Snake Venom Metalloproteinases and Their Peptide Inhibitors from Myanmar Russell’s Viper Venom

As more data are generated from proteome and transcriptome analyses of snake venoms, we are gaining an appreciation of the complexity of the venoms and, to some degree, the various sources of such complexity. However, our knowledge is still far from complete. The translation of genetic information from the snake genome to the transcriptome and ultimately the proteome is only beginning to be appreciated, and will require significantly more investigation of the snake venom genomic structure prior to a complete understanding of the genesis of venom composition. Venom complexity, however, is derived not only from the venom genomic structure but also from transcriptome generation and translation and, perhaps most importantly, post-translation modification of the nascent venom proteome. In this review, we examine the snake venom metalloproteinases, some of the predominant components in viperid venoms, with regard to possible synthesis and post-translational mechanisms that contribute to venom complexity. The aim of this review is to highlight the state of our knowledge on snake venom metalloproteinase post-translational processing and to suggest testable hypotheses regarding the cellular mechanisms associated with snake venom metalloproteinase complexity in venoms.

Snake bites can be deadly, but the venoms also contain components of medical and biotechnological value. The proteomic characterization of snake venom proteomes, snake venomics, has thus a number of potential benefits for basic research, clinical diagnosis, and development of new research tools and drugs of potential clinical use. Snake venomics is also relevant for a deep understanding of the evolution and the biological effects of the venoms, and to generate immunization protocols to elicit toxin-specific antibodies with greater specificity and effectiveness than conventional systems. Our snake venomics approach starts with the fractionation of the crude venom by reverse-phase HPLC, followed by the initial characterization of each protein fraction by combination of N-terminal sequencing, SDS-PAGE, and mass spectrometric determination of the molecular masses and the cysteine (SH and S--S) content. Protein fractions showing a single electrophoretic band, molecular mass, and N-terminal sequence can be straightforwardly assigned by BLAST analysis to a known protein family. On the other hand, protein fractions showing heterogeneous or blocked N-termini are analyzed by SDS-PAGE and the bands of interest subjected to automated reduction, carbamidomethylation, and in-gel tryptic digestion. The resulting tryptic peptides are then analyzed by MALDI-TOF mass fingerprinting followed by amino acid sequence determination of selected doubly and triply charged peptide ions by collision-induced dissociation tandem mass spectrometry. The combined strategy allows us to assign unambiguously all the isolated venom toxins representing over 0.05% of the total venom proteins to known protein families. Protocols and applications of snake venomics are reviewed and discussed. Copyright 2007 John Wiley & Sons, Ltd.