The Important Role and Implications of Citrate in the Composition, Structure, and Function of Oral/Periodontal/Craniofacial Tissues.

High citrate concentration is a major component in the structure of craniofacial bone, teeth and periodontal tissues of humans and other osteovertebrates. It is now established that citrate incorporation into the apatite/collagen complex of bone is essential for the manifestation of the important biomechanical properties of bone; such as stability, strength, and resistance to fracture. The osteoblasts are specialized citrate-producing cells that provide the citrate incorporated in bone during osteogenic stem cell differentiation for production of new bone; "citration" that occurs in concert with mineralization. Dentin and cementum contain high citrate levels; as contrasted with low citrate in enamel. There exists no information regarding the status and source of incorporated citrate in dentin or in cementum. These are important issues relating to oral, periodontal, craniofacial structures. For example, repair of defects should include new tissue that exhibits the composition, structure, and biomechanical properties of the "normal" tissue; which cannot be achieved in the absence of citrate incorporation in the new tissues. Unfortunately, the presence and role of citrate in these tissues have been largely ignored and unrecognized over the past about 40 years by the dental and medical community. The intent of this review is to re-establish the interest and research regarding the important citrate relationships and issues; with focus on related interests in dentistry.

Prostatic fluid electrolyte composition for the screening of prostate cancer: a potential solution to a major problem.

Early detection is the key to effective treatment of prostate cancer, and to the prevention of deaths due to progression to untreatable advanced stage cancer. Because of mitigating factors, especially benign prostatic hyperplasia (BPH), that result in a low accuracy (about 60%) of prostate-specific antigen (PSA) testing, there is an urgent need for a more reliable biomarker for the identification of early stage through advanced stage prostate cancer and 'at-risk' individuals. To address this issue we propose that changes in prostatic fluid composition could provide accurate and reliable biomarkers for the screening of prostate cancer. Most notable is the consistent and significant decrease in citrate and zinc that is associated with the development and progression of prostate cancer. In this review we provide the clinical and physiological basis and the evidence in support of the utility of prostatic fluid analysis as an effective approach for screening/detection of prostate cancer, especially early stage and 'at-risk' subjects. The problem of BPH interference that plagues PSA testing is eliminated in the potential prostatic fluid biomarkers. The potential development of rapid, simple, direct, accurate clinical tests provides additional advantageous conditions. Further exploration and development of citrate, zinc and other electrolytes as prostatic fluid biomarkers are urgently needed to address this critical prostate cancer issue.

Effect of metabolic inhibitors on ATP and citrate content in PC3 prostate cancer cells.

BACKGROUND: In normal prostate epithelial cells low m-aconitase activity decreases citrate oxidation leading to citrate accumulation. In prostate cancer cells m-aconitase activity is increased and citrate content is lower. The effect of inhibition of m-aconitase on ATP production by prostate cancer cells (PC3) is not known nor is the contribution of glycolysis versus respiration. METHODS: ATP content of PC3 cells as affected by inhibition of m-aconitase (fluoroacetate (FA), zinc), inhibition of glycolysis (2DxG), or respiration (DNP, oligomycin) was determined. The ability to maintain ATP using glucose or glutamine as sole substrate was also determined. Intermediates including ATP, lactate, glucose, and glutamine were assayed in neutralized perchloric acid (PCA) cell extracts, virgin, and conditioned medium by enzymatic fluorometry. RESULTS: Data show that inhibition of m-aconitase, glycolysis, or respiration alone did not decrease ATP content. Inhibition of both glycolysis and respiration were required to decrease ATP content. PC3 cells were able to produce ATP with either glucose or glutamine as sole substrate. Though FA clearly inhibited m-aconitase there was no evidence that zinc had a similar effect. CONCLUSION: PC3 cells can support ATP production when m-aconitase is inhibited by using glycolysis or oxidation of substrate (e.g., glutamine) entering the TCA cycle distal to citrate.

The pharmacokinetics and disposition of MK-0524, a Prosglandin D2 Receptor 1 antagonist, in rats, dogs and monkeys.

