EST-derived genic molecular markers: development and utilization for generating an advanced transcript map of chickpea

Well-saturated linkage maps especially those based on expressed sequence tag (EST)-derived genic molecular markers (GMMs) are a pre-requisite for molecular breeding. This is especially true in important legumes such as chickpea where few simple sequence repeats (SSR) and even fewer GMM-based maps have been developed. Therefore, in this study, 2,496 ESTs were generated from chickpea seeds and utilized for the development of 487 novel EST-derived functional markers which included 125 EST-SSRs, 151 intron targeted primers (ITPs), 109 expressed sequence tag polymorphisms (ESTPs), and 102 single nucleotide polymorphisms (SNPs). Whereas EST-SSRs, ITPs, and ESTPs were developed by in silico analysis of the developed EST sequences, SNPs were identified by allele resequencing and their genotyping was performed using the Illumina GoldenGate Assay. Parental polymorphism was analyzed between C. arietinum ICC4958 and C. reticulatum PI489777, parents of the reference chickpea mapping population, using a total of 872 markers: 487 new gene-based markers developed in this study along with 385 previously published markers, of which 318 (36.5%) were found to be polymorphic and were used for genotyping. The genotypic data were integrated with the previously published data of 108 markers and an advanced linkage map was generated that contained 406 loci distributed on eight linkage groups that spanned 1,497.7 cM. The average marker density was 3.68 cM and the average number of markers per LG was 50.8. Among the mapped markers, 303 new genomic locations were defined that included 177 gene-based and 126 gSSRs (genomic SSRs) thereby producing the most advanced gene-rich map of chickpea solely based on co-dominant markers.     

Definitive chromosomal location of the H-2 complex by in situ hybridization to pachytene chromosomes

Chromosome 17 of the mouse carries the H-2 complex and the T/t complex. An understanding of the organization of this region and an accurate genetic map of chromosome 17 would be of great value for both immunologists and developmental biologists. Until now the only maps available have been derived solely from recombinational studies using several translocations, an inherently inaccurate method. We have found the definitive location of the H-2 complex by the use of in situ hybridization. Our results show that both the T/t complex and the H-2 complex map to positions far more distal than the generally accepted map positions. This proves that recombination in Robertsonian chromosomes underestimates physical map distances on chromosome 17.     

Improving Mycobacterium bovis Bacillus Calmette-Guèrin as a Vaccine Delivery Vector for Viral Antigens by Incorporation of Glycolipid Activators of NKT Cells

Recombinant Mycobacterium bovis bacillus Calmette-Guèrin (rBCG) has been explored as a vector for vaccines against HIV because of its ability to induce long lasting humoral and cell mediated immune responses. To maximize the potential for rBCG vaccines to induce effective immunity against HIV, various strategies are being employed to improve its ability to prime CD8⁺ T cells, which play an important role in the control of HIV infections. In this study we adopted a previously described approach of incorporating glycolipids that activate CD1d-restricted natural killer T (NKT) cells to enhance priming of CD8⁺ T cells by rBCG strains expressing an SIV Gag antigen (rBCG-SIV gag). We found that the incorporation of the synthetic NKT activating glycolipid α-galactosylceramide (α-GC) into rBCG-SIV gag significantly enhanced CD8⁺ T cell responses against an immunodominant Gag epitope, compared to responses primed by unmodified rBCG-SIV gag. The abilities of structural analogues of α-GC to enhance CD8⁺ T cell responses to rBCG were compared in both wild type and partially humanized mice that express human CD1d molecules in place of mouse CD1d. These studies identified an α-GC analogue known as 7DW8-5, which has previously been used successfully as an adjuvant in non-human primates, as a promising compound for enhancing immunogenicity of antigens delivered by rBCG.vectors. Our findings support the incorporation of synthetic glycolipid activators of NKT cells as a novel approach to enhance the immunogenicity of rBCG-vectored antigens for induction of CD8⁺ T cell responses. The glycolipid adjuvant 7DW8-5 may be a promising candidate for advancing to non-human primate and human clinical studies for the development of HIV vaccines based on rBCG vectors.     

