Oral simvastatin administration delays castration-resistant progression and reduces intratumoral steroidogenesis of LNCaP prostate cancer xenografts.

BACKGROUND: Growing evidence supports the idea that de novo steroidogenesis has an important role in prostate cancer's progression to the castration-resistant state following androgen deprivation therapy. Therefore, reducing the availability of cholesterol for use as a precursor in androgen synthesis may reduce proliferation and disease progression. METHODS: LNCaP xenograft-bearing mice were castrated and administered simvastatin via diet, and tumor volume and PSA concentration were monitored for 8 weeks post castration. Levels of serum and intratumoral androgens along with serum simvastatin and common toxicity markers were measured at end point. RESULTS: Reduced post-castration tumor growth rate in simvastatin-treated mice correlated with delayed time to castration-resistant progression, determined by two serum PSA doublings from post-castration nadir, when compared with xenografts in mice on control diet. At 8 weeks post castration, serum simvastatin levels were comparable to clinically relevant human doses with no evidence of overt muscle or liver toxicity. This suppressed post-castration tumor growth in the simvastatin diet group was correlated with reduced intratumoral testosterone and dihydrotestosterone levels. CONCLUSIONS: Reduced tumor growth and intratumoral androgen levels observed in simvastatin-treated, castrated mice harboring LNCaP xenograft suggests that suppressing de novo steroidogenesis can delay castration-resistant progression of this tumor model.

A locus on mouse Ch10 influences susceptibility to limbic seizure severity: fine mapping and in silico candidate gene analysis.

Identification of genes contributing to mouse seizure susceptibility can reveal novel genes or pathways that provide insight into human epilepsy. Using mouse chromosome substitution strains and interval-specific congenic strains (ISCS), we previously identified an interval conferring pilocarpine-induced limbic seizure susceptibility on distal mouse chromosome 10 (Ch10). We narrowed the region by generating subcongenics with smaller A/J Ch10 segments on a C57BL/6J (B6) background and tested them with pilocarpine. We also tested pilocarpine-susceptible congenics for 6-Hz ECT (electroconvulsive threshold), another model of limbic seizure susceptibility, to determine whether the susceptibility locus might have a broad effect on neuronal hyperexcitability across more than one mode of limbic seizure induction. The ISCS Line 1, which contained the distal 2.7 Mb segment from A/J (starting at rs29382217), was more susceptible to both pilocarpine and ECT. Line 2, which was a subcongenic of Line 1 (starting at rs13480828), was not susceptible, thus defining a 1.0 Mb critical region that was unique to Line 1. Bioinformatic approaches identified 45 human orthologs within the unique Line 1 susceptibility region, the majority syntenic to human Ch12. Applying an epilepsy network analysis of known and suspected excitability genes and examination of interstrain genomic and brain expression differences revealed novel candidates within the region. These include Stat2, which plays a role in hippocampal GABA receptor expression after status epilepticus, and novel candidates Pan2, Cdk2, Gls2 and Cs, which are involved in neural cell differentiation, cellular remodeling and embryonic development. Our strategy may facilitate discovery of novel human epilepsy genes.

Arrhythmia in heart and brain: KCNQ1 mutations link epilepsy and sudden unexplained death.

Sudden unexplained death is a catastrophic complication of human idiopathic epilepsy, causing up to 18% of patient deaths. A molecular mechanism and an identified therapy have remained elusive. Here, we find that epilepsy occurs in mouse lines bearing dominant human LQT1 mutations for the most common form of cardiac long QT syndrome, which causes syncopy and sudden death. KCNQ1 encodes the cardiac KvLQT1 delayed rectifier channel, which has not been previously found in the brain. We have shown that, in these mice, this channel is found in forebrain neuronal networks and brainstem nuclei, regions in which a defect in the ability of neurons to repolarize after an action potential, as would be caused by this mutation, can produce seizures and dysregulate autonomic control of the heart. That long QT syndrome mutations in KCNQ1 cause epilepsy reveals the dual arrhythmogenic potential of an ion channelopathy coexpressed in heart and brain and motivates a search for genetic diagnostic strategies to improve risk prediction and prevention of early mortality in persons with seizure disorders of unknown origin.