Showing posts with label Rapamycin. Show all posts
Showing posts with label Rapamycin. Show all posts

Saturday, May 31, 2014

Combination of metformin and rapamycin shows potential in treating aging and related diseases

A proven approach to slow the aging process is dietary restriction, but new research in the Linus Pauling Institute at Oregon State University helps explain the action of a drug that appears to mimic that process - rapamycin.

Rapamycin, an antibiotic and immunosuppressant approved for use about 15 years ago, has drawn extensive interest for its apparent ability - at least in laboratory animal tests - to emulate the ability of dietary restriction in helping animals to live both longer and healthier.

However, this medication has some drawbacks, including an increase in insulin resistance that could set the stage for diabetes. The new findings, published in the Journals of Gerontology: Biological Sciences, help to explain why that happens, and what could be done to address it.
They suggest that a combination of rapamycin and another drug to offset that increase in insulin resistance might provide the benefits of this medication without the unwanted side effect.

"This could be an important advance if it helps us find a way to gain the apparent benefits of rapamycin without increasing insulin resistance," said Viviana Perez, an assistant professor in the Department of Biochemistry and Biophysics in the OSU College of Science.

"It could provide a way not only to increase lifespan but to address some age-related diseases and improve general health," Perez said. "We might find a way for people not only to live longer, but to live better and with a higher quality of life."

Age-related diseases include many of the degenerative diseases that affect billions of people around the world and are among the leading causes of death: cardiovascular disease, diabetes, Alzheimer's disease and cancer.

Monday, May 26, 2014

Research explains action of drug that may slow aging, related disease

Rapamycin, an antibiotic and immunosuppressant approved for use about 15 years ago, has drawn extensive interest for its apparent ability at least in laboratory animal tests -- to emulate the ability of dietary restriction in helping animals to live both longer and healthier.

However, this medication has some drawbacks, including an increase in insulin resistance that could set the stage for diabetes. The new findings, published in the Journals of Gerontology: Biological Sciences, help to explain why that happens, and what could be done to address it. They suggest that a combination of rapamycin and another drug to offset that increase in insulin resistance might provide the benefits of this medication without the unwanted side effect.

"This could be an important advance if it helps us find a way to gain the apparent benefits of rapamycin without increasing insulin resistance," said Viviana Perez, an assistant professor in the Department of Biochemistry and Biophysics in the OSU College of Science.

"It could provide a way not only to increase lifespan but to address some age-related diseases and improve general health," Perez said. "We might find a way for people not only to live longer, but to live better and with a higher quality of life."

Age-related diseases include many of the degenerative diseases that affect billions of people around the world and are among the leading causes of death: cardiovascular disease, diabetes, Alzheimer's disease and cancer. Laboratory mice that have received rapamycin have reduced the age-dependent decline in spontaneous activity, demonstrated more fitness, improved cognition and cardiovascular health, had less cancer and lived substantially longer than mice fed a normal diet.

Rapamycin, first discovered from the soils of Easter Island, or Rapa Nui in the South Pacific Ocean, is primarily used as an immunosuppressant to prevent rejection of organs and tissues. In recent years it was also observed that it can function as a metabolic "signaler" that inhibits a biological pathway found in almost all higher life forms --     the  ability to  sense when  food  has
been eaten, energy is available and it's okay for cell proliferation, protein synthesis and growth to proceed.

Called mTOR in mammals, for the term "mammalian target of rapamycin," this pathway has a critical evolutionary value -- it helps an organism avoid too much cellular expansion and growth when energy supplies are insufficient. That helps explain why some form of the pathway has been conserved across such a multitude of species, from yeast to fish to humans.

"Dietary restriction is one of the few interventions that inhibits this mTOR pathway," Perez said. "And a restricted diet in laboratory animals has been shown to increase their lifespan about 25-30 percent. Human groups who eat fewer calories, such as some Asian cultures, also live longer."
Aside from a food intake in laboratory mice that's about 40 percent fewer calories than normal, however, it's been found that another way to activate this pathway is with rapamycin, which appears to have a significant impact even when used late in life. Some human clinical trials are already underway exploring this potential.

