A comprehensive dataset of protein-protein interactions and ligand binding pockets for advancing drug discovery

✅ 全文

蛋白质-蛋白质相互作用和配体结合口袋的综合数据集用于推进药物发现

作者 Alexandra Moine-Franel; Fabien Mareuil; Michaël Nilges; Constantin Bogdan Ciambur; Olivier Spérandio 期刊 Scientific Data 发表日期 2024 ISSN 2052-4463 DOI 10.1038/s41597-024-03233-z 类型 原创研究 (Original Research)

📄 英文摘要 English Abstract

EN

This dataset represents a collection of pocket-centric structural data related to protein-protein interactions (PPIs) and PPI-related ligand binding sites. The dataset includes high-quality structural information on more than 23,000 pockets, 3,700 proteins on more than 500 organisms, and nearly 3500 ligands that can aid researchers in the fields of bioinformatics, structural biology, and drug discovery. It encompasses a diverse set of PPI complexes with more than 1,700 unique protein families including some with associated ligands, enabling detailed investigations into molecular interactions at the atomic level. This article introduces an indispensable resource designed to unlock the full potential of PPIs while pioneering a novel metric for pocket similarity for hypothesizing protein partners repurposing.

📄 中文摘要 Chinese Abstract

中文
蛋白质-蛋白质相互作用(PPIs)是生物系统的动力源泉,管理着众多细胞任务,在生命复杂过程中占据核心地位。充分挖掘这些蛋白质-蛋白质相互作用(PPIs)的潜力,特别是通过以结合口袋为中心的方法,对于理解细胞功能、疾病机制以及推进药物发现至关重要。在此背景下,我们引入了一项创新资源,旨在变革生物研究,主要聚焦于蛋白质结合口袋。创建该数据集的动机源于对构建一个集中且用户友好的存储库的迫切需求,该存储库能够捕捉PPIs和配体结合口袋的本质,以服务于药物设计目的。这一精心策划的数据集旨在为来自不同科学领域的研究者提供丰富的结构信息,并利用口袋相似性概念推断潜在的蛋白质相互作用伙伴。 PPIs是蛋白质在细胞内形成的动态伙伴关系。它们支撑着信号转导、DNA复制和代谢调控等重要过程。蛋白质之间的特异性结合协调着这些过程,使PPIs成为我们理解细胞功能的核心。另一方面,配体结合口袋是蛋白质内的分子对接位点,各种分子(包括小分子化合物和其他蛋白质)在此结合。这些相互作用调控蛋白质功能、控制细胞反应,对药物发现和靶向治疗至关重要。 本文提出的数据集的创建动机源于为跨不同科学领域的研究者提供全面且易于获取的资源的需求。作为一个经过策划和结构化的存储库,该数据集包含与PPI复合物、配体和配体结合口袋相关的结构数据。创建此类数据集服务于几个重要目的:推进生物研究、加速药物发现、实现数据驱动的突破,以及开发口袋相似性度量指标。

📋 英文结构化总结 English Structured Summary

全文整理

EN

Header:

Background Protein-protein interactions (PPIs) are the powerhouses of biological systems, managing a multitude of cellular tasks. They hold central roles in the intricate processes of life. Unlocking the full potential of these Protein-Protein Interactions (PPIs), particularly through a pocket-centric approach, is critical for comprehending cellular functions, diseases, and advancing drug discovery. In this context, we introduce an innovative resource poised to transform biological research, with a primary focus on protein binding pockets. Our motivation for creating this dataset arises from the pressing need for a central, user-friendly repository that captures the essence of PPIs and ligand binding pockets for drug design purposes. This carefully curated dataset is designed to support researchers from various scientific fields, offering a rich source of structural insights, and leverages the concept of pocket similarity to infer potential protein partners.

PPIs are the dynamic partnerships that proteins form within a cell. They underpin vital processes such as signal transduction, DNA replication, and metabolic regulation. The specific binding of proteins to each other orchestrates these processes, making PPIs central to our comprehension of cell function. Ligand binding pockets, on the other hand, are molecular docking sites within proteins where various molecules, including small compounds and other proteins, bind. These interactions regulate protein function, control cellular responses, and are critical for drug discovery and targeted therapies.

The motivation for creating the dataset presented in this article stems from the need for a comprehensive and accessible resource for researchers across diverse scientific domains. As a curated and structured repository of structural data pertaining to PPI complexes, ligands and ligand binding pockets. The creation of such a dataset serves several essential purposes: advancing biological research, accelerating drug discovery, enabling data-driven discoveries, and development of a pocket similarity metric.

Header:

Methods The dataset represents a collection of pocket-centric structural data related to protein-protein interactions (PPIs) and PPI-related ligand binding sites. The dataset includes high-quality structural information on more than 23,000 pockets, 3,700 proteins on more than 500 organisms, and nearly 3500 ligands. The methodology follows a workflow described in Figure 1, which outlines the steps used to build the dataset, focusing on PPI complexes, ligands, and ligand binding pockets.

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Results Key findings include the creation of a comprehensive, curated dataset covering more than 23,000 pockets, 3,700 proteins from over 500 organisms, and nearly 3,500 ligands. The dataset encompasses a diverse set of PPI complexes with more than 1,700 unique protein families, including some with associated ligands, enabling detailed investigations into molecular interactions at the atomic level. One of the key highlights of our dataset is the development of a metric for pocket similarity. This metric allows for the comparison of the structural similarity of docking sites within proteins.

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Data Summary The dataset contains more than 23,000 pockets, 3,700 proteins on more than 500 organisms, 1,700 unique protein families, and nearly 3,500 ligands. It includes high-quality structural information on PPI complexes and ligand binding pockets.

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Conclusions This article introduces an indispensable resource designed to unlock the full potential of PPIs while pioneering a novel metric for pocket similarity for hypothesizing protein partners repurposing.

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Practical Significance The dataset constitutes a centralized repository of structural data on PPIs and ligand binding pockets, enabling researchers to explore the structural basis of disease-associated PPIs, identify potential therapeutic targets, and accelerate drug discovery. It facilitates virtual screening and molecular docking studies to identify lead compounds, and supports data-driven discoveries for machine learning and AI applications.

📋 中文结构化总结 Chinese Structured Summary

中文

背景:

蛋白质-蛋白质相互作用(PPIs)是生物系统的动力源泉,管理着众多细胞任务,在生命复杂过程中占据核心地位。充分挖掘这些蛋白质-蛋白质相互作用(PPIs)的潜力,特别是通过以结合口袋为中心的方法,对于理解细胞功能、疾病机制以及推进药物发现至关重要。在此背景下,我们引入了一项创新资源,旨在变革生物研究,主要聚焦于蛋白质结合口袋。创建该数据集的动机源于对构建一个集中且用户友好的存储库的迫切需求,该存储库能够捕捉PPIs和配体结合口袋的本质,以服务于药物设计目的。这一精心策划的数据集旨在为来自不同科学领域的研究者提供丰富的结构信息,并利用口袋相似性概念推断潜在的蛋白质相互作用伙伴。

PPIs是蛋白质在细胞内形成的动态伙伴关系。它们支撑着信号转导、DNA复制和代谢调控等重要过程。蛋白质之间的特异性结合协调着这些过程,使PPIs成为我们理解细胞功能的核心。另一方面,配体结合口袋是蛋白质内的分子对接位点,各种分子(包括小分子化合物和其他蛋白质)在此结合。这些相互作用调控蛋白质功能、控制细胞反应,对药物发现和靶向治疗至关重要。

本文提出的数据集的创建动机源于为跨不同科学领域的研究者提供全面且易于获取的资源的需求。作为一个经过策划和结构化的存储库,该数据集包含与PPI复合物、配体和配体结合口袋相关的结构数据。创建此类数据集服务于几个重要目的:推进生物研究、加速药物发现、实现数据驱动的突破,以及开发口袋相似性度量指标。

方法:

该数据集代表了与蛋白质-蛋白质相互作用(PPIs)和PPI相关配体结合位点相关的以口袋为中心的结构数据的集合。该数据集包含超过23,000个口袋、来自500多种生物体的3,700种蛋白质以及近3,500种配体的高质量结构信息。该方法遵循图1中描述的工作流程,概述了构建数据集的步骤,重点关注PPI复合物、配体和配体结合口袋。

结果:

主要发现包括创建了一个全面的、经过策划的数据集,涵盖超过23,000个口袋、来自500多种生物体的3,700种蛋白质以及近3,500种配体。该数据集包含超过1,700个独特蛋白质家族的多样化PPI复合物集合,其中一些与相关配体关联,使得能够在原子水平上对分子相互作用进行详细研究。我们数据集的一个关键亮点是开发了口袋相似性度量指标。该度量指标允许比较蛋白质内对接位点的结构相似性。

数据摘要:

该数据集包含超过23,000个口袋、来自500多种生物体的3,700种蛋白质、1,700个独特蛋白质家族以及近3,500种配体。它包含PPI复合物和配体结合口袋的高质量结构信息。

结论:

本文介绍了一项不可或缺的资源,旨在充分挖掘PPIs的潜力,同时开创了一种新颖的口袋相似性度量指标,用于假设蛋白质相互作用伙伴的重新利用。

实际意义:

该数据集构成了PPIs和配体结合口袋结构数据的集中存储库,使研究人员能够探索与疾病相关的PPIs的结构基础,识别潜在的治疗靶点,并加速药物发现。它促进了虚拟筛选和分子对接研究以识别先导化合物,并支持机器学习和AI应用的数据驱动发现。

