Ineffective Phosphorylation of Mitogen-Activated Protein Kinase Hog1p in Response to High Osmotic Stress in the Yeast Kluyveromyces lactis.

Eukaryotic Cell Pub Date : 2015-09-01 Epub Date: 2015-07-06 DOI:10.1128/EC.00048-15
Nancy Velázquez-Zavala, Miriam Rodríguez-González, Rocío Navarro-Olmos, Laura Ongay-Larios, Laura Kawasaki, Francisco Torres-Quiroz, Roberto Coria
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引用次数: 9

Abstract

When treated with a hyperosmotic stimulus, Kluyveromyces lactis cells respond by activating the mitogen-activated protein kinase (MAPK) K. lactis Hog1 (KlHog1) protein via two conserved branches, SLN1 and SHO1. Mutants affected in only one branch can cope with external hyperosmolarity by activating KlHog1p by phosphorylation, except for single ΔKlste11 and ΔKlste50 mutants, which showed high sensitivity to osmotic stress, even though the other branch (SLN1) was intact. Inactivation of both branches by deletion of KlSHO1 and KlSSK2 also produced sensitivity to high salt. Interestingly, we have observed that in ΔKlste11 and ΔKlsho1 ΔKlssk2 mutants, which exhibit sensitivity to hyperosmotic stress, and contrary to what would be expected, KlHog1p becomes phosphorylated. Additionally, in mutants lacking both MAPK kinase kinases (MAPKKKs) present in K. lactis (KlSte11p and KlSsk2p), the hyperosmotic stress induced the phosphorylation and nuclear internalization of KlHog1p, but it failed to induce the transcriptional expression of KlSTL1 and the cell was unable to grow in high-osmolarity medium. KlHog1p phosphorylation via the canonical HOG pathway or in mutants where the SHO1 and SLN1 branches have been inactivated requires not only the presence of KlPbs2p but also its kinase activity. This indicates that when the SHO1 and SLN1 branches are inactivated, high-osmotic-stress conditions activate an independent input that yields active KlPbs2p, which, in turn, renders KlHog1p phosphorylation ineffective. Finally, we found that KlSte11p can alleviate the sensitivity to hyperosmotic stress displayed by a ΔKlsho1 ΔKlssk2 mutant when it is anchored to the plasma membrane by adding the KlSho1p transmembrane segments, indicating that this chimeric protein can substitute for KlSho1p and KlSsk2p.

Abstract Image

Abstract Image

高渗透胁迫下裂丝原活化蛋白激酶Hog1p的无效磷酸化研究
当受到高渗刺激时,乳酸菌细胞通过两个保守分支SLN1和SHO1激活丝裂原活化蛋白激酶(MAPK) K. KlHog1 (KlHog1)蛋白。只有一个分支受影响的突变体可以通过磷酸化激活KlHog1p来应对外部高渗透压,除了单个ΔKlste11和ΔKlste50突变体,它们对渗透胁迫表现出高度敏感性,即使另一个分支(SLN1)是完整的。通过缺失KlSHO1和KlSSK2使两个分支失活也产生了对高盐的敏感性。有趣的是,我们观察到在ΔKlste11和ΔKlsho1 ΔKlssk2突变体中,表现出对高渗胁迫的敏感性,与预期相反,KlHog1p被磷酸化。此外,在缺乏乳黄中存在的MAPK激酶激酶(MAPKKKs) (KlSte11p和KlSsk2p)的突变体中,高渗胁迫诱导了KlHog1p的磷酸化和核内化,但未能诱导KlSTL1的转录表达,细胞无法在高渗透压培养基中生长。通过典型的HOG途径或在SHO1和SLN1分支失活的突变体中,KlPbs2p的磷酸化不仅需要KlPbs2p的存在,还需要它的激酶活性。这表明当SHO1和SLN1分支失活时,高渗透胁迫条件激活了一个独立的输入,产生活跃的KlPbs2p,这反过来又使KlHog1p磷酸化无效。最后,我们发现通过添加KlSho1p跨膜片段将KlSte11p固定在质膜上,KlSte11p可以减轻ΔKlsho1 ΔKlssk2突变体对高渗胁迫的敏感性,表明该嵌合蛋白可以替代KlSho1p和KlSsk2p。
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来源期刊
Eukaryotic Cell
Eukaryotic Cell 生物-微生物学
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审稿时长
1 months
期刊介绍: Eukaryotic Cell (EC) focuses on eukaryotic microbiology and presents reports of basic research on simple eukaryotic microorganisms, such as yeasts, fungi, algae, protozoa, and social amoebae. The journal also covers viruses of these organisms and their organelles and their interactions with other living systems, where the focus is on the eukaryotic cell. Topics include: - Basic biology - Molecular and cellular biology - Mechanisms, and control, of developmental pathways - Structure and form inherent in basic biological processes - Cellular architecture - Metabolic physiology - Comparative genomics, biochemistry, and evolution - Population dynamics - Ecology
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