Strategies to detect genetic diversity in plants

Next-generation sequencing can provide access to the genomic sequence of even large and complex plant genomes. Three major strategies exist to assess the genomic information of a species at different scales and complexity levels: transcriptome, target capture and whole-genome shotgun sequencing. The scope of this thesis was to evaluate each concept, ascertain its potential for the discovery of genetic diversity, and develop methods for their improvement. With these objectives, the economically important crops rye, maize and barley were investigated to reveal novel insights into their genetic diversity. The study constructed the first rye transcriptome reference that was utilized for variant discovery revealing ~18,000 single nucleotide variants (SNVs) in coding regions. Subsequently, this resource was converted into a genotyping assay (RYE5k) for application e.g. in breeding programs. The identification of genomic variants requires a high degree of accuracy. Two methods were developed to increase the accuracy in the process of variant discovery: the ‘combinatorial variant calling’ and the approach of ‘k-mer repeat investigation’. With the first method, the reliability of variant calling was increased by the interlaced support and analysis of multiple detection procedures. The approach was successfully applied to determine the diversity in biomass-related genes of maize. Hereby, the applied capture sequencing approach revealed 86,875 SNVs in coding regions. The second method was motivated by the complexity of the large and repetitive barley genome. Therefore, k-mer analyses were used to gain knowledge of repetitive features and this resulted in greater precision in variant calling. The positive effect was shown in a genome-wide diversity study of barley. As a result, more than 15 million high-quality SNVs were identified in five cultivars and a wild progenitor of cultivated barley. The study successfully revealed novel insights into the genetic diversity of barley

BARLEX – the Barley Draft Genome Explorer

Colmsee C, Beier S, Himmelbach A, et al. BARLEX – the Barley Draft Genome Explorer. Molecular Plant. 2015;8(6):964-966

From RNA-seq to large-scale genotyping - genomics resources for rye (Secale cereale L.)

<p>Abstract</p> <p>Background</p> <p>The improvement of agricultural crops with regard to yield, resistance and environmental adaptation is a perpetual challenge for both breeding and research. Exploration of the genetic potential and implementation of genome-based breeding strategies for efficient rye (<it>Secale cereale </it>L.) cultivar improvement have been hampered by the lack of genome sequence information. To overcome this limitation we sequenced the transcriptomes of five winter rye inbred lines using Roche/454 GS FLX technology.</p> <p>Results</p> <p>More than 2.5 million reads were assembled into 115,400 contigs representing a comprehensive rye expressed sequence tag (EST) resource. From sequence comparisons 5,234 single nucleotide polymorphisms (SNPs) were identified to develop the Rye5K high-throughput SNP genotyping array. Performance of the Rye5K SNP array was investigated by genotyping 59 rye inbred lines including the five lines used for sequencing, and five barley, three wheat, and two triticale accessions. A balanced distribution of allele frequencies ranging from 0.1 to 0.9 was observed. Residual heterozygosity of the rye inbred lines varied from 4.0 to 20.4% with higher average heterozygosity in the pollen compared to the seed parent pool.</p> <p>Conclusions</p> <p>The established sequence and molecular marker resources will improve and promote genetic and genomic research as well as genome-based breeding in rye.</p

A homolog of <i>blade-on-petiole</i> <i>1</i> and <i>2</i> (<i>BOP1/2</i>) controls internode length and homeotic changes of the barley inflorescence

Inflorescence architecture in small-grain cereals has a direct effect on yield and is an important selection target in breeding for yield improvement. We analyzed the recessive mutation laxatum-a (lax-a) in barley (Hordeum vulgare), which causes pleiotropic changes in spike development, resulting in (1) extended rachis internodes conferring a more relaxed inflorescence, (2) broadened base of the lemma awns, (3) thinner grains that are largely exposed due to reduced marginal growth of the palea and lemma, and (4) and homeotic conversion of lodicules into two stamenoid structures. Map-based cloning enforced by mapping-by-sequencing of the mutant lax-a locus enabled the identification of a homolog of BLADE-ON-PETIOLE1 (BOP1) and BOP2 as the causal gene. Interestingly, the recently identified barley uniculme4 gene also is a BOP1/2 homolog and has been shown to regulate tillering and leaf sheath development. While the Arabidopsis (Arabidopsis thaliana) BOP1 and BOP2 genes act redundantly, the barley genes contribute independent effects in specifying the developmental growth of vegetative and reproductive organs, respectively. Analysis of natural genetic diversity revealed strikingly different haplotype diversity for the two paralogous barley genes, likely affected by the respective genomic environments, since no indication for an active selection process was detected

Sequencing of BAC pools by different next generation sequencing platforms and strategies

<p>Abstract</p> <p>Background</p> <p>Next generation sequencing of BACs is a viable option for deciphering the sequence of even large and highly repetitive genomes. In order to optimize this strategy, we examined the influence of read length on the quality of Roche/454 sequence assemblies, to what extent Illumina/Solexa mate pairs (MPs) improve the assemblies by scaffolding and whether barcoding of BACs is dispensable.</p> <p>Results</p> <p>Sequencing four BACs with both FLX and Titanium technologies revealed similar sequencing accuracy, but showed that the longer Titanium reads produce considerably less misassemblies and gaps. The 454 assemblies of 96 barcoded BACs were improved by scaffolding 79% of the total contig length with MPs from a non-barcoded library.</p> <p>Assembly of the unmasked 454 sequences without separation by barcodes revealed chimeric contig formation to be a major problem, encompassing 47% of the total contig length. Masking the sequences reduced this fraction to 24%.</p> <p>Conclusion</p> <p>Optimal BAC pool sequencing should be based on the longest available reads, with barcoding essential for a comprehensive assessment of both repetitive and non-repetitive sequence information. When interest is restricted to non-repetitive regions and repeats are masked prior to assembly, barcoding is non-essential. In any case, the assemblies can be improved considerably by scaffolding with non-barcoded BAC pool MPs.</p

Construction of a map-based reference genome sequence for barley, Hordeum vulgare L.

Barley (Hordeum vulgare L.) is a cereal grass mainly used as animal fodder and raw material for the malting industry. The map-based reference genome sequence of barley cv. `Morex' was constructed by the International Barley Genome Sequencing Consortium (IBSC) using hierarchical shotgun sequencing. Here, we report the experimental and computational procedures to (i) sequence and assemble more than 80,000 bacterial artificial chromosome (BAC) clones along the minimum tiling path of a genome-wide physical map, (ii) find and validate overlaps between adjacent BACs, (iii) construct 4,265 non-redundant sequence scaffolds representing clusters of overlapping BACs, and (iv) order and orient these BAC clusters along the seven barley chromosomes using positional information provided by dense genetic maps, an optical map and chromosome conformation capture sequencing (Hi-C). Integrative access to these sequence and mapping resources is provided by the barley genome explorer (BARLEX).Peer reviewe