📖 英文全文 English Full Text

EN

pmc Sci Data Sci Data 2628 sdata Scientific Data 2052-4463 Nature Publishing Group PMC11032347 PMC11032347.1 11032347 11032347 38643260 10.1038/s41597-024-03233-z 3233 1 Data Descriptor A comprehensive dataset of protein-protein interactions and ligand binding pockets for advancing drug discovery Moine-Franel Alexandra 1 2 Mareuil Fabien 1 Nilges Michael 1 Ciambur Constantin Bogdan 1 Sperandio Olivier olivier.sperandio@pasteur.fr 1 1 grid.508487.6 0000 0004 7885 7602 Structural Bioinformatics Unit, Department of Structural Biology and Chemistry, Institut Pasteur, Université de Paris, CNRS UMR3528 Paris, France 2 https://ror.org/02en5vm52 grid.462844.8 0000 0001 2308 1657 Collège Doctoral, Sorbonne Université, Paris, F-75005 France 20 4 2024 2024 11 452200 402 20 12 2023 5 4 2024 20 04 2024 21 04 2024 24 03 2026 © The Author(s) 2024 https://creativecommons.org/licenses/by/4.0/ Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons licence, and indicate if changes were made. The images or other third party material in this article are included in the article’s Creative Commons licence, unless indicated otherwise in a credit line to the material. If material is not included in the article’s Creative Commons licence and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this licence, visit http://creativecommons.org/licenses/by/4.0/ . This dataset represents a collection of pocket-centric structural data related to protein-protein interactions (PPIs) and PPI-related ligand binding sites. The dataset includes high-quality structural information on more than 23,000 pockets, 3,700 proteins on more than 500 organisms, and nearly 3500 ligands that can aid researchers in the fields of bioinformatics, structural biology, and drug discovery. It encompasses a diverse set of PPI complexes with more than 1,700 unique protein families including some with associated ligands, enabling detailed investigations into molecular interactions at the atomic level. This article introduces an indispensable resource designed to unlock the full potential of PPIs while pioneering a novel metric for pocket similarity for hypothesizing protein partners repurposing. Subject terms Target validation Data mining pmc-status-qastatus 0 pmc-status-live yes pmc-status-embargo no pmc-status-released yes pmc-prop-open-access yes pmc-prop-olf no pmc-prop-manuscript no pmc-prop-legally-suppressed no pmc-prop-has-pdf yes pmc-prop-has-supplement yes pmc-prop-pdf-only no pmc-prop-suppress-copyright no pmc-prop-is-real-version no pmc-prop-is-scanned-article no pmc-prop-preprint no pmc-prop-in-epmc yes pmc-license-ref CC BY issue-copyright-statement © Springer Nature Limited 2024 Background & Summary Protein-protein interactions (PPIs) are the powerhouses of biological systems, managing a multitude of cellular tasks 1 , 2 . They hold central roles in the intricate processes of life. Unlocking the full potential of these Protein-Protein Interactions (PPIs), particularly through a pocket-centric approach 3 – 5 , is critical for comprehending cellular functions, diseases, and advancing drug discovery. In this context, we introduce an innovative resource poised to transform biological research, with a primary focus on protein binding pockets. Our motivation for creating this dataset arises from the pressing need for a central, user-friendly repository that captures the essence of PPIs and ligand binding pockets for drug design purposes. This carefully curated dataset is designed to support researchers from various scientific fields, offering a rich source of structural insights, and leverages the concept of pocket similarity to infer potential protein partners. Importance of understanding PPIs and ligand binding pockets PPIs are the dynamic partnerships that proteins form within a cell. They underpin vital processes such as signal transduction, DNA replication, and metabolic regulation. The specific binding of proteins to each other orchestrates these processes, making PPIs central to our comprehension of cell function. Ligand binding pockets, on the other hand, are molecular docking sites within proteins where various molecules, including small compounds and other proteins, bind. These interactions regulate protein function, control cellular responses, and are critical for drug discovery and targeted therapies. Motivation behind creating this dataset The motivation for creating the dataset presented in this article stems from the need for a comprehensive and accessible resource for researchers across diverse scientific domains. As a curated and structured repository of structural data pertaining to PPI complexes, ligands and ligand binding pockets (Fig.  1 ). The creation of such a dataset serves several essential purposes: Fig. 1 Description of the workflow used to build the dataset. Advancing biological research The dataset constitutes a centralized repository of structural data (more 23,000 pockets, 3,700 proteins on more than 500 organisms, 1,700 unique protein families, and nearly 3,500 ligands) on protein-protein interactions (PPIs) and ligand binding pockets, enabling researchers to conduct a wide range of studies in structural biology, bioinformatics, and systems biology. For instance, researchers can utilize the dataset to explore the structural basis of disease-associated PPIs, gaining insights into the molecular mechanisms underlying various pathological conditions. By analysing the interactions between proteins and their binding partners, researchers can identify potential therapeutic targets for drug intervention. Furthermore, the dataset facilitates the investigation of molecular recognition and ligand binding specificity. Researchers can analyse the three-dimensional structures of PPI complexes and ligand binding pockets to elucidate the molecular determinants of binding affinity and selectivity. This knowledge is essential for understanding the molecular basis of drug action and designing drugs with enhanced potency and specificity. Accelerating drug discovery Understanding the structural characteristics of PPI complexes and ligand binding pockets is crucial for accelerating drug discovery efforts. The dataset provides detailed structural information on protein-ligand interactions, offering valuable insights into potential drug targets and binding sites. Researchers can leverage this information to identify druggable pockets within proteins and design small molecules or biologics that specifically target these sites. Moreover, the dataset facilitates virtual screening and molecular docking studies to identify potential lead compounds for drug development. By computationally screening large libraries of compounds against the three-dimensional structures of target proteins on well profiled binding pockets, researchers can prioritize promising candidates for experimental validation. This accelerates the process of lead identification and optimization, ultimately expediting the development of novel therapeutics for various diseases, including cancer, infectious diseases, and neurological disorders. Enabling data-driven discoveries Data scientists can use this dataset to uncover novel relationships between proteins, ligands, and their structural features, fuelling data-driven discoveries, hypothesis generation, and finally machine learning and AI. Development of a pocket similarity metric One of the key highlights of our dataset is the development of a metric for pocket similarity. This metric allows for the comparison of the structural similarity of docking sites within proteins. Researchers can leverage this information to potentially repurpose protein partners based on structural commonalities, leading to novel insights and discoveries. Potential Applications in Scientific Research The dataset presented here has wide-ranging applications in scientific research, including but not limited to: Elucidating the structural basis of disease-associated PPIs and identifying potential therapeutic targets. Investigating the mechanisms of molecular recognition and ligand binding specificity. Conducting large-scale computational analyses of PPI networks for systems biology studies. Supporting the development of personalized medicine by characterizing individual-specific interactions. In summary, this dataset serves as a valuable resource that bridges the gap between fundamental molecular interactions and their practical applications in scientific research. It is our hope that researchers from various disciplines will find this dataset instrumental in their quest to unravel the mysteries of biology and develop innovative solutions for health and drug discovery. Methods The preparation of the protein-protein dataset and the protein-ligand dataset involves several systematic steps to ensure data accuracy and relevance (Fig.  2 ). Fig. 2 Full filtering protocol to prepare the datasets HD, PLOC, PLONC and PLA. Protein selection The preparation of the protein-protein dataset and the protein-ligand dataset involves several systematic steps to ensure data accuracy and relevance. Initially, the metadata of the entire PDB database 6 (March 2023 version) is downloaded as a.json file from the protein databank in Europe (PDBe), serving as the primary data source. PDBe annotations and Uniprot 7 identifiers (IDs) are then leveraged to identify two distinct subsets: heterodimers complexes (HD dataset) complexes, representing protein-protein interactions, and protein-ligand complexes. The next step involves cross-referencing the protein-ligand complexes with the HD dataset, ensuring that they share a Uniprot ID to only select protein-ligand pairs associated with one or several HD complexes (PL dataset). To refine the protein subset, we further impose the following rules: that HD complexes only contain two molecules with different Uniprot IDs, and each molecule has more than three residues. PL complexes are required to contain one molecule, and their ligands must have at least five heavy atoms, to ensure more complex ligands are considered. Moreover, ligands must exclusively consist of drug-like atoms, encompassing carbon (C), nitrogen (N), oxygen (O), sulphur (S), phosphorus (P), and halogens (X = I, Br, Cl, F), along with boron (B). In addition, certain ligands, such as ATP, co-factors and molecules originating from crystallization buffers were omitted from the list due to their limited relevance to drug design. The criterium used for this final step was based on the occurrence of the ligands (No of times < 10) in the PDB to list ligands to exclude followed by a visual inspection to ensure that we did not remove pertinent ligands. Furthermore, following this preliminary curation, 3D structure quality filters were then applied to the subset. Only 3D structures determined by nuclear magnetic resonance, X-ray crystallography or cryogenic electron microscopy (cryo-EM) were selected. The resolution was imposed to be is lower or equal to 3.5 or 3 Å for X-ray and cryo-EM structures, respectively. The difference between the R-free and R-factor (for X-ray structures) and the Fourier shell correlation (for cryo-EM structures) was required to be lower or equal to 0.07 and 0.143, respectively. The list of PDB IDs requiring the download of the actual structure was then compiled and executed. To enhance the dataset’s reliability, several post-download filtering steps were implemented. The 3D structures could not contain any atom with alternative locations at the protein-protein or protein-ligand interface. Moreover, the ligands of the PL datasets were sorted depending on their location with respect to an HD-associated interface. The definition of the interaction patch is based on the Euclidean distance between all atoms of the protein target and its partner. The distance threshold was fixed at 6 Angstroms (Å). This step ensures that the ligands are contextually relevant to the heterodimer complexes. Before detecting pockets, incomplete amino acids in the structures were repaired by FoldX 8 (version 5) software. Heteroatoms (only for HD complexes) and water molecules were removed and HD and PL complexes were ultimately protonated with the OPLS-AA force field of GROMACS 9 (version 2020). Subsequently, the structures were converted into.mol2 format. Pockets detection, filtration and characterization VolSite 10 was employed to detect and characterize pockets. Pockets were detected within the monomers (PL) using the ligands as reference for the selection of surrounding residues for the VolSite pocket detection and profiling. Similarly, pockets were detected on one protein within the heterodimer (HD) with the other protein treated as the ligand, and vice versa, with the roles reversed. Given that pockets within PPIs typically exhibit distinct properties, such as shallowness, we adjusted the VolSite parameters to better suit the characteristics of PPI pockets using a selection of known liganded PPIs as a positive control (Table  1 ). Table 1 List of VolSite parameters used to detect PPI pockets. VolSite parameter Description Value step Edge length of each box (Å) 1 boxS Edge length of the main box (Å) 20 b Minimal threshold for buriedness 65 n Minimal neighbours for buried cavity boxes 12 nPTS Minimal number of cubes to consider it a cavity 20 In the context of heterodimer (HD) complexes, binding pockets were verified to reside at the interface, affirming their orthosteric nature. We delineated distinct types of ligand-binding pockets within protein-ligand complexes, differentiated into three main types based on their relationship with the protein-protein interaction (PPI) interface. These classifications are crucial not only for understanding the functional implications of ligand binding but also for training machine learning models to design focused chemical libraries. We classified these pockets into three main types: orthosteric competitive (PLOC), orthosteric non-competitive (PLONC), and allosteric (PLA) pockets (Fig.  3 ). PLOC pockets involve direct competition between the ligand and the protein partner’s epitope within the heterodimer. In contrast, PLONC pockets house ligands within orthosteric pockets that don’t directly compete with the protein’s epitope but may influence its function or conformation. Finally, PLA pockets, situated near the orthosteric binding pockets of a heterodimer, don’t directly overlap with the orthosteric site but may induce allosteric effects. Fig. 3 Creation of the Protein-Ligand (PL) datasets PLA, PLONC and PLOC. Such classifications are crucial not only for understanding the functional implications of ligand binding but also for training machine learning models to design focused chemical libraries. The primary set of PL structures, comprising PLOC, could serve as positive datasets for machine learning models, while PLA could represent negative datasets for ligands binding to PPI-involved protein chains without direct interface proximity. Furthermore, the PLONC subset, capturing intermediate scenarios where ligands occupy pockets alongside protein epitopes, offers additional training data for nuanced scenarios. This dichotomy facilitates accurate discernment between competitive and non-competitive ligand interactions within protein-ligand complexes, aiding in the design of focused chemical libraries tailored to modulate protein-protein interactions. To differentiate between PLOC and PLONC, we utilized a specific criterion: pockets where the ligand was located within 1 Å of their protein partner were labelled as PLOC, while those with ligands positioned more than 1 Å away were annotated as PLONC. While acknowledging the potential limitations of this approach, such as ligands inducing conformational changes affecting the PPI surface, we recognize the complexity involved and view our approach as a foundational step in classification. Definition of a PPI pocketome and of a pocket similarity index (PSI) To assess the similarity between different pockets, we developed a metric that relies on pocket properties (e.g. volume, exposure, asphericity, etc…) as encoded by a set of quantitative descriptors. The VolSite software was utilized to calculate an extensive initial array of 89 pocket descriptors. Then, a set of 10 supplementary descriptors amalgamating attributes from those initially derived by VolSite was computed, to furnish a more nuanced depiction of pocket characteristics. These 10 amalgamated descriptors were determined in accordance with the methodology outlined in Kuenemann et al . in 2016 11 . Finally, 10 more geometric descriptors were computed using the RDKit3D module, to encompass key pocket properties such as asphericity, sphericity index, molecular eccentricity, inertial shape factor, radius of gyration, principal moments of inertia, and normalized principal moments ratio. To keep consistency, these latter descriptors were specifically calculated using the MOL2 files of the VolSite pockets (Fig.  4 ). Fig. 4 Creation of a PPI pocketome using pocket descriptor and a pocket similarity index (PSI). From the total of 109 pocket descriptors obtained above we discarded those with zero values for more than 95% of the pockets in our sample, reducing the number to 82 descriptors. The distributions of their descriptor values were subsequently analysed to ensure that each descriptor provides an equitable and non-redundant contribution towards the similarity metric. Descriptors with a high dynamic range and highly skewed distributions were re-scaled to a logarithmic scale, specifically if their distribution satisfied the following conditions: (i.) the mean value <15% of the maximum value, and (ii.) the median <65% of the mean. Finally, the descriptors were all re-scaled to have zero mean and unit variance, to minimise bias or any covariance. The similarity between two pockets was evaluated based on their distance in this resulting high-dimensional space of pocket descriptors. Thus, the Euclidean distance was calculated pairwise for the entire sample, resulting in a N × N distance matrix, with N = 23238 pockets. A Gaussian kernel was then applied to this matrix to transform the distance values into probabilities between 0 and 1, constituting what we define as the pocket similarity index (PSI): 1 \documentclass[12pt]{minimal}

