Mouse With Human-Like Immune System Could Advance AIDS Research

HealthDay – Thu, Jul 19, 2012 WEDNESDAY, July 18 (HealthDay News) -- Scientists who created mice with elements of the human immune system believe the rodents will further efforts to develop a vaccine against HIV, the virus that causes AIDS.

One of the challenges facing researchers striving to develop an HIV vaccine has been the lack of a laboratory animals that accurately reflect the human response to HIV and how the virus evolves to avoid that response.

The U.S. team of scientists transplanted human bone marrow cells and other human tissue into mice without a functioning immune system. This gave the mice aspects of the human immune system.

"Our study showed not only that these humanized mice mount human immune responses against HIV but also that the ability of HIV to evade these responses by mutating viral proteins targeted by CD8 'killer' T-cells is accurately reflected in these mice," study senior author Todd Allen, an associate professor medicine at the Ragon Institute of Massachusetts General Hospital, MIT and Harvard, explained in a MGH news release.

T-cells are immune cells that protect the body from infection.

The mice might significantly reduce the time and costs required to test experimental HIV vaccines, according to the researchers.

The study was published in the July 18 issue of the journal Science Translational Medicine.

More information

The New Mexico AIDS Education and Training Center has more about HIV/AIDS vaccines.

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Human Breast Milk May Block HIV, Mouse Study Finds

HealthDay – Thu, Jun 14, 2012 THURSDAY, June 14 (HealthDay News) -- Human breast milk seems to kill HIV and block its oral (through the mouth) transmission, according to a new study conducted in mice.

The findings suggest that it may be possible to isolate the compounds in breast milk that destroy HIV and use these to combat the virus that causes AIDS, the University of North Carolina (UNC) School of Medicine researchers said.

More than 15 percent of new HIV infections occur among children. Left untreated, only 65 percent of infected babies survive until their first birthday, and less than 50 percent reach the age of 2, the study authors pointed out in a news release from the University of North Carolina Health Care.

While breast-feeding by HIV-infected mothers is believed to cause a large number of HIV infections in infants, most breast-fed infants do not become infected, despite prolonged and repeated exposure to the virus, researchers have found.

In order to investigate this contradiction, the UNC researchers used humanized mice, which have a fully functioning human immune system and can be infected with HIV in the same manner as humans.

The mice did not become infected when given HIV in whole breast milk from women without HIV, according to the report published June 14 in the online journal PLoS Pathogens.

"This study provides significant insight into the amazing ability of breast milk to destroy HIV and prevent its transmission," senior author J. Victor Garcia, a professor of medicine in the UNC Center for Infectious Diseases and the UNC Center for AIDS Research, said in the news release.

The research could lead to new ways to prevent HIV transmission, the study authors suggested.

"No child should ever be infected with HIV because it is breast-fed. Breast-feeding provides critical nutrition and protection from other infections, especially where clean water for infant formula is scarce," Garcia said. "Understanding how HIV is transmitted to infants and children despite the protective effects of milk will help us close this important door to the spread of AIDS."

It is important to note that research conducted on animals does not necessarily produce the same results in humans.

More information

The New Mexico AIDS Education and Training Center has more about pregnancy and HIV/AIDS.

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Mouse Study Suggests Certain Fats Could Trigger Crohn's, Colitis

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Belly 'Membrane' May Regulate Immune System, Mouse Study Finds

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Mouse Study Sheds Light on How Diet May Affect Epilepsy

HealthDay – 32 mins ago WEDNESDAY, May 23 (HealthDay News) -- It's long been known that a high-fat, low-carbohydrate diet can reduce epileptic seizures that resist drug therapy, and now researchers studying mice say they think they know why.

The results of their research in mice suggest that resistance to seizures among people who eat what's called a ketogenic diet is linked to a protein that modifies cellular metabolism in the brain.

The findings, reported in the May 24 issue of the journal Neuron, may lead to the development of new treatments for epilepsy, according to the researchers at Dana-Farber Cancer Institute and Harvard Medical School in Boston.

"The connection between metabolism and epilepsy has been such a puzzle," study co-leader Gary Yellen, a professor of neurobiology at Harvard Medical School, said in a Harvard news release. "I've met a lot of kids whose lives are completely changed by this diet. It's amazingly effective, and it works for many kids for whom drugs don't work."

