Your search keyword '"Vadivel Ganapathy"' showing total 618 results

1. Amino acid transporter SLC38A5 is a tumor promoter and a novel therapeutic target for pancreatic cancer

Author

Tyler Sniegowski, Devaraja Rajasekaran, Souad R. Sennoune, Sukumaran Sunitha, Fang Chen, Mohamed Fokar, Sudhir Kshirsagar, P. Hemachandra Reddy, Ksenija Korac, Mosharaf Mahmud Syed, Tanima Sharker, Vadivel Ganapathy, and Yangzom D. Bhutia

Subjects

Medicine, Science

Abstract

Abstract Pancreatic ductal adenocarcinoma (PDAC) cells have a great demand for nutrients in the form of sugars, amino acids, and lipids. Particularly, amino acids are critical for cancer growth and, as intermediates, connect glucose, lipid and nucleotide metabolism. PDAC cells meet these requirements by upregulating selective amino acid transporters. Here we show that SLC38A5 (SN2/SNAT5), a neutral amino acid transporter is highly upregulated and functional in PDAC cells. Using CRISPR/Cas9-mediated knockout of SLC38A5, we show its tumor promoting role in an in vitro cell line model as well as in a subcutaneous xenograft mouse model. Using metabolomics and RNA sequencing, we show significant reduction in many amino acid substrates of SLC38A5 as well as OXPHOS inactivation in response to SLC38A5 deletion. Experimental validation demonstrates inhibition of mTORC1, glycolysis and mitochondrial respiration in KO cells, suggesting a serious metabolic crisis associated with SLC38A5 deletion. Since many SLC38A5 substrates are activators of mTORC1 as well as TCA cycle intermediates/precursors, we speculate amino acid insufficiency as a possible link between SLC38A5 deletion and inactivation of mTORC1, glycolysis and mitochondrial respiration, and the underlying mechanism for PDAC attenuation. Overall, we show that SLC38A5 promotes PDAC, thereby identifying a novel, hitherto unknown, therapeutic target for PDAC.

Published

2023

2. Impact of Oncogenic Changes in p53 and KRAS on Macropinocytosis and Ferroptosis in Colon Cancer Cells and Anticancer Efficacy of Niclosamide with Differential Effects on These Two Processes

Author

Nhi T. Nguyen, Souad R. Sennoune, Gunadharini Dharmalingam-Nandagopal, Sathish Sivaprakasam, Yangzom D. Bhutia, and Vadivel Ganapathy

Subjects

p53 deletion, KRAS mutation, SLC7A11, SLC38A5, ferroptosis, macropinocytosis, Cytology, QH573-671

Abstract

Mutations in p53 and KRAS are seen in most cases of colon cancer. The impact of these mutations on signaling pathways related to cancer growth has been studied in depth, but relatively less is known on their effects on amino acid transporters in cancer cells. This represents a significant knowledge gap because amino acid nutrition in cancer cells profoundly influences macropinocytosis and ferroptosis, two processes with opposing effects on tumor growth. Here, we used isogenic colon cancer cell lines to investigate the effects of p53 deletion and KRAS activation on two amino acid transporters relevant to macropinocytosis (SLC38A5) and ferroptosis (SLC7A11). Our studies show that the predominant effect of p53 deletion is to induce SLC7A11 with the resultant potentiation of antioxidant machinery and protection of cancer cells from ferroptosis, whereas KRAS activation induces not only SLC7A11 but also SLC38A5, thus offering protection from ferroptosis as well as improving amino acid nutrition in cancer cells via accelerated macropinocytosis. Niclosamide, an FDA-approved anti-helminthic, blocks the functions of SLC7A11 and SLC38A5, thus inducing ferroptosis and suppressing macropinocytosis, with the resultant effective reversal of tumor-promoting actions of oncogenic changes in p53 and KRAS. These findings underscore the potential of this drug in colon cancer treatment.

Published

2024

3. Induction of Oxidative Stress and Ferroptosis in Triple-Negative Breast Cancer Cells by Niclosamide via Blockade of the Function and Expression of SLC38A5 and SLC7A11

Author

Marilyn Mathew, Sathish Sivaprakasam, Gunadharini Dharmalingam-Nandagopal, Souad R. Sennoune, Nhi T. Nguyen, Valeria Jaramillo-Martinez, Yangzom D. Bhutia, and Vadivel Ganapathy

Subjects

SLC38A5, SLC7A11, TNBC cells, seleno-methionine, glutathione, glutathione peroxidase, Therapeutics. Pharmacology, RM1-950

Abstract

The amino acid transporters SLC38A5 and SLC7A11 are upregulated in triple-negative breast cancer (TNBC). SLC38A5 transports glutamine, methionine, glycine and serine, and therefore activates mTOR signaling and induces epigenetic modifications. SLC7A11 transports cystine and increases the cellular levels of glutathione, which protects against oxidative stress and lipid peroxidation via glutathione peroxidase, a seleno (Se)-enzyme. The primary source of Se is dietary Se-methionine (Se-Met). Since SLC38A5 transports methionine, we examined its role in Se-Met uptake in TNBC cells. We found that SLC38A5 interacts with methionine and Se-Met with comparable affinity. We also examined the influence of Se-Met on Nrf2 in TNBC cells. Se-Met activated Nrf2 and induced the expression of Nrf2-target genes, including SLC7A11. Our previous work discovered niclosamide, an antiparasitic drug, as a potent inhibitor of SLC38A5. Here, we found SLC7A11 to be inhibited by niclosamide with an IC50 value in the range of 0.1–0.2 μM. In addition to the direct inhibition of SLC38A5 and SLC7A11, the pretreatment of TNBC cells with niclosamide reduced the expression of both transporters. Niclosamide decreased the glutathione levels, inhibited proliferation, suppressed GPX4 expression, increased lipid peroxidation, and induced ferroptosis in TNBC cells. It also significantly reduced the growth of the TNBC cell line MB231 in mouse xenografts.

Published

2024

4. Resetting amino acid metabolism of cancer cells by ATB0,+-targeted nanoparticles for enhanced anticancer therapy

Author

Longfa Kou, Xinyu Jiang, Yingying Tang, Xing Xia, Yingtao Li, Aimin Cai, Hailun Zheng, Hailin Zhang, Vadivel Ganapathy, Qing Yao, and Ruijie Chen

Subjects

Amino acid delivery, ATB0,+ targeting, Nanoparticles, Cancer therapy, mTOR, Materials of engineering and construction. Mechanics of materials, TA401-492, Biology (General), QH301-705.5

Abstract

Reprogramed cellular metabolism is one of the most significant hallmarks of cancer. All cancer cells exhibit increased demand for specific amino acids, and become dependent on either an exogenous supply or upregulated de novo synthesis. The resultant enhanced availability of amino acids supports the reprogramed metabolic pathways and fuels the malignant growth and metastasis of cancers by providing energy and critical metabolic intermediates, facilitating anabolism, and activating signaling networks related to cell proliferation and growth. Therefore, pharmacologic blockade of amino acid entry into cancer cells is likely to have a detrimental effect on cancer cell growth. Here we developed a nanoplatform (LJ@Trp-NPs) to therapeutically target two transporters, SLC6A14 (ATB0,+) and SLC7A5 (LAT1), that are known to be essential for the sustenance of amino acid metabolism in most cancers. The LJ@Trp-NPs uses tryptophan to guide SLC6A14-targeted delivery of JPH203, a high-affinity inhibitor of SLC7A5. In the process, SLC6A14 is also down-regulated. We tested the ability of this strategy to synergize with the anticancer efficacy of lapatinib, an inhibitor of EGFR/HER1/HER2-assocated kinase. These studies show that blockade of amino acid entry amplifies the anticancer effect of lapatinib via interference with mTOR signaling, promotion of apoptosis, and suppression of cell proliferation and metastasis. This represents the first study to evaluate the impact of amino acid starvation on the anticancer efficacy of widely used kinase inhibitor.

Published

2022

5. Editorial: Metabolite and Nutrient Transporters in Cancer-Cell Metabolism: Role in Cancer Progression and Metastasis

Author

Vadivel Ganapathy, Sebastian Haferkamp, Eric K. Parkinson, and Maria E. Mycielska

Subjects

cancer-cell metabolism, nutrient/acid/base transporters, Warburg effect, metabolomics, citrate, carnitine, Biology (General), QH301-705.5

Published

2022

6. Pharmacologic inducers of the uric acid exporter ABCG2 as potential drugs for treatment of gouty arthritis

Author

Bojana Ristic, Mohd Omar Faruk Sikder, Yangzom D. Bhutia, and Vadivel Ganapathy

Subjects

Therapeutics. Pharmacology, RM1-950

Abstract

Uric acid is the end product of purine catabolism and its plasma levels are maintained below its maximum solubility in water (6–7 mg/dl). The plasma levels are tightly regulated as the balance between the rate of production and the rate of excretion, the latter occurring in urine (kidney), bile (liver) and feces (intestinal tract). Reabsorption in kidney is also an important component of this process. Both excretion and reabsorption are mediated by specific transporters. Disruption of the balance between production and excretion leads to hyperuricemia, which increases the risk of uric acid crystallization as monosodium urate with subsequent deposition of the crystals in joints causing gouty arthritis. Loss-of-function mutations in the transporters that mediate uric acid excretion are associated with gout. The ATP-Binding Cassette exporter ABCG2 is important in uric acid excretion at all three sites: kidney (urine), liver (bile), and intestine (feces). Mutations in this transporter cause gout and these mutations occur at significant prevalence in general population. However, mutations that are most prevalent result only in partial loss of transport function. Therefore, if the expression of these partially defective transporters could be induced, the increased number of the transporter molecules would compensate for the mutation-associated decrease in transport function and hence increase uric acid excretion. As such, pharmacologic agents with ability to induce the expression of ABCG2 represent potentially a novel class of drugs for treatment of gouty arthritis. Keywords: Uric acid excretion, Intestine, ABCG2, Loss-of-function mutations, Gouty arthritis, Pharmacologic inducers

