Virtual screening of p53 mutants reveals Y220S as an additional rescue drug target for PhiKan083 with higher binding characteristics.

Pharmacological intervention to reactivate p53 in human tumors holds great promise for cancer patients. A number of small molecules that reactivate p53 mutants that are either specific to certain mutation or more broadly on various mutants of p53 are discovered by rational design and screening methods. One of the most remarkable among small molecules for the rescue of specific mutant p53, Y220C is PhiKan083 (1-(9-ethyl-9H-carbazole-3-yl)-N-methylmethanamine) that have been demonstrated effective in advanced pre-clinical trials. Our attempt here is to identify additional targets of p53 mutants for rescue drugs and provide insight into the molecular level interactions of the drug with the mutant target. In this study PhiKan083 also known as PK083 is investigated, screened and validated on 28 different mutants of p53 using FlexX. Interaction of PhiKan08 with Y220C is found to be largely hydrophobic and a crucial single H-bond interaction with Asp228 in addition to few electrostatic interactions. Our study identified Y220S mutant as an additional target for PK083 as it shows a similar interaction pattern. Besides this, Docking and MD simulation studies, showed that Y220S binds to PK083 at higher efficiency as a result of improved steric and hydrophobic environment in the binding cavity in comparison with known mutant target, Y220C. Further, we point out that structure guided optimization of PhiKan08 can lead to an improved drug that can interact favourably with yet another mutant, Y220 N. In addition, this study revealed that Y220H and other mutants including native p53 does not provide any favourable interaction with PhiKan08 which is in accord with the experimental findings. These findings can facilitate the selection of patients for clinical studies and cancer survival analysis.

NIH-3T3 fibroblast transplants enhance host regeneration and improve spatial learning in ventral subicular lesioned rats.

Transplants, besides providing neural replacement, also stimulate host regeneration, which could serve as a powerful means to establish functional recovery in CNS insults. Earlier, we have reported the H3-GFP transplant mediated recovery of cognitive functions in the ventral subicular lesioned rats. In the present study, we demonstrate the efficacy of a non-neural fibroblast transplants in mediating host regeneration and functional recovery in ventral subicular lesioned rats. Adult male Wistar rats were lesioned with ibotenic acid in the ventral subiculum (VSL) and were transplanted with NIH-3T3 fibroblast cells into CA1 region of the hippocampus. Ventral subicular lesioning impaired the spatial task performances in rats and produced considerable degree of dendritic atrophy of the hippocampal pyramidal neurons. Two months following transplantation, the transplants were seen in the dentate gyrus and expressed BDNF and bFGF. Further, the VSL rats with fibroblast transplants showed enhanced expression of BDNF in the hippocampus and enhanced dendritic branching and increased spine density in the CA1 hippocampal pyramidal neurons. Transplantation of fibroblast cells also helped to establish functional recovery and the rats with transplants showed enhanced spatial learning performances. We attribute the recovery of cognitive functions to the graft mediated host regeneration, although the mechanisms of functional recovery remain to be elucidated.

Transplantation of hippocampal cell lines restore spatial learning in rats with ventral subicular lesions.

We have demonstrated in our previous studies that ventral subicular lesion induces neurodegeneration of the hippocampus and produces cognitive impairment in rats. In the present study, the efficacy of transplanted green fluorescent protein (GFP)-labeled hippocampal cell line (H3-GFP) cells in establishing functional recovery in ventral subicular lesioned rats has been evaluated. The survival of H3-GFP transplants and their ability to express trophic factors in vivo were also investigated. Adult male Wistar rats were subjected to selective lesioning of ventral subiculum and were transplanted with H3-GFP cells into the cornu ammonis 1 (CA1) hippocampus. The transplants settled mainly in the dentate gyrus and expressed neurotrophic factors, brain-derived neurotrophic factor (BDNF), and basic fibroblast growth factor (bFGF). The ventral subicular lesioned (VSL) rats with H3-GFP transplants showed enhanced expression of BDNF in the hippocampus and performed well in eight-arm radial maze and Morris water maze tasks. The VSL rats without hippocampal transplants continued to show cognitive impairment in task learning. The present study demonstrated the H3-GFP transplants mediated recovery of cognitive functions in VSL rats. Our study supports the notion of graft meditated host regeneration and functional recovery through trophic support, although these mechanisms require further investigation.

Juvenile hormone accelerates ovarian development and does not affect age polyethism in the primitively eusocial wasp, Ropalidia marginata.

Juvenile hormone modulates post-imaginal reproductive division of labor in primitively eusocial species and promotes the production of queens (e.g., Polistes) while it modulates age polyethism and promotes the production of foragers in highly eusocial species (e.g., the honey bee). Ropalidia marginata is a primitively eusocial wasp that shows both post-imaginal regulation of reproductive division of labor as well as age polyethism. Hence, R.marginata is a particularly interesting model system to study the effect of juvenile hormone. We demonstrate here that a single, topical application of 100 micro g of juvenile hormone-III per female wasp accelerates ovarian development of wasps held in isolation. Similar application to wasps released back on to their natal nests has no effect on their rate of behavioral development as witnessed from the age of first performance of feed larva, build, bring pulp and bring food. We conclude therefore that in R.marginata, juvenile hormone has retained its function of modulating reproductive division of labor and has not acquired the function of modulating age polyethism.