Project description:Many cancers rely on glycolytic metabolism to fuel rapid proliferation. This has spurred interest in designing drugs that target tumor glycolysis such as AZD3965, a small molecule inhibitor of Monocarboxylate Transporter 1 (MCT1) currently undergoing Phase I evaluation for cancer treatment. Since MCT1 mediates proton-linked transport of monocarboxylates such as lactate and pyruvate across the plasma membrane (Halestrap and Meredith, 2004), AZD3965 is thought to block tumor growth through disruption of lactate transport and glycolysis. Here we show that MCT1 inhibition impairs proliferation of glycolytic breast cancer cells that express MCT4 via disruption of pyruvate rather than lactate export. We found that MCT1 expression is elevated in glycolytic breast tumors and cell lines as well as in malignant breast and lung tissues. High MCT1 expression predicts poor prognosis in breast and lung cancer patients. Stable knockdown and AZD3965-mediated inhibition of MCT1 promote oxidative metabolism. Acute inhibition of MCT1 reduces pyruvate export rate but does not consistently alter lactate transport or glycolytic flux in breast cancer cells that also express MCT4. Despite the lack of glycolysis impairment, MCT1 loss-of-function decreases breast cancer cell proliferation and blocks growth of mammary fat pad xenograft tumors. Our data suggest that MCT1 expression is elevated in glycolytic cancers to promote pyruvate export, which when inhibited enhances oxidative metabolism and reduces proliferation. This study presents an alternative molecular consequence of MCT1 inhibitors that further supports their use as anti-cancer therapeutics. Since MCT1 levels are elevated in glycolytic and malignant breast tumors, we hypothesized that MCT1 may contribute to the Warburg effect metabolic phenotype. To test this hypothesis, we generated whole genome microarray data from breast cancer cell lines either a) expressing a short hairpin (sh)RNA-mediated stable knockdown of MCT1; or b) treated for 24 hours with an MCT1 inhibitor (AZD3965). Scramble shRNA or DMSO were used as controls, and all conditions were analzed in triplicate. The cell lines used – HS578T, SUM149PT, and SUM159PT – are among the most glycolytic in a panel of 31 breast cancer cell lines.

Project description:Despite the implementation of personalized medicine, patients with metastatic CRC (mCRC) still have a dismal overall survival due to the frequent occurrence of acquired resistance mechanisms thereby leading to clinical relapse. Understanding molecular mechanisms that support acquired resistance to anti-EGFR targeted therapy in mCRC is therefore clinically relevant and key to improving patient outcomes. Here, we observe distinct metabolic changes between cetuximab-resistant CRC cell populations, with in particular an increased glycolytic activity in KRAS-mutant cetuximab-resistant LIM1215 but not in KRAS-amplified resistant DiFi cells. We show that cetuximab-resistant LIM1215 cells have the capacity to recycle glycolysis-derived lactate to sustain their growth capacity. This is associated with an upregulation of the lactate importer MCT1 at both transcript and protein levels. Pharmacological inhibition of MCT1, with AR-C155858, reduces the uptake and oxidation of lactate and impairs growth capacity in cetuximab-resistant LIM1215 cells. This study identifies MCT1-dependent lactate utilization as a clinically actionable, metabolic vulnerability to overcome KRAS-mutant-mediated acquired resistance to anti-EGFR therapy in CRC.

Project description:It has been reported that lactate plays as a bridging signaling molecule to coordinates tumor cell and tumor stroma. As pancreatic stellate cells (PSC) is the most majority and functional cells in tumor microenvironment (TME) of pancreatic cancer (PC), whether the lactate involving the crosstalk between PSC and pancreatic acinar cells (PACs) in tumorigenesis of PC has not been defined. The present study showed that lactate transporter, monocarboxylate transporter 1 (MCT1) was predominantly expressed in pancreatic stellate cells (PSC), and correlates with worse prognosis in PC patients. Moreover, we revealed lactate induced autophagy-mediated activation of PSC, while knockout MCT1 in PSC (PSC-MCT1-/- mice) obviously inhibited the proliferation and metastasis of PC in vivo. Meanwhile, results of single-cell sequence demonstrated that the PD-1 expression in CD8+T cells was dramatically increased. Mechanistically, the MCT1-mediated influx of lactate activated PSC by inducing lactylation of lysine residues K356 and K781 on Vps34, a key regulator for autophagy. Moreover, the PSC-derived CXCL9/CXCL10 upregulated PD-1 expression via activating CXCR3/STAT3 pathway in CD8+ T. Consistently, the growth of pancreatic tumor in situ was significantly inhibited in mice treated with MCT1 inhibitor AZD3965, which was further suppressed by combination with PD-1 antibody. In conclusion, our study implicates lactate functions as TME transducer mediating activation of PSC and formation of immunosuppressive TME, and indicates the synergistic effect of targeting PSC activation in immune checkpoint therapy in PC.

