ATB 0,ϩ (amino acid transporter responsible for the activity of system B 0,ϩ ) was named "B 0,ϩ " to indicate its broad substrate selectivity (denoted by "B"), accepting neutral (denoted by "0") and cationic (denoted by "ϩ") amino acids as substrates (1, 2). Its transport function is coupled to a Na ϩ gradient, a Cl Ϫ gradient, and membrane potential. ATB 0,ϩ is identified as SLC6A14 according to the Human Genome Organization nomenclature. This transporter has potential for delivery of a wide variety of drugs and prodrugs into cells (3-7). The substrate selectivity of SLC6A14 is interesting (1, 2). It transports all essential amino acids. The only excluded amino acids are glutamate and aspartate, which are nonessential. It also transports glutamine (an important precursor for nucleotide synthesis) and arginine (an amino acid essential for tumor growth). However, the transporter is expressed only at low levels in normal tissues. Tumor cells have an increased requirement for essential amino acids as well as glutamine and arginine to support their rapid growth. Essential amino acids are obligatory for protein synthesis. Leucine, an essential amino acid, is also a potent activator of mTOR (mammalian target of rapamycin) (8). Certain tumor cells metabolize glutamine at a rate far exceeding the requirement for protein and nucleotide synthesis, a phenomenon known as "glutamine addiction" (9 -11). Glutamine metabolism through a set of biochemical reactions called "glutaminolysis" provides a carbon source for tumor cells, thereby sparing glucose-derived carbon for the synthesis of lipids and other essential biomolecules. Arginine is essential for several types of cancer due to lack of the arginine-synthesizing enzyme argininosuccinate synthetase (12, 13). On the basis of these findings, we hypothesized that the expression of SLC6A14 may be up-regulated in cancer to meet the increasing demand for all essential amino acids as well as glutamine and arginine. In support of this hypothesis, past studies from our laboratory have shown that SLC6A14 is up-regulated in colon cancer (14) and cervical cancer (15). The transporter is also up-regulated in breast cancer cell lines, but interestingly only in estrogen receptor (ER) 2 -positive cell lines (16). Furthermore, we showed that blockade of SLC6A14 in ER-positive breast cancer cells by treatment with a selective blocker (␣-methyl-DLtryptophan (␣-MT)) starved the cells of glutamine, arginine, and essential amino acids, decreased cell proliferation, and caused apoptotic cell death (16). In the present study, we investigated the expression of SLC6A14 in primary breast cancer * This work was supported, in whole or in part, by National Institutes of Health Grant CA152396. 1 To whom correspondence should be addressed. E-mail: vganapat@ georgiahealth.edu.2 The abbreviations used are: ER, estrogen receptor; ␣-MT, ␣-methyl-DL-tryptophan; CHOP, CCAAT/enhancer-binding protein homologous protein; 3-MA, 3-methyladenine.
ATB(0,+) [SLC6A14 (solute carrier family 6 member 14)] is an Na(+)/Cl(-)-coupled amino acid transporter whose expression is upregulated in cancer. 1-Methyltryptophan is an inducer of immune surveillance against tumour cells through its ability to inhibit indoleamine dioxygenase. In the present study, we investigated the role of ATB(0,+) in the uptake of 1-methyltryptophan as a potential mechanism for entry of this putative anticancer drug into tumour cells. These studies show that 1-methyltryptophan is a transportable substrate for ATB(0,+). The transport process is Na(+)/Cl(-)-dependent with an Na(+)/Cl(-)/1-methyltryptophan stoichiometry of 2:1:1. Evaluation of other derivatives of tryptophan has led to identification of alpha-methyltryptophan as a blocker, not a transportable substrate, for ATB(0,+). ATB(0,+) can transport 18 of the 20 proteinogenic amino acids. alpha-Methyltryptophan blocks the transport function of ATB(0,+) with an IC(50) value of approximately 250 muM under conditions simulating normal plasma concentrations of all these 18 amino acids. These results suggest that alpha-methyltryptophan may induce amino acid deprivation in cells which depend on the transporter for their amino acid nutrition. Screening of several mammary epithelial cell lines shows that ATB(0,+) is expressed robustly in some cancer cell lines, but not in all; in contrast, non-malignant cell lines do not express the transporter. Treatment of ATB(0,+)-positive tumour cells with alpha-methyltryptophan leads to suppression of their colony-forming ability, whereas ATB(0,+)-negative cell lines are not affected. The blockade of ATB(0,+) in these cells with alpha-methyltryptophan is associated with cell cycle arrest. These studies reveal the potential of ATB(0,+) as a drug target for cancer chemotherapy.
