Research findings open new front in fight against AIDS virus

Most of the drugs now used to fight HIV, which is the retrovirus that causes acquired immune deficiency syndrome (AIDS), target the virus’s own proteins. However, because HIV has a high rate of genetic mutation, those viral targets change quickly and lead to the emergence of drug-resistant viral strains. Doctors have tried to outmaneuver the rapidly mutating virus by prescribing multi-drug regimens or switching drugs. But such strategies can increase the risk of toxic side effects, be difficult for patients to follow and are not always successful. Recently, interest has grown in attacking HIV on a new front by developing drugs that target proteins of human cells, which are far less prone to mutations than are viral proteins.

In the new study, Pamela Schwartzberg, M.D., Ph.D., a senior investigator at the National Human Genome Research Institute (NHGRI), part of NIH; Andrew J. Henderson, Ph.D., of Boston University; and their colleagues found that when they interfered with a human protein called interleukin-2-inducible T cell kinase (ITK) they inhibited HIV infection of key human immune cells, called T cells. ITK is a signaling protein that activates T cells as part of the body’s healthy immune response.

“This new insight represents an important contribution to HIV research,” said NHGRI Scientific Director Eric D. Green, M.D., Ph.D. “Finding a cellular target that can be inhibited so as to block HIV validates a novel concept and is an exciting model for deriving potential new HIV therapies.”

When HIV enters the body, it infects T cells and takes over the activities of these white blood cells so that the virus can replicate. Eventually, HIV infection compromises the entire immune system and causes AIDS. The new work shows that without active ITK protein, HIV cannot effectively take advantage of many signaling pathways within T cells, which in turn slows or blocks the spread of the virus.

“We were pleased and excited to realize the outcome of our approach,” Dr. Schwartzberg said. “Suppression of the ITK protein caused many of the pathways that HIV uses to be less active, thereby inhibiting or slowing HIV replication.”

In their laboratory experiments, the researchers used a chemical inhibitor and a type of genetic inhibitor, called RNA interference, to inactivate ITK in human T cells. Then, the T cells were exposed to HIV, and the researchers studied the effects of ITK inactivation upon various stages of HIV’s infection and replication cycle. Suppression of ITK reduced HIV’s ability to enter T cells and have its genetic material transcribed into new virus particles. However, ITK suppression did not interfere significantly with T cells’ normal ability to survive, and mice deficient in ITK were able to ward off other types of viral infection, although antiviral responses were delayed.

“ITK turns out to be a great target to examine,” said Dr. Schwartzberg, noting that researchers had been concerned that blocking other human proteins involved in HIV replication might kill or otherwise impair the normal functions of T cells.

According to Dr. Schwartzberg, ITK already is being investigated as a therapeutic target for asthma and other diseases that affect immune response. In people with asthma, ITK is required to activate T cells, triggering lung inflammation and production of excess mucus.

“There are several companies who have published research about ITK inhibitors as part of their target program,” Schwartzberg said. “We hope that others will extend our findings and that ITK inhibitors will be pursued as HIV therapies.”

Source: National Human Genome Research Institute

Viral recombination another way HIV fools the immune system
When individuals infected with HIV become infected with a second strain of the virus, the two viral strains can exchange genetic information, creating a third, recombinant strain of the virus. It is known that the presence of multiple viral strains, called superinfection, frequently leads to a loss of immune control of viral levels. Now a study from the Partners AIDS Research Center at Massachusetts General Hospital (PARC/MGH) shows that how and where viral strains swap DNA may be determined by the immune response against the original infecting strain. Their report will appear in the Journal of Experimental Medicine and has been released online.
HIV conquers immune system faster than previously realized
New research into the earliest events occurring immediately upon infection with HIV-I shows that the virus deals a stunning blow to the immune system earlier than was previously understood. According to scientists at Duke University Medical Center, this suggests the window of opportunity for successful intervention may be only a matter of days – not weeks – after transmission, as researchers had previously believed.
A Viral Cloaking Device: Biologists show how Human Cytomegalovirus hides from the immune system
(PhysOrg.com) -- Viruses achieve their definition of success when they can thrive without killing their host. Now, biologists Pamela Bjorkman and Zhiru Yang of the California Institute of Technology have uncovered how one such virus, prevalent in humans, evolved over time to hide from the immune system.
Genetic cause of innate resistance to HIV/AIDS
Some people may be naturally resistant to infection with HIV, the virus that causes AIDS. The results of a study conducted by Dr. Nicole Bernard of the Research Institute of the McGill University Health Centre (MUHC) bring us closer to a genetic explanation. Her study findings were published on July 16 in the journal AIDS.
Gene variant found in those with African ancestry increases odds of HIV infection
A variant of a gene found only in people of African ancestry increases the odds of becoming infected with the human immunodeficiency virus (HIV-1) by 40 percent, according to a long-term study of African Americans reported in the [date] issue of the journal Cell Host & Microbe, a publication of Cell Press. However, once people are infected, the same variant seems to protect against progression of the disease, allowing those who carry it to live about two years longer.
Genetic variation increases HIV risk in Africans
A genetic variation which evolved to protect people of African descent against malaria has now been shown to increase their susceptibility to HIV infection by up to 40 per cent, according to new research. Conversely, the same variation also appears to prolong survival of those infected with HIV by approximately two years.
UT pathologists believe they have pinpointed Achilles heel of HIV
Human Immunodeficiency Virus (HIV) researchers at The University of Texas Medical School at Houston believe they have uncovered the Achilles heel in the armor of the virus that continues to kill millions.
Scientists identify mechanism behind mind-body connection
Every cell contains a tiny clock called a telomere, which shortens each time the cell divides. Short telomeres are linked to a range of human diseases, including HIV, osteoporosis, heart disease and aging. Previous studies show that an enzyme within the cell, called telomerase, keeps immune cells young by preserving their telomere length and ability to continue dividing.

Research findings open new front in fight against AIDS virus

Related stories:

News discussion: