Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UMLS:C0376358 (prostate cancer)
 59,338 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The NKX3.1 transcription factor is an NK family homeodomain protein and a tumor suppressor gene that is haploinsufficient and down-regulated in the early phases of prostate cancer. Like its cardiac homolog, NKX2.5, NKX3.1 acts synergistically with serum response factor (SRF) to activate expression from the smooth muscle gamma-actin (SMGA) gene promoter. Using NMR spectroscopy, three conserved motifs in a construct containing the N-terminal region and homeodomain of NKX3.1 were observed to interact with the MADS box domain of SRF. These motifs interacted both in the absence of DNA and when both proteins were bound to a SMGA promoter DNA sequence. No significant interaction was seen between the homeodomain and SRF MADS box. One of the SRF-interacting regions was the tinman (TN) or engrailed homology-1 motif (EH-1), residues 29-35 (FLIQDIL), which for other NK proteins is the site of interaction with the repressor protein Groucho. A second hydrophobic interacting region was designated the SRF-interacting (SI) motif and included residues 99-105 (LGSYLLD). A third interacting motif was the acidic region adjacent to the SI motif including residues 88-96 (ETLAETEPE). The acidic domain (AD) motif signals also showed strengthening upon the NKX3.1 homeodomain binding to DNA in the absence of SRF, consistent with the acidic region weakly interacting with the homeodomain in the unbound state. The importance of these linear motifs in the transcriptional interaction of NKX3.1 and SRF was demonstrated by targeted mutagenesis of an NKX3.1 expression vector in a SMGA reporter assay. The results implicate the NKX3.1 N-terminal region in regulation of transcriptional activity of this tumor suppressor.
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PMID:Physical and functional interactions between the prostate suppressor homeoprotein NKX3.1 and serum response factor. 1681 6

NKX3.1 is a homeobox gene, expression of which is largely restricted to the adult prostatic epithelium. Loss of NKX3.1 expression has been linked to prostate carcinogenesis and disease progression and occurs in the absence of mutations in the coding region of the NKX3.1 gene. In this study, we have characterized regulation of NKX3.1 expression by all-trans retinoic acid (tRA), a naturally occurring vitamin A metabolite that is accumulated at high levels in the prostate. Using the prostate cancer cell line LNCaP, Western blot analysis revealed a approximately twofold induction of NKX3.1 protein levels following tRA exposure, with sequential analysis of NKX3.1 protein levels in cycloheximide co-treated cells indicating that tRA does not alter NKX3.1 protein turnover. The approximately 1.6-fold increase in NKX3.1 mRNA levels detected in tRA-treated LNCaP cells also occurred independently of new protein synthesis and was not mediated by changes in NKX3.1 mRNA stability. In contrast, nuclear run-on assays indicated that tRA treatment increased NKX3.1 transcription. To identify retinoid responsive regions of the NKX3.1 gene, DNA sequences encompassing approximately 2 kb of the NKX3.1 promoter or the entire 3'untranslated region (UTR) were cloned into luciferase reporter plasmids. Analysis of induced luciferase activity following transfection of these constructs into prostate cancer cells did not identify tRA responsiveness, however the 3'UTR was found to be strongly androgen responsive. These studies demonstrate that the NKX3.1 gene is a direct target of retinoid receptors and suggest that androgen regulation of NKX3.1 expression is mediated in part by the 3'UTR.
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PMID:Transcriptional regulation of the homeobox gene NKX3.1 by all-trans retinoic acid in prostate cancer cells. 1681 26

