Salil Kumar Bhowmik

Fatty Acid Oxidation-Driven Src Links Mitochondrial Energy Reprogramming and Oncogenic Properties in Triple-Negative Breast Cancer

Transmitochondrial cybrids and multiple OMICs approaches were used to understand mitochondrial reprogramming and mitochondria-regulated cancer pathways in triple-negative breast cancer (TNBC). Analysis of cybrids and established breast cancer (BC) cell lines showed that metastatic TNBC maintains high levels of ATP through fatty acid β oxidation (FAO) and activates Src oncoprotein through autophosphorylation at Y419. Manipulation of FAO including the knocking down of carnitine palmitoyltransferase-1A (CPT1) and 2 (CPT2), the rate-limiting proteins of FAO, and analysis of patient-derived xenograft models confirmed the role of mitochondrial FAO in Src activation and metastasis. Analysis of TCGA and other independent BC clinical data further reaffirmed the role of mitochondrial FAO and CPT genes in Src regulation and their significance in BC metastasis.

Coactivator SRC-2–dependent metabolic reprogramming mediates prostate cancer survival and metastasis

Metabolic pathway reprogramming is a hallmark of cancer cell growth and survival and supports the anabolic and energetic demands of these rapidly dividing cells. The underlying regulators of the tumor metabolic program are not completely understood; however, these factors have potential as cancer therapy targets. Here, we determined that upregulation of the oncogenic transcriptional coregulator steroid receptor coactivator 2 (SRC-2), also known as NCOA2, drives glutamine-dependent de novo lipogenesis, which supports tumor cell survival and eventual metastasis. SRC-2 was highly elevated in a variety of tumors, especially in prostate cancer, in which SRC-2 was amplified and overexpressed in 37% of the metastatic tumors evaluated. In prostate cancer cells, SRC-2 stimulated reductive carboxylation of α-ketoglutarate to generate citrate via retrograde TCA cycling, promoting lipogenesis and reprogramming of glutamine metabolism. Glutamine-mediated nutrient signaling activated SRC-2 via mTORC1-dependent phosphorylation, which then triggered downstream transcriptional responses by coactivating SREBP-1, which subsequently enhanced lipogenic enzyme expression. Metabolic profiling of human prostate tumors identified a massive increase in the SRC-2-driven metabolic signature in metastatic tumors compared with that seen in localized tumors, further implicating SRC-2 as a prominent metabolic coordinator of cancer metastasis. Moreover, SRC-2 inhibition in murine models severely attenuated the survival, growth, and metastasis of prostate cancer. Together, these results suggest that the SRC-2 pathway has potential as a therapeutic target for prostate cancer.

Pathway-Centric Integrative Analysis Identifies RRM2 as a Prognostic Marker in Breast Cancer Associated with Poor Survival and Tamoxifen Resistance

Breast cancer (BCa) molecular subtypes include luminal A, luminal B, normal-like, HER-2–enriched, and basal-like tumors, among which luminal B and basal-like cancers are highly aggressive. Biochemical pathways associated with patient survival or treatment response in these more aggressive subtypes are not well understood. With the limited availability of pathologically verified clinical specimens, cell line models are routinely used for pathway-centric studies. We measured the metabolome of luminal and basal-like BCa cell lines using mass spectrometry, linked metabolites to biochemical pathways using Gene Set Analysis, and developed a novel rank-based method to select pathways on the basis of their enrichment in patient-derived omics data sets and prognostic relevance. Key mediators of the pathway were then characterized for their role in disease progression. Pyrimidine metabolism was altered in luminal versus basal BCa, whereas the combined expression of its associated genes or expression of one key gene, ribonucleotide reductase subunit M2 (RRM2) alone, associated significantly with decreased survival across all BCa subtypes, as well as in luminal patients resistant to tamoxifen. Increased RRM2 expression in tamoxifen-resistant patients was verified using tissue microarrays, whereas the metabolic products of RRM2 were higher in tamoxifen-resistant cells and in xenograft tumors. Both genetic and pharmacological inhibition of this key enzyme in tamoxifen-resistant cells significantly decreased proliferation, reduced expression of cell cycle genes, and sensitized the cells to tamoxifen treatment. Our study suggests for evaluating RRM2-associated metabolites as noninvasive markers for tamoxifen resistance and its pharmacological inhibition as a novel approach to overcome tamoxifen resistance in BCa.

