剪接体组装网络的模块结构的详尽分析:一个Petri网方法。

Q2 Medicine In Silico Biology Pub Date : 2010-01-01 DOI:10.3233/ISB-2010-0419
Ralf H Bortfeldt, Stefan Schuster, Ina Koch
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引用次数: 17

摘要

剪接体是包含数百种具有多种功能相互作用的蛋白质的宏观复合物。剪接体组装是mRNA剪接和调节选择性剪接的关键过程。在过去的十年中,剪接体反应中涉及的因素的详细列表已经分类,但是,它们的功能相互作用通常是未知的,而且大多数目前的生物学模型只涵盖了完整组装过程的一部分。建立一个集成了分散的知识并结合了先前提出的多种反应方案的计算模型是一项具有挑战性的任务。由于大多数涉及剪接体装配的反应动力学参数不可用,我们提出了一个使用Petri网的离散建模,通过该模型,我们能够通过计算结构和动态特性来深入了解系统的行为。在本文中,我们从实验报告中编译并检查了有助于功能剪接体的反应。所有这些反应形成一个网络,描述了执行拼接过程所需的清单和条件。分析主要基于系统不变量。转换不变量(t不变量)可以解释为通过网络的信令路由。由于随着网络规模和复杂性的增加而出现大量的t不变量,因此使用最大公共转移集(MCTS)和t聚类进行进一步分析。此外,我们引入了一种假彩色地图表示,它允许快速调查网络模块和视觉检测单个反应或反应序列,这些反应或反应序列参与多个信号通路。我们设计了一个剪接体组装的结构化模型,该模型结合了对平台的需求,i)可以显示相关因素和并发过程,ii)提供运行知识提取的计算方法的可能性,iii)随着实验报告对剪接体功能的新见解的报道而不断扩展。该网络由161个跃迁(反应)和140个位置(反应物)组成。所有的反应都至少属于71个t不变量中的一个。这些t不变量定义了通路,这与目前关于剪接体组装过程中反应序列的知识和已知假设很好地一致,因此有助于剪接体的功能。我们证明了目前的知识,特别是组装过程的初始部分,描述了信号通路的并行性和相互作用,这表明功能冗余,并反映了剪接体组装起始对不同细胞条件的依赖性。两个开关进一步增加了网络的复杂性,这两个开关在早期剪接体组装的a复合体形成过程中以及从b复合体过渡到c复合体时引入了可选的路线。通过将已知的反应编译成一个完整的网络,不变计算的组合性质导致了以前没有被描述为连接路线的途径,尽管它们的成分是已知的。t簇将网络划分为模块,我们将其解释为剪接体成熟的构建块。我们得出结论,大型生物网络和系统不变量的Petri网表示非常适合作为验证实验知识整合到一致模型中的手段。基于该网络模型,便于进一步的实验设计。
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Exhaustive analysis of the modular structure of the spliceosomal assembly network: a Petri net approach.

Spliceosomes are macro-complexes involving hundreds of proteins with many functional interactions. Spliceosome assembly belongs to the key processes that enable splicing of mRNA and modulate alternative splicing. A detailed list of factors involved in spliceosomal reactions has been assorted over the past decade, but, their functional interplay is often unknown and most of the present biological models cover only parts of the complete assembly process. It is a challenging task to build a computational model that integrates dispersed knowledge and combines a multitude of reaction schemes proposed earlier.Because for most reactions involved in spliceosome assembly kinetic parameters are not available, we propose a discrete modeling using Petri nets, through which we are enabled to get insights into the system's behavior via computation of structural and dynamic properties. In this paper, we compile and examine reactions from experimental reports that contribute to a functional spliceosome. All these reactions form a network, which describes the inventory and conditions necessary to perform the splicing process. The analysis is mainly based on system invariants. Transition invariants (T-invariants) can be interpreted as signaling routes through the network. Due to the huge number of T-invariants that arise with increasing network size and complexity, maximal common transition sets (MCTS) and T-clusters were used for further analysis. Additionally, we introduce a false color map representation, which allows a quick survey of network modules and the visual detection of single reactions or reaction sequences, which participate in more than one signaling route. We designed a structured model of spliceosome assembly, which combines the demands on a platform that i) can display involved factors and concurrent processes, ii) offers the possibility to run computational methods for knowledge extraction, and iii) is successively extendable as new insights into spliceosome function are reported by experimental reports. The network consists of 161 transitions (reactions) and 140 places (reactants). All reactions are part of at least one of the 71 T-invariants. These T-invariants define pathways, which are in good agreement with the current knowledge and known hypotheses on reaction sequences during spliceosome assembly, hence contributing to a functional spliceosome. We demonstrate that present knowledge, in particular of the initial part of the assembly process, describes parallelism and interaction of signaling routes, which indicate functional redundancy and reflect the dependency of spliceosome assembly initiation on different cellular conditions. The complexity of the network is further increased by two switches, which introduce alternative routes during A-complex formation in early spliceosome assembly and upon transition from the B-complex to the C-complex. By compiling known reactions into a complete network, the combinatorial nature of invariant computation leads to pathways that have previously not been described as connected routes, although their constituents were known. T-clusters divide the network into modules, which we interpret as building blocks in spliceosome maturation. We conclude that Petri net representations of large biological networks and system invariants, are well-suited as a means for validating the integration of experimental knowledge into a consistent model. Based on this network model, the design of further experiments is facilitated.

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来源期刊
In Silico Biology
In Silico Biology Computer Science-Computational Theory and Mathematics
CiteScore
2.20
自引率
0.00%
发文量
1
期刊介绍: The considerable "algorithmic complexity" of biological systems requires a huge amount of detailed information for their complete description. Although far from being complete, the overwhelming quantity of small pieces of information gathered for all kind of biological systems at the molecular and cellular level requires computational tools to be adequately stored and interpreted. Interpretation of data means to abstract them as much as allowed to provide a systematic, an integrative view of biology. Most of the presently available scientific journals focus either on accumulating more data from elaborate experimental approaches, or on presenting new algorithms for the interpretation of these data. Both approaches are meritorious.
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