Apoptosis in prostate carcinogenesis

Development of effective therapeutic modalities for the treatment of human cancer relies heavily upon understanding the molecular alterations that result in initiation and progression of the tumorigenic process. Many of the molecular changes identified in human prostate tumorigenesis so far play key roles in apoptosis regulation. Apoptosis represents a universal and exquisitely efficient cellular suicide pathway. Since the therapeutic goal is to trigger tumor-selective apoptotic cell death (without clinically significant effects on the host), elucidation of the mechanisms underlying apoptosis deregulation will lead to the identification of specific cellular components for targeting therapeutic interventions. As our understanding of its vital role in the development and growth of the prostate gland has expanded, numerous genes that encode apoptotic regulators have been identified that are severely impaired in prostate cancer cells. In addition, the expression of apoptotic modulators within prostatic tumors appears to correlate with tumor sensitivity to traditional therapies such as hormonal ablation and radiotherapy. No strict correlation between apoptosis induction and a patient's long-term prognosis has emerged, perhaps due to the fact that the ability to achieve initial remission alone does not adequately predict long-term outcome. This review will encompass the known molecular changes intimately involved in the apoptotic pathway which have potential prognostic value in disease progression, as well as therapeutic significance in the enhancement of the apoptotic response to novel and established treatment strategies for the treatment of androgen-dependent and androgen-independent prostatic tumors. The main focus will be on the role of the transforming growth factor-beta (TGF-beta) signaling pathway, bcl-2 and the bcl-2 family members, the caspase cascade (apoptosis executioners), and the Fas pathway in induction and regulation of apoptosis following therapeutic stimuli for the management of advanced prostate cancer.     

Analysis of HPC1, HPCX, and PCaP in Icelandic hereditary prostate cancer

Putative prostate cancer susceptibility loci have recently been identified by genetic linkage analysis on chromosomes 1q24-25 (HPC1). 1q44.243 (PCaP), and Xq27-28 (HPCX). In order to estimate the genetic linkage in Icelandic prostate cancer families, we genotyped 241 samples from 87 families with eleven markers in the HPC1 region, six markers at PCaP, and eight at HPCX. Concurrently, we assessed allelic imbalance at the HPC1 and PCaP loci in selected tumors from the patients. For each of the candidate regions, the combined parametric and non-parametric LOD scores were strongly negative. Evidence for linkage allowing for genetic heterogeneity was also insignificant for all the regions. The results were negative irrespective of whether calculations were performed for the whole material or for a selected set of early age at onset families. The prevalence of allelic imbalance was relatively low in both the HPC1 (0%-9%) and PCaP (5%-20%) regions and was not elevated in tumors from positively linked families. Our studies indicate that the putative cancer susceptibility genes at chromosomes 1q24-25, 1q44.2-43, and Xq27-28 are unlikely to contribute significantly to hereditary prostate cancer in Iceland and that selective loss of the HPC1 and PCaP loci is a relatively rare somatic event in prostate cancers.     

Cloning of Rat Vitamin K-Dependent γ-Glutamyl Carboxylase and Developmentally Regulated Gene Expression in Postimplantation Embryos

Vitamin K-dependent carboxylase catalyzes the posttranslational modification of glutamate to γ-carboxyglutamate (Gla) in its substrates, the vitamin K-dependent proteins (VKDPs). This modification is required for the activities of the VKDPs. Recent evidence demonstrates previously unrecognized roles for VKDPs as signaling molecules important in the regulation of cell growth, adhesion, and apoptosis, suggesting developmental functions for VKDPs and hence the carboxylase. The tissue distribution and functions of carboxylase in development are unknown. In this study, we isolated and characterized the full-length cDNA encoding the rat carboxylase and analyzed, at the cellular level, the expression of this gene in rat embryos byin situhybridization. We demonstrate that the expression of this gene is highly regulated in a developmental and tissue-specific manner. Hepatocytes, the major site of synthesis of VKDPs of blood coagulation, express carboxylase mRNA late in gestation, in contrast to the central nervous system, mesenchymal, and skeletal tissues which express carboxylase mRNA early during rat embryogenesis. The tissue-specific temporal expression of the carboxylase gene during embryogenesis indicates that vitamin K-dependent carboxylation and the formation of Gla is developmentally regulated. These studies suggest that vitamin K-dependent carboxylation is an important modulator of embryonic VKDP function.     

