Repeated evolution of reproductive isolation in a marine snail: unveiling mechanisms of speciation

Johannesson, Kerstin; Panova, Marina; Kemppainen, Petri; André, Carl; Rolán‐Alvarez, Emilio; Butlin, Roger K.

doi:10.1098/rstb.2009.0256

Cited by 162 publications

(259 citation statements)

References 88 publications

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“…One potential origin of such variation, as suggested in this study and in Johannesson et al (2010), is ecotype evolution in concert, that is, new positively selected alleles directly sweep to high frequency in a specific habitat (ecotype) over large parts of a species' distribution. This explanation is similar to the 'transporter mechanism', as suggested by Schluter and Conte (2009), in which selection in one habitat repeatedly acts on standing genetic variation that is maintained in another habitat by export of alleles adaptive to the first habitat from elsewhere in the range.…”

Section: Discussionmentioning

confidence: 99%

“…(4) Locally adapted characters could have evolved in a concerted fashion; that is, the alleles responsible for trait differences have each arisen once and thereafter they have spread by spatial selective sweeps to similar microhabitats in other locations. This idea assumes that gene flow among ecotypes is high enough to allow the spread of advantageous alleles at a rate that at least overrides the rate by which these alleles would have arisen by repeated new mutations in each local site (for a similar mechanism explaining the collective evolution of species, see Rieseberg and Burke, 2001;Morjan and Rieseberg, 2004;Johannesson et al, 2010).…”

Section: Discussionmentioning

confidence: 99%

“…Ecotype-specific selective sweep Four alternative (not mutually exclusive) genetic mechanisms have been suggested for the repeated evolution of phenotypic traits ('parallel evolution') in pairs of contrasting ecotypes (see Johannesson et al, 2010). (1) The mutation responsible for the local adaptation could be due to parallel evolution in the strict sense; that is, independent mutations controlling the locally adapted traits could have arisen and been driven to fixation in different geographic locations (Rolan-Alvarez et al, 2004;Panova et al, 2006;Quesada et al, 2007;Galindo et al, 2009).…”

Section: Discussionmentioning

confidence: 99%

“…The genetic mechanisms behind this process are in many cases unclear but possible scenarios (reviewed in Johannesson et al, 2010) include: (1) parallel evolution, that is, the independent evolution of homologous loci that fulfil the same function in two or more lineages (Wood et al, 2005), (2) secondary contact after an initial allopatric divergence (Wilding et al, 2001), (3) evolution from standing genetic variation (Campbell and Bernatchez, 2004;Schluter et al, 2004;Barrett and Schluter, 2008) and (4) evolution in concert where positively selected alleles, directly after their appearance, spread among demographically independent populations by migration (Rieseberg and Burke, 2001;Morjan and Rieseberg, 2004;Johannesson et al, 2010). Distinguishing between these scenarios is possible but requires the detailed and joint analyses of both neutral and selected loci (Johannesson et al, 2010). An increasingly popular approach to identify loci under selection is to look for outliers in genome scans (see Nosil et al, 2009 for a review).…”

Section: Introductionmentioning

confidence: 99%

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Intron sequences of arginine kinase in an intertidal snail suggest an ecotype-specific selective sweep and a gene duplication

et al. 2010

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Intron sequences of arginine kinase in an intertidal snail suggest an ecotype-specific selective sweep and a gene duplication

et al. 2010

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“…On a small spatial scale (tens of meters), several recent studies have highlighted strong genetic discontinuities between adjacent populations segregating by intertidal height (periwinkles: Johannesson et al 2010) or by depth (gorgonians: Mokhtar--Jamai et al 2010 andPrada et al 2008; bird's nest coral: Bongaerts et al 2010). In addition to the caveats about correlation mentioned above, even if genotype--by--environment fitness differences can be demonstrated (as in Bongaerts et al 2011), it will be important to consider whether endogenous reproductive incompatibilities also maintain genetic divergence, with multiple loci segregating with environmental features indicative of such a situation.…”

Section: Adaptive Differentiation Seascape Genetics and Fitnessmentioning

confidence: 99%

Seascape genetics of Indo-Pacific reef organisms: methodologies and case studies for an emerging discipline

