miR2118-triggered phased siRNAs are differentially expressed during the panicle development of wild and domesticated African rice species.

BACKGROUND: Rice exhibits a wide range of panicle structures. To explain these variations, much emphasis has been placed on changes in transcriptional regulation, but no large-scale study has yet reported on changes in small RNA regulation in the various rice species. To evaluate this aspect, we performed deep sequencing and expression profiling of small RNAs from two closely related species with contrasting panicle development: the cultivated African rice Oryza glaberrima and its wild relative Oryza barthii. RESULTS: Our RNA-seq analysis revealed a dramatic difference between the two species in the 21 nucleotide small RNA population, corresponding mainly to miR2118-triggered phased siRNAs. A detailed expression profiling during the panicle development of O. glaberrima and O. barthii using qRT-PCRs and in situ hybridization, confirmed a delayed expression of the phased siRNAs as well as their lncRNA precursors and regulators (miR2118 and MEL1 gene) in O. glaberrima compared to O. barthii. We provide evidence that the 21-nt phasiRNA pathway in rice is associated with male-gametogenesis but is initiated in spikelet meristems. CONCLUSION: Differential expression of the miR2118-triggered 21-nt phasiRNA pathway between the two African rice species reflects differential rates of determinate fate acquisition of panicle meristems between the two species.

Intra-individual polymorphism in chloroplasts from NGS data: where does it come from and how to handle it?

Next-generation sequencing allows access to a large quantity of genomic data. In plants, several studies used whole chloroplast genome sequences for inferring phylogeography or phylogeny. Even though the chloroplast is a haploid organelle, NGS plastome data identified a nonnegligible number of intra-individual polymorphic SNPs. Such observations could have several causes such as sequencing errors, the presence of heteroplasmy or transfer of chloroplast sequences in the nuclear and mitochondrial genomes. The occurrence of allelic diversity has practical important impacts on the identification of diversity, the analysis of the chloroplast data and beyond that, significant evolutionary questions. In this study, we show that the observed intra-individual polymorphism of chloroplast sequence data is probably the result of plastid DNA transferred into the mitochondrial and/or the nuclear genomes. We further assess nine different bioinformatics pipelines' error rates for SNP and genotypes calling using SNPs identified in Sanger sequencing. Specific pipelines are adequate to deal with this issue, optimizing both specificity and sensitivity. Our results will allow a proper use of whole chloroplast NGS sequence and will allow a better handling of NGS chloroplast sequence diversity.

Parasitism and the retrotransposon life cycle in plants: a hitchhiker's guide to the genome.

LTR (long terminal repeat) retrotransposons are the main components of higher plant genomic DNA. They have shaped their host genomes through insertional mutagenesis and by effects on genome size, gene expression and recombination. These Class I transposable elements are closely related to retroviruses such as the HIV by their structure and presumptive life cycle. However, the retrotransposon life cycle has been closely investigated in few systems. For retroviruses and retrotransposons, individual defective copies can parasitize the activity of functional ones. However, some LTR retrotransposon groups as a whole, such as large retrotransposon derivatives and terminal repeats in miniature, are non-autonomous even though their genomic insertion patterns remain polymorphic between organismal accessions. Here, we examine what is known of the retrotransposon life cycle in plants, and in that context discuss the role of parasitism and complementation between and within retrotransposon groups.

Sequencing of the Triticum monococcum hardness locus reveals good microcolinearity with rice.

The Hardness ( Ha) locus on chromosome 5D is the main determinant of grain texture in hexaploid wheat. The related genes Puroindoline-a and -b ( Pina-D1, Pinb-D1) and Grain Softness Protein ( Gsp-D1) are tightly linked at this locus. Mutations in the Pina-D1 and Pinb-D1 genes are associated with increased grain hardness. We report here the complete sequence of a 101-kb BAC clone from Triticum monococcum (A(m ) genome) which includes these three genes, and its comparison with the orthologous region in rice. The genes Gsp-A(m) 1, Pina-A(m) 1 and Pinb-A(m) 1 are separated by 37 kb and 32 kb, respectively, and are organized in the same transcriptional orientation. Four additional genes, including a pair of duplicated genes, were identified upstream of Gsp-A(m) 1 within a high-density gene island. These additional genes were found in the same order and orientation, and the same relative distances apart as similar genes previously annotated on rice chromosome 12. An interesting discovery was a small unannotated putative rice gene that was similar to the Gsp-A(m) 1 gene of T. monococcum (65% similarity at the protein level), and that was disposed in the same orientation, and located in the same position relative to the other orthologous genes. The high gene density observed in this BAC (1 gene per 14 kb) was expected for a distal chromosome region, but the level of microcolinearity with rice was higher than that reported in similar distal regions of other wheat chromosomes. Most of the BAC sequence (40%) was represented by repetitive elements, mainly concentrated in regions adjacent to the genes Pina-A(m) 1 and Pinb-A(m) 1. Rearrangements among these repetitive elements might provide an explanation for the frequent deletions observed at this locus in the genomes of the polyploid wheat species.