Ultrastructure Expansion Microscopy applied to C. elegans embryos.

Visualization of organelles using expansion microscopy has been previously applied to Caenorhadbitis elegans adult gonads or worms. However, its application to embryos has remained a challenge due to the protective eggshell barrier. Here, by combining freeze-cracking and ultrastructure expansion microscopy (U-ExM), we demonstrate a four-time isotropic expansion of C. elegans embryos. As an example structure, we chose the nuclear pore and demonstrate that we achieve sufficient resolution to distinguish them individually. Our work provides proof of principle for U-ExM in C. elegans embryos, which will be applicable for imaging a wide range of cellular structures in this model system.

Cosegregation of recombinant chromatids maintains genome-wide heterozygosity in an asexual nematode.

In asexual animals, female meiosis is modified to produce diploid oocytes. If meiosis still involves recombination, this is expected to lead to a rapid loss of heterozygosity, with adverse effects on fitness. Many asexuals, however, have a heterozygous genome, the underlying mechanisms being most often unknown. Cytological and population genomic analyses in the nematode Mesorhabditis belari revealed another case of recombining asexual being highly heterozygous genome-wide. We demonstrated that heterozygosity is maintained despite recombination because the recombinant chromatids of each chromosome pair cosegregate during the unique meiotic division. A theoretical model confirmed that this segregation bias is necessary to account for the observed pattern and likely to evolve under a wide range of conditions. Our study uncovers an unexpected type of non-Mendelian genetic inheritance involving cosegregation of recombinant chromatids.

Programmed DNA elimination in Mesorhabditis nematodes.

Some species undergo programmed DNA elimination (PDE), whereby portions of the genome are systematically destroyed in somatic cells. PDE has emerged independently in several phyla, but its function is unknown. Although the mechanisms are partially solved in ciliates, PDE remains mysterious in metazoans because the study species were not yet amenable to functional approaches. We fortuitously discovered massive PDE in the free-living nematode genus Mesorhabditis, from the same family as C. elegans. As such, these species offer many experimental advantages to start elucidating the PDE mechanisms in an animal. Here, we used cytology to describe the dynamics of chromosome fragmentation and destruction in early embryos. Elimination occurs once in development, at the third embryonic cell division in the somatic blastomeres. Chromosomes are first fragmented during S phase. Next, some of the fragments fail to align on the mitotic spindle and remain outside the re-assembled nuclei after mitosis. These fragments are gradually lost after a few cell cycles. The retained fragments form new mini chromosomes, which are properly segregated in the subsequent cell divisions. With genomic approaches, we found that Mesorhabditis mainly eliminate repeated regions and also about a hundred genes. Importantly, none of the eliminated protein-coding genes are shared between closely related Mesorhabditis species. Our results strongly suggest PDE has not been selected for regulating genes with important biological functions in Mesorhabditis but rather mainly to irreversibly remove repeated sequences in the soma. We propose that PDE may target genes, provided their elimination in the soma is invisible to selection.