A big drawback to long-term use of rapamycin, however, is the increase in insulin resistance, observed in both humans and laboratory animals. The new research identified why that is happening. It found that both dietary restriction and rapamycin inhibited lipid synthesis, but only dietary restriction increased the oxidation of those lipids in order to produce energy.

Rapamycin, by contrast, allowed a buildup of fatty acids and eventually an increase in insulin resistance, which in humans can lead to diabetes. However, the drug metformin can address that concern, and is already given to some diabetic patients to increase lipid oxidation. In lab tests, the combined use of rapamycin and metformin prevented the unwanted side effect.

"If proven true, then combined use of metformin and rapamycin for treating aging and age-associated diseases in humans may be possible," the researchers wrote in their conclusion.

This work was supported by the National Institutes of Health. Collaborators included researchers from Oklahoma University Health Science Center, the Oklahoma City VA Medical Center, University of Michigan-Flint, and South Texas Veterans Health Care System.

"There's still substantial work to do, and it may not be realistic to expect with humans what we have been able to accomplish with laboratory animals," Perez said. "People don't live in a cage and eat only the exact diet they are given. 

Nonetheless, the potential of this work is exciting."





























































Friday, August 16, 2013

Rapamycin: Limited anti-aging effects

In continuation of my update on Rapamycin

The drug rapamycin is known to increase lifespan in mice. Whether rapamycin slows down aging, however, remains unclear. A team of researchers from the German Center for Neurodegenerative Diseases (DZNE) and the Helmholtz Zentrum München has now found that rapamycin extends lifespan -- but its impact on aging itself is limited. The life-extending effect seems to be related to rapamycin's suppression of tumors, which represent the main causes of death in these mouse strains....


Tuesday, August 6, 2013

Compounds outsmart solid tumors' malfunctioning machinery


In continuation of my update on Rapamycin

"Allosteric regulators are better than proteasome-affecting agents used in clinics because they do not induce classical drug resistance," Dr. Gaczynska said. "They bind to sites on the proteasome molecule used by natural regulatory proteins. They are more specific and are not restricted to proteasome inhibition but can activate the proteasome under certain conditions."

The new strategy was serendipitously found during experiments with rapamycin, a drug that in a highly publicized study by the UT Health Science Center's Barshop Institute for Longevity and Aging Studies was found to extend life span in mice.

Potential
The Molecular Pharmacology report and follow-up studies describe the unexpected and highly desired effects that rapamycin and similar compounds elicit on the proteasome. Based on these studies, it would be possible to design a new line of proteasome regulators with anti-cancer properties, Drs. Osmulski and Gaczynska said.... 

Tuesday, November 20, 2012

Drug trio of rapamycin, sildenafil and doxorubicin improved effectiveness of cancer treatment, protected heart


Combining cancer medication with a drug for erectile dysfunction and one for heart transplants helped kill cancer cells and protected the heart from damage. For decades, doxorubicin has been a powerful anti-cancer treatment for various human cancers, including breast, ovarian, colon and prostate. But its use has been limited due to harmful, possibly irreversible effects on the heart.

In this study, using cell and animal models, researchers found that sildenafil alone or in combination with rapamycin (an immunosuppressant used to prevent post-transplant organ rejection) significantly improved the anti-cancer effects of doxorubicin while protecting the heart. The combination of all three medications showed the most powerful effect, researchers said.

"Because sildenafil and rapamycin are clinically approved drugs that both protect heart muscle, we thought that combining these drugs with doxorubicin would be a unique strategy to eliminate the cardiac side effects of doxorubicin while further improving its cancer-killing ability," said Rakesh Kukreja, Ph.D., study co-author and professor of internal medicine and cardiology, Virginia Commonwealth University (VCU) School of Medicine in Richmond.

