Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UMLS:C0027819 (neuroblastoma)
 27,800 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Replication and encapsidation of measles virus (MV) requires the interaction between the nuclear protein (N) and the phosphoprotein (P). It is known that both proteins are phosphorylated on serine and threonine residues. Recently we have shown that N is phosphorylated on tyrosine in persistently-infected mouse neuroblastoma cells (NS20Y/MS). Here, we show that P in NS20Y/MS is also phosphorylated on tyrosine. To investigate whether cellular tyrosine kinases can bind and phosphorylate P, a solid phase kinase assay was employed. We show that bacterially-expressed MV P fragments, were phosphorylated on tyrosine by purified mouse c-Src protein-tyrosine kinase and when mixed with uninfected neuroblastoma cell (NS20Y) extracts, these P fragments were phosphorylated on tyrosine in addition to serine and threonine. These results imply that MV P is a substrate for tyrosine phosphorylation by cellular tyrosine kinase(s).
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PMID:Tyrosine phosphorylation of measles virus P-phosphoprotein in persistently infected neuroblastoma cells. 903 64

To evaluate the role of estrogen receptor in the differentiation of cells of neural origin, we developed a molecular approach aimed at the identification of estrogen target genes by mRNA differential display PCR (ddPCR) in human neuroblastoma SK-ER3 cells. More than 3000 RNAs were examined, a few of which displayed a differential regulation pattern in response to 17beta-estradiol (E2). Sequence analysis of three differentially amplified ddPCR products showed homology with the growth-associated nuclear protein prothymosin-alpha (PTMA), the Bcl2-interacting protein Nip2, and one mRNA previously described by others in fetal human brain. Two ddPCR products, referred to as P4 and P10, corresponded to new DNA sequences. Northern analysis confirmed that estrogen treatment of SK-ER3 cells resulted in the upregulation and downregulation of expression of these messages. In particular, PTMA was found to accumulate at both 1 and 17 hr after E2 treatment, whereas P10 product accumulated only at 1 hr. Conversely, P4, Nip2, and the fetal brain-related mRNAs were significantly decreased by the treatment. Further time course analysis of PTMA and Nip2 mRNAs levels indicated that the hormone exerted a marked biphasic regulatory effect on expression of both messages during the course of cell differentiation. In the present study we report for the first time the identification of a panel of estrogen target genes in neural cells that provide new insights in the molecular mechanism of action of E2 in cells of neural origin.
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PMID:Identification of estrogen-responsive genes in neuroblastoma SK-ER3 cells. 916 20

Autotaxin (ATX) is a newly found autocrine tumor cell motility-stimulating factor. ATX is a member of the ecto-phosphodiesterase I (PD-I)/ nucleotide pyrophosphatase family. PD-Ialpha was found as a brain-type ecto-phosphodiesterase I/nucleotide pyrophosphatase. ATX and PD-Ialpha are alternative splicing products from one gene. ATX stimulates motility of A2058 melanoma cells in vitro; however, it has not been known if PD-Ialpha/ATX is expressed in naturally occurred human tumors. In this study, we examined the expression of the human PD-Ialpha/ATX gene in human neuroblastoma tumor tissues and the motility stimulating activity of recombinant ATX on neuroblastoma cells and investigated its transcriptional regulatory mechanism in a human neuroblastoma cell line. The PD-Ialpha/ATX gene was expressed in the primary tumor tissues from neuroblastoma patients to varying degrees. This gene is also expressed in the SMS-KAN neuroblastoma cell line. We identified both isoforms, PD-Ialpha and ATX, in these tumor tissues and SMS-KAN cells. The recombinant ATX stimulated the motility of SMS-KAN cells at low nanomolar concentration. We situated the promoter region, which is essential for its transcription in SMS-KAN cells, at -287 to -254 nucleotides by the promoter activity assay. The gel-shift assay revealed that there exists a nuclear protein in SMS-KAN cells that binds this region. These new insights about autocrine tumor cell motility-stimulating protein will help us to understand the metastatic mechanism of human neuroblastoma.
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PMID:Expression and transcriptional regulation of the PD-Ialpha/autotaxin gene in neuroblastoma. 919 34

