 |
|
Secrets to antibody's success against West Nile Virus surprise scientists
September 29, 2005A monoclonal antibody that can effectively treat mice infected with West Nile virus has an intriguing secret: Contrary to scientists' expectations, it does not block the virus's ability to attach to host cells. Instead, the antibody somehow stops the infectious process at a later point.
"This was a complete surprise to us, but it gives us some very useful insights," says senior author Daved Fremont, Ph.D., associate professor of pathology & immunology and of biochemistry & molecular biophysics at Washington University School of Medicine in St. Louis. "Based on what we've learned, we are now developing therapeutic antibodies for related viruses that also are effective at stopping the process of infection after the virus attaches to host cells."
Detailed study of how the antibody physically binds to the virus has provided intriguing clues to how it may block infection. Scientists found evidence suggesting that the antibody prevents the virus from rearranging the protein envelope that surrounds its genetic material after it enters a host cell.
To reproduce, a virus must alter its envelope in order to inject its genetic material inside the cell. After that injection, the virus tricks the host cell into making more copies of the genetic material that can then be assembled into new viral particles or virions and sent out to infect other host cells and reproduce. But with the viral reproduction process blocked by the antibody, scientists suspect that the host cell eventually destroys the virion.
Fremont and colleagues, who publish their results in the Sept. 29 issue of Nature, hope to design a new diagnostic system that can determine whether vaccines for West Nile and related viruses undergoing clinical trials stimulate production of antibodies that stop infections at a similar point.
In 2004, West Nile virus, which is a mosquito-borne flavivirus, reportedly caused 2,470 infections and 88 deaths in the United States. First isolated in Africa in 1937, West Nile spread to the Middle East, Europe, and Asia before arriving in the United States in 1999. Most infections with the virus are mild or symptom-free, but infections in people with weakened immune systems and those over 50 sometimes lead to serious complications or death.
Like West Nile, dengue virus is a flavivirus spread by mosquito bites, but only in tropical regions of the world. The dengue virus is estimated by Centers for Disease Control and Prevention epidemiologists to cause100 million infections annually worldwide.
"Currently there are no effective and safe vaccines for pediatric dengue," says co-author Michael Diamond, M.D., Ph.D., assistant professor of molecular microbiology, of pathology & immunology and of medicine. "Thanks to our data from the West Nile virus antibody, we believe we now have a much better idea of how to evaluate vaccines for dengue."
Fremont and Diamond led a team of researchers at Washington University and Macrogenics Inc., a private company, that announced the identification of the effective West Nile antibody earlier this year. In a line of mice genetically altered to increase vulnerability to the virus, they found injection of the new antibodies could boost survival rates of mice infected with the virus to greater than 90 percent.
Scientists at Macrogenics are working on the preliminary studies required before the West Nile antibody can be tested in humans. Meanwhile, researchers at Washington University wanted to know why the new antibody was so effective.
Antibodies normally work by binding to invaders to flag them for consumption and destruction by immune system cells known as macrophages. In the prior study, which screened several potential West Nile antibodies, scientists found that all the most potent antibodies bound to a particular section of a protein that makes up the exterior of the viral envelope. The envelope of a single viral particle or virion is comprised of 180 copies of this protein.
For the new study, scientists determined the detailed structure of a single antibody bound to its envelope protein target region using the technique of protein crystallography. Scientists were able to affirm in greater detail earlier observations suggesting that the antibody will be therapeutic for all strains of West Nile Virus.
Based on this data, they predicted how multiple copies of the successful antibody would bind to a virion.
"We were startled to find that the antibody only seemed to be able to attach to 120 of the 180 copies of the target region in the complete viral envelope," says Grant Nybakken, a Washington University M.D./Ph.D. student who was lead author of the study.
Further tests showed that virions covered in infection-stopping antibodies could still bind to host cells, while antibodies that were less effective at stopping infection could more effectively prevent the virion from binding to host cells.
How does an antibody that's better at preventing the virus from binding to host cells actually turn out to be worse at treating infection? The key may lie in a theory known as antibody-dependent enhancement (ADE) of infection, which has been observed in test tube studies of dengue virus and may be important to the onset of dengue hemorrhagic fever.
