Amyloid Formation on Lipid Membrane Surfaces

P. Kinnunen
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Concomitantly, the low dielectricity also forces the polypeptides to maximize intramolecular hydrogen bonding by folding into amphipathic  -helices, which further aggregate, the latter adding cooperativity to the kinetics of membrane association. After the above, fast first events, several slower, cooperative conformational transitions of the oligomeric polypeptide chains take place in the membrane surface. Relaxation to the free energy minimum involves a complex free energy landscape of the above system comprised of a soft membrane interacting with, and accommodating peptide polymers. The overall free energy landscape thus involves a region of polypeptide aggregation associated with folding: polypeptide physicochemical properties and available conformation/oligomerization state spaces as determined by the amino acid sequence. In this respect, of major interest are those natively disordered proteins interacting with lipids, which in the absence of a ligand have no inherent structure and may adapt different functional states. Key sequence features for lipid and membrane interactions from the point of view of amyloid formation are i) conformational ambiguity, ii) adoption of amphipathic structures, iii) ion binding, and iv) propensity for aggregation and amyloid fibrillation. The pathways and states of the polypeptide conformational transitions further depend on the lipid composition, which thus couples the inherent properties of lipid membranes to the inherent properties of proteins. In other words, different lipids and their mixtures generate a very complex and rich scale of environments, involving also a number of cooperative transitions, sensitive to exogenous factors (temperature, ions, pH, small molecules), with small scale molecular properties and interactions translating into large scale 2- and 3-D organization. These lipid surface properties and topologies determine and couple to the transitions of the added polypeptide, the latter now undergoing oligomerization, with a sequence of specific and cooperative conformational changes. The above aggregation/folding pathways and transient intermediates of the polypeptide oligomers appear to have distinct biological functions. The latter involve i) the control of enzyme catalytic activity, ii) cell defence (e.g. antimicrobial and cancer killing peptides/proteins, as well as possibly also iii) control of cell shape and membrane traffic. On the other hand, these processes are also associated with the onset of major sporadic diseases, all involving protein misfolding, aggregation and amyloid formation, such as in Alzheimer's and Parkinson's diseases, prion disease, and type 2 diabetes. Exemplified by the latter, in an acidic phospholipid containing membrane human islet associated polypeptide (IAPP or amylin, secreted by pancreatic  -cells) efficiently transforms into amyloid  -sheet fibrils, the latter property being associated with established sequence features of IAPP, involved in aggregation and amyloid formation. IAPP sequence also harbors anion binding sites, such as those involving cationic side chains and N-terminal NH-groups of the  -helix. The association with acidic lipids neutralizes 'gatekeeping' cationic residues, abrogating electrostatic peptide-peptide repulsion. The subsequent aggregation of the  -helices involves further oligomerization and a sequence of slow transitions, driven by hydrogen bonding, and ending up as amyloid  -sheet fibrils. Importantly, the above processing of IAPP in its folding/aggregation free energy landscape under the influence of a lipid membrane involves also transient cytotoxic intermediates, which permeabilize membranes, allowing influx of Ca 2+ and triggering of cell death, this process resulting in the loss of  -cells, seen in type 2 diabetes. Similar chains of events are believed to underlie the loss of tissue function in the other disorders mentioned above.","PeriodicalId":22949,"journal":{"name":"The Open Biology Journal","volume":"39 1","pages":"163-175"},"PeriodicalIF":0.0000,"publicationDate":"2009-12-31","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"48","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"The Open Biology Journal","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/10.2174/1874196700902010163","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"","JCRName":"","Score":null,"Total":0}
引用次数: 48