MK-0524 is a potent, selective and orally active Prosglandin D(2) Receptor 1 (DP(1)) antagonist currently under clinical development for the treatment of niacin-induced flushing. Experiments to study the pharmacokinetics, metabolism and excretion of MK-0524 were conducted in rats, dogs and monkeys. MK-0524 displayed linear kinetics and rapid absorption following an oral dose. Following intravenous (i.v.) administration of MK-0524 to rats and dogs (1 and 5 mg/kg), the mean Cl(p) was approximately 2 and approximately 6 ml/min/kg, the T(1/2) was approximately 7 and approximately 13 h and the Vd(ss) was approximately 1 and approximately 5 L/kg, respectively. In monkeys dosed i.v. at 3 mg/kg, the corresponding values were 8 ml/min/kg, 3 h and 1 L/kg, respectively. Following oral dosing of MK-0524 to rats (5, 25 and 100 mg/kg), dogs (5 mg/kg) and monkeys (3 mg/kg), the absorption was rapid with the mean C(max) occurring between 1 and 4 h. Absolute oral bioavailability values in rats, dogs and monkeys were 50, 70 and 8%, respectively. The major circulating metabolite was the acyl glucuronide of MK-0524 (M2), with ratios of glucuronide to the parent aglycone being highest in the monkey followed by dog and rat. In bile duct-cannulated rats and dogs, MK-0524 was eliminated primarily via acyl glucuronidation followed by biliary excretion of the acyl glucuronide, M2, the major drug-related entity in bile.

Altered metabolism and mitochondrial genome in prostate cancer.

Mutations in mitochondrial DNA are frequent in cancer and the accompanying mitochondrial dysfunction and altered intermediary metabolism might contribute to, or signal, tumour pathogenesis. The metabolism of human prostate peripheral zone glandular epithelial cells is unique. Compared with many other soft tissues, these glandular epithelial cells accumulate high concentrations of zinc, which inhibits the activity of m-aconitase, an enzyme involved in citrate metabolism through Krebs cycle. This causes Krebs cycle truncation and accumulation of high concentrations of citrate to be secreted in prostatic fluid. The accumulation of zinc also inhibits terminal oxidation. Therefore, these cells exhibit inefficient energy production. In contrast, malignant transformation of the prostate is associated with an early metabolic switch, leading to decreased zinc accumulation and increased citrate oxidation. The efficient energy production in these transformed cells implies increased electron transport chain activity, increased oxygen consumption, and perhaps, excess reactive oxygen species (ROS) production compared with normal prostate epithelial cells. Because ROS have deleterious effects on DNA, proteins, and lipids, the altered intermediary metabolism may be linked with ROS production and accelerated mitochondrial DNA mutations in prostate cancer.

Mitochondrial function, zinc, and intermediary metabolism relationships in normal prostate and prostate cancer.

Human prostate secretory epithelial cells have the uniquely specialized function of accumulating and secreting extremely high levels of citrate. This is achieved by their ability to accumulate high cellular levels of zinc that inhibit citrate oxidation. This process of net citrate production requires unique metabolic/bioenergetic mitochondrial relationships. In prostate cancer, the malignant cells undergo a metabolic transformation from zinc-accumulating citrate-producing sane cells to citrate-oxidizing malignant cells that lost the ability to accumulate zinc. This review describes the metabolic/bioenergetic, zinc and mitochondrial relationships involved in normal and malignant prostate. Hopefully, this report will generate much needed interest and research in this neglected, but critically important, area of investigation.

Role of zinc in the pathogenesis and treatment of prostate cancer: critical issues to resolve.

The most consistent and persistent biochemical characteristic of prostate cancer (PCa) is the marked decrease in zinc and citrate levels in the malignant cells. This relationship provides compelling evidence that the lost ability of the malignant cells to accumulate zinc is an important factor in the development and progression of prostate malignancy. In addition, this relationship provides a rational basis for the concept that restoration of high zinc levels in malignant cells could be efficacious in the treatment and prevention of PCa. Epidemiological studies regarding dietary zinc effects on PCa have been conflicting and confusing. The purpose of this presentation is to present a current state of information regarding zinc relationships in the pathogenesis and treatment of PCa. We also hope to bring more attention to the medical and research community of the critical need for concerted clinical and basic research regarding zinc and PCa.

