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1 cells); T24 (bladder carcinoma); and DU 145 (prostate carcinoma).
2 es of AFAP-110 in the tumorigenic process of prostate carcinoma.
3 ncer and serum prostate-specific antigen for prostate carcinoma.
4 patients with newly diagnosed and recurrent prostate carcinoma.
5 l neoplasia, and remaining at high levels in prostate carcinoma.
6 in the detection, staging, and restaging of prostate carcinoma.
7 FACBC is a promising radiotracer for imaging prostate carcinoma.
8 p21.2, and one copy is frequently deleted in prostate carcinoma.
9 carcinoma, the 3LL lung carcinoma, and RM-1 prostate carcinoma.
10 show that PDGF D and uPA colocalize in human prostate carcinoma.
11 feratve function of adaptor protein GRB10 in prostate carcinoma.
12 ncluding curative antitumor activity against prostate carcinoma.
13 MIC is widely expressed in prostate carcinoma.
14 It is called squamous cell prostate carcinoma.
15 ing diagnostic or therapeutic strategies for prostate carcinoma.
16 region that has been shown to be involved in prostate carcinoma.
17 nt improvement to targeted radiotherapies of prostate carcinoma.
18 sion molecule, acts as a tumor suppressor in prostate carcinoma.
19 he androgen-insensitive state of progressive prostate carcinoma.
20 l test to examine the relationship of PIN to prostate carcinoma.
21 ribute to the development and progression of prostate carcinoma.
22 ily of cytokines, plays an important role in prostate carcinoma.
23 ding glioblastoma, endometrial carcinoma and prostate carcinoma.
24 rable disease control for men with high-risk prostate carcinoma.
25 iR-106b dependent downregulation of RBMS1 in prostate carcinoma.
26 o upregulated, and miR-107 downregulated, in prostate carcinoma.
27 vide high contrast in a mouse model of human prostate carcinoma.
28 molog (PTEN) is frequently involved in human prostate carcinoma.
29 astases from orthotopically implanted PC3LN3 prostate carcinoma.
30 movement are commonly mutated or deleted in prostate carcinomas.
31 c hyperplasia but significantly increased in prostate carcinomas.
32 ility for developing aggressive, spontaneous prostate carcinomas.
33 applied to an independent set of 30 primary prostate carcinomas.
34 xpressing tumor cells in invasive breast and prostate carcinomas.
35 minished the apoptotic effect of Ad.mda-7 in prostate carcinomas.
36 ed staining method for the identification of prostate carcinomas.
37 expression is lost in metastatic bladder and prostate carcinomas.
38 and numerically abnormal in the majority of prostate carcinomas.
39 uring transformation, as well as in advanced prostate carcinomas.
40 ll malignant human cancers, including 90% of prostate carcinomas.
41 peripheral zone and primary peripheral zone prostate carcinomas.
42 quired for mda-7/IL-24-mediated apoptosis of prostate carcinomas.
43 icity as seen in advanced hormone-refractory prostate carcinomas.
44 tions of IRDye 800CW 2-DG for epithelial and prostate carcinomas.
