Marty Condon

Hidden Neotropical Diversity: Greater Than the Sum of Its Parts

The diversity of tropical herbivorous insects has been explained as a direct function of plant species diversity. Testing that explanation, we reared 2857 flies from flowers and seeds of 24 species of plants from 34 neotropical sites. Samples yielded 52 morphologically similar species of flies and documented highly conserved patterns of specificity to host taxa and host parts. Widespread species of plants can support 13 species of flies. Within single populations of plants, we typically found one or more fly species specific to female flowers and multiple specialists on male flowers. We suggest that neotropical herbivorous insect diversity is not simply a function of plant taxonomic and architectural diversity, but also reflects the geographic distribution of hosts and the age and area of the neotropics.

Six cryptic species on a single species of host plant: morphometric evidence for possible reproductive character displacement

Abstract 1. Diversification of some highly host‐specific herbivorous insects may occur in allopatry, without shifts in host use. Such allopatric divergence may be accelerated by sexual selection operating on courtship displays. Wing size and shape may affect visual and vibrational courtship displays in tephritid fruit flies. Geometric morphometric methods were used to examine wings of six sympatric cryptic species in the neotropical genus Blepharoneura. All six species feed on flowers of the same species of host (Gurania spinulosa), a neotropical vine in the Cucurbitaceae. Three of the fly species court and mate in close proximity on the host. Thus, courtship behaviours could serve as important reproductive isolating mechanisms. Two sets of hypotheses were tested: (i) species differ in wing shape and wing size; and (ii) species are sexually dimorphic in wing size and wing shape. Wing size differed among a few species, but wing shape differed significantly among all six species. Sexual dimorphism in wing size was found in only one species, but sexual dimorphism in wing shape was found in two of the three species known to court on the same host plant. In the two sexually dimorphic species, wing shape differed among males, but not among females. This suggests that selection for reproductive character displacement might accelerate divergence in wing shape.

Lethal Interactions Between Parasites and Prey Increase Niche Diversity in a Tropical Community

Hidden Diversity Why are there so many species in the tropics? Niche partitioning by highly specialized plant species seems to be the main generator of high diversity. Condon et al. (p. 1240; see the Perspective by Godfray) show that niche partitioning can also be generated by interactions between plant resources and parasites, resulting in hyperdiverse communities. The cryptic diversity of 14 neotropical fly pollinators and 18 of their highly specific wasp parasites induced mortality partitions between multiple narrow niches. The extreme specificity of the wasp-fly relationships was initially only revealed by molecular analysis. Incorrect fly-host choice in parasitoid wasps creates multidimensional niches, generating high levels of hidden diversity. Ecological specialization should minimize niche overlap, yet herbivorous neotropical flies (Blepharoneura) and their lethal parasitic wasps (parasitoids) exhibit both extreme specialization and apparent niche overlap in host plants. From just two plant species at one site in Peru, we collected 3636 flowers yielding 1478 fly pupae representing 14 Blepharoneura fly species, 18 parasitoid species (14 Bellopius species), and parasitoid-host associations, all discovered through analysis of molecular data. Multiple sympatric species specialize on the same sex flowers of the same fly host-plant species—which suggests extreme niche overlap; however, niche partitioning was exposed by interactions between wasps and flies. Most Bellopius species emerged as adults from only one fly species, yet evidence from pupae (preadult emergence samples) show that most Bellopius also attacked additional fly species but never emerged as adults from those flies.

Genetically differentiated races and speciation-with-gene-flow in the sunflower maggot, Strauzia longipennis

