Nathália de Vasconcellos Racorti, Matheus Martinelli, Silvina Odete Bustos, Murilo Salardani, Maurício Frota Camacho, Uilla Barcick, Luis Roberto Fonseca Lima, Letícia Dias Lima Jedlicka, Claudia Barbosa Ladeira de Campos, Richard Hemmi Valente, Roger Chammas and André Zelanis*,
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引用次数: 0
摘要
代谢重编程是转化细胞的一个普遍特征,是癌症的标志之一,使肿瘤细胞能够适应新环境。累积的证据表明,一些肿瘤细胞无法将 6-磷酸甘露糖转化为 6-磷酸果糖,从而影响了 6-磷酸甘露糖异构酶(MPI)水平较低的细胞的肿瘤生长。因此,我们进行了功能分析,并分析了接受甘露糖处理的具有不同突变背景的黑色素瘤细胞系的蛋白质组图谱和蛋白酶底物谱(降解组)。我们的研究结果表明,经甘露糖处理后,黑色素瘤细胞系的蛋白质组和降解组发生了明显的重新排列,包括分解代谢途径(如蛋白质周转)的激活和蛋白质 N 端乙酰化的差异。尽管 MPI 蛋白丰度和基因表达状态不是预后标志物,但外源单糖源(即甘露糖)对网络造成的扰动会显著影响下游相互关联的生物回路。因此,正如本研究报告的那样,通过蛋白质组学/降解组学绘制甘露糖下游效应的图谱,可以从受影响的黑色素瘤信号回路中找出特定的分子角色。
Mannose-6-Phosphate Isomerase Functional Status Shapes a Rearrangement in the Proteome and Degradome of Mannose-Treated Melanoma Cells
Metabolic reprogramming is a ubiquitous feature of transformed cells, comprising one of the hallmarks of cancer and enabling neoplastic cells to adapt to new environments. Accumulated evidence reports on the failure of some neoplastic cells to convert mannose-6-phosphate into fructose-6-phosphate, thereby impairing tumor growth in cells displaying low levels of mannose-6-phosphate isomerase (MPI). Thus, we performed functional analyses and profiled the proteome landscape and the repertoire of substrates of proteases (degradome) of melanoma cell lines with distinct mutational backgrounds submitted to treatment with mannose. Our results suggest a significant rearrangement in the proteome and degradome of melanoma cell lines upon mannose treatment including the activation of catabolic pathways (such as protein turnover) and differences in protein N-terminal acetylation. Even though MPI protein abundance and gene expression status are not prognostic markers, perturbation in the network caused by an exogenous monosaccharide source (i.e., mannose) significantly affected the downstream interconnected biological circuitry. Therefore, as reported in this study, the proteomic/degradomic mapping of mannose downstream effects due to the metabolic rewiring caused by the functional status of the MPI enzyme could lead to the identification of specific molecular players from affected signaling circuits in melanoma.