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\begin{document}$$PS{I}_{ij}=\exp \left(\frac{-{d}_{ij}^{2}}{2{\sigma }^{2}}\right)$$\end{document} P S I i j = exp − d i j 2 2 σ 2 where d ij is the Euclidean distance between pockets i and j ( i ≠ j ), and σ is the standard deviation of d across all pairs. The pocketome is visualised as a minimum spanning tree using the tool TMAP 12 . This method selects only certain pairs from the complete PSI matrix in such a way as to span the entire dataset (no point is disconnected) in the optimal way, i.e. by minimising the total distance. The resulting “tree” therefore is a simplified yet powerful visual representation of our entire dataset, built to reflect local proximity (so pocket similarity) in the high dimensional pocketome space. With this tool, provided in interactive html format, users can quickly assess local clustering of similar pockets, but also study trends in the data with a number of pocket properties, such as their volume, exposure, asphericity, HD/PL or Pfam annotation, etc. We refer the reader to the Technical Validation section below for further details. Through this meticulous process of data collection, filtering, and classification, the resulting datasets are refined and enriched, facilitating comprehensive research on protein-protein interactions and ligand binding pockets, with potential implications for drug discovery. Specifically, by amalgamating a set of liganded binding pockets with an exhaustive catalogue of heterodimer pockets, we aim to create a resource intended to serve as a robust platform for identifying new potential protein-protein interaction (PPI) drug targets. This combined dataset not only enhances our understanding of protein interactions but also provides researchers with a valuable tool to explore novel avenues for drug development, potentially leading to the discovery of innovative therapeutic interventions (Fig.  4 ). Data Records The dataset is openly available 13 with the 10.5281/zenodo.10805580 under a CC BY 4.0 licence. This detailed dataset provides a comprehensive view of protein binding pockets, offering geometric, structural, and classification information crucial for understanding their properties and potential functional roles. In the following, we describe in detail one example of an HD system. For an HD system the provided folders and files always follows the same pattern. This example corresponds to the PDB code 1bxl, representing a heterodimer (HD) composed of two chains. Specifically, chain A denotes Bcl-2-like protein 1 (UniProt ID: Q07817 ) in complex with chain B, which represents Bcl-2 homologous antagonist/killer (UniProt ID: Q16611 ). 1bxl--AB-- Q07817 -- Q16611 .pdb: PDB file representing the heterodimeric complex of proteins Q07817 and Q16611 within the 1bxl structure. 1bxl--A--Q07817__Repair-H.pdb: PDB file representing the protein Q07817 (chain A) after the repair process by FoldX and protonation. 1bxl--B--Q16611__Repair-H.pdb: PDB file representing the protein Q16611 (chain B) after the repair process by FoldX and protonation. pdb1bxl.ent: Raw PDB file without any processing or modifications. results/1bxl-AB- Q07817 - Q16611 -withinA: 1bxl-AB- Q07817 - Q16611 -withinA_CAVITY_N1_ALL_orthosteric.mol2: Mol2 file describing the orthosteric VolSite pocket (CAVITY_N1) of the heterodimeric complex within chain A. 1bxl-AB- Q07817 - Q16611 -withinA_CAVITY_N2_ALL_orthosteric.mol2: Mol2 file describing another orthosteric VolSite pocket (CAVITY_N2) within chain A. 1bxl-AB- Q07817 - Q16611 -withinA_CAVITY_N3_ALL_nonorthosteric.mol2: Mol2 file representing a non-orthosteric VolSite pocket (CAVITY_N3) within chain A. 1bxl-AB- Q07817 - Q16611 -withinA_CAVITY_N4_ALL_nonorthosteric.mol2: Mol2 file representing another non-orthosteric VolSite pocket (CAVITY_N4) within chain A. 1bxl-AB- Q07817 - Q16611 -withinA_CAVITY_N5_ALL_nonorthosteric.mol2: Mol2 file representing a non-orthosteric VolSite pocket (CAVITY_N5) within chain A. 1bxl-AB- Q07817 - Q16611 -withinA_CAVITY_N6_ALL_nonorthosteric.mol2: Mol2 file representing a non-orthosteric VolSite pocket (CAVITY_N6) within chain A. 1bxl-AB- Q07817 - Q16611 -withinA_CAVITY_N7_ALL_nonorthosteric.mol2: Mol2 file representing a non-orthosteric VolSite pocket (CAVITY_N7) within chain A. 1bxl-AB- Q07817 - Q16611 -withinA_CAVITY_N1_ALL__.mol2: Mol2 file representing the orthosteric VolSite pocket (CAVITY_N1) without specific ligand information. 1bxl-AB- Q07817 - Q16611 -withinA_CAVITY_N2_ALL__.mol2: Mol2 file representing the orthosteric VolSite pocket (CAVITY_N2) without specific ligand information. 1bxl-AB- Q07817 - Q16611 -withinA_CAVITY_N3_ALL__.mol2: Mol2 file representing a non-orthosteric VolSite pocket (CAVITY_N3) without specific ligand information. 1bxl-AB- Q07817 - Q16611 -withinA_CAVITY_N4_ALL__.mol2: Mol2 file representing a non-orthosteric VolSite pocket (CAVITY_N4) without specific ligand information. 1bxl-AB- Q07817 - Q16611 -withinA_CAVITY_N5_ALL__.mol2: Mol2 file representing a non-orthosteric VolSite pocket (CAVITY_N5) without specific ligand information. 1bxl-AB- Q07817 - Q16611 -withinA_CAVITY_N6_ALL__.mol2: Mol2 file representing a non-orthosteric VolSite pocket (CAVITY_N6) without specific ligand information. 1bxl-AB- Q07817 - Q16611 -withinA_CAVITY_N7_ALL__.mol2: Mol2 file representing a non-orthosteric VolSite pocket (CAVITY_N7) without specific ligand information. state.log, state_step5.log: Log files containing information about the state or progress of the processing steps. results/1bxl-BA- Q16611 - Q07817 -withinB: 1bxl--B--Q16611__Repair-H_descriptors_3d.csv: CSV file containing 3D descriptors for the repaired structure of protein Q16611 (chain B) within chain B. state.log: Log file containing information about the state or progress of the processing steps. These files and directories provide a detailed view of the heterodimeric interactions between proteins Q07817 and Q16611 , including orthosteric and non-orthosteric binding sites and descriptors essential for understanding the binding characteristics within the 1bxl structure. Below is the description of one example of a PL system. For an PL system the provided folders and files always follows the same pattern. This example corresponds to the PDB code 1t4e, representing a PLOC PL structure composed of one chain and one ligand. Specifically, chain A denotes E3 ubiquitin-protein ligase Mdm2 (Uniprot ID – Q00987 ) in complex with ligand DIZ. 1t4e_A_DIZ_112.mol2: Mol2 file containing the ligand in its bioactive conformation, with detailed molecular information, such as atom types and bond properties, specifically for the orthosteric competitive binding site. 1t4e_A_DIZ_112.sdf: SDF (Structure Data File) format containing the ligand in its bioactive conformation for the orthosteric competitive binding site, including molecular properties. 1t4e--A-- Q00987 --DIZ-112__2mps--A--Q00987__aligned.pdb: PDB file where the protein structure (1t4e) from chain A is superimposed onto the corresponding heterodimer HD (2mps) structure, with the ligand (DIZ-112) indicated as an inhibitor. 1t4e--A-- Q00987 --DIZ-112__interface-residues_6A.txt: Text file containing a list of residues in contact with the ligand (DIZ-112) in the 1t4e structure, within a 6 Å distance threshold. 1t4e--A-- Q00987 –DIZ-112_orthosteric_competitive.pdb: PDB file representing the orthosteric competitive binding site of the protein (1t4e) with the ligand (DIZ-112) in its bioactive conformation. 1t4e--A-- Q00987 .pdb: PDB file representing chain A of the protein structure 1t4e, which is part of the heterodimer. pdb1t4e.ent: Raw PDB file without any processing or modifications. results/1t4e-A- Q00987 -DIZ-112: Directory containing various files related to the binding pockets and ligands within the 1t4e protein structure. 1t4e-A- Q00987 -DIZ-112_CAVITY_N1_ALL_liganded_orthosteric_competitive.mol2: Mol2 file describing the liganded orthosteric competitive VolSite pocket (CAVITY_N1) within the 1t4e structure. 1t4e-A- Q00987 -DIZ-112_CAVITY_N2_ALL_unliganded.mol2: Mol2 file representing the unliganded VolSite pocket (CAVITY_N2) within the 1t4e structure. 1t4e--A--Q00987__Repair-H_descriptors_3d.csv: CSV file containing 3D descriptors for the repaired structure. CAVITY_N1_ALL__.mol2: Mol2 file describing the orthosteric competitive VolSite pocket (CAVITY_N1) without specific ligand information. CAVITY_N2_ALL__.mol2: Mol2 file representing an unliganded VolSite pocket (CAVITY_N2) without specific ligand information. state.log, state_step5.log: Log files containing information about the state or progress of the processing steps. This detailed dataset provides a comprehensive view of protein-ligand interactions, including ligand structures, protein-ligand complexes, binding pocket information, and related descriptors. The files are meticulously organized and annotated, facilitating in-depth analysis and understanding of the protein-ligand interactions within the specified structures. Several csv files are provided as collections of annotated binding pockets: HD_part8_20230317_matrix_orthosteric.csv HD_part8_20230317PDBe_orthosteric__complete.csv PL_part8_20230317_matrix_liganded_allosteric.csv PL_part8_20230317PDBe_allosteric__complete.csv PL_part8_20230317_matrix_liganded_orthosteric_competitive.csv PL_part8_20230317PDBe_orthosteric_competitive__complete.csv PL_part8_20230317_matrix_liganded_orthosteric_noncompetitive.csv PL_part8_20230317PDBe_orthosteric_noncompetitive__complete.csv The provided CSV file contains a wealth of data pertaining to protein binding pockets, including VolSite pocket properties, geometric attributes derived from the negative image of the VolSite pockets stored in Mol2 format. The CSV files with the name containing “_complete” represent subsets of the former files and contain supplementary annotations related to CATH and PFAM classifications. Below is a description of the columns in the CSV file: cath: CATH classification of the protein domain to which the pocket belongs (only in csv file names containing “__complete”). pdb.chain: Identifier for the protein chain in the PDB structure. Cavity: Identifier for the specific pocket or cavity on the protein chain. ex:4lgu-A-Q13490-1YH-402_CAVITY_N2_liganded_orthosteric_competitive Pocket is found in pdb 4glu within chain A the Uniprot ID of chain A is Q13490 Ligand ID is 1YH Ligand residue number is 402 Volsite pocket is N2 the ligand found in this pocket is classified as ligand orthosteric competitive Volume: Volume of the pocket, indicating its size. CZ, CA, O, OD1, OG, N, NZ, DU: VolSite pockets properties based on polarity such aromaticity, hydrophobicity, positively/negatively charged etc. CZ40, CZ40.50,…, NZ120: VolSite pockets properties by thresholds of pocket probe burial from 40 (exposed) to 120 (buried) geometric properties calculated from the negative image of the pocket. T40, T40.50, …, T110.120: Combination of VolSite properties that aggregates the burial metric of the pocket regardless of the polarity of the probe. PMI1, PMI2, PMI3: Principal moments of inertia, describing the pocket’s shape derived from the negative image of the VolSite pockets stored in Mol2 format. NPR1, NPR2: Normalized polar requirement values derived from the negative image of the VolSite pockets stored in Mol2 format. Rgyr: Radius of gyration, a measure of the pocket’s compactness derived from the negative image of the VolSite pockets stored in Mol2 format. Asphericity: Measure of deviation from a perfect sphere derived from the negative image of the VolSite pockets stored in Mol2 format. SpherocityIndex: Index indicating how spherical the pocket is, derived from the negative image of the VolSite pockets stored in Mol2 format. Eccentricity: Measure of the pocket’s elongation, derived from the negative image of the VolSite pockets stored in Mol2 format. InertialShapeFactor: Measure of the pocket’s mass distribution, derived from the negative image of the VolSite pockets stored in Mol2 format. pdb_code_index: Identifier for the PDB code corresponding to the protein structure. chain_index: Identifier for the chain within the PDB structure. pfam_accession: PFAM accession number, indicating the protein family to which the pocket-embedding protein belongs. (only in csv file names containing “__complete”) pfam_name: Name of the PFAM protein family (only in csv file names containing “__complete”). class, architecture, topology: CATH hierarchical classifications describing the protein domain (only in csv file names containing “__complete”). homologous: Indicates whether the pocket-embedding protein has homologous structures (only in csv file names containing “__complete”). cath_name: CATH classification name of the protein domain (only in csv file names containing “__complete”). Technical Validation Data collection and filtering In meticulously curating our dataset, rigorous filtration processes were implemented to ensure its quality and relevance. After all filtering steps, four distinct subsets were built HD, PLOC, PLONC, and PLA (Table  2 ). Table 2 Summary of the four HDPL subsets. Datasets No PDBs No Pockets No Pfam No Uniprot No Unique ligands Metadata coverage HD 4770 18266 821 1735 NA 57% PLOC 1863 2325 76 119 1647 69% PLONC 715 817 42 71 539 53% PLA 1613 1830 83 112 1277 72% 1. HD Dataset: - The HD (Hetero-Dimer) dataset represents a comprehensive collection of proteins with diverse Pfam 14 domains. These proteins are involved in a wide range of biological processes and are characterized by a high level of functional variety. 2. PLOC Subset: - The PLOC (Protein-Ligand Orthosteric Competitive) subset comprises proteins from the HD dataset that interact with ligands through orthosteric binding sites. Orthosteric ligands compete with native protein partners, modulating protein activity. Proteins in this subset are involved in various cellular processes and play roles in ligand binding, signal transduction, and regulation of metabolic pathways. 3. PLONC Subset: - The PLONC (Protein-Ligand Orthosteric Non-Competitive) subset comprises proteins from the HD dataset that interact with ligands through orthosteric binding sites. These ligands modulate protein function remotely by binding to a common epitope pocket without directly competing with native protein partners. Proteins in this subset are associated with diverse biological functions, including enzyme regulation, receptor signalling, and cellular transport. 4. PLA Subset: - The PLA (Protein-Ligand Allosteric) subset consists of proteins in the HD dataset that interact with ligands at allosteric binding sites. Allosteric ligands bind to sites distinct from the interaction site. Proteins in this subset are involved in complex regulatory networks, including enzyme regulation, signal transduction, and gene expression control, and comprises a fair amount of protein kinases. Metadata: protein fold and pfam domains We could fetch the metadata for a fair amount of the detected pocket-embedding protein chains ranging from 53% for PLONC to 72% for PLA. Those metadata consist of CATH architectures and Pfam name and IDs. We could check for the 10,479 pockets of the HD for which metadata were available, that the 3 main classes (Mainly_Beta, Main_Alpha, Alpha_Beta) of the CATH classification of protein 3D-folds are well represented in the HD dataset (Fig.  5 ). A similar trend was also true for the 3 PL subsets. Fig. 5 CATH classification of the pocket-embedding protein chains of the HD dataset. The HD dataset contains a large variety of heterodimers with various cellular functions including the ones that have been investigated for drug design purposes (Table  2 ). A significant contribution of this study is the introduction of a straightforward metric, termed PSI (Pocket Similarity Index), designed to assess pocket similarities within the multidimensional pocketome space. This enables the classification, clustering, and inference of protein partner repurposing. Utilizing the PSI in conjunction with the minimum spanning tree method developed by Probst et al . 12 , we constructed a tree representing the pocketome of the HDPL datasets. Each pocket is depicted as a node in the tree, and edges connect pockets displaying a sufficiently high PSI. Notably, the tree incorporates the number of shared neighbours to establish connections, enhancing its accuracy. The resulting TMAP, available as an.html file, offers a valuable tool for pocketome analysis and exploration. Additionally, we employed the TMAP to colour-code the binding pockets based on various properties, including pocket volume, exposure, different subsets, and Pfam names (Fig.  6 ), providing a comprehensive visual representation of the intricate pocketome landscape. Fig. 6 Pocketome represented as a minimum spanning tree. Each pocket is represented as a node in the tree and the proximity of pockets in the tree highlight their similarity. TMAP coloured by Pfam (top left panel), by HDPL subsets (top right), by pocket volume (bottom left), and finally by pocket exposure (bottom right). The technical validation of our metric, in conjunction with TMAP, was first conducted by colour-coding pockets in the tree based on their Pfam annotations. This highlighted a strong alignment of Pfam names with the local branches of the tree, demonstrating the robustness and accuracy of our approach. Furthermore, when we applied colour-coding to differentiate between datasets (HD, PLOC, PLONC, and PLA) in the tree, we observed consistent branch homogeneity and distinct separation among subsets. Notably, certain branches contained pockets from multiple subsets, notably unliganded HD pockets in close proximity to successfully liganded pockets. Additionally, the colour-coding based on pocket properties, such as volume and exposure, provided further confirmation of our earlier observations, particularly the trend of HD pockets being smaller and shallower compared to those in the PL subsets. These findings validate the reliability and versatility of our metric and its integration with TMAPs, offering valuable insights into the structural intricacies of protein pockets. Supplementary information