NKX3.1 is a homeobox gene located at chromosome 8p21.2, and one copy is frequently deleted in prostate carcinoma. Prior studies of NKX3.1 mRNA and protein in human prostate cancer and prostatic intraepithelial neoplasia (PIN) have been conflicting, and expression in focal prostate atrophy lesions has not been investigated. Immunohistochemical staining for NKX3.1 on human tissue microarrays was decreased in most focal atrophy and PIN lesions. In carcinoma, staining was inversely correlated with Gleason grade. Fluorescence in situ hybridization showed that no cases of atrophy had loss or gain of 8p, 8 centromere, or 8q24 (C-MYC) and only 12% of high-grade PIN lesions harbored loss of 8p. By contrast, NKX3.1 staining in carcinoma was correlated with 8p loss and allelic loss was inversely related to Gleason pattern. Quantitative reverse transcription-PCR for NKX3.1 mRNA using microdissected atrophy revealed a concordance with protein in five of seven cases. In carcinoma, mRNA levels were decreased in 6 of 12 cases but mRNA levels correlated with protein levels in only 4 of 12 cases, indicating translational or post-translational control. In summary, NKX3.1 protein is reduced in focal atrophy and PIN but is not related to 8p allelic loss in these lesions. Therefore, whereas genetic disruption of NKX3.1 in mice leads to PIN, nongenetic mechanisms reduce NKX3.1 protein levels early in human prostate carcinogenesis, which may facilitate both proliferation and DNA damage in atrophic and PIN cells. Monoallelic deletions on chromosome 8p are associated with more advanced invasive and aggressive disease.
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PMID:Decreased NKX3.1 protein expression in focal prostatic atrophy, prostatic intraepithelial neoplasia, and adenocarcinoma: association with gleason score and chromosome 8p deletion. 1710 5

Prostate cancer is a disease involving complicated multiple-gene alterations. Both NKX3.1 and p53 are related to prostate cancer and play crucial roles in prostate cancer progression. However, little is known about the relationships and interactions between p53 and NKX3.1 in prostate cancer. We found that NKX3.1 expression is down-regulated by over-expression of wild type (wt) p53 in prostate cancer LNCaP cells. NKX3.1 is down-regulated at both the mRNA and protein levels by p53 over- expression due to either transient transfection of exogenous p53 or induction of endogenous p53. p53 over-expression represses androgen-induced transactivation of NKX3.1 by inhibiting the promoter of the androgen acceptor (AR) gene and by blocking AR-DNA binding activity. In addition, transfection with the p21 expression vector (pPSA-p21) showed that p21 does not reduce NKX3.1 expression, indicating that NKX3.1 expression is not the result of nonspecific effects of cell growth arrest. Our results provide biochemical and cellular biologic evidence that NKX3.1 is down-regulated by p53 over-expression in prostate cancer cells.
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PMID:p53 overexpression represses androgen-mediated induction of NKX3.1 in a prostate cancer cell line. 1720 38

The prostate-specific homeodomain protein NKX3.1 is a tumor suppressor that is commonly down-regulated in human prostate cancer. Using an NKX3.1 affinity column, we isolated topoisomerase I (Topo I) from a PC-3 prostate cancer cell extract. Topo I is a class 1B DNA-resolving enzyme that is ubiquitously expressed in higher organisms and many prokaryotes. NKX3.1 interacts with Topo I to enhance formation of the Topo I-DNA complex and to increase Topo I cleavage of DNA. The two proteins interacted in affinity pull-down experiments in the presence of either DNase or RNase. The NKX3.1 homeodomain was essential, but not sufficient, for the interaction with Topo I. NKX3.1 binding to Topo I occurred independently of the Topo I NH2-terminal domain. The binding of equimolar amounts of Topo I to NKX3.1 caused displacement of NKX3.1 from its cognate DNA recognition sequence. Topo I activity in prostates of Nkx3.1+/- and Nkx3.1-/- mice was reduced compared with wild-type mice, whereas Topo I activity in livers, where no NKX3.1 is expressed, was independent of Nkx3.1 genotype. Endogenous Topo I and NKX3.1 could be coimmunoprecipitated from LNCaP cells, where NKX3.1 and Topo I were found to colocalize in the nucleus and comigrate within the nucleus in response to either gamma-irradiation or mitomycin C exposure, two DNA-damaging agents. This is the first report that a homeodomain protein can modify the activity of Topo I and may have implications for organ-specific DNA replication, transcription, or DNA repair.
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PMID:NKX3.1 homeodomain protein binds to topoisomerase I and enhances its activity. 1723 52

