Abstract
In birds, males are homogametic and carry two copies of the Z chromosome (‘ZZ’), while females are heterogametic and exhibit a ‘ZW’ genotype. The Z chromosome evolves at a faster rate than similarly sized autosomes, a phenomenon termed ‘fast-Z evolution’. This is thought to be caused by two independent processes—greater Z chromosome genetic drift owing to a reduced effective population size, and stronger Z chromosome positive selection owing to the exposure of partially recessive alleles to selection. Here, we investigate the relative contributions of these processes by considering the effect of role-reversed polyandry on fast-Z in shorebirds, a paraphyletic group of wading birds that exhibit unusually diverse mating systems. We find stronger fast-Z effects under role-reversed polyandry, which is consistent with particularly strong selection on polyandrous females driving the fixation of recessive beneficial alleles. This result contrasts with previous research in birds, which has tended to implicate a primary role of genetic drift in driving fast-Z variation. We suggest that this discrepancy can be interpreted in two ways—stronger sexual selection acting on polyandrous females overwhelms an otherwise central role of genetic drift, and/or sexual antagonism is also contributing significantly to fast-Z and is exacerbated in sexually dimorphic species.
Original language | English |
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Article number | 20240397 |
Journal | Proceedings of the Royal Society B: Biological Sciences |
Volume | 291 |
Issue number | 2024 |
Early online date | 12 Jun 2024 |
DOIs | |
Publication status | Published - 30 Jun 2024 |
Data Availability Statement
The genome assemblies used were all previously published [36,54] and can be found deposited at NCBI SRA (accession PRJNA545868 and PRJNA739535), with some also found at CNGBdb (accession CNP0001928). The R code, as well as orthologue alignments, datasets and phylogenies, have been deposited onto Zenodo [82].Supplementary material is available online [83].
Acknowledgements
Many thanks to Guojie Zhang for providing funding for the Common Ringed Plover resequencing and for making available the genome assemblies that made this analysis possible. Many thanks also to Mike Bruford for their supervision and advice and to Judith Mank for their helpful comments on an early version of this manuscript.Funding
This work was supported by the National Environmental Research Council (NE/S007504/1 to K.W., NE/P004121/1 to A.O.U.), PAPPIT-DGAPA-UNAM (IA204020 to A.O.U.), Frontiers in Science CONACyT (FORDECYT/24SE/2020/09/30-03\u2014682142 to A.O.U.), the Royal Society (WM170050 and APX\\R1\\191045 to T.S.), the National Research, Development and Innovation Office of Hungary (KKP-126949 and HUN-REN-DE Reproductive Strategies Grant 1102207 to T.S.) and by a University of Bath Developing Networks in Europe Grant to A.O.U. and T.S.
Funders | Funder number |
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University of Bath | |
PAPPITDGAPA-UNAM | |
PAPPIT-DGAPA-UNAM | IA204020 |
Nemzeti Kutatási Fejlesztési és Innovációs Hivatal | KKP-126949, 1102207 |
Frontiers in Science CONACyT | FORDECYT/24SE/2020/09/30-03—682142 |
Royal Society | WM170050, APX\R1\191045 |
Natural Environment Research Council | NE/S007504/1, NE/P004121/1 |
Keywords
- fast-Z
- genetic drift
- polyandry
- sexual selection
- shorebirds
- Z chromosome
ASJC Scopus subject areas
- General Immunology and Microbiology
- General Biochemistry,Genetics and Molecular Biology
- General Environmental Science
- General Agricultural and Biological Sciences