L-5-[11C]-谷氨酰胺PET对乳腺癌小鼠模型的临床前研究

IF 3 4区医学 Q1 RADIOLOGY, NUCLEAR MEDICINE & MEDICAL IMAGING

Nuclear medicine and biology Pub Date : 2025-11-01 Epub Date: 2025-08-30 DOI:10.1016/j.nucmedbio.2025.109092

Christopher T. Hensley , Prashanth Padakanti , Raheema Damani , Christina Dulal , Hoon Choi , Shihong Li , Jianbo Cao , Hsiaoju Lee , Austin Pantel , Elizabeth Li , David Mankoff , Rong Zhou

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引用次数: 0

摘要

背景：谷氨酰胺是许多侵袭性肿瘤中重要的代谢底物，其重要性与葡萄糖代谢相当。利用人类乳腺癌小鼠异种移植模型，我们研究了PET显像剂L-5-[11C]-谷氨酰胺（[11C]glutamine或[11C]GLN）的动力学，这是谷氨酰胺代谢的生化真实底物，以进一步表征谷氨酰胺和下游标记代谢物的代谢。研究在有和没有抑制谷氨酰胺酶（GLS）的情况下进行，GLS是谷氨酰胺分解代谢产生谷氨酸的第一步，也是谷氨酰胺代谢癌症治疗的关键靶点。方法采用两种乳腺癌细胞系的异种移植小鼠模型，HCC1806是一种高度谷氨酰胺溶解的三阴性细胞系，MCF-7是一种仅低水平谷氨酰胺溶解的激素受体阳性细胞系。小鼠注射[11C]谷氨酰胺，进行代谢物分析或动态PET成像。在10min、20min和30min时，通过HPLC检测个体代谢物对血液和肿瘤组织中11c活性信号总量的贡献。我们测量了[11C]谷氨酰胺与标记代谢物的分数活性，重点是L-5-[11C]-谷氨酸（[11C]谷氨酸或[11C]GLU），以及其他标记为11C的代谢物小分子（11C-other或11C-oth）的活性。此外，还测量了[11C]CO2对总11C活性的贡献。与基于图像的摄取曲线一起，这产生了用对照或GLS抑制剂（CB-839）处理的异种移植物模型中[11C]谷氨酰胺和下游代谢物的估计时间活性曲线。结果我们发现，在注射后30 min，高谷氨酰胺溶瘤（HCC1806）的放射性主要以[11C]谷氨酰胺和[11C]谷氨酸的形式存在，谷氨酸下游代谢产物（包括[11C]CO2）的放射性相对较低。在HCC1806肿瘤中，[11C]谷氨酸保留在大的细胞谷氨酸池中，导致肿瘤组织中总放射性的大部分比例大于血液中的比例，这种肿瘤分数模式在CB-839中逆转。这一现象导致CB-839前后的总肿瘤时间-活性曲线只有微小的差异。载体治疗后MCF-7肿瘤的放射性模式与CB-839治疗后HCC1806肿瘤相似。我们对乳腺癌模型中[11C]谷氨酰胺的研究表明，在GLS活性高的肿瘤中，11C-活性以[11C]谷氨酸的形式显著保留，这混淆了GLS活性的非侵入性推断。这表明[11C]谷氨酰胺PET在推断肿瘤GLS活性及其药物抑制剂特异性拮抗作用方面的应用有限。然而，我们对小鼠模型中标记代谢物的分析确实产生了一些见解，包括由gls介导的分解代谢在大细胞池中产生的谷氨酸的保留，并且还提供了作为谷氨酰胺代谢的室室模型基础的数据，这是一篇伴随论文的主题。

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L-5-[11C]-glutamine PET of breast cancer: Preclinical studies in mouse models

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L-5-[11C]-glutamine PET of breast cancer: Preclinical studies in mouse models

Background

Glutamine is an important metabolic substrate in many aggressive tumors, with comparable importance to glucose metabolism. Utilizing human breast cancer mouse xenograft models, we studied the kinetics of the PET imaging agent, L-5-[¹¹C]-glutamine ([¹¹C]glutamine or [¹¹C]GLN) a biochemical authentic substrate for glutamine metabolism, to further characterize the metabolism of glutamine and downstream labeled metabolites. Studies were performed with and without inhibition of the enzyme, glutaminase (GLS), the first step in glutamine catabolism that generates glutamate, and key target for therapy directed to glutamine-metabolizing cancers.

