63 research outputs found
Introgression and pyramiding into common bean market class fabada of genes conferring resistance to anthracnose and potyvirus
Anthracnose and bean common mosaic (BCM) are considered major diseases in common bean crop causing severe yield losses worldwide. This work describes the introgression and pyramiding of genes conferring genetic resistance to BCM and anthracnose local races into line A25, a bean genotype classified as market class fabada. Resistant plants were selected using resistance tests or combining resistance tests and marker-assisted selection. Lines A252, A321, A493, Sanilac BC6-Are, and BRB130 were used as resistance sources. Resistance genes to anthracnose (Co-2 ( C ), Co-2 ( A252 ) and Co-3/9) and/or BCM (I and bc-3) were introgressed in line A25 through six parallel backcrossing programs, and six breeding lines showing a fabada seed phenotype were obtained after six backcross generations: line A1258 from A252; A1231 from A321; A1220 from A493; A1183 and A1878 from Sanilac BC6-Are; and line A2418 from BRB130. Pyramiding of different genes were developed using the pedigree method from a single cross between lines obtained in the introgression step: line A1699 (derived from cross A1258 Ă A1220), A2438 (A1220 Ă A1183), A2806 (A1878 Ă A2418), and A3308 (A1699 Ă A2806). A characterization based on eight morpho-agronomic traits revealed a limited differentiation among the obtained breeding lines and the recurrent line A25. However, using a set of seven molecular markers linked to the loci used in the breeding programs it was possible to differentiate the 11 fabada lines. Considering the genetic control of the resistance in resistant donor lines, the observed segregations in the last backcrossing generation, the reaction against the pathogens, and the expression of the molecular markers it was also possible to infer the genotype conferring resistance in the ten fabada breeding lines obtained. As a result of these breeding programs, genetic resistance to three anthracnose races controlled by genes included in clusters Co-2 and Co-3/9, and genetic resistance to BCM controlled by genotype I + bc-3 was combined in the fabada line A3308
BAC library resources for map-based cloning and physical map construction in barley (Hordeum vulgare L.)
Background: Although second generation sequencing (2GS) technologies allow re-sequencing of previously gold-standard-sequenced genomes, whole genome shotgun sequencing and de novo assembly of large and complex eukaryotic genomes is still difficult. Availability of a genome-wide physical map is therefore still a prerequisite for whole genome sequencing for genomes like barley. To start such an endeavor, large insert genomic libraries, i.e. Bacterial Artificial Chromosome (BAC) libraries, which are unbiased and representing deep haploid genome coverage, need to be ready in place. Result: Five new BAC libraries were constructed for barley (Hordeum vulgare L.) cultivar Morex. These libraries were constructed in different cloning sites (HindIII, EcoRI, MboI and BstXI) of the respective vectors. In order to enhance unbiased genome representation and to minimize the number of gaps between BAC contigs, which are often due to uneven distribution of restriction sites, a mechanically sheared library was also generated. The new BAC libraries were fully characterized in depth by scrutinizing the major quality parameters such as average insert size, degree of contamination (plate wide, neighboring, and chloroplast), empty wells and off-scale clones (clones with 250 fragments). Additionally a set of gene-based probes were hybridized to high density BAC filters and showed that genome coverage of each library is between 2.4 and 6.6 X. Conclusion: BAC libraries representing >20 haploid genomes are available as a new resource to the barley research community. Systematic utilization of these libraries in high-throughput BAC fingerprinting should allow developing a genome-wide physical map for the barley genome, which will be instrumental for map-based gene isolation and genome sequencing.Daniela Schulte, Ruvini Ariyadasa, Bujun Shi, Delphine Fleury, Chris Saski, Michael Atkins, Pieter deJong, Cheng-Cang Wu, Andreas Graner, Peter Langridge and Nils Stei
Mining and validating grape (Vitis L.) ESTs to develop EST-SSR markers for genotyping and mapping
