Genetic marker anchoring by six-dimensional pools for development of a soybean physical map

<p>Abstract</p> <p>Background</p> <p>Integrated genetic and physical maps are extremely valuable for genomic studies and as important references for assembling whole genome shotgun sequences. Screening of a BAC library using molecular markers is an indispensable procedure for integration of both physical and genetic maps of a genome. Molecular markers provide anchor points for integration of genetic and physical maps and also validate BAC contigs assembled based solely on BAC fingerprints. We employed a six-dimensional BAC pooling strategy and an <it>in silico </it>approach to anchor molecular markers onto the soybean physical map.</p> <p>Results</p> <p>A total of 1,470 markers (580 SSRs and 890 STSs) were anchored by PCR on a subset of a Williams 82 <it>Bst</it>Y I BAC library pooled into 208 pools in six dimensions. This resulted in 7,463 clones (~1× genome equivalent) associated with 1470 markers, of which the majority of clones (6,157, 82.5%) were anchored by one marker and 1106 (17.5%) individual clones contained two or more markers. This contributed to 1184 contigs having anchor points through this 6-D pool screening effort. In parallel, the 21,700 soybean Unigene set from NCBI was used to perform <it>in silico </it>mapping on 80,700 Williams 82 BAC end sequences (BES). This <it>in silico </it>analysis yielded 9,835 positive results anchored by 4152 unigenes that contributed to 1305 contigs and 1624 singletons. Among the 1305 contigs, 305 have not been previously anchored by PCR. Therefore, 1489 (78.8%) of 1893 contigs are anchored with molecular markers. These results are being integrated with BAC fingerprints to assemble the BAC contigs. Ultimately, these efforts will lead to an integrated physical and genetic map resource.</p> <p>Conclusion</p> <p>We demonstrated that the six-dimensional soybean BAC pools can be efficiently used to anchor markers to soybean BACs despite the complexity of the soybean genome. In addition to anchoring markers, the 6-D pooling method was also effective for targeting BAC clones for investigating gene families and duplicated regions in the genome, as well as for extending physical map contigs.</p

