Plasmid AZOBR_p1-borne fabG gene for putative 3-oxoacyl-[acyl-carrier protein] reductase is essential for proper assembly and work of the dual flagellar system in the alphaproteobacterium Azospirillum brasilense Sp245.

Azospirillum brasilense can swim and swarm owing to the activity of a constitutive polar flagellum (Fla) and inducible lateral flagella (Laf), respectively. Experimental data on the regulation of the Fla and Laf assembly in azospirilla are scarce. Here, the coding sequence (CDS) AZOBR_p1160043 (fabG1) for a putative 3-oxoacyl-[acyl-carrier protein (ACP)] reductase was found essential for the construction of both types of flagella. In an immotile leaky Fla- Laf- fabG1::Omegon-Km mutant, Sp245.1610, defects in flagellation and motility were fully complemented by expressing the CDS AZOBR_p1160043 from plasmid pRK415. When pRK415 with the cloned CDS AZOBR_p1160045 (fliC) for a putative 65.2 kDa Sp245 Fla flagellin was transferred into the Sp245.1610 cells, the bacteria also became able to assemble a motile single flagellum. Some cells, however, had unusual swimming behavior, probably because of the side location of the organelle. Although the assembly of Laf was not restored in Sp245.1610 (pRK415-p1160045), this strain was somewhat capable of swarming motility. We propose that the putative 3-oxoacyl-[ACP] reductase encoded by the CDS AZOBR_p1160043 plays a role in correct flagellar location in the cell envelope and (or) in flagellar modification(s), which are also required for the inducible construction of Laf and for proper swimming and swarming motility of A. brasilense Sp245.

Location and architecture of an antibody-binding site of influenza A virus nucleoprotein.

Amino acid positions recognized by monoclonal antibodies (MAbs) in the influenza A virus nucleoprotein (NP) have been reported. As these residues were scattered in the three-dimensional (3D) structure of NP, no patterns of the architecture of antibody-binding sites could be inferred. Here, we used site-specific mutagenesis and ELISA to screen the amino acids surrounding position 470 recognized by the MAb 3/1 as a linear epitope. Ten amino acid residues involved in the reaction of NP with the MAb 3/1 and the MAb 469/6 were identified. Our data are the first to outline a compact site recognized by MAbs in the 3D structure of the influenza virus NP.

Antibody-binding epitope differences in the nucleoprotein of avian and mammalian influenza A viruses.

Abstract Influenza virus nucleoprotein (NP) binds to the viral genome RNA and forms the internal ribonucleoprotein complex of the virus particle. Avian and human influenza virus NP have characteristic differences at several amino acid positions. It is not known whether any of these differences can be recognized by antibodies. In the present study five monoclonal antibodies (MAbs) were produced against NP of A/Duck/Novosibirsk/56/05 (H5N1) influenza virus. Two MAbs discerned human and avian influenza strains on ELISA testing. The NP expressed in a prokaryotic system was used for the analysis of site-specific mutants carrying amino acid substitutions in the relevant positions. Amino acid residues in positions 100 and 101 were shown to be recognized by the MAbs. The residue in position 100 is host-specific, and its recognition by the MAb 2E6 may be useful for the differentiation of human and avian viruses. The data are discussed in view of the effects of amino acid substitutions in influenza virus NP affecting both host range and antibody-binding specificity.

Effective expression of recombinant cytotoxic protein via its attachment to a polyglutamine domain.

Inadvertent cytotoxicity may hinder the expression of many recombinant proteins that are of industrial or medicinal importance. Here, we show that covalent binding of the influenza A cytotoxic protein M2 to a polyglutamine domain (polyQ-M2; QM2) results in significant delay of its cytotoxic effects when compared to wild-type protein (M2wt). We also show that while expression of recombinant M2wt from A/WSN/1933 strain could not be attained in vaccinia virus (VV), polyQ-M2 was successfully expressed in this system. Moreover, we demonstrate that in cell culture, the polyQ domain is cleaved off following 48 h of expression, thus releasing free and active M2. Similarly, we show the spontaneous cleavage and polyQ release from fusion with another distinct polypeptide, green fluorescent protein (GFP). Expression of M2 from QM2 construct was more prolonged than one based on M2wt-expressing construct, markedly exceeding it at the later time points. Therefore, cell death caused by a toxic polypeptide may be suppressed via genetic fusion with polyQ, resulting in its enhanced expression, followed by slow release of the free polypeptide from the fusion. Collectively, covalent fusion with polyQ or other aggregate-forming domains presents a novel approach for industrial production of cytotoxic proteins and also holds promise for gene therapy applications.

