Mechanism of how testosterone promotes prostate cancer

[Jinzang]

They started by adding testosterone to cancer cells grown in the lab to see what happened to gene activity when hormone levels rose. At the same time, they used prostate cancer samples from men who’d had hormone therapy (which reduces testosterone levels) to see what effect lower hormone levels had on gene activity.
The scientists found that changing testosterone levels affected a group of genes linked to a process called glycosylation, where sugar groups are added to the surface of the cancer cells. They noticed that lower testosterone levels in the samples from men on hormone therapy repressed the activity of a number of genes involved in the glycosylation process. However, when they added testosterone to cancer cells, the activity of these genes increased.

http://prostatecanceruk.org/about-u...sterone-and-cancer-cell-aggression-discovered

 

[Nelson Vergel]

That was an in-vitro test that does not include all the other hormones involved in activating receptors.

Does Testosterone Cause Prostate Cancer? Can Men Treated for Prostate Cancer Use TRT?

 

[PAUL-E]

Experts used an advanced screening technique which found hundreds of genes were affected by the male hormone testosterone. It is believed this could lead to new
diagnostic tests and treatments.Among the 700 genes identified was an important set that add sugar groups - known as glycans - to the surface of prostate cancer cells. This group has never been investigated before.
Results of the research, published in EBioMedicine, suggest that testosterone changes glycans to make cancer cells more likely to survive, grow and spread to other parts of the body.
Scientists say there is the potential to target these glycans which could stop the growth and spread of tumours and save lives.
http://medicalxpress.com/news/2016-07-prostate-cancer-breakthrough-diagnostic-treatments.html

 

[Nelson Vergel]

Extreme Response to High-Dose Testosterone in BRCA2- and ATM-Mutated Prostate Cancer

Defects in DNA repair genes are now understood to be common in patients with metastatic castration-resistant prostate cancer (mCRPC) according to studies sequencing tumor samples and the germline. In a proof-of concept study to demonstrate that such defects could be exploited therapeutically, patients with mCRPC with mutations in DNA repair genes had responses when treated with olaparib.

The mechanism by which PARP inhibition leads to cell death, is in part via induction of DNA double strand breaks, which go unrepaired in cells harboring defects in the homologous recombination repair pathway.

We have previously reported on the therapeutic potential of high-dose testosterone in men with mCRPC. Preclinical studies demonstrated that rapid cycling between high and low levels of androgen, termed bipolar androgen therapy (BAT), could disrupt DNA relicensing and produce DNA double-strand breaks in CRPC cells.

Given the emerging data on DNA repair defects in prostate cancer and the mechanism of BAT, we postulated that men with such defects may be particularly susceptible to BAT. Here we report a case of an exceptional responder to BAT and the underlying tumor mutations that possibly explain his susceptibility to the therapy.

The patient is a 70-yr-old man with mCRPC. He initially presented with Gleason 9 disease for which he underwent radical prostatectomy followed by salvage radiation therapy. He was initiated on hormonal therapy 2 yr later because of rising prostate-specific antigen (PSA).

He received bicalutamide, nilutamide, ketoconazole, and enzalutamide sequentially over 3 yr (Fig. 1). At the time of progression on enzalutamide, computed tomography (CT) imaging showed enlarging node-only disease (target lesion was 3.3 cm in the iliac node).

He was enrolled in a clinical trial and received testosterone cypionate 400 mg intramuscularly every 28 d and continuous luteinizing hormone–releasing hormone agonist therapy. After two cycles, his PSA became unmeasurable and has remained so for 20 cycles of ongoing BAT (Fig. 1).

He achieved a radiographic complete response after six cycles. At this point, the patient continues to have no evidence of disease on bone scan or CT scan, nondetectable PSA, and testosterone in the non-castrate range.
To test whether this patient's tumor had underlying DNA repair defects, we sequenced his archived primary prostate cancer tissue using a 203-gene panel (Personal Genome Diagnostics, Baltimore, MD, USA).

The tumor was found to have an inactivating S1982Rfs*22 frame shift mutation in BRCA2 and an L2307F missense mutation in ATM. Both of these mutations were present in the germline.
The results for this patient, who is experiencing a durable complete response to BAT, support the hypothesis that patients harboring mutations in DNA repair pathway genes may be particularly sensitive to BAT. Further testing of BAT in patients with DNA repair deficits or testing of BAT in combination with agents targeting the DNA repair pathway is warranted.

Teply BA, Kachhap S, Eisenberger MA, Denmeade SR. Extreme Response to High-dose Testosterone in BRCA2- and ATM-mutated Prostate Cancer. Eur Urol.

 

[Vince]

Cancer, like all cells, depend on blood sugar for energy. Giving more sugar to cancer cells doesn't speed their growth?