PurposeWe used targeted mass spectrometry to study the metabolic fingerprint of urothelial cancer and determine whether the biochemical pathway analysis gene signature would have a predictive value in independent cohorts of patients with bladder cancer.Materials and MethodsPathologically evaluated, bladder derived tissues, including benign adjacent tissue from 14 patients and bladder cancer from 46, were analyzed by liquid chromatography based targeted mass spectrometry. Differential metabolites associated with tumor samples in comparison to benign tissue were identified by adjusting the p values for multiple testing at a false discovery rate threshold of 15%. Enrichment of pathways and processes associated with the metabolic signature were determined using the GO (Gene Ontology) Database and MSigDB (Molecular Signature Database). Integration of metabolite alterations with transcriptome data from TCGA (The Cancer Genome Atlas) was done to identify the molecular signature of 30 metabolic genes. Available outcome data from TCGA portal were used to determine the association with survival.ResultsWe identified 145 metabolites, of which analysis revealed 31 differential metabolites when comparing benign and tumor tissue samples. Using the KEGG (Kyoto Encyclopedia of Genes and Genomes) Database we identified a total of 174 genes that correlated with the altered metabolic pathways involved. By integrating these genes with the transcriptomic data from the corresponding TCGA data set we identified a metabolic signature consisting of 30 genes. The signature was significant in its prediction of survival in 95 patients with a low signature score vs 282 with a high signature score (p = 0.0458).ConclusionsTargeted mass spectrometry of bladder cancer is highly sensitive for detecting metabolic alterations. Applying transcriptome data allows for integration into larger data sets and identification of relevant metabolic pathways in bladder cancer progression.
African American (AA) men have a 60% higher incidence and two times greater risk of dying of prostate cancer (PCa) than European American men, yet there is limited insight into the molecular mechanisms driving this difference. To our knowledge, metabolic alterations, a cancer-associated hallmark, have not been reported in AA PCa, despite their importance in tumor biology. Therefore, we measured 190 metabolites across ancestry-verified AA PCa/benign adjacent tissue pairs (n = 33 each) and identified alterations in the methionine-homocysteine pathway utilizing two-sided statistical tests for all comparisons. Consistent with this finding, methionine and homocysteine were elevated in plasma from AA PCa patients using case-control (AA PCa vs AA control, methionine: P = .0007 and homocysteine: P < .0001), biopsy cohorts (AA biopsy positive vs AA biopsy negative, methionine: P = .0002 and homocysteine: P < .0001), and race assignments based on either self-report (AA PCa vs European American PCa, methionine: P = .001, homocysteine: P < .0001) or West African ancestry (upper tertile vs middle tertile, homocysteine: P < .0001; upper tertile vs low tertile, homocysteine: P = .002). These findings demonstrate reprogrammed metabolism in AA PCa patients and provide a potential biological basis for PCa disparities.
African-American (AA) men are more than twice as likely to die of prostate cancer (PCa) than European American (EA) men. Previous in silico analysis revealed enrichment of altered lipid metabolic pathways in pan-cancer AA tumors. Here, we performed global unbiased lipidomics profiling on 48 matched localized PCa and benign adjacent tissues (30 AA, 24 ancestry-verified, and 18 EA, 8 ancestry verified) and quantified 429 lipids belonging to 14 lipid classes. Significant alterations in long chain polyunsaturated lipids were observed between PCa and benign adjacent tissues, low and high Gleason tumors, as well as associated with early biochemical recurrence, both in the entire cohort, and within AA patients. Alterations in cholesteryl esters, and phosphatidyl inositol classes of lipids delineated AA and EA PCa, while the levels of lipids belonging to triglycerides, phosphatidyl glycerol, phosphatidyl choline, phosphatidic acid, and cholesteryl esters distinguished AA and EA PCa patients with biochemical recurrence. These first-in-field results implicate lipid alterations as biological factors for prostate cancer disparities.
African-American (AA) men have a 60% higher incidence of prostate cancer compared to European-American (EA) men and tend to have a more aggressive clinical outcome. An understanding of the altered biological responses and the factors that lead to health disparity in prostate cancer development and progression is unclear. Metabolism defines the physiological state of the cell and metabolic reprogramming is a hallmark of cancer. Thus, studying the metabolic landscape will be critical for understanding the biological changes that might contribute to this disparity. Analysis of 190 metabolites across prostate cancer/benign adjacent tissue pairs from ancestry typed AA and EA men performed in our laboratory, revealed altered levels of nucleosides adenosine and inosine. High inosine to adenosine ratio is observed in AA men compared to EA men. In line with this finding, the enzyme adenosine deaminase (ADA), which converts adenosine to inosine was found elevated in AA men, potentially explaining the high inosine to adenosine ratio in AA PCa. The consequences of the accumulation of these metabolites on AA PCa progression are unknown. The current study will address the knowledge gap on the consequences of elevated ADA activity in AA PCa and attempt to dissect its role in effecting an aggressive phenotype in PCa. To determine the role of elevated ADA in PCa, it was overexpressed in ancestry-typed AA (MDA-PCa-2A) and EA PCa(LNCaP) cell lines (termed ADA OE). Phenotypic examination of these cells revealed increased ADA enzyme activity decreases the cell-ECM adhesion. This adhesion decrease is facilitated by a decrease in cell adhesion protein integrin β1 (ITGB1). Elevated ADA enzyme activity decreases cAMP which mediates this adhesion decrease by disrupting the Epac-Rap1 pathway. It is postulated that high inosine upon ADA OE activates adenosine receptors A1 and A3, which causes this decrease in cAMP levels. These molecular findings suggest that ADA-mediated adhesion decrease could facilitate metastatic dissemination from the primary tumor. From a translational viewpoint, ADA enzyme activity could serve as a biomarker for metastatic prostate cancer. Therefore, we further look to analyze the inosine to adenosine levels (ADA enzyme activity) in patient samples and correlate with various clinical outcomes in PCa. Our initial analysis reveals high inosine to adenosine ratio in biopsy positive patient samples compared to biopsy negative samples. Our next steps of analysis include correlating the enzyme activity with (i) Biochemical Recurrence (ii) Time to attaining castration resistance in castration sensitive patients (iii) Time to metastasis (iv) Response to Androgen deprivation in patients after BCr. Based on our current findings, we expect inosine to adenosine ratio in plasma or urine to serve as a predictive marker for PCa incidence or progression in AA men. In addition, we expect ADA to serve as a potential therapeutic target for AA PCa. Citation Format: Christy Charles, Jie Gohlke, Stacy Lloyd, Uttam Rasaily, James Henderson, Balasubramanyam Karanam, Brian Simons, Nora Navone, Rick Kittles, Stefan Ambs, George Michailidis, Nagireddy Putluri, Arun Sreekumar. Metabolic re-wiring in African-American prostate cancer: A role of adenosine-inosine axis [abstract]. In: Proceedings of the AACR Virtual Conference: Thirteenth AACR Conference on the Science of Cancer Health Disparities in Racial/Ethnic Minorities and the Medically Underserved; 2020 Oct 2-4. Philadelphia (PA): AACR; Cancer Epidemiol Biomarkers Prev 2020;29(12 Suppl):Abstract nr PR17.
