ABSTRACT:Reactive intermediates are a continuous burden in biology and several defense mechanisms have evolved. Here we focus on the functions of glutathione transferases (GSTs) with the aim to discuss the quantitative aspects of defense against reactive intermediates. Humans excrete approximately 0.1 mmol of thioether conjugates per day. As the amount of GST active sites in liver is Ϸ0.5 mmol, it appears that glutathione transferase catalysts are present in tremendous excess. In fact, the known catalytic properties of GSTs reveal that the enzymes can empty the liver glutathione (GSH) pool in a matter of seconds when provided with a suitable substrate. However, based on the urinary output of conjugates (or derivatives thereof), individual GSTs turn over (i.e., catalyze a single reaction) only once every few days. Glutathione transferase overcapacity reflects the fact that there is a linear relation between GST enzyme amount and protection level (provided that GSH is not depleted). Put in a different perspective, a few reactive molecules will always escape conjugation and reach cellular targets. It is therefore not surprising that signaling systems sensing reactive intermediates have evolved resulting in the increase of GSH and GST levels. Precisely for this reason, more moderately reactive electrophiles (Michael acceptors) are receiving growing interest due to their anticarcinogenic properties. Another putative regulatory mechanism involves direct activation of microsomal GST1 by thiol-reactive electrophiles through cysteine 49. The toxicological significance of low levels of reactive intermediates are of interest also in drug development, and here we discuss the use of microsomal GST1 activation as a surrogate detection marker.
Glutathione transferases (GSTs) are often upregulated in tumors and have been suggested to play an important role in multiple drug resistance in cancer chemotherapy. As a consequence GST-dependent pro-drugs and inhibitors are being developed. Little is known, however, on the potential role of membrane-bound GSTs in drug resistance despite the fact that detoxication of cytostatic drugs and upregulation in tumors has been demonstrated. Therefore, we have studied the involvement of membrane-bound microsomal GST1 (MGST1) in cellular resistance to anticancer drugs. As a tool we have developed a cell system utilizing MCF7 cells stably overexpressing MGST1. Here, we show for the first time that MGST1 can protect cells from several cytostatic drugs, chlorambucil, melphalan and cisplatin in an acute toxicity test (MTT assay) as well as a long-term colony forming efficiency cytotoxicity test. It is of note that these cells do not overexpress multidrug transporters, a prerequisite for protection with certain other GSTs investigated in this system. The cytostatic drugs used comprise both those that are known/predicted to be substrates as well as non-substrates. Thus, the mechanism most probably entails both direct detoxication and downstream protection of the cells from oxidative stress.
We report on a newborn with severe psychomotor retardation, minor anomalies, congenital heart defects, thumb and urogenital abnormalities. Cytogenetic analysis showed a 4q24qter duplication, never described before, as the result of a de novo t(4;14). The extension of the duplicated 4q region was defined by FISH using YAC probes. The breakpoint was localized between 106.3cM (YAC 800f2, D4S1572) and 111 cM (YAC 744e4, D4S1564). Comparing our patient with those previously reported in literature, we observed some features mature frequently reported in these patients: psychomotor retardation, retromicrognathia, low set and/or malformed ears and some more specific traits: congenital cardiac defects, hypoplastic thumb and urogenital abnormalities.
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