The high consumption of soy isoflavones in Asian diets has been correlated to a lower incidence of clinically important cases of prostate cancer. This study characterized the effects of a soy-derived isoflavone concentrate (ISF) on growth and gene expression profiles in the LNCaP, an androgen-sensitive human prostate cancer cell line. ISF caused a dose-dependent decrease in viability (P < 0.05) and DNA synthesis (P < 0.01), as well as an accumulation of cells in G(2)/M, and G(0)/G(1) phases of the cell cycle compared with controls. Using Affymetrix oligonucleotide DNA microarrays (U133A), we determined that ISF upregulated 80 genes and downregulated 33 genes (P < 0.05) involving androgen-regulated genes and pathways controlling cell cycle, metabolism, and intracellular trafficking. Changes in the expression of the genes of interest, identified by microarrays, were validated by Western immunoblot, Northern blot, and luciferase reporter assays. Prostate-specific antigen, homeobox protein NKX3, and cyclin B mRNA were significantly reduced, whereas mRNA was significantly upregulated for p21(CIP1), a major cell cycle inhibitory protein, and fatty acid and cholesterol synthesis pathway genes. ISF also significantly increased cyclin-dependent kinase inhibitor p27(KIP1) and FOXO3A/FKHRL1, a forkhead transcription factor. A differential pattern of androgen-regulated genes was apparent with genes involved in prostate cancer progression being downregulated by ISF, whereas metabolism genes were upregulated. In summary, we found that ISF inhibits the growth of LNCaP cells through the modulation of cell cycle progression and the differential expression of androgen-regulated genes. Thus, ISF treatment serves to identify new therapeutic targets designed to prevent proliferation of malignant prostate cells.
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PMID:Soy isoflavones exert differential effects on androgen responsive genes in LNCaP human prostate cancer cells. 1737 62

Human PCAN1 (prostate cancer gene 1) is a prostate-specific gene that is highly expressed in prostate epithelial tissue, and frequently mutated in prostate tumors. To better understand the regulation of the PCAN1 gene, a 2.6-kb fragment of its 5' flanking region was obtained by PCR. Its promoter activity was examined via the dual-luciferase reporter assay after it had been cloned into a pGL(3)-basic vector generating pGL(3)-p2.6 kb and transfected into LNCaP cells. pGL(3)-basic and pGL(3)-control were respectively used as the negative and positive controls. Sequence analysis with the MatInspector database showed that some possible binding sites for the transcriptional factors, NKX3.1, P53, SP1, cEBP and the PPAR/RXR heterodimers may locate on a 2.6-kb region upstream of the PCAN1 gene. To examine the relevant regulation of PCAN1, pGL(3)-p2.6 kb was transfected into the prostate cancer cell line LNCaP, which was treated with R1881 (10(-7) approximately 10(-9) mol/l), 17beta-estradiol (17beta-E(2), 10(-7) approximately 10(-9) mol/l), all-trans-retinoic acid (all-trans-RA, 10(-5) approximately 10(-7) mol/l) or 9-cis-retinoic acid (9-cis-RA, 10(-5) approximately 10(-7) mol/l), and eukaryotic expression plasmids of NKX3.1, p53, Sp1, Pten, PPARgamma or cEBPalpha were cotransfected with pGL(3)-p2.6 kb into LNCaP cells. pRL-TK, a Renilla luciferase reporter vector, was cotransfected into all the transfection lines as an internal control. The activities of pGL(3)-p2.6 kb (PCAN1 promoter) were analyzed via the dual-luciferase reporter assay 48 h after transfection. The results showed that 9-cis-RA enhanced the PCAN1 promoter activity in a dose-dependent manner, while R1881, 17beta-E(2) and all-trans-RA had no significant effect on PCAN1 promoter activities. Cotransfection with pGL(3)-p2.6kb and the expression plasmids of NKX3.1, p53, Sp1 or Pten respectively resulted in 1.66-, 2.48-, 2.00-and 1.72-fold 2.6 kb PCAN1 promoter activity increases relative to the controls, which were cotransfected with pcDNA3.1(+), while cotransfection of PPARgamma and cEBPalpha yielded no significant effect on PCAN1 promoter activities. These results could be applied for further study of the function and transcription regulation of the PCAN1 gene in prostate development and carcinogenesis.
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PMID:Molecular cloning and analysis of the human PCAN1 (GDEP) promoter. 1746 39

The epithelium-specific Ets transcription factor, PDEF, plays a role in prostate and breast cancer, although its precise function has not been established. In prostate cancer, PDEF is involved in regulating prostate-specific antigen expression via interaction with the androgen receptor and NKX3.1, and down-regulation of PDEF by antiproliferative agents has been associated with reduced PDEF expression. We now report that reduced expression of PDEF leads to a morphologic change, increased migration and invasiveness in prostate cancer cells, reminiscent of transforming growth factor beta (TGFbeta) function and epithelial-to-mesenchymal transition. Indeed, inhibition of PDEF expression triggers a transcriptional program of genes involved in the TGFbeta pathway, migration, invasion, adhesion, and epithelial dedifferentiation. Our results establish PDEF as a critical regulator of genes involved in cell motility, invasion, and adhesion of prostate cancer cells.
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PMID:Reduced PDEF expression increases invasion and expression of mesenchymal genes in prostate cancer cells. 1748 33

