Alterations In Glycolysis Research Articles

FTMT-dependent mitophagy is crucial for ferroptosis resistance in cardiac fibroblast

Metabolic responses to cellular stress are pivotal in cell ferroptosis, with mitophagy serving as a crucial mechanism in both metabolic processes and ferroptosis. This study aims to elucidate the effects of high glucose on cardiomyocytes (CMs) and cardiac fibroblasts (CFs) regarding ferroptosis and to uncover the underlying mechanisms involved. We examined alterations in glycolysis, mitochondrial oxidative phosphorylation (OXPHOS), and mitophagy, which are essential for metabolic adaptations and ferroptosis. High glucose exposure induced ferroptosis specifically in CMs, while CFs exhibited resistance to ferroptosis, increased glycolytic activity, and no change in OXPHOS. Moreover, high glucose treatment enhanced mitophagy and upregulated mitochondrial ferritin (FTMT). Notably, the combination of FTMT and the autophagy-related protein nuclear receptor coactivator 4 (NCOA4) increased under high glucose conditions. Silencing FTMT significantly impeded mitophagy and eliminated ferroptosis resistance in CFs cultured under high glucose conditions. The transcription factor forkhead box A1 (FOXA1) was upregulated in CFs upon high glucose exposure, playing a crucial role in the increased expression of FTMT. Within the 5′-flanking sequence of the FTMT mRNA, approximately −500 nt from the transcription initiation site, three putative FOXA1 binding sites were identified. High glucose augmented the binding affinity between FOXA1 and these sequences, thereby promoting FTMT transcription. In summary, high glucose upregulated FOXA1 expression and stimulated FTMT promoter activity in CFs, thereby promoting FTMT-dependent mitophagy and conferring ferroptosis resistance in CFs.

Exploring the Potential of Glycolytic Modulation in Myeloid-Derived Suppressor Cells for Immunotherapy and Disease Management.

Recent advancements in various technologies have shed light on the critical role of metabolism in immune cells, paving the way for innovative disease treatment strategies through immunometabolism modulation. This review emphasizes the glucose metabolism of myeloid-derived suppressor cells (MDSCs), an emerging pivotal immunosuppressive factor especially within the tumor microenvironment. MDSCs, an immature and heterogeneous myeloid cell population, act as a double-edged sword by exacerbating tumors or mitigating inflammatory diseases through their immune-suppressive functions. Numerous recent studies have centered on glycolysis of MDSC, investigating the regulation of altered glycolytic pathways to manage diseases. However, the specific changes in MDSC glycolysis and their exact functions continue to be areas of ongoing discussion yet. In this paper, we review a range of current findings, including the latest research on the alteration of glycolysis in MDSCs, the consequential functional alterations in these cells, and the outcomes of attempts to modulate MDSC functions by regulating glycolysis. Ultimately, we will provide insights into whether these research efforts could be translated into clinical applications.

Metabolic difference between patient-derived xenograft model of pancreatic ductal adenocarcinoma and corresponding primary tumor

BackgroundPatients-derived xenograft (PDX) model have been widely used for tumor biological and pathological studies. However, the metabolic similarity of PDX tumor to the primary cancer (PC) is still unknown.MethodsIn present study, we established PDX model by engrafting primary tumor of pancreatic ductal adenocarcinoma (PDAC), and then compared the tumor metabolomics of PC, the first generation of PDX tumor (PDXG1), and the third generation of PDX tumor (PDXG3) by using 1H NMR spectroscopy. Then, we assessed the differences in response to chemotherapy between PDXG1 and PDXG3 and corresponding metabolomic differences in drug-resistant tumor tissues. To evaluate the metabolomic similarity of PDX to PC, we also compared the metabolomic difference of cell-derived xenograft (CDX) vs. PC and PDX vs. PC.ResultsAfter engraftment, PDXG1 tumor had a low level of lactate, pyruvate, citrate and multiple amino acids (AAs) compared with PC. Metabolite sets enrichment and metabolic pathway analyses implied that glycolysis metabolisms were suppressed in PDXG1 tumor, and tricarboxylic acid cycle (TCA)-associated anaplerosis pathways, such as amino acids metabolisms, were enhanced. Then, after multiple passages of PDX, the altered glycolysis and TCA-associated anaplerosis pathways were partially recovered. Although no significant difference was observed in the response of PDXG1 and PDXG3 to chemotherapy, the difference in glycolysis and amino acids metabolism between PDXG1 and PDXG3 could still be maintained. In addition, the metabolomic difference between PC and CDX models were much larger than that of PDX model and PC, indicating that PDX model still retain more metabolic characteristics of primary tumor which is more suitable for tumor-associated metabolism research.ConclusionsCompared with primary tumor, PDX models have obvious difference in metabolomic level. These findings can help us design in vivo tumor metabolomics research legitimately and analyze the underlying mechanism of tumor metabolic biology thoughtfully.