Liggins¹

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Which factors shape population connectivity and the consistency of their influence across species and seascapes is largely unresolved. This thesis takes a comparative genetic approach to investigate the influences of seascape topology (past sea level changes, contemporary oceanography, and geography) and species biology on the genetic connectivity among coral reefs around Australia, the Indo-Australasian Archipelago (IAA), and the wider Indo-Pacific. I focus on a suite of common, codistributed coral reef fishes and invertebrates that differ in life history characteristics. In the introductory chapter of my thesis I discuss population connectivity in marine systems, the contribution of seascape genetics to marine population connectivity research, and the state of our knowledge in the Indian and Pacific Oceans (Chapter One). Chapters Two and Three review the field of seascape genetics and the methodologies used in seascape genetic studies, respectively. My empirical research (Chapters Four-Six) takes a broad, yet integrated approach to describe and understand the processes underlying seascape genetic patterns around Australia, the IAA, and the Indo-Pacific. First, I investigate historical spatial genetic (mitochondrial DNA, mtDNA) patterns and processes using a comparative, multi-species framework (Chapter Four). I extend typical methods of comparative phylogeography to include: a matrix comparison method that allows the quantitative characterization of spatial genetic patterns; and a multiple regression modeling approach to identify the processes underlying the spatial genetic patterns for each species. I find that despite being subjected to common geographic and seascape influences, spatial genetic patterns differ across four common coral reef fishes (Acanthurus triostegus, Dascyllus trimaculatus, Halichoeres hortulanus, Pomacentrus coelestis). Although species with similar dispersal potential (based on egg type and pelagic larval duration) have the most similar spatial genetic patterns, the seascape features and processes (e.g. previous landbridges and oceanographic distances) underlying the genetic patterns are not always shared among species. Second, I characterize the latitude-wide genetic patterns of one species (P. coelestis) and extend methods typically used in such investigations by borrowing concepts and measures more commonly used for analyses of community composition (Chapter Five). Genealogical analyses reveal that levels of population genetic diversity in the core of the species range are elevated by the co-occurrence of two cryptic clades. Furthermore, the application of partitioned -diversity measures and nestedness analyses reveal that differing demographic processes underlie the genetic patterns observed at the northern and southern latitudinal peripheries of the species range. Last, I focus on edge-of-range genetic patterns for two tropical echinoderm species (Acanthaster planci and Tripneustes gratilla) at a little-studied high latitude peripheral population, Kermadec Islands, New Zea...

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Hybrid Zones

Kawakami¹,

Butlin²

2012

Encyclopedia of Life Sciences

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A hybrid zone occurs where two distinct genetic forms meet, mate and produce offspring with mixed genomes. Such zones may vary in width, length and patchiness, and are found between species, subspecies, races or forms. Stable hybrid zones may be maintained by selection against hybrids, environmental selection, or a combination of the two. A hybrid zone can arise either by direct environmental selection in contiguous populations or by renewed contact between previously isolated populations. Hybrid zones act as semi‐permeable barriers, which allow gene exchange for neutral or adaptive characters, whereas restricting introgression of alleles that contribute to local adaptation or reduced hybrid fitness. The study of genomic regions that experience barriers to gene flow can provide an important window for identifying specific genes and mutations that underlie reproductive isolation and local adaptation. With the help of recent technological advances in development of thousands of molecular markers, distributed genome‐wide, identification of such genomic regions is becoming possible in natural hybrid zones. Key Concepts: A hybrid zone is a narrow geographic region where two genetically distinct populations or species are found in close proximity and hybridise to produce offspring of mixed ancestry. Hybrid zones are widespread, both geographically and across animal and plant taxa. A hybrid zone is maintained by a balance between selection and dispersal. Selective forces can be intrinsic (e.g. selection against less‐fit hybrids) or extrinsic (e.g. environment‐dependent selection). Spatial analysis of allele‐frequency clines across a hybrid zone provides estimates of important population genetic parameters (e.g. selection, dispersal and linkage disequilibrium). Surveys of differential gene flow across a hybrid zone have the potential to localise genomic regions that habour genes responsible for barriers to gene exchange.

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Repeated evolution of reproductive isolation in a marine snail: unveiling mechanisms of speciation

Cited by 162 publications

References 88 publications

Intron sequences of arginine kinase in an intertidal snail suggest an ecotype-specific selective sweep and a gene duplication

Intron sequences of arginine kinase in an intertidal snail suggest an ecotype-specific selective sweep and a gene duplication

Seascape genetics of Indo-Pacific reef organisms: methodologies and case studies for an emerging discipline

Hybrid Zones

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