The potent neurotrophic factor glial cell-derived neurotrophic factor (GDNF) is a distant member of the transforming growth factor-beta (TGF-beta) superfamily of proteins. We report a transcription factor that is the first nuclear protein known to be induced by GDNF, thus designated murine GDNF inducible factor (mGIF). The cDNA was cloned in the course of investigating transcription factors that bind to Sp1 consensus sequences, using the in situ filter detection method, and it was found to encode a protein having the same C2-H2 zinc finger motif as Sp1. Sequence analysis indicated that mGIF is homologous to the human TGF-beta inducible early gene (TIEG) and human early growth response gene-alpha (EGR-alpha). mGIF is widely distributed in the adult mouse with high mRNA levels in kidney, lung, brain, liver, heart, and testis. In the adult brain, mGIF is abundantly expressed in hippocampus, cerebral cortex, cerebellum, and amygdala with lower amounts in striatum, nucleus accumbens, olfactory tubercle, thalamus, and substantia nigra. During development, mGIF mRNA also has a wide distribution, including in cerebral cortex, cerebellar primordium, kidney, intestine, liver, and lung. GDNF induces the expression of mGIF rapidly and transiently both in a neuroblastoma cell line and in primary cultures of rat embryonic cortical neurons. Co-transfection of the Drosophila SL2 cells using mGIF expression plasmid and reporter constructs having Sp1 binding sites indicated that mGIF represses transcription from a TATA-containing as well as from a TATA-less promoter. These observations suggest that the zinc finger transcription factor mGIF could be important in mediating some of the biological effects of GDNF.
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PMID:Cloning and characterization of murine glial cell-derived neurotrophic factor inducible transcription factor (MGIF). 934 34

The vasoactive intestinal peptide cytokine response element (VIP CyRE) is responsible for mediating the transcriptional induction of the VIP gene to the neuropoietic cytokines leukemia inhibitory factor (LIF) and ciliary neurotrophic factor (CNTF). In investigating the sequence and function of the CyRE, we found a region of DNA with homology to the distal NFAT site in the IL-2 promoter. In this paper we characterize this sequence and show that the VIP NFAT site recognizes T cell NFAT with similar affinity to the previously characterized IL-2 NFAT site. However, despite its location in the middle of the CyRE, we find no CNTF/LIF induced binding to it. Instead we show that in NBFL neuroblastoma cells, the calcium ionophore A23187 induces a protein to bind to the VIP NFAT site. This A23187-mediated induction of nuclear protein binding to an NFAT oligonucleotide is dependent on extracellular calcium but not dependent on de novo protein synthesis. Thus, this protein has the characteristics of an NFAT-like protein and is recognized by an NFAT3-specific antiserum suggesting that it is indeed an NFAT protein. The location of the NFAT site in the VIP CyRE suggests that this may be one mechanism through which different signaling pathways engage in cross talk to alter VIP gene transcription.
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PMID:NFAT interactions with the vasoactive intestinal peptide cytokine response element. 955 32

Cyclooxygenase-2 (COX-2; EC 1.14.99.1) RNA message abundance in 25 control and Consortium to Establish a Registry for Alzheimer's Disease (CERAD)-confirmed sporadic Alzheimer's disease (AD) brains is remarkably heterogeneous when compared with 55 other AD brain RNA message levels that were previously characterized (Lukiw and Bazan: J Neurosci Res 50:937-945, 1997). Examination of nuclear protein extracts (NPXTs) that were derived from control and AD-affected brain neocortical nuclei (n = 20; age range, 60-82 years; postmortem interval, 0.5-6.5 hours) by using gel shift, gel supershift, and cold oligonucleotide competition assay revealed a highly significant relationship between the extent of inflammatory transcription factor, nuclear factor (NF)-kappaB: DNA binding and the abundance of the COX-2 RNA signal (P < 0.0001; analysis of variance). No strong correlation with AP-1-DNA binding was noted (P > 0.045). These data are the first linking inflammation-related transcription factor NF-KB-DNA binding to up-regulation of transcription from a key inflammatory gene, COX-2, in both normally aging brain and in AD-affected neocortex. Systematic deletion of NF-KB-DNA binding sites in human COX-2 promoter constructs attenuates COX-2 transcriptional induction by mediators of inflammation. Strong NF-kappaB-DNA binding has been reported previously to temporally precede COX-2 gene transcription in human epithelial (A549), hamster B-cell (HIT-T15), human endothelial (HUVEC), human lymphoblast (IM9), human fibroblast (IMR90), rat glioma/mouse neuroblastoma (NG108-15), human keratinocyte (NHEK), mouse fibroblast (NIH 3T3), rat neuroblastoma (SH-SY5Y) cell lines and in mouse and rat brain hippocampus, indicating a highly conserved inflammatory signaling pathway that is common to diverse species and cell types. The mouse, rat, and human COX-2 immediate promoters, despite 7.5 x 10(7) years of DNA sequence divergence, each retain multiple recognition sites specific for NF-kappaB-DNA binding. These data suggest that basic gene induction mechanisms, which have been conserved over long periods of evolution, that increase NF-kappaB-DNA binds ing may be fundamental in driving transcription from inflammation-related genes, such as COX-2, that operate in stressed tissues, in normally aging cell lines, and in neurodegenerative disorders that include AD brain.
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PMID:Strong nuclear factor-kappaB-DNA binding parallels cyclooxygenase-2 gene transcription in aging and in sporadic Alzheimer's disease superior temporal lobe neocortex. 972 29

