Expression sites and developmental regulation of genes encoding (1→3,1→4)-β-glucanases in germinated barley

Expression sites of genes encoding (13,14)--glucan 4-glucanohydrolase (EC 3.2.1.73) have been mapped in germinated barley grains (Hordeum vulgare L.) by hybridization histochemistry. A³²P-labelled cDNA (copy DNA) probe was hybridized to cryosections of intact barley grains to localize complementary mRNAs. No mRNA encoding (13,14)--glucanase is detected in ungerminated grain. Expression of (13,14)--glucanase genes is first detected in the scutellum after 1 d and is confined to the epithelial layer. At this stage, no expression is apparent in the aleurone. After 2 d, levels of (13,14)--glucanase mRNA decrease in the scutellar epithelium but increase in the aleurone. In the aleurone layer, induction of (13,14)--glucanase gene expression, as measured by mRNA accumulation, progresses from the proximal to distal end of the grain as a front moving away from, and parallel to, the face of the scutellum.Abbreviations cDNA copy DNA - RNase ribonuclease     

In situ biosurfactant production by Bacillus strains injected into a limestone petroleum reservoir

Biosurfactant-mediated oil recovery may be an economic approach for recovery of significant amounts of oil entrapped in reservoirs, but evidence that biosurfactants can be produced in situ at concentrations needed to mobilize oil is lacking. We tested whether two Bacillus strains that produce lipopeptide biosurfactants can metabolize and produce their biosurfactants in an oil reservoir. Five wells that produce from the same Viola limestone formation were used. Two wells received an inoculum (a mixture of Bacillus strain RS-1 and Bacillus subtilis subsp. spizizenii NRRL B-23049) and nutrients (glucose, sodium nitrate, and trace metals), two wells received just nutrients, and one well received only formation water. Results showed in situ metabolism and biosurfactant production. The average concentration of lipopeptide biosurfactant in the produced fluids of the inoculated wells was about 90 mg/liter. This concentration is approximately nine times the minimum concentration required to mobilize entrapped oil from sandstone cores. Carbon dioxide, acetate, lactate, ethanol, and 2,3-butanediol were detected in the produced fluids of the inoculated wells. Only CO(2) and ethanol were detected in the produced fluids of the nutrient-only-treated wells. Microbiological and molecular data showed that the microorganisms injected into the formation were retrieved in the produced fluids of the inoculated wells. We provide essential data for modeling microbial oil recovery processes in situ, including growth rates (0.06 +/- 0.01 h(-1)), carbon balances (107% +/- 34%), biosurfactant production rates (0.02 +/- 0.001 h(-1)), and biosurfactant yields (0.015 +/- 0.001 mol biosurfactant/mol glucose). The data demonstrate the technical feasibility of microbial processes for oil recovery.     

Mutant barley (1-->3,1-->4)-beta-glucan endohydrolases with enhanced thermostability

The similar three-dimensional structures of barley (1-->3)-beta-glucan endohydrolases and (1-->3,1-->4)-beta-glucan endohydrolases indicate that the enzymes are closely related in evolutionary terms. However, the (1-->3)-beta-glucanases hydrolyze polysaccharides of the type found in fungal cell walls and are members of the pathogenesis-related PR2 group of proteins, while the (1-->3,1-->4)-beta-glucanases function in plant cell wall metabolism. The (1-->3)-beta-glucanases have evolved to be significantly more stable than the (1-->3,1-->4)-beta-glucanases, probably as a consequence of the hostile environments imposed upon the plant by invading microorganisms. In attempts to define the molecular basis for the differences in stability, eight amino acid substitutions were introduced into a barley (1-->3,1-->4)-beta-glucanase using site-directed mutagenesis of a cDNA that encodes the enzyme. The amino acid substitutions chosen were based on structural comparisons of the barley (1-->3)- and (1-->3,1-->4)-beta-glucanases and of other higher plant (1-->3)-beta-glucanases. Three of the resulting mutant enzymes showed increased thermostability compared with the wild-type (1-->3,1-->4)-beta-glucanase. The largest increase in stability was observed when the histidine at position 300 was changed to a proline (mutant H300P), a mutation that was likely to decrease the entropy of the unfolded state of the enzyme. Furthermore, the three amino acid substitutions which increased the thermostability of barley (1-->3,1-->4)-beta-glucanase isoenzyme EII were all located in the COOH-terminal loop of the enzyme. Thus, this loop represents a particularly unstable region of the enzyme and could be involved in the initiation of unfolding of the (1-->3,1-->4)-beta-glucanase at elevated temperatures.     