Abstract 450: GCN2 protects cancer cells from hypertranslation and metabolic crisis

Abstract It is widely assumed that cancer cells rely on high levels of protein synthesis to support growth and proliferation. However, protein synthesis, including ribosome biogenesis, is a highly resource- and energy-demanding process that needs to be coordinated with protein degradation and metabolic programs. GCN2 is an evolutionarily conserved kinase that is primarily activated by uncharged tRNAs when amino acid levels drop and activates the Integrated Stress Response (ISR), which encompasses a global reduction in translation and increased amino acid uptake and generation. GCN2 has been shown to support cancer cell survival under conditions of nutrient scarcity. Here, we used an integrated systems biology approach to delineate the multifaceted role of GCN2 in cancer cells that do not suffer from nutrient shortages. We carried out a broad array of multiomic analyses (RNA-seq, TMT-labelling based proteomics, Ribo-seq, LC-MS metabolomics) of melanoma cells in which GCN2 was inhibited (GCN2iB) or genetically depleted (constitutive and inducible shRNA) in cell culture and in vivo in murine xenografts, supplemented by puromycinylation-based quantification of global protein synthesis. GCN2 inhibition in A375 cells triggered a transcriptome and proteome response that was dominated by the induction of processes linked to protein and ribosome synthesis while suppressing metabolic pathways such as glycolysis and the proteasome. We confirmed these observations in vivo via RNA-seq of tumor samples from mice xenografted with A375 cells in which GCN2 was knocked down by induced shRNA expression and from xenografted mice that were treated orally with GCN2iB. Ribo-seq further demonstrated that, upon GCN2 inhibition, A375 cells expand their translational machinery. Notably, we identified 50 ribosomal genes that were translated at higher rate in GCN2-inhibited cells and whose expression was regulated exclusively at the translational level. GCN2 inhibition/depletion also resulted in an approximately 1.8-fold increase in global protein synthesis and altered the druggable proteome. Moreover, metabolite profiling of GCN2iB-treated cells revealed a loss of metabolic homeostasis including substantial alterations in glycolysis and both amino acid and lipid metabolism. In addition, we observed a significant decrease in ATP levels despite increased translation of mitochondrial ETC complex proteins. Proteomic and translatomic analyses revealed a failure of cells to increase proteasomal subunits and to maintain the production of ECM proteins. Last, but not least, we did not observe a role of GCN2 in preventing or resolving ribosome collisions. Taken together, our findings reveal GCN2 as a master regulator of translation in cancer cells that do not suffer from nutrient scarcity that keeps protein synthesis in check to maintain metabolic homeostasis. Citation Format: Monica Roman-Trufero, Istvan T. Kleijn, Kevin Blighe, Paula Saavedra-Garcia, Jinglin Zhou, Abigail Gaffar, Marilena Christoforou, Mariia Yuneva, Audrey M. Michel, Glenn R. Masson, Vahid Shahrezaei, Holger W. Auner. GCN2 protects cancer cells from hypertranslation and metabolic crisis [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2024; Part 1 (Regular Abstracts); 2024 Apr 5-10; San Diego, CA. Philadelphia (PA): AACR; Cancer Res 2024;84(6_Suppl):Abstract nr 450.

Metabolomics, Transcriptome and Single-Cell RNA Sequencing Analysis of the Metabolic Heterogeneity between Oral Cancer Stem Cells and Differentiated Cancer Cells.

Understanding the distinct metabolic characteristics of cancer stem cells (CSC) may allow us to better cope with the clinical challenges associated with them. In this study, OSCC cell lines (CAL27 and HSC3) and multicellular tumor spheroid (MCTS) models were used to generate CSC-like cells. Quasi-targeted metabolomics and RNA sequencing were used to explore altered metabolites and metabolism-related genes. Pathview was used to display the metabolites and transcriptome data in a KEGG pathway. The single-cell RNA sequencing data of six patients with oral cancer were analyzed to characterize in vivo CSC metabolism. The results showed that 19 metabolites (phosphoethanolamine, carbamoylphosphate, etc.) were upregulated and 109 metabolites (2-aminooctanoic acid, 7-ketocholesterol, etc.) were downregulated in both MCTS cells. Integration pathway analysis revealed altered activity in energy production (glycolysis, citric cycle, fatty acid oxidation), macromolecular synthesis (purine/pyrimidine metabolism, glycerophospholipids metabolism) and redox control (glutathione metabolism). Single-cell RNA sequencing analysis confirmed altered glycolysis, glutathione and glycerophospholipid metabolism in in vivo CSC. We concluded that CSCs are metabolically inactive compared with differentiated cancer cells. Thus, oral CSCs may resist current metabolic-related drugs. Our result may be helpful in developing better therapeutic strategies against CSC.