This theory suggests that dengue and other viruses may have developed tricks that let them reproduce inside macrophages, the immune cells that normally consume and destroy any object that they find covered in antibodies. In effect, these tricks turn antibodies that should be death warrants into passes into cells where invaders can reproduce.
Fremont cautions that this phenomenon has not been seen in West Nile virus, but notes that when he and his colleagues tested the ability of several antibodies to prevent West Nile from reproducing inside macrophages, they found that only the therapeutic antibodies blocked the virus' reproduction. The therapeutic antibodies' ability to stop reproduction in macrophages even worked when the virions were simultaneously exposed to antibodies known to enhance infection.
"Do the therapeutic antibodies also prevent the virus from properly injecting its genetic material into macrophages? It's a tempting possibility, but we don't have the evidence to prove it yet," he says.
Washington University School of Medicine
To reproduce, a virus must alter its envelope in order to inject its genetic material inside the cell. After that injection, the virus tricks the host cell into making more copies of the genetic material that can then be assembled into new viral particles or virions and sent out to infect other host cells and reproduce. But with the viral reproduction process blocked by the antibody, scientists suspect that the host cell eventually destroys the virion.
Fremont and colleagues, who publish their results in the Sept. 29 issue of Nature, hope to design a new diagnostic system that can determine whether vaccines for West Nile and related viruses undergoing clinical trials stimulate production of antibodies that stop infections at a similar point.
In 2004, West Nile virus, which is a mosquito-borne flavivirus, reportedly caused 2,470 infections and 88 deaths in the United States. First isolated in Africa in 1937, West Nile spread to the Middle East, Europe, and Asia before arriving in the United States in 1999. Most infections with the virus are mild or symptom-free, but infections in people with weakened immune systems and those over 50 sometimes lead to serious complications or death.
Like West Nile, dengue virus is a flavivirus spread by mosquito bites, but only in tropical regions of the world. The dengue virus is estimated by Centers for Disease Control and Prevention epidemiologists to cause100 million infections annually worldwide.
"Currently there are no effective and safe vaccines for pediatric dengue," says co-author Michael Diamond, M.D., Ph.D., assistant professor of molecular microbiology, of pathology & immunology and of medicine. "Thanks to our data from the West Nile virus antibody, we believe we now have a much better idea of how to evaluate vaccines for dengue."
Fremont and Diamond led a team of researchers at Washington University and Macrogenics Inc., a private company, that announced the identification of the effective West Nile antibody earlier this year. In a line of mice genetically altered to increase vulnerability to the virus, they found injection of the new antibodies could boost survival rates of mice infected with the virus to greater than 90 percent.
Scientists at Macrogenics are working on the preliminary studies required before the West Nile antibody can be tested in humans. Meanwhile, researchers at Washington University wanted to know why the new antibody was so effective.
Antibodies normally work by binding to invaders to flag them for consumption and destruction by immune system cells known as macrophages. In the prior study, which screened several potential West Nile antibodies, scientists found that all the most potent antibodies bound to a particular section of a protein that makes up the exterior of the viral envelope. The envelope of a single viral particle or virion is comprised of 180 copies of this protein.
For the new study, scientists determined the detailed structure of a single antibody bound to its envelope protein target region using the technique of protein crystallography. Scientists were able to affirm in greater detail earlier observations suggesting that the antibody will be therapeutic for all strains of West Nile Virus.
Based on this data, they predicted how multiple copies of the successful antibody would bind to a virion.
"We were startled to find that the antibody only seemed to be able to attach to 120 of the 180 copies of the target region in the complete viral envelope," says Grant Nybakken, a Washington University M.D./Ph.D. student who was lead author of the study.
Further tests showed that virions covered in infection-stopping antibodies could still bind to host cells, while antibodies that were less effective at stopping infection could more effectively prevent the virion from binding to host cells.