45 = 21), compared with levels in patients with prostate carcinoma (0.12 +/- 0.03 ng/mg U(Cr); P < 0.02;
46 ects of apigenin on androgen-sensitive human prostate carcinoma 22Rv1 tumor xenograft subcutaneously
50 pha and EBV LMP1 enhance XMRV replication in prostate carcinoma and B-lineage cells through the kappa
52 One of these variants was identified in a prostate carcinoma and is altered from isoleucine to met
53 etide SPECT/CT in the detection of recurrent prostate carcinoma and is highly accurate in the differe
54 One hundred four men with newly diagnosed prostate carcinoma and no previous therapy were included
55 nhibits progression to poorly differentiated prostate carcinoma and pulmonary metastasis multiplicity
56 developed from a nodal metastasis of a human prostate carcinoma and that has been propagated as seria
57 patients are at risk for developing advanced prostate carcinoma and therefore would gain the most fro
59 ents who had metastatic castration-resistant prostate carcinoma and who had exhausted available thera
60 tor inhibitor-1 promoter (in NRP-154 and PC3 prostate carcinoma and WPMY-1 prostate myofibroblast cel
62 NKX3.1 protein expression is common in human prostate carcinomas and prostatic intraepithelial neopla
63 and restricted expression on the surface of prostate carcinomas and the neovasculature of most other
64 nd tissue microarrays demonstrates that both prostate carcinomas and the presumed precursor lesion (h
65 or androgen deprivation in hormone-dependent prostate carcinoma, and it has been examined as a chemop
67 ternative source of cAMP, was found in human prostate carcinoma, and therefore, the contribution of t
68 terolemia directly accelerates the growth of prostate carcinomas, and that the pharmacological reduct
69 ls of a neuroendocrine/small cell variant of prostate carcinoma are available for experimental studie
72 setting of earlier detection, a majority of prostate carcinomas are still clinically localized and o
73 a/K-ATPase is significantly reduced in human prostate carcinoma as well as in several human cancer ce
74 (FAS) has been found to be overexpressed in prostate carcinomas, as well as other cancers, and it is
75 tion data of (125)I-labeled ligands in human prostate carcinoma bearing (PC-3) mice revealed two comp
76 U118 (human glioblastoma), and DU145 (human prostate carcinoma), but not that of M14-Mel xenografts
79 an +/-s.d.), and results in human breast and prostate carcinoma cell arrest and retention in the micr
80 ostate tumor growth and drastically enhances prostate carcinoma cell interaction with surrounding str
81 In this report, we characterized the human prostate carcinoma cell line 22Rv1 in an orthotopic syst
82 sion, using as our model the PA DU-145 human prostate carcinoma cell line and a highly invasive subli
83 excellent in vitro uptake within the DU-145 prostate carcinoma cell line and orthotopically implante
85 ma incidence, restoration of expression in a prostate carcinoma cell line homozygous for the frameshi
87 d differential display analysis of the human prostate carcinoma cell line PC-3 and its highly metasta
95 ave observed HSP70 release from intact human prostate carcinoma cell lines (PC-3 and LNCaP) by a mech
96 ecreted MDA-7/IL-24 in inducing apoptosis in prostate carcinoma cell lines and displayed transformed
100 ibitor, significantly inhibited migration of prostate carcinoma cell lines, demonstrating that tumor
101 ates tumor metastasis, we used two different prostate carcinoma cell lines, DU145 and PC3, in which t
102 kDa PRL transfection in DU145 and PC-3 human prostate carcinoma cell lines, we demonstrated that expr
103 1A promoter was observed in five widely used prostate carcinoma cell lines, which acquired the abilit
104 silencing of RASSF1A was found in four other prostate carcinoma cell lines, which were adapted for ce
108 odel showed that some rapidly promoted LNCaP prostate carcinoma cell tumorigenesis and others had no
109 omote angiogenesis and growth of LNCaP human prostate carcinoma cell tumors, and that these increases
110 e epithelial cells (PZ-HPV-7); several human prostate carcinoma cells (22Rv1, DU145, LNCaP, and PC3);
111 oration of CEACAM1(a)-4L expression in human prostate carcinoma cells (PC-3) suppresses tumorigenicit
113 NV1023 had significant oncolytic effect on prostate carcinoma cells (PC3, DU145, and LNCap) in vitr
116 , we show that androgen deprivation of human prostate carcinoma cells activates the small GTPase, Ral
118 of wild-type p53 with increased survival of prostate carcinoma cells after fractionated exposure to
119 ted the suppression of GSK-3beta activity in prostate carcinoma cells and enhanced the turnover of be
120 esions because of high expression of PSMA in prostate carcinoma cells and in bone metastases and lymp