Rejection files Publisher’s note Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations. These authors contributed equally: Alexandra Moine-Franel, Fabien Mareuil. Supplementary information The online version contains supplementary material available at 10.1038/s41597-024-03233-z. Author contributions A.M.F. and F.M. have written all the scripts to collect the data and set up calculations to annotate the data. M.N. has helped to design the curation pipeline and quality controls. C.B.C. has designed the PPI pocketome and PPI chemical space using the TMAP embedding the minimum spanning tree. O.S. has designed, supervised the study, and wrote the manuscript. Code availability No custom code was used during this study for the curation and/or validation of the dataset. Competing interests The authors declare no competing interests. References 1. Keskin O Tuncbag N Gursoy A Characterization and prediction of protein interfaces to infer protein-protein interaction networks Curr Pharm Biotechnol 2008 9 67 76 10.2174/138920108783955191 18393863 2. Gokhale A Weldeghiorghis TK Taneja V Satyanarayanajois SD Conformationally constrained peptides from CD2 to modulate protein-protein interactions between CD2 and CD58 J Med Chem 2011 54 5307 5319 10.1021/jm200004e 21755948 PMC3171192 3. Meireles LMC Dömling AS Camacho CJ ANCHOR: A web server and database for analysis of protein-protein interaction binding pockets for drug discovery Nucleic Acids Res 2010 38 W407 11 10.1093/nar/gkq502 20525787 PMC2896143 4. Koes DR Camacho CJ PocketQuery: Protein-protein interaction inhibitor starting points from protein-protein interaction structure Nucleic Acids Res 2012 40 W387 92 10.1093/nar/gks336 22523085 PMC3394328 5. Kumar V Mahato S Munshi A Kulharia M PPInS: a repository of protein-protein interaction sitesbase Sci Rep 2018 8 12453 10.1038/s41598-018-30999-1 30127348 PMC6102274 6. Berman HM The Protein Data Bank Nucleic Acids Res 2000 28 235 242 10.1093/nar/28.1.235 10592235 PMC102472 7. Bateman A UniProt: the Universal Protein Knowledgebase in 2023 Nucleic Acids Res 2023 51 D523 D531 10.1093/nar/gkac1052 36408920 PMC9825514 8. Schymkowitz, J. et al . The FoldX web server: an online force field. Nucleic Acids Res 33 , (2005). 10.1093/nar/gki387 PMC1160148 15980494 9. Van Der Spoel D GROMACS: Fast, flexible, and free J Comput Chem 2005 26 1701 1718 10.1002/jcc.20291 16211538 10. Desaphy J Azdimousa K Kellenberger E Rognan D Comparison and druggability prediction of protein-ligand binding sites from pharmacophore-annotated cavity shapes J Chem Inf Model 2012 52 2287 2299 10.1021/ci300184x 22834646 11. Kuenemann MA Labbé CM Cerdan AH Sperandio O Imbalance in chemical space: How to facilitate the identification of protein-protein interaction inhibitors Sci Rep 2016 6 23815 10.1038/srep23815 27034268 PMC4817116 12. Probst D Reymond JL Visualization of very large high-dimensional data sets as minimum spanning trees J Cheminform 2020 12 1 13 10.1186/s13321-020-0416-x 33431043 PMC7015965 13. 2023 A Comprehensive Dataset of protein-protein interactions and Ligand Binding Pockets for Advancing Drug Discovery Zenodo 10.5281/zenodo.10805580 PMC11032347 38643260 14. Mistry J Pfam: The protein families database in 2021 Nucleic Acids Res 2021 49 D412 D419 10.1093/nar/gkaa913 33125078 PMC7779014

