RESUMEN

In certain tetraploid species resulting from interspecific hybridization, one parent's subgenome is known to selectively undergo DNA loss. The molecular mechanisms behind this remain unclear. In our study, we compared the genomes of a standard diploid species with two allotetraploid species from the Xenopus genus, both possessing L (longer) and S (shorter) homoeologous subgenomes. We observed substantial gene losses and intergenic DNA deletions in both the S and L subgenomes of the tetraploid species. Gene losses were around 1,000 to 3,000 for L and 4,000 to 6,000 for S, with especially prominent losses in the S subgenome. Many of these losses likely occurred shortly after interspecific hybridization in both L/S subgenomes. We also deduced frequent large inversions in the S subgenome. Upon reassessing transposon dynamics using updated genome databases, we reaffirmed heightened DNA transposon activity during the hybridization, as previously reported. We next investigated whether S subgenome-biased DNA loss could be correlated with the activation of DNA transposons following hybridization. Notably, distinct patterns were observed in the dynamics of DNA transposons between the L and S subgenomes. Several DNA transposon subfamilies correlated positively with DNA deletions in the S subgenome and negatively in the L subgenome. Based on these results, we propose a model that, upon and after hybridization between two related diploid Xenopus species, the mixture of their genomes resulted in the derepression of DNA transposons, especially in the S subgenome, leading to selective DNA loss in the S subgenome.

Asunto(s)

RESUMEN

Interspecific hybridization between two closely related species sometimes resulted in a new species with allotetraploid genomes. Many clawed frog species belonging to the Xenopus genus have diverged from the allotetraploid ancestor created by the hybridization of two closely related species with the predicted L and S genomes. There are species-specific repeated sequences including transposable elements in each genome of organisms that reproduce sexually. To understand what happened on and after the hybridization of the two distinct systems consisting of repeated sequences and their corresponding piRNAs, we isolated small RNAs from ovaries and testes of three Xenopus species consisting of allotetraploid X. laevis and X. borealis and diploid X. tropicalis as controls. After a comprehensive sequencing and selection of piRNAs, comparison of their sequences showed that most piRNA sequences were different between the ovaries and testes in all three species. We compared piRNA and genome sequences and specified gene clusters for piRNA expression in each genome. The synteny and homology analyses showed many distinct piRNA clusters among the three species and even between the two L and/or S subgenomes, indicating that most clusters of the two allotetraploid species changed after hybridization. Moreover, evolutionary analysis showed that DNA transposons including Kolobok superfamily might get activated just after hybridization and then gradually inactivated. These findings suggest that some DNA transposons and their piRNAs might greatly influence allotetraploid genome evolution after hybridization.

RESUMEN

Genetic sex-determining systems in vertebrates include two basic types of heterogamety; XX (female)/XY (male) and ZZ (male)/ZW (female) types. The African clawed frog Xenopus laevis has a ZZ/ZW-type sex-determining system. In this species, we previously identified a W-specific sex (female)-determining gene dmw, and specified W and Z chromosomes, which could be morphologically indistinguishable (homomorphic). In addition to dmw, we most recently discovered two genes, named scanw and ccdc69w, and one gene, named capn5z in the W- and Z-specific regions, respectively. In this study, we revealed the detail structures of the W/Z-specific loci and genes. Sequence analysis indicated that there is almost no sequence similarity between 278kb W-specific and 83kb Z-specific sequences on chromosome 2Lq32-33, where both the transposable elements are abundant. Synteny and phylogenic analyses indicated that all the W/Z-specific genes might have emerged independently. Expression analysis demonstrated that scanw and ccdc69w or capn5z are expressed in early differentiating ZW gonads or testes, thereby suggesting possible roles in female or male development, respectively. Importantly, the sex-determining gene (SDG) dmw might have been generated after allotetraploidization, thereby indicating the construction of the new sex-determining system by dmw after species hybridization. Furthermore, by direct genotyping, we confirmed that diploid WW embryos developed into normal female frogs, which indicate that the Z-specific region is not essential for female development. Overall, these findings indicate that sex chromosome differentiation has started, although no heteromorphic sex chromosomes are evident yet, in X. laevis. Homologous recombination suppression might have promoted the accumulation of mutations and transposable elements, and enlarged the W/Z-specific regions, thereby resulting in differentiation of the W/Z chromosomes.

Asunto(s)