Sex determination in papaya is controlled by a recently evolved XY chromosome pair, with two slightly different Y chromosomes controlling the development of males (Y) and hermaphrodites (Y h ).To study the events of early sex chromosome evolution, we sequenced the hermaphrodite-specific region of the Y h chromosome (HSY) and its X counterpart, yielding an 8.1-megabase (Mb) HSY pseudomolecule, and a 3.5-Mb sequence for the corresponding X region. The HSY is larger than the X region, mostly due to retrotransposon insertions. The papaya HSY differs from the X region by two large-scale inversions, the first of which likely caused the recombination suppression between the X and Y h chromosomes, followed by numerous additional chromosomal rearrangements. Altogether, including the X and/or HSY regions, 124 transcription units were annotated, including 50 functional pairs present in both the X and HSY. Ten HSY genes had functional homologs elsewhere in the papaya autosomal regions, suggesting movement of genes onto the HSY, whereas the X region had none. Sequence divergence between 70 transcripts shared by the X and HSY revealed two evolutionary strata in the X chromosome, corresponding to the two inversions on the HSY, the older of which evolved about 7.0 million years ago. Gene content differences between the HSY and X are greatest in the older stratum, whereas the gene content and order of the collinear regions are identical. Our findings support theoretical models of early sex chromosome evolution.Carica papaya | DNA sequencing | molecular evolution | sex chromosomes S ex chromosomes have evolved independently in diverse lineages of animals and plants, and new dioecious species are still evolving (1, 2). Evidence of homology between nascent sex chromosome pairs in flowering plants and fish (3-6) supports the notion that sex chromosomes evolved from autosomes that gained sex determination genes. The key event in sex chromosome evolution is the suppression of recombination between the sex-determining regions of ancestrally homologous chromosome pairs, which limits one chromosome of the pair to one sex, producing XY (male heterogametic) or ZW (female heterogametic) systems. Evolutionary models predict that a lack of recombination allows for Y-or W-specific characteristics to accumulate, through the reduced efficacy of selection on these chromosomes (7,8), leading to the Y and W chromosomes accumulating deleterious mutations and transposable elements, and ultimately undergoing genetic degeneration, through the loss of genes or gene functions, as observed in mammals, Drosophila, birds, fishes, and snakes (9, 10). In some animals and plants, the greater number of mitotic cell divisions in spermatogenesis than oogenesis also leads to Y chromosomes having a higher mutation rate than autosomes or X chromosomes (11)(12)(13)(14) and is predicted to further contribute to greater changes of the evolving Y (or W) chromosome than the X (or Z) chromosome.To test these predictions of repetitive sequence accumulation, chromosoma...