Molecular genetics of chicken egg quality

Faultless quality in eggs is important in all production steps, from chicken to packaging, transportation, storage, and finally to the consumer. The egg industry (specifically transportation and packing) is interested in robustness, the consumer in safety and taste, and the chicken itself in the reproductive performance of the egg. High quality is commercially profitable, and egg quality is currently one of the key traits in breeding goals. In conventional breeding schemes, the more traits that are included in a selection index, the slower the rate of genetic progress for all the traits will be. The unveiling of the genes underlying the traits, and subsequent utilization of this genomic information in practical breeding, would enhance the selection progress, especially with traits of low inheritance, genderconfined traits, or traits which are difficult to assess. In this study, two experimental mapping populations were used to identify quantitative trait loci (QTL) of egg quality traits. A whole genome scan was conducted in both populations with different sets of microsatellite markers. Phenotypic observations of albumen quality, internal inclusions, egg taint, egg shell quality traits, and production traits during the entire production period were collected. To study the presence of QTL, a multiple marker linear regression was used. Polymorphisms found in candidate genes were used as SNP (single nucleotide polymorphism) markers to refine the map position of QTL by linkage and association. Furthermore, independent commercial egg layer lines were utilized to confirm some of the associations. Albumen quality, the incidence of internal inclusions, and egg taint were first mapped with the whole genome scan and fine-mapped with subsequent analyses. In albumen quality, two distinct QTL areas were found on chromosome 2. Vimentin, a gene maintaining the mechanical integrity of the cells, was studied as a candidate gene. Neither sequencing nor subsequent analysis using SNP within the gene in the QTL analysis suggested that variation in this gene could explain the effect on albumen thinning. The same mapping approach was used to study the incidence of internal inclusions, specifically, blood and meat spots. Linkage analysis revealed one genome-wide significant region on chromosome Z. Fine-mapping exposed that the QTL overlapped with a tight junction protein gene ZO-2, and a microsatellite marker inside the gene. Sequencing of a fragment of the gene revealed several SNPs. Two novel SNPs were found to be located in a miRNA (gga-mir-1556) within the ZO-2. MicroRNA-SNP and an exonic synonymous SNP were genotyped in the populations and showed significant association to blood and meat spots. A good congruence between the experimental population and commercial breeds was achieved both in QTL locations and in association results. As a conclusion, ZO-2 and gga-mir-1556 remained candidates for having a role in susceptibility to blood and meat spot defects across populations. This is the first report of QTL affecting blood and meat spot frequency in chicken eggs, albeit the effect explained only 2 % of the phenotypic variance. Fishy taint is a disorder, which is a characteristic of brown layer lines. Marker-trait association analyses of pooled samples indicated that egg-taint and the FMO3 gene map to chicken chromosome 8 and that the variation found by sequencing in the chicken FMO3 gene was associated with the TMA content of the egg. The missense mutation in the FMO3 changes an evolutionary, highly conserved amino acid within the FMO-characteristic motif (FATGY). In conclusion, several QTL regions affecting egg quality traits were successfully detected. Some of the QTL findings, such as albumen quality, remained at the level of wide chromosomal regions. For some QTL, a putative causative gene was indicated: miRNA gga-mir-1556 and/or its host gene ZO-2 might have a role in susceptibility to blood and meat spot defects across populations. Nonetheless, fishy taint in chicken eggs was found to be caused with a substitution within a conserved motif of the FMO3 gene. This variation has been used in a breeding program to eliminate fishy-taint defects from commercial egg layer lines. Objective The objective of this thesis was to map loci affecting economically important egg quality traits in chickens and to increase knowledge of the molecular genetics of these complex traits. The aim was to find markers linked to the egg quality traits, and finally unravel the variation in the genes underlying the phenotypic variation of internal egg quality. QTL mapping methodology was used to identify chromosomal regions affecting various production and egg quality traits (I, III, IV). Three internal egg quality traits were selected for fine-mapping (II, III, IV). Some of the results were verified in independent mapping populations and present-day commercial lines (III, IV). The ultimate objective was to find markers to be applied in commercial selection programs

Genome Resources for Climate‐Resilient Cowpea, an Essential Crop for Food Security

Cowpea (Vigna unguiculata L. Walp.) is a legume crop that is resilient to hot and drought‐prone climates, and a primary source of protein in sub‐Saharan Africa and other parts of the developing world. However, genome resources for cowpea have lagged behind most other major crops. Here we describe foundational genome resources and their application to the analysis of germplasm currently in use in West African breeding programs. Resources developed from the African cultivar IT97K‐499‐35 include a whole‐genome shotgun (WGS) assembly, a bacterial artificial chromosome (BAC) physical map, and assembled sequences from 4355 BACs. These resources and WGS sequences of an additional 36 diverse cowpea accessions supported the development of a genotyping assay for 51 128 SNPs, which was then applied to five bi‐parental RIL populations to produce a consensus genetic map containing 37 372 SNPs. This genetic map enabled the anchoring of 100 Mb of WGS and 420 Mb of BAC sequences, an exploration of genetic diversity along each linkage group, and clarification of macrosynteny between cowpea and common bean. The SNP assay enabled a diversity analysis of materials from West African breeding programs. Two major subpopulations exist within those materials, one of which has significant parentage from South and East Africa and more diversity. There are genomic regions of high differentiation between subpopulations, one of which coincides with a cluster of nodulin genes. The new resources and knowledge help to define goals and accelerate the breeding of improved varieties to address food security issues related to limited‐input small‐holder farming and climate stress

Whole Genome Profiling provides a robust framework for physical mapping and sequencing in the highly complex and repetitive wheat genome

