Aidan J Flynn, Kari Miller, Jennette M Codjoe, Matthew R King, Elizabeth S Haswell
{"title":"机械敏感离子通道 MSL8、MSL9 和 MSL10 具有对环境敏感的本征无序区,在体外具有不同的生物物理特性。","authors":"Aidan J Flynn, Kari Miller, Jennette M Codjoe, Matthew R King, Elizabeth S Haswell","doi":"10.1002/pld3.515","DOIUrl":null,"url":null,"abstract":"<p><p>Intrinsically disordered protein regions (IDRs) are highly dynamic sequences that rapidly sample a collection of conformations over time. In the past several decades, IDRs have emerged as a major component of many proteomes, comprising ~30% of all eukaryotic protein sequences. Proteins with IDRs function in a wide range of biological pathways and are notably enriched in signaling cascades that respond to environmental stresses. Here, we identify and characterize intrinsic disorder in the soluble cytoplasmic N-terminal domains of MSL8, MSL9, and MSL10, three members of the MscS-like (MSL) family of mechanosensitive ion channels. In plants, MSL channels are proposed to mediate cell and organelle osmotic homeostasis. Bioinformatic tools unanimously predicted that the cytosolic N-termini of MSL channels are intrinsically disordered. We examined the N-terminus of MSL10 (MSL10<sup>N</sup>) as an exemplar of these IDRs and circular dichroism spectroscopy confirms its disorder. MSL10<sup>N</sup> adopted a predominately helical structure when exposed to the helix-inducing compound trifluoroethanol (TFE). Furthermore, in the presence of molecular crowding agents, MSL10<sup>N</sup> underwent structural changes and exhibited alterations to its homotypic interaction favorability. Lastly, interrogations of collective behavior via in vitro imaging of condensates indicated that MSL8<sup>N</sup>, MSL9<sup>N</sup>, and MSL10<sup>N</sup> have sharply differing propensities for self-assembly into condensates, both inherently and in response to salt, temperature, and molecular crowding. Taken together, these data establish the N-termini of MSL channels as intrinsically disordered regions with distinct biophysical properties and the potential to respond uniquely to changes in their physiochemical environment.</p>","PeriodicalId":2,"journal":{"name":"ACS Applied Bio Materials","volume":null,"pages":null},"PeriodicalIF":4.6000,"publicationDate":"2023-08-03","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"https://www.ncbi.nlm.nih.gov/pmc/articles/PMC10400277/pdf/","citationCount":"0","resultStr":"{\"title\":\"Mechanosensitive ion channels MSL8, MSL9, and MSL10 have environmentally sensitive intrinsically disordered regions with distinct biophysical characteristics in vitro.\",\"authors\":\"Aidan J Flynn, Kari Miller, Jennette M Codjoe, Matthew R King, Elizabeth S Haswell\",\"doi\":\"10.1002/pld3.515\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<p><p>Intrinsically disordered protein regions (IDRs) are highly dynamic sequences that rapidly sample a collection of conformations over time. In the past several decades, IDRs have emerged as a major component of many proteomes, comprising ~30% of all eukaryotic protein sequences. Proteins with IDRs function in a wide range of biological pathways and are notably enriched in signaling cascades that respond to environmental stresses. Here, we identify and characterize intrinsic disorder in the soluble cytoplasmic N-terminal domains of MSL8, MSL9, and MSL10, three members of the MscS-like (MSL) family of mechanosensitive ion channels. In plants, MSL channels are proposed to mediate cell and organelle osmotic homeostasis. Bioinformatic tools unanimously predicted that the cytosolic N-termini of MSL channels are intrinsically disordered. We examined the N-terminus of MSL10 (MSL10<sup>N</sup>) as an exemplar of these IDRs and circular dichroism spectroscopy confirms its disorder. MSL10<sup>N</sup> adopted a predominately helical structure when exposed to the helix-inducing compound trifluoroethanol (TFE). Furthermore, in the presence of molecular crowding agents, MSL10<sup>N</sup> underwent structural changes and exhibited alterations to its homotypic interaction favorability. Lastly, interrogations of collective behavior via in vitro imaging of condensates indicated that MSL8<sup>N</sup>, MSL9<sup>N</sup>, and MSL10<sup>N</sup> have sharply differing propensities for self-assembly into condensates, both inherently and in response to salt, temperature, and molecular crowding. 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引用次数: 0
摘要
本质上无序的蛋白质区域(IDRs)是一种高度动态的序列,可随着时间的推移快速采样一系列构象。在过去几十年中,IDRs 已成为许多蛋白质组的主要组成部分,占所有真核蛋白质序列的 30%左右。具有内切酶的蛋白质在多种生物通路中发挥作用,尤其是在应对环境压力的信号级联中。在这里,我们鉴定并描述了 MSL8、MSL9 和 MSL10 这三个类 MscS(MSL)机械敏感离子通道家族成员的可溶性胞质 N 端结构域中的内在紊乱。在植物中,MSL 通道被认为介导细胞和细胞器的渗透平衡。生物信息学工具一致预测,MSL 通道的细胞膜 N 端是内在无序的。我们将 MSL10(MSL10N)的 N 端作为 IDR 的典范进行了研究,圆二色性光谱证实了其无序性。当暴露于螺旋诱导化合物三氟乙醇(TFE)时,MSL10N主要呈螺旋结构。此外,在分子排挤剂的作用下,MSL10N 也发生了结构变化,并显示出其同型相互作用有利性的改变。最后,通过冷凝物体外成像对集体行为进行的研究表明,MSL8N、MSL9N 和 MSL10N 在自组装成冷凝物方面具有截然不同的倾向性,既有固有倾向性,也有对盐、温度和分子拥挤的反应倾向性。综上所述,这些数据证实了 MSL 通道的 N 端是本质上无序的区域,具有不同的生物物理特性,并有可能对其理化环境的变化做出独特的反应。
Mechanosensitive ion channels MSL8, MSL9, and MSL10 have environmentally sensitive intrinsically disordered regions with distinct biophysical characteristics in vitro.
Intrinsically disordered protein regions (IDRs) are highly dynamic sequences that rapidly sample a collection of conformations over time. In the past several decades, IDRs have emerged as a major component of many proteomes, comprising ~30% of all eukaryotic protein sequences. Proteins with IDRs function in a wide range of biological pathways and are notably enriched in signaling cascades that respond to environmental stresses. Here, we identify and characterize intrinsic disorder in the soluble cytoplasmic N-terminal domains of MSL8, MSL9, and MSL10, three members of the MscS-like (MSL) family of mechanosensitive ion channels. In plants, MSL channels are proposed to mediate cell and organelle osmotic homeostasis. Bioinformatic tools unanimously predicted that the cytosolic N-termini of MSL channels are intrinsically disordered. We examined the N-terminus of MSL10 (MSL10N) as an exemplar of these IDRs and circular dichroism spectroscopy confirms its disorder. MSL10N adopted a predominately helical structure when exposed to the helix-inducing compound trifluoroethanol (TFE). Furthermore, in the presence of molecular crowding agents, MSL10N underwent structural changes and exhibited alterations to its homotypic interaction favorability. Lastly, interrogations of collective behavior via in vitro imaging of condensates indicated that MSL8N, MSL9N, and MSL10N have sharply differing propensities for self-assembly into condensates, both inherently and in response to salt, temperature, and molecular crowding. Taken together, these data establish the N-termini of MSL channels as intrinsically disordered regions with distinct biophysical properties and the potential to respond uniquely to changes in their physiochemical environment.