Identification of microsatellite markers from Cicer reticulatum: molecular variation and phylogenetic analysis

Microsatellite sequences were cloned and sequenced from Cicer reticulatum, the wild annual progenitor of chickpea (C. arietinum L.). Based on the flanking sequences of the microsatellite motifs, 11 sequence-tagged microsatellite site (STMS) markers were developed. These markers were used for phylogenetic analysis of 29 accessions representing all the nine annual Cicer species. The 11 primer pairs amplified distinct fragments in all the annual species demonstrating high levels of sequence conservation at these loci. Efficient marker transferability (97%) of the C. reticulatum STMS markers across other species of the genus was observed as compared to microsatellite markers from the cultivated species. Variability in the size and number of alleles was obtained with an average of 5.8 alleles per locus. Sequence analysis at three homologous microsatellite loci revealed that the microsatellite allele variation was mainly due to differences in the copy number of the tandem repeats. However, other factors such as (1) point mutations, (2) insertion/deletion events in the flanking region, (3) expansion of closely spaced microsatellites and (4) repeat conversion in the amplified microsatellite loci were also responsible for allelic variation. An unweighted pairgroup method with arithmetic averages (UPGMA)-based dendrogram was obtained, which clearly distinguished all the accessions (except two C. judaicum accessions) from one another and revealed intra- as well as inter-species variability in the genus. An annual Cicer phylogeny was depicted which established the higher similarity between C. arietinum and C. reticulatum. The placement of C. pinnatifidum in the second crossability group and its closeness to C. bijugum was supported. Two species, C. yamashitae and C. chorassanicum, were grouped distinctly and seemed to be genetically diverse from members of the first crossability group. Our data support the distinct placement of C. cuneatum as well as a revised classification regarding its placement.     

In situ localization of human fibronectin (FN) genes to chromosome regions 2p14----p16, 2q34----q36, and 11q12.1----q13.5 in germ line cells, but to chromosome 2 sites only in somatic cells

The locations of the genes for fibronectin (FN) on chromosomes of human germ line and somatic cells were determined by in situ molecular hybridization with two 3H-labeled DNA probes, one for the region encoding the cell attachment domain of human FN, the other for the 3' noncoding and part of the coding region. Pachytene chromosomes of two males and lymphocyte chromosomes of one of these males and a female were used. Two regions of hybridization on pachytene and somatic chromosome 2 (p14----p16 and q34----q36) were found, but not in all individuals. A third region of hybridization was found at 11q12.1----q13.5 in meiotic, but not with significant frequency in somatic chromosomes. It is not clear if these differences between meiotic and somatic chromosomes, and the large differences between individuals at some of the other hybridization sites, resulted solely from technical factors. The differences between the findings in meiotic and somatic preparations might be due to the presence of four strands in pachytene chromosomes versus only one per somatic chromatid. Individual differences in DNA sequences in the chromosome segment containing the gene, differences in gene locations among individuals, or between meiotic and mitotic chromosomes might account for the other findings. The results confirm some of the earlier studies with cell hybrids that mapped FN genes to chromosomes 2 or 11. The combined findings suggest that some of these loci may be coding for the plasma form of FN and others for the cellular form. The expression of the different FN types by differentiated cells might then depend on the loci that are activated.     

Silver-stained synaptonemal complexes of human pachytene bivalents studied by light microscopy

Summary The synaptonemal complex (SC), a part of the ultrastructure of the pachytene bivalent of eukaryotic organisms, is intimately connected with the pairing of homologous chromosomes. Its development, structure, and function have been studied extensively with the electron microscope during the past 20 years. A simple method of staining with silver nitrate has made it possible for us to visualize human SCs with the light microscope.