Fungal secondary metabolites as a potential inhibitor of T315I- BCR::ABL1 mutant in chronic myeloid leukemia by molecular docking, molecular dynamics simulation and binding free energy exploration approaches

IF 3.5 Q3 Biochemistry, Genetics and Molecular Biology Journal of Genetic Engineering and Biotechnology Pub Date : 2024-11-20 DOI:10.1016/j.jgeb.2024.100444

Dilinazi Abulaiti, Niluopaer Tuerxun, Huan Wang, Lina Ma, Fang Zhao, Yang Liu, Jianping Hao

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Abstract

Background

Chronic Myeloid Leukemia (CML) is particularly challenging to treat due to the T315I BCR::ABL1 mutation. Although fungal metabolites are known for their pharmaceutical potential, none are approved for CML. Our study screened approximately 2000 fungal secondary metabolites to discover inhibitors targeting the T315I- BCR::ABL1 mutant protein.

Methods

We conducted comprehensive analyses to elucidate the interactions between the T315I-BCR::ABL1 mutant protein and selected fungal metabolites. These analyses included molecular docking, ADMET assessment, molecular dynamics simulations, principal components analysis, exploration of free energy landscapes, and per-residue decomposition.

Results

We identified a range of binding affinities for fungal secondary metabolites, from −11.2 kcal/mol to −2.90 kcal/mol, with the co-crystal ponatinib showing a binding affinity of −9.9 kcal/mol. Notably, twenty seven fungal metabolites had affinities ≤ -10.0 kcal/mol, surpassing ponatinib. Eight compounds, including Phellifuropyranone A and Meshimakobnol B, showed favorable drug-likeness. Molecular dynamics parameters, including RMSD, RMSF, Rg, and SASA, confirmed that Phellifuropyranone A and Meshimakobnol B bind stably to the T315I-BCR::ABL1 mutant protein. Additionally, PCA, DCCM, and free energy landscapes analyses validated the consistency of the molecular dynamics parameters. MM/PBSA analysis indicated that Phellifuropyranone A (–22.88 ± 4.28 kcal/mol) and Meshimakobnol B (−25.86 ± 3.51 kcal/mol) bind similarly to ponatinib (−25.54 ± 6.31 kcal/mol). Per-residue decomposition explored residues MET290, VAL299, ILE315, and PHE359 as crucial for binding to the T315I-BCR::ABL1 mutant protein.

Conclusions

Phellifuropyranone A and Meshimakobnol B show significant potency as inhibitors of the T315I-BCR::ABL1 mutant protein, comparable to ponatinib. These compounds may serve as effective alternatives or synergistic agents with ponatinib, potentially overcoming drug resistance and improving treatment outcomes in Chronic Myeloid Leukemia.

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通过分子对接、分子动力学模拟和结合自由能探索方法，将真菌次生代谢物作为慢性髓性白血病 T315I- BCR::ABL1 突变体的潜在抑制剂

背景由于T315I BCR::ABL1突变，慢性髓性白血病（CML）的治疗尤其具有挑战性。尽管真菌代谢物具有制药潜力，但没有一种真菌代谢物被批准用于治疗 CML。我们的研究筛选了约 2000 种真菌次生代谢物，以发现针对 T315I- BCR::ABL1 突变蛋白的抑制剂。方法我们进行了全面的分析，以阐明 T315I-BCR::ABL1 突变蛋白与所选真菌代谢物之间的相互作用。这些分析包括分子对接、ADMET评估、分子动力学模拟、主成分分析、自由能图谱探索和每残基分解。结果我们确定了真菌次生代谢物的一系列结合亲和力，从-11.2 kcal/mol到-2.90 kcal/mol不等，共晶体泊纳替尼的结合亲和力为-9.9 kcal/mol。值得注意的是，有 27 种真菌代谢物的亲和力≤ -10.0 kcal/mol，超过了泊纳替尼。Phellifuropyranone A和Meshimakobnol B等8种化合物显示出良好的药物相似性。分子动力学参数（包括RMSD、RMSF、Rg和SASA）证实，Phellifuropyranone A和Meshimakobnol B能与T315I-BCR::ABL1突变蛋白稳定结合。此外，PCA、DCCM 和自由能图谱分析也验证了分子动力学参数的一致性。MM/PBSA 分析表明，Phellifuropyranone A（-22.88 ± 4.28 kcal/mol）和 Meshimakobnol B（-25.86 ± 3.51 kcal/mol）与泊纳替尼（-25.54 ± 6.31 kcal/mol）的结合情况相似。每残基分解发现残基 MET290、VAL299、ILE315 和 PHE359 是与 T315I-BCR::ABL1 突变体蛋白结合的关键。这些化合物可作为有效的替代品或与泊纳替尼协同作用，从而克服耐药性，改善慢性粒细胞白血病的治疗效果。

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来源期刊

Journal of Genetic Engineering and Biotechnology Biochemistry, Genetics and Molecular Biology-Biotechnology

CiteScore

5.70

自引率

5.70%

发文量

159

审稿时长

16 weeks

期刊介绍： Journal of genetic engineering and biotechnology is devoted to rapid publication of full-length research papers that leads to significant contribution in advancing knowledge in genetic engineering and biotechnology and provide novel perspectives in this research area. JGEB includes all major themes related to genetic engineering and recombinant DNA. The area of interest of JGEB includes but not restricted to: •Plant genetics •Animal genetics •Bacterial enzymes •Agricultural Biotechnology, •Biochemistry, •Biophysics, •Bioinformatics, •Environmental Biotechnology, •Industrial Biotechnology, •Microbial biotechnology, •Medical Biotechnology, •Bioenergy, Biosafety, •Biosecurity, •Bioethics, •GMOS, •Genomic, •Proteomic JGEB accepts