In tests with mice, the researchers found that modifying the BCL-2-associated agonist of cell death protein led to altered brain metabolism and protected against seizures.

"Diet sounds like this wholesome way to treat seizures, but it's very hard. I mean, diets in general are hard, and this diet is really hard," Yellen said. "So finding a pharmacological substitute for this would make lots of people really happy."

While the findings hold promise, experts note that research involving animals frequently fails to lead to benefits for humans.

More information

The Epilepsy Foundation has more about the ketogenic diet.

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Mouse Study Hints at New Path for Diabetes Treatment

HealthDay – 43 mins ago THURSDAY, April 12 (HealthDay News) -- A potential new treatment for type 2 diabetes targets the hormone glucagon instead of insulin, according to a new study in mice.

Although the research hasn't yet progressed past animal models of the disease, initial results suggest that the novel therapy can lower blood sugar, decrease insulin resistance, lower cholesterol and help keep fatty deposits from settling in the liver.

What's more, the researchers didn't see any adverse effects from the treatment.

"A new target for the adverse effects of glucagon on diabetes has been identified, and with treatment we got rid of all the bad stuff, but didn't cause side effects," said the study's lead author, Dr. Ira Tabas, a distinguished professor of medicine at Columbia University Medical Center, in New York City.

Results of the study are published in the April 12 online edition of Cell Metabolism.

Glucagon is a hormone whose main role is to protect the body and brain from low blood-sugar levels during periods of fasting, such as overnight. It is produced by the alpha cells in the pancreas, Tabas said. When the alpha cells in the pancreas sense dropping blood sugar and insulin levels, they secrete glucagon, which in turn, causes the liver to produce glucose to feed the brain and body.

Normally, glucagon only kicks in when you're starving, because it senses low insulin levels. But, in type 2 diabetes, the body becomes resistant to insulin, so even though insulin is present, the liver thinks the body has no glucose because the insulin isn't helping get glucose into the body's cells the way it should, Tabas explained. That causes the liver to send out a signal for glucagon, and then the liver releases more sugar. "It just turns into a horrible feedback cycle," he said.

Commenting on the study, Dr. Vivian Fonseca, president of medicine and science at the American Diabetes Association, explained that "when you eat a meal and your sugar goes up, glucagon and glucose should switch off, but that doesn't happen in type 2 diabetes."

Currently, type 2 diabetes treatments focus on replacing insulin or making insulin work more effectively (known as improving insulin sensitivity). But, finding a way to block some of the action of glucagon might also help control type 2 diabetes.

The problem is that because glucagon serves a vital function in keeping the brain and body nourished with glucose in times of fasting, scientists can't make a drug that completely suppresses the action of glucagon.

In addition to the brain not getting enough sugar, early research that just partially blocked glucagon caused weight gain, fatty liver deposits and increased cholesterol. Tabas said it's still not entirely clear why partially blocking glucagon caused these effects.

Clearly, a different approach was needed. So, rather than trying to block glucagon, Tabas and his colleagues followed glucagon's pathways.

"Imagine if you have five pathways: A, B, C, D and E. Blocking pathways A and B can stop diabetes. But, if you block C, D, and E, you cause bad effects. So, you have to move further downstream to find the molecules that are responsible for pathways A and B so you can block those without blocking C, D, and E," Tabas explained.

"The more specific you can get, the less likely you'll have adverse effects," he added.

The pathway they found is an enzyme called CaMKII, and Tabas said this particular pathway is also being studied in inflammatory diseases, such as arthritis and asthma, because inhibiting this enzyme seems to lower inflammation as well.

When the researchers blocked CaMKII in obese mice bred to have diabetes, their blood sugar went down, insulin sensitivity improved, cholesterol decreased and fatty liver improved. And, there was no evidence of adverse effects from blocking CaMKII.

"There's always a concern whenever you inhibit any molecule in the body. We need to know why it's there naturally and what could be the possible effects of inhibiting it. Our study showed no specific concerns though," Tabas said.

While the findings of the new study are promising, scientists note that research involving animals often fails to produce similar results in humans.

For her part, Fonseca said, "This is an interesting and exciting scientific finding on how glucagon works, and it provides a new treatment target. But, it's in the very early stages of research."

More information

Learn more about currently available treatments for type 2 diabetes from the American Diabetes Association.

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