Abstract Prostate cancer (PCa), the most common male cancer worldwide, causes about 10% of cancer related deaths in Europe. It has a wide spectrum of clinical behavior that ranges from decades of indolence to rapid metastatic progression and lethality. However, the molecular mechanisms involved in aggressive PCa progression are still poorly understood. In PCa the expression of anoctamin 7 (ANO7) has been shown to diminish as the cancer progresses. We have previously linked single-nucleotide polymorphisms in the ANO7 gene to the risk of aggressive prostate cancer and shown that in homozygous carriers of rs77559646, the variant leads to a total loss of ANO7 protein. ANO7 is a prostate-specific gene and is highly expressed in the luminal cells of the human prostate. ANO7 belongs to a family of calcium-activated chloride channels and select members of the anoctamin family have phospholipid scramblase activity. To uncover the cellular functions of ANO7 has proven challenging because ANO7 is not expressed in commercially available cell lines. To study the cellular functions of ANO7, we have generated stable prostate cell lines overexpressing ANO7 using lentiviral transduction. To gain information into what pathways ANO7 is affecting, we performed RNA-sequencing and gene set enrichment analysis. Interestingly, we found enrichment and downregulation of mitochondrial genes participating in oxidative phosphorylation in ANO7 cells. We assessed the mitochondrial function by measuring the oxidative phosphorylation capability of the cells and showed that the basal and maximal respiratory capacity of ANO7 overexpressing cells is indeed reduced. We also analyzed which of the three major mitochondrial fuels (glucose, glutamine and fatty acids) are not used as efficiently for oxidative phosphorylation in ANO7 overexpressing cells. The result proves that ANO7 cells are not utilizing glucose as effectively as control cells. Furthermore, the glycolysis stress assay showed that glycolytic capacity is increased in ANO7 overexpressing cells. In addition, a targeted metabolite screening revealed that aspartate is decreased in ANO7 cells, which again points towards perturbed mitochondrial function as aspartate is produced from a tricarboxylic acid cycle intermediate. By inhibiting the uptake of extracellular aspartate, we measured slower proliferation of ANO7 expressing cells, while inhibiting aspartate had no effect on control cells. Interestingly, preliminary results also suggest ANO7's involvement in regulation of phospholipid acyl chain length and saturation, offering insights into altered signaling observed in ANO7 cells. Taken together, this study shows for the first time that ANO7 rewires prostate mitochondrial functions and thus cellular metabolism, which could explain why it is beneficial for cancer cells to lose ANO7 expression. Citation Format: Christoffer Löf, Nasrin Sultana, Neha Goel, Gudrun Wahlström, Johanna Schleutker. The role of aggressive prostate cancer risk gene ANO7 in prostate metabolism [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 7056.
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