Comprehensive analyses of genomes, transcriptomes and metabolites of neem tree

Neem (Azadirachta indica A. Juss) is one of the most versatile tropical evergreen tree species known in India since the Vedic period (1500 BC–600 BC). Neem tree is a rich source of limonoids, having a wide spectrum of activity against insect pests and microbial pathogens. Complex tetranortriterpenoids such as azadirachtin, salanin and nimbin are the major active principles isolated from neem seed. Absolutely nothing is known about the biochemical pathways of these metabolites in neem tree. To identify genes and pathways in neem, we sequenced neem genomes and transcriptomes using next generation sequencing technologies. Assembly of Illumina and 454 sequencing reads resulted in 267 Mb, which accounts for 70% of estimated size of neem genome. We predicted 44,495 genes in the neem genome, of which 32,278 genes were expressed in neem tissues. Neem genome consists about 32.5% (87 Mb) of repetitive DNA elements. Neem tree is phylogenetically related to citrus, Citrus sinensis. Comparative analysis anchored 62% (161 Mb) of assembled neem genomic contigs onto citrus chromomes. Ultrahigh performance liquid chromatography-mass spectrometry-selected reaction monitoring (UHPLC-MS/SRM) method was used to quantify azadirachtin, nimbin, and salanin from neem tissues. Weighted Correlation Network Analysis (WCGNA) of expressed genes and metabolites resulted in identification of possible candidate genes involved in azadirachtin biosynthesis pathway. This study provides genomic, transcriptomic and quantity of top three neem metabolites resource, which will accelerate basic research in neem to understand biochemical pathways

Effect of organogel components on in vitro nasal delivery of propranolol hydrochloride

The purpose of this research was to evaluate in vitro transnasal sustained-release ability of sorbitan monostearate (SMS) organogels in isopropyl myristate (IM). Organogels were prepared containing SMS (2.5%–20%) and water (5%–25%) in IM and analyzed microscopically for phase behavior. The effect of Tween surfactants on gel strength and in vitro nasal diffusion of propranolol is reported. The in vitro nasal release retardant effect of SMS and Tween 20 was investigated using factorial design. The microscopic changes in structure of organogel during in vitro nasal diffusion were studied. The water-holding capacity of SMS organogels in IM increased with SMS concentration. The release retardant effect with incorportation of cosurfactant was of the order of Tween 80> Tween 60> Tween 20. Gel strengthening and increased viscosity were evident with increased concentration of SMS and Tween 20. The 3-dimensional network of SMS molecules controls the diffusional drug release. The organogel system on nasal mucosa during diffusion is dynamic in nature and changes continuously with the time of diffusion. The water penetration in the organogel network results in percolation and emulsification of organogel, thus affecting the release. Organogels provided an effective barrier for diffusion of propranolol. The surface epithelium lining and the granular cellular structure of treated nasal mucosa were intact