The subcellular location of aluminium is unknown, probably because of difficulties in investigating aluminium biochemistry and the use of varied experimental approaches of uncertain sensitivity. We have studied levels of uptake and the localization of gallium and of aluminium in cultured human neuroblastoma cells treated with soluble metal complexes (mainly Al- or Ga-EDTA), radiolabeled with 26Al or 67Ga, respectively. Crude nuclei and cytoplasm were obtained by two separate methods, and DNA, RNA, and proteins were prepared from the nuclei by centrifugation in high salt; also, cytosol and noncytosol were separated using a nondissociating method. Levels of uptake were of similar order for the two metals-on average about 50 pmol/10(6) cells for aluminium and 120 pmol/10(6) cells for gallium, after 4 to 8 days treatment at 250 microM, and approximately 50 to 70% of the metal was found in the cytosol. About 20% of the aluminium and 10 to 25% of the gallium was associated with nuclear protein. A lower proportion was bound to DNA and to nuclear RNA. In cells treated with gallium-citrate/transferrin mixtures, 30 to 35% of the gallium in the cytosol was bound to protein, at least 35 being loosely bound; the main gallium-associated protein was probably intracellular transferrin. The remaining 65 to 70% of the metal in the cytosol was in low-molecular-weight form, and we suggest that the latter metal could affect structures such as the cytoskeleton and also metabolic processes in the cytoplasm. The similarity in distribution of the two metals supports the use of gallium as a "surrogate" for aluminium, at least in cell culture studies.
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PMID:Location of aluminium and gallium in human neuroblastoma cells treated with metal-chelating agent complexes. 977 10

The candidate tumor-suppressor gene ING1 encodes p33(ING1), a nuclear protein which physically interacts with TP53. It has been shown that p33(ING1) acts in the same biochemical pathway as TP53, leading to cell growth inhibition. Interestingly, a rearrangement of the ING1 gene was found in a neuroblastoma cell line, supporting its involvement in tumor development. Because ING1 resides on the long arm of chromosome 13 (13q34) (a region frequently deleted in many tumor types), we sought to characterize its role in head and neck squamous-cell carcinoma (HNSCC). We first analyzed 44 primary tumors for loss of heterozygosity (LOH) at 13q, using four widely spaced microsatellite markers (13q14, 13q14.3-q22, 13q22, and 13q34). Twenty (48%) of the tumor samples showed LOH in all of the informative markers tested, including D13S1315 at 13q34. Two of the tumors displayed partial losses restricted to one marker (D13S118 at 13q14 in tumor 1164, and D13S135 at 13q14.3-q22 in tumor 1398). We then determined the genomic structure of the ING1 gene and sequenced the entire coding region in 20 primary tumors showing 13q LOH and in five head and neck cancer cell lines. A single germline polymorphism was detected in 10 of the tumors analyzed (T to C change) located 110 nucleotides upstream of the starting methionine. No somatic mutations were found in any of the samples, suggesting that ING1 is not a tumor suppressor gene target in head and neck cancer. Genes Chromosomes Cancer 27:319-322, 2000.
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PMID:Molecular analysis of the candidate tumor suppressor gene ING1 in human head and neck tumors with 13q deletions. 1067 22