How does an antibody that's better at preventing the virus from binding to host cells actually turn out to be worse at treating infection? The key may lie in a theory known as antibody-dependent enhancement (ADE) of infection, which has been observed in test tube studies of dengue virus and may be important to the onset of dengue hemorrhagic fever.
This theory suggests that dengue and other viruses may have developed tricks that let them reproduce inside macrophages, the immune cells that normally consume and destroy any object that they find covered in antibodies. In effect, these tricks turn antibodies that should be death warrants into passes into cells where invaders can reproduce.
Fremont cautions that this phenomenon has not been seen in West Nile virus, but notes that when he and his colleagues tested the ability of several antibodies to prevent West Nile from reproducing inside macrophages, they found that only the therapeutic antibodies blocked the virus' reproduction. The therapeutic antibodies' ability to stop reproduction in macrophages even worked when the virions were simultaneously exposed to antibodies known to enhance infection.
"Do the therapeutic antibodies also prevent the virus from properly injecting its genetic material into macrophages? It's a tempting possibility, but we don't have the evidence to prove it yet," he says.
Washington University School of Medicine
West Nile Virus News and Current West Nile Virus Events RSSNew and improved test for West Nile virus in horses
A new test for West Nile virus in horses that could be modified for use on humans and wildlife may help track the spread of the disease, according to an article in the September issue of the Journal of Medical Microbiology.
Groundbreaking research shows DEET's not sweet to mosquitoes
Spray yourself with a DEET-based insect repellent and the mosquitoes will leave you alone. But why? They flee because of their intense dislike for the smell of the chemical repellent and not because DEET jams their sense of smell, report researchers at the University of California, Davis.
Plastics suspect in lobster illness
The search for what causes a debilitating shell disease affecting lobsters from Long Island Sound to Maine has led one Marine Biological Laboratory (MBL) visiting scientist to suspect environmental alkyphenols, formed primarily by the breakdown of hard transparent plastics.
Diversity among bird populations found to reduce threat of West Nile virus
A biologist and undergraduate student have discovered that what's good for an area's bird population is also good for people living nearby.
New West Nile and Japanese encephalitis vaccines produced
University of Texas Medical Branch at Galveston researchers have developed new vaccines to protect against West Nile and Japanese encephalitis viruses. The investigators created the vaccines using an innovative technique that they believe could also enable the development of new vaccines against other diseases, such as yellow fever and dengue fever, which are caused by similar viruses.
Geneticists at the American Museum of Natural History trace the evolution of St. Louis encephalitis
Before West Nile virus arrived in this country, we had (and still have) a home-grown relative of this pathogen. An epidemic of unknown origin exploded around St. Louis, Missouri in the autumn of 1933, a disease that is now known to be transmitted by mosquitoes from birds to people.
Emerging infectious diseases on the rise: Next target 'hotspot' predicted
It's not just your imagination. Providing the first-ever definitive proof, a team of scientists has shown that emerging infectious diseases such as HIV, Severe Acute Respiratory Syndrome (SARS), West Nile virus and Ebola are indeed on the rise.
Scientists confirm new virus responsible for deaths of transplant recipients in Australia
In the first application of high throughput DNA sequencing technology to investigate an infectious disease outbreak, scientists from Columbia University Mailman School of Public Health, the Victorian Infectious Diseases Reference Laboratory (VIRDL) in Melbourne, Australia, the Centers for Disease Control and 454 Life Sciences link the discovery of a new arenavirus to the deaths of three transplant recipients who received organs from a single donor in Victoria, Australia in April 2007.
Scientists confirm new virus responsible for deaths of transplant recipients in Australia
In the first application of high throughput DNA sequencing technology to investigate an infectious disease outbreak, scientists from Columbia University Mailman School of Public Health, the Victorian Infectious Diseases Reference Laboratory (VIRDL) in Melbourne, Australia, the Centers for Disease Control and 454 Life Sciences link the discovery of a new arenavirus to the deaths of three transplant recipients who received organs from a single donor in Victoria, Australia in April 2007.
Researchers put the bite on mosquitoes
Few things sting like a mosquito's bite--especially if that bite carries a disease such as malaria, yellow fever, Dengue fever or West Nile virus. But if researchers from The University of Arizona in Tucson have their way, one day mosquito bites may prove deadly to the mosquitoes as well.
