Soybean genomic survey: BAC-end sequences near RFLP and SSR markers.

We are building a framework physical infrastructure across the soybean genome by using SSR (simple sequence repeat) and RFLP (restriction fragment length polymorphism) markers to identify BACs (bacterial artificial chromosomes) from two soybean BAC libraries. The libraries were prepared from two genotypes, each digested with a different restriction enzyme. The BACs identified by each marker were grouped into contigs. We have obtained BAC- end sequence from BACs within each contig. The sequences were analyzed by the University of Minnesota Center for Computational Genomics and Bioinformatics using BLAST algorithms to search nucleotide and protein databases. The SSR-identified BACs had a higher percentage of significant BLAST hits than did the RFLP-identified BACs. This difference was due to a higher percentage of hits to repetitive-type sequences for the SSR-identified BACs that was offset in part, however, by a somewhat larger proportion of RFLP-identified significant hits with similarity to experimentally defined genes and soybean ESTs (expressed sequence tags). These genes represented a wide range of metabolic functions. In these analyses, only repetitive sequences from SSR-identified contigs appeared to be clustered. The BAC-end sequences also allowed us to identify microsynteny between soybean and the model plants Arabidopsis thaliana and Medicago truncatula. This map-based approach to genome sampling provides a means of assaying soybean genome structure and organization.

bcl-1 gene rearrangements in mantle cell lymphoma: a comprehensive analysis of 118 cases, including B-5-fixed tissue, by polymerase chain reaction and Southern transfer analysis.

We evaluated 118 cases of mantle cell lymphoma by polymerase chain reaction (PCR) for the major translocation cluster (MTC) region and another breakpoint corresponding to probe p94PS, located 24 kb telomeric to the MTC locus on chromosome 11. The specimens included 64 frozen, 19 formalin-fixed, and 9 B-5-fixed lymph nodes and 26 B-5-fixed bone marrow biopsy specimens. We also analyzed DNA from the 64 frozen lymph nodes by Southern transfer analysis (SB) using three separate bcl-1 breakpoint probes. Gene rearrangements were identified in 17 (PCR) and 18 (SB) of 64 frozen lymph nodes and by PCR in 6 of 19 formalin-fixed lymph nodes, 3 of 9 B-5-fixed lymph nodes, and 12 of 26 B-5-fixed bone marrow cores with MTC locus primers and probe. Only one case showed rearrangement with the p11EH probe that corresponds to breakpoints situated 63 kb telomeric to the MTC locus. No rearrangements were detected by PCR or SB for the breakpoint site corresponding to the p94PS probe, but we identified a polymorphic restriction site with HinD III digest in approximately 25% of the cases. In agreement with other studies, these results confirmed that breakpoints in the MTC region of the bcl-1 locus are tightly clustered and associated with 30 to 40% of mantle cell lymphomas. Other breakpoints in the bcl-1 locus seem to be heterogeneous and cannot be detected by PCR or SB with use of existing probes or primer sequences. The most important finding of our study is optimization of the methodology for the detection of immunoglobulin heavy chain gene rearrangement and MTC region breakpoints by PCR from the DNA isolated from B-5-fixed, paraffin-embedded lymph nodes and bone marrow biopsy specimens. The results obtained from these tissues are comparable to those obtained from frozen or formalin-fixed tissue.

Quantitative analysis in molecular diagnostics.

Quantitative analysis of DNA products derived from polymerase chain reaction (PCR)-based assays depends on the careful optimization of each of the reaction parameters to achieve highly efficient amplification of target sequences. In practice, however, measurement of the accumulated PCR product is reliable only when analyses are performed at points in the exponential phase of the PCR amplification curve and before the onset of the plateau phase. The recent development of more sensitive DNA product detection systems has permitted the analysis of PCR assays after fewer amplification cycles, where the accumulation of product approaches linearity, while at the same time maintaining superior assay specificity. These methods include the use of high performance liquid chromatography, automated fluorescence detection, electrochemiluminescence, and the ligase chain reaction. Clinical applications of these methods are numerous and include diagnostic testing as well as therapeutic monitoring for neoplastic, infectious, and inherited genetic disease.