EA 2160-IUML FR3473 CNRS, Nantes Université, UMR6286, US2B, 44035 Nantes, France.
Department of Biopathology, Institut de Cancérologie de l'Ouest, 44805 Saint-Herblain, France.
Nutrients. 2022 Jun 14;14(12):2461. doi: 10.3390/nu14122461.
According to the International Agency for Research on Cancer (IARC) more than 10% of cancers can be explained by inadequate diet and excess body weight. Breast cancer is the most common cancer affecting women. The goal of our study is to clarify the relationship between ω3 fatty acids (FA) carried by different lipoproteins and breast cancer (BC) severity, according to two approaches: through clinic-biological data and through in vitro breast cancer cell models. The clinical study has been performed in sera from a cohort of BC women (n = 140, ICO, France) whose tumors differed by their hormone receptors status (HR− for tumors negative for estrogen receptors and progesterone receptors, HR+ for tumors positive for either estrogen receptors or progesterone receptors) and the level of proliferation markers (Ki-67 ≤ 20% Prolif− and Ki-67 ≥ 30% Prolif+). Lipids and ω3FA have been quantified in whole serum and in apoB-containing lipoproteins (Non-HDL) or free of it (HDL). Differences between Prolif− and Prolif+ were compared by Wilcoxon test in each sub-group HR+ and HR−. Results are expressed as median [25th−75th percentile]. Plasma cholesterol, triglycerides, HDL-cholesterol and Non-HDL cholesterol did not differ between Prolif− and Prolif+ sub-groups of HR− and HR+ patients. Plasma EPA and DHA concentrations did not differ either. In the HR− group, the distribution of EPA and DHA between HDL and Non-HDL differed significantly, as assessed by a higher ratio between the FA concentration in Non-HDL and HDL in Prolif− vs. Prolif+ patients (0.20 [0.15−0.36] vs. 0.04 [0.02−0.08], p = 0.0001 for EPA and 0.08 [0.04−0.10] vs. 0.04 [0.01−0.07], p = 0.04 for DHA). In this HR− group, a significant increase in Non-HDL EPA concentration was also observed in Prolif− vs. Prolif+ (0.18 [0.13−0.40] vs. 0.05 [0.02−0.07], p = 0.001). A relative enrichment on Non-HDL in EPA and DHA was also observed in Prolif− patients vs. Prolif+ patients, as assessed by a higher molar ratio between FA and apoB (0.12 [0.09−0.18] vs. 0.02 [0.01−0.05], p < 0.0001 for EPA and 1.00 [0.73−1.69 vs. 0.52 [0.14−1.08], p = 0.04 for DHA). These data were partly confirmed by an in vitro approach of proliferation of isolated lipoproteins containing EPA and DHA on MDA-MB-231 (HR−) and MCF-7 (HR+) cell models. Indeed, among all the studied fractions, only the correlation between the EPA concentration of Non-HDL was confirmed in vitro, although with borderline statistical significance (p = 0.07), in MDA-MB-231 cells. Non-HDL DHA, in the same cells model was significantly correlated to proliferation (p = 0.04). This preliminary study suggests a protective effect on breast cancer proliferation of EPA and DHA carried by apo B-containing lipoproteins (Non-HDL), limited to HR− tumors.
根据国际癌症研究机构 (IARC) 的数据,超过 10%的癌症可以归因于饮食不当和体重超标。乳腺癌是最常见的女性癌症。我们的研究目标是根据两种方法阐明不同脂蛋白携带的 ω3 脂肪酸 (FA) 与乳腺癌 (BC) 严重程度之间的关系:通过临床生物学数据和体外乳腺癌细胞模型。这项临床研究是在 ICO 法国的一组乳腺癌女性的血清中进行的(n = 140),这些肿瘤根据其激素受体状态(HR−为雌激素受体和孕激素受体阴性的肿瘤,HR+为雌激素受体或孕激素受体阳性的肿瘤)和增殖标志物水平(Ki-67 ≤ 20% Prolif−和 Ki-67 ≥ 30% Prolif+)而有所不同。在整个血清以及载脂蛋白 B 含量的脂蛋白(非高密度脂蛋白)或不含载脂蛋白 B 的脂蛋白(高密度脂蛋白)中都对脂质和 ω3FA 进行了定量。在每个 HR+和 HR−亚组中,通过 Wilcoxon 检验比较了 Prolif−和 Prolif+之间的差异。结果以中位数[25 分位数-75 分位数]表示。在 HR−和 HR+患者的 Prolif−和 Prolif+亚组中,血浆胆固醇、甘油三酯、高密度脂蛋白胆固醇和非高密度脂蛋白胆固醇没有差异。EPA 和 DHA 浓度也没有差异。在 HR−组中,EPA 和 DHA 在 HDL 和非 HDL 之间的分布差异显著,这可以通过在 Prolif−患者中非高密度脂蛋白和高密度脂蛋白中 FA 浓度的比值来评估(0.20 [0.15-0.36] 与 0.04 [0.02-0.08],p = 0.0001 用于 EPA 和 0.08 [0.04-0.10] 与 0.04 [0.01-0.07],p = 0.04 用于 DHA)。在这个 HR−组中,还观察到 Prolif−患者的非高密度脂蛋白 EPA 浓度显著增加(0.18 [0.13-0.40] 与 0.05 [0.02-0.07],p = 0.001)。在 Prolif−患者中,还观察到 EPA 和 DHA 在非高密度脂蛋白中的相对富集,这可以通过 FA 和载脂蛋白 B 之间的摩尔比来评估(0.12 [0.09-0.18] 与 0.02 [0.01-0.05],p < 0.0001 用于 EPA 和 1.00 [0.73-1.69] 与 0.52 [0.14-1.08],p = 0.04 用于 DHA)。通过体外 MDA-MB-231(HR−)和 MCF-7(HR+)细胞模型中 EPA 和 DHA 分离脂蛋白的增殖实验,部分证实了这些数据。实际上,在所研究的所有馏分中,仅在 MDA-MB-231 细胞中,非高密度脂蛋白 EPA 浓度与体外观察到的相关性得到证实,尽管具有边缘统计学意义(p = 0.07)。在同一细胞模型中,非高密度脂蛋白 DHA 与增殖呈显著相关(p = 0.04)。这项初步研究表明,载脂蛋白 B 含量的脂蛋白(非高密度脂蛋白)携带的 EPA 和 DHA 对 HR−肿瘤的乳腺癌增殖具有保护作用。
