AutoSNPdb: an annotated single nucleotide polymorphism database for crop plants

Single nucleotide polymorphisms (SNPs) may be considered the ultimate genetic marker as they represent the finest resolution of a DNA sequence (a single nucleotide), are generally abundant in populations and have a low mutation rate. Analysis of assembled EST sequence data provides a cost-effective means to identify large numbers of SNPs associated with functional genes. We have developed an integrated SNP discovery pipeline, which identifies SNPs from assembled EST sequences. The results are maintained in a custom relational database along with EST source and annotation information. The current database hosts data for the important crops rice, barley and Brassica. Users may rapidly identify polymorphic sequences of interest through BLAST sequence comparison, keyword searches of annotations derived from UniRef90 and GenBank comparisons, GO annotations or in genes corresponding to syntenic regions of reference genomes. In addition, SNPs between specific varieties may be identified for targeted mapping and association studies. SNPs are viewed using a user-friendly graphical interface. The database is freely accessible at http://autosnpdb.qfab.org.au/

An approach for global scanning of single nucleotide variations

Efficient global scanning of single nucleotide variations in DNA sequences between related, complex DNA samples remains a challenge. In the present article we present an approach to this problem. We have used immobilized thymidine DNA glycosylases to capture and enrich DNA fragments containing internal mismatched base pairs and separate these fragments as a pool from perfectly base-paired fragments as another pool. Enrichments of up to several hundredfold were obtained with one cycle of treatment, and all of the four groups of single nucleotide mismatches were fully covered by combining use of two thymine DNA glycosylases generated here. We have used a heterohybrid-orientating strategy for selective amplification of duplexes with one strand derived from each of two input DNA samples, which can also be used for selective amplification of duplexes with both strands derived from one of two input samples when desired. By combining these methods, the single nucleotide variations either between two DNA pools or within one DNA pool can be obtained in one process. This approach has been applied to the total cDNA from a human cell line and has several potential applications in mapping genetic variations, particularly global scanning of cDNA single nucleotide variations or polymorphisms, and finally high-throughput mapping of complex genetic traits

A new class of oxidosqualene cyclases directs synthesis of antimicrobial phytoprotectants in monocots

Many plants synthesize antimicrobial secondary metabolites as part of their normal program of growth and development, often sequestering them in tissues where they may protect against microbial attack. These include glycosylated triterpenoids (saponins), natural products that are exploited by man for a variety of purposes including use as drugs [Hostettmann, K. & Marston, A. (1995) Saponins (Cambridge Univ. Press, Cambridge, U.K.)]. Very little is known about the genes required for the synthesis of this important family of secondary metabolites in plants. Here we show the novel oxidosqualene cyclase AsbAS1 catalyzes the first committed step in the synthesis of antifungal triterpenoid saponins that accumulate in oat roots. We also demonstrate that two sodium azide-generated saponin-deficient mutants of oat, which define the Sad1 genetic complementation group, are defective in the gene encoding this enzyme and provide molecular genetic evidence indicating a direct link between AsbAS1, triterpenoid saponin biosynthesis, and disease resistance. Orthologs of AsbAS1 are absent from modern cereals and may have been lost during selection, raising the possibility that this gene could be exploited to enhance disease resistance in crop plants