Grape expressed sequence tags (ESTs) are a new resource for developing simple sequence repeat (SSR) functional markers for genotyping and genetic mapping. An integrated pipeline including several computational tools for SSR identification and functional annotation was developed to identify 6,447 EST-SSR sequences from a total collection of 215,609 grape ESTs retrieved from NCBI. The 6,447 EST-SSRs were further reduced to 1,701 non-redundant sequences via clustering analysis, and 1,037 of them were successfully designed with primer pairs flanking the SSR motifs. From them, 150 pairs of primers were randomly selected for PCR amplification, polymorphism and heterozygosity analysis in V. vinifera cvs. Riesling and Cabernet Sauvignon, and V. rotundifolia (muscadine grape) cvs. Summit and Noble, and 145 pairs of these primers yielded PCR products. Pairwise comparisons of loci between the parents Riesling and Cabernet Sauvignon showed that 72 were homozygous in both cultivars, while 70 loci were heterozygous in at least one cultivar of the two. Muscadine parents Noble and Summit had 90 homozygous SSR loci in both parents and contained 50 heterozygous loci in at least one of the two. These EST-SSR functional markers are a useful addition for grape genotyping and genome mapping
Extension of the core map of common bean with EST-SSR, RGA, AFLP, and putative functional markers
Microsatellites and gene-derived markers are still underrepresented in the core molecular linkage map of common bean compared to other types of markers. In order to increase the density of the core map, a set of new markers were developed and mapped onto the RIL population derived from the âBAT93â Ă âJalo EEP558â cross. The EST-SSR markers were first characterized using a set of 24 bean inbred lines. On average, the polymorphism information content was 0.40 and the mean number of alleles per locus was 2.7. In addition, AFLP and RGA markers based on the NBS-profiling method were developed and a subset of the mapped RGA was sequenced. With the integration of 282 new markers into the common bean core map, we were able to place markers with putative known function in some existing gaps including regions with QTL for resistance to anthracnose and rust. The distribution of the markers over 11 linkage groups is discussed and a newer version of the common bean core linkage map is proposed
Analysis of high-identity segmental duplications in the grapevine genome
<p>Abstract</p> <p>Background</p> <p>Segmental duplications (SDs) are blocks of genomic sequence of 1-200 kb that map to different loci in a genome and share a sequence identity > 90%. SDs show at the sequence level the same characteristics as other regions of the human genome: they contain both high-copy repeats and gene sequences. SDs play an important role in genome plasticity by creating new genes and modeling genome structure. Although data is plentiful for mammals, not much was known about the representation of SDs in plant genomes. In this regard, we performed a genome-wide analysis of high-identity SDs on the sequenced grapevine (<it>Vitis vinifera</it>) genome (PN40024).</p> <p>Results</p> <p>We demonstrate that recent SDs (> 94% identity and >= 10 kb in size) are a relevant component of the grapevine genome (85 Mb, 17% of the genome sequence). We detected mitochondrial and plastid DNA and genes (10% of gene annotation) in segmentally duplicated regions of the nuclear genome. In particular, the nine highest copy number genes have a copy in either or both organelle genomes. Further we showed that several duplicated genes take part in the biosynthesis of compounds involved in plant response to environmental stress.</p> <p>Conclusions</p> <p>These data show the great influence of SDs and organelle DNA transfers in modeling the <it>Vitis vinifera </it>nuclear DNA structure as well as the impact of SDs in contributing to the adaptive capacity of grapevine and the nutritional content of grape products through genome variation. This study represents a step forward in the full characterization of duplicated genes important for grapevine cultural needs and human health.</p
Next Generation Mapping of Enological Traits in an F2 Interspecific Grapevine Hybrid Family
In winegrapes (Vitis spp.), fruit quality traits such as berry color, total soluble solids content (SS), malic acid content (MA), and yeast assimilable nitrogen (YAN) affect fermentation or wine quality, and are important traits in selecting new hybrid winegrape cultivars. Given the high genetic diversity and heterozygosity of Vitis species and their tendency to exhibit inbreeding depression, linkage map construction and quantitative trait locus (QTL) mapping has relied on F1 families with the use of simple sequence repeat (SSR) and other markers. This study presents the construction of a genetic map by single nucleotide polymorphisms identified through genotyping-by-sequencing (GBS) technology in an F2 mapping family of 424 progeny derived from a cross between the wild species V. riparia Michx. and the interspecific hybrid winegrape cultivar, âSeyvalâ. The resulting map has 1449 markers spanning 2424 cM in genetic length across 19 linkage groups, covering 95% of the