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# 翻译

pmc Sci Data Sci Data 2628 sdata Scientific Data 2052-4463 Nature Publishing Group PMC11032347 PMC11032347.1 11032347 11032347 38643260 10.1038/s41597-024-03233-z 3233 1 数据描述符 面向药物发现的蛋白质-蛋白质相互作用及配体结合口袋综合数据集 Moine-Franel Alexandra 1 2 Mareuil Fabien 1 Nilges Michael 1 Ciambur Constantin Bogdan 1 Sperandio Olivier olivier.sperandio@pasteur.fr 1 1 grid.508487.6 0000 0004 7885 7602 结构生物信息学研究室,结构生物学与化学系,巴斯德大学,巴黎大学,法国国家科学研究中心 UMR3528,巴黎,法国 2 https://ror.org/02en5vm52 grid.462844.8 0000 0001 2308 1657 博士学院,索邦大学,巴黎,F-75005,法国 20 4 2024 2024 11 452200 402 20 12 2023 5 4 2024 20 04 2024 21 04 2024 24 03 2026 © 作者 2024 https://creativecommons.org/licenses/by/4.0/ 开放获取 本文采用知识共享署名4.0国际许可协议授权,允许在任何媒介或格式下使用、共享、改编、分发和复制,只要您对原作者和来源给予适当的署名,提供知识共享许可协议的链接,并注明是否进行了修改。本文中的图像或其他第三方材料包含在文章的知识共享许可协议中,除非在材料的信用行中另有说明。如果材料未包含在文章的知识共享许可协议中,且您的预期用途未被法规许可或超出许可范围,您需要直接获得版权持有人的许可。要查看本许可协议的副本,请访问 http://creativecommons.org/licenses/by/4.0/ 。该数据集代表了与蛋白质-蛋白质相互作用(PPIs)及PPI相关配体结合口袋相关的以口袋为中心的结构数据集合。该数据集包含超过23,000个口袋、来自500多种生物体的3,700种蛋白质以及近3,500种配体的高质量结构信息,可为生物信息学、结构生物学和药物发现领域的研究人员提供帮助。该数据集涵盖了多样化的PPI复合物,包含超过1,700个独特蛋白质家族(其中一些具有相关配体),能够在原子水平上对分子相互作用进行详细研究。本文介绍了一种旨在充分释放PPI潜力的不可或缺的资源,同时提出了一种新颖的口袋相似性度量指标,用于推测蛋白质伴侣的重新定位。 主题词 靶标验证 数据挖掘 pmc-status-qastatus 0 pmc-status-live yes pmc-status-embargo no pmc-status-released yes pmc-prop-open-access yes pmc-prop-olf no pmc-prop-manuscript no pmc-prop-legally-suppressed no pmc-prop-has-pdf yes pmc-prop-has-supplement yes pmc-prop-pdf-only no pmc-prop-suppress-copyright no pmc-prop-is-real-version no pmc-prop-is-scanned-article no pmc-prop-preprint no pmc-prop-in-epmc yes pmc-license-ref CC BY issue-copyright-statement © Springer Nature Limited 2024

## 背景与概述

蛋白质-蛋白质相互作用(PPIs)是生物系统的动力源泉,管理着众多的细胞任务^1,2^。它们在生命的复杂过程中发挥着核心作用。充分释放这些蛋白质-蛋白质相互作用(PPIs)的潜力,特别是通过以口袋为中心的方法^3–5^,对于理解细胞功能、疾病机制以及推进药物发现至关重要。在此背景下,我们引入了一种创新资源,旨在变革生物学研究,重点关注蛋白质结合口袋。我们创建该数据集的动机源于对一个集中且用户友好的存储库的迫切需求,该存储库能够捕获PPIs和配体结合口袋的本质特征以用于药物设计目的。该精心策划的数据集旨在为来自不同科学领域的研究人员提供丰富的结构信息,并利用口袋相似性概念来推断潜在的蛋白质伴侣。

### 理解PPIs和配体结合口袋的重要性

PPIs是蛋白质在细胞内形成的动态伙伴关系。它们支撑着信号转导、DNA复制和代谢调节等重要过程。蛋白质之间的特异性结合协调着这些过程,使得PPIs成为我们理解细胞功能的核心。配体结合口袋则是蛋白质内的分子对接位点,各种分子(包括小分子化合物和其他蛋白质)在此处结合。这些相互作用调控蛋白质功能、控制细胞响应,并且对于药物发现和靶向治疗至关重要。

