Satoshi Uemura, Takahiro Mochizuki, Yusuke Kato, Tetsuo Mioka, Riseko Watanabe, Mai Fuchita, Mao Yamada, Yoichi Noda, Takashi Moriguchi, Fumiyoshi Abe
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引用次数: 0
摘要
静水压是一种常见的机械应激源,可调节新陈代谢并降低细胞活力。真核细胞具有应对静水压压力和维持细胞内平衡的基因程序。然而,静水压耐受性的内在机制在很大程度上仍然未知。我们最近证明,端粒盖蛋白6(Mtc6)通过支持营养渗透酶的完整性,在静水压胁迫下对出芽酵母的存活起到保护作用。目前的研究证明,Mtc6 是一种内质网(ER)膜蛋白。Mtc6 包括两个跨膜结构域、一个 C 端胞质结构域和一个附有 12 个 Asn(N)连接糖的腔区。连续突变分析表明,胞质 C 端氨基酸残基 GVPS 对 Mtc6 的活性至关重要。腔内区域的多个 N-连接聚糖参与了 Mtc6 的结构构象。此外,缺失MTC6会导致亮氨酸渗透酶Bap2在静水压力下的降解增加,这表明Mtc6有助于营养物质渗透酶在压力条件下在ER中正确折叠。我们提出了一个新的分子功能模型,其中Mtc6的糖基化管腔结构域和胞质GVPS序列共同支持营养物质渗透酶的活性。
Mtc6/Ehg2 is a novel endoplasmic reticulum-resident glycoprotein essential for high-pressure tolerance
Hydrostatic pressure is a common mechanical stressor that modulates metabolism and reduces cell viability. Eukaryotic cells have genetic programs to cope with hydrostatic pressure stress and maintain intracellular homeostasis. However, the mechanism underlying hydrostatic pressure tolerance remains largely unknown. We have recently demonstrated that Maintenance of telomere capping protein 6 (Mtc6) plays a protective role in the survival of the budding yeast Saccharomyces cerevisiae under hydrostatic pressure stress by supporting the integrity of nutrient permeases. The current study demonstrate that Mtc6 acts as an endoplasmic reticulum (ER) membrane protein. Mtc6 comprises two transmembrane domains, a C-terminal cytoplasmic domain, and a luminal region with 12 Asn (N)-linked glycans attached to it. Serial mutational analyses showed that the cytoplasmic C-terminal amino acid residues GVPS are essential for Mtc6 activity. Multiple N-linked glycans in the luminal region are involved in the structural conformation of Mtc6. Moreover, deletion of MTC6 led to increased degradation of the leucine permease Bap2 under hydrostatic pressure, suggesting that Mtc6 facilitates proper folding of nutrient permeases in the ER under the stress condition. We propose a novel model of molecular function in which the glycosylated luminal domain and cytoplasmic GVPS sequences of Mtc6 cooperatively support the nutrient permease activity.