RNA-Seq Analysis of the Response of the Halophyte,Mesembryanthemum crystallinum (Ice Plant) to High Salinity

Understanding the molecular mechanisms that convey salt tolerance in plants is a crucial issue for increasing crop yield. The ice plant (Mesembryanthemum crystallinum) is a halophyte that is capable of growing under high salt conditions. For example, the roots of ice plant seedlings continue to grow in 140 mM NaCl, a salt concentration that completely inhibits Arabidopsis thaliana root growth. Identifying the molecular mechanisms responsible for this high level of salt tolerance in a halophyte has the potential of revealing tolerance mechanisms that have been evolutionarily successful. In the present study, deep sequencing (RNAseq) was used to examine gene expression in ice plant roots treated with various concentrations of NaCl. Sequencing resulted in the identification of 53,516 contigs, 10,818 of which were orthologs of Arabidopsis genes. In addition to the expression analysis, a web-based ice plant database was constructed that allows broad public access to the data. The results obtained from an analysis of the RNAseq data were confirmed by RT-qPCR. Novel patterns of gene expression in response to high salinity within 24 hours were identified in the ice plant when the RNAseq data from the ice plant was compared to gene expression data obtained from Arabidopsis plants exposed to high salt. Although ABA responsive genes and a sodium transporter protein (HKT1), are up-regulated and down-regulated respectively in both Arabidopsis and the ice plant; peroxidase genes exhibit opposite responses. The results of this study provide an important first step towards analyzing environmental tolerance mechanisms in a non-model organism and provide a useful dataset for predicting novel gene functions.     

Localization of gene expression,tissue specificity of <Emphasis Type="Italic">Populus</Emphasis> xylosyltransferase genes by isolation and functional characterization of their promoters

Efficient bioconversion of cellulose into glucose using lignocellulose as the feedstock requires improved cell wall traits. Xylan is part of the matrix covering cellulose and linkages of xylan and lignin inhibit cellulases access. Xylose, an uncommon sugar in the yeast fermentation process, represents 20% of the lignocellulose mass fraction, thus xylan related genes are important targets for biotechnology. Initially, the isolation of candidate genes and their functional characterization is a prerequisite. A common strategy is to perform exhaustive promoter characterizations for candidate genes. Here, we report on the characterization of two xylosyltransferases-related gene promoters that were isolated upstream of the respective candidate genes in poplar, a promising feedstock for bioenergy that is characterized by its short-rotation. The species is known to have undergone recent whole genome duplication, thus finding duplicated gene sequences for xylosyltransferases based on phylogeny reconstruction but with distinct expression patterns is expected. To investigate these two genes closely related to the single, well-characterised Arabidopsis thaliana (At) irx10 gene, we constructed two binary vectors, each studying the full-length promoter of the respective gene. For the poplar (Ptr) gene, most likely the functionally closest to the At irx10 gene, localization of gene expression was studied using the green fluorescence protein (GFP). Poplar’s glucuronoxylan glucuronosyltransferase protein, PtrGUT2B, expression was localized in the inflorescence, and specifically in the xylem and along the fibres, suggesting that PtrGUT2B gene expression is associated with fibre production similar to the At irx10 gene. Conversely, the second, duplicated, poplar gene termed PtrGUT2A showed expression in the cambium/phloem, vascular bundles, in the primary xylem and the central cylinder that actively undergo cell divisions and differentiation as evidenced by driving ß-glucuronidase (GUS) expression in these specific tissues. There was no staining detected in the mature secondary xylem or interfascicular fibres. Our study demonstrated that the PtrGUT2B is the true ortholog of irx10 and the two isolated promoters can be used to target tissue specific expression in plant biotechnology assays.     

LEA Gene Introns: is the Intron of Dehydrin Genes a Characteristic of the Serine-Segment?

Dehydrins, which belong to group 2 LEA proteins, are a family of intrinsically unstructured plant proteins that accumulate during the late stages of embryogenesis and in response to abiotic stresses. We have previously reported that the OpsDHN1 gene, encoding an SK₃-type acidic dehydrin protein from Opuntia streptacantha, contains an intron inserted within the sequence encoding the S-motif. Herein, we present an in silico analysis of intron sequences in dehydrin genes from mono- and dicotyledonous plants that reveals a preference for insertion within the nucleotide sequence encoding the S-motif. Sequence comparison of ten Dhn genes from Arabidopsis thaliana and the orthologous genes in Arabidopsis lyrata revealed that introns maintain considerable sequence identity and conserve the insertion pattern. Furthermore, syntenic regions were identified among eight orthologous genes of A. thaliana and A. lyrata, showing that correlated gene arrangements are conserved between these Arabidopsis species. Our study shows that most SKn-type dehydrins contain one intron that is conserved in phase and location; this intron is linked to the nucleotide sequence that encodes the S-motif.