genome with an average distance between markers of 1.67 cM. Compared to an SSR map previously developed for this F2 family, these results represent an improved map covering a greater portion of the genome with higher marker density. The accuracy of the map was validated using the well-studied trait berry color. QTL affecting YAN, MA and SS related traits were detected. A joint MA and SS QTL spans a region with candidate genes involved in the malate metabolism pathway. We present an analytical pipeline for calling intercross GBS markers and a high-density linkage map for a large F2 family of the highly heterozygous Vitis genus. This study serves as a model for further genetic investigations of the molecular basis of additional unique characters of North American hybrid wine cultivars and to enhance the breeding process by marker-assisted selection. The GBS protocols for identifying intercross markers developed in this study can be adapted for other heterozygous species
Linkage maps of grapevine displaying the chromosomal locations of 420 microsatellite markers and 82 markers for R-gene candidates
Abstract Genetic maps functionally oriented towards
disease resistance have been constructed in grapevine
by analysing with a simultaneous maximum-likelihood
estimation of linkage 502 markers including microsatellites
and resistance gene analogs (RGAs). Mapping material consisted of two pseudo-testcrosses, \u2018Chardonnay\u2019 x \u2018Bianca\u2019 and \u2018Cabernet Sauvignon\u2019 x
\u201820/3\u2019 where the seed parents were Vitis vinifera genotypes
and the male parents were Vitis hybrids carrying
resistance to mildew diseases. Individual maps
included 320\u2013364 markers each. The simultaneous use
of two mapping crosses made with two pairs of distantly
related parents allowed mapping as much as
91% of the markers tested. The integrated map
included 420 Simple Sequence Repeat (SSR) markers
that identiWed 536 SSR loci and 82 RGA markers that
identiWed 173 RGA loci. This map consisted of 19
linkage groups (LGs) corresponding to the grape
haploid chromosome number, had a total length of
1,676 cM and a mean distance between adjacent loci
of 3.6 cM. Single-locus SSR markers were randomly
distributed over the map (CD = 1.12). RGA markers
were found in 18 of the 19 LGs but most of them
(83%) were clustered on seven LGs, namely groups 3,
7, 9, 12, 13, 18 and 19. Several RGA clusters mapped
to chromosomal regions where phenotypic traits of
resistance to fungal diseases such as downy mildew
and powdery mildew, bacterial diseases such as
Pierce\u2019s disease, and pests such as dagger and rootknot
nematode, were previously mapped in different
segregating populations. The high number of RGA
markers integrated into this new map will help find
markers linked to genetic determinants of different
pest and disease resistances in grape
Neutral invertases in grapevine and comparative analysis with Arabidopsis, poplar and rice
none7Neutral invertases (NIs, EC 3.2.1.26) cleave sucrose to glucose and fructose. They are encoded by a small gene family of 9 members in the Arabidopsis genome, 8 in rice, 16 in poplar and 9 in Vitis vinifera (L.). The grapevine NIs were identified in the 8.4X genome assembly of the quasi-homozygous line PN40024. In addition, alleles of three NIs were sequenced in the heterozygous cultivar 'Cabernet Sauvignon'. Analyses of sequence variation between alleles, homoeologous and paralogous copies in grapevine and their orthologues in Arabidopsis, poplar and rice are provided. In grapevine, NIs were classified into four alpha NIs and five beta NIs and subsequently grouped into hierarchical clades using a combination of evidence including amino acid identity, exon/intron structure, rate of synonymous substitutions (K(s)) and chromosomal distribution. Estimation of K(s) proved the ancient origin of all NIs and the lack of expansion by gene duplication past the event of polyploidisation. We then focused on transcription analysis of five NIs for which evidence of expression was available from expressed sequence tag databases. Among these, four NIs consisted of pairs of homoeologous copies, each pair lying on a pair of chromosomes duplicated by polyploidy. Unequal expression of homoeologous genes was observed by quantitative RT-PCR in leaf, flower, seed and root tissues. Since NIs might play significant roles in fruit and wine quality, NIs expression was monitored in flesh and skin of 'Merlot' berries and shown in parallel with the suite of changes that accompany fruit ripening, including glucose and fructose accumulation.noneNONIS A.; RUPERTI B; PIERASCO A; CANAGUIER A; ADAM-BLONDON A.-F; DI GASPERO G; VIZZOTTO GNonis, Alberto; Ruperti, Benedetto; Pierasco, A; Canaguier, A; ADAM BLONDON A., F; DI GASPERO, G; Vizzotto, G
- âŠ