Differences in the metabolism and pharmacokinetics of two structurally similar PPAR agonists in dogs: involvement of taurine conjugation.

1. The metabolism and pharmacokinetics of two structurally similar PPAR agonists, MRL-I, (2R)-7-[3-[2-chloro-4-(4-fluorophenoxy)phenoxy]propoxy]-2-ethyl-3,4-dihydro-2H-benzopyran-2-carboxylic acid, and MRL-II, (2R)-7-[3-[2-chloro-4-(2,2,2,-trifluoroethoxy)phenoxy]propoxy]-3,4-dihydro-2-methyl-2H-benzopyran-2-carboxylic acid, in dogs were investigated. 2. MRL-I was absorbed rapidly in dogs and exhibited linear pharmacokinetics over the dose range examined, 1-25mgkg(-1). In contrast, the pharmacokinetics of MRL-II were non-linear following both intravenous and oral administration. 3. The acyl glucuronide (AG) conjugate was the only radioactive component detected in bile from dogs dosed with [14C]MRL-I, whereas bile from dogs dosed with [14C]MRL-II contained varying amounts of both the AG and taurine conjugates. The percentages of the acyl glucuronide and taurine conjugates of [14C]MRL-II in dog bile were dose dependent. A higher percentage of radioactivity was associated with the taurine conjugate (about 41%) following intravenous administration at 0.2mgkg(-1) than at 0.9mgkg(-1) (about 14%) or oral administration at 5 mgkg(-1) (about 6%). The decrease in the percentage of radioactivity associated with the taurine conjugate at 0.9 mgkg(-1) was accompanied by a concomitant increase in the amount of the acyl glucuronide. 4. MRL-I, but not MRL-II, was subject to significant enterohepatic recirculation in dogs. Continuous collection of bile resulted in an 11-fold decrease in the terminal half-life of MRL-I in plasma (1.5 versus 16.6 h), and a 2.4-fold increase in its plasma clearance (4.0 versus 1.7 ml min(-1) kg(-1)) after intravenous administration at 1 mg kg(-1). 5. Collectively, the data suggest that the presence and subsequent saturation of the taurine conjugation pathway might have contributed to the non-linear pharmacokinetics of MRL-II in the dog.

The effect of exogenous zinc ions on the pattern of oxygen consumption of the hepatic mitochondria of albino rats.

The effect of incubation of coupled liver mitochondria on varying concentration of zinc ion was determined. A low concentration of 6 microM zinc ion was found to inhibit the rate of oxygen consumption of the liver mitochondria significantly [P < 0.01]. There was uncoupling of the liver mitochondria when subjected to varying incubation periods. There was no change observed in the control experiment. Zinc-citrate inhibited the rate of oxygen consumption significantly [P < 0.01] when compare with the control. The changes observed in the Zn-aspartate were insignificant. Zn-EDTA had no inhibitory or stimulatory effect on the rate of liver mitochondrial oxygen consumption.

Metabolism and disposition of gemfibrozil in Wistar and multidrug resistance-associated protein 2-deficient TR- rats.

1. The roles of multidrug resistance-associated protein (Mrp) 2 deficiency and Mrp3 up-regulation were evaluated on the metabolism and disposition of gemfibrozil. 2. Results from in vitro studies in microsomes showed that the hepatic intrinsic clearance (CLint) for the oxidative metabolism of gemfibrozil was slightly higher (1.5-fold) in male TR- rats, which are deficient in Mrp2, than in wild-type Wistar rats, whereas CLint for glucuronidation was similar in both strains. 3. The biliary excretion of intravenously administered [14C]gemfibrozil was significantly impaired in TR-) rats compared with Wistar rats (22 versus 93% of the dose excreted as the acyl glucuronides over 72 h). Additionally, the extent of urinary excretion of radioactivity was much higher in TR- than in Wistar rats (78 versus 2.6% of the dose). 4. There were complex time-dependent changes in the total radioactivity levels and metabolite profiles in plasma, liver and kidney, some of which appeared to be related to the up-regulation of Mrp3. 5. Overall, it was demonstrated that alterations in the expression of the transporters Mrp2 and Mrp3 significantly affected the excretion as well as the secondary metabolism and distribution of [14C]gemfibrozil.

