Crystal Structure and Directed Evolution of Specificity of NlaIV Restriction Endonuclease.

Specificity engineering is challenging and particularly difficult for enzymes that have the catalytic machinery and specificity determinants in close proximity. Restriction endonucleases have been used as a paradigm for protein engineering, but successful cases are rare. Here, we present the results of a directed evolution approach to the engineering of a dimeric, blunt end cutting restriction enzyme NlaIV (GGN/NCC). Based on the remote similarity to EcoRV endonuclease, regions for random mutagenesis and in vitro evolution were chosen. The obtained variants cleaved target sites with an up to 100-fold kcat/KM preference for AT or TA (GGW/WCC) over GC or CG (GGS/SCC) in the central dinucleotide step, compared to the only ~17-fold preference of the wild-type enzyme. To understand the basis of the increased specificity, we determined the crystal structure of NlaIV. Despite the presence of DNA in the crystallization mix, the enzyme crystallized in the free form. We therefore constructed a computational model of the NlaIV-DNA complex. According to the model, the mutagenesis of the regions that were in the proximity of DNA did not lead to the desired specificity change, which was instead conveyed in an indirect manner by substitutions in the more distant regions.

Bioinformatic analysis of outer membrane proteome of Neisseria meningitidis and Neisseria lactamica.

Two-dimensional electrophoresis (isoelectric focusing/SDS-PAGE) and Western-blotting techniques were used to analyze and compare common and/or specific outer-membrane proteins and antigens from Neisseria meningitidis and Neisseria lactamica. Bioinformatic image analyses of proteome and immunoproteome maps indicated the presence of numerous proteins and several antigens shared by N. meningitidis and N. lactamica, although the inter-strain variation in the maps was of similar magnitude to the inter-species variation, and digital comparison of the maps did not reveal proteins found to be identical by MALDI-TOF fingerprinting analysis. PorA and RmpM, two relevant outer-membrane antigens, manifested as various spots at several different positions. While some of these were common to all the strains analyzed, others were exclusive to N. meningitidis and their electrophoretic mobilities were different than expected. One such spot, with a molecular mass of 19 kDa, may be the C-terminal fragment of RmpM (RmpM-Cter). The results demonstrate that computer-driven analysis based exclusively on spot positions in the proteome or immunoproteome maps is not a reliable approach to predict the identity of proteins or antigens; rather, other identification techniques are necessary to obtain accurate comparisons.

Cross-linking analysis of antigenic outer membrane protein complexes of Neisseria meningitidis.

Polysaccharide-based approaches have not enabled the development of effective vaccines against meningococci of serogroup B, and the most promising current research is focused on the use of outer membrane vesicles. Due to the toxicity of the outer membrane oligosaccharides, new vaccines based on purified proteins are being sought, but despite the application of advanced techniques, they remain elusive, perhaps due to the fact that standard techniques for analysis of antigens overlook conformational epitopes located in membrane complexes. Membrane complex antigens have been analyzed in Neisseria gonorrhoeae, and a study published on Neisseria meningitidis has reported the in vitro formation of 800-kD complexes by deposition of a purified protein (MSP63) onto synthetic lipid layers; however, no studies to date have attempted to identify membrane complexes present in vivo in N. meningitidis. In the present study, cross-linking with formaldehyde was used to identify outer membrane protein associations in various N. meningitidis and Neisseria lactamica strains. In N. meningitides, complexes of about 450 kD (also present in N. lactamica), 165 and 95 kD were detected and shown to be made up of the proteins MSP63, PorA/PorB/RmpM/FetA, and PorA/PorB/RmpM, respectively. In western blots, the 450-kD complex was identified by mouse antibodies raised against outer membrane vesicles, but not by antibodies raised against the purified complex, demonstrating the importance of conformational epitopes, and thus suggesting that the analysis of antigens in their native conformation may be useful or even essential for the design of effective vaccines against meningococci.

Rapid characterization of outer-membrane proteins in Neisseria lactamica by SELDI-TOF-MS (surface-enhanced laser desorption ionization-time-of-flight MS) for use in a meningococcal vaccine.

Immunological and epidemiological evidence suggests that the development of natural immunity to meningococcal disease results from colonization of the nasopharynx by commensal Neisseria species, particularly with Neisseria lactamica. We have reported previously that immunization with N. lactamica outer-membrane vesicles containing the major OMPs (outer-membrane proteins) protected mice against lethal challenge with meningococci of diverse serogroups and serotypes and has the potential to form the basis of a vaccine against meningococcal diseases [Oliver, Reddin, Bracegirdle et al. (2002) Infect. Immun. 70, 3621-3626]. In the present study, we have shown that biomass production and the profile of outer-membrane vesicle proteins may be affected by fermentation conditions and, in particular, media composition. Ciphergen SELDI-TOF Protein Chips were used as a rapid and sensitive new method in comparison with conventional SDS/PAGE. SELDI-TOF-MS (surface-enhanced laser-desorption ionization-time-of-flight MS) reproducibly identified three major OMPs (NspA, RmpM and PorB) and detected the changes in the protein profile when the growth medium was altered. The findings of this work indicate that SELDI-TOF-MS is a useful tool for the rapid optimization of OMP production in industrial fermentation processes and can be adapted as a Process Analytical Technology.