Published

2020

7. Chronic exposure to excess iron promotes EMT and cancer via p53 loss in pancreatic cancer

Author

Yangzom D. Bhutia, Jiro Ogura, Paul J. Grippo, Carolina Torres, Toshihiro Sato, Mitchell Wachtel, Sabarish Ramachandran, Ellappan Babu, Sathish Sivaprakasam, Devaraja Rajasekaran, Bradley Schniers, Nhu On, Logan Smoot, Muthusamy Thangaraju, Jaya P. Gnana-Prakasam, and Vadivel Ganapathy

Subjects

Therapeutics. Pharmacology, RM1-950

Abstract

Based on the evidence that hemochromatosis, an iron-overload disease, drives hepatocellular carcinoma, we hypothesized that chronic exposure to excess iron, either due to genetic or environmental causes, predisposes an individual to cancer. Using pancreatic cancer as our primary focus, we employed cell culture studies to interrogate the connection between excess iron and cancer, and combined in vitro and in vivo studies to explore the connection further. Ferric ammonium citrate was used as an exogenous iron source. Chronic exposure to excess iron induced epithelial-mesenchymal transition (EMT) in normal and cancer cell lines, loss of p53, and suppression of p53 transcriptional activity evidenced from decreased expression of p53 target genes (p21, cyclin D1, Bax, SLC7A11). To further extrapolate our cell culture data, we generated EL-KrasG12D (EL-Kras) mouse (pancreatic neoplastic mouse model) expressing Hfe+/+and Hfe−/− genetic background. p53 target gene expression decreased in EL-Kras/Hfe−/− mouse pancreas compared to EL-Kras/Hfe+/+ mouse pancreas. Interestingly, the incidence of acinar-to-ductal metaplasia and cystic pancreatic neoplasms (CPN) decreased in EL-Kras/Hfe−/− mice, but the CPNs that did develop were larger in these mice than in EL-Kras/Hfe+/+ mice. In conclusion, these in vitro and in vivo studies support a potential role for chronic exposure to excess iron as a promoter of more aggressive disease via p53 loss and SLC7A11 upregulation within pancreatic epithelial cells. Keywords: SLC7A11, p53, Iron, Heme, Epithelial-mesenchymal transition

Published

2020

8. OCTN2-targeted nanoparticles for oral delivery of paclitaxel: differential impact of the polyethylene glycol linker size on drug delivery in vitro, in situ, and in vivo

Author

Longfa Kou, Rui Sun, Shuyi Xiao, Xiao Cui, Jin Sun, Vadivel Ganapathy, Qing Yao, and Ruijie Chen

Subjects

nanoparticles, ligand flexibility, oral absorption, targeting efficiency, octn2, Therapeutics. Pharmacology, RM1-950

Abstract

Targeted nanocarriers have shown great promise in drug delivery because of optimized drug behavior and improved therapeutic efficacy. How to improve the targeting efficiency of nanocarriers for the maximum possible drug delivery is a critical issue. Here we developed L-carnitine-conjugated nanoparticles targeting the carnitine transporter OCTN2 on enterocytes for improved oral absorption. As a variable, we introduced various lengths of the polyethylene glycol linker (0, 500, 1000, and 2000) between the nanoparticle surface and the ligand (CNP, C5NP, C10NP and C20NP) to improve the ligand flexibility, and consequently for more efficient interaction with the transporter, to enhance the oral delivery of the cargo load into cells. An increased absorption was observed in cellular uptake in vitro and in intestinal perfusion assay in situ when the polyethylene glycol was introduced to link L-carnitine to the nanoparticles; the highest absorption was achieved with C10NP. In contrast, the linker decreased the absorption efficiency in vivo. As the presence or absence of the mucus layer was the primary difference between in vitro/in situ versus in vivo, the presence of this layer was the likely reason for this differential effect. In summary, the size of the polyethylene glycol linker improved the absorption in vitro and in situ, but interfered with the absorption in vivo. Even though this strategy of increasing the ligand flexibility with the variable size of the polyethylene glycol failed to increase oral absorption in vivo, this approach is likely to be useful for enhanced cellular uptake following intravenous administration of the nanocarriers.

Published

2020

9. Extracellular Citrate Fuels Cancer Cell Metabolism and Growth

Author

Sebastian Haferkamp, Konstantin Drexler, Marianne Federlin, Hans J. Schlitt, Mark Berneburg, Jerzy Adamski, Andreas Gaumann, Edward K. Geissler, Vadivel Ganapathy, E. Kenneth Parkinson, and Maria E. Mycielska

Subjects

cancer, metabolism, transporter, cancer associated fibroblast (CAF), senescent fibroblasts, Biology (General), QH301-705.5

Abstract

Cancer cells need excess energy and essential nutrients/metabolites not only to divide and proliferate but also to migrate and invade distant organs for metastasis. Fatty acid and cholesterol synthesis, considered a hallmark of cancer for anabolism and membrane biogenesis, requires citrate. We review here potential pathways in which citrate is synthesized and/or supplied to cancer cells and the impact of extracellular citrate on cancer cell metabolism and growth. Cancer cells employ different mechanisms to support mitochondrial activity and citrate synthesis when some of the necessary substrates are missing in the extracellular space. We also discuss the different transport mechanisms available for the entry of extracellular citrate into cancer cells and how citrate as a master metabolite enhances ATP production and fuels anabolic pathways. The available literature suggests that cancer cells show an increased metabolic flexibility with which they tackle changing environmental conditions, a phenomenon crucial for cancer cell proliferation and metastasis.

Published

2020

10. Unconventional Functions of Amino Acid Transporters: Role in Macropinocytosis (SLC38A5/SLC38A3) and Diet-Induced Obesity/Metabolic Syndrome (SLC6A19/SLC6A14/SLC6A6)

Author

Yangzom D. Bhutia, Marilyn Mathew, Sathish Sivaprakasam, Sabarish Ramachandran, and Vadivel Ganapathy

Subjects

macropinocytosis, amino acid-dependent Na+/H+ exchange, SLC38A5/SLC38A3, enteroendocrine cell, gut hormones, insulin signaling, Microbiology, QR1-502

Abstract

Amino acid transporters are expressed in mammalian cells not only in the plasma membrane but also in intracellular membranes. The conventional function of these transporters is to transfer their amino acid substrates across the lipid bilayer; the direction of the transfer is dictated by the combined gradients for the amino acid substrates and the co-transported ions (Na+, H+, K+ or Cl−) across the membrane. In cases of electrogenic transporters, the membrane potential also contributes to the direction of the amino acid transfer. In addition to this expected traditional function, several unconventional functions are known for some of these amino acid transporters. This includes their role in intracellular signaling, regulation of acid–base balance, and entry of viruses into cells. Such functions expand the biological roles of these transporters beyond the logical amino acid homeostasis. In recent years, two additional unconventional biochemical/metabolic processes regulated by certain amino acid transporters have come to be recognized: macropinocytosis and obesity. This adds to the repertoire of biological processes that are controlled and regulated by amino acid transporters in health and disease. In the present review, we highlight the unusual involvement of selective amino acid transporters in macropinocytosis (SLC38A5/SLC38A3) and diet-induced obesity/metabolic syndrome (SLC6A19/SLC6A14/SLC6A6).

Published

2022

11. RETRACTED ARTICLE: Identification of a novel Na+-coupled Fe3+-citrate transport system, distinct from mammalian INDY, for uptake of citrate in mammalian cells

Author

Jiro Ogura, Ellappan Babu, Seiji Miyauchi, Sabarish Ramachandran, Elizebeta Nemeth, Yangzom D. Bhutia, and Vadivel Ganapathy

Subjects

Medicine, Science

Abstract

Abstract NaCT is a Na+-coupled transporter for citrate expressed in hepatocytes and neurons. It is the mammalian ortholog of INDY (I’m Not Dead Yet), a transporter which modifies lifespan in Drosophila. Here we describe a hitherto unknown transport system for citrate in mammalian cells. When liver and mammary epithelial cells were pretreated with the iron supplement ferric ammonium citrate (FAC), uptake of citrate increased >10-fold. Iron chelators abrogated the stimulation of citrate uptake in FAC-treated cells. The iron exporter ferroportin had no role in this process. The stimulation of citrate uptake also occurred when Fe3+ was added during uptake without pretreatment. Similarly, uptake of Fe3+ was enhanced by citrate. The Fe3+-citrate uptake was coupled to Na+. This transport system was detectable in primary hepatocytes and neuronal cell lines. The functional features of this citrate transport system distinguish it from NaCT. Loss-of-function mutations in NaCT cause early-onset epilepsy and encephalopathy; the newly discovered Na+-coupled Fe3+-citrate transport system might offer a novel treatment strategy for these patients to deliver citrate into affected neurons independent of NaCT. It also has implications to iron-overload conditions where circulating free iron increases, which would stimulate cellular uptake of citrate and consequently affect multiple metabolic pathways.