<p>Abstract</p> <p>Background</p> <p>Sequencing projects using a clone-by-clone approach require the availability of a robust physical map. The SNaPshot technology, based on pair-wise comparisons of restriction fragments sizes, has been used recently to build the first physical map of a wheat chromosome and to complete the maize physical map. However, restriction fragments sizes shared randomly between two non-overlapping BACs often lead to chimerical contigs and mis-assembled BACs in such large and repetitive genomes. Whole Genome Profiling (WGP™) was developed recently as a new sequence-based physical mapping technology and has the potential to limit this problem.</p> <p>Results</p> <p>A subset of the wheat 3B chromosome BAC library covering 230 Mb was used to establish a WGP physical map and to compare it to a map obtained with the SNaPshot technology. We first adapted the WGP-based assembly methodology to cope with the complexity of the wheat genome. Then, the results showed that the WGP map covers the same length than the SNaPshot map but with 30% less contigs and, more importantly with 3.5 times less mis-assembled BACs. Finally, we evaluated the benefit of integrating WGP tags in different sequence assemblies obtained after Roche/454 sequencing of BAC pools. We showed that while WGP tag integration improves assemblies performed with unpaired reads and with paired-end reads at low coverage, it does not significantly improve sequence assemblies performed at high coverage (25x) with paired-end reads.</p> <p>Conclusions</p> <p>Our results demonstrate that, with a suitable assembly methodology, WGP builds more robust physical maps than the SNaPshot technology in wheat and that WGP can be adapted to any genome. Moreover, WGP tag integration in sequence assemblies improves low quality assembly. However, to achieve a high quality draft sequence assembly, a sequencing depth of 25x paired-end reads is required, at which point WGP tag integration does not provide additional scaffolding value. Finally, we suggest that WGP tags can support the efficient sequencing of BAC pools by enabling reliable assignment of sequence scaffolds to their BAC of origin, a feature that is of great interest when using BAC pooling strategies to reduce the cost of sequencing large genomes.</p

Generation and application of genomic tools as important prerequisites for sugar beet genome analyses.

Genetic and physical maps of a genome are essential tools for structural, functional and applied genomics. Genetic maps allow the detection of quantitative trait loci (QTLs), the characterisation of QTL effects and facilitate marker-assisted selection (MAS). The characterisation of genome structure and analysis of evolution is augmented by physical maps. Whole genome physical maps or ultimately complete genomic sequences, respectively, of a species display frameworks that provide essential information for understanding processes in respect to physiology, morphology, development and genetics. However, comprehensive annotation underpins the values a genome sequence or physical map represents. An important task of genome annotation is the linkage of genetic traits to the genome sequence, which is facilitated by integrated genetic and physical maps. In the context of this study several sugar beet (Beta vulgaris L.) genomic tools were developed and applied for evolutionary studies and linkage analysis. A new technique allowing high-throughput identification and genotyping of genetic markers was developed, utilising representational oligonucleotide microarray analysis (ROMA). We tested the performance of the method in sugar beet as a model for crop plants with little sequence information available. Genomic representations of both parents of a mapping population were hybridised on microarrays containing custom oligonucleotides based on sugar beet bacterial artificial chromosome (BAC) end sequences (BESs) and expressed sequence tags (ESTs). Subsequent analysis identified potential polymorphic oligonucleotides, which were placed on new microarrays used for screening of 184 F2 individuals. Exploiting known co-dominant anchor markers, we obtained 511 new dominant markers distributed over all nine sugar beet linkage groups and calculated genetic maps. Besides the method´s transferability to other species, the obtained genetic markers will be an asset for ordering of sequence contigs in the context of the ongoing sugar beet genome sequencing project. In addition, possible linkage of physical and genetic maps was provided, since genetic markers were based on source sequences, which were also used for construction of a BAC based physical map utilising a hybridisation approach. An example of the hybridisation based approach for physical map construction and its application for synteny studies was demonstrated. Since little is known about synteny between rosids and Caryophyllales so far, we analysed the extent of synteny between the genomic sequences of two BAC clones derived from two different Beta vulgaris haplotypes and rosid genomes. For selection of the two BAC clones we hybridised 30 oligonucleotide probes based on ESTs corresponding to Arabidopsis orthologs on chromosomes 1 and 4 that were presumably co-localised in the reconstructed Arabidopsis pseudo ancestral genome (Blanc et al. 2003) on sugar beet BAC macroarrays comprising two different sugar beet libraries. A total of 27,648 clones were screened per sugar beet library, corresponding to 4.4-fold and 5.5-fold, respectively, sugar beet genome coverage. We obtained four and five positive clones for the probes on average. Two clones, one from each haplotype that were positive with the same five EST probes, were selected and their genomic sequences were determined, annotated and exploited for synteny studies. Furthermore, I constructed and characterised a sugar beet fosmid library from the doubled haploid accession KWS2320 encompassing 115,200 independent clones. The insert size of the fosmid library was determined by pulsed field gel electrophoresis to be 39 kbp on average, thus representing 5.9-fold coverage of the sugar beet genome. Fosmids bear the advantage of narrowly defined size of the clone inserts, thus fosmid end sequences will essentially contribute to the future assembly and ordering of sequence contigs. Since repeats are a major obstacle for successful assembly of plant genome sequences, frequently causing gaps and misassembled contigs, I generated a genomic short-insert library. The short-insert library facilitated repeat identification within the sugar beet genome, which was exemplarily shown for three miniature inverted-repeat transposable element (MITE) families. Altogether this work contributed substantially to a deeper understanding of the genome structure of sugar beet and provided the basis for successful sequencing of the sugar beet genome

