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Influenza study: Meet virus' new enemy

Date:
February 21, 2013
Source:
Simon Fraser University
Summary:
Virologists have discovered a new class of molecular compounds capable of killing the influenza virus. Working on the premise that too much of a good thing can be a killer, the scientists have advanced previous researchers' methods of manipulating an enzyme that is key to how influenza replicates and spreads. The new compounds will lead to a new generation of anti-influenza drugs that the virus' strains can't adapt to, and resist, as easily as they do Tamiflu.
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Simon Fraser University virologist Masahiro Niikura and his doctoral student Nicole Bance are among an international group of scientists that has discovered a new class of molecular compounds capable of killing the influenza virus.

Working on the premise that too much of a good thing can be a killer, the scientists have advanced previous researchers' methods of manipulating an enzyme that is key to how influenza replicates and spreads.

Their new compounds will lead to a new generation of anti-influenza drugs that the virus' strains can't adapt to, and resist, as easily as they do Tamiflu. It's an anti-influenza drug that is becoming less effective against the constantly mutating flu virus.

These increasingly less adequate anti-influenza drugs are currently doctors' best weapons against influenza. They helped the world beat H1N1, swine flu, into submission four years ago.

The journal Science Express has just published online the scientists' study, revealing how to use their newly discovered compounds to interrupt the enzyme neuraminidase's facilitation of influenza's spread.

Tamiflu and another anti-influenza drug, Relenza, focus on interrupting neuraminidase's ability to help influenza detach from an infected cell's surface by digesting sialic acid, a sugar on the surface of the cell. The flu virus uses the same sugar to stick to the cell while invading it. Once attached, influenza can invade the cell and replicate.

This is where the newly discovered compounds come to the still-healthy cells' rescue. They clog up neuraminidase, stopping the enzyme from dissolving the sialic acid, which prevents the virus from escaping the infected cell and spreading.

The new compounds are also more effective because they're water-soluble. "They reach the patient's throat where the flu virus is replicating after being taken orally," says Niikura, a Faculty of Health Sciences associate professor.

"Influenza develops resistance to Relenza less frequently, but it's not the drug of choice like Tamiflu because it's not water-soluble and has to be taken as a nasal spray.

"Our new compounds are structurally more similar to sialic acid than Tamiflu. We expect this closer match will make it much more difficult for influenza to adapt to new drugs."

Ultimately, the new compounds will buy scientists more time to develop new vaccines for emerging strains of influenza that are resistant to existing vaccines.


Story Source:

Materials provided by Simon Fraser University. Note: Content may be edited for style and length.


Journal Reference:

  1. Jin-Hyo Kim, Ricardo Resende, Tom Wennekes, Hong-Ming Chen, Nicole Bance, Sabrina Buchini, Andrew G. Watts, Pat Pilling, Victor A. Streltsov, Martin Petric, Richard Liggins, Susan Barrett, Jennifer L. McKimm-Breschkin, Masahiro Niikura, and Stephen G. Withers. Mechanism-Based Covalent Neuraminidase Inhibitors with Broad Spectrum Influenza Antiviral Activity. Science, 21 February 2013 DOI: 10.1126/science.1232552

Cite This Page:

Simon Fraser University. "Influenza study: Meet virus' new enemy." ScienceDaily. ScienceDaily, 21 February 2013. <www.sciencedaily.com/releases/2013/02/130221194241.htm>.
Simon Fraser University. (2013, February 21). Influenza study: Meet virus' new enemy. ScienceDaily. Retrieved November 7, 2024 from www.sciencedaily.com/releases/2013/02/130221194241.htm
Simon Fraser University. "Influenza study: Meet virus' new enemy." ScienceDaily. www.sciencedaily.com/releases/2013/02/130221194241.htm (accessed November 7, 2024).

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