Published

2018

12. Drosophila INDY and Mammalian INDY: Major Differences in Transport Mechanism and Structural Features despite Mostly Similar Biological Functions

Author

Valeria Jaramillo-Martinez, Sathish Sivaprakasam, Vadivel Ganapathy, and Ina L. Urbatsch

Subjects

I’m Not Dead Yet, caloric restriction, lifespan, Drosophila INDY, mammalian INDY, SLC13A5, Microbiology, QR1-502

Abstract

INDY (I’m Not Dead Yet) is a plasma membrane transporter for citrate, first identified in Drosophila. Partial deficiency of INDY extends lifespan in this organism in a manner similar to that of caloric restriction. The mammalian counterpart (NaCT/SLC13A5) also transports citrate. In mice, it is the total, not partial, absence of the transporter that leads to a metabolic phenotype similar to that caloric restriction; however, there is evidence for subtle neurological dysfunction. Loss-of-function mutations in SLC13A5 (solute carrier gene family 13, member A5) occur in humans, causing a recessive disease, with severe clinical symptoms manifested by neonatal seizures and marked disruption in neurological development. Though both Drosophila INDY and mammalian INDY transport citrate, the translocation mechanism differs, the former being a dicarboxylate exchanger for the influx of citrate2− in exchange for other dicarboxylates, and the latter being a Na+-coupled uniporter for citrate2−. Their structures also differ as evident from only ~35% identity in amino acid sequence and from theoretically modeled 3D structures. The varied biological consequences of INDY deficiency across species, with the beneficial effects predominating in lower organisms and detrimental effects overwhelming in higher organisms, are probably reflective of species-specific differences in tissue expression and also in relative contribution of extracellular citrate to metabolic pathways in different tissues

Published

2021

13. Dual targeting of l-carnitine-conjugated nanoparticles to OCTN2 and ATB0,+ to deliver chemotherapeutic agents for colon cancer therapy

Author

Longfa Kou, Qing Yao, Sathish Sivaprakasam, Qiuhua Luo, Yinghua Sun, Qiang Fu, Zhonggui He, Jin Sun, and Vadivel Ganapathy

Subjects

l-carnitine, nanoparticles, octn2, atb0,+, colon cancer, Therapeutics. Pharmacology, RM1-950

Abstract

l-Carnitine, obligatory for oxidation of fatty acids, is transported into cells by the Na+-coupled transporter OCTN2 and the Na+/Cl–-coupled transporter ATB0,+. Here we investigated the potential of L-carnitine-conjugated poly(lactic-co-glycolic acid) (PLGA) nanoparticles (LC-PLGA NPs) to deliver chemotherapeutic drugs into cancer cells by targeting the nanoparticles to both OCTN2 and ATB0,+. The cellular uptake of LC-PLGA NPs in the breast cancer cell line MCF7 and the colon cancer cell line Caco-2 was increased compared to unmodified nanoparticles, but decreased in the absence of co-transporting ions (Na+ and/or Cl–) or in the presence of competitive substrates for the two transporters. Studies with fluorescently labeled nanoparticles showed their colocalization with both OCTN2 and ATB0,+, confirming the involvement of both transporters in the cellular uptake of LC-PLGA NPs. As the expression levels of OCTN2 and ATB0,+ are higher in colon cancer cells than in normal colon cells, LC-PLGA NPs can be used to deliver chemotherapeutic drugs selectively into cancer cells for colon cancer therapy. With 5-fluorouracil-loaded LC-PLGA NPs, we were able to demonstrate significant increases in the uptake efficiency and cytotoxicity in colon cancer cells that were positive for OCTN2 and ATB0,+. In a 3D spheroid model of tumor growth, LC-PLGA NPs showed increased uptake and enhanced antitumor efficacy. These findings indicate that dual-targeting LC-PLGA NPs to OCTN2 and ATB0,+ has great potential to deliver chemotherapeutic drugs for colon cancer therapy. Dual targeting LC-PLGA NPs to OCTN2 and ATB0,+ can selectively deliver chemotherapeutics to colon cancer cells where both transporters are overexpressed, preventing targeting to normal cells and thus avoiding off-target side effects.

Published

2017

14. Deficiency of Dietary Fiber in Slc5a8-Null Mice Promotes Bacterial Dysbiosis and Alters Colonic Epithelial Transcriptome towards Proinflammatory Milieu

Author

Sathish Sivaprakasam, Pramodh K. Ganapathy, Mohd Omar Faruk Sikder, Moamen Elmassry, Sabarish Ramachandran, Kameswara Rao Kottapalli, and Vadivel Ganapathy

Subjects

Diseases of the digestive system. Gastroenterology, RC799-869

Abstract

Inflammatory bowel disease (IBD) is characterized by chronic inflammation in the intestinal tract due to disruption of the symbiotic relationship between the host immune system and microbiota. Various factors alter the gut microbiota which lead to dysbiosis; in particular, diet and dietary fibers constitute important determinants. Dietary fiber protects against IBD; bacteria ferment these dietary fibers in colon and generate short-chain fatty acids (SCFAs), which mediate the anti-inflammatory actions of dietary fibers. SLC5A8 is a high-affinity transporter in the apical membrane of colonic epithelium which mediates the entry of SCFAs from the lumen into cells in Na+-coupled manner. Due to the unique transport kinetics, the function of the transporter becomes important only under conditions of low dietary fiber intake. Here, we have examined the impact of dietary fiber deficiency on luminal microbial composition and transcriptomic profile in colonic epithelium in wild-type (WT) and Slc5a8-null (KO) mice. We fed WT and KO mice with fiber-containing diet (FC-diet) or fiber-free diet (FF-diet) and analyzed the luminal bacterial composition by sequencing 16S rRNA gene in feces. Interestingly, results showed significant differences in the microbial community depending on dietary fiber content and on the presence or absence of Slc5a8. There were also marked differences in the transcriptomic profile of the colonic epithelium depending on the dietary fiber content and on the presence or absence of Slc5a8. We conclude that absence of fiber in diet in KO mice causes bacterial dysbiosis and alters gene expression in the colon that is conducive for inflammation.

Published

2019

15. SLC6A14 and SLC38A5 Drive the Glutaminolysis and Serine–Glycine–One-Carbon Pathways in Cancer

Author

Tyler Sniegowski, Ksenija Korac, Yangzom D. Bhutia, and Vadivel Ganapathy

Subjects

cancer-specific metabolism, one-carbon metabolism, glutamine addiction, oncometabolites, amino acid transporters, SLC6A14 and SLC38A5, Medicine, Pharmacy and materia medica, RS1-441

Abstract

The glutaminolysis and serine–glycine–one-carbon pathways represent metabolic reactions that are reprogramed and upregulated in cancer; these pathways are involved in supporting the growth and proliferation of cancer cells. Glutaminolysis participates in the production of lactate, an oncometabolite, and also in anabolic reactions leading to the synthesis of fatty acids and cholesterol. The serine–glycine–one-carbon pathway is involved in the synthesis of purines and pyrimidines and the control of the epigenetic signature (DNA methylation, histone methylation) in cancer cells. Methionine is obligatory for most of the methyl-transfer reactions in the form of S-adenosylmethionine; here, too, the serine–glycine–one-carbon pathway is necessary for the resynthesis of methionine following the methyl-transfer reaction. Glutamine, serine, glycine, and methionine are obligatory to fuel these metabolic pathways. The first three amino acids can be synthesized endogenously to some extent, but the need for these amino acids in cancer cells is so high that they also have to be acquired from extracellular sources. Methionine is an essential amino acid, thus making it necessary for cancer cells to acquire this amino acid solely from the extracellular milieu. Cancer cells upregulate specific amino acid transporters to meet this increased demand for these four amino acids. SLC6A14 and SLC38A5 are the two transporters that are upregulated in a variety of cancers to mediate the influx of glutamine, serine, glycine, and methionine into cancer cells. SLC6A14 is a Na+/Cl− -coupled transporter for multiple amino acids, including these four amino acids. In contrast, SLC38A5 is a Na+-coupled transporter with rather restricted specificity towards glutamine, serine, glycine, and methionine. Both transporters exhibit unique functional features that are ideal for the rapid proliferation of cancer cells. As such, these two amino acid transporters play a critical role in promoting the survival and growth of cancer cells and hence represent novel, hitherto largely unexplored, targets for cancer therapy.

