TY - JOUR
T1 - Genetic and Ecogeographic Controls on Species Cohesion in Australia’s Most Diverse Lizard Radiation
AU - Prates, Ivan
AU - Singhal, Sonal
AU - Marchán-Rivadeneira, M. Raquel
AU - Grundler, Maggie R.
AU - Moritz, Craig
AU - Donnellan, Stephen C.
AU - Rabosky, Daniel L.
N1 - Publisher Copyright:
© 2022 The University of Chicago.
PY - 2022/2
Y1 - 2022/2
N2 - Species vary extensively in geographic range size and climatic niche breadth. If range limits are primarily determined by climatic factors, species with broad climatic tolerances and those that track geographically widespread climates should have large ranges. However, large ranges might increase the probability of population fragmentation and adaptive divergence, potentially decoupling climatic niche breadth and range size. Conversely, ecological generalism in large-ranged species might lead to higher gene flow across climatic transitions, increasing species’ cohesion and thus decreasing genetic isolation by distance (IBD). Focusing on Australia’s iconic Ctenotus lizard radiation, we ask whether species range size scales with climatic niche breadth and the degree of population isolation. To this end, we infer independently evolving operational taxonomic units (OTUs), their geographic and climatic ranges, and the strength of IBD within OTUs based on genome-wide loci from 722 individuals spanning 75 taxa. Large-ranged OTUs were common and had broader climatic niches than small-ranged OTUs; thus, large ranges do not appear to simply result from passive tracking of widespread climatic zones. OTUs with larger ranges and broader climatic niches showed relatively weaker IBD, suggesting that large-ranged species might possess intrinsic attributes that facilitate genetic cohesion across large distances and varied climates. By influencing population divergence and persistence, traits that affect species cohesion may play a central role in large-scale patterns of diversification and species richness.
AB - Species vary extensively in geographic range size and climatic niche breadth. If range limits are primarily determined by climatic factors, species with broad climatic tolerances and those that track geographically widespread climates should have large ranges. However, large ranges might increase the probability of population fragmentation and adaptive divergence, potentially decoupling climatic niche breadth and range size. Conversely, ecological generalism in large-ranged species might lead to higher gene flow across climatic transitions, increasing species’ cohesion and thus decreasing genetic isolation by distance (IBD). Focusing on Australia’s iconic Ctenotus lizard radiation, we ask whether species range size scales with climatic niche breadth and the degree of population isolation. To this end, we infer independently evolving operational taxonomic units (OTUs), their geographic and climatic ranges, and the strength of IBD within OTUs based on genome-wide loci from 722 individuals spanning 75 taxa. Large-ranged OTUs were common and had broader climatic niches than small-ranged OTUs; thus, large ranges do not appear to simply result from passive tracking of widespread climatic zones. OTUs with larger ranges and broader climatic niches showed relatively weaker IBD, suggesting that large-ranged species might possess intrinsic attributes that facilitate genetic cohesion across large distances and varied climates. By influencing population divergence and persistence, traits that affect species cohesion may play a central role in large-scale patterns of diversification and species richness.
KW - Climatic niche breadth
KW - Geographic range size
KW - Isolation by distance
KW - Macroecology
KW - Speciation
KW - Species delimitation
UR - http://www.scopus.com/inward/record.url?scp=85122313111&partnerID=8YFLogxK
U2 - 10.1086/717411
DO - 10.1086/717411
M3 - Article
SN - 0003-0147
VL - 199
SP - E57-E75
JO - American Naturalist
JF - American Naturalist
IS - 2
ER -