Human ZIP1 is a major zinc uptake transporter for the accumulation of zinc in prostate cells.

The prostate gland of humans and other animals accumulates a level of zinc that is 3-10 times greater than that found in other tissues. Associated with this ability to accumulate zinc is a rapid zinc uptake process in human prostate cells, which we previously identified as the hZIP1 zinc transporter. We now provide additional evidence that hZIP1 is an important operational transporter that allows for the transport and accumulation of zinc. The studies reveal that hZIP1 (SLC39A1) but not hZIP2 (SLC39A2) is expressed in the zinc-accumulating human prostate cell lines, LNCaP and PC-3. Transfected PC-3 cells that overexpress hZIP1 exhibit increased uptake and accumulation of zinc. The V(max) for zinc uptake was increased with no change in K(m). Along with the increased intracellular accumulation of zinc, the overexpression of hZIP1 also results in the inhibition of growth of PC-3 cells. Down-regulation of hZIP1 by treatment of PC-3 cells with hZIP1 antisense oligonucleotide resulted in a decreased zinc uptake. Uptake of zinc from zinc chelated with citrate was as rapid as from free zinc ions; however, the cells did not take up zinc chelated with EDTA. The cellular uptake of zinc is not dependent upon an available pool of free Zn(2+) ions. Instead, the mechanism of transport appears to involve the transport of zinc from low molecular weight ligands that exist in circulation as relatively loosely bound complexes with zinc.

Identification of novel metabolites of pioglitazone in rat and dog.

1. Four new metabolites of pioglitazone were identified by liquid chromatography-mass spectrometry (LC-MS/MS) as being formed by hydroxylation (M-VII and M-VIII), opening of the thiazolidinedione ring (M-X) and by desaturation of the terminal ethyl side chain or tether ethoxy moiety (M-IX), respectively. The structure of one of the hydroxylated metabolites (M-VII) was confirmed by chemical modification using the Jones reaction. 2. Oxidative cleavage of the thiazolidinedione ring is a novel pathway not previously reported for pioglitazone. 3. The hydroxylated M-VII was detected in incubations with rat, dog and human liver and kidney microsomes, and in plasma from rats and dogs dosed orally with [(3)H]pioglitazone. 4. The carboxylic acid derivative of M-VII (M-V) and its taurine conjugate were the major radioactive components in dog bile.

Testosterone and prolactin regulation of metabolic genes and citrate metabolism of prostate epithelial cells.

The control and alteration of key regulatory enzymes is a determinant of the reactions and pathways of intermediary metabolism in mammalian cells. An important mechanism in the metabolic control is the hormonal regulation of the genes associated with the transcription and the biosynthesis of these key enzymes. The secretory epithelial cells of the prostate gland of humans and other animals possess a unique citrate-related metabolic pathway regulated by testosterone and prolactin. This specialized hormone-regulated metabolic activity is responsible for the major prostate function of the production and secretion of extraordinarily high levels of citrate. The key regulatory enzymes directly associated with citrate production in the prostate cells are mitochondrial aspartate aminotransferase, pyruvate dehydrogenase, and mitochondrial aconitase. Testosterone and prolactin are involved in the regulation of the corresponding genes associated with these enzymes (which we refer to as "metabolic genes"). The regulatory regions of these genes contain the necessary response elements that confer the ability of both hormones to control gene transcription. In this report, we describe the role of protein kinase c (PKC) as the signaling pathway for the prolactin regulation of the metabolic genes in prostate cells. Testosterone and prolactin regulation of these metabolic genes (which are constitutively expressed in all mammalian cells) is specific for these citrate-producing cells. We hope that this review will provide a strong basis for future studies regarding the hormonal regulation of citrate-related intermediary metabolism. Most importantly, altered citrate metabolism is a persistent distinguishing characteristic (decreased citrate production) of prostate cancer (PCa) and also (increased citrate production) of benign prostatic hyperplasia (BPH). An understanding of the role of hormonal regulation of metabolism is essential to understanding the pathogenesis of prostate disease. The relationships described for the regulation of prostate cell metabolism provides insight into the mechanisms of hormonal regulation of mammalian cells in general.