Distinct Alterations in Mitochondrial Mass and Function Characterize Different Models of Apoptosis

Recent studies have shown that reduction in mitochondrial membrane potential (ΔΨ_m) and generation of reactive oxygen species are early events in apoptosis. In this study, we present two different models of apoptotic cell death, Chinese hamster ovary (CHO) cells treated with aphidicolin and dexamethasone-treated 2B4 T-cell hybridoma cells, which display opposing mitochondrial changes. CHO cells arrested at G1/S with aphidicolin have a progressive increase in mitochondria mass and number, assessed by flow cytometry and fluorescent microscopy with mitochondria-specific probes. The increase in mitochondrial mass was not accompanied by a gain in net cellular mitochondrial membrane potential, consistent with an accumulation of relatively depolarized mitochondria. Fluorescent microscopy demonstrated an increased content of low ΔΨ_mmitochondria in aphidicolin-treated CHO cells, but high ΔΨ_mmitochondria were also present and remained stable in number. Mitochondrial mass correlated with decreased clonogenicity of aphidicolin-treated CHO cells. Cycloheximide prevented both the proliferation of mitochondria and subsequent cell death. In contrast, dexamethasone treatment of 2B4 T-cell hybridoma cells caused a decrease in ΔΨ_mwithout mitochondrial proliferation. Cycloheximide and Bcl-2 overexpression inhibited the loss of ΔΨ_m, as well as apoptosis. In both models, cell death was associated with a decrease in mitochondrial potential relative to mitochondrial mass, suggesting that an accumulation of damaged or dysfunctional mitochondria had occurred.     

Foot-and-Mouth Disease Virus Virulent for Cattle Utilizes the Integrin αvβ3 as Its Receptor

Adsorption and plaque formation of foot-and-mouth disease virus (FMDV) serotype A₁₂ are inhibited by antibodies to the integrin α_vβ₃ (A. Berinstein et al., J. Virol. 69:2664–2666, 1995). A human cell line, K562, which does not normally express α_vβ₃ cannot replicate this serotype unless cells are transfected with cDNAs encoding this integrin (K562-α_vβ₃ cells). In contrast, we found that a tissue culture-propagated FMDV, type O₁BFS, was able to replicate in nontransfected K562 cells, and replication was not inhibited by antibodies to the endogenously expressed integrin α₅β₁. A recent report indicating that cell surface heparan sulfate (HS) was required for efficient infection of type O₁ (T. Jackson et al., J. Virol. 70:5282–5287, 1996) led us to examine the role of HS and α_vβ₃ in FMDV infection. We transfected normal CHO cells, which express HS but not α_vβ₃, and two HS-deficient CHO cell lines with cDNAs encoding human α_vβ₃, producing a panel of cells that expressed one or both receptors. In these cells, type A₁₂ replication was dependent on expression of α_vβ₃, whereas type O₁BFS replicated to high titer in normal CHO cells but could not replicate in HS-deficient cells even when they expressed α_vβ₃. We have also analyzed two genetically engineered variants of type O₁Campos, vCRM4, which has greatly reduced virulence in cattle and can bind to heparin-Sepharose columns, and vCRM8, which is highly virulent in cattle and cannot bind to heparin-Sepharose. vCRM4 replicated in wild-type K562 cells and normal, nontransfected CHO (HS⁺ α_vβ_3⁻) cells, whereas vCRM8 replicated only in K562 and CHO cells transfected with α_vβ₃ cDNAs. A similar result was also obtained in assays using a vCRM4 virus with an engineered RGD→KGE mutation. These results indicate that virulent FMDV utilizes the α_vβ₃ integrin as a primary receptor for infection and that adaptation of type O₁ virus to cell culture results in the ability of the virus to utilize HS as a receptor and a concomitant loss of virulence.     

Region-Specific Targets of p42/p44MAPK Signaling in Rat Brain

Abstract: In vitro studies indicate that p42/p44^MAPK phosphorylate both nuclear and cytoplasmic proteins. However, the functional targets of p42/p44^MAPK activation in vivo remain unclear. To address this question, we localized activated p42/p44^MAPK in hippocampus and cortex and determined their signaling effects after electroconvulsive shock treatment (ECT) in rats. Phosphorylated p42/p44^MAPK content increased in the cytoplasm of hippocampal neurons in response to ECT. Consistent with this cytoplasmic localization, inhibition of ECT-induced p42/p44^MAPK activation by the extracellular signal-regulated kinase kinase inhibitor PD098059 blocked phosphorylation of the cytoplasmic protein microtubule-associated protein 2c (MAP2c), but failed to inhibit the induction of the nuclear protein c-Fos in response to ECT. In contrast to hippocampal neurons, cortical neurons exhibited an increase in amount of phosphorylated p42/p44^MAPK in both the nucleus and cytoplasm after ECT. Accordingly, PD098059 blocked the induction of Fos-like immunoreactivity in the nuclei of cortical neurons as well as MAP2c phosphorylation in the cytoplasm. Our data indicate that both nuclear and cytoplasmic substrates can be activated by p42/p44^MAPK in vivo. However, the functional targets of p42/p44^MAPK signaling depend on the precise location of p42/p44^MAPK within different subcellular compartments of brain regions. These results indicate unique functional pathways of p42/p44^MAPK-mediated signal transduction within different brain regions in vivo.