121 (3-Cl-AHPC), induces apoptosis in breast and prostate carcinoma cells and inhibits AKT activity in th
125 in both human normal prostate epithelial and prostate carcinoma cells as well as in clinical prostate
126 egulation of NAG-1 expression in LNCaP human prostate carcinoma cells by 12-O-tetradecanoylphorbol-13
127 by MT1-MMP enhanced the migration of DU-145 prostate carcinoma cells by 2-fold compared with uncleav
128 MMP-9) activation promoted invasion of human prostate carcinoma cells by dissolving basement membrane
129 ndicate that EGCG induces apoptosis in human prostate carcinoma cells by shifting the balance between
130 The growth of normal prostate as well as of prostate carcinoma cells depends on functional androgen
132 to identify gene expression changes in LNCaP prostate carcinoma cells exposed to PC-SPES and estrogen
134 ilencing in vitro and extend tests to target prostate carcinoma cells following systemic administrati
135 ditional PLCgamma1 knockdown in PC3LN3 human prostate carcinoma cells for further evaluation of PLCga
136 vivo, and in vivo that metastatic breast and prostate carcinoma cells form multicellular homotypic ag
137 of highly malignant viable circulating human prostate carcinoma cells from orthotopic but not ectopic
138 d hormone-related protein) overexpression by prostate carcinoma cells has been implicated in tumor pr
140 vo model of NI was established by implanting prostate carcinoma cells in the sciatic nerves of nude m
141 ous than sequential treatment in human DU145 prostate carcinoma cells infected with an adenovirus con
142 density the migration speed of DU-145 human prostate carcinoma cells is a balance between tractile a
143 show that N-cadherin mRNA expression in PC-3 prostate carcinoma cells is dependent on beta(1) integri
144 ven by the CDKN1A and CDH1 promoters in PC-3 prostate carcinoma cells is sensitive to treatment with
148 c approach and generated an isogenic pair of prostate carcinoma cells PC3 (p53-/-) by stably introduc
149 Fas expression and converting Fas-sensitive prostate carcinoma cells PC3 into Fas-resistant ones.
151 F4/p130 association after IR was observed in prostate carcinoma cells regardless of their sensitivity
152 r prostate stromal cells cotransplanted with prostate carcinoma cells s.c. into nude mice reduced tum
154 TGFbeta and the medium conditioned by the prostate carcinoma cells stimulated myofibroblast differ
155 s increased and accumulated in the nuclei of prostate carcinoma cells subjected to ionizing radiation
156 d receptor expressed at the surface of human prostate carcinoma cells that plays central roles in ang
157 y be responsible for enhanced sensitivity of prostate carcinoma cells to a variety of anticancer trea
159 sitized the apoptotic response of breast and prostate carcinoma cells to various drugs, ranging from
160 SAT was conditionally overexpressed in LNCaP prostate carcinoma cells via a tetracycline-regulatable
166 n were internalized by Siglec-XII-expressing prostate carcinoma cells, allowing targeting of a toxin
167 We show here that EGR1 binds to the AR in prostate carcinoma cells, and an EGR1-AR complex can be
168 MMP-9, highly invasive and metastatic human prostate carcinoma cells, androgen-repressed prostate ca
169 ceptor 1 (FGFR1) is ectopically expressed in prostate carcinoma cells, but its functional contributio
171 transfection prevented the proliferation of prostate carcinoma cells, led to lactate dehydrogenase r
172 SRB12-p9 skin SCC cells, as well as with PC3 prostate carcinoma cells, revealed that RXRalpha transcr
174 ydrazine (laromustine)-resistant DU145 human prostate carcinoma cells, which express high levels of A
175 n specifically induced in vitro apoptosis in prostate carcinoma cells, with innate resistance to chem
210 ssociated with an increased risk of advanced prostate carcinoma compared with the CC genotype [odds r
211 ) signaling persists in castration-resistant prostate carcinomas (CRPC), because of several mechanism
212 the cytotoxicity of PG, EGCG and Q to human prostate carcinoma DU-145 cells, since catalase increase
213 milk thistle extract, against advanced human prostate carcinoma DU145 cells and later identified that
215 e NE cell population is greatly increased in prostate carcinomas during androgen ablation therapy tha
217 n cultured human cancer cells (glioblastoma, prostate carcinoma, Ewing's sarcoma), HCR transduction m
219 ETV1, a JMJD2A-binding protein, resulted in prostate carcinoma formation in mice haplodeficient for
220 d that the levels of MMP-26 protein in human prostate carcinomas from multiple patients were signific
222 We report here that hormone-refractory human prostate carcinoma growing orthotopically efficiently de
