Patterns of evolution of sex chromosome systems in crickets: an integrated approach between cytogenetics and genomics

Sex chromosomes have arisen independently from an ordinary autosomal pair and in several lineages they present common characteristics, such as accumulation of distinct classes of repetitive DNAs, restriction of the recombination and loss or gain of genes due to the morphological and genetic differentiation between the sexual chromosomes X and Y or Z and W. These characteristics represent a fascinating example of evolutionary convergence. In Orthoptera, the X0♂/XX♀ sex-determining system is considered modal but eventually, diverse sex chromosome systems evolved several times, such as neo-XY♂/XX♀, X1X20♂/X1X1X2X2♀ and even neo- X1X2Y♂/X1X1X2X2♀. It was found that particularly centric fusions (i.e., Robertsonian translocations) and tandem fusions with autosomes, dissociations and inversions contributed to the formation of neo-sex chromosomes in Orthoptera. The present work had three objectives. First, get insights of the role of repetitive DNAs in the structure/diversification of simple and derivative sex-chromosomes by isolation and physical mapping of repetitive DNA sequences, such as multigene families, satellite DNA (satDNA) and microsatellites using Gryllus assimilis, Cycloptiloides americanus e Eneoptera surinamensis, as models. Second, looking at differential satDNA transcription between different tissues, sexes, and species from transcriptomes of Gryllus assimilis, G. bimaculatus, G. firmus and G. rubens, I tried to understand the possible functional roles of these sequences in gene regulation, chromatin modulation and as functional components of important structures such as telomeres, centromeres and sex chromosomes. Third, using transcriptomes from cricket species (Gryllus assimilis, G. bimaculatus and G. firmus), I searched for genes encoding proteins related to sexual determination, reproductive fitness and sex-biased genes which are responsible for the phenotypic differences between males and females. I also tried to elucidate in a comparative way the evolutionary factors acting at these loci. De novo origin of sex chromosomes by chromosomal rearrangements, as well as repetitive DNA accumulation that led to the differentiation between sex chromosomes are reported for C. americanus (X1X20) e E. surianmensis (neo-X1X2Y). These features observed in crickets represent another remarkable case of evolutionary convergence because unrelated sex chromosomes share many common properties among distant taxa. Especially astonishing accumulation of satDNAs loci was found in the highly differentiated neo-Y, including 39 satDNAs over-represented in this chromosome, which is the greatest satDNAs diversity yet reported for sex chromosomes. It has been documented that, particularly the satDNA, contributed greatly to the increase in genomic size between G. assimilis and E. surinamensis. An interesting finding was the identification of satDNA conserved among species of crickets (Gryllus assimilis, G. bimaculatus and G. firmus), but differentially transcribed. The data regarding satDNA presence in G. assimilis genome was discussed in an evolutionary context, with transcriptional data enabling comparisons between sexes and across tissues when possible. I discussed hypotheses for the conservation and transcription of satDNAs in Gryllus, which might result from their role in sexual differentiation at the chromatin level, heterochromatin formation, and centromeric function. Another finding was the identification of sex-determining genes and other genes related to reproductive fitness, such as biosynthesis of insect hormones and circadian rhythm among Gryllus species. The effectors as well as downstream targets of sex-determination pathways have been previously identified in other insects but never in Orthoptera. Using G. assimilis to study sex-biased genes I identified a set of highly expressed genes that might account for phenotypic differences between sexes. Furthermore, I estimated that proteinencoding reproductive genes evolve faster than non-reproductive genes as result of strong positive selection at those loci. It was documented that the species studied harbor exceptionally high levels of gene duplications. The findings suggest that gene duplications may play a role in sex-biased genes expression in the field cricket G. assimilis, a species likely to yield insights into the functional genomics and epigenetics of sex determination. (AU)