More West Nile Virus News Articles
 | West Nile Virus (Deadly Diseases and Epidemics) by Jeffrey N. Sfakianos |
 | Crow Medicine (Jane Ray's Wildlife Rescue Series) by Diane Haynes In the exciting Jane Ray's Wildlife Rescue series, reluctant heroine Jane Ray comes face to face with the challenges and rewards of wildlife rescue and rehabilitation. Packed with fascinating facts and interactive resources, including volunteer opportunities and animal rescue tips, the series is sure to delight animal lovers everywhere. Crow Medicine opens under the impending threat of West... |
 | Human Antibody Therapeutics For Viral Disease (Current Topics in Microbiology and Immunology) Although the utility of human antibodies as medical therapeutics for cancer and immune diseases has been well-established, it is only beginning to be realized for the treatment of viral infectious diseases. Polyclonal immunoglobulins have long been used for some viral diseases, but they have limited potency and disease scope. It should theoretically be possible to create monoclonal or oligoclonal... |
 | West Nile Story by Dickson Despommier West Nile Story describes the outbreaks of the West Nile virus that occurred in and around New York City in 1999 and again in 2000. It contains an additional chapter to the soft cover edition, "We Paved Paradise." West Nile Story is intended for a mature general audience (age 15 and up). Both the soft cover and hard cover versions have received high praise from reviewers and readers,... |
 | Viral Fitness: The Next SARS and West Nile in the Making by Jaap Goudsmit Despite vaccines and medicines, we have not succeeded in eradicating the most poisonous viruses in the world, like jaundice, measles, diarrhea, polio, and AIDS, not to mention newcomers like West Nile and SARS. Also, since September 11, it is no longer unthinkable that a terrorist would intentionally spread a virus among people or the food chain. In this book, Jaap Goudsmit argues that there is... |
| Only one surefire way to avoid West Nile virus: Avoid mosquito bites.(General News): An article from: The Register-Guard (Eugene, OR) This digital document is an article from The Register-Guard (Eugene, OR), published by The Register Guard on April 21, 2003. The length of the article is 721 words. The page length shown above is based on a typical 300-word page. The article is delivered in HTML format and is available in your Amazon.com Digital Locker immediately after purchase. You can view it with any web browser.Citation... | |
| Gen-Probe nucleic acid test for West Nile Virus now available.: An article from: BIOTECH Patent News This digital document is an article from BIOTECH Patent News, published by Biotech Patent News on June 1, 2003. The length of the article is 543 words. The page length shown above is based on a typical 300-word page. The article is delivered in HTML format and is available in your Amazon.com Digital Locker immediately after purchase. You can view it with any web browser.Citation DetailsTitle:... | |
| Unexplained fever in transplant recipients may be West Nile virus.: An article from: Transplant News This digital document is an article from Transplant News, published by Transplant Communications, Inc. on May 30, 2004. The length of the article is 366 words. The page length shown above is based on a typical 300-word page. The article is delivered in HTML format and is available in your Amazon.com Digital Locker immediately after purchase. You can view it with any web browser.Citation... | |
| West Nile virus effects may linger: neurologic manifestations.(News): An article from: Internal Medicine News by Betsy Bates This digital document is an article from Internal Medicine News, published by International Medical News Group on September 1, 2003. The length of the article is 882 words. The page length shown above is based on a typical 300-word page. The article is delivered in HTML format and is available in your Amazon.com Digital Locker immediately after purchase. You can view it with any web... | |
| Just for fun.(West Nile Virus spraying): An article from: Synthesis/Regeneration by Don Fitz This digital document is an article from Synthesis/Regeneration, published by WD Press on March 22, 2003. The length of the article is 554 words. The page length shown above is based on a typical 300-word page. The article is delivered in HTML format and is available in your Amazon.com Digital Locker immediately after purchase. You can view it with any web browser.Citation DetailsTitle: Just for... |
| © 2008 BrightSurf.com |