Naz Sadia, Ngo Tony, Farooq Umar, Abagyan Ruben
Department of Chemistry, COMSATS Intitute of Information Technology, Abbottabad, Pakistan.
Skaggs School of Pharmacy & Pharmaceutical Sciences, University of California, San Diego, CA, United States of America.
PeerJ. 2017 Sep 19;5:e3765. doi: 10.7717/peerj.3765. eCollection 2017.
The rapid increase in antibiotic resistance by various bacterial pathogens underlies the significance of developing new therapies and exploring different drug targets. A fraction of bacterial pathogens abbreviated as ESKAPE by the European Center for Disease Prevention and Control have been considered a major threat due to the rise in nosocomial infections. Here, we compared putative drug binding pockets of twelve essential and mostly conserved metabolic enzymes in numerous bacterial pathogens including those of the ESKAPE group and . The comparative analysis will provide guidelines for the likelihood of transferability of the inhibitors from one species to another.
Nine bacterial species including six ESKAPE pathogens, along with and , two non-pathogenic bacteria, have been selected for drug binding pocket analysis of twelve essential enzymes. The amino acid sequences were obtained from Uniprot, aligned using ICM v3.8-4a and matched against the Pocketome encyclopedia. We used known co-crystal structures of selected target enzyme orthologs to evaluate the location of their active sites and binding pockets and to calculate a matrix of pairwise sequence identities across each target enzyme across the different species. This was used to generate sequence maps.
High sequence identity of enzyme binding pockets, derived from experimentally determined co-crystallized structures, was observed among various species. Comparison at both full sequence level and for drug binding pockets of key metabolic enzymes showed that binding pockets are highly conserved (sequence similarity up to 100%) among various ESKAPE pathogens as well as . Enzymes orthologs having conserved binding sites may have potential to interact with inhibitors in similar way and might be helpful for design of similar class of inhibitors for a particular species. The derived pocket alignments and distance-based maps provide guidelines for drug discovery and repurposing. In addition they also provide recommendations for the relevant model bacteria that may be used for initial drug testing.
Comparing ligand binding sites through sequence identity calculation could be an effective approach to identify conserved orthologs as drug binding pockets have shown higher level of conservation among various species. By using this approach we could avoid the problems associated with full sequence comparison. We identified essential metabolic enzymes among ESKAPE pathogens that share high sequence identity in their putative drug binding pockets (up to 100%), of which known inhibitors can potentially antagonize these identical pockets in the various species in a similar manner.
各种细菌病原体对抗生素耐药性的迅速增加凸显了开发新疗法和探索不同药物靶点的重要性。欧洲疾病预防控制中心将一部分细菌病原体简称为ESKAPE,由于医院感染的增加,这些病原体被视为重大威胁。在此,我们比较了众多细菌病原体(包括ESKAPE组的病原体)中12种必需且大多保守的代谢酶的假定药物结合口袋。比较分析将为抑制剂从一个物种转移到另一个物种的可能性提供指导。
选择了9种细菌,包括6种ESKAPE病原体,以及两种非致病性细菌 和 ,用于对12种必需酶进行药物结合口袋分析。氨基酸序列从Uniprot获得,使用ICM v3.8 - 4a进行比对,并与Pocketome百科全书进行匹配。我们使用选定目标酶直系同源物的已知共晶体结构来评估其活性位点和结合口袋的位置,并计算不同物种间每种目标酶的成对序列同一性矩阵。这用于生成序列图谱。
在不同物种间观察到源自实验确定的共结晶结构的酶结合口袋具有高度序列同一性。在全序列水平以及关键代谢酶的药物结合口袋方面的比较表明,各种ESKAPE病原体以及 中的结合口袋高度保守(序列相似性高达100%)。具有保守结合位点的酶直系同源物可能有潜力以相似方式与抑制剂相互作用,这可能有助于为特定物种设计类似类别的抑制剂。推导的口袋比对和基于距离的图谱为药物发现和重新利用提供了指导。此外,它们还为可用于初始药物测试的相关模式细菌提供了建议。
通过序列同一性计算比较配体结合位点可能是识别保守直系同源物作为药物结合口袋的有效方法,因为在不同物种间结合口袋已显示出较高水平的保守性。通过使用这种方法,我们可以避免与全序列比较相关的问题。我们在ESKAPE病原体中鉴定出在其假定药物结合口袋中具有高度序列同一性(高达100%)的必需代谢酶,其中已知抑制剂可能以类似方式拮抗不同物种中的这些相同口袋。
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