EMT-induced metabolite signature identifies poor clinical outcome

Metabolic reprogramming is a hallmark of cancer. Epithelial-mesenchymal transition (EMT) induces cancer stem cell (CSC) characteristics and promotes tumor invasiveness; however relatively little is known about the metabolic reprogramming in EMT. Here we show that breast epithelial cells undergo metabolic reprogramming following EMT. Relative to control, cell lines expressing EMT transcription factors show ≥1.5-fold accumulation of glutamine, glutamate, beta-alanine and glycylleucine as well as ≥1.5-fold reduction of phosphoenolpyruvate, urate, and deoxycarnitine. Moreover, these metabolic alterations were found to be predictive of overall survival (hazard ratio = 2.3 (95% confidence interval: 1.31–4.2), logrank p-value = 0.03) and define breast cancer molecular subtypes. EMT-associated metabolites are primarily composed of anapleurotic precursors, suggesting that cells undergoing EMT have a shift in energy production. In summary, we describe a unique panel of metabolites associated with EMT and demonstrate that these metabolites have the potential for predicting clinical and biological characteristics associated with patient survival.

A Novel [15N] Glutamine Flux using LC-MS/MS-SRM for Determination of Nucleosides and Nucleobases

The growth of cancer cells relies more on increased proliferation and autonomy compared to non-malignant cells. The rate of de novo nucleotide biosynthesis correlates with cell proliferation rates. In part, glutamine is needed to sustain high rates of cellular proliferation as a key nitrogen donor in purine and pyrimidine nucleotide biosynthesis. In addition, glutamine serves as an essential substrate for key enzymes involved in the de novo synthesis of purine and pyrimidine nucleotides. Here, we developed a novel liquid chromatography (LC-MS) to quantify glutamine-derived [15N] nitrogen flux into nucleosides and nucleobases (purines and pyrimidines). For this, DNA from 5637 bladder cancer cell line cultured in 15N labelled glutamine and then enzymatically hydrolyzed by sequential digestion. Subsequently, DNA hydrolysates were separated by LC-MS and Selected Reaction Monitoring (SRM) was employed to identify the nucleobases and nucleosides. Thus, high sensitivity and reproducibility of the method make it a valuable tool to identify the nitrogen flux primarily derived from glutamine and can be further adaptable for high throughput analysis of large set of DNA in a clinical setting.

Application of 13C isotope labeling using liquid chromatography mass spectrometry (LC-MS) to determining phosphate-containing metabolic incorporation

Here, we describe an approach wherein negative electrospray ionization mass spectrometry has used to understand the relative flux through phosphate containing metabolic intermediates associated with central carbon metabolism after administering cells with 13C-labeled substrates. The method was applied to examine the 13C incorporation through glycolysis in T47D breast cancer cells and showed reduction of glycolytic relative flux upon treatment with 2-Deoxyglucose. Copyright

Abstract B92: Metabolomic landscape of African American prostate cancer: Insights into the biologic basis of the racial disparity

African American (AA) men have an approximately 60% higher incidence of prostate cancer (PCa) and have about two times greater risk of dying of the disease than their European American (EA) counterparts. Despite this staggeringly unequal burden of PCa incidence and outcome between AA and EA men, there is limited insight into the molecular mechanisms associated with this racial disparity. Using state-of-the-art mass spectrometry platform, we uncovered the very first metabolic and lipidomics landscape in PCa/benign adjacent tissue pairs and paired plasma and urine containing epidemiologic meta-data from ancestry-typed AA and EA men. A total of 190 polar and mid-polar metabolites and 495 lipids were measured in tissues and 183 metabolites and lipids were examined in the plasma and urine samples. AA PCa tissue and plasma signatures had unique alterations in metabolites and key enzymes associated with the methionine-homocysteine pathway, including adenosine and inosine levels, compared to corresponding tissues and plasma from EA case controls and EA PCa tissues. Intriguingly, methionine levels in AA PCa were also portrayed by distinct dietary practices in these patients. In addition, AA PCa tissues demonstrated unique patterns of bioenergetic metabolites and accumulated lipids reflecting impaired mitochondrial activity and TCA cycle. Further characterization of these first-in-the-field findings demonstrating reprogrammed metabolism in AA PCa relative to EA tumors could reveal insights into the biologic basis of PCa disparities and novel areas for therapeutic intervention. Citation Format: Stacy M. Lloyd*, Jie H. Gohlke*, Sumanta Basu*, Vasanta Putluri,Shaiju K Vareed, Rebeca San Martin, Thekkelnaycke Rajendiran, Tiffany A. Dorsey, Bandana Prasad, Rajni Sonavane, Uttam Rasaily, James Henderson, Balasubramanyam Karanam, Harene Venghatakrishnan, Salil Bhowmik, Alexander Zaslavsky,Nilanjan Guha, Rick Kittles, Stefan Ambs, Michael Ittmann,David Rowley, Ganesh Palapattu, Nagireddy Putluri,George Michailidis, Arun Sreekumar. Metabolomic landscape of African American prostate cancer: Insights into the biologic basis of the racial disparity [abstract]. In: Proceedings of the Tenth AACR Conference on the Science of Cancer Health Disparities in Racial/Ethnic Minorities and the Medically Underserved; 2017 Sep 25-28; Atlanta, GA. Philadelphia (PA): AACR; Cancer Epidemiol Biomarkers Prev 2018;27(7 Suppl):Abstract nr B92.