Background:The Beclin 1-Vps34 protein-protein interaction network is critical for autophagy regulation. Results: Nrbf2 is a component of the Atg14L-containing Beclin 1-Vps34 protein complex. Nrbf2 deficiency disrupts Atg14L-Vps34/Vps15 interactions and increases intracellular PI3P levels and autophagic flux. Conclusion: Nrbf2 is important for the Beclin 1-Vps34 interaction network to achieve tight autophagy regulation. Significance: Our work identifies a novel aspect of autophagy regulation.
Background 3-Bromopyruvate is an alkylating agent with antitumor activity. It is currently believed that blockade of ATP production from glycolysis and mitochondria is the primary mechanism responsible for this antitumor effect. The present studies have uncovered a new and novel mechanism for the antitumor activity of 3-bromopyruvate. Methods Transport of 3-bromopyruvate via SLC5A8, a tumor suppressor and a Na+-coupled electrogenic transporter for short-chain monocarboxylates, was studied using a mammalian cell expression and the Xenopus laevis oocyte expression systems. The effect of 3-bromopyruvate on histone deacetylases (HDACs) was monitored using the lysate of the human breast cancer cell line MCF7 and human recombinant HDAC isoforms as the enzyme sources. Cell viability was monitored by FACS analysis and colony formation assay. Acetylation status of histone H4 was evaluated by Western blot. Results 3-Bromopyruvate is a transportable substrate for SLC5A8, with the transport process being Na+-coupled and electrogenic. MCF7 cells do not express SLC5A8 and are not affected by 3-bromopyruvate. However, when transfected with SLC5A8 or treated with inhibitors of DNA methylation, these cells undergo apoptosis in the presence of 3-bromopyruvate. This cell death is associated with inhibition of HDAC1/HDAC3. Studies with different isoforms of human recombinant HDACs identify HDAC1 and HDAC3 as the targets for 3-bromopyruvate. Conclusions 3-Bromopyruvate is transported into cells actively via the tumor suppressor SLC5A8 and the process is energized by an electrochemical Na+ gradient. Ectopic expression of the transporter in MCF7 cells leads to apoptosis, and the mechanism involves inhibition of HDAC1/HDAC3.
PURPOSE To investigate whether conjunctival epithelial cells express transport processes for opioid peptides. METHODS We monitored the uptake of [3H]deltorphin II and [3H]DADLE, two hydrolysis-resistant synthetic opioid peptides, in the rabbit conjunctival epithelial cell line CJVE and elucidated the characteristics of the uptake process. RESULTS CJVE cells express robust uptake activity for deltorphin II and DADLE. Both opioid peptides compete with each other for transport. Several endogenous and synthetic opioid peptides, but not non-peptide opioid antagonists, are recognized by the transport process. Though various peptides inhibit the uptake of deltorphin II and DADLE in a similar manner, the uptake of deltorphin II is partly Na+-dependent whereas that of DADLE mostly Na+-independent. The transport process shows high affinity for many endogenous/synthetic opioid peptides. Functional features reveal that this transport process may be distinct from the opioid peptide transport system described in the retinal pigment epithelial cell line ARPE-19 and also from the organic anion transporting polypeptides (OATPs), which are known to transport opioid peptides. CONLCUSIONS CJVE cells express a novel, hitherto unknown transport process for endogenous/synthetic opioid peptides. This new transport process may offer an effective delivery route for opioid peptide drugs to the posterior segment of the eye.
