Researchers learn why immune system's watch dogs howl

Toll-like receptors are the guard dogs of the immune system, sniffing out bacteria and viruses then activating the body’s immune system for an attack on these invaders.

Because of their ability to quickly activate the body’s defenses, toll-like receptors have recently become a darling of drug makers. One of the proteins in this class, toll-like receptor 9 or TLR9, can pick up a very specific scent – a snippet of DNA common in bacteria and viruses.

The idea for drug makers is to create DNA-based drugs containing these snippets, called CpG DNA. The drugs would get the guard dogs howling, which, in turn, would trip a fast immune response, causing the body to attack cancerous tumors or, if used as an ingredient in vaccines, bolster the assault on infectious diseases such as hepatitis B and C. CpG DNA could even be used to treat immune system disorders such as asthma and allergies.

To make these pills or vaccines, however, it would be helpful to know what gets the guard dogs howling. New research led by Brown University immunologist Wen-Ming Chu, M.D., has uncovered one of these molecular mechanisms – high-mobility group box 1 protein, or HMGB1, a protein released when infection occurs, when cells are damaged or when tissue is injured.

Chu and his team found a direct interaction between HMGB1 and TLR9. When the invader’s DNA is present, researchers found that TLR9 meets up with HMGB1. The combination occurs inside tiny cellular cargo boxes, with a long name: endoplasmic reticulum-Golgi intermediate compartments or ERGIC. In these boxes, researchers found, the proteins bind to form a complex. Formation of this complex sets off a biochemical cascade that triggers the body’s immune response.

When HMGB1 is absent from cells, researchers found, the body’s immune response is significantly delayed.

“We found out that HMGB1 acts an accelerator, quickly activating the body’s defenses,” Chu said. “What’s exciting is that drug makers might be able to use this knowledge to treat disease. CpG DNA and HMGB1 could be used together in a vaccine.”

Source: Brown University

Related stories:

In the laboratory, green tea proves a powerful medicine against severe sepsis
A major component of green tea could prove the perfect elixir for severe sepsis, an abnormal immune system response to a bacterial infection.
Scientists discover how gold eases pain of arthritis
Scientists at Duke University Medical Center may have solved the mystery surrounding the healing properties of gold – a discovery they say may renew interest in gold salts as a treatment for rheumatoid arthritis and other inflammatory diseases.
Killing 'angry' immune cells in fat could fight diabetes
By killing off "angry" immune cells that take up residence in obese fat and muscle tissue, researchers have shown that they can rapidly reverse insulin resistance in obese mice. The findings reported in the October Cell Metabolism, a publication of Cell Press, suggest that treatments aimed at specific subsets of the so-called macrophage cells might offer a very effective new antidiabetic therapy, according to the researchers.
Study links 'hygiene hypothesis' to diabetes prevention
A research study funded by JDRF suggests that a common intestinal bacteria may provide some protection from developing type 1 diabetes. The findings provide an important step towards understanding how and why type 1 diabetes develops in people, and may lead to potential cures.
Form of Crohn's disease traced to disabled gut cells
Scientists report online this week in Nature that they have linked the health of specialized gut immune cells to a gene associated with Crohn's disease, an often debilitating and increasingly prevalent inflammatory bowel disorder.
Chemical 'orienteering': how accurately can cells follow a chemical trail to find their way around?
(PhysOrg.com) -- Scientists have long known that single-cell organisms find their way around by detecting chemicals in their surroundings. Now new research out this week in the Proceedings of the National Academy of Sciences (PNAS) journal has shown how accurately cells are able to do this.
DNA of good bacteria drives intestinal response to infection
A new study shows that the DNA of so-called "good bacteria" that normally live in the intestines may help defend the body against infection.
Researchers develop novel anti-tumor vaccine
A novel anti-tumor vaccine for neuroblastoma and melanoma developed by scientists and clinicians at Children's National Medical Center in collaboration with investigators from the University of Iowa is showing significant impact on tumor growth in mice, according to new research published in the October edition of the research journal Cancer Immunology, Immunotherapy. The vaccine uses the tumor's own protein to induce an immune system response, allowing for a personalized approach to treatment.

News discussion:

Medicine & Health news