Abstract A65: An integromics approach identifies immune escape as a potential mechanism for prostate cancer disparities

Background: AA men with PCa will die at a rate nearly 2.5 times higher than their EA counterparts. Presently, no mechanism has been described to explain the differences observed between AA and EA men with PCa; yet, many have interrogated the role of social and anthropometric data on PCa outcomes within these populations. However, when these factors are statistically controlled, the differences in incidence, morbidity, and mortality between AA and EA PCa persist. These findings support the notion that biological factors are one of the major driving forces of PCa disparities. Therefore, to obtain better insights into the molecular aspects of PCa disparities, we examined metabolomic and gene expression profiles of PCa and matched adjacent benign tissue from AA and EA men. Metabolomics is defined as the study of all the small molecule metabolites produced by cellular processes in the body. We hypothesize that racially distinct metabolic pathways and the associated bioprocesses, may contribute to PCa health disparities Methodology: A total of 190 polar and mid-polar metabolites were measured using mass spectrometry across 50 and 28 PCa/benign tissue pairs from AA and EA men, respectively. Likewise, gene expression microarray analysis was performed on 48 and 21 PCa/benign tissue pairs from AA and EA men. Ancestry informative markers were genotyped and ancestry estimates were determined. Metabolic profiles of AA and EA PCa and benign adjacent pairs were compared using paired t-tests. FDR corrected p-values were used to detect differential metabolites and genes. Results: Unique biochemical alterations associated with AA tumors were identified. Pathways such as cysteine/methionine, arginine/proline and de novo purine biosynthesis were enhanced in AA PCa. Metabolites such as cystathione, cysteine, and S-Adenosylhomocysteine (SAH), are elevated in AA PCa compared to matched adjacent benign. Consistent with this, transcript and protein levels of DNA Methyl Transferase 1 (DNMT1) and Cystathione Beta Synthase (CBS) were elevated in AA PCa tissues and cell lines. Interestingly, protein and transcript levels of Adenosine Deaminase, an enzyme that converts SAM-derived adenosine to inosine was significantly down regulated in AA PCa, both in tissues and cell lines. Consistent with this, accumulated levels of adenosine were found in AA PCa. Conclusions: Taken together, the metabolomics data alludes to the existence of an efficient immune escape mechanism in AA PCa. Corroborating this, analysis of gene expression data from AA men with PCa also reveals enriched immune escape pathways. Citation Format: Stacy M. Lloyd, Jie Gohlke, Sumanta Basu, Salil Bhowmik, Vasanta Putluri, Rashmi Krishnapurnam, Kimal Rajapakshe, Cristian Coarfa, Nilanjan Guha, SA Deepak, Arunkumar Padmanabhan, Mohammed Sayeeduddin, Patricia Castro, Michael Ittmann, Ganesh Palapattu, Nagireddy Putluri, George Michailidis, Arun Sreekumar. An integromics approach identifies immune escape as a potential mechanism for prostate cancer disparities. [abstract]. In: Proceedings of the Eighth AACR Conference on The Science of Health Disparities in Racial/Ethnic Minorities and the Medically Underserved; Nov 13-16, 2015; Atlanta, GA. Philadelphia (PA): AACR; Cancer Epidemiol Biomarkers Prev 2016;25(3 Suppl):Abstract nr A65.