Increase in xylanase production by Streptomyces lividans through simultaneous use of the Sec- and Tat-dependent protein export systems.

Xylanase B1 (XlnB1) from Streptomyces lividans is a protein consisting of two discrete structural and functional units, an N-terminal catalytic domain and a C-terminal substrate binding domain. In the culture medium, two forms of xylanase B are present, namely, XlnB1 and XlnB2, the latter of which corresponds to the catalytic domain of XlnB1 deprived of the substrate binding domain. Both forms of the xylanase have the same activity on xylan. The enzyme is secreted through the Sec-dependent pathway with a better yield of XlnB1 than XlnB2. Interestingly, XlnB2 exhibits 80% identity with XlnC which is secreted exclusively through the Tat-dependent pathway. To demonstrate whether XlnB1 and XlnB2 could also be secreted through the Tat-dependent pathway, the Tat-targeting xlnC signal sequence was fused to the structural genes of xlnB1 and xlnB2. Both XlnB1 and XlnB2 were secreted through the Tat-dependent pathway, but XlnB2 was better produced than XlnB1. As XlnB1 and XlnB2 could be better secreted through the Sec- and Tat-dependent systems, respectively, a copy of the structural gene of xlnB1 fused to a Sec signal sequence and a copy of the structural gene of xlnB2 fused to a Tat signal sequence were inserted into the same plasmid under the control of the xlnA promoter. The transformant produced xylanase activity which corresponded approximately to the sum of activities of the individual strain producing xylanase by either the Sec- or Tat-dependent secretion system. This indicated that both secretion systems are functional and independent of each other in the recombinant strain. This is the first report on the efficient secretion of a protein using two different secretion systems at the same time. Assuming that the protein to be secreted could be properly folded prior to and after translocation via the Tat- and Sec-dependent pathways, respectively, the simultaneous use of the Sec- and Tat-dependent pathways provides an efficient means to increase the production of a given protein.

Genetic diversity of merozoite surface protein-1 gene of Plasmodium vivax isolates in mining villages of Venezuela (Bolivar State).

The merozoite surface protein-1 gene of Plasmodium vivax is highly polymorphic and so, currently used in epidemiological studies of P. vivax malaria. We sequenced the variable block 5 of the gene from 39 Venezuelan isolates, 18 of which were co-infected with Plasmodium falciparum. We observed a limited variability with 34 isolates belonging to the type Salvador I, none Belem type and only five recombinants. Among the recombinants, only two types of sequences were observed with, respectively, 18 and 21 poly-Q residues. Nucleotide substitutions explained the major differences of the 11 patterns observed. We could evidence neither specific MSP-1 genotype associated with co-infected samples, nor peculiar MSP-1 genotype distribution inside the investigated areas. In comparison with other low endemic regions in the world, our sampling has a lower genetic diversity, which could be mainly explained by the lack of Belem type. In fact, the variable repeats of poly-Q residues involved in the polymorphism of Belem type and recombinant isolates are responsible for a great part of variability observed in MSP-1 block 5.

Extensive antigenic changes in an atypical isolate of very virulent infectious bursal disease virus and experimental clinical control of this virus with an antigenically classical live vaccine.

The 99323 Egyptian isolate of infectious bursal disease (IBD) virus (IBDV) was identified during an international survey of acute IBD cases. Its unique antigenicity was characterized by a markedly reduced binding of neutralizing monoclonal antibodies 3, 4, 5, 6, 8 and 9 in an antigen-capture enzyme-linked immunosorbent assay. Nucleotide sequencing of the genome region encoding the VP2 major immunogenic domain in 99323 revealed amino acid changes occurring at positions critical for antigenicity, but phylogenetic analysis demonstrated that 99323 was related to typical, very virulent IBDV (e.g. isolate 89163). Protection experimentally afforded by an antigenically classical live IBD vaccine was investigated in specific pathogen free chickens challenged with 99323 or 89163. Both viruses were similarly controlled, as evaluated by clinical signs, growth retardation, bursa-to-body weight ratios and histological lesions of the bursa after challenge. These results document that an active antibody response to a classical live antigen may clinically control infection by an antigenically atypical very virulent IBDV.