The ecological interactions parasitic insects have with their hosts may contribute to their prodigious diversity, which is unrivaled among animals. Many insects assumed to be polyphagous generalists have been shown to consist of several differentiated races, each occupying a different host-niche. The sunflower maggot fly, Strauzia longipennis, has long been thought to consist of two or more races due to its substantial intra-specific morphological variation. Here, we use nuclear and mitochondrial markers to test the hypothesis that S. longipennis is a complex of two or more partially reproductively isolated races. We collected S. longipennis flies as pupae from roots of Jerusalem artichoke (Helianthus tuberosus) and as adults swept from leaves of mature H. tuberosus across the breadth of a field season. Flies were scored for morphological variety (typica or vittigera), mitochondrial haplotype (A or B) and a panel of 176 AFLP loci. Bayesian clustering and neighbor-joining phylogenetic analyses of AFLP data supported the existence of at least three, possibly four, genetic races of Strauzia (clusters I, II, III, and V), as well as a small number of putative interracial hybrids (cluster IV). Clusters I and III each consisted of flies of both morphological varieties and both haplotype groups, while flies in cluster II were all of variety typica and all but one was of mitochondrial haplotype B. Flies in cluster II were also collected only as adults on H. tuberosus and not among flies reared from pupae collected from H. tuberosus roots, suggesting that they use a different plant as their larval host. Mean capture date was significantly different between flies of each genetic race, indicating that partial allochronic isolation may be one contemporary barrier to gene flow between races. Evidence that mitochondrial genomes and morphological traits have moved between lineages implies a model of speciation-with-gene-flow for S. longipennis races.

Incipient Speciation in Strauzia longipennis (Diptera: Tephritidae): Two Sympatric Mitochondrial DNA Lineages in Eastern Iowa

ABSTRACT Strauzia longipennis (Wiedemann) (Diptera: Tephritidae) is a notoriously variable species. Seven varieties were once recognized. Three varieties were elevated to species status. The status of the other four varieties, including the synonyms for S. longipennis, has been contested. Such taxonomic instability, particularly when associated with variable patterns of host use, suggests that S. longipennis may represent a dynamic complex of host-associated populations in the process of divergence. To detect evidence of genetic differentiation indicating genetically distinct sympatric populations of S. longipennis, we sequenced a fragment of cytochrome c oxidase subunit I of mitochondrial DNA of S. longipennis from two sites (three habitats) in eastern Iowa. At each site, we found two genetically and morphologically distinct sympatric populations. One corresponds to morphological descriptions of S. longipennis variety typica (Loew). The other corresponds to descriptions of S. longipennis variety vittigera (Loew). High levels of genetic differentiation between these divergent sympatric populations suggest the populations might represent host races or incipient species.

Genetic differentiation associated with host plants and geography among six widespread species of South American Blepharoneura fruit flies (Tephritidae)

Tropical herbivorous insects are astonishingly diverse, and many are highly host‐specific. Much evidence suggests that herbivorous insect diversity is a function of host plant diversity; yet, the diversity of some lineages exceeds the diversity of plants. Although most species of herbivorous fruit flies in the Neotropical genus Blepharoneura are strongly host‐specific (they deposit their eggs in a single host plant species and flower sex), some species are collected from multiple hosts or flowers and these may represent examples of lineages that are diversifying via changes in host use. Here, we investigate patterns of diversification within six geographically widespread Blepharoneura species that have been collected and reared from at least two host plant species or host plant parts. We use microsatellites to (1) test for evidence of local genetic differentiation associated with different sympatric hosts (different plant species or flower sexes) and (2) examine geographic patterns of genetic differentiation across multiple South American collection sites. In four of the six fly species, we find evidence of local genetic differences between flies collected from different hosts. All six species show evidence of geographic structure, with consistent differences between flies collected in the Guiana Shield and flies collected in Amazonia. Continent‐wide analyses reveal – in all but one instance – that genetically differentiated flies collected in sympatry from different host species or different sex flowers are not one anothers closest relatives, indicating that genetic differences often arise in allopatry before, or at least coincident with, the evolution of novel host use.

Divergence before the host shift? Prezygotic reproductive isolation among three varieties of a specialist fly on a single host plant

1. Although divergence via host‐plant shifting is a common theme in the speciation of some phytophagous insects, it is not clear whether host shifts are typically initiators of speciation or if they instead contribute to divergence events already in progress. While host shifts appear to be generally associated with speciation events for flies in the genus Strauzia, three sympatric varieties of the sunflower fly [Strauzia longipennis (Wiedemann)] co‐occur on the same host plant in the Midwestern United States and may have evolved reproductive barriers without a host shift.