SLC6A14 (also known as ATB0,+) is a Na+/Cl− -coupled amino acid transporter that transports 18 of the 20 proteinogenic amino acids, including all essential amino acids. Normal tissues express this transporter at low levels, whereas tumor tissues (colon, breast, and cervix) upregulate this transporter several-fold. The unique functional features of SLC6A14 (broad substrate specificity and multiple driving forces) make it an ideal transporter for tumor cells to maintain amino acid nutrition necessary for enhanced cell proliferation. We speculate that SLC6A14 could not only be an ideal tumor-specific delivery system for amino acid-based anti-cancer drugs but also be a direct drug target for cancer chemotherapy. Recently we identified alpha-methyltryptophan (ALT) as a blocker of SLC6A14. Here we examine the potential of this blocker as an anti-cancer agent in SLC6A14-positive breast and colon cancer cells. Treatment of MCF7 (a breast cancer cell line), HCT116 and LS174T (colon cancer cell lines) with ALT causes amino acid starvation as evidenced by the upregulation of asparagine synthetase and CHOP. These three cell lines are SLC6A14-positive. In contrast, ALT treatment of breast cancer cell line MDA-MB231, which is SLC6A14-negative, does not show any evidence of amino acid starvation. Similarly, ALT treatment has no effect on normal breast and colon epithelial cell lines (MCF10A and CCD841, respectively). These cell lines also do not express SLC6A14. These data show that ALT-induced amino acid starvation is mediated specifically through the blockade of SLC6A14. Since nutrient signaling is also associated with changes in mTOR pathway, we examined the influence of ALT treatment on phosphorylation of S6 and S6kinase. Blockade of SLC6A14 with ALT in SLC6A14-positive cancer cell lines leads to decreased mTOR signaling as evidenced by decreased phosphorylation of S6 and S6kinase. Again, such changes are not seen in SLC6A14-negative cancer or normal cell lines. The initial response of the SLC6A14-positive cancer cell lines to ALT treatment is induction of autophagy. ALT-induced autophagy is documented in these cells by light and electron microscopic examination as well as by biochemical means. Inhibition of autophagy with 3-methyladenine under these conditions leads to apoptosis. We conclude that SLC6A14 is a potential drug target for cancer chemotherapy and that ALT could serve as a lead compound for the future design of high-affinity blockers of SLC6A14. Citation Format: {Authors}. {Abstract title} [abstract]. In: Proceedings of the 101st Annual Meeting of the American Association for Cancer Research; 2010 Apr 17-21; Washington, DC. Philadelphia (PA): AACR; Cancer Res 2010;70(8 Suppl):Abstract nr 4838.
Introduction: SLC6A14 is an amino acid transporter that transports all essential amino acids as well as glutamine and arginine, and is energized by Na+ gradient, Cl- gradient, and membrane potential. The expression of SLC6A14 is upregulated in ER-positive breast cancer cells but not in ER-negative breast cancer cells. Since cancer cells have an increased need for essential amino acids (protein synthesis), Gln (nucleotide synthesis/glutaminolysis), and Arg (essential amino acid in cancer), we hypothesize that cancer cells satisfy their need for these amino acids by upregulating SLC6A14, and that blockade of SLC6A14 offers a rational strategy for treatment of ER-positive breast cancer. Methods: The transport of Leu, Gln, and Arg via SLC6A14 was studied in X. laevis oocyte expression system. SLC6A14 expression was monitored by RT-PCR and immunohistochemistry in normal and tumors (ER-positive and ER-negative) from primary breast cancer specimens. The influence of estrogen on SLC6A14 expression was investigated in ER-positive BT474 breast cancer cells. α-MT was used as the blocker of SLC6A14. The differential effects of α-MT on MCF7 (ER-positive), MB231 (ER-negative) and MCF10A (non-malignant) cells were investigated in terms of mTOR activity, autophagy, and apoptosis. The ability of α-MT to inhibit the growth of breast cancer cells was evaluated by xenograft in nude mice. α-MT was administered to mice in drinking water (2 mg/ml). Plasma levels of α-MT were measured by HPLC. Results: The transport of Leu, Gln, and Arg via SLC6A14 was dependent on Na+ and Cl- with a Na+:Cl-:amino acid stoichiometry of 2:1:1, and was blocked by α-MT. SLC6A14 expression was upregulated in ER-positive breast cancer. SLC6A14 was not expressed in ER-negative breast cancer. Estrogen induced SLC6A14 expression in ER-positive breast cancer cells. Exposure of ER-positive MCF7 breast cancer cells to α-MT induced the expression of asparagine synthetase and CHOP, inhibited mTOR activity, and induced autophagy and apoptosis. When combined with an autophagy inhibitor, α-MT induced apoptosis in MCF7 cells more potently. These effects were specific for ER-positive breast cancer cells, and were not seen in ER-negative cells or in non-malignant cells. In mouse xenografts, α-MT reduced the growth of ER-positive ZR-75-1 breast cancer cells, but did not have any effect on the growth of ER-negative MB231 cells. MCF7 cells did not grow in nude mice unless estrogen was administered, and under these conditions, α-MT did not block the growth of the cells. Plasma concentration of α-MT in treated mice was 8.5 ± 1.5 μM. α-MT was not detectable in the plasma of untreated mice. Conclusions: SLC6A14 is an ideal and effective drug target for treatment of ER-positive breast cancer. α-MT has potential for use as an anticancer drug, and may also serve as a lead compound in the design/development of newer blockers of SLC6A14 for use in humans. Citation Format: {Authors}. {Abstract title} [abstract]. In: Proceedings of the 102nd Annual Meeting of the American Association for Cancer Research; 2011 Apr 2-6; Orlando, FL. Philadelphia (PA): AACR; Cancer Res 2011;71(8 Suppl):Abstract nr 4459. doi:10.1158/1538-7445.AM2011-4459
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