Identification and characterization of SSR, SNP and InDel molecular markers from RNA-Seq data of guar (Cyamopsis tetragonoloba, L. Taub.) roots.

BACKGROUND: Guar [Cyamopsis tetragonoloba, L. Taub.] is an important industrial crop because of the commercial applications of the galactomannan gum contained in its seeds. Plant breeding programmes based on marker-assisted selection require a rich resource of molecular markers. As limited numbers of such markers are available for guar, molecular breeding programmes have not been undertaken for the genetic improvement of this important crop. Hence, the present work was done to enrich the molecular markers resource of guar by identifying high quality SSR, SNP and InDel markers from the RNA-Seq data of the roots of two guar varieties. RESULTS: We carried out RNA-Seq analysis of the roots of two guar varieties, namely, RGC-1066 and M-83. A total of 102,479 unigenes with an average length of 1016 bp were assembled from about 30 million high quality pair-end reads generated by an Illumina HiSeq 2500 platform. The assembled unigenes had 86.55% complete and 97.71% partially conserved eukaryotic genes (CEGs). The functional annotation of assembled unigenes using BLASTX against six databases showed that the guar unigenes were most similar to Glycine max. We could assign GO terms to 45,200 unigenes using the UniProt database. The screening of 102,479 unigenes with MISA and SAMtools version 1.4 softwares resulted in the identification of 25,040 high-confidence molecular markers which consisted of 18,792 SSRs, 5999 SNPs and 249 InDels. These markers tagged most of the genes involved in root development, stress tolerance and other general metabolic activities. Each of the 25,040 molecular markers was characterized, particularly with respect to its position in the unigene. For 71% of the molecular markers, we could determine the names, products and functions of the unigenes. About 80% of the markers, from a random sample of molecular markers, showed PCR amplification. CONCLUSIONS: We have identified and characterized 25,040 high confidence SSR, SNP and InDel molecular markers in guar. It is expected that these markers will be useful in molecular breeding programmes and will also be helpful in studying molecular mechanisms of root development, stress tolerance and gum synthesis in guar.

A candidate gene OsAPC6 of anaphase-promoting complex of rice identified through T-DNA insertion.

A dwarf mutant (Oryza sativa anaphase-promoting complex 6 (OsAPC6)) of rice cultivar Basmati 370 with 50% reduced plant height as compared to the wild type was isolated by Agrobacterium tumefaciens-mediated transformation using Hm(R) Ds cassette. This mutant was found to be insensitive to exogenous gibberellic acid (GA(3)) application. Homozygous mutant plants showed incomplete penetrance and variable expressivity for plant height and pleiotropic effects including gibberellic acid insensitivity, reduced seed size, panicle length, and female fertility. Single copy insertion of T-DNA and its association with OsAPC6 was confirmed by Southern hybridization, germination on hygromycin, and 3:1 segregation of HPT gene in F(2) from OsAPC6 x Basmati 370 cross. The T-DNA flanking region sequenced through thermal asymmetric interlaced polymerase chain reaction showed a single hit on chromosome 3 of japonica rice cultivar Nipponbare in the second exonic region of a gene which encodes for sixth subunit of anaphase-promoting complex/cyclosome. The candidate gene of 8.6-kb length encodes a 728-amino acid protein containing a conserved tetratricopeptide repeat (TPR) domain and has only a paralog, isopenicillin N-synthase family protein on the same chromosome without the TPR domain. There was no expression of the gene in the mutant while in Basmati 370, it was equal in both roots and shoots. The knockout mutant OsAPC6 interferes with the gibberellic acid signaling pathway leading to reduced height and cell size probably through ubiquitin-mediated proteolysis. Further functional validation of the gene through RNAi is in progress.

Cyamopsis tetragonoloba type 1 metallothionein (CtMT1) gene is upregulated under drought stress and its protein product has an additional C-X-C motif and unique metal binding pattern.

Metallothioneins (MTs) are involved in cellular homeostasis of essential metal ions and detoxification of nonessential metal ions. We report here the identification of four MT genes, CtMT1, CtMT2, CtMT3 and CtMT4, encoding CtMT1, CtMT2, CtMT3 and CtMT4 proteins, respectively, from the industrial guar crop. The primary structures of last three proteins were similar to those of respective MT proteins of other plants but the CtMT1 protein primary structure was different from the other plant MT1 proteins in having an additional C-X-C motif. The four MT genes showed tissue specific expression patterns suggesting their specific roles in different tissues. High expression of CtMT1 gene was observed in roots and nodules whereas CtMT2 and CtMT3 genes showed high expression in leaves. The expression of CtMT4 gene was high in seeds. The qRT-PCR studies revealed upregulation in expression of CtMT1 gene under drought stress. Recombinant CtMT1 protein was produced in E. coli Rosetta cells and purified by metal affinity chromatography. The purified protein showed antioxidant property and the order of its metal ion binding affinities was Cu2+ > Zn2+ > Fe2+ > Cd2+. This information about CtMT1 protein is expected to be useful in understanding its role in drought tolerance and other physiological processes of guar.

Bioavailability of iron from wheat aegilops derivatives selected for high grain iron and protein contents.

A coupled in vitro digestion/Caco-2 model was employed to assess iron bioavailability from wheat Aegilops derivatives selected for high iron and protein contents. The iron content in wheat genotypes used in this study correlated to a great extent with both protein (r = 0.80) and phytate (r = 0.68) contents. The iron bioavailability was based on Caco-2 cell ferritin formation from cooked digests of these derivatives (relative to WL711 control) and correlated positively with dialyzable iron (r = 0.63) and total iron content (r = 0.38) but not with the phytate content. The apparently decreased phytate/iron molar ratios, however, correlated negatively (r = -0.42) with the iron bioavailability, justifying the utilization of these parameters in biofortification programs. Iron bioavailability in the derivatives increased up to 1.5-fold, corresponding to a 1.5-2.2-fold increase observed in iron content over control. These data suggest that biofortification for iron proportionately leading to higher iron bioavailability will be the most feasible and cost-effective approach to combat micronutrient deficiency.