inhabit submerged macrophytes in these habitats. Because predatory fish in the small-ecotype habitats use visual cues to detect prey (Healey 1984), dispersal from plant to plant may be avoided because of its high mortality risk. If dispersal rates are very low, demes may develop from a few founder individuals at the spatial scale of individual plants or plant stems. Such demic structure may not develop in the fishless habitats because prey motion is generally less costly in fishless habitats (McPeek 1990; Wellborn et al. 1996). Reproductive isolation between ecotypes- Available evidence indicates that gene flow between Hyalella ecotypes in southeast Michigan is restricted, possibly to the degree of complete reproductive isolation. First, no successful reproduction was observed in the between-ecotype interbreeding trials, but successful reproduction was observed in 74% of within-ecotype trials. Second, Duck Lake (small ecotype) and Duck Marsh (large ecotype) populations were genetically dissimilar, despite the physical proximity of the habitats that makes movement of individuals between the habitats very likely. Third, reproductive isolation probably explains the persistence of both ecotypes in Winnewanna Reservoir (Wellborn 1995a). Individuals of the two ecotypes coexist in sympatry at roughly equal densities in Winne- Amphipod evolution wanna Reservoir, yet there is no apparent hybridization, as evidenced by the absence of morphologically intermediate individuals (Wellborn 1995a). Because even low levels of gene flow between ecotypes should lead to their genetic amalgamation under such conditions, reproductive isolation between the ecotypes is likely to play a strong role in their persistence as distinct ecotypes. Although the mechanism of reduced reproductive success between ecotypes has not yet been examined, two factors, a size bias in female mating preferences and the difference in body size between ecotypes, may play important roles. In the large ecotype, male reproductive success is strongly dependent on body size, with large males obtaining the great majority of copulations (Wellborn 1995b). This size bias in male reproductive success is apparently due to female choice of larger males (Wellborn 1995b). Thus, a small-ecotype male dispersing into a large-ecotype habitat may be effectively prevented from mating in that habitat simply because of his small body size. Similarly, a large-ecotype female dispersing into a small-ecotype habitat may avoid mating with smaller males. Although male reproductive success is also size-dependent for the small ecotype, larger males do not have greater mating success than males of intermediate size. Thus, a large-ecotype male dispersing into a small-ecotype habitat, while possibly being able to mate, will not have a special mating advantage conferred by its large size. In addition to behavioral differences in the size dependency of male mating success, the large disparity in body size between ecotypes might preclude interbreeding because of mechanical incompatibilities in fertilization. Males grasp females in a stereotypical fashion and must position their genital pore close to the posterior edge of the female’s ventral brood pouch at the time of egg release (Wilder 1940). Because this positioning of the genital pore requires that males bend their bodies around females, body size differences between ecotypes may hinder proper positioning and thus fertilization. Are ecotypes separate species?- Four lines of evidence suggest that large and small Hyalella ecotypes in southeast Michigan are separate species. First, as discussed above, this study and field patterns imply a high degree of reproductive isolation between populations of dissimilar ecotype, but not between populations of the same ecotype. Second, Duck Lake and Duck Marsh populations are genetically distinct despite their close spatial proximity and the substantial opportunity for interbreeding. Similarly, both ecotypes coexist sympatrically in Winnewanna Reservoir (Wellborn 1995a) yet remain morphologically distinct, indicating little if any gene flow between ecotypes in this habitat. Third, withinpopulation genetic structure differed between ecotypes but was similar within ecotypes. Fourth, ecotype differences in body size and important life history traits are nonplastic and genetically based (Strong 1972; Wellborn 1994a). The presence of genetically based phenotypic differences, differences in allelic frequencies, and absence of gene flow between ecotypes indicate speciation under current species concepts (Cracraft 1989; Templeton 1989). Although we think the weight of current evidence suggests that the large and small Hyalella ecotypes in southeast 1167 Michigan are separate species, the lack of consistent genetic differences between ecotypes points to ambiguity on the issue of speciation. Although the average genetic distance between populations of different ecotypes is consistent with the hypothesis of separate species (Thorpe 1982; Nei 1987), the range of distance values is high and overlaps with withinecotype genetic distances. This lack of distinct genetic differentiation between apparently different species probably reflects a relatively recent divergence time for the ecotypes and suggests the possibility of repeated parallel evolution of the ecotypes. A recent divergence is also suggested by the absence of distinct morphological differences between ecotypes (Wellborn 1995a). study helps to elucidate Evolutionary patterns - This some evolutionary patterns in Hyalella, at both geographic and local spatial scales. For example, an important largescale pattern of divergence in these amphipods is that Hyalella ecotypes similar to the