Marine Biotechnology: A New Vision and Strategy for Europe

Marine Board-ESF The Marine Board provides a pan-European platform for its member organisations to develop common priorities, to advance marine research, and to bridge the gap between science and policy in order to meet future marine science challenges and opportunities. The Marine Board was established in 1995 to facilitate enhanced cooperation between European marine science organisations (both research institutes and research funding agencies) towards the development of a common vision on the research priorities and strategies for marine science in Europe. In 2010, the Marine Board represents 30 Member Organisations from 19 countries. The Marine Board provides the essential components for transferring knowledge for leadership in marine research in Europe. Adopting a strategic role, the Marine Board serves its Member Organisations by providing a forum within which marine research policy advice to national agencies and to the European Commission is developed, with the objective of promoting the establishment of the European Marine Research Area

Insights into isogenic clonal fish line development using high-throughput sequencing technologies

Isogenic clonal fish lines are a powerful resource for aquaculture-related research. Fully inbred individuals, clone founders, can be produced either through mitotic gynogenesis or androgenesis and a further generation from those propagates fully inbred clonal lines. Despite rapid generation, as opposed to successive generation of sibling mating as in mice, the production of such lines may be hampered due to (i) potential residual contribution from irradiated gametes associated with poorly optimised protocols, (ii) reduced survival of clone founders and (iii) spontaneous arisal of meiotic gynogenetics with varying degree of heterozygosity, contaminating fully homozygous progenies. This research set out to address challenges and gain insights into isogenic clonal fish lines development by using double-digest RADseq (ddRADseq) to generate large numbers of genetic markers covering the genome of interest. Analysis of potential contribution from irradiated sperm indicated successful uniparental inheritance in meiotic and mitotic gynogenetics European seabass. Exclusive transmission of maternal alleles was detected in G1 progeny of Atlantic salmon (with a duplicated genome), while G2 progenies presented varying levels of sire contribution suggesting sub-optimal UV irradiation which was undetected previously with 27 microsatellite markers. Identification of telomeric markers in European seabass, with higher recombination frequencies for efficient differentiation of meiotic and mitotic gynogenetics was successful, and a genetic linkage map was generated from this data. One clear case of a spontaneous meiotic gynogenetic fish was detected among 18 putative DH fish in European seabass, despite earlier screening for isogenicity using 11 microsatellite markers. An unidentified larval DNA restriction digestion inhibition mechanism observed in Nile tilapia prevented the construction of SNP-based genetic linkage map. In summary, this study provides strong evidence on efficacy of NGS technologies for the development and verification of isogenic clonal fish lines. Reliable establishment of isogenic clonal fish lines is critical for their utility as a research tool

Genomic selection in aquaculture: application, limitations and opportunities with special reference to marine shrimp and pearl oysters