Mitochondrial Dysfunction by FADDosome Promotes Gastric Mucosal Injury in Portal Hypertensive Gastropathy.

Mucosal epithelial death is an essential pathological characteristic of portal hypertensive gastropathy (PHG). FADDosome can regulate mucosal homeostasis by controlling mitochondrial status and cell death. However, it remains ill-defined whether and how the FADDosome is involved in the epithelial death of PHG. The FADDosome formation, mitochondrial dysfunction, glycolysis process and NLRP3 inflammasome activation in PHG from both human sections and mouse models were investigated. NLRP3 wild-type (NLRP3-WT) and NLRP3 knockout (NLRP3-KO) littermate models, critical element inhibitors and cell experiments were utilized. The mechanism underlying FADDosome-regulated mitochondrial dysfunction and epithelial death in PHG was explored. Here, we found that FADD recruited caspase-8 and receptor-interacting serine/threonine-protein kinase 1 (RIPK1) to form the FADDosome to promote Drp1-dependent mitochondrial fission and dysfunction in PHG. Also, FADDosome modulated NOX2 signaling to strengthen Drp1-dependent mitochondrial fission and alter glycolysis as well as enhance mitochondrial reactive oxygen species (mtROS) production. Moreover, due to the dysfunction of electron transport chain (ETC) and alteration of antioxidant enzymes activity, this altered glycolysis also contributed to mtROS production. Subsequently, the enhanced mtROS production induced NLRP3 inflammasome activation to result in the epithelial pyroptosis and mucosal injury in PHG. Thus, the FADDosome-regulated pathways may provide a potential therapeutic target for PHG.

Metabolic Alterations in NADSYN1-Deficient Cells.

NAD synthetase 1 (encoded by the gene NADSYN1) is a cytosolic enzyme that catalyzes the final step in the biosynthesis of nicotinamide adenine dinucleotide (NAD+) from tryptophan and nicotinic acid. NADSYN1 deficiency has recently been added to the spectrum of congenital NAD+ deficiency disorders. To gain insight into the metabolic consequences of NADSYN1 deficiency, the encoding gene was disrupted in A549 and HEK293T cells, and the metabolome was profiled in the presence of different NAD+ precursors, including tryptophan, nicotinamide and nicotinic acid. We demonstrate that when precursors of the NAD+ salvage pathway in the form of nicotinamide become limiting, NADSYN1 deficiency results in a decline in intracellular NAD+ levels even in the presence of other potential NAD+ sources such as tryptophan and nicotinic acid. As a consequence, alterations in 122 and 69 metabolites are observed in NADSYN1-deficient A549 and HEK293T cells compared to the wild-type cell line (FC > 2 and p < 0.05). We thus show that NADSYN1 deficiency results in a metabolic phenotype characterized by alterations in glycolysis, the TCA cycle, the pentose phosphate pathway, and the polyol pathway.