RGS proteins comprise a family of proteins named for their ability to negatively regulate heterotrimeric G protein signaling. Biochemical studies suggest that members of this protein family act as GTPase-activating proteins for certain Galpha subunits, thereby accelerating the turn-off mechanism of Galpha and terminating signaling by both Galpha and Gbetagamma subunits. In the present study, we used confocal microscopy to examine the intracellular distribution of several RGS proteins in COS-7 cells expressing RGS-green fluorescent protein (GFP) fusion proteins and in cells expressing RGS proteins endogenously. RGS2 and RGS10 accumulated in the nucleus of COS-7 cells transfected with GFP constructs of these proteins. In contrast, RGS4 and RGS16 accumulated in the cytoplasm of COS-7 transfectants. As observed in COS-7 cells, RGS4 exhibited cytoplasmic localization in mouse neuroblastoma cells, and RGS10 exhibited nuclear localization in human glioma cells. Deletion or alanine substitution of an N-terminal leucine repeat motif present in both RGS4 and RGS16, a domain identified as a nuclear export sequence in HIV Rev and other proteins, promoted nuclear localization of these proteins in COS-7 cells. In agreement with this observation, treatment of mouse neuroblastoma cells with leptomycin B to inhibit nuclear protein export by exportin1 resulted in accumulation of RGS4 in the nucleus of these cells. GFP fusions of RGS domains of RGS proteins localized in the nucleus, suggesting that nuclear localization of RGS proteins results from nuclear targeting via RGS domain sequences. RGSZ, which shares with RGS-GAIP a cysteine-rich string in its N-terminal region, localized to the Golgi complex in COS-7 cells. Deletion of the N-terminal domain of RGSZ that includes the cysteine motif promoted nuclear localization of RGSZ. None of the RGS proteins examined were localized at the plasma membrane. These results demonstrate that RGS proteins localize in the nucleus, the cytoplasm, or shuttle between the nucleus and cytoplasm as nucleo-cytoplasmic shuttle proteins. RGS proteins localize differentially within cells as a result of structural differences among these proteins that do not appear to be important determinants for their G protein-regulating activities. These findings suggest involvement of RGS proteins in more complex cellular functions than currently envisioned.
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PMID:Cytoplasmic, nuclear, and golgi localization of RGS proteins. Evidence for N-terminal and RGS domain sequences as intracellular targeting motifs. 1079 63

Dynamin I is expressed at high levels in brain and its expression is regulated during the developmental stages of brain. To elucidate the molecular mechanism by which the expression is tissue-specifically regulated, we cloned the 5'-flanking region of the mouse dynamin I gene and determined the nucleotide sequence of 1036 bases upstream from the translation start site. Transient transfection studies with a chloramphenicol acetyltransferase reporter gene in neuroblastoma NS20Y and Lewis lung cells demonstrated that the 5'-flanking region has a cell-type-specific promoter activity. Deletion analyses demonstrated that the minimal promoter activity was detected in the proximal region 195 bp upstream of the translation initiation codon (-90 to +105). The minimal promoter was embedded in a GC-rich region (75% GC content), in which an Sp1-binding motif and a nuclear factor (NF)-kappa B-like element (NE-1) were found, but it lacked TATA and CAAT boxes. Mutational analysis and electrophoretic mobility-shift assay analysis revealed that Sp1 binds to the Sp1 site and that this element is critical for the promoter activity of the dynamin I gene. We found that the NE-1 sequence is required for the expression of the dynamin I gene but NEBP (NE-1-binding protein), which binds to the NE-1 sequence, is not NF-kappa B. We also found that one base in the NE-1 sequence (the underlined G residue in GGGATTCGCGGA) is critical for binding specificity to discriminate between NEBP and NF-kappa B. By UV cross-linking analysis, we found that NEBP is an approx. 104 kDa nuclear protein.
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PMID:Characterization of the mouse dynamin I gene promoter and identification of sequences that direct expression in neuronal cells. 1104 20


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