Reviews

1. Pyroglutamic acid: Throwing light on a lightly studied metabolite, Current Science,102:288-297.

( Invited review in the special issue of Chemistry and Biology, celebtrations of year of chemistry),

2. Glutathione transporters, Biochim Biophysica Acta, 1830(5):3154-64.2013. ( Invited review in the special issue on Glutathione ).

    

Collaborators (former and present )

Dr. Serge Delrot

Dr Andree Bourbouloux

Dr Arunaloke Chakrabarti

Dr Susan Michaelis

Dr Philip Rea

Dr Michel Toledano

Dr Chris Junot

Dr Rupinder Kaur

Dr K Ganesan

Dr Asit Chakrabarti

Dr Joachim Morschausser

Dr CM Gupta

Dr Sagar Sengupta

Dr. Shantanu Sengupta

Dr MK Mathew

Dr Bruno Gassnier

      Glutathione, Sulphur and Redox are the key areas around which our lab interests are centred. The major question that we are asking is 'How is glutathione homeostasis maintained in living cells ?' Surrounding this major question are several other questions that become important for our understanding. The principal model systems that we use to address these questions are the yeasts Saccharomyces cerevisiae and Schizosaccharomyces pombe. Glutathione, γ-glutamyl cysteinyl glycine, an unusual thiol containing tripeptide that is present in high concentrations in almost all eukaryotic cells, plays multiple roles including protection from oxidative stress, maintenance of the cellular redox buffer, in mitochondrial iron-sulphur metabolism, in gene regulation, and in metal and drug detoxification. Glutathione metabolism is intimately linked to sulphur metabolism owing to the presence of the key cysteine residue, and we thus also investigate aspects of sulphur metabolism related to glutathione homeostasis. As the focus is on understanding how glutathione levels are maintained in the cell, we are examining different pathways that contribute towards this maintenance. This includes the high affinity plasma membrane transporter of glutathione that was identified in our lab, the classical and two recently discovered non-classical pathways of glutathione degradation (also discovered in our lab) biosynthesis, organellar compartmentalization and utilization of glutathione. We are attempting to not only understand these different pathways and their regulation in detail, but are interested in integrating these pathways and their regulation into a larger picture of glutathione homeostasis in living cells.