School of Computer Science and Engineering, Hebrew University of Jerusalem, 91904, Israel.
Biol Direct. 2010 Jan 26;5:6. doi: 10.1186/1745-6150-5-6.
Phosphorylation is the most prevalent post-translational modification on eukaryotic proteins. Multisite phosphorylation enables a specific combination of phosphosites to determine the speed, specificity and duration of biological response. Until recent years, the lack of high quality data limited the possibility for analyzing the properties of phosphorylation at the proteome scale and in the context of a wide range of conditions. Thanks to advances of mass spectrometry technologies, thousands of phosphosites from in-vivo experiments were identified and archived in the public domain. Such resource is appropriate to derive an unbiased view on the phosphosites properties in eukaryotes and on their functional relevance.
We present statistically rigorous tests on the spatial and functional properties of a collection of approximately 70,000 reported phosphosites. We show that the distribution of phosphosites positioning along the protein tends to occur as dense clusters of Serine/Threonines (pS/pT) and between Serine/Threonines and Tyrosines, but generally not as much between Tyrosines (pY) only. This phenomenon is more ubiquitous than anticipated and is pertinent for most eukaryotic proteins: for proteins with > or = 2 phosphosites, 54% of all pS/pT sites are within 4 amino acids of another site. We found a strong tendency for clustered pS/pT to be activated by the same kinase. Large-scale analyses of phosphopeptides are thus consistent with a cooperative function within the cluster.
We present evidence supporting the notion that clusters of pS/pT but generally not pY should be considered as the elementary building blocks in phosphorylation regulation. Indeed, closely positioned sites tend to be activated by the same kinase, a signal that overrides the tendency of a protein to be activated by a single or only few kinases. Within these clusters, coordination and positional dependency is evident. We postulate that cellular regulation takes advantage of such design. Specifically, phosphosite clusters may increase the robustness of the effectiveness of phosphorylation-dependent response.
Reviewed by Joel Bader, Frank Eisenhaber, Emmanuel Levy (nominated by Sarah Teichmann). For the full reviews, please go to the Reviewers' comments section.
磷酸化是真核蛋白质最普遍的翻译后修饰。多部位磷酸化使特定的磷酸化位点组合能够确定生物反应的速度、特异性和持续时间。直到最近几年,高质量数据的缺乏限制了在蛋白质组规模和广泛条件下分析磷酸化特性的可能性。多亏了质谱技术的进步,数千个来自体内实验的磷酸化位点被鉴定出来并归档在公共领域。这种资源适合于在真核生物中得出关于磷酸化位点特性及其功能相关性的无偏观点。
我们对大约 70000 个报告的磷酸化位点集合的空间和功能特性进行了统计严格的检验。我们表明,磷酸化位点在蛋白质上的定位分布倾向于密集地聚集丝氨酸/苏氨酸(pS/pT)和丝氨酸/苏氨酸与酪氨酸之间,但通常不会像酪氨酸(pY)之间那样多。这种现象比预期的更为普遍,适用于大多数真核蛋白质:对于具有≥2 个磷酸化位点的蛋白质,所有 pS/pT 位点中有 54%位于另一位点的 4 个氨基酸内。我们发现密集的 pS/pT 位点倾向于被同一激酶激活的强烈趋势。大规模的磷酸肽分析与簇内的合作功能一致。
我们提供了支持以下观点的证据:pS/pT 簇但通常不是 pY 簇应被视为磷酸化调节的基本构建块。事实上,位置接近的位点往往被同一激酶激活,这一信号超过了蛋白质被单一或少数几种激酶激活的趋势。在这些簇中,协调和位置依赖性是明显的。我们假设细胞调节利用了这种设计。具体来说,磷酸化位点簇可能会增加磷酸化依赖反应的有效性的稳健性。
Joel Bader、Frank Eisenhaber、Emmanuel Levy(由 Sarah Teichmann 提名)。完整的评论请前往评论者意见部分。
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