Impact of dilution on microbial community structure and functional potential: comparison of numerical simulations and batch culture experiments.

A series of microcosm experiments was performed using serial dilutions of a sewage microbial community to inoculate a set of batch cultures in sterile sewage. After inoculation, the dilution-defined communities were allowed to regrow for several days and a number of community attributes were measured in the regrown assemblages. Based upon a set of numerical simulations, community structure was expected to differ along the dilution gradient; the greatest differences in structure were anticipated between the undiluted-low-dilution communities and the communities regrown from the very dilute (more than 10(-4)) inocula. Furthermore, some differences were expected among the lower-dilution treatments (e.g., between undiluted and 10(-1)) depending upon the evenness of the original community. In general, each of the procedures used to examine the experimental community structures separated the communities into at least two, often three, distinct groups. The groupings were consistent with the simulated dilution of a mixture of organisms with a very uneven distribution. Significant differences in community structure were detected with genetic (amplified fragment length polymorphism and terminal restriction fragment length polymorphism), physiological (community level physiological profiling), and culture-based (colony morphology on R2A agar) measurements. Along with differences in community structure, differences in community size (acridine orange direct counting), composition (ratio of sewage medium counts to R2A counts, monitoring of each colony morphology across the treatments), and metabolic redundancy (i.e., generalist versus specialist) were also observed, suggesting that the differences in structure and diversity of communities maintained in the same environment can be manifested as differences in community organization and function.

The intermediary metabolism of the prostate: a key to understanding the pathogenesis and progression of prostate malignancy.

This review emphasizes the importance and role of altered intermediary metabolism of prostate cells in the pathogenesis of prostate adenocarcinoma (PCa) and the progression of malignancy. The focus of the presentation is a summary of the overwhelming evidence which implicates the metabolic transformation of citrate-producing sane cells to citrate-oxidizing malignant cells in the process of malignancy. The evidence now demonstrates that altered zinc accumulation is an important factor in this transformation. These metabolic relationships are uniquely different from the metabolic alterations associated with tumorigenesis of other mammalian cells. The metabolic transformation of zinc-accumulating citrate-producing normal prostate epithelial cells to citrate-oxidizing malignant cells has important implications on cellular bioenergetics, cell growth and apoptosis, lipogenesis, angiogenesis. Based on the metabolic considerations new concepts concerning the pathogenesis, diagnosis and treatment of prostate malignancy are presented. Unfortunately the metabolism of the prostate has been a seriously neglected and largely ignored area of prostate research. The importance of expanded research into the intermediary metabolism of normal and neoplastic prostate is essential to future significant advances in understanding and dealing with PCa.

Zinc causes a shift toward citrate at equilibrium of the m-aconitase reaction of prostate mitochondria.

Prostate secretory epithelial cells have the unique function and capability of accumulating and secreting extraordinarily high levels of citrate. To achieve this, these cells possess a uniquely limiting mitochondrial (m)-aconitase activity that minimizes the oxidation of citrate via the Krebs cycle. The steady-state citrate/isocitrate ratio of mammalian tissues is generally maintained at about 10-11/l, independent of the concentration of citrate, which is the result of the chemical equilibrium reached in the presence of m-aconitase. In contrast, the citrate/isocitrate ratio of prostate tissue is about 30-40/l. Zinc, which is also accumulated in prostate cells at much higher levels than in other cells, inhibits m-aconitase activity thereby minimizing citrate oxidation. This current report is concerned with an effect of zinc on the equilibrium of the reaction catalyzed by m-aconitase. Studies were conducted with mitochondrial extract preparations from rat ventral prostate epithelial cells. With citrate as the initial substrate, the addition of zinc (7-10 microM) to the prostate mitochondrial preparation resulted in a change in the citrate/isocitrate ratio at equilibrium from an average of 10.5/l to 13.5/l. In contrast, the identical treatment of kidney mitochondrial preparations resulted in no zinc-induced change in the citrate/isocitrate ratio. When either cis-aconitate or isocitrate was employed as the initial substrate, the addition of zinc did not alter the citrate/isocitrate ratio of prostate or kidney preparations. Partial purification of the prostate preparation revealed that the prostate mitochondrial extract contained a putative protein (which we have designated as 'citrate factor protein') that is required for the zinc-induced increase in the citrate/isocitrate ratio. This novel effect of zinc provides another mechanism by which it is assured that the accumulation of citrate is maximized in citrate-producing prostate epithelial cells.

