In this report, we present a fluorescence-based approach to the assessment of cellular gene expression and transcription rates. Nuclear run-on was performed by supplying biotin-16-UTP to nuclei, and labeled transcripts were bound to streptavidin-coated magnetic beads. Total cDNA was then synthesized by means of random hexamer primed reverse transcription of captured molecules. To monitor transcript abundance in cDNA, both from nuclear run-on and total RNA, we propose a semiquantitative PCR approach based on the use of fluorescent primers.
Hirschsprung disease (HSCR) is an inherited disorder characterised by absence of intrinsic ganglion cells in the distal gastrointestinal tract. Different susceptibility genes, involved in either the Ret-tyrosine kinase or the endothelin signalling pathways, contribute to HSCR phenotype. Interestingly, alterations of these genes are detected in only 30-50% of all HSCR patients, suggesting the involvement of modifier genes and/or additional genetic or environmental risk factors. In complex disorders common polymorphic variants can be associated with the disease phenotype, thus modifying the risk of recurrence. To investigate whether sequence variants of the RET proto-oncogene may be associated with the development of the HSCR phenotype, we analysed 92 Italian patients for the 2508C > T synonymous substitution in exon 14 (S836S) finding that the T allele is clearly less frequent than in control individuals (Fisher exact test P = 0.0002). On the other hand, this RET variant allele is overrepresented in patients affected with medullary thyroid carcinoma. Assuming a direct effect of this single-nucleotide polymorphism in predisposing to RET associated pathologies, we have performed functional tests which excluded any possible involvement of the C and T alleles in DNA-protein binding, transcript stability and RNA splicing and editing.
Hirschsprung disease (HSCR) is a common genetic disorder characterized by intestinal obstruction secondary to enteric aganglionosis. HSCR demonstrates a complex pattern of inheritance, with the RET proto-oncogene acting as a major gene and with several additional susceptibility loci related to the Ret-signaling pathway or to other developmental programs of neural crest cells. To test how the HSCR phenotype may be affected by the presence of genetic variants, we investigated the role of a single-nucleotide polymorphism (SNP), 2508C-->T (S836S), in exon 14 of the RET gene, characterized by low frequency among patients with HSCR and overrepresentation in individuals affected by sporadic medullary thyroid carcinoma. Typing of several different markers across the RET gene demonstrated that a whole conserved haplotype displayed anomalous distribution and nonrandom segregation in families with HSCR. We provide genetic evidence about a protective role of this low-penetrant haplotype in the pathogenesis of HSCR and demonstrate a possible functional effect linked to RET messenger RNA expression.
In a large proportion of familial and sporadic cases of Hirschsprung disease (HSCR) mutations in the RET (rearranged during transfection) protooncogene have been described. We have investigated the structure of the RET gene promoter and have analysed a region of approximately 1000 nucleotides in its promoter and 5'-upstream segments for the occurrence of 5-methyldeoxycytidine (5-mC) residues by using the bisulfite protocol of the genomic sequencing method. With an estimated sensitivity of about 93% of this technique, not a single 5-mC residue could be detected in the control region of a gene that seems to be silenced or exhibit low activity in many adult tissues. In these experiments, the DNAs of peripheral white blood cells (PWBC) from four healthy individuals, from seven patients with familial HSCR, as well as DNAs from different human tissues and from a human embryonic kidney (HEK) cell line have been included. In a DNA segment starting 790 nucleotides upstream of the transcriptional start site of the RET gene, a few 5-mC residues have been identified. This region possibly constitutes the transition site from an unmethylated promoter to a more extensively methylated region in the human genome. The data presented are remarkable in that a highly 5'-CG-3'-enriched segment of the human genome with 49 5'-CG-3' dinucleotide pairs in 400 bp within the putative promoter region is completely devoid of 5-mC residues, although this control region is not actively transcribed in most adult human tissues. By hybridization of a PCR-amplified RET protooncogene cDNA probe harboring exons 9-15 to a membrane (Clontech) containing poly-A selected RNAs from 50 different human tissues, weak RET protooncogene expression in many of the neural cell derived tissues has been detected. RNAs extracted from many other human tissues do not share sequence homologies to this 32P-labeled probe. Mechanisms other than DNA methylation obviously play the crucial role in the inactivation of the RET gene promoter in these tissues. We have also demonstrated by the in vitro premethylation of a RET promoter-chloramphenicol acetyltransferase (CAT) gene construct and transient transfection experiments into neuroblastoma cells that the transcriptional activity of the RET promoter is decreased by HpaII (5'-CCGG-3') methylation and abolished by SssI (5'-CG-3') methylation. Hence, the RET promoter region is sensitive to this regulatory signal. However in vivo, DNA methylation of the promoter region seems not to be the predominant regulatory mechanism for the RET protooncogene. Possibly, in adults the RET gene can be occasionally activated.