ZBTB7A Loss Promotes Synthesis of Lipids and Ketone Bodies in Myeloid Leukemia

Cancer cells reprogram their metabolism at many levels to meet the high demand for ATP and metabolites necessary for rapid tumor growth. We recently showed that inactivation of ZBTB7A, a transcription factor essential for lineage fate decision, causes upregulation of glycolysis culminating in increased energy supply in myeloid leukemia cells (Redondo Monte et al., 2020, Oncogene). ZBTB7A mutations are specifically associated with AML t(8;21), pointing toward cooperation with the RUNX1-RUNX1T1 fusion. However, the underlying mechanism is still not fully understood. Besides alteration of glycolysis, we found genes related to fatty acid metabolism upregulated in the K562 ZBTB7A knockout (KO) myeloid leukemia cell line. This led us to hypothesize that the loss of ZBTB7A could provide the cells with additional energy via increased fatty acid oxidation. To further investigate the role of ZBTB7A in fatty acid metabolism we performed metabolic flux (Seahorse, Agilent) and metabolic tracing experiments. In the palmitate oxidation assay, using a setting where the cells were cultivated in a substrate-limited medium overnight prior to the experiment and deprived of glutamine during the assay, the K562 ZBTB7A KO cells did not exhibit an advantage in oxidizing this substrate for ATP production. Moreover, in this context, the ZBTB7A KO cells responded negatively to the inhibition of the CPT1A enzyme by Etomoxir, suggesting that these cells are not dependent on fatty acid oxidation. Interestingly, RNA-seq revealed that in K562 ZBTB7A KO cells several genes from the electron transport chain (ETC) were downregulated, supporting the idea that these cells do not depend on OXPHOS metabolism. Metabolic tracing of the 13C6 glucose isotope by mass spectrometry confirmed that K562 ZBTB7A KO cells exhibit upregulated glycolysis and pentose phosphate pathways, as previously reported (Redondo Monte et al., 2020, Oncogene; Liu et al., 2014, Genes Dev.). Conversely, tricarboxylic acid cycle (TCA) metabolites were not different between control and knockout cells. We observed that upregulation of glycolysis resulted in high amounts of acetyl-CoA, which is not entering the OXPHOS metabolism but is used as a precursor for palmitate synthesis instead (Figure 1A). Of note, palmitate is required for the production of several complex lipids in cell membranes, which are highly demanded in cancer cells. Accordingly, the transcript level of FASN, the enzyme that catalyses palmitate synthesis, is upregulated in core binding factor (CBF) AML patients with mutation in ZBTB7A (Figure 1B). Remarkably, the K562 ZBTB7A KO cells preferentially produce acetoacetate (ketone bodies) from the additional acetyl-CoA and secrete it to the medium (Figure 1A). The genes HMGCS1 and ACAT1, encoding enzymes that enable ketone bodies reutilization in lipid synthesis, are downregulated upon ZBTB7A loss, indicating that these cells do not use the ketone bodies. Since ketone bodies not only serve as a substrate for ATP production but also act as signaling mediators, we hypothesize that ketone bodies might fuel the bone marrow microenvironment to support leukemia cells expansion. In summary, we have advanced the understanding of ZBTB7A loss in leukemia metabolism, showing increased lipid and ketone bodies synthesis at the metabolite level. Lipid synthesis enzymes, such as FASN, FADS1, and FADS2 are attractive drug targets for therapeutic applications, especially in combination with standard therapies and glycolysis inhibitors.

Purine Metabolism Modulates Leukemia Stem Cell Maintenance in MLL-Rearranged Acute Leukemia

Acute myeloid leukemia (AML) represents the most prevalent hematopoietic malignancy driven by leukemia stem cells (LSCs) and remains challenging to treat in adult patients. MLL rearrangement results in a genetically unique subtype of AML characterized by chromosomal translocations involving the MLL gene and over 80 fusion partners, including AF9 as one of the most common partners. The oncogenic MLL fusion proteins interact with multiple transcription and chromatin regulators, such as Menin, to induce leukemogenic stem cell gene programs and transform hematopoietic stem and progenitor cells. Although significant progress has been made in understanding the metabolic dysregulation in acute leukemia, such as alterations in glycolysis, energetic metabolism, amino acid metabolism, and fatty acid metabolism, the metabolic factors that modulate MLL fusion oncogenic transcriptional activity in AML remain incompletely elucidated. To identify novel metabolic vulnerabilities in MLL-rearranged AML, we performed a whole genome CRISPR dropout screen and profiled the metabolites of murine LSCs of MLL-AF9 murine model. This analysis revealed the purine biosynthesis pathway is essential for MLL-rearranged leukemia and that MLL-rearranged LSCs are enriched in metabolites of the purine biosynthesis pathway. Isotypoe incorporation experiments using [U- 13C]glucose demonstrated a high purine biosynthetic rate in the LSCs compared to bulk leukemia cells. Accordingly, human acute myeloid leukemia stem cells express high levels of the purine biosynthetic genes. Furthermore, we found that MYC, a well-known downstream target of MLL-AF9, mediates the enhanced purine synthesis in LSCs. These results demonstrate enhanced purine biosynthetic pathways in LSCs. We utilized genetic and pharmacological (mycophenolate mofetil, MMF, a purine biosynthesis inhibitor of IMPDH) approaches to target the enhanced purine metabolism and found inhibition of the purine synthesis pathway promotes myeloid differentiation of both murine and human LSCs. Metabolomics analysis reveals a remarkable reduction of purine metabolites. Supplementing the LSCs with guanosine, an intermediate metabolite of the purine biosynthesis pathway, substantially rescued the differentiation. Importantly, treatment of MLL-AF9-driven murine leukemia mice with MMF impaired LSCs function, prolonged leukemia survival, and reduced leukemia burden in the peripheral blood and bone marrow, while causing minimal effects on normal hematopoiesis. These results demonstrate the reliance on enhanced purine metabolism in LSCs maintenance. Previous work has shown that the purine biosynthesis pathway is essential for rRNA transcription in the nucleolus, which could be inhibited by CX-5461. To verify the essentiality of the rRNA transcription in MLL-rearranged LSCs, we treated MLL-AF9-induced murine LSCs cells with CX-5461 and found CX-5461 promotes myeloid differentiation of LSCs. Moreover, we found that the myeloid differentiation induced by MMF or CX-5461 is associated with reduced chromatin occupancy of the MLL-AF9 complex, especially Menin, and downregulated expression of MLL-AF9 target genes, such as Meis1, Hoxa9 and Myc, suggesting a regulatory role of nucleolar rRNA transcription on MLL-AF9 oncogenic gene expression program. We are currently focusing on the synergistic effects of targeting purine metabolism and Menin inhibition on AML suppression. Altogether, our findings reveal that purine metabolism maintains nucleolar rRNA transcription homeostasis to modulate MLL fusion complex-induced leukemogenic transcriptional activity in LSCs. The enhanced purine metabolism emerges as a crucial dependency for LSCs, providing potential targets for novel therapeutic strategies in treating MLL-rearranged leukemia.