large and small ecotypes found in southeastern Michigan also occur in Oregon (Strong 1972). In Oregon, coastal lakes with bluegill and other fish have small-bodied Hyalella populations, whereas mountain lakes, which contain only salmonid fish, contain large-bodied Hyalella (Strong 1972). One explanation for the parallel pattern in both geographic regions is that divergence in Hyalella into two primary ecotypes occurred only once, with their current distributional pattern due to postdivergence dispersal to appropriate habitat types. The absence of distinct allelic differences and the inconsistent pattern of allele frequency differentiation between ecotypes in Michigan, however, makes this scenario doubtful. That genetic differentiation within the small ecotype is greater than differentiation between ecotypes in southeast Michigan suggests that the divergence occurred more locally. Thus, a more plausible scenario is recent divergence in Michigan, with the Oregon ecotypes issuing from a similar but independent divergence event. When considered at the local spatial scale of southeast Michigan, our results suggest that ecotypic divergence may have occurred at least once within this group of habitats. As described earlier, the patterns of genetic differentiation do not clearly distinguish populations of the two ecotypes in this area. Whether considered at local or geographic spatial scales, our results suggest that Hyalella may have diversified through the mechanism of parallel speciation (Schluter and Nagel 1995). Parallel speciation involves repeated independent evolution of the same reproductive isolating mechanism in separate, but closely related, lineages. The process of parallel speciation involves the active or passive dispersal of individuals from an ancestral source population into ecologically similar habitats where descendent populations are established. Each descendent population evolves the same reproductive isolating mechanism, thus becoming isolated from the ancestral population but not necessarily reproductively isolated from other descendent populations (species). The same reproductive isolating mechanism evolves because descendent populations occupy ecologically similar habitats and thus evolve similarly by natural selection. In Hyalella, if body size differences between ecotypes are responsible for reproductive isolation of large and small ecotypes, then evo- 1168 McPeek and Wellborn lution of one ecotype from the other will produce reproductive isolation between them. For Hyalella, it is unclear whether one ecotype is always the ancestral “source” population, but allowing either ecotype to give rise to the other does not alter the fundamental processes that characterize parallel speciation. The possibility that the pattern of association between Hyalella ecotype and habitat type (fish-containing versus fishless) may have arisen through multiple independent evolutionary divergences at local or geographic scales is strengthened by the observations that size and life history changes appear to be (1) due to relatively simple shifts in quantitative traits and (2) driven by similar selective regimes that may cause rapid divergence within a lineage and trait convergence between lineages. The major differences between populations in both body size and life history appear to derive from a single, fundamental difference between the ecotypes in the way they allocate resources to growth versus reproduction across their ontogeny (Wellborn 1994b). When compared with the large-bodied ecotype, the small-bodied ecotype initiates allocation of resources to reproduction at a relatively small body size (and thus has a smaller terminal body size) and invests relatively heavily in reproduction (Wellborn 1994a,b). Furthermore, divergence appears to be an adaptive response to habitat differences in size-biased predation and the resultant schedules of size-specific mortality (Wellborn 1994a). Disparate predation regimes can drive rapid divergence in these life history traits (Reznick et al. 1990, 1997). Studies involving other aquatic species have suggested that parallel or convergent evolution, rather than common ancestry, is responsible for morphological similarity among isolated populations. For example, populations of the amphipod Gammarus minus in the southeastern United States inhabit both surface waters and subterranean pools. Cave populations have reduced eyes and large antennae relative to surface water populations (Culver 1987; Kane et al. 1992), and morphological similarity among populations occupying similar habitats has apparently arisen through multiple episodes of parallel evolution (Jones et al. 1992; Kane et al. 1992; Sarbu et al. 1993; Culver et al. 1995). Conclusions The gradient of freshwater habitats from small ponds to large lakes may play an important role in diversification of freshwater taxa (McPeek et al. 1996, Wellborn et al. 1996). Many freshwater animal genera contain species that are distributed among ecologically disparate regions of the gradient (Wellborn et al. 1996), and such spatial heterogeneity in ecological regime can drive trait divergence among spatially segregated populations (Reznick and Endler 1982; Reznick et al. 1990; Neill 1992; Wellborn 1994a; Wellborn et al. 1996). In such an ecological setting, parallel speciation or related processes may be important mechanisms of diversification. Future study of explicit evolutionary mechanisms of diversification across the habitat gradient, including studies of population genetics, phylogenetics, and selection, should contribute importantly to our understanding of the role of ecological processes in shaping lineage diversification. References Amphipod evolution 1169