Published

2021

16. Selenomethionine (Se-Met) Induces the Cystine/Glutamate Exchanger SLC7A11 in Cultured Human Retinal Pigment Epithelial (RPE) Cells: Implications for Antioxidant Therapy in Aging Retina

Author

Sudha Ananth, Seiji Miyauchi, Muthusamy Thangaraju, Ravirajsinh N. Jadeja, Manuela Bartoli, Vadivel Ganapathy, and Pamela M. Martin

Subjects

retina, retinal pigment epithelium (RPE), oxidative stress, age-related macular degeneration (AMD), antioxidants, selenium, selenomethionine (Se-Met), Therapeutics. Pharmacology, RM1-950

Abstract

Oxidative damage has been identified as a major causative factor in degenerative diseases of the retina; retinal pigment epithelial (RPE) cells are at high risk. Hence, identifying novel strategies for increasing the antioxidant capacity of RPE cells, the purpose of this study, is important. Specifically, we evaluated the influence of selenium in the form of selenomethionine (Se-Met) in cultured RPE cells on system xc- expression and functional activity and on cellular levels of glutathione, a major cellular antioxidant. ARPE-19 and mouse RPE cells were cultured with and without selenomethionine (Se-Met), the principal form of selenium in the diet. Promoter activity assay, uptake assay, RT-PCR, northern and western blots, and immunofluorescence were used to analyze the expression of xc-, Nrf2, and its target genes. Se-Met activated Nrf2 and induced the expression and function of xc- in RPE. Other target genes of Nrf2 were also induced. System xc- consists of two subunits, and Se-Met induced the subunit responsible for transport activity (SLC7A11). Selenocysteine also induced xc- but with less potency. The effect of Se-met on xc- was associated with an increase in maximal velocity and an increase in substrate affinity. Se-Met increased the cellular levels of glutathione in the control, an oxidatively stressed RPE. The Se-Met effect was selective; under identical conditions, taurine transport was not affected and Na+-coupled glutamate transport was inhibited. This study demonstrates that Se-Met enhances the antioxidant capacity of RPE by inducing the transporter xc- with a consequent increase in glutathione.

Published

2020

17. Transporter-Guided Delivery of Nanoparticles to Improve Drug Permeation across Cellular Barriers and Drug Exposure to Selective Cell Types

Author

Longfa Kou, Yangzom D. Bhutia, Qing Yao, Zhonggui He, Jin Sun, and Vadivel Ganapathy

Subjects

plasma membrane transporters, nano-drug delivery systems, nanoparticles, targeted drug delivery, intestinal absorption, transfer across blood–brain barrier, Therapeutics. Pharmacology, RM1-950

Abstract

Targeted nano-drug delivery systems conjugated with specific ligands to target selective cell-surface receptors or transporters could enhance the efficacy of drug delivery and therapy. Transporters are expressed differentially on the cell-surface of different cell types, and also specific transporters are expressed at higher than normal levels in selective cell types under pathological conditions. They also play a key role in intestinal absorption, delivery via non-oral routes (e.g., pulmonary route and nasal route), and transfer across biological barriers (e.g., blood–brain barrier and blood–retinal barrier. As such, the cell-surface transporters represent ideal targets for nano-drug delivery systems to facilitate drug delivery to selective cell types under normal or pathological conditions and also to avoid off-target adverse side effects of the drugs. There is increasing evidence in recent years supporting the utility of cell-surface transporters in the field of nano-drug delivery to increase oral bioavailability, to improve transfer across the blood–brain barrier, and to enhance delivery of therapeutics in a cell-type selective manner in disease states. Here we provide a comprehensive review of recent advancements in this interesting and important area. We also highlight certain key aspects that need to be taken into account for optimal development of transporter-assisted nano-drug delivery systems.

Published

2018

18. Hydroxyurea differentially modulates activator and repressors of γ-globin gene in erythroblasts of responsive and non-responsive patients with sickle cell disease in correlation with Index of Hydroxyurea Responsiveness

Author

Xingguo Zhu, Tianxiang Hu, Meng Hsuan Ho, Yongchao Wang, Miao Yu, Niren Patel, Wenhu Pi, Jeong-Hyeon Choi, Hongyan Xu, Vadivel Ganapathy, Ferdane Kutlar, Abdullah Kutlar, and Dorothy Tuan

Subjects

Diseases of the blood and blood-forming organs, RC633-647.5

Abstract

Hydroxyurea (HU), the first of two drugs approved by the US Food and Drug Administration for treating patients with sickle cell disease (SCD), produces anti-sickling effect by re-activating fetal γ-globin gene to enhance production of fetal hemoglobin. However, approximately 30% of the patients do not respond to HU therapy. The molecular basis of non-responsiveness to HU is not clearly understood. To address this question, we examined HU-induced changes in the RNA and protein levels of transcription factors NF-Y, GATA-1, -2, BCL11A, TR4, MYB and NF-E4 that assemble the γ-globin promoter complex and regulate transcription of γ-globin gene. In erythroblasts cultured from peripheral blood CD34+ cells of patients with SCD, we found that HU-induced changes in the protein but not the RNA levels of activator GATA-2 and repressors GATA-1, BCL11A and TR4 correlated with HU-induced changes in fetal hemoglobin (HbF) levels in the peripheral blood of HU high and low responders. However, HU did not significantly induce changes in the protein or RNA levels of activators NF-Y and NF-E4. Based on HU-induced changes in the protein levels of GATA-2, -1 and BCL11A, we calculated an Index of Hydroxyurea Responsiveness (IndexHU-3). Compared to the HU-induced fold changes in the individual transcription factor protein levels, the numerical values of IndexHU-3 statistically correlated best with the HU-induced peripheral blood HbF levels of the patients. Thus, IndexHU-3 can serve as an appropriate indicator for inherent HU responsiveness of patients with SCD.

Published

2017

19. The amino acid transporter SLC6A14 in cancer and its potential use in chemotherapy

Author

Yangzom D. Bhutia, Ellappan Babu, Puttur D. Prasad, and Vadivel Ganapathy

Subjects

Essential amino acids, Glutamine addiction, Amino acid transporters, SLC6A14, Prodrugs, Cancer therapy, Therapeutics. Pharmacology, RM1-950

Abstract

Tumor cells have an increased demand for glucose and amino acids to support their rapid growth, and also exhibit alterations in biochemical pathways that metabolize these nutrients. Transport across the plasma membrane is essential to feed glucose and amino acids into these tumor cell-selective metabolic pathways. Transfer of amino acids across biological membranes occurs via a multitude of transporters; tumor cells must upregulate one or more of these transporters to satisfy their increased demand for amino acids. Among the amino acid transporters, SLC6A14 stands out with specific functional features uniquely suited for the biological needs of the tumor cells. This transporter is indeed upregulated in tumors of epithelial origin, including colon cancer, cervical cancer, breast cancer, and pancreatic cancer. Since normal cells express this transporter only at low levels, blockade of this transporter should lead to amino acid starvation selectively in tumor cells, thus having little effect on normal cells. This offers a novel, yet logical, strategy for the treatment of cancers that are associated with upregulation of SLC6A14. In addition, a variety of amino acid-based prodrugs are recognized as substrates by SLC6A14, thus raising the possibility that anticancer drugs can be delivered into tumor cells selectively via this transporter in the form of amino acid prodrugs. This strategy allows exposure of SLC6A14-positive tumor cells to chemotherapy with minimal off-target effects. In conclusion, the amino acid transporter SLC6A14 holds great potential not only as a direct drug target for cancer therapy but also for tumor cell-selective delivery of anticancer drugs.

Published

2014

20. Plasma Membrane Na+-Coupled Citrate Transporter (SLC13A5) and Neonatal Epileptic Encephalopathy

Author

Yangzom D. Bhutia, Jonathan J. Kopel, John J. Lawrence, Volker Neugebauer, and Vadivel Ganapathy

Subjects

citrate transporter, NaCT (SLC13A5), CIC (SLC25A1), cytoplasmic citrate, mitochondrial citrate, GABA, neurotransmitters, fatty acid synthesis, cholesterol synthesis, tricarboxylic acid cycle, NMDA receptor, zinc, Organic chemistry, QD241-441

Abstract

SLC13A5 is a Na+-coupled transporter for citrate that is expressed in the plasma membrane of specific cell types in the liver, testis, and brain. It is an electrogenic transporter with a Na+:citrate3− stoichiometry of 4:1. In humans, the Michaelis constant for SLC13A5 to transport citrate is ~600 μM, which is physiologically relevant given that the normal concentration of citrate in plasma is in the range of 150–200 μM. Li+ stimulates the transport function of human SLC13A5 at concentrations that are in the therapeutic range in patients on lithium therapy. Human SLC13A5 differs from rodent Slc13a5 in two important aspects: the affinity of the human transporter for citrate is ~30-fold less than that of the rodent transporter, thus making human SLC13A5 a low-affinity/high-capacity transporter and the rodent Slc13a5 a high-affinity/low-capacity transporter. In the liver, SLC13A5 is expressed exclusively in the sinusoidal membrane of the hepatocytes, where it plays a role in the uptake of circulating citrate from the sinusoidal blood for metabolic use. In the testis, the transporter is expressed only in spermatozoa, which is also only in the mid piece where mitochondria are located; the likely function of the transporter in spermatozoa is to mediate the uptake of citrate present at high levels in the seminal fluid for subsequent metabolism in the sperm mitochondria to generate biological energy, thereby supporting sperm motility. In the brain, the transporter is expressed mostly in neurons. As astrocytes secrete citrate into extracellular medium, the potential function of SLC13A5 in neurons is to mediate the uptake of circulating citrate and astrocyte-released citrate for subsequent metabolism. Slc13a5-knockout mice have been generated; these mice do not have any overt phenotype but are resistant to experimentally induced metabolic syndrome. Recently however, loss-of-function mutations in human SLC13A5 have been found to cause severe epilepsy and encephalopathy early in life. Interestingly, there is no evidence of epilepsy or encephalopathy in Slc13a5-knockout mice, underlining the significant differences in clinical consequences of the loss of function of this transporter between humans and mice. The markedly different biochemical features of human SLC13A5 and mouse Slc13a5 likely contribute to these differences between humans and mice with regard to the metabolic consequences of the transporter deficiency. The exact molecular mechanisms by which the functional deficiency of the citrate transporter causes epilepsy and impairs neuronal development and function remain to be elucidated, but available literature implicate both dysfunction of GABA (γ-aminobutyrate) signaling and hyperfunction of NMDA (N-methyl-d-aspartate) receptor signaling. Plausible synaptic mechanisms linking loss-of-function mutations in SLC13A5 to epilepsy are discussed.

