Entecavir Patent Evaluation, Molecular
Modelling Study of Drug-Resistant HBV
Volume 1 - Issue 3
Krishnasarmapathy*
-
Author Information
Open or Close
- Department of Chemistry, Lucknow, India
*Corresponding author:
Krishnasarmapathy, Department of Chemistry, IPL Research Center Lucknow, India
Received: June 11, 2018; Published: June 19, 2018
DOI: 10.32474/SJFN.2018.01.000114
Full Text
PDF
To view the Full Article Peer-reviewed Article PDF
Abstract
Entecavir is an oral antiviral drug used in the treatment of hepatitis B infection. Entecavir is a guanosine nucleoside analogue
with selective activity against hepatitis B virus (HBV), which inhibits reverse transcription, Hepatitis B virus (HBV) is highly endemic
in South Africa and across sub-Saharan Africa, where around 8% of people are chronically infected, and rates of HBV-related liver
cancer are some of the highest in the world. Globally, viral hepatitis causes approximately 1.3 million deaths every year-more than
either malaria or tuberculosis-with around 240 million people chronically infected with HBV1. The currently available anti-HBV
drugs show potent antiviral activity in patients with chronic hepatitis B; however, the resistance and cross-resistance to the drugs is
a major obstacle in long-term treatment. Many studies have been conducted to understand the molecular basis of drug resistance,
and the mechanistic characterization and molecular modeling of anti-HBV drugs complexed with HBV RT have been reported.
Although the three-dimensional X-ray structure of HBV polymerase is not available, its homology model has been reported
using the X-ray structure of HIV RT as a template [1-5]. Even though the homology models may not be accurate due to the low
sequence homology between the overall HIV and HBV polymerase, the sequence conservation between the RT domains of HIV and
HBV polymerase enables molecular modeling of HBV RT [6]. In particular, the residues around the active site that are responsible
for recognizing the template-primer or an incoming nucleoside triphosphate are highly conserved. Nucleoside analogue HBV
polymerase inhibitors cause chain termination after incorporation into the growing chain in the active site of HBV polymerase and
consequently inhibit viral reverse transcriptase. Thus, the HBV homology model structure based on the crystal structure of HIV
polymerase serves as a useful guide for understanding the molecular basis of HBV resistance to drugs.
Abstract|
Introduction|
Discussion|
Conclusion|
References|