Project description:Many cancers rely on glycolytic metabolism to fuel rapid proliferation. This has spurred interest in designing drugs that target tumor glycolysis such as AZD3965, a small molecule inhibitor of Monocarboxylate Transporter 1 (MCT1) currently undergoing Phase I evaluation for cancer treatment. Since MCT1 mediates proton-linked transport of monocarboxylates such as lactate and pyruvate across the plasma membrane (Halestrap and Meredith, 2004), AZD3965 is thought to block tumor growth through disruption of lactate transport and glycolysis. Here we show that MCT1 inhibition impairs proliferation of glycolytic breast cancer cells that express MCT4 via disruption of pyruvate rather than lactate export. We found that MCT1 expression is elevated in glycolytic breast tumors and cell lines as well as in malignant breast and lung tissues. High MCT1 expression predicts poor prognosis in breast and lung cancer patients. Stable knockdown and AZD3965-mediated inhibition of MCT1 promote oxidative metabolism. Acute inhibition of MCT1 reduces pyruvate export rate but does not consistently alter lactate transport or glycolytic flux in breast cancer cells that also express MCT4. Despite the lack of glycolysis impairment, MCT1 loss-of-function decreases breast cancer cell proliferation and blocks growth of mammary fat pad xenograft tumors. Our data suggest that MCT1 expression is elevated in glycolytic cancers to promote pyruvate export, which when inhibited enhances oxidative metabolism and reduces proliferation. This study presents an alternative molecular consequence of MCT1 inhibitors that further supports their use as anti-cancer therapeutics.

Project description:Glioblastoma (GBM) is a malignancy with a complex tumour microenvironment (TME) dominated by glioblastoma stem cells (GSCs) and infiltrated by tumour-associated macrophages (TAMs), and exhibits aberrant metabolic pathways. Lactate is a critical glycolytic metabolite that promotes tumour progression; however, the mechanisms of lactate transport and lactylation in the TME of GBM remain elusive. Here we show that lactate is transported from TAMs to GSCs via MCT4/MCT1. TAMs provide lactate to GSCs, promoting GSC proliferation and inducing lactylation of the non-homologous end joining (NHEJ) protein KU70 at lysine 317 (K317), which inhibits cGAS-STING signaling and remodels the immunosuppressive TME. Inhibition of lactate transport or targeting the lactylation of KU70, in combination with the immune checkpoint blockade, demonstrates additive therapeutic benefits in immunocompetent xenograft models. This study unveils TAM-derived lactate and lactylation as critical regulators in GSCs to enforce an immunosuppressive microenvironment, opening avenues for developing combinatorial therapy for GBM.

Project description:Lactate metabolism and signaling intricately intertwine in the context of cancer and immunity. Basigin, working alongside monocarboxylate transporters MCT1 and MCT4, orchestrates the movement of lactate across cell membranes. Despite promising potential in treating aggressive tumors, the impact of basigin antibodies on these interactions remains unclear. Our research sheds light on this complex interplay: basigin positively modulates MCT activity. A basigin antibody transforms basigin into a negative regulator of MCTs. The antibody suppresses lactate transport and enhances anti-tumor immunity in vitro and in vivo. Furthermore, antibody alters metabolic profiles in PDOs-NSCLCs and T cells. Cryo-EM structure analysis and molecular dynamics simulations unveil that MCT1’s turnover rate is influenced by the flexibility of basigin’s Ig2 domain. By restricting Ig2 flexibility, antibody reduces MCT1 turnover. These findings underscore the promise of basigin antibodies in tumor combat by influencing metabolism and immunity and the value of shared ancillary subunits in targeting heteromeric transporters.

Project description:Lactate is the most abundant circulating metabolic intermediate in mammals and an important energy source for many organs. To use lactate as a fuel, it must be oxidized to pyruvate for entry into the TCA cycle. It is usually described that this reaction occurs in the cytosol and requires the mitochondrial pyruvate carrier (MPC) for pyruvate transport into the mitochondria. Here, using 13C stable isotope tracing, we report that lactate can be oxidized in the heart tissue of mice even when the MPC is genetically deleted. MPC-independent lactate import and oxidation within mitochondria is dependent upon the monocarboxylate transporter 1 (MCT1/ Slc16a1). Mitochondria isolated from Mct1iCKO hearts have impaired respiration on lactate but not pyruvate. Lactate import coupled to mitochondrial lactate dehydrogenase activity functions as an electron shuttle which can produce NADH sufficient for respiration even when the TCA cycle is blocked. Cardiac-specific loss of MCT1 leads to rapid decompensation into heart failure with reduced ejection fraction in response to diverse cardiac injuries. Thus, we identify a new mitochondrial electron shuttle that enables the oxidation of lactate and is required to support cardiac energetics under stress conditions.