The Expression of Two Distinct Sets of Glycolytic Enzymes Reveals Differential Effects of Glycolytic Reprogramming on Pancreatic Ductal Tumorigenesis in Mice.

Pancreatic ductal adenocarcinoma (PDAC) is associated with enhanced aerobic glycolysis through elevated glucose uptake and the upregulated expression of genes encoding rate-limiting glycolytic enzymes. However, the direct impact of altered glycolytic pathways on pancreatic tumor progression has not been thoroughly investigated. Here, we utilized two strains of BAC transgenic mice with pancreatic expression of two distinct sets of glycolytic genes each arranged in a polycistronic fashion (PFKFB3-HK2-GLUT1 and LDHA-PDK1, respectively) to investigate the role of altered glycolysis on the development of pancreatic ductal tumor development in the Pdx1-Cre; LSL-KrasG12D mice. The overexpression of the two sets of glycolytic genes exhibited no significant effects on tumor development in the 4-5-month-old mice (the PanIN2 lesions stage). In the 9-10-month-old mice, the overexpression of PFKFB3-HK2-GLUT1 significantly accelerated PanIN3 progression, exhibiting elevated levels of ductal cell marker CK19 and tumor fibrosis. Surprisingly, the overexpression of LDHA-PDK1 significantly attenuated the progression of PanIN3 in the 9-10-month-old mice with significantly downregulated levels of CK19 and fibrosis. Therefore, distinct set of glycolytic enzymes that are involved in different glycolytic routes exhibited contrasting effects on pancreatic ductal tumor development depending on the tumor stages, providing novel insights into the complexity of the glycolytic pathway in the perspective of PDAC development and therapy.

Glycolysis and acute lung injury: A review

Acute lung injury is featured as diffuse pulmonary edema and persistent hypoxemia caused by lung or systemic injury. It is believed that these pathological changes are associated with damage to the alveolar epithelium and vascular endothelium, recruitment of inflammatory cells, and inflammatory factor storms. In recent years, the metabolic reprogramming of lung parenchymal cells and immune cells, particularly alterations in glycolysis, has been found to occur in acute lung injury. Inhibition of glycolysis can reduce the severity of acute lung injury. Thus, this review focuses on the interconnection between acute lung injury and glycolysis and the mechanisms of interaction, which may bring hope for the treatment of acute lung injury.

Identification of an optimized glycolytic-related risk signature for predicting the prognosis in breast cancer using integrated bioinformatic analysis.

Aberrant metabolic disorders and significant glycolytic alterations in tumor tissues and cells are hallmarks of breast cancer (BC) progression. This study aims to elucidate the key biomarkers and pathways mediating abnormal glycolysis in breast cancer using bioinformatics analysis. Differential genes expression analysis, gene ontology analysis, Kyoto encyclopedia of genes and genomes analysis, gene set enrichment analyses, and correlation analysis were performed to explore the expression and prognostic implications of glycolysis-related genes. We effectively integrated 4 genes to construct a prognostic model of shorter survival in the high-risk versus low-risk group. The prognostic model showed promising predictive value and may be an integral part of the prognosis of BC. The survival analysis and receiver operating characteristic curves suggested that the signature showed a good predictive performance in both the The Cancer Genome Atlas training set and 2 gene expression omnibus validation sets. Multivariable analysis demonstrated that the 4-gene signature had an independent prognostic value. Furthermore, all calibration curves exhibited robust validity in prognostic prediction. We established an optimized 4-gene signature to clarify the connection between glycolysis and BC, and offered an attractive platform for risk stratification and prognosis predication of BC patients.

