The phosphorylation of Metaxin 1 controls Bak activation during TNFα induced cell death.

The proapoptotic protein Bak is implicated in the execution phase of apoptosis, a cell death program. Bak is essentially mitochondrial and during early steps of apoptosis undergoes conformational changes that lead to its full membrane integration in mitochondria and the subsequent liberation of pro-apoptotic mitochondrial proteins. Little is known about the partners and mechanisms implicated in the activation of Bak. We have recently shown that Bak is incorporated into a Voltage dependent anionic channel of type 2 (VDAC2)/Metaxin 1(Mtx1)/Metaxin 2 (Mtx2) multi-protein complex in both resting and dying cells. Here, we show that, after the induction of apoptosis, Bak switches from its association with Mtx2 and VDAC2 to a closer association with Mtx1. This change of partners is under the control of a tyrosine phosphorylation of Mtx1 by c-Abl.

Metaxins 1 and 2, two proteins of the mitochondrial protein sorting and assembly machinery, are essential for Bak activation during TNF alpha triggered apoptosis.

The proteins Bax and Bak are central in the execution phase of apoptosis; however, little is known about the partners involved in the control of this complex process. Here, we show that mitochondrial Bak is incorporated into a VDAC2/Mtx1/Mtx2 multi-protein complex in both resting and dying cells. VDAC2 is a porin that has previously been described as a partner of Bak while Mtx1 and Mtx2 are two proteins of the mitochondrial sorting and assembly machinery (SAM) that have been implicated in TNF-induced apoptosis. We show that, after the induction of apoptosis, Bak switches from its association with Mtx2 and VDAC2 to interact with Mtx1.

Glutathione transferases kappa 1 and kappa 2 localize in peroxisomes and mitochondria, respectively, and are involved in lipid metabolism and respiration in Caenorhabditis elegans.

To elucidate the function of kappa class glutathione transferases (GSTs) in multicellular organisms, their expression and silencing were investigated in Caenorhabditis elegans. In contrast with most vertebrates, which possess only one GST kappa gene, two distinct genes encoding GSTK-1 and GSTK-2 are present in the C. elegans genome. The amino acid sequences of GSTK-1 and GSTK-2 share around 30% similarity with the human hGSTK1 sequence and, like the human transferase, GSTK-1 contains a C-terminal peroxisomal targeting sequence. gstk-1 and gstk-2 genes show distinct developmental and tissue expression patterns. We show that GSTK-2 is localized in the mitochondria and expressed mainly in the pharynx, muscles and epidermis, whereas GSTK-1 is restricted to peroxisomes and expressed in the intestine, body wall muscles and epidermis. In order to determine the potential role(s) of GST kappa genes in C. elegans, specific silencing of the gstk-1 and gstk-2 genes was performed by an RNA interference approach. Knockdown of gstk-1 or gstk-2 had no apparent effect on C. elegans reproduction, development, locomotion or lifespan. By contrast, when biological functions (oxygen consumption and lipid metabolism) related to peroxisomes and/or mitochondria were investigated, we observed a significant decrease in respiration rate and a lower concentration of the monounsaturated fatty acid cis-vaccenic acid (18:1omega7) when worms were fed on bacteria expressing RNA interference targeting both gstk-1 and gstk-2. These results demonstrate that GST kappa, although not essential for the worm's life, may be involved in energetic and lipid metabolism, two functions related to mitochondria and peroxisomes.

The mitochondrial outer membrane protein import machinery: a new player in apoptosis?

The proteins of the BCL-2 family (pBCL-2s) are involved in the sequence of events that culminates in apoptosis, a type I cell death program. The mitochondrion is the primary site of action of pBCL-2s and represents the cross roads between the initiation and the execution phases of apoptosis. pBCL-2s are either constitutively associated with the mitochondria outer membrane (MOM) or targeted to this membrane at the onset of apoptosis. The mechanisms implicated in their targeting and activation during apoptosis is largely unknown. Recently, several pBCL-2s have been shown to interact with components of the translocase of the outer membrane (TOM), a complex responsible for the import into and across the MOM of nuclear encoded mitochondrial proteins. Here we will review the available data and discuss the possible implications of this interaction in the apoptotic programme.

