Differential introgression and the maintenance of species boundaries in an advanced generation avian hybrid zone

AbstractInteractions between extrinsic factors, such as disruptive selection, and intrinsic factors, such as genetic incompatibilities among loci, can contribute to the maintenance of species boundaries. The relative roles of these factors in the establishment of reproductive isolation can be examined using species pairs characterized by gene flow throughout their divergence history. We investigated the process of speciation and the maintenance of species boundaries between Pinus strobiformis and P.flexilis. Utilizing ecological niche modeling, demographic modeling, and genomic cline analyses, we illustrated a history of divergence with continuous gene flow between these species. We found an abundance of advanced generation hybrids and a lack of loci exhibiting large allele frequency differences across the hybrid zone. Additionally, we found evidence for climate-associated variation in the hybrid index and niche divergence between parental species and the hybrid zone. Our results are consistent with extrinsic factors, such as climate, being an important isolating mechanism for these species. A buildup of intrinsic incompatibilities and of co-adapted gene complexes is also apparent in our results, although these appear to be in the earliest stages of development. This supports previous work in coniferous species demonstrating the importance of extrinsic factors in creating and enforcing species boundaries. Overall, we lend support to the hypothesis that varying strengths and directions of selection pressures across the long lifespans of conifers, in combination with their life history strategies, delay the evolution of strong intrinsic incompatibilities.

Download Full-text

A maladaptive combination of traits contributes to the maintenance of a stable hybrid zone between two divergent species of Drosophila

10.1101/138388 ◽

2017 ◽

Cited By ~ 3

Author(s):

Brandon S. Cooper ◽

Alisa Sedghifar ◽

W. Thurston Nash ◽

Aaron A. Comeault ◽

Daniel R. Matute

Keyword(s):

Gene Flow ◽

Hybrid Zone ◽

Hybrid Zones ◽

Hybrid Male ◽

Open Habitat ◽

Preferred Habitat ◽

Species Overlap ◽

Agricultural Areas ◽

Stable Hybrid ◽

Advanced Generation

ABSTRACTGeographical areas where two species come into contact and hybridize serve as natural laboratories for assessing mechanisms that limit gene flow between species. The ranges of about half of all closely related Drosophila species overlap, and the genomes of several pairs reveal signatures of past introgression. However, only two contemporary hybrid zones have been characterized in the genus, and both are recently diverged sister species (D. simulans-D. sechellia, Ks = 0.05; D. yakuba-D. santomea, Ks = 0.048). Here we present evidence of a new hybrid zone, and the ecological mechanisms that maintain it, between two highly divergent Drosophila species (Ks = 0.11). On the island of Bioko in west Africa, D. teissieri occupies mostly forests, D. yakuba occupies mostly open agricultural areas, and recently, we discovered that hybrids between these species occur near the interface of these habitats. Genome sequencing revealed that all field-sampled hybrids are F1 progeny of D. yakuba females and D. teissieri males. We found no evidence for either advanced-generation hybrids or F1 hybrids produced by D. teissieri females and D.yakuba males. The lack of advanced-generation hybrids on Bioko is consistent with mark-recapture and laboratory experiments that we conducted, which indicate hybrids have a maladaptive combination of traits. Like D. yakuba, hybrids behaviorally prefer open habitat that is relatively warm and dry, but like D. teissieri, hybrids have low desiccation tolerance, which we predict leaves them physiologically ill-equipped to cope with their preferred habitat. These observations are consistent with recent findings of limited introgression in the D. yakuba clade and identify an ecological mechanism for limiting gene flow between D. yakuba and D. teissieri; namely, selection against hybrids that we have documented, in combination with hybrid male sterility, contributes to the maintenance of this narrow (~30m), stable hybrid zone centered on the forest-open habitat ecotone. Our results show how a deleterious combination of parental traits can result in unfit or maladapted hybrids.