Metabolic barriers in non-small cell lung cancer with LKB1 and/or KEAP1 mutations for immunotherapeutic strategies.

Currently, immune checkpoint inhibitors (ICIs) are widely considered the standard initial treatment for advanced non-small cell lung cancer (NSCLC) when there are no targetable driver oncogenic alternations. NSCLC tumors that have two alterations in tumor suppressor genes, such as liver kinase B1 (LKB1) and/or Kelch-like ECH-associated protein 1 (KEAP1), have been found to exhibit reduced responsiveness to these therapeutic strategies, as revealed by multiomics analyses identifying immunosuppressed phenotypes. Recent advancements in various biological approaches have gradually unveiled the molecular mechanisms underlying intrinsic reprogrammed metabolism in tumor cells, which contribute to the evasion of immune responses by the tumor. Notably, metabolic alterations in glycolysis and glutaminolysis have a significant impact on tumor aggressiveness and the remodeling of the tumor microenvironment. Since glucose and glutamine are essential for the proliferation and activation of effector T cells, heightened consumption of these nutrients by tumor cells results in immunosuppression and resistance to ICI therapies. This review provides a comprehensive summary of the clinical efficacies of current therapeutic strategies against NSCLC harboring LKB1 and/or KEAP1 mutations, along with the metabolic alterations in glycolysis and glutaminolysis observed in these cancer cells. Furthermore, ongoing trials targeting these metabolic alterations are discussed as potential approaches to overcome the extremely poor prognosis associated with this type of cancer.

β-HB treatment reverses sorafenib resistance by shifting glycolysis–lactate metabolism in HCC

Hepatocellular carcinoma (HCC) is the most common primary malignant tumor. Although sorafenib and regorafenib have been approved for first-line and second-line treatment, respectively, of patients with advanced HCC, long-term treatment often results in acquired resistance. Given that glycolysis-mediated lactate production can contribute to drug resistance and impair HCC treatment efficacy, we investigated the effects of ketone body treatment on the metabolic shift in sorafenib-resistant HCC cells. We discovered differential expression of 3-hydroxymethyl glutaryl-CoA synthase 2 (HMGCS2) and the ketone body D-β-hydroxybutyrate (β-HB) in four sorafenib-resistant HCC cell lines. In sorafenib-resistant HCC cells, lower HMGCS2 and β-HB levels were correlated with more glycolytic alterations and higher lactate production. β-HB treatment enhanced pyruvate dehydrogenase (PDH) expression and decreased lactate dehydrogenase (LDHA) expression and lactate production in sorafenib-resistant HCC cells. Additionally, β-HB combined with sorafenib or regorafenib promoted the antiproliferative and antimigratory abilities of sorafenib-resistant HCC cells by inhibiting the B-raf/mitogen-activated protein kinase pathway and mesenchymal N-cadherin-vimentin axis. Although the in vivo β-HB administration did not affect tumor growth, the expression of proliferative and glycolytic proteins was inhibited in subcutaneous sorafenib-resistant tumors. In conclusion, exogenous β-HB treatment can reduce lactate production and reverse sorafenib resistance by inducing a glycolytic shift; it can also synergize with regorafenib for treating sorafenib-resistant HCC.

Metabolic Profile of Individuals with and without Type 2 Diabetes from Sub-Saharan Africa.

Epidemiological data predicts that sub-Saharan Africa will have the largest increase in type 2 diabetes (T2D) prevalence over the next two decades. Metabolomics studies have identified biomarkers that could improve T2D diagnosis and follow-up. However, no studies have characterized the metabolome of people from sub-Saharan Africa. Plasma samples from Senegalese individuals with T2D (n = 31) or without T2D (n = 34) were compared using measures of oxidative stress damage and plasma antioxidant enzyme activity and mass-spectrometry-based metabolomics analyses. Results showed that glucose, lactate, and tricarboxylic acid metabolites (fumarate, malate, and succinate) were increased in the T2D group, suggesting alterations in glycolysis and mitochondrial dysfunction. Several amino acids (leucine, isoleucine, valine, and tryptophan) and long-to-very-long-chain fatty acids were higher in the T2D group. Finally, elevated levels of ketone bodies and acylcarnitines were observed along with increased levels of oxidative stress damage and antioxidant activity. In conclusion, the T2D group exhibited modifications in metabolites previously shown to be associated with T2D risk in populations from other areas of the world. Future studies should seek to test whether these metabolites could be used as predictors for T2D-related complications in people from sub-Saharan Africa.

