Your search keyword '"Jacobs, Lian M. C."' showing total 4 results

1. Drug Discovery in the Field of β-Lactams: An Academic Perspective.

Author

Jacobs, Lian M. C., Consol, Patrick, and Chen, Yu

Subjects

DRUG discovery, LACTAMS, CEFTAZIDIME, PENICILLIN-binding proteins, CYCLIC compounds, SMALL molecules, DRUG resistance in bacteria

Abstract

β-Lactams are the most widely prescribed class of antibiotics that inhibit penicillin-binding proteins (PBPs), particularly transpeptidases that function in peptidoglycan synthesis. A major mechanism of antibiotic resistance is the production of β-lactamase enzymes, which are capable of hydrolyzing β-lactam antibiotics. There have been many efforts to counter increasing bacterial resistance against β-lactams. These studies have mainly focused on three areas: discovering novel inhibitors against β-lactamases, developing new β-lactams less susceptible to existing resistance mechanisms, and identifying non-β-lactam inhibitors against cell wall transpeptidases. Drug discovery in the β-lactam field has afforded a range of research opportunities for academia. In this review, we summarize the recent new findings on both β-lactamases and cell wall transpeptidases because these two groups of enzymes are evolutionarily and functionally connected. Many efforts to develop new β-lactams have aimed to inhibit both transpeptidases and β-lactamases, while several promising novel β-lactamase inhibitors have shown the potential to be further developed into transpeptidase inhibitors. In addition, the drug discovery progress against each group of enzymes is presented in three aspects: understanding the targets, screening methodology, and new inhibitor chemotypes. This is to offer insights into not only the advancement in this field but also the challenges, opportunities, and resources for future research. In particular, cyclic boronate compounds are now capable of inhibiting all classes of β-lactamases, while the diazabicyclooctane (DBO) series of small molecules has led to not only new β-lactamase inhibitors but potentially a new class of antibiotics by directly targeting PBPs. With the cautiously optimistic successes of a number of new β-lactamase inhibitor chemotypes and many questions remaining to be answered about the structure and function of cell wall transpeptidases, non-β-lactam transpeptidase inhibitors may usher in the next exciting phase of drug discovery in this field. [ABSTRACT FROM AUTHOR]

Published

2024

2. A yeast-based system to study SARS-CoV-2 Mpro structure and to identify nirmatrelvir resistant mutations.

Author

Ou, Jin, Lewandowski, Eric M., Hu, Yanmei, Lipinski, Austin A., Aljasser, Ali, Colon-Ascanio, Mariliz, Morgan, Ryan T., Jacobs, Lian M. C., Zhang, Xiujun, Bikowitz, Melissa J., Langlais, Paul R., Tan, Haozhou, Wang, Jun, Chen, Yu, and Choy, John S.

Subjects

PROTEASE inhibitors, SARS-CoV-2, SARS-CoV-2 Omicron variant, COVID-19, SACCHAROMYCES cerevisiae, COVID-19 treatment, DRUG resistance

Abstract

The SARS-CoV-2 main protease (Mpro) is a major therapeutic target. The Mpro inhibitor, nirmatrelvir, is the antiviral component of Paxlovid, an orally available treatment for COVID-19. As Mpro inhibitor use increases, drug resistant mutations will likely emerge. We have established a non-pathogenic system, in which yeast growth serves as an approximation for Mpro activity, enabling rapid identification of mutants with altered enzymatic activity and drug sensitivity. The E166 residue is known to be a potential hot spot for drug resistance and yeast assays identified substitutions which conferred strong nirmatrelvir resistance and others that compromised activity. On the other hand, N142A and the P132H mutation, carried by the Omicron variant, caused little to no change in drug response and activity. Standard enzymatic assays confirmed the yeast results. In turn, we solved the structures of Mpro E166R, and Mpro E166N, providing insights into how arginine may drive drug resistance while asparagine leads to reduced activity. The work presented here will help characterize novel resistant variants of Mpro that may arise as Mpro antivirals become more widely used. Author summary: The SARS-CoV-2 virus has proven to be highly adept at evading the newly developed vaccines. Antiviral drugs provide an important alternative that can reduce disease severity. Nirmatrelvir, an orally available drug approved by the FDA to treat COVID-19, inhibits the SARS-CoV-2 main or 3C-like protease (Mpro or 3CLpro) and reduces the severity of COVID-19 infections. However, continued use of nirmatrelvir will likely drive the emergence of drug resistant Mpro mutations. Our study reports a rapid, inexpensive, and non-pathogenic system using baker's yeast that can determine if potential Mpro mutations may confer drug resistance. Furthermore, we solve the structures of two Mpro mutants first characterized in yeast that provide insights into how E166 can change to drive resistance versus leading to inactivity. Our results can aid in advancing our understanding of resistance mechanisms that will be important as nirmatrelvir and other protease inhibitors become more widely used. [ABSTRACT FROM AUTHOR]

Published

2023

3. Naturally Occurring Mutations of SARS-CoV‑2 Main Protease Confer Drug Resistance to Nirmatrelvir.

Author

Hu, Yanmei, Lewandowski, Eric M., Tan, Haozhou, Zhang, Xiaoming, Morgan, Ryan T., Zhang, Xiujun, Jacobs, Lian M. C., Butler, Shane G., Gongora, Maura V., Choy, John, Deng, Xufang, Chen, Yu, and Wang, Jun

Published

2023

4. Metallocenyl 7‐ACA Conjugates: Antibacterial Activity Studies and Atomic‐Resolution X‐ray Crystal Structure with CTX‐M β‐Lactamase.

Author

Lewandowski, Eric M., Szczupak, Łukasz, Kowalczyk, Aleksandra, Mendoza, Gracia, Arruebo, Manuel, Jacobs, Lian M. C., Stączek, Paweł, Chen, Yu, and Kowalski, Konrad

Published

2020