### 创建该数据集的动机

本文所呈现数据集的创建动机源于为跨不同科学领域的研究人员提供全面且可访问资源的需求。该数据集是一个经过策划和结构化的存储库,包含与PPI复合物、配体和配体结合口袋相关的结构数据(图1)。该数据集的创建服务于以下几个重要目的:

**图1 用于构建数据集的工作流程描述。**

**推进生物学研究**

该数据集构成了一个集中的结构数据存储库(包含超过23,000个口袋、来自500多种生物体的3,700种蛋白质、1,700个独特蛋白质家族以及近3,500种配体),涵盖蛋白质-蛋白质相互作用(PPIs)和配体结合口袋,使研究人员能够开展结构生物学、生物信息学和系统生物学领域的广泛研究。例如,研究人员可以利用该数据集探索与疾病相关的PPIs的结构基础,深入了解各种病理状况的分子机制。通过分析蛋白质与其结合伴侣之间的相互作用,研究人员可以识别药物干预的潜在治疗靶标。此外,该数据集有助于研究分子识别和配体结合特异性。研究人员可以分析PPI复合物和配体结合口袋的三维结构,以阐明结合亲和力和选择性的分子决定因素。这些知识对于理解药物作用的分子基础以及设计具有增强效力和特异性的药物至关重要。

**加速药物发现**

理解PPI复合物和配体结合口袋的结构特征对于加速药物发现工作至关重要。该数据集提供了蛋白质-配体相互作用的详细结构信息,为潜在药物靶标和结合位点提供了宝贵的见解。研究人员可以利用这些信息识别蛋白质中的可药性口袋,并设计特异性靶向这些位点的小分子或生物制剂。此外,该数据集有助于虚拟筛选和分子对接研究,以识别药物开发的潜在先导化合物。通过对大型化合物库进行计算筛选,针对靶标蛋白质在特征明确的结合口袋上的三维结构,研究人员可以优先选择有前景的候选物进行实验验证。这加速了先导化合物的识别和优化过程,最终加快针对各种疾病(包括癌症、传染病和神经系统疾病)的新型疗法的开发。

**实现数据驱动的发现**

数据科学家可以利用该数据集揭示蛋白质、配体及其结构特征之间的新关系,推动数据驱动的发现、假设生成,以及最终的机器学习和人工智能应用。

### 口袋相似性度量指标的开发

我们数据集的一个关键亮点是开发了一种口袋相似性度量指标。该度量指标允许比较蛋白质内对接位点的结构相似性。研究人员可以利用这些信息,基于结构共性来潜在地重新定位蛋白质伴侣,从而获得新的见解和发现。

### 在科学研究中的潜在应用

本文所呈现的数据集在科学研究中具有广泛的应用,包括但不限于:

- 阐明与疾病相关的PPIs的结构基础并识别潜在治疗靶标。 - 研究分子识别和配体结合特异性的机制。 - 对PPI网络进行大规模计算分析以用于系统生物学研究。 - 通过表征个体特异性相互作用来支持个性化医疗的发展。

总之,该数据集作为一个宝贵的资源,架起了基础分子相互作用与其在科学研究中实际应用之间的桥梁。我们希望来自不同学科的研究人员能够发现该数据集在揭示生物学奥秘以及开发健康和药物发现创新解决方案方面的重要作用。

## 方法

蛋白质-蛋白质数据集和蛋白质-配体数据集的准备涉及多个系统步骤,以确保数据的准确性和相关性(图2)。

**图2 用于准备数据集HD、PLOC、PLONC和PLA的完整过滤流程。**

### 蛋白质选择

蛋白质-蛋白质数据集和蛋白质-配体数据集的准备涉及多个系统步骤,以确保数据的准确性和相关性。首先,从欧洲蛋白质数据库(PDBe)下载整个PDB数据库^6^(2023年3月版本)的元数据作为.json文件,作为主要数据源。随后利用PDBe注释和Uniprot^7^标识符(IDs)来识别两个不同的子集:异源二聚体复合物(HD数据集),代表蛋白质-蛋白质相互作用,以及蛋白质-配体复合物。下一步涉及将蛋白质-配体复合物与HD数据集进行交叉引用,确保它们共享一个Uniprot ID,以仅选择与一个或多个HD复合物相关的蛋白质-配体对(PL数据集)。

为了细化蛋白质子集,我们进一步施加以下规则:HD复合物仅包含具有不同Uniprot ID的两个分子,且每个分子具有超过三个残基。PL复合物需要包含一个分子,且其配体必须具有至少五个重原子,以确保考虑更复杂的配体。此外,配体必须仅由类药原子组成,包括碳(C)、氮(N)、氧(O)、硫(S)、磷(P)和卤素(X = I、Br、Cl、F),以及硼(B)。此外,某些配体,如ATP、辅因子和来自结晶缓冲液的分子,由于与药物设计的相关性有限而被从列表中排除。用于此最终步骤的标准基于配体在PDB中的出现次数(出现次数 < 10)来列出需要排除的配体,随后进行目视检查以确保我们没有移除相关配体。

此外,在初步整理之后,对子集应用三维结构质量过滤器。仅选择通过核磁共振、X射线晶体学或冷冻电子显微镜(cryo-EM)确定的三维结构。分辨率要求X射线和cryo-EM结构分别低于或等于3.5 Å或3 Å。R-free与R因子之间的差值(对于X射线结构)和傅里叶壳层相关系数(对于cryo-EM结构)要求分别低于或等于0.07和0.143。随后编译并执行需要下载实际结构的PDB ID列表。

为了增强数据集的可靠性,实施了多个下载后过滤步骤。三维结构在蛋白质-蛋白质或蛋白质-配体界面处不能包含任何具有替代位置的原子。此外,PL数据集的配物根据其在HD相关界面处的位置进行分类。相互作用斑块的定义基于靶标蛋白质与其伴侣的所有原子之间的欧几里得距离。距离阈值固定为6埃(Å)。此步骤确保配体与异源二聚体复合物在上下文中相关。

在检测口袋之前,使用FoldX^8^(版本5)软件修复结构中不完整的氨基酸。去除杂原子(仅针对HD复合物)和水分子,并最终使用GROMACS^9^(版本2020)的OPLS-AA力场对HD和PL复合物进行质子化。随后,将结构转换为.mol2格式。

### 口袋检测、过滤和表征

采用VolSite^10^进行口袋检测和表征。在单体(PL)中利用配体作为参考来检测口袋,以选择周围残基进行VolSite口袋检测和表征。类似地,在异源二聚体(HD)中的一个蛋白质上检测口袋,将另一个蛋白质视为配体,反之亦然,角色互换。鉴于PPIs内的口袋通常表现出不同的特征,例如较浅,我们调整了VolSite参数以更好地适应PPI口袋的特征,使用一组已知的配体结合PPI作为阳性对照(表1)。

**表1 用于检测PPI口袋的VolSite参数列表。**

| VolSite参数 | 描述 | 值 | |---|---|---| | step | 每个盒子的边缘长度(Å) | 1 | | boxS | 主盒子的边缘长度(Å) | 20 | | b | 埋藏度最小阈值 | 65 | | n | 埋藏腔盒的最小邻居数 | 12 | | nPTS | 将其视为腔所需的最小立方体数 | 20 |

在异源二聚体(HD)复合物的背景下,验证结合口袋位于界面处,确认其正构性质。我们在蛋白质-配体复合物中定义了不同类型的配体结合口袋,根据它们与蛋白质-蛋白质相互作用(PPI)界面的关系分为三种主要类型。这些分类不仅对于理解配体结合的功能意义至关重要,而且对于训练机器学习模型以设计聚焦化学文库也至关重要。我们将这些口袋分为三种主要类型:正构竞争性(PLOC)、正构非竞争性(PLONC)和变构性(PLA)口袋(图3)。PLOC口袋涉及配体与异源二聚体中蛋白质伴侣表位之间的直接竞争。相反,PLONC口袋容纳正构口袋中的配体,这些配体不与蛋白质的表位直接竞争,但可能影响其功能或构象。最后,PLA口袋位于异源二聚体的正构结合口袋附近,不与正构位点直接重叠,但可能诱导变构效应。

**图3 蛋白质-配体(PL)数据集PLA、PLONC和PLOC的创建。**

这些分类不仅对于理解配体结合的功能意义至关重要,而且对于训练机器学习模型以设计聚焦化学文库也至关重要。PL结构的主要集合(包含PLOC)可作为机器学习模型的正数据集,而PLA可代表与PPI涉及的蛋白质链结合但不直接接近界面的配体的负数据集。此外,PLONC子集捕获了配体与蛋白质表位共同占据口袋的中间场景,为细微场景提供了额外的训练数据。这种二分法有助于准确区分蛋白质-配体复合物中的竞争性配体相互作用和非竞争性配体相互作用,有助于设计定制化的聚焦化学文库以调节蛋白质-蛋白质相互作用。

为了区分PLOC和PLONC,我们使用了一个特定标准:配体位于其蛋白质伴侣1 Å以内的口袋被标记为PLOC,而配体距离超过1 Å的口袋被注释为PLONC。虽然承认这种方法可能存在局限性,例如配体诱导影响PPI表面的构象变化,但我们认识到所涉及的复杂性,并将我们的方法视为分类的基础步骤。

### PPI口袋组的定义和口袋相似性指数(PSI)

为了评估不同口袋之间的相似性,我们开发了一种依赖于口袋属性(例如体积、暴露度、非球面性等)的度量指标,这些属性由一组定量描述符编码。利用VolSite软件计算了包含89个口袋描述符的广泛初始阵列。随后,计算了10个补充描述符,这些描述符融合了最初由VolSite导出的属性,以提供更细致的口袋特征描述。这10个融合描述符是根据Kuenemann等人于2016年^11^概述的方法确定的。最后,使用RDKit3D模块计算了10个几何描述符,以涵盖关键口袋属性,如非球面性、球形指数、分子偏心率、惯性形状因子、回转半径、主惯性矩和归一化主惯性矩比。为保持一致性,这些描述符专门使用VolSite口袋的MOL2文件计算(图4)。