Location of antigenic sites recognized by monoclonal antibodies in the influenza A virus nucleoprotein molecule.

The locations of amino acid positions relevant to antigenic variation in the nucleoprotein (NP) of influenza virus are not conclusively known. We analysed the antigenic structure of influenza A virus NP by introducing site-specific mutations at amino acid positions presumed to be relevant for the differentiation of strain differences by anti-NP monoclonal antibodies. Mutant proteins were expressed in a prokaryotic system and analysed by performing ELISA with monoclonal antibodies. Four amino acid residues were found to determine four different antibody-binding sites. When mapped in a 3D X-ray model of NP, the four antigenically relevant amino acid positions were found to be located in separate physical sites of the NP molecule.

Mobile elements of an Azospirillum brasilense Sp245 85-MDa plasmid involved in replicon fusions.

Sequence analysis of approximately 25kb of an Azospirillum brasilense Sp245 85-MDa ( approximately 142kb) plasmid, p85, identified two novel IS elements mediating p85 fusions with a suicide plasmid vector, pJFF350. These IS elements, 1465-bp ISAzba1 and 1112-bp ISAzba3, belong to the IS256 family and to the IS5 family/IS903 group, respectively. Truncated ISAzba2 from the ISL3 family was found near one of the copies of ISAzba1 that flank pJFF350 in p85::pJFF350. As another factor potentially contributing to the known genetic plasticity of p85, a phage integrase gene was identified in this plasmid.

The proteosomal degradation of fusion proteins cannot be predicted from the proteosome susceptibility of their individual components.

It is assumed that the proteosome-processing characteristics of fusion constructs can be predicted from the sum of the proteosome sensitivity of their components. In the present study, we observed that a fusion construct consisting of proteosome-degradable proteins does not necessarily result in a proteosome-degradable chimera. Conversely, fusion of proteosome-resistant proteins may result in a proteosome-degradable composite. We previously demonstrated that conserved influenza proteins can be unified into a single fusion antigen that is protective, and that vaccination with combinations of proteosome-resistant and proteosome-degradable antigens resulted in an augmented T-cell response. In the present study we constructed proteosome-degradable mutants of conserved influenza proteins NP, M1, NS1, and M2. These were then fused into multipartite proteins in different positions. The stability and degradation profiles of these fusion constructs were demonstrated to depend on the relative position of the individual proteins within the chimeric molecule. Combining unstable sequences of either NP and M1 or NS1 and M2 resulted in either rapidly proteosome degraded or proteosome-resistant bipartite fusion mutants. However, further unification of the proteosome-degradable forms into a single four-partite fusion molecule resulted in relatively stable chimeric proteins. Conversely, the addition of proteosome-resistant wild-type M2 to proteosome-resistant NP-M1-NS1 fusion protein lead to the decreased stability of the resulting four-partite multigene products, which in one case was clearly proteosome dependent. Additionally, a highly destabilized form of M1 failed to destabilize the wild-type NP. Collectively, we did not observe any additive effect leading to proteosomal degradation/nondegradation of a multigene construct.

Immunization with hepatitis C virus core gene triggers potent T-cell response, but affects CD4+ T-cells.

Numerous attempts to induce immunity against HCV core (HCV-C) by DNA immunization met serious difficulties in optimizing T-helper cell and antibody responses. Immunomodulatory properties of HCV-C could be blamed that seem to be dependent on the genotype of HCV source. Here, we characterized HCV-C gene from HCV 1b isolate 274933RU. Eukaryotic expression of HCV-C was effectively driven by CMVIE, while human elongation factor 1 alpha promoter directed low levels of HCV-C expression. C57BL/6 mice were immunized with CMVIE-driven HCV-C gene, and assessed for specific antibody production, T-cell proliferation and cytokine secretion. The number and proportion of CD19+, CD3+, CD3+/CD4+, and CD3+/CD8+ splenocytes in HCV-C gene recipients was evaluated by flow cytometry. A significant mounting drop in CD3+/CD4+ T-cell counts occurred in HCV-C gene-recipients as compared to the controls. Despite that, 75% of mice exhibited core-specific cellular reactivity revealed as high proliferative responses to HCV-C and HCV-C peptides. Stimulated T-cells secreted predominantly IFN-gamma and IL-2. A shift of epitope specificity was observed with the early response being broad, and the late limited to the HCV-C C-terminus. Thus, we demonstrate both T-cell immunogenicity and T-cell modulation by core of HCV 1b. Immune modulation by HCV core may affect host ability to mount long-lasting cellular and antibody response and should be dealt with in designing core-based HCV vaccines.