Biotin-dependent regulation of gene expression in human cells

The role of biotin as cofactor of carboxylases and its importance in metabolic homeostasis are well known. In recent years, different researchers have suggested the participation of biotin as a regulator molecule in the control of gene expression. Biotin-dependent gene expression requires of the transformation of biotin into biotinyl-5'-AMP by holocarboxylase synthetase and the activation of soluble guanylate cyclase and a cGMP-dependent protein kinase. The regulatory role of biotin is responsible for the correct expression of enzymes involved in biotin utilization in human cells. We propose that this mechanism protects the brain from biotin deficiency.     

Epigenetic regulation of gelsolin expression in human breast cancer cells.

Gelsolin is a multifunctional, actin-binding protein that is greatly decreased in many transformed cell lines and tumor tissues, including breast cancers. Downregulation of gelsolin RNA occurs in most breast cancers of rats, mice, and humans, but gross mutations of the gelsolin gene have not been found. Here we demonstrate by PCR and RT-PCR analysis that there are no point mutations in putative regulatory regions or the entire coding region of the cytoplasmic isoform of the gelsolin gene in human breast cancer cells (BCC). To determine if epigenetic modification is involved in downregulating gelsolin expression in MDA-MB-231 (MDA231), MCF7, and T47D BCC, we have used Southern blot analysis, 5-azacytidine (5aza) treatment, and trichostatin A (TSA) treatment. Southern blot analysis performed on genomic DNA demonstrated altered CpG methylation within intron 1 in DNA from all BCC compared to normal, mortal human mammary epithelial cells (HMEC). Treatment of the BCC with 5aza converted the DNA restriction pattern to that seen in untreated HMEC genomic DNA and caused modest increases in gelsolin RNA and protein. Incubation with TSA, an inhibitor of histone deacetylase, induced a dramatic upregulation of gelsolin RNA and protein levels which preceded apoptotic death of all BCC within 48-60 h. Our data support a role for epigenetic changes in chromatin structure leading to downregulation of gelsolin expression in human breast cancer. To our knowledge, this is the first example of a tumor suppressor gene downregulated in human breast cancer by changes in histone acetylation.     

Alterations of expression and regulation of transforming growth factor beta in human cancer prostate cell lines

TGFβ can promote and/or suppress prostate tumor growth through multiple and opposing actions. Alterations of its expression, secretion, regulation or of the sensitivity of target cells can lead to a favorable environment for tumor development. To gain a better insight in TGFβ function during cancer progression, we have used different cultured human prostate cells: preneoplastic PNT2 cells, the androgen-dependent LNCaP and the androgen-independent PC3 and DU145 prostate cancer cell lines. We have studied by specific ELISA assays in conditioned media (CM), the secretion of TGFβ1 and TGFβ2 in basal conditions and after hormonal treatment (DHT or E2) and the expression of TGFβ1 mRNA by Northern blot. We have also compared the effect of fibroblast CM on TGFβ secretion by the different cell types. Compared to PNT2 cells, cancer cell lines secrete lower levels of active TGFβ which are not increased in the presence of fibroblast CM. LNCaP cells respond to androgen or estrogen treatment by a 10-fold increase of active TGFβ secretion while PC3 and DU145 are unresponsive. In conclusion, prostate cancer cell lines have lost part of their ability to secrete and activate TGFβ, and to regulate this secretion through stromal–epithelial interactions. Androgen-sensitive cancer cells may compensate this loss by hormonal regulation.     

Prospects for gene therapy in human prostate cancer

Prostate cancer is the most common neoplasm in men and a significant cause of mortality in affected patients. Despite significant advances, current methods of treatment are effective only in the absence of metastatic disease. Gene therapy offers a renewed hope of using the differential characteristics of normal and malignant tissue in constructing treatment strategies. Several clinical trials in prostate cancer gene therapy are currently under way, using immunomodulatory genes, anti-oncogenes, tumor suppressor genes and suicide genes. A continued understanding of the etiological mechanisms involved in the establishment and progression of prostate cancer, along with advances in gene therapy technology, should make gene therapy for prostate cancer therapeutically valuable in the future.     

