First report of whole genome sequence of septicemic Pasteurella multocida serovar B:2 'Soron' strain isolated from swine.

Pig pasteurellosis, caused by Pasteurella multocida, is an acute infection that also has economic implications for pig farmers. We report the complete genome sequence of a P. multocida, serovar B:2 'Soron' strain isolated from the blood of a pig that had died of pasteurellosis in India. The isolate was not found to be haemorrhagic septicaemia (HS) specific B:2 by the PCR assay. The genome of 'Soron' strain is a single circular chromosome of 2,272,124 base pairs in length and contains 2014 predicted coding regions, 4 ribosomal RNA operons, and 52 tRNAs. It has 1812 protein-coding genes that were also found in reference sequence PmP52Vac. Phylogenetic analysis revealed that Pm_P52VAc and P. multocida 'Soron' serovar B:2 were clustered in different clades. Pasteurella multocida 'Soron' serovar B:2 was found to cluster with the same ancestor of Pm70, which is of avian origin. The genome was found to contain regions that encode proteins which may confer resistance to various antibiotics including cephalosporin, which is used to treat pasteurellosis. The isolate was also found to harbour a phage region. This strain represents a novel multi-locus sequence type (MLST) that has not been previously identified, as all of the alleles used for MLST were found, but did not match any of the alleles in the database with 100% nucleotide identity. The most closely related ST was ST221. This is the first whole-genome sequence from P. multocida serovar B:2 of pig origin.

Homology modeling of LmxMPK4 of Leishmania mexicana and virtual screening of potent inhibitors against it.

Leishmaniasis is one of the most important diseases of mankind. In the life cycle of Leishmania mexicana, two most important developmental stages are observed. In insect vector it is in promastigote form and in mammalian macrophages is the amastigote form. The family of protein kinases are extremely important regulators of many different cellular processes such as transcriptional control, cell cycle development and differentiation, and also draw much attention as possible drug targets for protozaon parasites. Leishmania mexicana mitogen activated protein kinase 4 (LmxMPK4) is essential for proliferation and survival of the parasite promastigote and amastigote forms and is a potential drug target for leishmaniasis. The existing therapy for leishmaniasis is not enough due to host toxicity and drug resistance. The experimental 3D structure of this protein has not yet been determined. In this study, we have used homology modelling techniques to generate the 3D structure of LmxMPK4 and selected effective inhibitors by ZINC database on the basis of structure of berberine alkaloid for molecular docking studies with LmxMPK4. The inhibitors ZINC05999210, ZINC40402312 and ZINC40977377 were found to be more potent for inhibition of leishmaniasis due to the robust binding affinity and strong inhibition constant (Ki) of the protein-ligand interactions. This finding may help to understand the nature of MAP kinase and development of specific anti-leishmanial therapies.