Differential toxic effects of azathioprine, 6-mercaptopurine and 6-thioguanine on human hepatocytes.

Thiopurines (azathioprine, 6-mercaptopurine and 6-thioguanine) are therapeutic compounds widely administered in the clinic for their multiple uses (autoimmune diseases, post-transplant immunosuppression and cancer). Despite these advantages, their therapeutic potential is limited by occasional adverse effects (myelotoxicity and hepatotoxicity) and by a relatively frequent lack of efficacy. Previous studies have demonstrated that azathioprine decreased the viability of rat hepatocytes. In order to investigate cytotoxic effects of thiopurines in human liver, we used primary human hepatocytes and a highly differentiated human hepatoma cell line, HepaRG, treated or not with azathioprine, 6-mercaptopurine and 6-thioguanine. In parallel, expression of the genes involved in the metabolism of thiopurines, glutathione synthesis and antioxidant defences was measured by quantitative PCR. We clearly demonstrate that human liver parenchymal cells were much less sensitive than rat hepatocytes to thiopurine treatments. The toxic effects appeared after 96 h of treatment while ATP depletion was observed after a 24 h incubation with azathioprine and 6-mercaptopurine. Toxic effects were more pronounced for azathioprine and 6-mercaptopurine, when compared to 6-thioguanine, and might explain glutathione synthesis and antioxidant enzyme induction only by these two drugs. Finally, we also demonstrate for the first time an up-regulation by azathioprine and 6-mercaptopurine of inosine monophosphate dehydrogenase which might have consequences on the de novo biosynthesis of guanine nucleotides and thiopurines metabolism.

Oltipraz regulates different categories of genes relevant to chemoprevention in human hepatocytes.

Numerous chemical compounds are cytotoxic or carcinogenic to human beings and attention is now focusing on preventative strategies. One agent, oltipraz (OPZ), regarded as one of the most promising chemoprotectors, has been shown to be a potent inducer of phase II enzymes involved in the detoxification of carcinogens, including aflatoxins. However, little is known about its effects on global gene expression in human cells. Thus, we used microarrays and reverse transcription-quantitative polymerase chain reaction to test the effects of OPZ on the overall pattern of mRNA expression of multiple metabolic pathways in human hepatocytes in primary culture. Our results show for the first time that OPZ significantly alters the expression of human genes within different functional categories (detoxification of xenobiotics, antioxidant defences, xenobiotic transport, cell cycle and stress responses), at both the mRNA and protein levels, some of which are highly relevant to chemoprevention. Amongst these genes, several have never been described as being regulated by OPZ before. We also demonstrate variations in response to OPZ, depending on the individual from whom the cells were derived, that might potentially contribute to differences in efficacy of chemopreventive treatments between individuals. Moreover, comparison of our results with those obtained in rodents demonstrates species differences in response to OPZ for some genes, underlying the importance of studies on human cells to predict the effects of chemopreventive agents.

Gene and protein characterization of the human glutathione S-transferase kappa and evidence for a peroxisomal localization.

Kappa class glutathione S-transferase (GST) cDNA sequences have been identified in rat, mouse, and human. In the present study, we determined the structure and chromosomal location of the human GST Kappa 1 (hGSTK1) gene, characterized the protein, and demonstrated its subcellular localization. The human gene spans approximately 5 kb, has 8 exons, and maps onto chromosome 7q34. The 5'-flanking region lacks TATA or CCAAT boxes, but there is an initiator element overlapping the transcription start site. hGSTK1 amino acid sequence showed homology to bacterial 2-hydroxychromene-2-carboxylate isomerase, an enzyme involved in naphthalene degradation pathway. hGSTK1 mRNA was expressed in all of the organs examined. Subcellular fractionation of HepG2 cells showed that the protein was located in peroxisomes and mitochondria and was not detectable in cytoplasm. The peroxisomal localization was confirmed by transfection of HepG2 cells with a plasmid coding a green fluorescent protein fused inframe to the N terminus of hGSTK1. The C terminus of hGSTK1 was essential for localization of the protein to peroxisomes, and the C-terminal sequence Ala-Arg-Leu represents a peroxisome targeting signal. This is the first time that a human GST has been found in peroxisomes, suggesting a new function for this family of enzymes.