A Transcriptome Response of Bread Wheat ( L.) to a 5B Chromosome Substitution from Wild Emmer.

Over the years, alien chromosome substitution has attracted the attention of geneticists and breeders as a rich source of remarkable genetic diversity for improvement in narrowly adapted wheat cultivars. One of the problems encountered along this way is the coadaptation and realization of the genome of common wheat against the background of the introduced genes. Here, using RNA-Seq, we assessed a transcriptome response of hexaploid wheat L.

The genome of a Far Eastern isolate of Diaporthe caulivora, a soybean fungal pathogen.

Diaporthe caulivora is an economically important fungal pathogen and a causal agent of soybean stem canker and seed decay. Here, the genome of a Russian Far Eastern isolate of D. caulivora was sequenced, assembled, and announced.

Selective precipitation of RNA with linear polyacrylamide.

Selective precipitation of RNA is often used in molecular biology as one of the methods for separation of nucleic acids to obtain samples enriched with DNA or RNA molecules alone or for purification of RNA samples. In the present study a simple and fast approach for selective precipitation of RNA with linear polyacrylamide is proposed for the first time. The method is based on the different predispositions of the DNA and RNA molecules to bind with the polyacrylamide.

VRN1-ratio test for polyploid wheat.

The duplications of the dominantVrn-A1alleles as well as theVRN-B1gene, revealed for the first time, are new sources of polymorphism in polyploid wheat at these agronomically valuable genomic locations. Flowering time is an important trait in wheat breeding. In spring wheat, this feature is mainly determined by the variants and number of the homoeologous dominant VRN1 alleles.

Divergence of VRN-B3 alleles during the evolution of domesticated wheat.

Genetic changes accrued during the domestication of wheat have been crucial in improving the cultivation and yield of this strategic crop. Allelic variation at the VRN3 gene makes a significant contribution to the adaptability of wheat to a wide range of environmental conditions. In the present study, the origin and distribution of the Vrn-B3a and Vrn-B3b alleles during the evolution of wheat were investigated.

In Silico PCR Tools for a Fast Primer, Probe, and Advanced Searching.

The polymerase chain reaction (PCR) is fundamental to molecular biology and is the most important practical molecular technique for the research laboratory. The principle of this technique has been further used and applied in plenty of other simple or complex nucleic acid amplification technologies (NAAT). In parallel to laboratory "wet bench" experiments for nucleic acid amplification technologies, in silico or virtual (bioinformatics) approaches have been developed, among which in silico PCR analysis.

Allelic variation at the VERNALIZATION-A1, VRN-B1, VRN-B3, and PHOTOPERIOD-A1 genes in cultivars of Triticum durum Desf.

The durum wheat varieties from Ukraine, Russia, and Kazakhstan are characterized by the specific allelic composition of the VRN genes that sharply distinguish them from the Triticum durum varieties from other countries. For numerous varieties, the VRN alleles which previously were not found in tetraploid wheat were identified. The ability of wheat to adapt to a wide range of environmental conditions is mostly determined by the allelic diversity within genes regulating the vernalization requirement (VRN) and photoperiod response (PPD).

Novel alleles of the VERNALIZATION1 genes in wheat are associated with modulation of DNA curvature and flexibility in the promoter region.

Background: In wheat, the vernalization requirement is mainly controlled by the VRN genes. Different species of hexaploid and tetraploid wheat are widely used as genetic source for new mutant variants and alleles for fundamental investigations and practical breeding programs. In this study, VRN-A1 and VRN-B1 were analysed for 178 accessions representing six tetraploid wheat species (Triticum dicoccoides, T.

Discovery, evaluation and distribution of haplotypes and new alleles of the Photoperiod-A1 gene in wheat.

Photoperiod response in wheat is determined to a large extent by the homoeologous series of Photoperiod 1 (Ppd1) genes. In this study, Ppd-A1 genomic sequences from the 5' UTR and promoter region were analysed in 104 accessions of six tetraploid wheat species (Triticum dicoccoides, T. dicoccum, T.