[
Life Sci,
2019]
AIM: In the current scenario of ethical issues related to animal usage in research, the present study was intended to explore the proficient utility of nematode, Caenorhabditis elegans as wound model in preliminary screening of wound healing therapeutics. MAIN METHODS: In this study, a new wounding protocol and quantitative assessment strategies for various healing parameters [survival, Reactive Oxygen Species (ROS), calcium signals, F-actin dynamics, new collagen synthesis and wound induced anti-microbial peptides] were developed and used for preliminary screening of wound healing actives from natural sources. Wound healing ability of positive lead Tridax procumbens (TP) and its major phytocompounds [Octa decenoic acid (ODA), Pyridine carboxamide oxime, known as Nicotinamide (NA) and Dimethyl Benz[c]acridine (DMB)] were assessed using C. elegans wound model and cell lines scratch wound healing assay. Mode of action of active lead was elucidated using metabolome analysis coupled with MALDI-MS followed by molecular docking. KEY FINDINGS: From the four tested methanolic extracts, TP was chosen as positive lead compared to control, Benzalkonium chloride (BKC) based on survival and new collagen synthesis analyses. Results indicated that the wound healing ability of TP was majorly contributed by NA. Further, it was found that NA acts in chloromethyl nicotinamide derivative form by interacting with the known wound healing biomarker, glycogen synthase kinase 3 (GSK-3) to exert wound healing ability. SIGNIFICANCE: The study evidenced that C. elegans, could be a reliable wound model for high-throughput screening of wound healing actives and to identify their possible mode of action.
[
J Chromatogr A,
2000]
Frontal affinity chromatography is a method for quantitative analysis of biomolecular interactions. We reinforced it by incorporating various merits of a contemporary liquid chromatography system. As a model study, the interaction between an immobilized Caenorhabditis elegans galectin (LEC-6) and fluorescently labeled oligosaccharides (pyridylaminated sugars) was analyzed. LEC-6 was coupled to N-hydroxysuccinimide-activated Sepharose 4 Fast Flow (100 microm diameter), and packed into a miniature column (e.g., 10 x 4.0 mm, 0.126 ml). Twelve pyridylaminated oligosaccharides were applied to the column through a 2-ml sample loop, and their elution patterns were monitored by fluorescence. The volume of the elution front (V) determined graphically for each sample was compared with that obtained in the presence of an excess amount of hapten saccharide, lactose (V0); and the dissociation constant, Kd, was calculated according to the literature [K. Kasai, Y. Oda, M. Nishikawa, S. Ishii, J. Chromatogr. 376 (1986) 33]. This system also proved to be useful for an inverse confirmation; that is, application of galectins to an immobilized glycan column (in the present case, asialofetuin was immobilized on Sepharose 4 Fast Flow), and the elution profiles were monitored by fluorescence based on tryptophan. The relative affinity of various galectins for asialofetuin could be easily compared in terms of the extent of retardation. The newly constructed system proved to be extremely versatile. It enabled rapid (analysis time 12 min/cycle) and sensitive (20 nM for pyridylaminated derivatives, and 1 microg/ml for protein) analyses of lectin-carbohydrate interactions. It should become a powerful tool for elucidation of biomolecular interactions, in particular for functional analysis of a large number of proteins that should be the essential issues of post-genome projects.