Human glial fibrillary acidic protein (GFAP): molecular cloning of the complete cDNA sequence and chromosomal localization (chromosome 17) of the GFAP gene

N-(4-Hydroxyphenyl) retinamide induced both differentiation and apoptosis in human glioblastoma T98G and U87MG cells

N-(4-Hydroxyphenyl) retinamide (4-HPR) is a synthetic retinoid that has shown biological activity against several malignant tumors and minimal side effects in humans. To explore the mechanisms underlying the chemotherapeutic effects of 4-HPR in glioblastoma, we used two human glioblastoma T98G and U87MG cell lines. In situ methylene blue staining showed the morphological features of astrocytic differentiation in glioblastoma cells following exposure to 1 microM and 2 microM 4-HPR for a short duration (24 h). Astrocytic differentiation was associated with an increase in expression of glial fibrillary acidic protein (GFAP) and downregulation of telomerase. Wright staining and ApopTag assay indicated appearance of apoptotic features in glioblastoma cells following exposure to 1 microM and 2 microM 4-HPR for a long duration (72 h). We found that 4-HPR caused apoptosis with activation of caspase-8 and cleavage of Bid to truncated Bid (tBid). Besides, apoptosis was associated with alterations in expression of pro-apoptotic Bax and anti-apoptotic Bcl-2 proteins resulting in an increase in Bax:Bcl-2 ratio, mitochondrial release of cytochrome c and Smac, downregulation of selective baculoviral inhibitor-of-apoptosis repeat containing (BIRC) molecules, an increase in intracellular free [Ca2+], and activation of calpain and caspase-3. Taken together, these results strongly suggested that 4-HPR could be used at low doses for induction of both differentiation and apoptosis in human glioblastoma cells.

Retinoids induced astrocytic differentiation with down regulation of telomerase activity and enhanced sensitivity to taxol for apoptosis in human glioblastoma T98G and U87MG cells

We hypothesized that induction of differentiation with retinoid could increase sensitivity to microtubule-binding drug taxol (TXL) for apoptosis in human glioblastoma T98G and U87MG cells. Treatment of cells with 1 microM all-trans retinoic acid (ATRA) or 1 microM 13-cis retinoic acid (13-CRA) for 7 days induced astrocytic differentiation, overexpression of glial fibrillary acidic protein (GFAP), and also down regulated telomerase expression and activity, thereby increased sensitivity to TXL for apoptosis. Treatment of glioblastoma cells with TXL triggered production of reactive oxygen species (ROS), induced phosphorylation of p38 mitogen-activated protein kinase (MAPK), and activated the redox-sensitive c-Jun NH(2)-terminal kinase 1 (JNK1) pathway. Moreover, TXL activated Raf-1 kinase for phosphorylation and inactivation of anti-apoptotic Bcl-2 protein. The events of apoptosis included increase in expression of Bax, down regulation of Bcl-2 and baculoviral inhibitor-of-apoptosis protein (IAP) repeat containing (BIRC) proteins, mitochondrial release of cytochrome c and Smac into the cytosol, increase in intracellular free [Ca(2+)], and activation of calpain, caspase-9, and caspase-3. Increased activity of caspase-3 cleaved inhibitor of caspase-activated DNase (ICAD) to release and translocate CAD to the nucleus for DNA fragmentation. Involvement of stress signaling kinases and proteolytic activities of calpain and caspase-3 in apoptosis was confirmed by pretreating cells with specific inhibitors. Taken together, our results suggested that retinoid (ATRA or 13-CRA) induced astrocytic differentiation with down regulation of telomerase activity to increase sensitivity to TXL to enhance apoptosis in glioblastoma cells. Thus, combination of retinoid and TXL could be an effective therapeutic strategy for controlling the growth of glioblastoma.

TGF-alpha differentially regulates GFAP, vimentin, and nestin gene expression in U-373 MG glioblastoma cells: correlation with cell shape and motility

To begin understanding the regulation and biological significance of changes in the expression of intermediate filament proteins in astrocytic tumors, we have recently shown that TGF-alpha alters the protein level of glial fibrillary acidic protein (GFAP), nestin, and vimentin in U-373 MG glioblastoma cells. Here, we have determined the molecular mechanisms regulating these changes. In addition, to evaluate the significance of these changes we have examined whether TGF-alpha affects various cellular properties related to differentiation. Our results show that, in U-373 MG cells treated with TGF-alpha, GFAP gene transcription, mRNA level, and specific protein synthesis decrease by approximately 50%. This suggests that, in U-373 MG cells, TGF-alpha down-regulates the expression of this marker of astrocytic differentiation at the transcriptional level, resulting in decreased GFAP mRNA level and specific protein synthesis. In contrast, TGF-alpha does not change vimentin gene transcription, but increases by about 50% the transcription of the gene for nestin, a marker for undifferentiated astrocytic precursors. This differential regulation of GFAP, nestin, and vimentin gene expression indicates that TGF-alpha induces further dedifferentiation of U-373 MG cells. This notion is also supported by our findings that TGF-alpha increases the motility of U-373 MG cells and induces a less stellate morphology.

Stochastic determination of the chromosomal region responsible for expression of human glial fibrillary acidic protein in astrocytic tumors

Previous investigators have localized the human glial fibrillary acidic protein (GFAP) gene in the segment 17q21 in chromosome 17. In the present study, we statistically assessed the association between the allelic status in thirty-three microsatellite loci and the immunohistochemical expression of GFAP in twenty human astrocytic tumors. The results demonstrated that the loss of heterozygosity in only one locus (D17S795 located in 17q21.2) was significantly associated with the impaired expression of GFAP (P = 0.0280, Pc = 0.0384 by Fisher's exact test). The adjacent loci located in 17q21.1 and 17q21.3 were not relevant to GFAP expression. Those data suggest that the critical region responsible for GFAP expression (coding sequence and regulatory elements) is located close to the locus D17S795 in the segment 17q21.2.