The pyruvate dehydrogenase E1 alpha gene is testosterone and prolactin regulated in prostate epithelial cells.

The prostate gland of humans and other animals has the unique function of accumulating and secreting extraordinarily high levels of citrate. The prostate secretory epithelial cells synthesize citrate which, due to a limiting mitochondrial (m-) aconitase, accumulates rather than being oxidized. Thus citrate is essentially an end product of metabolism in prostate. For continued net citrate production, a continual source of oxaloacetate (OAA) and acetyl CoA is required. Glucose via pyruvate oxidation provides the source of Acetyl CoA. In prostate cells, citrate production is regulated by testosterone and/or by prolactin. Both hormones selectively regulate the level and activity of pyruvate dehydrogenase E1 alpha (E1a) in animal prostate cells; thereby regulating the availability of acetyl CoA for citrate synthesis. Studies were conducted to determine if testosterone and prolactin might regulate the expression of the E1a gene in prostate epithelial cells. Prolactin treatment of rat ventral and lateral prostate cells and human PC3 cells increased the levels of E1a mRNA and the rates of transcription of the E1a gene. Testosterone also increased the mRNA level and transcription of E1a in rat ventral prostate cells, and in PC3 cells transfected with androgen receptor. However, testosterone treatment resulted in a repression of E1a gene expression in lateral prostate cells. Evidence is presented which supports the view that prolactin regulation of E1a is mediated via PKC. The rapidity of the effects of both hormones is representative of an immediate-early gene response. To our knowledge this represents the first report in any mammalian cells that, in addition to its constitutive expression in all mammalian cells, the E1a gene is a hormonally-regulated gene in specifically targeted prostate epithelial cells.

Mitochondrial aconitase gene expression is regulated by testosterone and prolactin in prostate epithelial cells .

BACKGROUND: m-aconitase catalyzes the first step leading to the oxidation of citrate via the Krebs cycle. It is a constituitive enzyme in virtually all mammalian cells, found in excess, and is considered to be a regulatory or regulated enzyme. In contrast to these general relationships, prostate secretory epithelial cells possess a uniquely limiting mitochondrial (m-) aconitase which minimizes the oxidation of citrate. This permits the unique prostate function of accumulating and secreting extraordinarily high levels of citrate. Previous animal studies demonstrated that testosterone and prolactin regulate the level of m-aconitase specifically in citrate-producing prostate cells. The present studies were conducted to determine if testosterone and prolactin regulated the expression of the m-aconitase gene in prostate cells, and to determine the effect of the hormones on human prostate cells. METHODS: The studies were conducted with freshly prepared rat ventral, rat lateral, and pig prostate epithelial cells, and with the human malignant cell lines LNCaP and PC-3. The effects of 1 nM testosterone and 3 nM prolactin on the level of m-aconitase mRNA and on the transcription rate of m-aconitase were determined. RESULTS: The studies revealed that both prolactin and testosterone increase the levels of m-aconitase mRNA and the transcription rates of m-aconitase in rat ventral prostate cells, pig prostate cells, and human malignant prostate cells (LNCaP and PC-3). In contrast, both hormones decreased the level of m-aconitase mRNA and repressed m-aconitase gene transcription in rat lateral prostate cells. The hormonal regulation of m-aconitase corresponded with the levels of m-aconitase enzyme, m-aconitase activity, and citrate oxidation. CONCLUSIONS: In addition to the constitutive expression of m-aconitase, the m-aconitase gene is testosterone- and prolactin-regulated in specifically targeted prostate cells. The hormonal regulation of m-aconitase gene expression and biosynthesis of m-aconitase provide a regulatory mechanism for the oxidation of citrate, and consequently, the level of net citrate production by prostate. The hormonally increased expression and biosynthesis of m-aconitase in human malignant cells might be involved in the increased citrate oxidation associated with the development of true malignant cells in prostate cancer.