**图4 使用口袋描述符和口袋相似性指数(PSI)创建PPI口袋组。**

从上述获得的109个口袋描述符中,我们丢弃了在我们样本中超过95%的口袋中值为零的描述符,将数量减少到82个。随后分析其描述符值的分布,以确保每个描述符对相似性度量指标提供公平且非冗余的贡献。具有大动态范围和高偏态分布的描述符被重新缩放为对数尺度,具体而言,如果其分布满足以下条件:(i.)平均值 < 最大值的15%,以及(ii.)中位数 < 平均值的65%。最后,所有描述符被重新缩放为零均值和单位方差,以最小化偏差或任何协方差。

两个口袋之间的相似性基于它们在所得高维口袋描述符空间中的距离进行评估。因此,对整个样本成对计算欧几里得距离,得到一个N × N距离矩阵,其中N = 23,238个口袋。随后对该矩阵应用高斯核,将距离值转换为0到1之间的概率,构成我们定义的口袋相似性指数(PSI):

$$PSI_{ij} = \exp\left(\frac{-d_{ij}^2}{2\sigma^2}\right)$$

其中$d_{ij}$是口袋$i$和$j$($i \neq j$)之间的欧几里得距离,$\sigma$是所有配对中$d$的标准差。

口袋组使用工具TMAP^12^可视化为最小生成树。该方法从完整PSI矩阵中仅选择某些配对,以最优方式跨越整个数据集(没有任何点断开连接),即通过最小化总距离。因此,所得的"树"是我们整个数据集的简化但强大的可视化表示,构建为反映高维口袋组空间中的局部邻近性(即口袋相似性)。通过此工具(以交互式html格式提供),用户可以快速评估相似口袋的局部聚类,还可以研究数据中多种口袋属性的趋势,如体积、暴露度、HD/PL或Pfam注释等。我们请读者参阅下文的技术验证部分以获取更多详细信息。

通过这一细致的数据收集、过滤和分类过程,所得数据集经过精炼和丰富,有助于对蛋白质-蛋白质相互作用和配体结合口袋进行全面研究,对药物发现具有潜在意义。具体而言,通过将一组配体结合口袋与异源二聚体口袋的综合目录相结合,我们旨在创建一个资源,作为识别新的潜在蛋白质-蛋白质相互作用(PPI)药物靶标的强大平台。该组合数据集不仅增强了我们对蛋白质相互作用的理解,还为研究人员提供了探索药物开发新途径的宝贵工具,可能带来创新治疗干预的发现(图4)。

## 数据记录

该数据集在CC BY 4.0许可协议下公开可用^13^,DOI为10.5281/zenodo.10805580。该详细数据集提供了蛋白质结合口袋的全面视图,提供了解其特性和潜在功能作用所必需的几何、结构和分类信息。以下我们详细描述了一个HD系统的示例。对于HD系统,所提供的文件夹和文件始终遵循相同的模式。该示例对应于PDB代码1bxl,代表一个由两条链组成的异源二聚体(HD)。具体而言,链A表示Bcl-2样蛋白1(UniProt ID:Q07817),与链B形成复合物,链B表示Bcl-2同源拮抗剂/杀手(UniProt ID:Q16611)。

- **1bxl--AB--Q07817--Q16611.pdb**:PDB文件,表示1bxl结构内蛋白质Q07817和Q16611的异源二聚体复合物。 - **1bxl--A--Q07817__Repair-H.pdb**:PDB文件,表示经过FoldX修复和质子化后的蛋白质Q07817(链A)。 - **1bxl--B--Q16611__Repair-H.pdb**:PDB文件,表示经过FoldX修复和质子化后的蛋白质Q16611(链B)。 - **pdb1bxl.ent**:未经任何处理或修改的原始PDB文件。 - **results/1bxl-AB-Q07817-Q16611-withinA**: - **1bxl-AB-Q07817-Q16611-withinA_CAVITY_N1_ALL_orthosteric.mol2**:描述异源二聚体复合物在链A内的正构VolSite口袋(CAVITY_N1)的Mol2文件。 - **1bxl-AB-Q07817-Q16611-withinA_CAVITY_N2_ALL_orthosteric.mol2**:描述链A内另一个正构VolSite口袋(CAVITY_N2)的Mol2文件。 - **1bxl-AB-Q07817-Q16611-withinA_CAVITY_N3_ALL_nonorthosteric.mol2**:表示链A内一个非正构VolSite口袋(CAVITY_N3)的Mol2文件。 - **1bxl-AB-Q07817-Q16611-withinA_CAVITY_N4_ALL_nonorthosteric.mol2**:表示链A内另一个非正构VolSite口袋(CAVITY_N4)的Mol2文件。 - **1bxl-AB-Q07817-Q16611-withinA_CAVITY_N5_ALL_nonorthosteric.mol2**:表示链A内一个非正构VolSite口袋(CAVITY_N5)的Mol2文件。 - **1bxl-AB-Q07817-Q16611-withinA_CAVITY_N6_ALL_nonorthosteric.mol2**:表示链A内一个非正构VolSite口袋(CAVITY_N6)的Mol2文件。 - **1bxl-AB-Q07817-Q16611-withinA_CAVITY_N7_ALL_nonorthosteric.mol2**:表示链A内一个非正构VolSite口袋(CAVITY_N7)的Mol2文件。 - **1bxl-AB-Q07817-Q16611-withinA_CAVITY_N1_ALL__.mol2**:表示无特定配体信息的正构VolSite口袋(CAVITY_N1)的Mol2文件。 - **1bxl-AB-Q07817-Q16611-withinA_CAVITY_N2_ALL__.mol2**:表示无特定配体信息的正构VolSite口袋(CAVITY_N2)的Mol2文件。 - **1bxl-AB-Q07817-Q16611-withinA_CAVITY_N3_ALL__.mol2**:表示无非特定配体信息的非正构VolSite口袋(CAVITY_N3)的Mol2文件。 - **1bxl-AB-Q07817-Q16611-withinA_CAVITY_N4_ALL__.mol2**:表示无特定配体信息的非正构VolSite口袋(CAVITY_N4)的Mol2文件。 - **1bxl-AB-Q07817-Q16611-withinA_CAVITY_N5_ALL__.mol2**:表示无特定配体信息的非正构VolSite口袋(CAVITY_N5)的Mol2文件。 - **1bxl-AB-Q07817-Q16611-withinA_CAVITY_N6_ALL__.mol2**:表示无特定配体信息的非正构VolSite口袋(CAVITY_N6)的Mol2文件。 - **1bxl-AB-Q07817-Q16611-withinA_CAVITY_N7_ALL__.mol2**:表示无特定配体信息的非正构VolSite口袋(CAVITY_N7)的Mol2文件。 - **state.log, state_step5.log**:包含处理步骤状态或进度信息的日志文件。 - **results/1bxl-BA-Q16611-Q07817-withinB**: - **1bxl--B--Q16611__Repair-H_descriptors_3d.csv**:包含链B内蛋白质Q16611(链B)修复结构的3D描述符的CSV文件。 - **state.log**:包含处理步骤状态或进度信息的日志文件。

这些文件和目录提供了蛋白质Q07817和Q16611之间异源二聚体相互作用的详细视图,包括正构和非正构结合位点以及理解1bxl结构内结合特征所必需的描述符。

以下是一个PL系统示例的描述。对于PL系统,所提供的文件夹和文件始终遵循相同的模式。该示例对应于PDB代码1t4e,代表由一个链和一个配体组成的PLOC PL结构。具体而言,链A表示E3泛素蛋白连接酶Mdm2(UniProt ID – Q00987),与配体DIZ形成复合物。

- **1t4e_A_DIZ_112.mol2**:包含配体生物活性构象的Mol2文件,具有详细的分子信息,如原子类型和键特性,专门针对正构竞争性结合位点。 - **1t4e_A_DIZ_112.sdf**:SDF(结构数据文件)格式,包含正构竞争性结合位点配体的生物活性构象,包括分子特性。 - **1t4e--A--Q00987--DIZ-112__2mps--A--Q00987__aligned.pdb**:PDB文件,其中1t4e的蛋白质结构(链A)叠加到相应的异源二聚体HD(2mps)结构上,配体(DIZ-112)被标记为抑制剂。 - **1t4e--A--Q00987--DIZ-112__interface-residues_6A.txt**:文本文件,包含在1t4e结构中与配体(DIZ-112)接触的残基列表,距离阈值为6 Å。 - **1t4e--A--Q00987–DIZ-112_orthosteric_competitive.pdb**:PDB文件,表示蛋白质(1t4e)与配体(DIZ-112)在生物活性构象中的正构竞争性结合位点。 - **1t4e--A--Q00987.pdb**:PDB文件,表示蛋白质结构1t4e的链A,该链是异源二聚体的一部分。 - **pdb1t4e.ent**:未经任何处理或修改的原始PDB文件。 - **results/1t4e-A-Q00987-DIZ-112**:包含与1t4e蛋白质结构内结合口袋和配体相关的各种文件的目录。 - **1t4e-A-Q00987-DIZ-112_CAVITY_N1_ALL_liganded_orthosteric_competitive.mol2**:描述1t4e结构内配体结合的正构竞争性VolSite口袋(CAVITY_N1)的Mol2文件。 - **1t4e-A-Q00987-DIZ-112_CAVITY_N2_ALL_unliganded.mol2**:表示1t4e结构内未配体结合的VolSite口袋(CAVITY_N2)的Mol2文件。 - **1t4e--A--Q00987__Repair-H_descriptors_3d.csv**:包含修复结构的3D描述符的CSV文件。 - **CAVITY_N1_ALL__.mol2**:描述无特定配体信息的正构竞争性VolSite口袋(CAVITY_N1)的Mol2文件。 - **CAVITY_N2_ALL__.mol2**:表示无特定配体信息的未配体结合VolSite口袋(CAVITY_N2)的Mol2文件。 - **state.log, state_step5.log**:包含处理步骤状态或进度信息的日志文件。