"The drug combination led to a dramatic protection of heart muscle from apoptosis (cellular self-destruction) and, to a lesser extent, necrosis (cell death from disease)," said David E. Durrant, study lead author and Ph.D. candidate at the VCU School of Medicine. "We think this combination therapy may have excellent potential to move forward into clinical trials and eventually improve life expectancy of cancer patients."



Sunday, January 31, 2010

Rapamycin as a potential treatment for kidney disease (ADPKD).........

I did  mention about the use of Rapamycin (see structure)  to improve the  efficacy of tuberculosis vaccine in my earlier blog. This drug has been already  used as an immunosuppressant drug to prevent rejection in organ transplantation,  especially useful in kidney transplants.

 Rapamycin, was originally developed as an antifungal agent. However, this was abandoned when it was discovered that it had potent immunosuppressive and antiproliferative properties. Some researchers have  also reported that  the drug prolong the life of mice and might also be useful in the treatment of certain cancers.

Researchers from UC Santa Barbara  earlier claimed that, rapamycin has  a potential to treat  kidney disease,  however  concluded  that the  mice had different genes affected than human patients. Interestingly, the same researchers recently found that  "rapamycin is also highly effective in a new mouse model in which the same gene is affected as in most human patients".

As claimed by the lead researcher, Thomas Weimbs currently, no treatment exists to prevent or slow cyst formation and most ADPKD patients require kidney transplants or lifelong dialysis for survival. I think this will boost the confidence of the several international groups,  who are undertaking the  clinical trials  to test the safety and efficacy of rapamycin and related drugs in polycystic kidney disease. Though the  researchers are hopeful of positive results  they caution that,  it will be critical to balance any benefits against the expected side effects to judge whether these drugs should be recommended for the treatment of polycystic kidney disease. Let us be optimistic.....

Ref : http://www.ia.ucsb.edu/pa/display.aspx?pkey=2164

Thursday, March 12, 2009

Improved efficacy of tuberculosis vaccine ?

We know that BCG (Bacille Calmette-Guérin) is a live but weakened form of a bacterium, M. bovis, which causes tuberculosis in cattle. It is sufficiently related to the human pathogen to stimulate production of specialized immune cells that fight off TB infection when it is injected into a person as a vaccine. The bacilli have retained enough strong antigenicity to become a somewhat effective vaccine for the prevention of human tuberculosis. At best, the BCG vaccine is 80% effective in preventing tuberculosis for a duration of 15 years, however, its protective effect appears to vary according to geography.


Many attempts have been made to improve the vaccine by incorporating antigens (molecular components of the bacteria) to induce a stronger immune response. However, tuberculosis and BCG have evasive mechanisms that prevent the development of stronger immune responses. We read oftenly in news paper, about the drug resistant strains and use of combined drugs. Now thanx to the two research groups from UT Health Science Center at Houston. The importance of this research is in the fact that the two groups investigated mechanisms by which BCG evades immune stimulating mechanisms and devised two means to neutralize them.

1. scientists used genetically-modified organisms and
2. a drug used for organ transplantation (Rapamycin, see the structure)to block BCG's evasive mechanisms, causing it to induce stronger immune responses.

This dual approach to the BCG vaccine was associated with a tenfold increase in the number of TB organisms killed and a threefold increase in the duration of protection in tests with an NIH-approved mouse model, Dr. Jagannath said.

The research is of great importance because of the fact that "it has countered the ability of TB organisms to subvert immunization", (Tuberculosis hides in cells so the antigens are not recognized by the immune system. The BCG vaccine also does the same thing). The role of the drug is of great importance, i.e., it modulates the movement of particles in cells, would cause BCG antigens to enter pathways leading to improved immunization. I would say one more significant contribution(or else one more serendipity !) of the drug apart from bieng used in 1. treatment of cancer and inflammation 2. in significantly reducing the frequency of acute kidney transplant rejection.

Though further research to substantiate the claim is essential. Its a good beginning in this direction for the improved efficay of the vaccine.. Congrats Dr. Jagannath and group.. More...