Castellnou Pilar, Gómez-Martínez María, Gómez-Vallejo Vanessa, Baz Zuriñe, López-Gallego Fernando, Rondon-Lorefice Ivana, Zabala-Letona Amaia, Poot Alex J, Mendizabal Isabel, Carracedo Arkaitz, Rejc Luka, Llop Jordi
CIC biomaGUNE, Basque Research and Technology Alliance (BRTA), 20014 San Sebastian, Spain.
CIC biomaGUNE, Basque Research and Technology Alliance (BRTA), 20014 San Sebastian, Spain; IKERBASQUE, Basque Foundation for Science, 48009 Bilbao, Spain.
Nucl Med Biol. 2025 Jun 30;148-149:109048. doi: 10.1016/j.nucmedbio.2025.109048.
Cancer cells often exhibit aberrant cellular metabolism, with a common characteristic being their reliance on anaerobic glucose utilization. Prostate cancer (PC), however, displays unique metabolic profiles that extend beyond glycolysis, notably incorporating amino acid metabolism. This divergence in metabolic patterns opens potential avenues for targeted therapeutic strategies using D-amino acids. In this work, we investigated the biodistribution and tumour accumulation of D- and L-[methyl-C]alanine using positron emission tomography (PET) imaging in a genetic mouse model of prostate cancer.
D- and L-[methyl-C]alanine were synthesized according to established protocols. Conditional PTEN knockout mice (n = 6) were used as a model for prostate cancer. Dynamic PET-CT scans were performed for 60 min immediately following intravenous administration of the radiolabelled amino acids at the ages of 4 and 7 months. PET images were reconstructed, and volumes of interest (VOIs) were delineated in major organs, including the prostate and bladder. Dynamic time-activity curves (TACs) were analysed in terms of Standardized Uptake Values (SUV). After imaging, samples of the reproductive system were collected for static PET-CT imaging and subsequent histological analysis.
L- and D-[methyl-C]alanine were synthesized with good radiochemical yields and high enantiomeric excess using enantioselective alkylation with [C]methyl iodide in the presence of a chiral phase transfer catalysts. PET imaging of a genetic faithful mouse model of prostate cancer demonstrated that D-[methyl-C]alanine exhibited faster blood clearance, higher age-dependent kidney retention, and greater prostate lesion uptake at 7 months compared to L-[methyl-C]alanine. Histological analysis confirmed malignant lesions in the prostate of PTEN knockout mice, corroborating the PET imaging findings.
Our study offers valuable insights into the metabolic landscape of prostate cancer using a genetic mouse model that closely mimics human disease pathogenesis. The significantly greater accumulation of D-[methyl-C]alanine compared to its L-enantiomer underscores the potential of D-amino acids as biomarkers, and their potential use to interfere with cancer cell metabolism.
癌细胞通常表现出异常的细胞代谢,其一个共同特征是依赖无氧葡萄糖利用。然而,前列腺癌(PC)展现出独特的代谢特征,不仅局限于糖酵解,还显著涉及氨基酸代谢。这种代谢模式的差异为使用D - 氨基酸的靶向治疗策略开辟了潜在途径。在这项研究中,我们利用正电子发射断层扫描(PET)成像技术,在前列腺癌基因小鼠模型中研究了D - 和L - [甲基 - C]丙氨酸的生物分布和肿瘤蓄积情况。
根据既定方案合成D - 和L - [甲基 - C]丙氨酸。将条件性PTEN基因敲除小鼠(n = 6)用作前列腺癌模型。在4个月和7个月龄时,静脉注射放射性标记氨基酸后立即进行60分钟的动态PET - CT扫描。重建PET图像,并在包括前列腺和膀胱在内的主要器官中划定感兴趣区(VOIs)。根据标准化摄取值(SUV)分析动态时间 - 活性曲线(TACs)。成像后,收集生殖系统样本进行静态PET - CT成像及后续组织学分析。
在 chiral 相转移催化剂存在下,通过与[C]甲基碘进行对映选择性烷基化反应,以良好的放射化学产率和高对映体过量合成了L - 和D - [甲基 - C]丙氨酸。前列腺癌基因忠实小鼠模型的PET成像显示,与L - [甲基 - C]丙氨酸相比,D - [甲基 - C]丙氨酸在7个月时表现出更快的血液清除率、更高的年龄依赖性肾脏滞留以及更高的前列腺病变摄取量。组织学分析证实了PTEN基因敲除小鼠前列腺中的恶性病变,证实了PET成像结果。
我们的研究利用紧密模拟人类疾病发病机制的基因小鼠模型,为前列腺癌的代谢格局提供了有价值的见解。与L - 对映体相比,D - [甲基 - C]丙氨酸的显著更高蓄积突出了D - 氨基酸作为生物标志物的潜力,以及它们干扰癌细胞代谢的潜在用途。
