Integrating Secondary Structures Information into Triangular Spatial Relationships (TSR) for Advanced Protein Classification.

ArXiv Pub Date : 2024-11-19
Poorya Khajouie, Titli Sarkar, Krishna Rauniyar, Li Chen, Wu Xu, Vijay Raghavan
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Abstract

Protein structures represent the key to deciphering biological functions. The more detailed form of similarity among these proteins is sometimes overlooked by the conventional structural comparison methods. In contrast, further advanced methods, such as Triangular Spatial Relationship (TSR), have been demonstrated to make finer differentiations. Still, the classical implementation of TSR does not provide for the integration of secondary structure information, which is important for a more detailed understanding of the folding pattern of a protein. To overcome these limitations, we developed the SSE-TSR approach. The proposed method integrates secondary structure elements (SSEs) into TSR-based protein representations. This allows an enriched representation of protein structures by considering 18 different combinations of helix, strand, and coil arrangements. Our results show that using SSEs improves the accuracy and reliability of protein classification to varying degrees. We worked with two large protein datasets of 9.2K and 7.8K samples, respectively. We applied the SSE-TSR approach and used a neural network model for classification. Interestingly, introducing SSEs improved performance statistics for Dataset 1, with accuracy moving from 96.0% to 98.3%. For Dataset 2, where the performance statistics were already good, further small improvements were found with the introduction of SSE, giving an accuracy of 99.5% compared to 99.4%. These results show that SSE integration can dramatically improve TSR key discrimination, with significant benefits in datasets with low initial accuracies and only incremental gains in those with high baseline performance. Thus, SSE-TSR is a powerful bioinformatics tool that improves protein classification and understanding of protein function and interaction.

将二级结构信息整合到三角空间关系(TSR)中,实现高级蛋白质分类。
蛋白质结构是破译生物功能的关键。传统的结构比较方法有时会忽略这些蛋白质之间更细致的相似性。相比之下,三角形空间关系(TSR)等更先进的方法已被证明可以进行更精细的区分。然而,TSR 的经典实现方法并没有整合二级结构信息,而这对于更详细地了解蛋白质的折叠模式非常重要。为了克服这些局限性,我们开发了 SSE-TSR 方法。该方法将二级结构元素(SSE)整合到基于 TSR 的蛋白质表征中。这样就可以通过考虑 18 种不同的螺旋、链和线圈排列组合来丰富蛋白质结构的表示方法。我们的研究结果表明,使用 SSE 在不同程度上提高了蛋白质分类的准确性和可靠性。我们使用了两个大型蛋白质数据集,分别包含 9.2K 和 7.8K 个样本。我们采用了 SSE-TSR 方法,并使用神经网络模型进行分类。有趣的是,引入 SSE 改善了数据集 1 的性能统计,准确率从 96.0% 提高到 98.3%。数据集 2 的性能统计本来就不错,引入 SSE 后又有小幅提高,准确率从 99.4% 提高到 99.5%。这些结果表明,SSE 集成可以显著提高 TSR 的关键识别能力,在初始准确率较低的数据集上有明显的优势,而在基线性能较高的数据集上则只有增量收益。因此,SSE-TSR 是一种功能强大的生物信息学工具,它能改善蛋白质分类和对蛋白质功能与相互作用的理解。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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