Diploid organisms manipulate the extent to which their haploid gametes experience selection. Animals typically produce sperm with a diploid complement of most proteins and RNA, limiting selection on the haploid genotype. Plants, however, exhibit extensive expression in pollen, with actively transcribed haploid genomes. Here we analyze models that track the evolution of genes that modify the strength of haploid selection to predict when evolution intensifies and when it dampens the “selective arena” within which male gametes compete for fertilization. Considering deleterious mutations, evolution leads diploid mothers to strengthen selection among haploid sperm/pollen, because this reduces the mutation load inherited by their diploid offsprin...
To date, research on the evolution of sex chromosomes has focused on sexually antagonistic selection...
As an immediate consequence of sexual reproduction, biphasic life cycles with alternating diploid an...
An inescapable consequence of sex in eukaryotes is the evolution of a biphasic life cycle with alter...
Diploid organisms manipulate the extent to which their haploid gametes experience selection. Animals...
Diploid organisms manipulate the extent to which their haploid gametes experience selection. Animals...
Many organisms spend a significant portion of their life cycle as haploids and as diploids (a haploi...
Sexual reproduction leads to an alternation between haploid and diploid phases, whose relative lengt...
Evolutionary rates and strength of selection differ markedly between haploid and diploid genomes. An...
The evolution of sex chromosomes is usually considered to be driven by sexually antagonistic selecti...
The evolution of dimorphic sex chromosomes is driven largely by the evolution of reduced recombinati...
A consequence of sexual reproduction in eukaryotes is the evolution of a biphasic life cycle with al...
Frequency-dependent selection should drive dioecious populations toward a 1:1 sex ratio, but biased ...
To date, research on the evolution of sex chromosomes has focused on sexually antagonistic selection...
As an immediate consequence of sexual reproduction, biphasic life cycles with alternating diploid an...
An inescapable consequence of sex in eukaryotes is the evolution of a biphasic life cycle with alter...
Diploid organisms manipulate the extent to which their haploid gametes experience selection. Animals...
Diploid organisms manipulate the extent to which their haploid gametes experience selection. Animals...
Many organisms spend a significant portion of their life cycle as haploids and as diploids (a haploi...
Sexual reproduction leads to an alternation between haploid and diploid phases, whose relative lengt...
Evolutionary rates and strength of selection differ markedly between haploid and diploid genomes. An...
The evolution of sex chromosomes is usually considered to be driven by sexually antagonistic selecti...
The evolution of dimorphic sex chromosomes is driven largely by the evolution of reduced recombinati...
A consequence of sexual reproduction in eukaryotes is the evolution of a biphasic life cycle with al...
Frequency-dependent selection should drive dioecious populations toward a 1:1 sex ratio, but biased ...
To date, research on the evolution of sex chromosomes has focused on sexually antagonistic selection...
As an immediate consequence of sexual reproduction, biphasic life cycles with alternating diploid an...
An inescapable consequence of sex in eukaryotes is the evolution of a biphasic life cycle with alter...