Bio Saga Blog - A Chronicle of Life Sciences & Informatics

Oseltamivir (Tamiflu) is currently the frontline antiviral drug employed to fight the flu virus in infected individuals by inhibiting neuraminidase, a flu protein responsible for the release of newly synthesized virions. However, oseltamivir resistance has become a critical problem due to rapid mutation of the flu virus. Unfortunately, how mutations actually confer drug resistance is not well understood. In this study, we employ molecular dynamics (MD) and steered molecular dynamics (SMD) simulations, as well as graphics processing unit (GPU)-accelerated electrostatic mapping, to uncover the mechanism behind point mutation induced oseltamivir-resistance in both H5N1 “avian” and H1N1pdm “swine” flu N1-subtype neuraminidases. The simulations reveal an electrostatic binding funnel that plays a key role in directing oseltamivir into and out of its binding site on N1 neuraminidase. The binding pathway for oseltamivir suggests how mutations disrupt drug binding and how new drugs may circumve...

Aileron Therapeutics and Roche announced today that they have entered into a collaboration to discover, develop and commercialise a new class of drugs called Stapled Peptide Therapeutics. As part of this agreement, Roche will work with Aileron to develop drug candidates against up to five undisclosed targets selected from Roche’s key therapeutic areas, which include oncology, virology, inflammation, metabolism and CNS. Stapled Peptide Therapeutics are a result of Aileron’s breakthrough peptide stabilization technology, and are a potential solution to drug as-yet intractable disease targets, including those originating from long sought-after intracellular protein-protein interactions. Under the terms of the agreement, Roche will provide Aileron guaranteed funding of at least $25 million in technology access fees and R&D support. Aileron is eligible to receive up to $1.1 billion in payments upon the achievement of discovery, development, regulatory and commercialisation milesto...

Dr. Ronald Collman talks about exciting new discoveries on HIV, the virus that has taken 25 million lives. Dr. Ronald Collman , professor of medicine in microbiology, virus/cell/molecular core director, Penn Center for AIDS Research, University of Pennsylvania.He describes the molecular structure, pathology, and with great insight, the incredible discoveries that might just help us conquer HIV. Listen to the Original audio source

The United States Department of Agriculture has released the complete genetic sequences of 150 different avian influenza viruses and will make the information available through the National Institutes of Health’s GenBank. The USDA said on Friday that the sequencing data is part of the federal government’s Initiative on Avian Influenza, and that this information will be combined with studies that compare the viruses’ ability to infect poultry such as chickens, turkeys, and domestic ducks. This virus research that generated this data was conducted by the USDA’s Agricultural Research Service’s Southeast Poultry Research Laboratory (SEPRL), by the University of Georgia, the Ohio State University, the University of Delaware, and the University of Alaska-Fairbanks. "The project's ultimate goal is to sequence 900 avian influenza viruses from the SEPRL repository," David Suarez, a researcher with SEPRL, said in a statement. "These include avian influenza viruses col...

Already blogging about vital information that can be obtained form publications and scientific literature Smart tools to track, analyze and visualize research and the importance of Protein structure information in Protein structure databases with new web services for structural biology and biomedical research . Now one of the tactics used by influenza virus to take over the machinery of infected cells has been laid bare by structural biologists at the European Molecular Biology Laboratory ( EMBL ) and the joint Unit of Virus Host-Cell Interaction of EMBL, the University Joseph Fourier and National Centre for Scientific Research (CNRS), in Grenoble, France. The high-resolution image of the influenza virus' PB2 protein shows how the virus steals a 'cap' molecule from its host to take over the protein production machinery and multiply. PB2 binds the cap by sandwiching it between aromatic amino acids. "Viruses are masters of cunning when it comes to hijacking the normal f...