African Americans (AA) are two times more likely to be diagnosed with and succumb to prostate cancer (PCa) compared to European Americans (EA). There is mounting evidence that biological differences in these tumors contribute to disparities in patient outcomes. Our goal was to examine the differences in DNA damage in AA and EA prostate tissues. Tissue microarrays with matched tumor-benign adjacent pairs from 77 AA and EA PCa patients were analyzed for abasic sites, oxidative lesions, crosslinks, and uracil content using the Repair Assisted Damage Detection (RADD) assay. Our analysis revealed that AA PCa, overall, have more DNA damage than EA PCa. Increased uracil and pyrimidine lesions occurred in AA tumors, while EA tumors had more oxidative lesions. AA PCa have higher levels of UMP and folate cycle metabolites than their EA counterparts. AA PCa showed higher levels of UNG, the uracil-specific glycosylase, than EA, despite uracil lesions being retained within the genome. AA patients also had lower levels of the base excision repair protein XRCC1. These results indicate dysfunction in the base excision repair pathway in AA tumors. Further, these findings reveal how metabolic rewiring in AA PCa drives biological disparities and identifies a targetable axis for cancer therapeutics.
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 glutaminederived [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.
Prostate cancer (PCa) is the second most common cancer and constitutes about 14.7% of total cancer cases. PCa is highly prevalent and more aggressive in African American (AA) men when compared to European-American (EA) men. PCa tends to be a highly heterogeneous malignancy with a complex biology that is not fully understood. We use metabolomics as a tool to understand the mechanisms behind PCa progression and disparities in its clinical outcome. A key enzyme in the purine metabolic pathway, Adenosine deaminase (ADA) was found upregulated in PCa. ADA was also associated with higher-grade PCa and poor disease-free survival. The inosine-to-adenosine ratio which is a surrogate for ADA activity was high in the urine of PCa patients and higher in AA PCa compared to EA PCa. To understand the significance of high ADA in PCa, we established ADA overexpression models and performed various in vitro and in vivo studies. Our studies have revealed that an acute increase in the expression of ADA during later stages of tumor development enhances in vivo growth in multiple pre-clinical models. Further analysis reveals that this tumor growth could be driven by the activation of mTOR signaling. Chronic ADA overexpression shows alterations in the cell adhesion machinery and a decrease in the adhesion potential of the cells to the extracellular matrix in vitro. Loss of cell-matrix interaction is critical for metastatic dissemination, suggestive of the role of ADA in promoting metastasis. This is consistent with the association of higher ADA expression with higher-grade tumors and poor patient survival. Overall, our findings suggest that increased ADA expression may promote PCa progression, specifically tumor growth and metastatic dissemination.
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. 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 may contribute to PCa health disparities and also delineate mechanistic biological pathways. 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, and gene set enrichment (GSEA) analysis was performed. 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. Biological validation was performed using tissue microarrays, qPCR, and western blots. Results: Unique biochemical alterations associated with AA tumors were identified. Relative to EA tumors, AA tumors had significant alterations in the cysteine/methionine pathway; specifically accumulations of adenosine were most prominent in AA PCa, as well as urine. Protein and transcript levels of Adenosine Deaminase (ADA), an enzyme that converts SAM-derived adenosine to inosine was significantly down regulated in AA PCa, a finding validated in both tissue and cell lines. GSEA analysis revealed that genes involved in the immune system were prominent among AA PCa compared to EA PCa. To this end, significant inverse correlations between ADA and CD4+, CD8+, and CD68+ levels were also identified. Conclusions: Taken together, this integromics approach generated data that alludes to the existence of an efficient immune escape mechanism in AA PCa, which may explain the disparity facing AA men with PCa. Citation Format: Stacy M. Lloyd, Jie Gohlke, Sumanta Basu, Salil Bhowmik, Vasanta Putluri, Kimal Rajapakshe, Cristian Coarfa, 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 Ninth AACR Conference on the Science of Cancer Health Disparities in Racial/Ethnic Minorities and the Medically Underserved; 2016 Sep 25-28; Fort Lauderdale, FL. Philadelphia (PA): AACR; Cancer Epidemiol Biomarkers Prev 2017;26(2 Suppl):Abstract nr PR10.
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