Project description:Merkel cell polyomavirus (MCPyV) is an etiological agent of Merkel cell carcinoma (MCC), a highly aggressive skin cancer. The MCPyV small tumor antigen (ST) is required for maintenance of MCC and can transform normal cells. To gain insight into cellular perturbations induced by MCPyV ST, we performed transcriptome analysis of normal human fibroblasts with inducible expression of ST. MCPyV ST dynamically alters the cellular transcriptome with increased levels of glycolytic genes, including the monocarboxylate lactate transporter SLC16A1 (MCT1). Extracellular flux analysis revealed increased lactate export reflecting elevated aerobic glycolysis in ST expressing cells. Inhibition of MCT1 activity suppressed the growth of MCC cell lines and impaired MCPyV-dependent transformation of IMR90 cells. Both NF-κB and MYC have been shown to regulate MCT1 expression. While MYC was required for MCT1 induction, MCPyV-induced MCT1 levels decreased following knockdown of the NF-κB subunit RelA, supporting a synergistic activity between MCPyV and MYC in regulating MCT1 levels. Several MCC lines had high levels of MYCL and MYCN but not MYC. Increased levels of MYCL was more effective than MYC or MYCN in increasing extracellular acidification in MCC cells. Our results demonstrate the effects of MCPyV ST on the cellular transcriptome and reveal that transformation is dependent, at least in part, on elevated aerobic glycolysis.

Project description:Adipose tissue is an active producer of lactate. In obesity, the increased size of adipocytes is accompanied by an increase in lactate production in adipose tissue, caused by hypoxia in obese adipocytes. How lactate affects metabolism in adipocyte and insulin sensitivity remains unclear. Here we develop a mouse model of MCT1,coding by Slc16a1, specific deletion in adipose tissues, using the AP2 promoter to drive Cre expression. This MCT1 AKO mice develop more severe insulin resistance in obesity with 16 weeks high fat diet treatment, while few changes happen to lipid metabolism in adipose tissues. We used RNA-seq to analyze the gene expression patterns of eWAT of obese MCT1 AKO mice compared to WT, and found significant changes in innate immune signaling and adipocyte apoptosis that reflect systemic inflammation and insulin resistance.

Project description:Regulatory T (Treg) cells are vital for maintaining immune homeostasis and preventing autoimmunity, but represent a major barrier to robust cancer immunity as the tumor microenvironment (TME) actively recruits, activates, and promotes their differentiation1,2. Tumor cells have deregulated cellular metabolism leading to a metabolite-depleted, hypoxic, and acidic TME3. Highly glycolytic tumor infiltrating CD8 T cells are in direct competition with the tumor for glucose and oxygen which impairs their effector function4–6. In contrast, Treg cells maintain their high suppressive function within the TME7,8. Further, studies of in vitro induced and directly ex vivo Treg cells reveal a distinct metabolic profile compared to effector T cells9–11. Thus, we hypothesized that the altered metabolic landscape of the TME and the increased activity of intratumoral Treg cells are linked. Here we show Treg cells display heterogeneity in terms of their glucose metabolism and can engage an alternative metabolic pathway to maintain their high suppressive function and proliferation within the TME and other tissues. Tissue derived Treg cells (both at the steady state and under inflammatory conditions) show broad heterogeneity in their ability to take up glucose. However, glucose uptake correlates with poorer suppressive function and long-term functional stability, and culture of Treg cells in high glucose conditions decreased suppressive function. Treg cells under low glucose conditions upregulate genes associated with the uptake and metabolism of the glycolytic end-product lactic acid. Treg cells withstand high lactate conditions, and lactate treatment prevents the destabilizing effects of high glucose culture. Treg cells utilize lactate within the TCA cycle and generate phosphoenolpyruvate (PEP), a critical intermediate that can fuel intratumoral Treg cell proliferation in vivo. Using mice with a Treg cell-restricted deletion of lactate transporter Slc16a1 (MCT1) we show MCT1 is dispensable for peripheral Treg cell function but required intratumorally, resulting in slowed tumor growth and prolonged survival. These data support a model in which Treg cells are metabolically flexible such that they can utilize ‘alternative’ metabolites present in the TME to maintain their suppressive identity. Further, our studies support the notion that tumors avoid immune destruction not only by depriving effector T cells of essential nutrients, but also by metabolically supporting regulatory T cells.