224 s AGS (gastric carcinoma), DU-145 and LNCaP (prostate carcinoma), HCT-116 (colon carcinoma), MCF-7 (b
226 , PC-3, ND-1, DU-145, 22Rv1, and one primary prostate carcinoma immortalized by overexpression of the
227 metric MR imaging for detection of recurrent prostate carcinoma in patients with suspected recurrence
229 ation of PKCzeta in mice results in invasive prostate carcinoma in vivo in the context of phosphatase
230 against orthotopically implanted LNCaP human prostate carcinomas in male nude mice and orthotopically
232 hough SIGLEC12 allele status did not predict prostate carcinoma incidence, restoration of expression
236 DU-145 cells, an E-cadherin expressing human prostate carcinoma line, survive loss of integrin-depend
237 bits the growth of androgen-responsive human prostate carcinoma LNCaP cells and provide molecular und
238 report that EGCG-induced apoptosis in human prostate carcinoma LNCaP cells is mediated via modulatio
240 s efficiently than the wild-type XMRV in the prostate carcinoma LNCaP, DU145, and PC-3 cell lines, HE
241 iferative activity against hormone dependent prostate carcinoma LNCaP, with an IC50 value 3 times low
243 ia an MET-dependent pathway; however, in two prostate carcinoma models, metastatic colonization was M
244 Fifteen patients with a recent diagnosis of prostate carcinoma (n = 9) or suspected recurrence (n =
245 expression in normal prostate tissue and in prostate carcinoma of increasing Gleason grades in paraf
246 timal markers were also measured for Dunning prostate carcinomas of anaplastic (RHF = 15%-20%) and we
247 er ADAM9 is critical for the pathogenesis of prostate carcinoma, one of the most common cancers in me
248 l (nanocurie) levels into mice bearing solid prostate carcinoma or disseminated human lymphoma induce
250 or when inoculated with metastatic melanoma, prostate carcinoma, or mammary carcinoma cell lines.
252 nce with a series of 73 castration-resistant prostate carcinoma patients treated with (225)Ac-PSMA-61
255 r (AR) signaling is a distinctive feature of prostate carcinoma (PC) and represents the major therape
256 titutively activated in androgen-independent prostate carcinoma (PC) cell lines due to the upregulate
257 roles in prostate tumorigenesis: AR promotes prostate carcinoma (PC) development, whereas GR acts as
258 wing sarcoma (Rh1), glioblastoma (U-373) and prostate carcinoma (PC-3) cells, and concurrently inhibi
259 migration of ovarian carcinoma (SKOV-3) and prostate carcinoma (PC-3) were examined following treatm
261 ancer 1) tumor-suppressor gene in metastatic prostate carcinoma (PCA) cells increased the expression
266 c membrane antigen (PSMA), expressed by most prostate carcinomas (PCa), is a promising target for PCa
268 eminating variants of human fibrosarcoma and prostate carcinoma recruit elevated levels of infiltrati
269 ion, DLC-3 expression was reduced in primary prostate carcinomas relative to normal prostate tissue.
272 an immunohistochemical analysis of 126 human prostate carcinoma samples using polyclonal anti-NGEP se
278 Differential display of mRNA expression in prostate carcinoma sublines with varying metastatic pote
279 d expression of beta-catenin associated with prostate carcinoma suggests a role for beta-catenin in p
282 Two hundred seventy four patients with pT3 prostate carcinoma treated by radical prostatectomy and
283 astoma, and human DU145 androgen-independent prostate carcinoma tumor cells indicated that both compo
286 n 5 were investigated in normal and invasive prostate carcinoma using immunohistochemistry, Northern
287 ause the prognosis of histologically similar prostate carcinomas varies, thus creating a need to pred
289 of the following criteria: (a) Recurrence of prostate carcinoma was suspected after definitive therap
290 own efficacy as a single agent against human prostate carcinoma, we evaluated 2ME2 as a potential rad
291 nces and chemoresistance in lung, colon, and prostate carcinoma, we hypothesized that 14-3-3zeta prom
292 hods: In total, 280 men with newly diagnosed prostate carcinoma were included in the present study.
293 5-85 y) with metastatic castration-resistant prostate carcinoma were treated with 210 cycles of (225)
295 de that oncolytic therapy effectively treats prostate carcinomas with NI in an in vivo murine model w
296 hypoacetylation at this site is observed in prostate carcinomas with poor prognosis, this suggests t
297 hormone-independent (DU-145 and PC-3) human prostate carcinomas, without altering growth or survival
298 nanoparticles towards glioblastoma (GBM) and prostate carcinoma xenograft lesions in nude mice (eight
299 We report a human neuroendocrine/small cell prostate carcinoma xenograft that was developed from a n