The fourth isoform of the adenine nucleotide translocator inhibits mitochondrial apoptosis in cancer cells.

The adenine nucleotide translocator (ANT) is a mitochondrial bi-functional protein, which catalyzes the exchange of ADP and ATP between cytosol and mitochondria and participates in many models of mitochondrial apoptosis. The human adenine nucleotide translocator sub-family is composed of four isoforms, namely ANT1-4, encoded by four nuclear genes, whose expression is highly regulated. Previous studies have revealed that ANT1 and 3 induce mitochondrial apoptosis, whereas ANT2 is anti-apoptotic. However, the role of the recently identified isoform ANT4 in the apoptotic pathway has not yet been elucidated. Here, we investigated the effects of stable heterologous expression of the ANT4 on proliferation, mitochondrial respiration and cell death in human cancer cells, using ANT3 as a control of pro-apoptotic isoform. As expected, ANT3 enhanced mitochondria-mediated apoptosis in response to lonidamine, a mitochondriotoxic chemotherapeutic drug, and staurosporine, a protein kinase inhibitor. Our results also indicate that the pro-apoptotic effect of ANT3 was accompanied by decreased rate of cell proliferation, alteration in the mitochondrial network topology, and decreased reactive oxygen species production. Of note, we demonstrate for the first time that ANT4 enhanced cell growth without impacting mitochondrial network or respiration. Moreover, ANT4 differentially regulated the intracellular levels of hydrogen peroxide without affecting superoxide anion levels. Finally, stable ANT4 overexpression protected cancer cells from lonidamine and staurosporine apoptosis in a manner independent of Bcl-2 expression. These data highlight a hitherto undefined cytoprotective activity of ANT4, and provide a novel dichotomy in the human ANT isoform sub-family with ANT1 and 3 isoforms functioning as pro-apoptotic while ANT2 and 4 isoforms render cells resistant to death inducing stimuli.

Overexpression of adenine nucleotide translocase reduces Ca2+ signal transmission between the ER and mitochondria.

The adenine nucleotide translocase (ANT), besides transferring ATP from the mitochondrial matrix to the rest of the cell, has also been proposed to be involved in mitochondrial permeability transition (MPT), and accordingly in mitochondrial Ca2+ homeostasis. In order to assess the role of ANT in Ca2+ signal transmission from the endoplasmic reticulum (ER) to mitochondria, we overexpressed the various ANT isoforms and measured the matrix [Ca2+] ([Ca2+]m) increases evoked by stimulation with IP3-dependent agonists. ANT overexpression reduced the amplitude of the [Ca2+]m peak following Ca2+ release, an effect that was markedly greater for ANT-1 and ANT-3 isoforms than for ANT-2. Three further observations might explain these findings. First, the effect was partially reversed by treating the cells with cyclosporine A, suggesting the involvement of MPT. Second, the effect was paralleled by alterations of the 3D structure of the mitochondria. Finally, ANT-1 and ANT-3 overexpression also caused a reduction of ER Ca2+ loading that caused a marginal decrease in the cytosolic Ca2+ responses. Overall, these data provide evidence for the involvement of ANT-1 and ANT-3 in the induction of MPT and indicate the relevance of this phenomenon in ER-mitochondria Ca2+ transfer.

IL-4-induced upregulation of adenine nucleotide translocase 3 and its role in Th cell survival from apoptosis.

We have identified mitochondrial adenine nucleotide translocase (ANT)3 as a novel target up-regulated by IL-4 in human T cells. The IL-4-induced ANT3 expression is dependent on tyrosine kinase, NF-kappaB, PI3K/Akt, and Erk pathways. In fact, IL-4 induced specific activation of NF-kappaB, Akt, and Erk in Jurkat T cells and partially rescued these cells from dexamethasone-induced apoptosis. The IL-4-mediated T cell survival was blocked by inhibitors of tyrosine kinase, NF-kappaB, PI3K/Akt, and Erk. During the IL-4-induced T cell rescue, there was a concomitant increase in ANT3, nuclear NF-kappaB, and Bcl-2 and a decrease in ANT1, I-kappaB, and mitochondrial Bax-alpha levels. Importantly, overexpression of ANT3 effectively protected T cells from dexamethasone-induced apoptosis, while forced expression of ANT1 caused apoptosis. In contrast, siRNA knock-out of ANT3 expression induced T cell apoptosis and blocked the IL-4-mediated cell survival. Together these results suggest that ANT3 has a potential role in Th cell survival and immune cell homeostasis.

The human mitochondrial ADP/ATP carriers: kinetic properties and biogenesis of wild-type and mutant proteins in the yeast S. cerevisiae.

The mitochondrial adenine nucleotide carrier, or Ancp, plays a key role in the maintenance of the energetic fluxes in eukaryotic cells. Human disorders have been found associated to unusual human ANC gene (HANC) expression but also to direct inactivation of the protein, either by autoantibody binding or by mutation. However, the individual biochemical properties of the three HAncp isoforms have not yet been deciphered. To do so, the three HANC ORF were expressed in yeast under the control of the regulatory sequences of ScANC2. Each of the three HANC was able to restore growth on a nonfermentable carbon source of a yeast mutant strain lacking its three endogenous ANC. Their ADP/ATP exchange properties could then be measured for the first time in isolated mitochondria. HANC3 was the most efficient to restore yeast growth, and HAnc3p presented the highest V(M) (80 nmol ADP min(-1) mg protein(-1)) and K(ADP)(M)(8.4 microM). HAnc1p and HAnc2p presented similar kinetic constants (V(M) approximately 30-40 nmol ADP min(-(1) mg protein(-1) and K(ADP)(M) approximately 2.5-3.7 microM), whose values were consistent with HANC1's and HANC2's lower capacity to restore yeast growth. However, the HANC genes restored growth at a lower level than ScANC2, indicating that HAncp amount may be limiting in vivo. To optimize the HAncp production, we investigated their biogenesis into mitochondria by mutagenesis of two charged amino acids in the N-terminus of HAnc1p. Severe effects were observed with the D3A and D3K mutations that precluded yeast growth. On the contrary, the K10A mutation increased yeast growth complementation and nucleotide exchange rate as compared to the wild type. These results point to the importance of the N-terminal region of HAnc1p for its biogenesis and transport activity in yeast mitochondria.