黑素细胞的分化和机械感觉是由不同的细胞外基质蛋白差异调节的。

IF 6.2 1区生物学 Q1 BIOCHEMISTRY & MOLECULAR BIOLOGY

EMBO Reports Pub Date : 2025-09-19 DOI:10.1038/s44319-025-00583-6

Carole Luthold, Marie Didion, Vanessa Samira Rácz, Emilio Benedum, Ann-Kathrin Burkhart, Nina Demmerle, Evelyn Wirth, Gubesh Gunaratnam, Sudharshini Thangamurugan, Volkhard Helms, Markus Bischoff, Annika Ridzal, Sandra Iden

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引用次数: 0

摘要

黑素细胞功能障碍可导致色素沉着障碍或黑色素瘤。黑素细胞与各种类型的ECM相互作用，包括胶原和纤维连接蛋白。ECM组成和硬度的改变可以影响细胞行为，但它们对黑素细胞功能的具体作用尚不清楚。我们将黑素细胞暴露于不同的ECM蛋白和不同的底物硬度下，并确定了MITF，一个黑素细胞分化和功能的关键调节因子，作为ECM和机械敏感的转录因子。此外，不同的ECM蛋白和底物硬度参与FAK/MEK/ERK/MITF信号轴来控制黑素细胞的功能。胶原I限制FAK和ERK的激活，促进核MITF水平升高，黑素细胞增殖和分化的转录组特征。相反，纤维连接蛋白诱导FAK和ERK激活，减少核MITF，增加运动性和去分化转录组特征。在纤维连接蛋白上，抑制MEK/ERK活性导致MITF核定位增加和黑色素生成增强。此外，FAK抑制降低了ERK的激活并增强了黑色素生成，支持FAK在ERK上游起作用。最后，黑素细胞表现出依赖于ecm的机械反应。总之，外在线索对黑素细胞功能有实质性影响，包括erk依赖性MITF调节。

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Melanocyte differentiation and mechanosensation are differentially modulated by distinct extracellular matrix proteins.

Melanocyte dysfunctions can lead to pigmentation disorders or melanoma. Melanocytes interact context-dependently with various types of ECM, including collagens and fibronectin. Alterations in ECM composition and stiffness can impact cell behavior, but their specific roles for melanocyte functions remain unclear. We here exposed melanocytes to different ECM proteins and varying substrate stiffnesses, and identified MITF, a key regulator of melanocyte differentiation and function, as an ECM- and mechanosensitive transcription factor. Moreover, distinct ECM proteins and substrate stiffness engaged a FAK/MEK/ERK/MITF signaling axis to control melanocyte functions. Collagen I restricted FAK and ERK activation, promoting elevated nuclear MITF levels, melanocyte proliferation and a differentiated transcriptomic signature. Conversely, fibronectin elicited FAK and ERK activation, reduced nuclear MITF, increased motility and a dedifferentiated transcriptomic signature. On fibronectin, inhibiting MEK/ERK activity caused increased MITF nuclear localization and enhanced melanogenesis. Additionally, FAK inhibition reduced ERK activation and enhanced melanogenesis, supporting that FAK acts upstream of ERK. Finally, melanocytes show ECM-dependent mechanoresponses. In summary, extrinsic cues exert substantial effects on melanocyte function, involving ERK-dependent MITF regulation.

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来源期刊

EMBO Reports 生物-生化与分子生物学

CiteScore

11.20

自引率

1.30%

发文量

267

审稿时长

1 months

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