Abstract

Several lines of research have concluded lipid membranes to efficiently induce the formation of amyloid-type fibers by a number of proteins. In brief, membranes, particularly when containing acidic, negatively charged lipids, concentrate cationic peptides/proteins onto their surfaces, into a local low pH milieu. The latter together with the anisotropic low dielectricity environment of the lipid membrane further forces polypeptides to align and adjust their conformation so as to enable a proper arrangement of the side chains according to their physicochemical characteristics, creating a hydrophobic surface contacting the lipid hydrocarbon region. Concomitantly, the low dielectricity also forces the polypeptides to maximize intramolecular hydrogen bonding by folding into amphipathic  -helices, which further aggregate, the latter adding cooperativity to the kinetics of membrane association. After the above, fast first events, several slower, cooperative conformational transitions of the oligomeric polypeptide chains take place in the membrane surface. Relaxation to the free energy minimum involves a complex free energy landscape of the above system comprised of a soft membrane interacting with, and accommodating peptide polymers. The overall free energy landscape thus involves a region of polypeptide aggregation associated with folding: polypeptide physicochemical properties and available conformation/oligomerization state spaces as determined by the amino acid sequence. In this respect, of major interest are those natively disordered proteins interacting with lipids, which in the absence of a ligand have no inherent structure and may adapt different functional states. Key sequence features for lipid and membrane interactions from the point of view of amyloid formation are i) conformational ambiguity, ii) adoption of amphipathic structures, iii) ion binding, and iv) propensity for aggregation and amyloid fibrillation. The pathways and states of the polypeptide conformational transitions further depend on the lipid composition, which thus couples the inherent properties of lipid membranes to the inherent properties of proteins. In other words, different lipids and their mixtures generate a very complex and rich scale of environments, involving also a number of cooperative transitions, sensitive to exogenous factors (temperature, ions, pH, small molecules), with small scale molecular properties and interactions translating into large scale 2- and 3-D organization. These lipid surface properties and topologies determine and couple to the transitions of the added polypeptide, the latter now undergoing oligomerization, with a sequence of specific and cooperative conformational changes. The above aggregation/folding pathways and transient intermediates of the polypeptide oligomers appear to have distinct biological functions. The latter involve i) the control of enzyme catalytic activity, ii) cell defence (e.g. antimicrobial and cancer killing peptides/proteins, as well as possibly also iii) control of cell shape and membrane traffic. On the other hand, these processes are also associated with the onset of major sporadic diseases, all involving protein misfolding, aggregation and amyloid formation, such as in Alzheimer's and Parkinson's diseases, prion disease, and type 2 diabetes. Exemplified by the latter, in an acidic phospholipid containing membrane human islet associated polypeptide (IAPP or amylin, secreted by pancreatic  -cells) efficiently transforms into amyloid  -sheet fibrils, the latter property being associated with established sequence features of IAPP, involved in aggregation and amyloid formation. IAPP sequence also harbors anion binding sites, such as those involving cationic side chains and N-terminal NH-groups of the  -helix. The association with acidic lipids neutralizes 'gatekeeping' cationic residues, abrogating electrostatic peptide-peptide repulsion. The subsequent aggregation of the  -helices involves further oligomerization and a sequence of slow transitions, driven by hydrogen bonding, and ending up as amyloid  -sheet fibrils. Importantly, the above processing of IAPP in its folding/aggregation free energy landscape under the influence of a lipid membrane involves also transient cytotoxic intermediates, which permeabilize membranes, allowing influx of Ca 2+ and triggering of cell death, this process resulting in the loss of  -cells, seen in type 2 diabetes. Similar chains of events are believed to underlie the loss of tissue function in the other disorders mentioned above.
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脂膜表面淀粉样蛋白的形成
一些研究已经得出结论,脂质膜可以有效地诱导淀粉样蛋白型纤维的形成。简而言之,膜,特别是当含有酸性,带负电荷的脂质时,将阳离子肽/蛋白质浓缩到其表面,进入局部低pH环境。后者与脂质膜的各向异性低介电环境一起,进一步迫使多肽排列和调整其构象,使侧链能够根据其物理化学特性进行适当的排列,从而形成与脂质烃区接触的疏水表面。同时,低介电性也迫使多肽通过折叠成两性的-螺旋来最大化分子内的氢键,这些螺旋进一步聚集,后者为膜结合动力学增加了协同性。在上述快速初始事件之后,膜表面发生了几个较慢的低聚多肽链的协同构象转变。松弛到自由能最小值涉及上述系统的复杂自由能景观,该系统由与肽聚合物相互作用和容纳的软膜组成。因此,整体自由能景观涉及与折叠相关的多肽聚集区域:多肽的物理化学性质和可用的构象/寡聚化状态空间由氨基酸序列决定。在这方面,主要关注的是那些与脂质相互作用的天然无序蛋白质,这些蛋白质在没有配体的情况下没有固有结构,可能适应不同的功能状态。从淀粉样蛋白形成的角度来看,脂质和膜相互作用的关键序列特征是:(1)构象模糊,(2)采用两亲结构,(3)离子结合,(4)倾向于聚集和淀粉样蛋白纤颤。多肽构象转变的途径和状态进一步取决于脂质组成,从而将脂质膜的固有特性与蛋白质的固有特性耦合在一起。换句话说,不同的脂质及其混合物产生了非常复杂和丰富的环境尺度,还涉及许多合作转变,对外源因素(温度、离子、pH、小分子)敏感,具有小尺度的分子性质和相互作用,转化为大规模的2- 3-D组织。这些脂质表面性质和拓扑结构决定并耦合到添加的多肽的转变,后者现在正在进行寡聚化,具有一系列特定的和合作的构象变化。上述聚合/折叠途径和多肽低聚物的瞬时中间体似乎具有不同的生物学功能。后者涉及i)酶催化活性的控制,ii)细胞防御(例如抗菌和抗癌肽/蛋白质,以及可能的iii)细胞形状和膜交通的控制。另一方面,这些过程也与主要散发性疾病的发病有关,所有这些疾病都涉及蛋白质错误折叠、聚集和淀粉样蛋白形成,例如阿尔茨海默病和帕金森病、朊病毒病和2型糖尿病。以后者为例,在含有酸性磷脂膜的人胰岛相关多肽(IAPP或胰淀素,由胰腺-细胞分泌)有效地转化为淀粉样蛋白-片原纤维,后者的特性与IAPP的既定序列特征有关,参与聚集和淀粉样蛋白的形成。IAPP序列还包含阴离子结合位点,例如涉及-螺旋的阳离子侧链和n端nh基团的位点。与酸性脂质的结合中和了“守门人”阳离子残基,废除了静电肽-肽排斥。随后-螺旋的聚集涉及进一步的寡聚化和一系列缓慢的转变,由氢键驱动,最终形成淀粉样蛋白-薄片原纤维。重要的是,上述IAPP在脂质膜影响下的折叠/聚集自由能过程还涉及到瞬时细胞毒性中间体,这些中间体渗透细胞膜,允许ca2 +的流入并触发细胞死亡,这一过程导致-细胞的损失,在2型糖尿病中可见。类似的连锁事件被认为是上述其他疾病中组织功能丧失的基础。
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