A class I chitinase from soybean seed coat.

Protein extracts from soybean (Glycine max [L.] Merr) seed hulls were fractionated by isoelectric focusing and SDS-PAGE analysis and components identified by peptide microsequencing. An abundant 32 kDa protein possessed an N-terminal cysteine-rich hevein domain present in class I chitinases and in other chitin-binding proteins. The protein could be purified from seed coats by single step binding to a chitin bead matrix and displayed chitinase activity by an electrophoretic zymogram assay. The corresponding cDNA and genomic clones for the chitinase protein were isolated and characterized, and the expression pattern determined by RNA blot analysis. The deduced peptide sequence of 320 amino acids included an N-terminal signal peptide and conserved chitin-binding and catalytic domains interspaced by a proline hinge. An 11.3 kb EcoRI genomic fragment bearing the 2.4 kb chitinase gene was fully sequenced. The gene contained two introns and was flanked by A+T-rich tracts. Analysis by DNA blot hybridization showed that this is a single or low copy gene in the soybean genome. The chitinase is expressed late in seed development, with particularly high expression in the seed coat. Expression was also evident in the late stages of development of the pod, root, leaf, and embryo, and in tissues responding to pathogen infection. This study further illustrates the differences in protein composition of the various seed tissues and demonstrates that defence-related proteins are prevalent in the seed coat.

Hydrophobic protein synthesized in the pod endocarp adheres to the seed surface.

Soybean (Glycine max [L.] Merr.) hydrophobic protein (HPS) is an abundant seed constituent and a potentially hazardous allergen that causes asthma in persons allergic to soybean dust. By analyzing surface extracts of soybean seeds with sodium dodecyl sulfate-polyacrylamide gel electrophoresis and amino-terminal microsequencing, we determined that large amounts of HPS are deposited on the seed surface. The quantity of HPS present varies among soybean cultivars and is more prevalent on dull-seeded phenotypes. We have also isolated cDNA clones encoding HPS and determined that the preprotein is translated with a membrane-spanning signal sequence and a short hydrophilic domain. Southern analysis indicated that multiple copies of the HPS gene are present in the soybean genome, and that the HPS gene structure is polymorphic among cultivars that differ in seed coat luster. The pattern of HPS gene expression, determined by in situ hybridization and RNA analysis, shows that HPS is synthesized in the endocarp of the inner ovary wall and is deposited on the seed surface during development. This study demonstrates that a seed dust allergen is associated with the seed luster phenotype in soybean and that compositional properties of the seed surface may be altered by manipulating gene expression in the ovary wall.

Development of a diagnostic DNA probe for xanthomonads causing bacterial spot of peppers and tomatoes.

Xanthomonas vesicatoria and Xanthomonas axonopodis pv. vesicatoria, causal agents for bacterial spot of tomatoes and peppers, are difficult to distinguish from other xanthomonads found on field-grown plants. A genomic subtraction technique with subtracter DNA from nonpathogenic epiphytic xanthomonads was used to enrich for sequences that could serve as diagnostic probes for these pathogens. A 1.75-kb PstI-NotI fragment (KK1750) that preferentially hybridized to X. vesicatoria DNA and X. axonopodis pv. vesicatoria DNA was identified and cloned into pBluescriptII KS+. It hybridized to 46 (89%) of the 52 geographically diverse bacterial spot-causing xanthomonad (bsx) strains included in this study. The six probe-negative strains were genotypically and pathologically distinct from the other bsx strains studied. Two of these strains, DC91-1 and DC91-2, resembled X. campestris pv. raphani in that they also infected radish plants. X. vesicatoria strains gave stronger hybridization signals than did most X. axonopodis pv. vesicatoria strains. In a survey of 110 non-bsx plant-associated bacteria, including 44 nonvesicatoria phytopathogenic xanthomonads and 43 epiphytic xanthomonad strains, only 8 were probe positive, but the responses were weak. Further testing revealed that one of these strains was actually a tomato pathogen. Pulsed-field gel electrophoresis and Southern blot analysis of 46 bsx strains indicated that KK1750 sequences could be either plasmid-borne (10.9%), chromosome-borne (43.4%), or present on both replicons (45.7%). KK1750, unique in its ability to hybridize to both X. axonopodis pv. vesicatoria and X. vesicatoria strains, should facilitate disease diagnosis for these important plant pathogens.