Download Full-text

HYBRID ZONE ORIGINS, SPECIES BOUNDARIES, AND THE EVOLUTION OF WING-PATTERN DIVERSITY IN A POLYTYPIC SPECIES COMPLEX OF NORTH AMERICAN ADMIRAL BUTTERFLIES (NYMPHALIDAE: LIMENITIS)

Evolution ◽

10.1111/j.1558-5646.2008.00366.x ◽

2008 ◽

Vol 62 (6) ◽

pp. 1400-1417 ◽

Cited By ~ 33

Author(s):

Sean P. Mullen ◽

Erik B. Dopman ◽

Richard G. Harrison

Keyword(s):

Hybrid Zone ◽

North American ◽

Species Complex ◽

Species Boundaries ◽

Wing Pattern ◽

Pattern Diversity

Download Full-text

Low fertility of wild hybrid male flycatchers despite recent divergence

Biology Letters ◽

10.1098/rsbl.2013.0169 ◽

2013 ◽

Vol 9 (3) ◽

pp. 20130169 ◽

Cited By ~ 24

Author(s):

Murielle Ålund ◽

Simone Immler ◽

Amber M. Rice ◽

Anna Qvarnström

Keyword(s):

Hybrid Zone ◽

Parental Species ◽

Low Fertility ◽

Species Boundaries ◽

Postzygotic Isolation ◽

Hybrid Male ◽

Hybrid Fitness ◽

Extra Pair Paternity ◽

Wild Hybrid ◽

Sperm Traits

Postzygotic isolation may be important for maintaining species boundaries, particularly when premating barriers are incomplete. Little is known about the course of events leading from minor environmental mismatches affecting hybrid fitness to severe genetic incompatibilities causing sterility or inviability. We investigated whether reduced reproductive success of hybrid males was caused by suboptimal sperm traits or by more severe genetic incompatibilities in a hybrid zone of pied ( Ficedula hypoleuca ) and collared flycatchers ( F. albicollis ) on the island of Öland, Sweden. About 4 per cent hybridization is observed in this population and all female hybrids are sterile. We found no sperm in the ejaculates of most sampled hybrid males, and sperm with abnormal morphology in two hybrids. Furthermore, none of the hybrids sired any offspring because of high levels of hatching failure and extra-pair paternity in their nests. These results from a natural hybrid zone suggest that the spermatogenesis of hybrid males may become disrupted despite little genetic divergence between the parental species.

Download Full-text

Opposing dominance within a color gene block is associated with maladaptive hybrid signal discordance

10.1101/2021.02.18.431741 ◽

2021 ◽

Author(s):

Devin R. de Zwaan ◽

Jacqueline Mackenzie ◽

Else Mikklesen ◽

Silu Wang

Keyword(s):

Hybrid Zone ◽

Social Dynamics ◽

Color Variation ◽

Species Boundaries ◽

Gene Block ◽

Behavioral Mechanism ◽

Stable Species ◽

Significant Gene ◽

Behavioral Mechanisms ◽

Social Signaling

AbstractColor divergence is increasingly recognized as important for speciation in songbirds through its influence on social dynamics. However, the behavioral mechanisms underlying the eco-evolutionary feedback that acts across species boundaries is poorly understood. The hybrid zone between Setophaga occidentalis (SOCC) and S. townsendi (STOW) in the Cascade mountain ranges provides a natural observatory to test the interplay between genetics and social behaviour in maintaining species boundaries. Recently, we found that selection within a gene block underpinning color variation (ASIP-RALY) has maintained a stable and narrow hybrid zone. Here we investigated the social signaling roles of cheek darkness and flank streaking, two color traits linked to ASIP-RALY that reflect opposing dominance of SOCC and STOW alleles. We found that both traits act as honest badges of status, as they predicted male breeding quality. The opposing dominance effects of ASIP-RALY resulted in signal discordance for heterozygotes, which in turn was associated with inferior hybrid territorial performance, a fitness proxy quantified by vocal and physical responses of resident males to a decoy intruder. Taken together, this study highlights a potential behavioral mechanism underlying selection acting on a simple genetic architecture that has maintained a stable species boundary over decades despite significant gene flow.

Download Full-text