Methods

The study used xenograft mouse models for two breast cancer cell lines, HCC1806, a highly glutaminolytic triple-negative cell line, and MCF-7, a hormone receptor positive line with only low levels of glutaminolysis. Mice were injected with [¹¹C]glutamine and either underwent metabolite analysis or dynamic PET imaging. The contributions of individual metabolites to the total ¹¹C-activity signal in blood and tumor tissue were measured at 10, 20, and 30 min via HPLC. We measured fractional activity in the form of [¹¹C]glutamine versus labeled metabolites, focusing on L-5-[¹¹C]-glutamate ([¹¹C]glutamate or [¹¹C]GLU), and any activity in the other metabolite small molecules labeled with ¹¹C (¹¹C-other or ¹¹C-OTH). Additionally, the contribution of [¹¹C]CO₂ to total ¹¹C-activity was measured. Together with image-based uptake curves, this generated estimated time activity curves for [¹¹C]glutamine and downstream metabolites in both xenograft models treated with vehicle or GLS inhibitor (CB-839).

Results

We found that, out to 30 min post-injection, the majority of radioactivity in highly glutaminolytic tumors (HCC1806) was in the form of [¹¹C]glutamine and [¹¹C]glutamate, with relatively low amounts of radioactivity in metabolites downstream of glutamate including [¹¹C]CO₂. In HCC1806 tumors, [¹¹C]glutamate was retained in the large cellular glutamate pool leading to a majority fraction of total radioactivity in tumor tissue that is greater than the fraction within the blood, with this tumoral fractional pattern reversing with CB-839. This phenomenon leads to a total tumor time-activity curve that is only marginally different before and after CB-839. The radioactivity patterns of MCF-7 tumors after vehicle treatment were similar HCC1806 tumors after CB-839 treatment.

Conclusion

Our studies on [¹¹C]glutamine in breast cancer models show significant retention of ¹¹C-activity in the form of [¹¹C]glutamate in tumors with high GLS activity that confounds non-invasive inference of GLS activity. This suggests limited utility for [¹¹C]glutamine PET for inferring tumor GLS activity and its specific antagonism by drug inhibitors. Our analysis of labeled metabolites in mouse models does, however, yield insights that include the retention of glutamate generated by GLS-mediated catabolism in a large cellular pool and also provide data that is the basis for a compartmental model of glutamine metabolism that is the subject of a companion paper.

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来源期刊

Nuclear medicine and biology 医学-核医学

CiteScore

6.00

自引率

9.70%

发文量

479

审稿时长

51 days

期刊介绍： Nuclear Medicine and Biology publishes original research addressing all aspects of radiopharmaceutical science: synthesis, in vitro and ex vivo studies, in vivo biodistribution by dissection or imaging, radiopharmacology, radiopharmacy, and translational clinical studies of new targeted radiotracers. The importance of the target to an unmet clinical need should be the first consideration. If the synthesis of a new radiopharmaceutical is submitted without in vitro or in vivo data, then the uniqueness of the chemistry must be emphasized. These multidisciplinary studies should validate the mechanism of localization whether the probe is based on binding to a receptor, enzyme, tumor antigen, or another well-defined target. The studies should be aimed at evaluating how the chemical and radiopharmaceutical properties affect pharmacokinetics, pharmacodynamics, or therapeutic efficacy. Ideally, the study would address the sensitivity of the probe to changes in disease or treatment, although studies validating mechanism alone are acceptable. Radiopharmacy practice, addressing the issues of preparation, automation, quality control, dispensing, and regulations applicable to qualification and administration of radiopharmaceuticals to humans, is an important aspect of the developmental process, but only if the study has a significant impact on the field. Contributions on the subject of therapeutic radiopharmaceuticals also are appropriate provided that the specificity of labeled compound localization and therapeutic effect have been addressed.