Within aquaculture industries, selection based on genomic information (genomic selection) has the profound potential to change genetic improvement programs and production systems. Genomic selection exploits the use of realized genomic relationships among individuals and information from genome-wide markers in close linkage disequilibrium with genes of biological and economic importance. We discuss the technical advances, practical requirements, and commercial applications that have made genomic selection feasible in a range of aquaculture industries, with a particular focus on molluscs (pearl oysters, Pinctada maxima) and marine shrimp (Litopenaeus vannamei and Penaeus monodon). The use of low-cost genome sequencing has enabled cost-effective genotyping on a large scale and is of particular value for species without a reference genome or access to commercial genotyping arrays. We highlight the pitfalls and offer the solutions to the genotyping by sequencing approach and the building of appropriate genetic resources to undertake genomic selection from first-hand experience. We describe the potential to capture large-scale commercial phenotypes based on image analysis and artificial intelligence through machine learning, as inputs for calculation of genomic breeding values. The application of genomic selection over traditional aquatic breeding programs offers significant advantages through being able to accurately predict complex polygenic traits including disease resistance; increasing rates of genetic gain; minimizing inbreeding; and negating potential limiting effects of genotype by environment interactions. Further practical advantages of genomic selection through the use of large-scale communal mating and rearing systems are highlighted, as well as presenting rate-limiting steps that impact on attaining maximum benefits from adopting genomic selection. Genomic selection is now at the tipping point where commercial applications can be readily adopted and offer significant short- and long-term solutions to sustainable and profitable aquaculture industries

CHARACTERIZATION OF A LARGE VERTEBRATE GENOME AND HOMOMORPHIC SEX CHROMOSOMES IN THE AXOLOTL, \u3cem\u3eAMBYSTOMA MEXICANUM\u3c/em\u3e

Changes in the structure, content and morphology of chromosomes accumulate over evolutionary time and contribute to cell, developmental and organismal biology. The axolotl (Ambystoma mexicanum) is an important model for studying these changes because: 1) it provides important phylogenetic perspective for reconstructing the evolution of vertebrate genomes and amphibian karyotypes, 2) its genome has evolved to a large size (~10X larger than human) but has maintained gene orders, and 3) it possesses potentially young sex chromosomes that have not undergone extensive differentiation in the structure that is typical of many other vertebrate sex chromosomes (e.g. mammalian XY chromosomes and avian ZW chromosomes). Early chromosomal studies were performed through cytogenetics, but more recent methods involving next generation sequencing and comparative genomics can reveal new information. Due to the large size and inherent complexity of the axolotl genome, multiple approaches are needed to cultivate the genomic and molecular resources essential for expanding its utility in modern scientific inquiries. This dissertation describes our efforts to improve the genomic and molecular resources for the axolotl and other salamanders, with the aim of better understanding the events that have driven the evolution of vertebrate (and amphibian) chromosomes. First, I review our current state of knowledge with respect to genome and karyotype evolution in the amphibians, present a case for studying sex chromosome evolution in the axolotl, and discuss solutions for performing analyses of large vertebrate genomes. In the second chapter, I present a study that resulted in the optimization of methods for the capture and sequencing of individual chromosomes and demonstrate the utility of the approach in improving the existing Ambystoma linkage map and generating targeted assemblies of individual chromosomes. In the third chapter, I present a published work that focuses on using this approach to characterize the two smallest chromosomes and provides an initial characterization of the huge axolotl genome. In the fourth chapter, I present another study that details the development of a dense linkage map for a newt, Notophthalmus viridescens, and its use in comparative analyses, including the discovery of a specific chromosomal fusion event in Ambystoma at the site of a major effect quantitative trait locus for metamorphic timing. I then describe the characterization of the relatively undifferentiated axolotl sex chromosomes, identification of a tiny sex-specific (W-linked) region, and a strong candidate for the axolotl sex-determining gene. Finally, I provide a brief discussion that recapitulates the main findings of each study, their utility in current studies, and future research directions. The research in this dissertation has enriched this important model with genomic and molecular resources that enhance its use in modern scientific research. The information provided from evolutionary studies in axolotl chromosomes shed critical light on vertebrate genome and chromosome evolution, specifically among amphibians, an underrepresented vertebrate clade in genomics, and in homomorphic sex chromosomes, which have been largely unstudied in amphibians