Published

2017

21. Carnitine deficiency in OCTN2-/- newborn mice leads to a severe gut and immune phenotype with widespread atrophy, apoptosis and a pro-inflammatory response.

Author

Srinivas Sonne, Prem S Shekhawat, Dietrich Matern, Vadivel Ganapathy, and Leszek Ignatowicz

Subjects

Medicine, Science

Abstract

We have investigated the gross, microscopic and molecular effects of carnitine deficiency in the neonatal gut using a mouse model with a loss-of-function mutation in the OCTN2 (SLC22A5) carnitine transporter. The tissue carnitine content of neonatal homozygous (OCTN2(-/-)) mouse small intestine was markedly reduced; the intestine displayed signs of stunted villous growth, early signs of inflammation, lymphocytic and macrophage infiltration and villous structure breakdown. Mitochondrial β-oxidation was active throughout the GI tract in wild type newborn mice as seen by expression of 6 key enzymes involved in β-oxidation of fatty acids and genes for these 6 enzymes were up-regulated in OCTN2(-/-) mice. There was increased apoptosis in gut samples from OCTN2(-/-) mice. OCTN2(-/-) mice developed a severe immune phenotype, where the thymus, spleen and lymph nodes became atrophied secondary to increased apoptosis. Carnitine deficiency led to increased expression of CD45-B220(+) lymphocytes with increased production of basal and anti-CD3-stimulated pro-inflammatory cytokines in immune cells. Real-time PCR array analysis in OCTN2(-/-) mouse gut epithelium demonstrated down-regulation of TGF-β/BMP pathway genes. We conclude that carnitine plays a major role in neonatal OCTN2(-/-) mouse gut development and differentiation, and that severe carnitine deficiency leads to increased apoptosis of enterocytes, villous atrophy, inflammation and gut injury.

Published

2012

22. IFN-γ upregulates survivin and Ifi202 expression to induce survival and proliferation of tumor-specific T cells.

Author

Mary Zimmerman, Dafeng Yang, Xiaolin Hu, Feiyan Liu, Nagendra Singh, Darren Browning, Vadivel Ganapathy, Phillip Chandler, Divaker Choubey, Scott I Abrams, and Kebin Liu

Subjects

Medicine, Science

Abstract

A common procedure in human cytotoxic T lymphocyte (CTL) adoptive transfer immunotherapy is to expand tumor-specific CTLs ex vivo using CD3 mAb prior to transfer. One of the major obstacles of CTL adoptive immunotherapy is a lack of CTL persistence in the tumor-bearing host after transfer. The aim of this study is to elucidate the molecular mechanisms underlying the effects of stimulation conditions on proliferation and survival of tumor-specific CTLs.Tumor-specific CTLs were stimulated with either CD3 mAb or cognate Ag and analyzed for their proliferation and survival ex vivo and persistence in tumor-bearing mice. Although both Ag and CD3 mAb effectively induced the cytotoxic effecter molecules of the CTLs, we observed that Ag stimulation is essential for sustained CTL proliferation and survival. Further analysis revealed that Ag stimulation leads to greater proliferation rates and less apoptosis than CD3 mAb stimulation. Re-stimulation of the CD3 mAb-stimulated CTLs with Ag resulted in restored CTL proliferative potential, suggesting that CD3 mAb-induced loss of proliferative potential is reversible. Using DNA microarray technology, we identified that survivin and ifi202, two genes with known functions in T cell apoptosis and proliferation, are differentially induced between Ag- and CD3 mAb-stimulated CTLs. Analysis of the IFN-γ signaling pathway activation revealed that Ag stimulation resulted in rapid phosphorylation of STAT1 (pSTAT1), whereas CD3 mAb stimulation failed to activate STAT1. Chromatin immunoprecipitation revealed that pSTAT1 is associated with the promoters of both survivin and ifi202 in T cells and electrophoresis mobility shift assay indicated that pSTAT1 directly binds to the gamma activation sequence element in the survivin and ifi202 promoters. Finally, silencing ifi202 expression significantly decreased T cell proliferation.Our findings delineate a new role of the IFN-γ signaling pathway in regulating T cell proliferation and apoptosis through upregulating survivin and ifi202 expression.

Published

2010

23. Carbidopa suppresses estrogen receptor-positive breast cancer via AhR-mediated proteasomal degradation of ERα

Author

Zhiwei, Chen, Xing, Xia, Heyan, Chen, Huirong, Huang, Xingsi, An, Meng, Sun, Qing, Yao, Kwonseop, Kim, Hailin, Zhang, Maoping, Chu, Ruijie, Chen, Yangzom D, Bhutia, Vadivel, Ganapathy, and Longfa, Kou

Subjects

Pharmacology, Estrogen Receptor alpha, Carbidopa, Breast Neoplasms, Parkinson Disease, Estrogens, Mice, Receptors, Aryl Hydrocarbon, Receptors, Estrogen, Oncology, Cell Line, Tumor, Humans, Animals, Female, Pharmacology (medical)

Abstract

Estrogen receptor-α (ERα) promotes breast cancer, and ER-positive cancer accounts for ~ 80% of breast cancers. This subtype responds positively to hormone/endocrine therapies involving either inhibition of estrogen synthesis or blockade of estrogen action. Carbidopa, a drug used to potentiate the therapeutic efficacy of L-DOPA in Parkinson's disease, is an agonist for aryl hydrocarbon receptor (AhR). Pharmacotherapy in Parkinson’s disease decreases the risk for cancers, including breast cancer. The effects of carbidopa on ER-positive breast cancer were evaluated in cell culture and in mouse xenografts. The assays included cell proliferation, apoptosis, cell migration/invasion, subcellular localization of AhR, proteasomal degradation, and tumor growth in xenografts. Carbidopa decreased proliferation and migration of ER-positive human breast cancer cells in vitro with no significant effect on ER-negative breast cancer cells. Treatment of ER-positive cells with carbidopa promoted nuclear localization of AhR and expression of AhR target genes; it also decreased cellular levels of ERα via proteasomal degradation in an AhR-dependent manner. In vivo, carbidopa suppressed the growth of ER-positive breast cancer cells in mouse xenografts; this was associated with increased apoptosis and decreased cell proliferation. Carbidopa has therapeutic potential for ER-positive breast cancer either as a single agent or in combination with other standard chemotherapies.

Published

2022

24. Supplementary Figure S2 from IFNγ Induces DNA Methylation–Silenced GPR109A Expression via pSTAT1/p300 and H3K18 Acetylation in Colon Cancer

Author

Kebin Liu, Jeffrey R. Lee, Keni Gu, Christopher M. Heaton, Vadivel Ganapathy, Darren D. Browning, Muthusamy Thangaraju, Pamela M. Martin, Yangzom D. Bhutia, Priscilla S. Simon, May R. Chen, Dafeng Yang, Amy V. Paschall, and Kankana Bardhan

Abstract

Figure S2. Effects of cytokines on GPR109A expression in human colon carcinoma cells.

Published

2023

25. Supplementary Table S3 from IFNγ Induces DNA Methylation–Silenced GPR109A Expression via pSTAT1/p300 and H3K18 Acetylation in Colon Cancer

Author

Kebin Liu, Jeffrey R. Lee, Keni Gu, Christopher M. Heaton, Vadivel Ganapathy, Darren D. Browning, Muthusamy Thangaraju, Pamela M. Martin, Yangzom D. Bhutia, Priscilla S. Simon, May R. Chen, Dafeng Yang, Amy V. Paschall, and Kankana Bardhan

Abstract

Table S3. Differential expression of inflammatory genes in human colon carcinoma

Published

2023

26. Data from RAD51AP1 Loss Attenuates Colorectal Cancer Stem Cell Renewal and Sensitizes to Chemotherapy

Author

Muthusamy Thangaraju, Vadivel Ganapathy, Bal L. Lokeshwar, Vinata B. Lokeshwar, Puttur D. Prasad, Santhakumar Manicassamy, Nagendra Singh, Hasan Korkaya, Pamela M. Martin, Nikhil Patel, Ravirajsinh N. Jedeja, Pachiappan Arjunan, Sarrah L. Hasanali, Daley S. Morera, Pragya Rajpurohit, Adrienne Lester, Utkarsh Parwal, Kavin Tamizhmani, Sabarish Ramachandran, and Allison E. Bridges

Abstract

DNA damage, induced by either chemical carcinogens or environmental pollutants, plays an important role in the initiation of colorectal cancer. DNA repair processes, however, are involved in both protecting against cancer formation, and also contributing to cancer development, by ensuring genomic integrity and promoting the efficient DNA repair in tumor cells, respectively. Although DNA repair pathways have been well exploited in the treatment of breast and ovarian cancers, the role of DNA repair processes and their therapeutic efficacy in colorectal cancer is yet to be appreciably explored. To understand the role of DNA repair, especially homologous recombination (HR), in chemical carcinogen-induced colorectal cancer growth, we unraveled the role of RAD51AP1 (RAD51-associated protein 1), a protein involved in HR, in genotoxic carcinogen (azoxymethane, AOM)–induced colorectal cancer. Although AOM treatment alone significantly increased RAD51AP1 expression, the combination of AOM and dextran sulfate sodium (DSS) treatment dramatically increased by several folds. RAD51AP1 expression is found in mouse colonic crypt and proliferating cells. RAD51AP1 expression is significantly increased in majority of human colorectal cancer tissues, including BRAF/KRAS mutant colorectal cancer, and associated with reduced treatment response and poor prognosis. Rad51ap1-deficient mice were protected against AOM/DSS-induced colorectal cancer. These observations were recapitulated in a genetically engineered mouse model of colorectal cancer (ApcMin/+). Furthermore, chemotherapy-resistant colorectal cancer is associated with increased RAD51AP1 expression. This phenomenon is associated with reduced cell proliferation and colorectal cancer stem cell (CRCSC) self-renewal. Overall, our studies provide evidence that RAD51AP1 could be a novel diagnostic marker for colorectal cancer and a potential therapeutic target for colorectal cancer prevention and treatment.Implications:This study provides first in vivo evidence that RAD51AP1 plays a critical role in colorectal cancer growth and drug resistance by regulating CRCSC self-renewal.

