Your search keyword '"Ajmal, Amar"' showing total 4 results

1. Structural and dynamics insights into the GBA variants associated with Parkinson’s disease

Author

Mahmood, Arif, Samad, Abdus, Bano, Shazia, Umair, Muhammad, Ajmal, Amar, Ilyas, Iqra, Shah, Abid Ali, Li, Ping, and Hu, Junjian

Abstract

AbstractThe GBA1gene encodes for the lysosomal enzyme glucocerebrosidase (GCase), which maintains glycosphingolipid homeostasis and regulates the autophagy process. Genomic variants of GBA1are associated with Goucher disease; however, several heterozygous variants of GBA (E326K, T369M, N370S, L444P) are frequent high-risk factors for Parkinson’s disease (PD). The underlying mechanism of these variants has been revealed through functional and patient-centered research, but the structural and dynamical aspects of these variants have not yet been thoroughly investigated. In the current study, we used a thorough computational method to pinpoint the structural changes that GBA underwent because of genomic variants and drug binding mechanisms. According to our findings, PD-linked nsSNP variants of GBA showed structural variation and abnormal dynamics when compared to wild-typ. The docking analysis demonstrated that the mutants E326K, N370S, and L444P have higher binding affinities for Ambroxol. Root means square deviation (RMSD), Root mean square fluctuation analysis (RMSF), and MM-GBSA analysis confirmed that the Ambroxol are more stable in the binding site of N370S and L444P, and that their binding affinities are stronger as compared to the wild-type and T369M variants of GBA. The evaluation of hydrogen bonds and the calculation of the free binding energy provided additional evidence in favor of this conclusion. When docked with Ambroxol, GBA demonstrated an increase in binding affinity and catalytic activity. Understanding the therapeutic efficacy and potential against the aforementioned changes in the GBA will be beneficial in order to use more efficient methods for developing novel drugs.

Published

2024

2. Structural and dynamics insights into the GBA variants associated with Parkinson’s disease

Author

Mahmood, Arif, primary, Samad, Abdus, additional, Bano, Shazia, additional, Umair, Muhammad, additional, Ajmal, Amar, additional, Ilyas, Iqra, additional, Shah, Abid Ali, additional, Li, Ping, additional, and Hu, Junjian, additional

Published

2023

3. Identification of novel peptide inhibitors for the KRas-G12C variant to prevent oncogenic signaling

Author

Ajmal, Amar, primary, Ali, Yasir, additional, Khan, Ajmal, additional, Wadood, Abdul, additional, and Rehman, Ashfaq Ur, additional

Published

2022

4. Identification of novel peptide inhibitors for the KRas-G12C variant to prevent oncogenic signaling

Author

Ajmal, Amar, Ali, Yasir, Khan, Ajmal, Wadood, Abdul, and Rehman, Ashfaq Ur

Abstract

AbstractKirsten rat sarcoma viral oncogene homolog (KRas) activating mutations are common in solid tumors, accounting for 90%, 45%, and 35% of pancreatic, colorectal, and lung cancers (LC), respectively. Each year, nearly 150k new cases (both men and women) of KRas-mutated malignancies are reported in the United States. NSCLC (non-small cell lung cancer) accounts for 80% of all LC cases. KRas mutations are found in 15% to 25% of NSCLC patients. The main cause of NSCLC is the KRas-G12C mutation. The drugs Sotorasib and Adagrasib were recently developed to treat advanced NSCLC caused by the KRas-G12C mutation. Most patients do not respond to KRas-G12C inhibitors due to cellular, molecular, and genetic resistance. Because of their safety, efficacy, and selectivity, peptide inhibitors have the potential to treat newly developing KRas mutations. Based on the KRas mutations, peptide inhibitors that are highly selective and specific to individual lung cancers can be rationally designed. The current study uses an alanine and residue scanning approach to design peptide inhibitors for KRas-G12C based on the known peptide. Our findings show that substitution of F3K, G11T, L8C, T14C, K13D, G11S, and G11P considerably enhances the binding affinity of the novel peptides, whereas F3K, G11T, L8C, and T14C peptides have higher stability and favorable binding to the altered peptides. Overall, our study paves the road for the development of potential therapeutic peptidomimetics that target the KRas-G12C complex and may inhibit the KRas and SOS complex from interacting.Communicated by Ramaswamy H. Sarma

Published

2023