Cloning of human and mouse cDNAs encoding novel zinc finger proteins expressed in cerebellum and hippocampus

We identified a novel gene, kf-1, highly expressed in the normal cerebellum but not in the cerebral cortex, the expression of which could have been augmented in the cerebral cortex of a sporadic Alzheimer's disease patient. We cloned human and mouse entire kf-1 cDNAs encoding conserved 79 kDa proteins containing a zinc-binding RING-H2 finger motif at the carboxy-terminus as found in acetylcholine receptor-associated protein (RAPsyn). The 3'-untranslated regions are highly conserved between human and mouse as to constitute a common mRNA secondary structure. In situ hybridization analysis of mouse brain sections revealed strong kf-1 expression in the cerebellum and hippocampus. We propose that KF-1 is involved in membranous protein-sorting apparatus similarly to RAPsyn. We mapped the human kf-1 gene to 2p11.2.

Structure and transcriptional regulation of the GFAP gene

Transcriptional regulation of the GFAP gene is intimately connected with astrocyte function: its initial activation marks the differentiation of astrocytes, and its up-regulation accompanies the reactive response to CNS injury. Studies of GFAP transcription should thus provide insights into multiple regulatory pathways operating in these cells. In addition, they should identify DNA elements that could be used to direct synthesis of other proteins to astrocytes in transgenic animals, permitting creation of disease models, and the testing of cause and effect relationships. This review describes several GFAP cDNA and genomic clones that have been isolated, including homology comparisons of the encoded RNAs and proteins. Cell transfection studies by several laboratories are summarized that have identified a DNA segment immediately upstream of the RNA start site that is essential for transcriptional activity, but which have yielded conflicting results concerning the importance of other segments located both further upstream and downstream of the RNA start site. Two procedures are recounted that have led to the successful expression of GFAP-transgenes in astrocytes in mice. One of these incorporates the transgene into the first exon of a fragment spanning the entire GFAP gene, while the other links it to a 2 kb 5'-flanking segment. Results already produced by GFAP-transgenic studies include demonstration of a neurotoxic effect of the HIV-1 gp120 coat protein, and creation of a hydrocephalic mouse model.

Structure, expression and chromosomal localization of the gene encoding human 2',3'-cyclic-nucleotide 3'-phosphodiesterase

Four human genomic DNA clones for 2',3'-cyclic-nucleotide 3'-phosphodiesterase (CNP) were isolated by screening a human genomic library with human CNP cDNA clones as probes. Restriction mapping and sequence analysis revealed that the human CNP gene is about 8.5 kb long and composed of four exons interrupted by three introns. There are two transcription start points and in human brain, two forms of CNP mRNA are produced from a single gene by alternative splicing, similar to mouse. A homology search of the 5'-flanking regions of exon 0 and exon 1 in the human CNP gene indicated the presence of oligodendroglia-specific elements and myelin basic protein transcription element (MBTE) motif, in addition to TATA-box-like sequences. Spot blot hybridization of flow-sorted human chromosomes with the 3'-noncoding region of the human CNP cDNA showed the localization of CNP to chromosome 17.

Gene expression in cells of the central nervous system

This review summarized a part of our studies over a long period of time, relating them to the literature on the same topics. We aimed our research toward an understanding of the genetic origin of brain specific proteins, identified by B. W. Moore and of the high complexity of the nucleotide sequence of brain mRNA, originally investigated by W. E. Hahn, but have not completely achieved the projected goal. According to our studies, the reason for the high complexity in the RNA of brain nuclei might be the high complexity in neuronal nuclear RNA as described in the Introduction. Although one possible explanation is that it results from the summation of RNA complexities of several neuronal types, our saturation hybridization study with RNA from the isolated nuclei of granule cells showed an equally high sequence complexity as that of brain. It is likely that this type of neuron also contains numerous rare proteins and peptides, perhaps as many as 20,000 species which were not detectable even by two-dimensional PAGE. I was possible to gain insight into the reasons for the high sequence complexity of brain RNA by cloning the cDNA and genomic DNA of the brain-specific proteins as described in the previous sections. These data provided evidence for the long 3'-noncoding regions in the cDNA of the brain-specific proteins which caused the mRNA of brain to be larger than that from other tissues. During isolation of such large mRNAs, a molecule might be split into a 3'-poly(A)+RNA and 5'-poly(A)-RNA. In the studies on genomic DNA, genes with multiple transcription initiation sites were found in brain, such as CCK, CNP and MAG, in addition to NSE which was a housekeeping gene, and this may contribute to the high sequence complexity of brain RNA. Our studies also indicated the presence of genes with alternative splicing in brain, such as those for CNP, MAG and NGF, suggesting a further basis for greater RNA nucleotide sequence complexity. It is noteworthy that alternative splicing of the genes for MBP and PLP also produced multiple mRNAs. Such a mechanism may be a general characteristic of the genes for the myelin-specific proteins produced by oligodendrocytes. In considering the high nucleotide sequence complexity, it is interesting that MAG and S-100 beta genes etc. possess two additional sites for poly(A).(ABSTRACT TRUNCATED AT 400 WORDS)