Published

2023

27. Supplementary Methods from RAD51AP1 Loss Attenuates Colorectal Cancer Stem Cell Renewal and Sensitizes to Chemotherapy

Author

Muthusamy Thangaraju, Vadivel Ganapathy, Bal L. Lokeshwar, Vinata B. Lokeshwar, Puttur D. Prasad, Santhakumar Manicassamy, Nagendra Singh, Hasan Korkaya, Pamela M. Martin, Nikhil Patel, Ravirajsinh N. Jedeja, Pachiappan Arjunan, Sarrah L. Hasanali, Daley S. Morera, Pragya Rajpurohit, Adrienne Lester, Utkarsh Parwal, Kavin Tamizhmani, Sabarish Ramachandran, and Allison E. Bridges

Abstract

Supplementary Methods

Published

2023

28. Data from IFNγ Induces DNA Methylation–Silenced GPR109A Expression via pSTAT1/p300 and H3K18 Acetylation in Colon Cancer

Author

Kebin Liu, Jeffrey R. Lee, Keni Gu, Christopher M. Heaton, Vadivel Ganapathy, Darren D. Browning, Muthusamy Thangaraju, Pamela M. Martin, Yangzom D. Bhutia, Priscilla S. Simon, May R. Chen, Dafeng Yang, Amy V. Paschall, and Kankana Bardhan

Abstract

Short-chain fatty acids, metabolites produced by colonic microbiota from fermentation of dietary fiber, act as anti-inflammatory agents in the intestinal tract to suppress proinflammatory diseases. GPR109A is the receptor for short-chain fatty acids. The functions of GPR109A have been the subject of extensive studies; however, the molecular mechanisms underlying GPR109A expression is largely unknown. We show that GPR109A is highly expressed in normal human colon tissues, but is silenced in human colon carcinoma cells. The GPR109A promoter DNA is methylated in human colon carcinoma. Strikingly, we observed that IFNγ, a cytokine secreted by activated T cells, activates GPR109A transcription without altering its promoter DNA methylation. Colon carcinoma grows significantly faster in IFNγ-deficient mice than in wild-type mice in an orthotopic colon cancer mouse model. A positive correlation was observed between GPR109A protein level and tumor-infiltrating T cells in human colon carcinoma specimens, and IFNγ expression level is higher in human colon carcinoma tissues than in normal colon tissues. We further demonstrated that IFNγ rapidly activates pSTAT1 that binds to the promoter of p300 to activate its transcription. p300 then binds to the GPR109A promoter to induce H3K18 hyperacetylation, resulting in chromatin remodeling in the methylated GPR109A promoter. The IFNγ-activated pSTAT1 then directly binds to the methylated but hyperacetylated GPR109 promoter to activate its transcription. Overall, our data indicate that GPR109A acts as a tumor suppressor in colon cancer, and the host immune system might use IFNγ to counteract DNA methylation–mediated GPR109A silencing as a mechanism to suppress tumor development. Cancer Immunol Res; 3(7); 795–805. ©2015 AACR.

Published

2023

29. Supplementary Data from RAD51AP1 Loss Attenuates Colorectal Cancer Stem Cell Renewal and Sensitizes to Chemotherapy

Author

Muthusamy Thangaraju, Vadivel Ganapathy, Bal L. Lokeshwar, Vinata B. Lokeshwar, Puttur D. Prasad, Santhakumar Manicassamy, Nagendra Singh, Hasan Korkaya, Pamela M. Martin, Nikhil Patel, Ravirajsinh N. Jedeja, Pachiappan Arjunan, Sarrah L. Hasanali, Daley S. Morera, Pragya Rajpurohit, Adrienne Lester, Utkarsh Parwal, Kavin Tamizhmani, Sabarish Ramachandran, and Allison E. Bridges

Abstract

Supplementary Figures and Legends 1-3

Published

2023

30. Supplemental Figure Legend from IFNγ Induces DNA Methylation–Silenced GPR109A Expression via pSTAT1/p300 and H3K18 Acetylation in Colon Cancer

Author

Kebin Liu, Jeffrey R. Lee, Keni Gu, Christopher M. Heaton, Vadivel Ganapathy, Darren D. Browning, Muthusamy Thangaraju, Pamela M. Martin, Yangzom D. Bhutia, Priscilla S. Simon, May R. Chen, Dafeng Yang, Amy V. Paschall, and Kankana Bardhan

Abstract

Supplemental Data

Published

2023

31. DRUG TRANSPORT IN THE PLACENTA

Author

Jashvant D. Unadkat, Vadivel Ganapathy, and Qingcheng Mao

Subjects

Andrology, medicine.anatomical_structure, Chemistry, Placenta, medicine, Human placenta, Drug transport

Published

2022

32. Deletion of Slc6a14 reduces cancer growth and metastatic spread and improves survival in KPC mouse model of spontaneous pancreatic cancer

Author

Bradley K. Schniers, Mitchell S. Wachtel, Meenu Sharma, Ksenija Korac, Devaraja Rajasekaran, Shengping Yang, Tyler Sniegowski, Vadivel Ganapathy, and Yangzom D. Bhutia

Subjects

Pancreatic Neoplasms, Disease Models, Animal, Mice, Amino Acid Transport Systems, endocrine system diseases, Animals, Humans, Cell Biology, Amino Acids, Mechanistic Target of Rapamycin Complex 1, Molecular Biology, Biochemistry

Abstract

Pancreatic ductal adenocarcinoma (PDAC) is lethal. There is a dire need for better therapeutic targets. Cancer cells have increased demand for sugars, amino acids, and lipids and therefore up-regulate various nutrient transporters to meet this demand. In PDAC, SLC6A14 (an amino acid transporter (AAT)) is up-regulated, affecting overall patient survival. Previously we have shown using in vitro cell culture models and in vivo xenograft mouse models that pharmacological inhibition of SLC6A14 with α-methyl-l-tryptophan (α-MLT) attenuates PDAC growth. Mechanistically, blockade of SLC6A14-mediated amino acid transport with α-MLT leads to amino acid deprivation, eventually inhibiting mTORC1 signaling pathway, in tumor cells. Here, we report on the effect of Slc6a14 deletion on various parameters of PDAC in KPC mice, a model for spontaneous PDAC. Pancreatic tumors in KPC mice show evidence of Slc6a14 up-regulation. Deletion of Slc6a14 in this mouse attenuates PDAC growth, decreases the metastatic spread of the tumor, reduces ascites fluid accumulation, and improves overall survival. At the molecular level, we show lower proliferation index and reduced desmoplastic reaction following Slc6a14 deletion. Furthermore, we find that deletion of Slc6a14 does not lead to compensatory up-regulation in any of the other amino transporters. In fact, some of the AATs are actually down-regulated in response to Slc6a14 deletion, most likely related to altered mTORC1 signaling. Taken together, these results underscore the positive role SLC6A14 plays in PDAC growth and metastasis. Therefore, SLC6A14 is a viable drug target for the treatment of PDAC and also for any other cancer that overexpresses this transporter.

Published

2022

33. Resetting amino acid metabolism of cancer cells by ATB0,+-targeted nanoparticles for enhanced anticancer therapy

Author

Ruijie Chen, Vadivel Ganapathy, Yingtao Li, Hailun Zheng, Hailin Zhang, Longfa Kou, Qing Yao, Aimin Cai, Xing Xia, Yingying Tang, and Xinyu Jiang

Subjects

Cancer therapy, QH301-705.5, Biomedical Engineering, Lapatinib, Metastasis, Biomaterials, medicine, ATB0,+ targeting, Biology (General), Materials of engineering and construction. Mechanics of materials, PI3K/AKT/mTOR pathway, chemistry.chemical_classification, Amino acid delivery, Kinase, Chemistry, Cell growth, Cancer, medicine.disease, Amino acid, Cancer cell, mTOR, TA401-492, Cancer research, Nanoparticles, Biotechnology, medicine.drug

Abstract

Reprogramed cellular metabolism is one of the most significant hallmarks of cancer. All cancer cells exhibit increased demand for specific amino acids, and become dependent on either an exogenous supply or upregulated de novo synthesis. The resultant enhanced availability of amino acids supports the reprogramed metabolic pathways and fuels the malignant growth and metastasis of cancers by providing energy and critical metabolic intermediates, facilitating anabolism, and activating signaling networks related to cell proliferation and growth. Therefore, pharmacologic blockade of amino acid entry into cancer cells is likely to have a detrimental effect on cancer cell growth. Here we developed a nanoplatform (LJ@Trp-NPs) to therapeutically target two transporters, SLC6A14 (ATB0,+) and SLC7A5 (LAT1), that are known to be essential for the sustenance of amino acid metabolism in most cancers. The LJ@Trp-NPs uses tryptophan to guide SLC6A14-targeted delivery of JPH203, a high-affinity inhibitor of SLC7A5. In the process, SLC6A14 is also down-regulated. We tested the ability of this strategy to synergize with the anticancer efficacy of lapatinib, an inhibitor of EGFR/HER1/HER2-assocated kinase. These studies show that blockade of amino acid entry amplifies the anticancer effect of lapatinib via interference with mTOR signaling, promotion of apoptosis, and suppression of cell proliferation and metastasis. This represents the first study to evaluate the impact of amino acid starvation on the anticancer efficacy of widely used kinase inhibitor.