NMR metabolomics in bladder cancer: Identification and monitoring of serum biomarkers during Pt-based treatment.

3057 Background: To date, predictive and prognostic biomarkers for Bladder Cancer (BC) are lacking. Metabolomics, the study of small molecules involved in metabolism, aims to identify diagnostic, predictive and prognostic biomarkers. Overall, BC shows perturbations of various metabolic pathways, involved in biochemical reactions essential for energy production and for the maintenance of the REDOX balance, as well as in the metabolism of purines and pyrimidines. The main objective of this study is to characterize the serum metabolic profile of patients with BC undergoing platinum-based chemotherapy (Pt-CT), to identify the alterations induced by CT and evaluate the associated deregulated metabolic pathways, in order to identify potential biomarkers, prognostic and predictive of response to treatment. Methods: We enrolled patients with BC undergoing Pt-CT in different settings (neoadjuvant, adjuvant or metastatic). For each patient, a blood sample was collected before the start of each CT cycle (T0, T1, Tn). Metabolomic analysis was performed using the Bruker Avance 600 spectrometer. At baseline (T0), the metabolomic profiles of BC patients were compared with that of age- and sex-matched healthy controls. Major metabolites up- or down-regulated in patients with BC at baseline, were then monitored during CT (T1, Tn). Results: 14 patients were enrolled. When compared with age- and sex-matched healthy controls, patients with BC had elevated levels of acetate and acetone (ketone bodies), hypoxanthine, trimethylamine N-oxide (TMAO), glutamate, lactate, phenylalanine, and ornithine, and decreased levels of carnitine, choline, betaine, aspartate, threonine, 2-hydroxybutyrate, 2-aminobutyrate and histidine. When monitored during CT, hypoxanthine, glutamate, and aspartate levels increased; acetone, acetate and TMAO instead had a decreasing trend. Conclusions: The results of our pilot study confirm perturbations in several metabolic pathways: up-regulation of lactate, ketone bodies, hypoxanthine, phenylalanine, and glutamate levels in BC patients reflects altered glycolysis, fatty acid, purine, and amino acid metabolism, respectively. In addition, TMAO may play a role in the development of BC by promoting a pro-inflammatory and oxidative stress state. Furthermore, monitoring these metabolites could be a useful tool for predicting response to treatments. To our knowledge, there are no metabolomic studies that evaluated BC patients receiving CT and that included longitudinal monitoring to identify any changes in the metabolic profile induced by treatment.

Metabolism heterogeneity in melanoma fuels deactivation of immunotherapy: Predict before protect.

Malignant melanoma is widely acknowledged as the most lethal skin malignancy. The metabolic reprogramming in melanoma leads to alterations in glycolysis and oxidative phosphorylation (OXPHOS), forming a hypoxic, glucose-deficient and acidic tumor microenvironment which inhibits the function of immune cells, resulting in a low response rate to immunotherapy. Therefore, improving the tumor microenvironment by regulating the metabolism can be used to improve the efficacy of immunotherapy. However, the tumor microenvironment (TME) and the metabolism of malignant melanoma are highly heterogeneous. Therefore, understanding and predicting how melanoma regulates metabolism is important to improve the local immune microenvironment of the tumor, and metabolism regulators are expected to increase treatment efficacy in combination with immunotherapy. This article reviews the energy metabolism in melanoma and its regulation and prediction, the integration of immunotherapy and metabolism regulators, and provides a comprehensive overview of future research focal points in this field and their potential application in clinical treatment.

MiR-1285-3p targets TPI1 to regulate the glycolysis metabolism signaling pathway of Tibetan sheep Sertoli cells.

Glycolysis in Sertoli cells (SCs) can provide energy substrates for the development of spermatogenic cells. Triose phosphate isomerase 1 (TPI1) is one of the key catalytic enzymes involved in glycolysis. However, the biological function of TPI1 in SCs and its role in glycolytic metabolic pathways are poorly understood. On the basis of a previous research, we isolated primary SCs from Tibetan sheep, and overexpressed TPI1 gene to determine its effect on the proliferation, glycolysis, and apoptosis of SCs. Secondly, we investigated the relationship between TPI1 and miR-1285-3p, and whether miR-1285-3p regulates the proliferation and apoptosis of SCs, and participates in glycolysis by targeting TPI1. Results showed that overexpression of TPI1 increased the proliferation rate and decreased apoptosis of SCs. In addition, overexpression of TPI1 altered glycolysis and metabolism signaling pathways and significantly increased amount of the final product lactic acid. Further analysis showed that miR-1285-3p inhibited TPI1 by directly targeting its 3'untranslated region. Overexpression of miR-1285-3p suppressed the proliferation of SCs, and this effect was partially reversed by restoration of TPI1 expression. In summary, this study shows that the miR-1285-3p/TPI1 axis regulates glycolysis in SCs. These findings add to our understanding on the regulation of spermatogenesis in sheep and other mammals.