该详细数据集提供了蛋白质-配体相互作用的全面视图,包括配体结构、蛋白质-配体复合物、结合口袋信息和相关描述符。这些文件经过精心组织和注释,有助于深入分析和理解指定结构内的蛋白质-配体相互作用。

提供了多个CSV文件作为注释结合口袋的集合:

- HD_part8_20230317_matrix_orthosteric.csv - HD_part8_20230317PDBe_orthosteric__complete.csv - PL_part8_20230317_matrix_liganded_allosteric.csv - PL_part8_20230317PDBe_allosteric__complete.csv - PL_part8_20230317_matrix_liganded_orthosteric_competitive.csv - PL_part8_20230317PDBe_orthosteric_competitive__complete.csv - PL_part8_20230317_matrix_liganded_orthosteric_noncompetitive.csv - PL_part8_20230317PDBe_orthosteric_noncompetitive__complete.csv

所提供的CSV文件包含大量与蛋白质结合口袋相关的数据,包括VolSite口袋属性、从以Mol2格式存储的VolSite口袋负像导出的几何属性。文件名包含"_complete"的CSV文件是上述文件的子集,包含与CATH和PFAM分类相关的补充注释。

以下是CSV文件中各列的描述:

- **cath**:口袋所属蛋白质结构域的CATH分类(仅在文件名包含"__complete"的CSV文件中)。 - **pdb.chain**:PDB结构中蛋白质链的标识符。 - **Cavity**:蛋白质链上特定口袋或空腔的标识符。 - 示例:4lgu-A-Q13490-1YH-402_CAVITY_N2_liganded_orthosteric_competitive - 口袋位于PDB 4glu的链A中,链A的UniProt ID为Q13490,配体ID为1YH,配体残基编号为402,VolSite口袋为N2,该口袋中的配体被分类为正构竞争性配体。 - **Volume**:口袋的体积,表示其大小。 - **CZ, CA, O, OD1, OG, N, NZ, DU**:基于极性的VolSite口袋属性,如芳香性、疏水性、正/负电荷等。 - **CZ40, CZ40.50,…, NZ120**:从40(暴露)到120(埋藏)的口袋探针埋藏阈值下的VolSite口袋属性,从口袋负像计算的几何属性。 - **T40, T40.50, …, T110.120**:组合了VolSite属性的属性,汇总了口袋的埋藏度量,无论探针的极性如何。 - **PMI1, PMI2, PMI3**:主惯性矩,描述从以Mol2格式存储的VolSite口袋负像导出的口袋形状。 - **NPR1, NPR2**:从以Mol2格式存储的VolSite口袋负像导出的归一化极性需求值。 - **Rgyr**:回转半径,衡量紧凑性的指标,从以Mol2格式存储的VolSite口袋负像导出。 - **Asphericity**:偏离完美球体的度量,从以Mol2格式存储的VolSite口袋负像导出。 - **SpherocityIndex**:表示口袋球形程度的指数,从以Mol2格式存储的VolSite口袋负像导出。 - **Eccentricity**:口袋伸长度的度量,从以Mol2格式存储的VolSite口袋负像导出。 - **InertialShapeFactor**:口袋质量分布的度量,从以Mol2格式存储的VolSite口袋负像导出。 - **pdb_code_index**:对应蛋白质结构的PDB代码标识符。 - **chain_index**:PDB结构内链的标识符。 - **pfam_accession**:PFAM登录号,表示口袋嵌入蛋白质所属的蛋白质家族(仅在文件名包含"__complete"的CSV文件中)。 - **pfam_name**:PFAM蛋白质家族的名称(仅在文件名包含"__complete"的CSV文件中)。 - **class, architecture, topology**:描述蛋白质结构域的CATH层次分类(仅在文件名包含"__complete"的CSV文件中)。 - **homologous**:表示口袋嵌入蛋白质是否具有同源结构(仅在文件名包含"__complete"的CSV文件中)。 - **cath_name**:蛋白质结构域的CATH分类名称(仅在文件名包含"__complete"的CSV文件中)。

## 技术验证

### 数据收集和过滤

在精心策划我们的数据集时,实施了严格的过滤流程以确保其质量和相关性。在所有过滤步骤之后,构建了四个不同的子集:HD、PLOC、PLONC和PLA(表2)。

**表2 四个HDPL子集的摘要。**

| 数据集 | PDB数量 | 口袋数量 | Pfam数量 | Uniprot数量 | 独特配体数量 | 元数据覆盖率 | |---|---|---|---|---|---|---| | HD | 4770 | 18266 | 821 | 1735 | NA | 57% | | PLOC | 1863 | 2325 | 76 | 119 | 1647 | 69% | | PLONC | 715 | 817 | 42 | 71 | 539 | 53% | | PLA | 1613 | 1830 | 83 | 112 | 1277 | 72% |

1. **HD数据集**:HD(异源二聚体)数据集代表了具有多样化Pfam^14^结构域的蛋白质的综合集合。这些蛋白质参与广泛的生物过程,具有高度的功能多样性。 2. **PLOC子集**:PLOC(蛋白质-配体正构竞争性)子集包含HD数据集中通过正构结合位点与配体相互作用的蛋白质。正构配体与天然蛋白质伴侣竞争,调节蛋白质活性。该子集中的蛋白质参与各种细胞过程,并在配体结合、信号转导和代谢途径调节中发挥作用。 3. **PLONC子集**:PLONC(蛋白质-配体正构非竞争性)子集包含HD数据集中通过正构结合位点与配体相互作用的蛋白质。这些配体通过结合共同表位口袋远程调节蛋白质功能,而不与天然蛋白质伴侣直接竞争。该子集中的蛋白质与多种生物功能相关,包括酶调节、受体信号传导和细胞转运。 4. **PLA子集**:PLA(蛋白质-配体变构性)子集由HD数据集中在变构结合位点与配体相互作用的蛋白质组成。变构配体结合不同于相互作用位点的位点。该子集中的蛋白质参与复杂的调节网络,包括酶调节、信号转导和基因表达控制,并包含相当数量的蛋白激酶。

### 元数据:蛋白质折叠和Pfam结构域

我们能够获取相当一部分检测到的口袋嵌入蛋白质链的元数据,范围从PLONC的53%到PLA的72%。这些元数据包括CATH架构以及Pfam名称和ID。我们能够检查HD中10,479个有元数据可用的口袋,CATH蛋白质三维折叠分类的3个主要类别(Mainly_Beta、Main_Alpha、Alpha_Beta)在HD数据集中得到了很好的表示(图5)。三个PL子集也呈现类似的趋势。

**图5 HD数据集的口袋嵌入蛋白质链的CATH分类。**

HD数据集包含多种具有不同细胞功能的异源二聚体,包括那些已被用于药物设计研究的异源二聚体(表2)。

本研究的一个重要贡献是引入了一个简单的度量指标,称为PSI(口袋相似性指数),旨在评估多维口袋组空间内的口袋相似性。这使得能够对蛋白质伴侣的重新定位进行分类、聚类和推断。利用PSI与Probst等人^12^开发的最小生成树方法相结合,我们构建了代表HDPL数据集口袋组的树。每个口袋被描绘为树中的节点,边连接显示足够高PSI的口袋。值得注意的是,该树纳入共享邻居的数量以建立连接,提高了其准确性。所得的TMAP以.html文件形式提供,为口袋组分析和探索提供了有价值的工具。

此外,我们利用TMAP根据各种属性对结合口袋进行颜色编码,包括口袋体积、暴露度、不同子集和Pfam名称(图6),提供了复杂口袋组景观的全面可视化表示。

**图6 表示为最小生成树的口袋组。每个口袋被表示为树中的一个节点,树中口袋的邻近性突出它们的相似性。按Pfam着色的TMAP(左上)、按HDPL子集着色(右上)、按口袋体积着色(左下),以及按口袋暴露度着色(右下)。**

我们的度量指标与TMAP结合的技术验证首先通过根据口袋的Pfam注释对树中的口袋进行颜色编码来进行。这突出了Pfam名称与树的局部分支之间的强一致性,证明了我们方法的稳健性和准确性。此外,当我们应用颜色编码来区分树中的数据集(HD、PLOC、PLONC和PLA)时,我们观察到一致的分支同质性和子集之间的明显分离。值得注意的是,某些分支包含来自多个子集的口袋,特别是未配体结合的HD口袋与成功配体结合的口袋非常接近。此外,基于口袋属性(如体积和暴露度)的颜色编码进一步证实了我们的早期观察,特别是与PL子集中的口袋相比,HD口袋更小且更浅的趋势。这些发现验证了我们的度量指标及其与TMAP集成的可靠性和多功能性,为蛋白质口袋的结构复杂性提供了宝贵的见解。

## 补充信息

## 拒稿文件

## 出版者说明

Springer Nature对已出版地图和机构隶属关系中的管辖权主张保持中立。

这些作者贡献相同:Alexandra Moine-Franel、Fabien Mareuil。

## 补充信息

在线版本包含补充材料,获取地址为10.1038/s41597-024-03233-z。

## 作者贡献

A.M.F.和F.M.编写了所有数据收集脚本并建立了数据注释计算流程。M.N.帮助设计了整理流程和质量控制。C.B.C.使用嵌入最小生成树的TMAP设计了PPI口袋组和PPI化学空间。O.S.设计、监督了研究并撰写了手稿。

## 代码可用性

在本研究的数据集整理和/或验证过程中未使用自定义代码。

## 竞争利益

作者声明无竞争利益。