Androgen receptor gene mutations in human prostate cancer

To investigate the structural abnormality of the androgen receptor (AR) in human prostate cancers, exons B-H encoding DNA- and hormone-binding domains were examined by single-strand conformation polymorphism analysis of polymerase chain reaction products using originally designed oligoprimers. Tissues from 7 cases of untreated stage B prostate cancer surgically removed and from 8 cases of endocrine therapy-resistant cancers obtained at autopsy were used in the study. Two different mutations were identified in exons D and H in the different cancer foci of the same cancer death patient. One mutation in exon D (at codon 701, Leu to His) was detected in the prostate, and the other in exon H (at codon 877, Thr to Ala) was found in metastatic tissues. In untreated cancer tissues and the other autopsy samples, no mutations were detected. The mutation in exon H was identical to that reported in LNCaP cells. These results indicate that AR gene mutations occur in relation to endocrine therapy-resistance, although the mutation was found in 1 out of 8 resistant cases (12.5%) at autopsy.     

Profiling of zinc-altered gene expression in human prostate normal vs. cancer cells: a time course study

We have demonstrated that zinc exposure induces apoptosis in human prostate cancer cells (PC-3) and benign hyperplasia cells (BPH), but not in normal prostate cells (HPR-1). However, the mechanisms underlying the effects of zinc on prostate cancer cell growth and zinc homeostasis remain unclear.To explore the zinc effect on gene expression profiles in normal (HPR-1) and malignant prostate cells (PC-3), we conducted a time course study of Zn treatment with microarray analysis. Microarray data were evaluated and profiled using computational approach for the primary and secondary data analyses. Final analyses were focused on the genes (1) highly sensitive to zinc; (2) associated with zinc homeostasis, i.e., metallothioneins (MTs), solute zinc carriers (ZIPs) and zinc exporters (ZnTs); (3) relevant to several oncogenic pathways. Zinc-mediated mRNA levels of MT isotypes were further validated by semi-quantitative RT-PCR.Results showed that zinc effect on genome-wide expression patterns was cell-type specific, and zinc appeared to have mainly down-regulatory effects on thousands of genes (1953 in HPR-1; 3534 in PC-3) with a threshold of ±2.5-fold, while fewer genes were up-regulated (872 in HPR-1; 571 in PC-3). The patterns of zinc effect on functional MT genes' expression provided evidence for the cell type-dependent zinc accumulation and zinc-induced apoptosis in prostate cells. In PC-3 cells, zinc significantly up-regulated the expression of MT-1 isotypes MT-1J and MT-1M, denoted previously as “nonfunctional” MT genes, and now a depictive molecular structure of MT-1J was proposed. Examination of genes involved in oncogenic pathways indicated that certain genes, e.g., Fos, Akt1, Jak3 and PI3K, were highly regulated by zinc with cell-type specificity.This work provided an extensive database on zinc-related prostate cancer research. The strategy of data analysis was devoted to finding genes highly sensitive to Zn, and the genes associated with zinc accumulation and zinc-induced apoptosis. The results indicate that zinc regulation of gene expression is cell-type specific, and MT genes play important roles in prostate malignancy.     

The regulation of human corticotrophin-releasing hormone gene expression in the placenta.

Corticotrophin-releasing hormone (CRH) is a 41 amino acid neuropeptide that is expressed in the hypothalamus and the human placenta. Placental CRH production has been linked to the determination of gestational length in the human. Although encoded by a single copy gene, CRH expression in the placenta is regulated differently to the hypothalamus. Glucocorticoids stimulate CRH promoter activity in the placenta but inhibit it's activity in the hypothalamus, via mechanisms involving different regions of the CRH promoter. We discuss how various stimuli alter CRH promoter activity and why these responses are unique to the placenta.     

Androgen regulation of FLICE-like inhibitory protein gene expression in the rat prostate

In hope of eventually identifying defects in human prostatic neoplasias that render them insensitive to anti-androgen therapy, we have examined the regulation of components of ligand-induced cell death pathways during castration-induced regression of the prostate. Rat prostates were obtained after surgical castration with or without subsequent androgen replacement. The mRNA levels of genes encoding components of the apoptotic pathway were measured from individual prostates. Whole prostates 1-10 days after castration did not show a significant change in mRNA levels encoding either Fas or FasL, which some studies suggest are necessary for regression to occur. However, the mRNA encoding a catalytically inactive cysteinyl aspartate-specific protease (caspase) analog, FLICE-like inhibitor protein (FLIP), decreases during the first day following castration. In the most apoptotically responsive ventral lobe of the rat prostate, the reduction in FLIP mRNA levels is evident within 12 h of castration. The mRNA levels of the principal target of FLIP inhibition, caspase-8, do not change during the period preceding the onset of detectable DNA fragmentation. Androgen administration to castrated rats reverses prostate regression, and restores FLIP mRNA to normal levels. By acting as an inhibitor of caspase-8, FLIP may protect prostatic epithelium from apoptosis. Androgen withdrawal, by reducing FLIP mRNA levels, might leave the cells vulnerable to as yet unidentified cell death signals.