Distinct role of mitochondrial function and protein kinase C in intimal and medial calcification in vitro.

IntroductionVascular calcification (VC) is a major risk factor for cardiovascular morbidity and mortality. Depending on the location of mineral deposition within the arterial wall, VC is classified as intimal and medial calcification. Using in vitro mineralization assays, we developed protocols triggering both types of calcification in vascular smooth muscle cells (SMCs) following diverging molecular pathways.Materials and methods and resultsHuman coronary artery SMCs were cultured in osteogenic medium (OM) or high calcium phosphate medium (CaP) to induce a mineralized extracellular matrix. OM induces osteoblast-like differentiation of SMCs–a key process in intimal calcification during atherosclerotic plaque remodeling. CaP mimics hyperphosphatemia, associated with chronic kidney disease–a risk factor for medial calcification. Transcriptomic analysis revealed distinct gene expression profiles of OM and CaP-calcifying SMCs. OM and CaP-treated SMCs shared 107 differentially regulated genes related to SMC contraction and metabolism. Real-time extracellular efflux analysis demonstrated decreased mitochondrial respiration and glycolysis in CaP-treated SMCs compared to increased mitochondrial respiration without altered glycolysis in OM-treated SMCs. Subsequent kinome and in silico drug repurposing analysis (Connectivity Map) suggested a distinct role of protein kinase C (PKC). In vitro validation experiments demonstrated that the PKC activators prostratin and ingenol reduced calcification triggered by OM and promoted calcification triggered by CaP.ConclusionOur direct comparison results of two in vitro calcification models strengthen previous observations of distinct intracellular mechanisms that trigger OM and CaP-induced SMC calcification in vitro. We found a differential role of PKC in OM and CaP-calcified SMCs providing new potential cellular and molecular targets for pharmacological intervention in VC. Our data suggest that the field should limit the generalization of results found in in vitro studies using different calcification protocols.

Podocyte specific deletion of PKM2 ameliorates LPS-induced podocyte injury through beta-catenin

BackgroundAcute kidney injury (AKI) is associated with a severe decline in kidney function caused by abnormalities within the podocytes' glomerular matrix. Recently, AKI has been linked to alterations in glycolysis and the activity of glycolytic enzymes, including pyruvate kinase M2 (PKM2). However, the contribution of this enzyme to AKI remains largely unexplored.MethodsCre-loxP technology was used to examine the effects of PKM2 specific deletion in podocytes on the activation status of key signaling pathways involved in the pathophysiology of AKI by lipopolysaccharides (LPS). In addition, we used lentiviral shRNA to generate murine podocytes deficient in PKM2 and investigated the molecular mechanisms mediating PKM2 actions in vitro.ResultsSpecific PKM2 deletion in podocytes ameliorated LPS-induced protein excretion and alleviated LPS-induced alterations in blood urea nitrogen and serum albumin levels. In addition, PKM2 deletion in podocytes alleviated LPS-induced structural and morphological alterations to the tubules and to the brush borders. At the molecular level, PKM2 deficiency in podocytes suppressed LPS-induced inflammation and apoptosis. In vitro, PKM2 knockdown in murine podocytes diminished LPS-induced apoptosis. These effects were concomitant with a reduction in LPS-induced activation of β-catenin and the loss of Wilms’ Tumor 1 (WT1) and nephrin. Notably, the overexpression of a constitutively active mutant of β-catenin abolished the protective effect of PKM2 knockdown. Conversely, PKM2 knockdown cells reconstituted with the phosphotyrosine binding–deficient PKM2 mutant (K433E) recapitulated the effect of PKM2 depletion on LPS-induced apoptosis, β-catenin activation, and reduction in WT1 expression.ConclusionsTaken together, our data demonstrates that PKM2 plays a key role in podocyte injury and suggests that targetting PKM2 in podocytes could serve as a promising therapeutic strategy for AKI.Trial registrationNot applicable.66jzd3p7x7ZtqB-vdEamwaVideo abstract