February 20, 2007

Polymerizing Actin Fibers Position Integrins Primed to Probe for Adhesion Sites

As animal cells migrate across a surface, they send out processes known as filopodia that explore the substratum. Galbraith et al.  now find that the intracellular actin network directs very local protrusions that contain clusters of cell surface-adhesion molecules at their tips that are primed to interact with molecules of the extracellular matrix. These "sticky fingers" at the leading edge of motile cells appear to search for suitable sites of adhesion that can then be used to help move the rest of the cell.

Source:
Polymerizing Actin Fibers Position Integrins Primed to Probe for Adhesion Sites. Galbraith et al. Science 16 February 2007 : Vol. 315. no. 5814, pp. 992 - 995.

February 15, 2007

HIV reveals site of vulnerability

Medical researchers have found a chink in the constantly shape-shifting armour of the HIV virus. The discovery could be a significant step forward in the ongoing quest for a vaccine.

The AIDS virus evades the immune system because most of the proteins that cover the surface of the virus constantly change their structure. But researchers have now identified a site that doesn't change, and shown how an antibody can bind to it. If the body could be stimulated to produce its own copies of this antibody before infection, then in theory, it would allow it to attack the otherwise elusive virus and prevent infection.

"For a long time people have been asking whether an HIV vaccine is even possible," says Peter Kwong of the US National Institute of Allergy and Infectious Diseases in Bethesda, Maryland, who led the research. "What this finding says is that it's not just a dream — there is this site of vulnerability."

Hide and seek

The discovery hinges on an HIV protein called gp120. During infection, gp120 latches onto a protein found in the human immune system called CD4. Because this is an essential step in the virus's replication cycle, a key site within gp120 retains its conformation, unlike other HIV surface proteins.

Vaccine researchers have known about this process for years, but there was a stumbling block. Previously, they thought that this site for antibody binding was hidden within the folds of the gp120 protein until the crucial moment of infection. This masking would mean that antibodies would not be able to recognize the unchanging portion and bind to it.

But Kwong and his colleagues have now shown that is not the case. This key part of gp120 are never hidden, they found — the protein doesn't change shape until after gp120 binds with CD4. This means that the never-changing binding site is not locked away from antibodies after all.

What's more, the team has succeeded in getting an antibody, called b12, to bind to gp120, and has studied the process to reveal the structure of the two molecules as they clamp together. They report their discovery in Nature.

Mass production

The b12 antibody is already known to protect monkeys from infection with the related simian immunodeficiency virus. The challenge now lies in finding a way to get the human body to produce lots of b12 antibodies.

A vaccine could do this in several ways, says Kwong. It could be a protein or a string of DNA that gives the body information on how to produce b12. Or a part of the HIV gp120 protein could be used to stimulate the body to raise antibodies against it.

Some people infected with HIV have developed similar antibodies. But because they have already been exposed to the virus, it is too late to prevent permanent infection. So, such a vaccine would work only if given before infection.

The question, says Kwong, is whether a drug can be developed that stimulates antibody production in someone who has never encountered the virus. The researchers now plan animal tests to see whether high levels of the antibody can be achieved.

Sources:

news@nature


Structural definition of a conserved neutralization epitope on HIV-1 gp120. Zhou T., et al. Nature, 445. 732 - 737 (2007).