Recent developments in CCR5 regulation for HIV cure.

Acquired immunodeficiency syndrome (AIDS) has affected millions of people worldwide. The human immunodeficiency virus (HIV) which infects T cells by using CD4 as its main receptor. Currently different treatments are available against HIV infection which can improve life expectancy of the patient but still it remains incurable. CCR5, which is also required as a co-receptor by majority of HIV strains for entry into the target cells, is now being targeted for gene therapy to develop HIV resistance in patients. In this review, we discuss different strategies that are being adapted for CCR5-gene disruption in CD4+ T cells and in hematopoietic stem cells (HSCs) to generate a HIV-resistant immune system in infected individuals. If CCR5 gene that can shape HIV-resistant T cells, it will aim in new approaches in clinical trials. But these techniques have certain weaknesses and disadvantages, and will need to be paired with other strategies to form a full HIV remedy. There is also a need to establish methods to help deter HIV re-emergence following targeted CCR5 therapy. But ultimately, this brought us a better knowledge of the road to HIV treatment.

Metabolism of cisplatin in the organs of Rattus norvegicus: role of Glutathione S-transferase P1.

Glutathione S-transferases (GSTs) play an important role in the biotransformation of endogenous compounds and xenobiotics as well as in the metabolic inactivation of pharmacologically active substances, including anticancer drugs. Using cisplatin as the prototype drug, we investigated if any correlation exists between GSH levels, GSTs/GSTP1 activity and the fate of cisplatin in different organs of Rattus norvegicus. GSH-cisplatin complex was prepared, purified by anion-exchange chromatography and subjected to mass spectroscopic analysis which confirmed the structure to be diglutathione-monoplatinum (diglutathionylplatinum). Purified diglutathionylplatinum was used to quantify metabolite formed in different tissue homogenates. Specific GSTP1 activity was found to be highest in kidneys, which correlated positively with the levels of metabolite formed in renal tissues. Altogether, our results showed that cisplatin metabolism in different organs of rats correlated positively with specific GSTP1 activities and this enzyme may be a critical determinant of extent of cellular uptake or retention of cisplatin in renal and liver tissues.