HIV uses several routes to escape immune system pressure

September 19, 2009 By Leave a Comment

Washington, September 19 (ANI): Researchers at the Emory Vaccine Center have shown that HIV relies upon a number of strategies rather than use any preferred escape route to escape immune system pressure.

The human immune system has the ability to temporarily overpower HIV in early infection.

Studies conducted in the recent past have shown that most newly infected patients develop neutralizing antibodies. These are blood proteins that glob onto the virus and would allow patients to defend themselves – if they were facing only one target.

However, the problem occurs when HIV mutates, and disguises itself enough to get away from the antibodies. The virus eventually wears down the immune system into exhaustion.

The Emory team’s findings attain significance as they suggest that even if any scientist succeeds in identifying a vaccine component that can stimulate neutralizing antibodies, HIV’s capacity for rapid mutation could still be a confounding factor.

Dr. Cynthia Derdeyn, associate professor of pathology at Emory University School of Medicine, Emory Vaccine Center and Yerkes National Primate Research Center, says that a single type of neutralizing antibody may not be enough to contain HIV.

“These neutralizing antibodies work really well – they hit the virus fast and hard. But so far, every time we look, the virus escapes,” she says.

During the study, the researchers took blood samples from the participants a few weeks after infection occurred, and then later as two participants’ immune responses continued.

They isolated individual viruses over the first two years of HIV infection, and tested how well the patients’ own antibodies could neutralize them.

“In one patient where we had very early samples, there was evidence that neutralizing antibody came up within weeks, and that’s earlier than what was previously thought,” Derdeyn says.

In both patients, some viruses mutated part of their outer proteins so that after the mutation, an enzyme would be likely to attach a sugar molecule to it.

Though the sugar molecule interferes with antibody attack, this tactic, known as the “glycan shield”, was not observed in all cases.

Other viruses mutated the part of the outer protein that the neutralizing antibodies stick to directly. In both patients, many changes in the virus’ genetic code were necessary for escape.

“We need to understand early events in the immune response if we are going to figure out what a potential vaccine should have in it. What we can show is that even in one patient, several escape strategies are going on,” Derdeyn says.

According to her, that means that in order to be immune to HIV infection, someone may need to have several types of neutralizing antibodies ready to go.

Seeing how the virus mutates will allow researchers to choose the best parts to put in a vaccine, she says.

The results are online and scheduled for publication in the September issue of the journal Public Library of Science Pathogens.(ANI)

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How HIV escapes immune system pressure

April 16, 2009 By Leave a Comment

Washington, April 16 (ANI): Studying HIV-infected people with a particular gene, scientists have gained fresh insights into how the virus mutates and evolves in response to the body’s immune pressure.

Dr. Eric Hunter of the Emory Vaccine Center and Oxford University graduate student Hayley Crawford studied people in Zambia and South Africa with one form of the HLA gene that helps the immune system control HIV, called HLA-B*5703.

HLA genes encode molecules that display fragments of viral proteins, known as epitopes, on the surface of infected cells.

When white blood cells known as cytotoxic T lymphocytes (CTLs) spot certain combinations of HLA molecules and viral epitopes, they attack the infected cells.

During the study, the researchers observed that a set of three mutations in HIV’s Gag protein, which makes up the viral core, progressively slow viral replication.

They say that a triple-mutant virus replicates 20 times slower than normal in cell culture.

However, the same mutations effectively eliminate the ability of CTLs to detect the virus, so that in an infected person, once all three mutations are in place, viral abundance shoots upwards.

“In this situation, HIV resembles a thief picking a lock. Once all three mutations are in place, the lock is picked and the virus can thrive because the immune system can’t fight against it,” Hunter says.

The Emory/Oxford researchers followed the mutations’ fate after transmission by studying couples in which one person had infected the other.

They observed that the virus lost the mutations when the recipient lacked HLA-B*5703, as the three handicapping mutations were not useful in evading the new, different immune system.

However, unlucky recipients with the HLA gene, who got the triple-mutant virus from their partners, quickly got sick.

The results demonstrate the importance of CTLs, the white blood cells that attack viral infected cells, in controlling HIV infection.

They also suggest that a successful vaccine will need to induce responses to many epitopes, or combinations of HLA molecule and viral protein.

The study has been published in the Journal of Experimental Medicine. (ANI)

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New nose drops protect mice against H5N1 for months

March 1, 2009 By Leave a Comment

Washington, February 28 (ANI): Scientists at the Emory Vaccine Center have come up with a type of nose drops that may prevent against lethal H5N1 infection.

Upon using the nose drops to immunise mice, they found that the animals were protected for months against H5N1 infection.

The researchers have revealed that the heart of their nose drops are virus-like particles (VLPs)-empty shells that look like viruses but do not replicate.

Describing their approach in the journal PLoS ONE, the researchers say that it may offer an alternative to the current method of growing seasonal influenza vaccines in chicken eggs, which is slow and inefficient.

“These results suggest that VLPs could form the basis of an effective human vaccine against H5N1 influenza,” says senior author Dr. Richard Compans, professor of microbiology and immunology at Emory University School of Medicine.

With a view to determining the ability of VLPs to stimulate antibody production, Compans and his colleagues immunised some mice with them.

The researchers observed that such mice could resist an otherwise lethal dose of H5N1 virus isolated from Vietnam.

According to them, the mice’s immunity-including the levels of antibodies that protected their respiratory systems-stayed stable for over six months.

Compans has revealed that he and his colleagues would next try to determine whether if their approach can also protect against infection by mutant forms of the virus that arise frequently in birds.

His team will also be evaluating the vaccine in other animal species, in which influenza causes disease symptoms similar to those seen in humans. (ANI)

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