Protein kinase C alpha, epsilon and AP-1 mediate prolactin regulation of mitochondrial aspartate aminotransferase expression in the rat lateral prostate.

Citrate accumulation and secretion are physiological functions of the prostate gland that are regulated by testosterone and prolactin. The metabolic pathway for citrate production in the prostate involves the activity of mitochondrial aspartate aminotransferase (mAAT). The expression of mAAT in the prostate is regulated by prolactin through a signal transduction pathway mediated by protein kinase C (PKC). In this report we determined which PKC isoforms are expressed in rat lateral prostate epithelial cells and their activation by prolactin. Eight PKC isoforms are expressed in the ventral and lateral prostate lobes. Although all eight isoforms are expressed, only PKCalpha and PKCvarepsilon were stimulated by prolactin and only in the lateral prostate lobe. Activator protein-1 (AP-1) appears to be the target of prolactin-PKC signaling because prolactin stimulated nuclear protein binding to an AP-1 consensus oligodeoxynucleotide. Moreover, the nuclear binding protein stimulated by prolactin also bound an mAAT oligodeoxynucleotide that contained an AP-1 consensus sequence and which competed for binding with the consensus AP-1 oligodeoxynucleotide. A PKCvarepsilon antisense oligodeoxynucleotide blocked expression of mAAT mRNA. Thus, we conclude that PKCvarepsilon is a specific PKC isoform that mediates via AP-1 the signal for prolactin regulation of mAAT gene expression in rat lateral prostate epithelial cells.

Inhibitory effect of zinc on human prostatic carcinoma cell growth.

BACKGROUND: Normal human prostate accumulates the highest levels of zinc of any soft tissue in the body. In contrast, the zinc level in prostate cancer is markedly decreased from the level detected in nonprostate tissues. Despite these relationships, the possible role of zinc in the growth of normal and malignant prostate has not been determined. METHODS: Growth inhibition and various regulatory responses were investigated in two human prostate carcinoma cell lines (LNCaP and PC-3), treated with or without zinc. RESULTS: Incubation of the prostate carcinoma cell lines with physiological levels of zinc resulted in the marked inhibition of cell growth. A lower 50% inhibition of cell growth (IC50) value for zinc (about 100 ng/ml) was detected in LNCaP cells, which are androgen-responsive, whereas androgen-independent PC-3 cells exhibited a higher IC50 for zinc (about 700 ng/ml). Incubation with 1 microg/ml zinc resulted in maximum inhibition of growth in both cell lines. These inhibitory effects of zinc correlated well with the accumulation of zinc in the cells. Simultaneously, cell flow cytometric analyses revealed a dramatic increase of the cell population in G2/M phase, in both LNCaP (2.3-fold vs. control) and PC-3 (1.9-fold vs. control), and a decreased proportion of cells in S phase (LNCaP, -51.4%; PC-3, -23%), indicating a G2/M phase arrest. The cell growth inhibition and G2/M arrest in these cells were accompanied by an increase in apoptosis, as demonstrated by the characteristic cell morphology and further confirmed by cellular DNA fragmentation. The specificity of zinc-induced apoptosis was identified by ethylenediamine-tetraacetic acid (EDTA)-chelation, which abolished the zinc effect on cellular DNA fragmentation. The zinc-induced G2/M phase arrest and apoptosis were accompanied by increased mRNA levels of p21(Waf1/Cip1/Sdi1) in both LNCaP (p53+/+) and PC-3 (p53-/-) cells. CONCLUSIONS: These results suggest that zinc inhibits human prostatic carcinoma cell growth, possibly due to induction of cell cycle arrest and apoptosis. There now exists strong evidence that the loss of a unique capability to retain high levels of zinc is an important factor in the development and progression of malignant prostate cells.