Published

2022

34. Supplementary Figure S2 from Extracellular Citrate Affects Critical Elements of Cancer Cell Metabolism and Supports Cancer Development In Vivo

Author

Edward K. Geissler, Peter J. Oefner, Jerzy Adamski, Sven A. Lang, Andreas Gaumann, Christian H. Wetzel, Christine Ziegler, Karl Kunzelmann, Hans J. Schlitt, Vadivel Ganapathy, Christian J. Wachsmuth, Elke Eggenhofer, Gudrun E. Koehl, Alexander Cecil, Moritz Schladt, Margareta Lantow, Gregor M. Madej, Wolfgang Jagla, Vladimir M. Milenkovic, Cornelia Prehn, Katharina Schmidt, Petra Rümmele, Katja Dettmer, and Maria E. Mycielska

Abstract

Krebs cycle activity in the presence of extracellular citrate and absolute citrate levels.

Published

2023

35. Supplementary Table S1 from Extracellular Citrate Affects Critical Elements of Cancer Cell Metabolism and Supports Cancer Development In Vivo

Author

Edward K. Geissler, Peter J. Oefner, Jerzy Adamski, Sven A. Lang, Andreas Gaumann, Christian H. Wetzel, Christine Ziegler, Karl Kunzelmann, Hans J. Schlitt, Vadivel Ganapathy, Christian J. Wachsmuth, Elke Eggenhofer, Gudrun E. Koehl, Alexander Cecil, Moritz Schladt, Margareta Lantow, Gregor M. Madej, Wolfgang Jagla, Vladimir M. Milenkovic, Cornelia Prehn, Katharina Schmidt, Petra Rümmele, Katja Dettmer, and Maria E. Mycielska

Abstract

List of metabolites measured with the AbsoluteIDQ® p180 Kit

Published

2023

36. Supplementary Figure 1 from Extracellular Citrate Affects Critical Elements of Cancer Cell Metabolism and Supports Cancer Development In Vivo

Author

Edward K. Geissler, Peter J. Oefner, Jerzy Adamski, Sven A. Lang, Andreas Gaumann, Christian H. Wetzel, Christine Ziegler, Karl Kunzelmann, Hans J. Schlitt, Vadivel Ganapathy, Christian J. Wachsmuth, Elke Eggenhofer, Gudrun E. Koehl, Alexander Cecil, Moritz Schladt, Margareta Lantow, Gregor M. Madej, Wolfgang Jagla, Vladimir M. Milenkovic, Cornelia Prehn, Katharina Schmidt, Petra Rümmele, Katja Dettmer, and Maria E. Mycielska

Abstract

Intracellular Ca2+ in the presence of extracellular citrate.

Published

2023

37. Data from Extracellular Citrate Affects Critical Elements of Cancer Cell Metabolism and Supports Cancer Development In Vivo

Author

Edward K. Geissler, Peter J. Oefner, Jerzy Adamski, Sven A. Lang, Andreas Gaumann, Christian H. Wetzel, Christine Ziegler, Karl Kunzelmann, Hans J. Schlitt, Vadivel Ganapathy, Christian J. Wachsmuth, Elke Eggenhofer, Gudrun E. Koehl, Alexander Cecil, Moritz Schladt, Margareta Lantow, Gregor M. Madej, Wolfgang Jagla, Vladimir M. Milenkovic, Cornelia Prehn, Katharina Schmidt, Petra Rümmele, Katja Dettmer, and Maria E. Mycielska

Abstract

Glycolysis and fatty acid synthesis are highly active in cancer cells through cytosolic citrate metabolism, with intracellular citrate primarily derived from either glucose or glutamine via the tricarboxylic acid cycle. We show here that extracellular citrate is supplied to cancer cells through a plasma membrane-specific variant of the mitochondrial citrate transporter (pmCiC). Metabolomic analysis revealed that citrate uptake broadly affected cancer cell metabolism through citrate-dependent metabolic pathways. Treatment with gluconate specifically blocked pmCiC and decreased tumor growth in murine xenografts of human pancreatic cancer. This treatment altered metabolism within tumors, including fatty acid metabolism. High expression of pmCiC was associated with invasion and advanced tumor stage across many human cancers. These findings support the exploration of extracellular citrate transport as a novel potential target for cancer therapy.Significance: Uptake of extracellular citrate through pmCiC can be blocked with gluconate to reduce tumor growth and to alter metabolic characteristics of tumor tissue. Cancer Res; 78(10); 2513–23. ©2018 AACR.

Published

2023

38. Supplementary Figures 1 - 5, Table 1 from The Niacin/Butyrate Receptor GPR109A Suppresses Mammary Tumorigenesis by Inhibiting Cell Survival

Author

Muthusamy Thangaraju, Vadivel Ganapathy, Puttur D. Prasad, Lesleyann Hawthorn, Pamela M. Martin, Nagendra Singh, Ling Lan, Ravi N. Padia, Sudha Ananth, Sabarish Ramachandran, Rajneesh Pathania, and Selvakumar Elangovan

Abstract

PDF file - 548K, Supplementary Table S1- Primers used for the RT-PCR assays. Figure S1. DNA methylation inhibitor re-activates GPR109A expression in human breast cancer cells. Figure S2. Stable expression of GPR109A in human breast cancer cell lines. Figure S3. GPR109A activation in breast cancer cells inhibits anti-apoptotic genes and induces pro-apoptotic genes. Figure S4. GPR109A activation in breast cancer cells regulates genes involved in various cellular processes. Figure S5. GPR109A binding is inhibited by components in the media. A, MB231-pCDH and MB231-GPR109A stable cell lines were subjected to radio-labeled nicotinate (NA) binding with binding buffer and L15 media.

Published

2023

39. Supplementary Figure Legends 1-5 from GPR109A Is a G-protein–Coupled Receptor for the Bacterial Fermentation Product Butyrate and Functions as a Tumor Suppressor in Colon

Author

Vadivel Ganapathy, Puttur D. Prasad, Nevin A. Lambert, Gregory J. Digby, Sylvia B. Smith, John D. Mellinger, Darren D. Browning, Jaya P. Gnanaprakasam, Sudha Ananth, Kebin Liu, Gail A. Cresci, and Muthusamy Thangaraju

Abstract

Supplementary Figure Legends 1-5 from GPR109A Is a G-protein–Coupled Receptor for the Bacterial Fermentation Product Butyrate and Functions as a Tumor Suppressor in Colon

Published

2023

40. Supplementary Figure S3 from SLC5A8 Triggers Tumor Cell Apoptosis through Pyruvate-Dependent Inhibition of Histone Deacetylases

Author

Vadivel Ganapathy, Esta Sterneck, Puttur D. Prasad, Sylvia B. Smith, Sudha Ananth, Pamela M. Martin, Elangovan Gopal, and Muthusamy Thangaraju

Abstract

Supplementary Figure S3 from SLC5A8 Triggers Tumor Cell Apoptosis through Pyruvate-Dependent Inhibition of Histone Deacetylases

Published

2023

41. Data from Ratio of miR-196s to HOXC8 Messenger RNA Correlates with Breast Cancer Cell Migration and Metastasis

Author

Shuang Huang, Muthusamy Thangaraju, Vadivel Ganapathy, Zheng Dong, Huijun Chen, Maoxiang Zhang, and Yong Li

Abstract

Expression profiling has identified metastasis-associated microRNAs (miRNA) but technical limitations hinder the discovery of metastasis-suppressing miRNAs. In this study, we sought metastasis-suppressing miRNAs by functional screening. Individual miRNAs were lentivirally introduced into metastatic MDA-MB-231 breast cancer cells and analyzed for effects on cell migration, a critical step in cancer metastasis. Among 486 miRNAs screened, 14 were identified that included all of the members of the miRNA-196 family (miR-196a1, miR-196a2, and miR-196b). Enforced expression of miR-196a1/2 or miR-196b abrogated in vitro invasion and in vivo spontaneous metastasis of breast cancer cells, indicating that members of the miR-196 family are potent metastasis suppressors. We found that miR-196 inhibited the expression of transcription factor HOXC8. Functional linkage was implied by small interfering RNA–mediated knockdown of HOXC8, which suppressed cell migration and metastasis, and by ectopic expression of HOXC8, which prevented the effects of miR-196 on cell migration and metastasis. Unlike other metastasis-associated miRNAs that have been described, the expressions of miR-196 were not correlated with breast cancer cell migration or the metastatic status of clinical breast tumor specimens. Instead, we detected an excellent correlation between the ratio of miR-196 to HOXC8 messages and the migratory behavior of breast cancer cell lines as well as the metastatic status of clinical samples. Our findings identify miRNA-196s as potent metastasis suppressors and reveal that the ratio of miR-196s to HOXC8 mRNA might be an indicator of the metastatic capability of breast tumors. Cancer Res; 70(20); 7894–904. ©2010 AACR.

