Analysis of archaic human haplotypes suggest 5-hmC to act as epigenetic guide for meiotic point recombination

Meiotic “point recombination” refers to homologue recombination events affecting only individual SNPs. Driven mostly by gene conversion, it is common process that allows for a gradual adaptation and maturation of haplotypes during genetic evolution. In contrast to crossover recombination it is not tied to predetermined recombination sites and therefore assumed to occur largely randomly. Our analysis of archaic human haplotypes however revealed striking differences in the local point recombination rate. A linkage-study of 1.9 million SNPs defined by the sequence of denisovan hominids revealed low rates in introns and quiescent intergenic regions but high rates in splice sites, exons, 5’- and 3’-UTRs, and CpG islands. Correlations with ChIP-Seq tracks from ENCODE and other public sources identified a number of epigenetic modifications, that associated directly with these recombination events. A particularly tight association was observed for 5-hydroxymethylcytosine marks (5hmC). The mark was enriched in virtually all of the functional regions associated with elevated point recombination rates, including CpG islands and ‘poised’ bivalent regions. As intermediate of oxidative demethylation, 5hmC is also a marker of recently opened gene loci. The data, thus, supports a model of ‘guided’ evolution, in which point recombination is directed by 5hmC marks towards the functionally relevant regions.

Inter-homologue repair in fertilized human eggs?

Many human diseases have an underlying genetic component. The development and application of methods to prevent the inheritance of damaging mutations through the human germline could have significant health benefits, and currently include preimplantation genetic diagnosis and carrier screening. Ma et al. take this a step further by attempting to remove a disease mutation from the human germline through gene editing1. They assert the following advances: (i) the correction of a pathogenic gene mutation responsible for hypertrophic cardiomyopathy in human embryos using CRISPR-Cas9 and (ii) the avoidance of mosaicism in edited embryos. In the case of correction, the authors conclude that repair using the homologous chromosome was as or more frequent than mutagenic nonhomologous end-joining (NHEJ). Their conclusion is significant, if validated, because such a “self-repair” mechanism would allow gene correction without the introduction of a repair template. While the authors’ analyses relied on the failure to detect mutant alleles, here we suggest approaches to provide direct evidence for inter-homologue recombination and discuss other events consistent with the data. We also review the biological constraints on inter-homologue recombination in the early embryo.

Transposition of pGh9:ISS1 is random and efficient in Streptococcus thermophilus CNRZ368

Streptococcus thermophilus bacteria are used as a starter in the fermentation of yogurts and many cheeses. To construct mutants of S. thermophilus CNRZ368, the use of the plasmid pGh9:ISS1 was considered. This plasmid is known to be a good tool for insertional mutagenesis in gram-positive bacteria, owing to its ability to integrate in the genome by a mechanism of replicative transposition. However, the presence of three endogenous ISS1 copies in the genome of S. thermophilus CNRZ368 and the possible occurrence of homologous recombination could reduce the efficiency of pGh9:ISS1 as a tool for generating mutants. To address this question, the ability of pGh9:ISS1 to transpose randomly in the genome of strain CNRZ368 was investigated. The results of our experiments indicated that: (i) the frequency of transposition of ISS1 was high, approximately 2 × 10–2, in S. thermophilus CNRZ368; (ii) the integration of multiple tandem copies of the plasmid was frequent; (iii) homologous recombination events between ISS1 were not predominant; and (iv) plasmid pGh9:ISS1 transposed randomly around the S. thermophilus CNRZ368 chromosome. In addition, we describe the strategy used to localize the pGh9:ISS1 insertion locus on the physical map of strain CNRZ368 and the method used to clone the regions flanking this insertion site, especially when multiple copies of the plasmid were integrated in tandem.Key words: insertional mutagenesis, random transposition, Streptococcus thermophilus, homologue recombination, ISS1.