Biological activities of three medicinal plants from district Mirpur, AJK, Pakistan.

Present research work was aimed to investigate the biological activities i.e. antibacterial, antifungal, antioxidant, cytotoxic and antitumor activities of crude methanolic extract of Anagallis arvensis L., Butea monosperma (Lam.) Kuntze and Coronopus didymus (L.) Pers. against Gram positive strains (Bacillus subtilis, Staphylococcus aureus) and gram negative strains (Vibrio cholera, Enterobacter aerogenes, Klebsiella pneumonia, Agrobacterium tumefaciens, Escherichia coli) were screened. Best activity was observed against K. pneumonia and S. aureus by A. arvensis compared with other strains. Butea monosperma exhibited considerable activity against S. aureus, V. cholera, E. aerogenes and K. pneumonia compared with other strains. Methanolic extract of A. arvensis L. inhibited fungal growth against A. niger up to 30.2%. B. monosperma inhibited the growth of A. niger up to 43.5% and against A. fumigatus 27.3%. C. didymus inhibited the A. fumigates up to 27.3% and against A. niger, it inhibited 48%. Brine shrimps lethality bioassay was used to evaluate the cytotoxic activity and LD50 value was calculated by using probit analysis. Potato disc bioassay was designed to screen antitumor activity and data was analyzed by one way ANOVA.

Evolutionary origins of a novel host plant detoxification gene in butterflies.

Chemical interactions between plants and their insect herbivores provide an excellent opportunity to study the evolution of species interactions on a molecular level. Here, we investigate the molecular evolutionary events that gave rise to a novel detoxifying enzyme (nitrile-specifier protein [NSP]) in the butterfly family Pieridae, previously identified as a coevolutionary key innovation. By generating and sequencing expressed sequence tags, genomic libraries, and screening databases we found NSP to be a member of an insect-specific gene family, which we characterized and named the NSP-like gene family. Members consist of variable tandem repeats, are gut expressed, and are found across Insecta evolving in a dynamic, ongoing birth-death process. In the Lepidoptera, multiple copies of single-domain major allergen genes are present and originate via tandem duplications. Multiple domain genes are found solely within the brassicaceous-feeding Pieridae butterflies, one of them being NSP and another called major allergen (MA). Analyses suggest that NSP and its paralog MA have a unique single-domain evolutionary origin, being formed by intragenic domain duplication followed by tandem whole-gene duplication. Duplicates subsequently experienced a period of relaxed constraint followed by an increase in constraint, perhaps after neofunctionalization. NSP and its ortholog MA are still experiencing high rates of change, reflecting a dynamic evolution consistent with the known role of NSP in plant-insect interactions. Our results provide direct evidence to the hypothesis that gene duplication is one of the driving forces for speciation and adaptation, showing that both within- and whole-gene tandem duplications are a powerful force underlying evolutionary adaptation.