The RET proto-oncogene encodes a receptor tyrosine kinase expressed during neural crest development. RET expression is enhanced in vitro by several differentiating agents, including retinoic acid (RA), which up-regulates RET expression in neuroblastoma cell lines. In the present work we sequenced and analysed a 5 kbp genomic fragment 5' to RET. Three deletion fragments of this region were tested for their RA inducibility in transient transfection assays and failed to support the hypothesis of a direct transcriptional activation. Finally, our functional analysis of a candidate RA response element present in the RET promoter provides new hints for the understanding of the interaction between nuclear receptors and their specific recognition sites.
The RET gene is expressed with high tissue and stage speci¢city during development. Understanding its transcriptional regulation might provide new clues to clarify developmental mechanisms. Here we show that the histone deacetylase inhibitor sodium butyrate (NaB) increases RET transcription in cells displaying low levels of its mRNA, while it has no e¡ect in cells expressing at high levels. Chromatin immunoprecipitation (ChIP) experiments showed increased histone acetylation within the same region, in particular the Sox10^Pax3 enhancer site, due to NaB. Accordingly, ChIP showed di¡erent acetylation levels at the Sox10^Pax3 site associated with cellline speci¢c RET transcription rates. Concluding, chromatin acetylation targeted to functional sequences in the RET regulatory region may control its transcription. ß
Background:The RET gene encodes a tyrosine kinase receptor involved in different human neurocristopathies, such as specific neuroendocrine tumours and Hirschsprung disease (HSCR). Gene expression is developmentally regulated and the RET transcript is undetectable in most adult cells, including lymphocytes. The impossibility of performing functional studies on RET mRNA has to date limited the detection and characterisation of an indefinite proportion of gene anomalies that cannot be identified by conventional DNA genomic screening in HSCR cases. Aims: Development of a protocol suitable to activate RET expression in RET negative cell lines and therefore to investigate directly RET mRNA, extending the conventional gene mutation analysis to detection of splicing anomalies and impaired expression of the RET gene. Methods: The effect of sodium butyrate (NaB), a histone deacetylase inhibitor, on rescuing RET expression was tested by one round of reverse transcription-polymerase chain reaction from total RNA of treated lymphoblasts from both HSCR patients and control individuals. Results: Analysis of RET expression was possible by NaB treatment of RET negative cells, such as lymphoblasts. This treatment allowed us to detect impaired RET expression as well as a splicing defect in two HSCR patients previously believed to be devoid of any gene abnormality. Conclusions:The full application of the proposed protocol in most of the unexplained HSCR cases will allow us to establish the precise role of RET not only in causing but also in predisposing to HSCR pathogenesis.T he RET proto-oncogene (REarranged during Transfection) encodes a tyrosine kinase receptor predominantly expressed during neural crest development and involved in different human neurocristopathies.1 Germline RET mutations have been found in association with both inherited cancer syndromes, including multiple endocrine neoplasia type 2A (MEN2A), type 2B (MEN2B), and familial medullary thyroid carcinoma, and Hirschsprung disease (HSCR), a developmental disorder characterised by the absence of enteric neurones in variable lengths of the distal gastrointestinal tract.2 Loss of function, low penetrant RET mutations have been identified in only 10-40% of total HSCR cases while a small proportion of patients (5-10%) show alterations in other genes, generally related to the developmental programme of neural crest cells.3 4 By using sibpair analysis, a recent study has recognised three HSCR susceptibility loci at 3p21, 10q11, and 19q12 which may clarify the molecular basis of a great proportion of unexplained HSCR cases. 5 The locus in 10q11 probably corresponds to RET, confirming the central role played by this gene in HSCR pathogenesis. Taking into account the persistent failure to detect RET coding sequence mutations in a proportion of familial cases found to be linked to the gene, it has recently been suggested that genetic defects in introns and in the promoter region can contribute in some cases to the HSCR phenotype. [5][6][7] Moreover, several common polymorphi...
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