Prostate cancer incidence is steadily increasing in Western industrialized countries where it has become the most common male malignancy and second most common cause of cancer death among men. Despite efforts to understand the mechanisms of prostate cancer development and progression, the reasons for the disease remain unclear. Although recurrent DNA copy number aberrations in prostate cancer have been well documented in the past 15 years, most of the target genes for these aberrations remain to be identified. The most common DNA copy number aberrations are losses in chromosomes 5q, 6q, 8p, 10q, 13q, 16q, 17p, and 18q, and gains in 7p/q, 8q, 9p, and Xq. In addition, a chromosomal rearrangement in 21q has been observed in over 50% of prostate cancers. The target genes for two common chromosomal aberrations have been identified: the androgen receptor (AR) gene at Xq12, and TMPRSS2 and ERG at 21q. Putative target genes for other copy number aberrations include: NKX3-1 (8p loss), PTEN and MXI1 (10q loss), FOXO1A (13q loss), CDH1 and ATBF1 (16q loss), MCM7 and EZH2 (7q gain), TCEB1, EIF3S3 and MYC (8q gain). The identification of target genes for the chromosomal aberrations will provide new prognostic markers and therapeutic targets for future drug development.
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PMID:Chromosomal aberrations in prostate cancer. 1748 99

The histologic distinction between high-grade prostate cancer and infiltrating high-grade urothelial cancer may be difficult, and has significant implications because each disease may be treated very differently (ie, hormone therapy for prostate cancer and chemotherapy for urothelial cancer). Immunohistochemistry of novel and established prostatic and urothelial markers using tissue microarrays (TMAs) were studied. Prostatic markers studied included: prostate-specific antigen (PSA), prostein (P501s), prostate-specific membrane antigen (PSMA), NKX3.1 (an androgen-related tumor suppressor gene), and proPSA (pPSA) (precursor form of PSA). "Urothelial markers" included high molecular weight cytokeratin (HMWCK), p63, thrombomodulin, and S100P (placental S100). TMAs contained 38 poorly differentiated prostate cancers [Gleason score 8 (n=2), Gleason score 9 (n=18), Gleason score 10 (n=18)] and 35 high-grade invasive urothelial carcinomas from radical prostatectomy and cystectomy specimens, respectively. Each case had 2 to 8 tissue spots (0.6-mm diameter). If all spots for a case showed negative staining, the case was called negative. The sensitivities for labeling prostate cancers were PSA (97.4%), P501S (100%), PSMA (92.1%), NKX3.1 (94.7%), and pPSA (94.7%). Because of PSA's high sensitivity on the TMA, we chose 41 additional poorly differentiated primary (N=36) and metastatic (N=5) prostate carcinomas which showed variable PSA staining at the time of diagnosis and performed immunohistochemistry on routine tissue sections. Compared to PSA, which on average showed 18.8% of cells with moderate to strong positivity, cases stained for P501S, PSMA, and NKX3.1 had on average 42.5%, 53.7%, 52.9% immunoreactivity, respectively. All prostatic markers showed excellent specificity. HMWCK, p63, thrombomodulin, and S100P showed lower sensitivities in labeling high-grade invasive urothelial cancer in the TMAs with 91.4%, 82.9%, 68.6%, and 71.4% staining, respectively. These urothelial markers were relatively specific with only a few prostate cancers showing scattered (<or=2%) weak-moderate positive cells. In summary, PSA can be used as the first screening marker for differentiating high-grade prostate adenocarcinoma from high-grade urothelial carcinoma. Immunohistochemistry for P501S, PSMA, NKX3.1, and pPSA are useful when high-grade prostate cancer is suspected based on the morphology or clinical findings, yet shows negative or equivocal PSA staining. HMWCK and p63 are superior to the novel markers thrombomodulin and S100P.
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PMID:Immunohistochemical differentiation of high-grade prostate carcinoma from urothelial carcinoma. 1766 50


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