Posted on 10/09/2017 10:52:52 AM PDT by Red Badger
This image depicts the structure of the BAX protein (purple). The activator compound BTSA1 (orange) has bound to the active site of BAX (green), changing the shape of the BAX molecule at several points (shown in yellow, magenta and cyan). BAX, once in its final activated form, can home in on mitochondria and puncture their outer membranes, triggering apoptosis (cell death). Credit: Albert Einstein College of Medicine
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Scientists at Albert Einstein College of Medicine have discovered the first compound that directly makes cancer cells commit suicide while sparing healthy cells. The new treatment approach, described in today's issue of Cancer Cell, was directed against acute myeloid leukemia (AML) cells but may also have potential for attacking other types of cancers.
"We're hopeful that the targeted compounds we're developing will prove more effective than current anti-cancer therapies by directly causing cancer cells to self-destruct," says Evripidis Gavathiotis, Ph.D., associate professor of biochemistry and of medicine and senior author of the study. "Ideally, our compounds would be combined with other treatments to kill cancer cells faster and more efficientlyand with fewer adverse effects, which are an all-too-common problem with standard chemotherapies."
AML accounts for nearly one-third of all new leukemia cases and kills more than 10,000 Americans each year. The survival rate for patients has remained at about 30 percent for several decades, so better treatments are urgently needed.
The newly discovered compound combats cancer by triggering apoptosisan important process that rids the body of unwanted or malfunctioning cells. Apoptosis trims excess tissue during embryonic development, for example, and some chemotherapy drugs indirectly induce apoptosis by damaging DNA in cancer cells.
Apoptosis occurs when BAXthe "executioner protein" in cellsis activated by "pro-apoptotic" proteins in the cell. Once activated, BAX molecules home in on and punch lethal holes in mitochondria, the parts of cells that produce energy. But all too often, cancer cells manage to prevent BAX from killing them. They ensure their survival by producing copious amounts of "anti-apoptotic" proteins that suppress BAX and the proteins that activate it.
"Our novel compound revives suppressed BAX molecules in cancer cells by binding with high affinity to BAX's activation site," says Dr. Gavathiotis. "BAX can then swing into action, killing cancer cells while leaving healthy cells unscathed."
Dr. Gavathiotis was the lead author of a 2008 paper in Nature that first described the structure and shape of BAX's activation site. He has since looked for small molecules that can activate BAX strongly enough to overcome cancer cells' resistance to apoptosis. His team initially used computers to screen more than one million compounds to reveal those with BAX-binding potential. The most promising 500 compoundsmany of them newly synthesized by Dr. Gavathiotis' teamwere then evaluated in the laboratory.
"A compound dubbed BTSA1 (short for BAX Trigger Site Activator 1) proved to be the most potent BAX activator, causing rapid and extensive apoptosis when added to several different human AML cell lines," says lead author Denis Reyna, M.S., a doctoral student in Dr. Gavathiotis' lab. The researchers next tested BTSA1 in blood samples from patients with high-risk AML. Strikingly, BTSA1 induced apoptosis in the patients' AML cells but did not affect patients' healthy blood-forming stem cells.
Finally, the researchers generated animal models of AML by grafting human AML cells into mice. BTSA1 was given to half the AML mice while the other half served as controls. On average, the BTSA1-treated mice survived significantly longer (55 days) than the control mice (40 days), with 43 percent of BTSA1-treated AML mice alive after 60 days and showing no signs of AML.
Importantly, the mice treated with BTSA1 showed no evidence of toxicity. "BTSA1 activates BAX and causes apoptosis in AML cells while sparing healthy cells and tissuesprobably because the cancer cells are primed for apoptosis," says Dr. Gavathiotis. He notes that his study found that AML cells from patients contained significantly higher BAX levels compared with normal blood cells from healthy people. "With more BAX available in AML cells," he explained, "even low BTSA1 doses will trigger enough BAX activation to cause apoptotic death, while sparing healthy cells that contain low levels of BAX or none at all."
Plans call for Dr. Gavathiotis and his team to see whether BTSA1 will show similar effectiveness when tested on animal models of other types of cancer.
Explore further: Scientists discover potential new improved way to kill cancer cells
More information: "Direct activation of BAX by BTSA1 overcomes apoptosis resistance in acute myeloid leukemia," Cancer Cell (2017).
Journal reference: Nature
Wonderful news for so many! But will it be in time?
Interesting.
And this is the last we will ever hear of it.
bkmk
Great news!
Any chance this can be modified to attack fat cells?
Baloney. Anyone with such a drug would become a billionaire.
They have already modified the science to destroy functioning brain cells, as evidenced by Pelosi and Schumer’s successful treatment. Procedure did not work on Auntie Maxine, however there is an on-going search for a donor brain which will not reject transplant.
Great more animal testing. So this chemical that were pretty sure Works will probably be available to treat my cancer about 8 years after I’m dead.
“Baloney. Anyone with such a drug would become a billionaire.”
They will be thwarted by those without such a solution that stand to lose billions.
If someone made that possible, whoever it is would make Bill Gates look poor.
ah fuggedaboutit
“Wonderful news for so many! But will it be in time?”
How many times have we said that about these “magic bullets” for cancer?
These are basically advertisements looking for investors.
I don’t think the Albert Einstein Medical School has a problem with raising money. It would not have to look far.
There have been some great new treatments out for specific cancers and specific protien markers. Look at Rituxan for an example.
https://en.m.wikipedia.org/wiki/Rituximab
“And this is the last we will ever hear of it.”
I’d call you a doubting Thomas, but over the years I have seen similar medical reports, and each time nothing happens. Too much money in continuing disease.
My point is they’re always on the verge of curing XXXXX and never quite get there.
Can they do it for other illnesses such as neuroathy?
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