Published

2023

42. Supplementary Table 4 from The Niacin/Butyrate Receptor GPR109A Suppresses Mammary Tumorigenesis by Inhibiting Cell Survival

Author

Muthusamy Thangaraju, Vadivel Ganapathy, Puttur D. Prasad, Lesleyann Hawthorn, Pamela M. Martin, Nagendra Singh, Ling Lan, Ravi N. Padia, Sudha Ananth, Sabarish Ramachandran, Rajneesh Pathania, and Selvakumar Elangovan

Abstract

XLSX file - 43K, Supplementary Table 4 contains the top 100 down regulated genes that are differentially expressed in MB231-pCDH and MB231-GPR109A stable clones in the presence and absence of niacin.

Published

2023

43. Supplementary Table 3 from The Niacin/Butyrate Receptor GPR109A Suppresses Mammary Tumorigenesis by Inhibiting Cell Survival

Author

Muthusamy Thangaraju, Vadivel Ganapathy, Puttur D. Prasad, Lesleyann Hawthorn, Pamela M. Martin, Nagendra Singh, Ling Lan, Ravi N. Padia, Sudha Ananth, Sabarish Ramachandran, Rajneesh Pathania, and Selvakumar Elangovan

Abstract

XLSX file - 42K, Supplementary Table 3 contains the top 100 upregulated genes that are differentially expressed in MB231-pCDH and MB231-GPR109A stable clones in the presence and absence of niacin.

Published

2023

44. Supplementary Table 1 from Combined Inhibition of DNMT and HDAC Blocks the Tumorigenicity of Cancer Stem-like Cells and Attenuates Mammary Tumor Growth

Author

Muthusamy Thangaraju, Vadivel Ganapathy, Bal L. Lokeshwar, Suash Sharma, Puttur D. Prasad, Ravindra Kolhe, Santhakumar Manicassamy, Jeong-Hyeon Choi, Huidong Shi, Priyanka Thakur, Gurusamy Mariappan, Sabarish Ramachandran, and Rajneesh Pathania

Abstract

Supplementary table 1 will provide a complete list of genes that are differentially regulated genes in RNA-seq analysis for control and 5-AzaC+Butyrate treated CSCs

Published

2023

45. Supplementary Table 2 from The Niacin/Butyrate Receptor GPR109A Suppresses Mammary Tumorigenesis by Inhibiting Cell Survival

Author

Muthusamy Thangaraju, Vadivel Ganapathy, Puttur D. Prasad, Lesleyann Hawthorn, Pamela M. Martin, Nagendra Singh, Ling Lan, Ravi N. Padia, Sudha Ananth, Sabarish Ramachandran, Rajneesh Pathania, and Selvakumar Elangovan

Abstract

XLSX file - 27K, Supplementary Table 2 contains genes that are differentially expressed in MB231-pCDH and MB231-GPR109A stable clones without niacin treatment.

Published

2023

46. Supplementary Table 2 from Combined Inhibition of DNMT and HDAC Blocks the Tumorigenicity of Cancer Stem-like Cells and Attenuates Mammary Tumor Growth

Author

Muthusamy Thangaraju, Vadivel Ganapathy, Bal L. Lokeshwar, Suash Sharma, Puttur D. Prasad, Ravindra Kolhe, Santhakumar Manicassamy, Jeong-Hyeon Choi, Huidong Shi, Priyanka Thakur, Gurusamy Mariappan, Sabarish Ramachandran, and Rajneesh Pathania

Abstract

Supplementary Table S2 will provide information about the Pathway and gene network analyses

Published

2023

47. Data from GPR109A Is a G-protein–Coupled Receptor for the Bacterial Fermentation Product Butyrate and Functions as a Tumor Suppressor in Colon

Author

Vadivel Ganapathy, Puttur D. Prasad, Nevin A. Lambert, Gregory J. Digby, Sylvia B. Smith, John D. Mellinger, Darren D. Browning, Jaya P. Gnanaprakasam, Sudha Ananth, Kebin Liu, Gail A. Cresci, and Muthusamy Thangaraju

Abstract

Short-chain fatty acids, generated in colon by bacterial fermentation of dietary fiber, protect against colorectal cancer and inflammatory bowel disease. Among these bacterial metabolites, butyrate is biologically most relevant. GPR109A is a G-protein–coupled receptor for nicotinate but recognizes butyrate with low affinity. Millimolar concentrations of butyrate are needed to activate the receptor. Although concentrations of butyrate in colonic lumen are sufficient to activate the receptor maximally, there have been no reports on the expression/function of GPR109A in this tissue. Here we show that GPR109A is expressed in the lumen-facing apical membrane of colonic and intestinal epithelial cells and that the receptor recognizes butyrate as a ligand. The expression of GPR109A is silenced in colon cancer in humans, in a mouse model of intestinal/colon cancer, and in colon cancer cell lines. The tumor-associated silencing of GPR109A involves DNA methylation directly or indirectly. Reexpression of GPR109A in colon cancer cells induces apoptosis, but only in the presence of its ligands butyrate and nicotinate. Butyrate is an inhibitor of histone deacetylases, but apoptosis induced by activation of GPR109A with its ligands in colon cancer cells does not involve inhibition of histone deacetylation. The primary changes in this apoptotic process include down-regulation of Bcl-2, Bcl-xL, and cyclin D1 and up-regulation of death receptor pathway. In addition, GPR109A/butyrate suppresses nuclear factor-κB activation in normal and cancer colon cell lines as well as in normal mouse colon. These studies show that GPR109A mediates the tumor-suppressive effects of the bacterial fermentation product butyrate in colon. [Cancer Res 2009;69(7):2826–32]

Published

2023

48. Pri-miRNA's, Supplementary Figures 1-5, Table 1 from Ratio of miR-196s to HOXC8 Messenger RNA Correlates with Breast Cancer Cell Migration and Metastasis

Author

Shuang Huang, Muthusamy Thangaraju, Vadivel Ganapathy, Zheng Dong, Huijun Chen, Maoxiang Zhang, and Yong Li

Abstract

Pri-miRNA's, Supplementary Figures 1-5, Table 1 from Ratio of miR-196s to HOXC8 Messenger RNA Correlates with Breast Cancer Cell Migration and Metastasis

Published

2023

49. Data from Combined Inhibition of DNMT and HDAC Blocks the Tumorigenicity of Cancer Stem-like Cells and Attenuates Mammary Tumor Growth

Author

Muthusamy Thangaraju, Vadivel Ganapathy, Bal L. Lokeshwar, Suash Sharma, Puttur D. Prasad, Ravindra Kolhe, Santhakumar Manicassamy, Jeong-Hyeon Choi, Huidong Shi, Priyanka Thakur, Gurusamy Mariappan, Sabarish Ramachandran, and Rajneesh Pathania

Abstract

Recently, impressive technical advancements have been made in the isolation and validation of mammary stem cells and cancer stem cells (CSC), but the signaling pathways that regulate stem cell self-renewal are largely unknown. Furthermore, CSCs are believed to contribute to chemo- and radioresistance. In this study, we used the MMTV-Neu-Tg mouse mammary tumor model to identify potential new strategies for eliminating CSCs. We found that both luminal progenitor and basal stem cells are susceptible to genetic and epigenetic modifications, which facilitate oncogenic transformation and tumorigenic potential. A combination of the DNMT inhibitor 5-azacytidine and the HDAC inhibitor butyrate markedly reduced CSC abundance and increased the overall survival in this mouse model. RNA-seq analysis of CSCs treated with 5-azacytidine plus butyrate provided evidence that inhibition of chromatin modifiers blocks growth-promoting signaling molecules such as RAD51AP1 and SPC25, which play key roles in DNA damage repair and kinetochore assembly. Moreover, RAD51AP1 and SPC25 were significantly overexpressed in human breast tumor tissues and were associated with reduced overall patient survival. In conclusion, our studies suggest that breast CSCs are intrinsically sensitive to genetic and epigenetic modifications and can therefore be significantly affected by epigenetic-based therapies, warranting further investigation of combined DNMT and HDAC inhibition in refractory or drug-resistant breast cancer. Cancer Res; 76(11); 3224–35. ©2016 AACR.

Published

2023

50. Supplemental Materials and Methods from Combined Inhibition of DNMT and HDAC Blocks the Tumorigenicity of Cancer Stem-like Cells and Attenuates Mammary Tumor Growth

Author

Muthusamy Thangaraju, Vadivel Ganapathy, Bal L. Lokeshwar, Suash Sharma, Puttur D. Prasad, Ravindra Kolhe, Santhakumar Manicassamy, Jeong-Hyeon Choi, Huidong Shi, Priyanka Thakur, Gurusamy Mariappan, Sabarish Ramachandran, and Rajneesh Pathania

Abstract

The Supplemental materials and method file has methods for the Generation of mammospheres and tumorospheres, Preparation of single cell suspension from mammary gland, methods for RNA Isolation and Real-time PCR, and Clonogenic assay.

Published

2023