Evolution and function of the extended miR-2 microRNA family

MicroRNAs are essential post-transcriptional regulators. Many animal microRNAs are clustered in the genome, and it has been shown that clustered microRNAs may be transcribed as a single transcript. Polycistronic microRNAs are often members of the same family, suggesting a role of tandem duplication in the emergence of clusters. The mir-2 microRNA family is the largest in Drosophila melanogaster, with 8 members that are mostly clustered in the genome. Previous studies suggest that the copy number and genomic distribution of mir-2 family members has been subject to significant change during evolution. The effects of such changes on their function are still unknown. Here we study the evolution of function in the mir-2 family. Our analyses show that, in spite of the change in number and organization among invertebrates, most mir-2 loci produce very similar mature microRNA products. Multiple mature miR-2 sequences are predicted to target genes involved in neural development in Drosophila. These targeting properties are conserved in the distant species Caenorhabditis elegans. Duplication followed by functional diversification is frequent during protein-coding gene evolution. However, our results suggest that the production of microRNA clusters by gene duplication rarely involves functional changes. This pattern of functional redundancy among clustered paralogous microRNAs reflects birth-and-death evolutionary dynamics. However, we identified a small number of mir-2 sequences in Drosophila that may have undergone functional shifts associated with genomic rearrangements. Therefore, redundancy in microRNA families may facilitate the acquisition of novel functional features

Dysbiosis and Its Discontents

International audienceDysbiosis is a key term in human microbiome research, especially when microbiome patterns are associated with disease states. Although some questions have been raised about how this term is applied, its use continues undiminished in the literature. We investigate the ways in which microbiome researchers discuss dysbiosis and then assess the impact of different concepts of dysbiosis on microbiome research. After an overview of the term's historical roots, we conduct quantitative and qualitative analyses of a large selection of contemporary dysbiosis statements. We categorize both short definitions and longer conceptual statements about dysbiosis. Further analysis allows us to identify the problematic implications of how dysbiosis is used, particularly with regard to causal hypotheses and normal-abnormal distinctions. We suggest that researchers should reflect carefully on the ways in which they discuss dysbiosis, in order for the field to continue to develop greater predictive scope and explanatory depth

Contrasting Strategies: Human Eukaryotic versus Bacterial Microbiome Research

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Intron evolution in Saccharomycetaceae.

International audienceIntrons in protein-coding genes are very rare in hemiascomycetous yeast genomes. It has been suggested that these species have experienced extensive intron loss during their evolution from the postulated intron-rich fungal ancestor. However, no intron-devoidy east species have been identified and some of the introns remaining within the genomes of intron-poor species, such as Saccharomyces cerevisiae, appear to be beneficial during growth under stress conditions. In order to reveal the pattern of intron retention within intron-poor yeast species and better understand the mechanisms of intron evolution, we generated a comprehensive set of 250 orthologous introns in the 20 species that comprise the Saccharomycetaceae, by analyzing RNA deep-sequencing data and alignments of intron-containing genes. Analysis of these intron sets shows that intron loss is at least two orders of magnitude more frequent than intron gain. Fine mapping of intron positions shows that intron sliding is rare, and that introns are almost always removed without changing the primary sequence of the encoded protein. The latter finding is consistent with the prevailing view that homologous recombination between reverse-transcribed mature mRNAs and the corresponding genomic locus is the primary mechanism of intron loss. However, we also find evidence that loss of a small number of introns is mediated by micro-homology, and that the number of intron losses is diminished in yeast species that have lost the microhomology end joining and nonhomologous end joining machinery

Causal clarity and deeper dimensions in microbiota-gut-brain research

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Conserved RNA structures in the non-canonical Hac1/Xbp1 intron

The unconventional splicing of Hac1 by the ribonuclease Ire1 is a key event in the activation of the unfolded protein response (UPR) in Saccharomyces cerevisiae. This splicing is independent of the spliceosome and is mediated by a secondary structure at the intron-exon boundaries of the mRNA. Similar unconventional splicing was also described for the gene Xbp1 in human, mouse, Caenorhabditis elegans and Drosophila melanogaster, and for Hac1 in five other fungi. We used reported RNA structures to build a multiple sequence alignment and the Infernal package to search for homologous structures. We identified homologous non-canonical intron structures in 128 out of 156 searched eukaryotic genomes. Our results show that the sequence of the Hac1/Xbp1 intron is highly conserved only around the splice sites recognized by Ire1. The consensus structure of the Hac1/Xbp1 mRNA is well conserved in Fungi and Metazoa and resembles structures previously described. We show that a typical Hac1/Xbp1 intron is very short, only 20–26 bases, whereas yeast species have a long intron (>100 bases). We identified six species with unambiguous Hac1/Xbp1 homologs that have lost the non-canonical intron structure. We propose that these species use a different mechanism to regulate the UPR

Novel Intronic RNA Structures Contribute to Maintenance of Phenotype in Saccharomyces cerevisiae

The Saccharomyces cerevisiae genome has undergone extensive intron loss during its evolutionary history. It has been suggested that the few remaining introns (in only 5% of protein-coding genes) are retained because of their impact on function under stress conditions. Here, we explore the possibility that novel noncoding RNA structures (ncRNAs) are embedded within intronic sequences and are contributing to phenotype and intron retention in yeast. We employed de novo RNA structure prediction tools to screen intronic sequences in S. cerevisiae and 36 other fungi. We identified and validated 19 new intronic RNAs via RNA sequencing (RNA-seq) and RT-PCR. Contrary to the common belief that excised introns are rapidly degraded, we found that, in six cases, the excised introns were maintained intact in the cells. In another two cases we showed that the ncRNAs were further processed from their introns. RNA-seq analysis confirmed that introns in ribosomal protein genes are more highly expressed when they contain predicted RNA structures. We deleted the novel intronic RNA structure within the GLC7 intron and showed that this region, rather than the intron itself, is responsible for the cell’s ability to respond to salt stress. We also showed a direct association between the in cis presence of the intronic RNA and GLC7 expression. Overall, these data support the notion that some introns may have been maintained in the genome because they harbor functional RNA structures