Abstract
The advent of personalised medicine promises a deeper understanding of mechanisms and therefore therapies. However, the connection between genomic sequences and clinical treatments is often unclear. We studied 50 breast cancer patients belonging to a population-cohort in the state of Qatar. From Sanger sequencing, we identified several new deleterious mutations in the estrogen receptor 1 gene (ESR1). The effect of these mutations on drug treatment in the protein target encoded by ESR1, namely the estrogen receptor, was achieved via rapid and accurate protein–ligand binding affinity interaction studies which were performed for the selected drugs and the natural ligand estrogen. Four nonsynonymous mutations in the ligand-binding domain were subjected to molecular dynamics simulation using absolute and relative binding free energy methods, leading to the ranking of the efficacy of six selected drugs for patients with the mutations. Our study shows that a personalised clinical decision system can be created by integrating an individual patient’s genomic data at the molecular level within a computational pipeline which ranks the efficacy of binding of particular drugs to variant proteins.
Highlights
The advent of personalised medicine promises a deeper understanding of mechanisms and therapies
In our study we identified genetic aberrations in 50 breast cancer patients from a population cohort in the state of Qatar using Sanger sequencing targeted on estrogen receptor 1 gene (ESR1), and performed ESMACS15,16 and TIES16,17 binding free energy studies to understand the effects of these mutations in a manner that could be used in the development of novel therapeutic strategies to inhibit these estrogen receptor (ER) mutants and substantially improve treatment o utcomes[18]
The present study is based on a small set of 50 breast cancer patients, it demonstrates the power of patient-specific medical approaches in treating breast cancer as it reveals the presence of uncommon mutations among patients within one local and small geographical region
Summary
The advent of personalised medicine promises a deeper understanding of mechanisms and therapies. From Sanger sequencing, we identified several new deleterious mutations in the estrogen receptor 1 gene (ESR1) The effect of these mutations on drug treatment in the protein target encoded by ESR1, namely the estrogen receptor, was achieved via rapid and accurate protein–ligand binding affinity interaction studies which were performed for the selected drugs and the natural ligand estrogen. In our study we identified genetic aberrations in 50 breast cancer patients from a population cohort in the state of Qatar using Sanger sequencing targeted on ESR1, and performed ESMACS (enhanced sampling of molecular dynamics with approximation of continuum solvent)[15,16] and TIES (thermodynamic integration with enhanced sampling)[16,17] binding free energy studies to understand the effects of these mutations in a manner that could be used in the development of novel therapeutic strategies to inhibit these ER mutants and substantially improve treatment o utcomes[18]. A related approach could be used to design new drugs which are resistant to such mutations
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