Organic compound found in red wine boosts the body's ability to fight drug-resistant TB
An organic compound found in grape skins can stimulate the mouse immune system to fight even the most persistent tuberculosis strains. Such immune-based therapies, commonly used to treat cancer, could be the only hope against the spread of drug-resistant tuberculosis, says Amit Singhal, who led the study at the A*STAR Singapore Immunology Network.
Tuberculosis (TB), known in the old days as 'consumption', has
plagued mankind for centuries and killed hundred of millions of
people. Antibiotics have been the standard treatment since
penicillin became widely available in the 1940s, but the
emergence of drug-resistant strains of Mycobacterium
tuberculosis have led to a resurgence of the disease.
"TB
is making a comeback; it is now the largest killer among
communicable diseases affecting people at an age when they are
most productive," says Singhal. In 2015, an estimated 10.4
million people were infected with tuberculosis, and 1.4 million
died of the disease. "The global TB elimination program might
not meet its targets unless we come up with new therapeutic and
diagnostic strategies."
In search of alternatives, in
2014 Singhal and his team screened FDA-approved drugs for their
anti-tuberculosis activity and discovered that the common
anti-diabetic drug, metformin, targets an immune protein,
leading to reduced inflammation and lung tissue damage in
tuberculosis-infected mice. He is now collaborating with
clinicians to test metformin therapy in clinical trials.
His
search didn't end there. Several other immune proteins can be
targeted by drugs in the same way as metformin, and Singhal
wanted to test their efficacy as well. His next target was
sirtuin-1, an enzyme known to regulate metabolic function and
important in aging and inflammation. Sirtuin-1 activators are
naturally found in grape skins and red wine, and have been sold
as nutritional supplements for their anti-aging benefits.
Mouse
models in which sirtuin-1 activity was blocked had tuberculosis
spreading much more than the controls. The opposite happened
when sirtuin-1 activity was enhanced: the virulent and stubborn
tuberculosis colonies in the lungs and spleens of infected mice
began to shrink. The antibacterial effect was even more
pronounced when sirtuin-1 treatment was combined with a standard
antibiotic.
Closer examination of the lung tissue
revealed less damage and inflammation under sirtuin-1
enhancement, as compared with untreated controls. Gene
expression analysis found that the enzyme worked by inducing the
tuberculosis bacteria to devour themselves, a process known as
autophagy.
Singhal is now testing sirtuinin-1
activators on monkey models of tuberculosis. He is also looking
into whether they can be combined with metformin for a more
powerful therapy.
"We now have two candidates to
further expand our studies and we may even find something else."
Reference:
Catherine Y. Cheng et al. Host sirtuin 1 regulates mycobacterial immunopathogenesis and represents a therapeutic target against tuberculosis, Science Immunology (2017). DOI: 10.1126/sciimmunol.aaj1789
Source:
Medical Xpress