High-yield production,refolding and a molecular modelling of the catalytic module of (1,3)-β-<Emphasis Type="SmallCaps">d</Emphasis>-glucan (curdlan) synthase from <Emphasis Type="Italic">Agrobacterium</Emphasis> sp.

Biosynthesis of the (1,3)-β-d-glucan (curdlan) in Agrobacterium sp., is believed to proceed by the repetitive addition of glucosyl residues from UDP-glucose by a membrane-embedded curdlan synthase (CrdS) [UDP-glucose: (1,3)-β-d-glucan 3-β-d-glucosyltransferase; EC 2.4.1.34]. The catalytic module of CrdS (cm-CrdS) was expressed in good yield from a cDNA encoding cm-CrdS cloned into the pET-32a(+) vector, containing a coding region for thioredoxin, and from the Champion™ pET SUMO system that possesses a coding region of a small ubiquitin-related modifier (SUMO) partner protein. The two DNA fusions, designated pET-32a_cm-CrdS and SUMO_cm-CrdS were expressed as chimeric proteins. High yields of inclusion bodies were produced in E. coli and these could be refolded to form soluble proteins, using a range of buffers and non-detergent sulfobetaines. A purification protocol was developed, which afforded a one-step on-column refolding and simultaneous purification of the recombinant 6xHis-tagged SUMO_cm-CrdS protein. The latter protein was digested by a specific protease to yield intact cm-CrdS in high yields. The refolded SUMO_cm-CrdS protein did not exhibit curdlan synthase activity, but showed a circular dischroism spectrum, which had an α/β-type-like conformation. Amino acid sequences of tryptic fragments of the SUMO_cm-CrdS fusion and free cm-CrdS proteins, determined by MALDI/TOF confirmed that the full-length proteins were synthesized by E. coli, and that no alterations in amino acid sequences occurred. A three-dimensional model of cm-CrdS predicted the juxtaposition of highly conserved aspartates D156, D208, D210 and D304, and the QRTRW motif, which are likely to play roles in donor and acceptor substrate binding and catalysis.     

Fertile plant regeneration from cell suspension and protoplast cultures of barley (t Hordeum vulgare cv. Schooner)

Fertile plants were regenerated from both cell suspension and protoplast-derived cultures of the two-row barley, Hordeum vulgare L. cv. Schooner. Embryogenic calluses, derived from immature embryos, were used to establish suspension cultures. More than 100 plants, with variable seed set, have been regenerated from six embryogenic cell suspension cultures. Protoplasts isolated from three suspension cultures divided and when the resultant embryogenic proto-calluses were transferred to regeneration medium both green and albino shoots were produced. The green shoots were transferred to growth regulator-free medium and plantlets that developed strong root systems were potted in soil and grown to maturity in the glasshouse. Root tip analysis of plants regenerated from cell suspension cultures revealed the expected 2N = 14 complement of chromosomes. However, chromosomal analysis of protoplast-derived plants showed numerical variation among a proportion of the regenerants. This revised version was published online in June 2006 with corrections to the Cover Date.     

Members of a New Group of Chitinase-Like Genes are Expressed Preferentially in Cotton Cells with Secondary Walls

Two homologous cotton (Gossypium hirsutum L.) genes, GhCTL1 and GhCTL2, encode members of a new group of chitinase-like proteins (called the GhCTL group) that includes other proteins from two cotton species, Arabidopsis, rice, and pea. Members of the GhCTL group are assigned to family GH19 glycoside hydrolases along with numerous authentic chitinases (http://afmb.cnrs-mrs.fr/CAZY/index.html), but the proteins have novel consensus sequences in two regions that are essential for chitinase activity and that were previously thought to be conserved. Maximum parsimony phylogenetic analyses, as well as Neighbor-Joining distance analyses, of numerous chitinases confirmed that the GhCTL group is distinct. A molecular model of GhCTL2 (based on the three-dimensional structure of a barley chitinase) had changes in the catalytic site that are likely to abolish catalytic activity while retaining potential to bind chitin oligosaccharides. RNA blot analysis showed that members of the GhCTL group had preferential expression during secondary wall deposition in cotton lint fiber. Cotton transformed with a fusion of the GhCTL2 promoter to the beta -d-glucuronidase gene showed preferential reporter gene activity in numerous cells during secondary wall deposition. Together with evidence from other researchers that mutants in an Arabidopsis gene within the GhCTL group are cellulose-deficient with phenotypes indicative of altered primary cell walls, these data suggest that members of the GhCTL group of chitinase-like proteins are essential for cellulose synthesis in primary and secondary cell walls. However, the mechanism by which they act is more likely to involve binding of chitin oligosaccharides than catalysis.