An effective method for saliva stabilization and magnetic nanoparticles based DNA extraction for genomic applications.

Introduction of magnetisable solid phase extraction procedures have provided various advantages over spin-column based extraction techniques. Although certain methods for magnetic bead based extraction of DNA from human saliva already exist, there is still a need to address the inadequate purity profile and low yield which occur due to the inefficiency of extraction methods. Hence, an improved method for DNA extraction from human saliva using uncoated magnetic nanoparticles (MNPs) intended to resolve the issues mentioned above is described here. The uncoated magnetic nanoparticles used in this study facilitate reversible binding of DNA and due to the absence of surface coating the particle size remains small thereby providing higher surface area to volume ratio for binding DNA. Another objective of this study was to develop a saliva preservation buffer (SPB) to solve the major challenges associated with storage and easy transportation of saliva sample at room temperature. Human saliva samples stored in the saliva preservation buffer were stable up to 160 days at room temperature without any bacterial or fungal growth and the quality of genomic DNA was intact.

Stilbenoid prenyltransferases define key steps in the diversification of peanut phytoalexins.

Defense responses of peanut (Arachis hypogaea) to biotic and abiotic stresses include the synthesis of prenylated stilbenoids. Members of this compound class show several protective activities in human disease studies, and the list of potential therapeutic targets continues to expand. Despite their medical and biological importance, the biosynthetic pathways of prenylated stilbenoids remain to be elucidated, and the genes encoding stilbenoid-specific prenyltransferases have yet to be identified in any plant species. In this study, we combined targeted transcriptomic and metabolomic analyses to discover prenyltransferase genes in elicitor-treated peanut hairy root cultures. Transcripts encoding five enzymes were identified, and two of these were functionally characterized in a transient expression system consisting of Agrobacterium-infiltrated leaves of Nicotiana benthamiana We observed that one of these prenyltransferases, AhR4DT-1, catalyzes a key reaction in the biosynthesis of prenylated stilbenoids, in which resveratrol is prenylated at its C-4 position to form arachidin-2, whereas another, AhR3'DT-1, added the prenyl group to C-3' of resveratrol. Each of these prenyltransferases was highly specific for stilbenoid substrates, and we confirmed their subcellular location in the plastid by fluorescence microscopy. Structural analysis of the prenylated stilbenoids suggested that these two prenyltransferase activities represent the first committed steps in the biosynthesis of a large number of prenylated stilbenoids and their derivatives in peanut. In summary, we have identified five candidate prenyltransferases in peanut and confirmed that two of them are stilbenoid-specific, advancing our understanding of this specialized enzyme family and shedding critical light onto the biosynthesis of bioactive stilbenoids.