17α-ethynyl-5α-androstane-3α, 17ß-diol treatment of MNU-induced mammary cancer in rats.

N-methyl-N-nitrosourea (MNU) induces estrogen-dependent mammary tumors in female Lewis rats. We explored the antineoplastic activity of a synthetic androstane derivative, 17α-ethynyl-5α-androstane-3α, 17ß-diol (HE3235), as a single agent or in combination with docetaxel compared to tamoxifen, anastrazole, and docetaxel monotherapies against MNU-induced mammary tumors in female Lewis rats. Treatment with HE3235 alone rapidly reduced tumor burden, similar in effect to tamoxifen and anastrozole. The combination of HE3235 with docetaxel was more effective than any single agent, although without apparent toxicity. Only HE3235 or HE3235 plus docetaxel continued to suppress tumor growth after cessation of treatment. HE3235 treatment increased immunohistochemical markers of apoptosis and expression of proapoptotic genes and estrogen receptor beta and decreased expression of antiapoptotic genes, androgen receptor, and estrogen receptor alpha. These data warrant clinical investigation of HE3235 for breast cancer treatment.

HE3235 inhibits growth of castration-resistant prostate cancer.

Treatments for advanced prostate cancer (CaP) typically involve androgen deprivation therapy. However, most patients eventually develop castration-resistant CaP (CRPC) for which highly effective therapies are limited. We explored the efficacy of a novel agent, HE3235, in inhibiting growth of CRPC in preclinical models. Castrated male mice were implanted subcutaneously with LuCaP35V CaP xenografts in the presence and absence of 5'-androstenediol (AED) and treated with HE3235. To investigate the effect of HE3235 on CaP tumor in the bone, castrated mice were injected intratibially with C4-2B CaP cells and treated with HE3235. Serum prostate-specific antigen (PSA) levels, tumor volume, immunohistochemistry, gene expression, and levels of intratumoral androgens were analyzed. HE3235 significantly prolonged the tumor doubling time of LuCaP35V, decreased androgen receptor expression, and lowered levels of intratumoral testosterone by approximately 89% and dihydrotestosterone by approximately 63% in both the presence and the absence of AED. HE3235 inhibited tumor growth in the bone environment. Weights of tumored tibiae of HE3235-treated animals were lower than those of control (P = .031), and normalized PSA levels were also significantly decreased at the end of study by HE3235 treatment (P = .0076). HE3235 inhibits the growth of subcutaneous CRPC as well as CRPC in the bone environment. Our data show that HE3235 exhibits a wide range of effects, including alteration of androgen receptor signaling and reductions in levels of intratumoral androgens. Our results support ongoing clinical investigations into the effectiveness of HE3235 in the setting of CRPC and warrants further studies into the mechanisms behind the effects of HE3235.

16alpha-Bromoepiandrosterone restores T helper cell type 1 activity and accelerates chemotherapy-induced bacterial clearance in a model of progressive pulmonary tuberculosis.

BALB/c mice with pulmonary tuberculosis develop a T helper cell type 1 response that peaks at 3 weeks, temporarily controlling bacterial growth. Then bacterial proliferation recommences, accompanied by increasing interleukin (IL)-4 levels and decreasing interferon (IFN)-gamma, tumor necrosis factor (TNF)-alpha, and inducible nitric oxide synthase (iNOS) levels. These changes mimic those in the human disease. In a previous study, administration of dehydroepiandrosterone (DHEA) beginning on day 60 after infection reversed these changes and protected the mice. However, DHEA is suboptimal for human use, partly because it is readily metabolized into sex steroids. 16alpha-Bromoepiandrosterone (EpiBr; 16alpha -bromo-5alpha -androstan-3beta-ol-17-one) is a synthetic adrenal steroid derivative that does not enter sex steroid pathways. In the present study, when tuberculous BALB/c mice were treated with EpiBr 3 times/week beginning on day 60, inhibition of bacterial proliferation and increased expression of TNF-alpha, IFN-gamma, and iNOS were observed, although decreased expression of IL-4 was also observed. Moreover, when given as an adjunct to conventional chemotherapy, EpiBr enhanced bacterial clearance. Trials for the use of EpiBr in the treatment of human tuberculosis are now justified.

The effects of chemotherapeutics on cellular metabolism and consequent immune recognition.

Awidely held view is that oncolytic agents induce death of tumor cells directly. In this report we review and discuss the apoptosis-inducing effects of chemotherapeutics, the effects of chemotherapeutics on metabolic function, and the consequent effects of metabolic function on immune recognition. Finally, we propose that effective chemotherapeutic and/or apoptosis-inducing agents, at concentrations that can be achieved physiologically, do not kill tumor cells directly. Rather, we suggest that effective oncolytic agents sensitize immunologically altered tumor cells to immune recognition and immune-directed cell death.

Characterization of a novel metabolic strategy used by drug-resistant tumor cells.

Acquired or inherent drug resistance is the major problem in achieving successful cancer treatment. However, the mechanism(s) of pleiotropic drug resistance remains obscure. We have identified and characterized a cellular metabolic strategy that differentiates drug-resistant cells from drug-sensitive cells. This strategy may serve to protect drug-resistant cells from damage caused by chemotherapeutic agents and radiation. We show that drug-resistant cells have low mitochondrial membrane potential, use nonglucose carbon sources (fatty acids) for mitochondrial oxygen consumption when glucose becomes limited, and are protected from exogenous stress such as radiation. In addition, drug-resistant cells express high levels of mitochondrial uncoupling protein 2 (UCP2). The discovery of this metabolic strategy potentially facilitates the design of novel therapeutic approaches to drug resistance.