Montalbano Serena, Raboni Samanta, Sidoli Simone, Mozzarelli Andrea, Bettati Stefano, Buschini Annamaria
Department of Chemistry, Life Sciences and Environmental Sustainability, University of Parma, Parco Area delle Scienze 11/A, 43124 Parma, Italy.
COMT (Interdepartmental Centre for Molecular and Translational Oncology), University of Parma, Parco Area delle Scienze 11/A, 43124 Parma, Italy.
Cancers (Basel). 2023 Jan 15;15(2):527. doi: 10.3390/cancers15020527.
Methionine is an essential amino acid involved in the formation of polyamines and a precursor metabolite for DNA and protein methylation. The dependence of cancer cells on methionine has triggered extensive investigations aimed at its targeting for cancer therapy, including the exploitation as a therapeutic tool of methionine γ-lyase (MGL), a bacterial enzyme that degrades methionine, capable of inhibiting cancer cells growth due to methionine starvation. We have exploited the high-resolution power of mass spectrometry to compare the effects of reduced availability of the methyl donor SAM, induced by MGL treatment, on the post-translational modifications of the histone tails in normal Hs27 and cancer HT-29 cells. In the absence of MGL, our analysis detected a three-fold higher relative abundance of trimethylated K25 of H1.4 in HT-29 than Hs27 cells, and a complex pattern of methylated, unmethylated and acetylated peptides in H2 and H3.3. In the presence of MGL, in HT-29, the peptide H2A1_4_11 is predominantly unmodified with mono-methylated K5 increasing upon treatment, whereas in Hs27 cells, H2A1_4_11 is monomethylated at K5 and K9 with these marks decreasing upon treatment. The time dependence of the effects of MGL-mediated methionine depletion on PTMs of histone variants in HT-29 cancer cells was also monitored. Overall, our present data on histone variants H1, H2A, H2B as well as H3.3 integrated with our previous studies on histones H3 and H4, shed light on the epigenetic modifications associated with methionine starvation and associated cancer cell death.
甲硫氨酸是一种必需氨基酸,参与多胺的形成,也是DNA和蛋白质甲基化的前体代谢物。癌细胞对甲硫氨酸的依赖性引发了广泛的研究,旨在将其作为癌症治疗的靶点,包括利用甲硫氨酸γ-裂解酶(MGL)作为治疗工具,MGL是一种能降解甲硫氨酸的细菌酶,由于甲硫氨酸饥饿而能够抑制癌细胞生长。我们利用质谱的高分辨率能力,比较了MGL处理诱导的甲基供体S-腺苷甲硫氨酸(SAM)可用性降低对正常Hs27细胞和癌症HT-29细胞组蛋白尾部翻译后修饰的影响。在没有MGL的情况下,我们的分析检测到HT-29细胞中H1.4的K25三甲基化相对丰度比Hs27细胞高三倍,并且在H2和H3.3中存在甲基化、未甲基化和乙酰化肽的复杂模式。在存在MGL的情况下,在HT-29细胞中,肽H2A1_4_11主要未被修饰,处理后单甲基化的K5增加,而在Hs27细胞中,H2A1_4_11在K5和K9处单甲基化,这些标记在处理后减少。还监测了MGL介导的甲硫氨酸消耗对HT-29癌细胞中组蛋白变体翻译后修饰影响的时间依赖性。总体而言,我们目前关于组蛋白变体H1、H2A、H2B以及H3.3的数据,与我们之前关于组蛋白H3和H4的研究相结合,揭示了与甲硫氨酸饥饿和相关癌细胞死亡相关的表观遗传修饰。
