Researchers identify a possible therapeutic target for Kennedy's disease and prostate cancer

https://www.eurekalert.org/pub_releases/2019-08/ifri-ria080819.php

NEWS RELEASE 8-AUG-2019

Researchers identify a possible therapeutic target for Kennedy's disease and prostate cancer

INSTITUTE FOR RESEARCH IN BIOMEDICINE (IRB BARCELONA)

A study led by scientists at the Institute for Research in Biomedicine (IRB Barcelona) and published in Nature Communicationsproposes chaperone protein Hps70 as an attractive therapeutic target for the treatment of Kennedy's disease--a rare neuromuscular condition--and of castration-resistant prostate cancer.

Kennedy´s disease is caused by a mutation in the androgen receptor. This receptor serves as a sensor of testosterone, detecting the levels of this hormone and activating the genes responsible for male traits. But in patients with this disease, the mutated receptor shows an altered structure, as demonstrated by this lab in a previous study recently published in the same journal, and it forms aggregates that damage muscle cells and causes muscular atrophy or wasting.

Chaperone proteins are one of the mechanisms through which the formation of toxic protein aggregates is prevented. These chaperones bind to other proteins in order to facilitate their correct folding, assembly and transport, as well as regulating their degradation. "But we didn't know the role of these chaperones in the regulation of the activity, cell concentration and solubility of the androgen receptor," says ICREA researcher Xavier Salvatella, head of the Laboratory of Molecular Biophysics at IRB Barcelona.

Using a sophisticated biophysics approach, nuclear magnetic resonance (NMR), and experiments with human cell cultures, the scientists discovered that the chaperones Hsp40 and Hsp70 bind strongly to a region of the androgen receptor that is susceptible to forming toxic aggregates. This interaction between the chaperones and the receptor prevents the formation of these deposits and facilitates their clearance.

To confirm whether the increase in the activity of these chaperones decreases the formation of toxic aggregates and whether these proteins are therefore useful for the treatment of Kennedy`s disease, the scientists performed experiments in mouse models. These experiments were done in collaboration with the labs of Professors Jason E. Gestwicki and Andrew P. Lieberman from the University of California San Francisco and the University of Michigan, respectively.

"The results obtain in mice confirm that compounds that activate Hsp70 lead to a decrease in the formation of the aggregates," says Salvatella. "Therefore the chaperone Hsp70 emerges as a possible therapeutic target for Kennedy's disease," he goes on to say.

The results may also be useful in the search for a treatment for castration-resistant prostate cancer, the most advanced stage of this kind of cancer, which causes 30,000 deaths a year in Europe. In cells resistant to current treatments, the binding site of Hsp40 and Hsp70 in the androgen receptor is not altered, and therefore these chaperones may also serve as a therapeutic target in this disease.

Cancer Cells Committing Suicide

I read this short article in the “Big Think” and found it interesting. If this is successful in humans, it would be a major step forward in treating some cancers.

Every time I read about chemotherapy, I remember an original Star Trek episode where Bones is talking to Spock. He explains a barbaric torture that 20^th century doctors used to treat cancer called chemotherapy.
 

Scientists Get Cancer Cells to Commit Suicide

by Orion Jones

What's the Latest Development?
Scientists have found a special molecule that activates the body's own tumor killing system, causing the death of cancerous tissue in mice while preserving the integrity of healthy cells. "The molecule, TIC10, activates the gene for a protein called TRAIL (tumor-necrosis-factor-related apoptosis-inducing ligand), which has long been a target for cancer researchers looking for drugs that would avoid the debilitating effects of conventional therapies." Experiments showed that TIC10 had potent effects against a variety of tumors, including breast, lymphatic, colon and lung cancer.

What's the Big Idea?
The TIC10 molecule has been shown to be especially effective at triggering cell suicide in gliobastoma, a kind of brain tumor that is notoriously difficult to treat. By activating the TRAIL gene in cancerous and healthy cells, cell suicide is induced in cancer cells immediately next to healthy ones. Wafik El-Deiry, an oncologist at Pennsylvania State University in Hershey and lead author of the study, said "TRAIL is a part of our immune system: all of us with functional immune systems use this molecule to keep tumors from forming or spreading, so boosting this will not be as toxic as chemotherapy."