Home  About us  Contact
 

Potential Regulatory Elements (potential + regulatory_element)

Distribution by Scientific Domains
Life Sciences50%

Selected Abstracts

Characterization of genomic DNA encoding cecropins from an Aedes albopictus mosquito cell line

INSECT MOLECULAR BIOLOGY, Issue 1 2002
D. Sun
Abstract We used cDNA probes from Aedes albopictus mosquito cecropins AalCecA, B, and C to obtain genomic DNA copies and flanking DNA. Two gene copies (AalCecA1 and A2, AalCecB1 and B2, AalCecC1 and C2) encoding each of the three mature cecropin peptides were recovered. All these genes had a similar organization, into two exons interrupted by a single short intron. AalCecA1 and AalCecA2 encode mature protein products that differ by one amino acid residue, while AalCecB1 and AalCecB2, AalCecC1 and AalCecC2 encode identical mature cecropin peptides, respectively. The AalCecB and C gene pairs each share a common intergenic region of approximately 1 kb, with the two coding regions transcribed in opposite directions. With the exception of small insertions/deletions, the intergenic spacer region was highly conserved between the B1/C1 and B2/C2 clones. In transfected cells, 0.8 kb of upstream sequence was sufficient for inducible expression of AalCecA1. Within this region, a 28 bp sequence at positions ,192 to ,165 upstream of the transcription initiation site was found to contain a potential regulatory element. In electrophoretic mobility shift assays, synthetic double-stranded DNA containing this 28 bp sequence retarded protein in cytoplasmic and nuclear extracts from C7-10 cells. [source]

Evaluation of potential regulatory elements identified as DNase I hypersensitive sites in the CFTR gene

FEBS JOURNAL, Issue 2 2002
Marios Phylactides
The cystic fibrosis transmembrane conductance regulator (CFTR) gene shows a complex pattern of expression, with temporal and spatial regulation that is not accounted for by elements in the promoter. One approach to identifying the regulatory elements for CFTR is the mapping of DNase I hypersensitive sites (DHS) within the locus. We previously identified at least 12 clusters of DHS across the CFTR gene and here further evaluate DHS in introns 2, 3, 10, 16, 17a, 18, 20 and 21 to assess their functional importance in regulation of CFTR gene expression. Transient transfections of enhan- cer/reporter constructs containing the DHS regions showed that those in introns 20 and 21 augmented the activity of the CFTR promoter. Structural analysis of the DNA sequence at the DHS suggested that only the one intron 21 might be caused by inherent DNA structures. Cell specificity of the DHS suggested a role for the DHS in introns 2 and 18 in CFTR expression in some pancreatic duct cells. Finally, regulatory elements at the DHS in introns 10 and 18 may contribute to upregulation of CFTR gene transcription by forskolin and mitomycin C, respectively. These data support a model of regulation of expression of the CFTR gene in which multiple elements contribute to tightly co-ordinated expression in vivo. [source]

Functional analysis of the osteoarthritis susceptibility,associated GDF5 regulatory polymorphism

ARTHRITIS & RHEUMATISM, Issue 7 2009
Rainer J. Egli
Objective Single-nucleotide polymorphism (SNP) rs143383 (T to C) in the 5,-untranslated region (5,-UTR) of GDF5 has recently been reported to be associated with osteoarthritis (OA) susceptibility, with lower expression of the risk-associated T allele observed in vitro and in vivo. The in vivo studies were performed on cartilage tissue from OA patients. The present study was undertaken to expand the analysis of the effect of this SNP on GDF5 allelic expression to more joint tissue types, to investigate for cis and trans factors that interact with the SNP, and to examine novel cis -acting GDF5 regulatory polymorphisms. Methods Tissue samples were collected from OA patients undergoing joint replacement of the hip or knee. Nucleic acid was extracted, and, using rs143383 and an assay that discriminates and quantifies allelic expression, the relative amount of GDF5 expression from the T and C alleles was measured. Additional common variants in the GDF5 transcript sequence were interrogated as potential regulatory elements using allelic expression and luciferase reporter assays, and electrophoretic mobility shift assays were used to search for trans factors binding to rs143383. Results We observed a consistent allelic expression imbalance of GDF5 in all tissues tested, implying that the functional effect mediated by rs143383 on GDF5 expression is joint-wide. We identified a second polymorphism, located in the 3,-UTR of GDF5, that influenced allelic expression of the gene independent of rs143383. Finally, we observed differential binding of deformed epidermal autoregulatory factor 1 (DEAF-1) to the 2 alleles of rs143383. Conclusion These findings show that the OA susceptibility mediated by polymorphism in GDF5 is not restricted to cartilage, emphasizing the need to consider the disease as involving the whole joint. The existence of an additional cis -acting regulatory polymorphism highlights the complexity of the regulation of expression of this important OA susceptibility locus. DEAF-1 is a trans -acting factor that merits further investigation as a potential tool for modulating GDF5 expression. [source]

Analysis of two translocation breakpoints and identification of a negative regulatory element in patients with Rieger's syndrome

BIRTH DEFECTS RESEARCH, Issue 2 2004
Dimitri G. Trembath
Abstract BACKGROUND Rieger's syndrome is an autosomal dominant disorder characterized by eye, tooth, and umbilical anomalies. A gene responsible for Rieger's syndrome, PITX2, has previously been cloned using two patients with balanced translocations, t(4;16) and t(4;11), with breakpoints that lie near the gene, but which do not interrupt it. METHODS We sequenced both breakpoint regions on chromosome 4 and screened this area for novel genes. Fluorescence in situ hybridization (FISH) was used to determine if PITX2 was still present on the 4:16 chromosome. Both the chromosome 16 and chromosome 11 breakpoints were cloned and sequenced using panhandle polymerase chain reaction (PHPCR). Transient transfection studies were performed to compare effects on a reporter gene between native chromosome 4 sequence and chromosome 11 sequence. RESULTS The region surrounding PITX2 on chromosome 4 is rich in repetitive elements, but no novel genes were identified. FISH demonstrated that PITX2 was intact on the 4:16 translocation chromosome. The PHPCR experiments demonstrated that the translocated regions of chromosomes 16 and 11 were repeat-rich, and transfection studies revealed a slight enhancer effect with the chromosome 4 sequence, and a strong silencer effect when the chromosome 11 sequence was present. CONCLUSIONS Given the lack of any novel genes near either breakpoint, changes in potential regulatory elements may be the best model to explain the loss of PITX2 expression in these patients and hence the Rieger's syndrome phenotype. Birth Defects Research (Part A), 2004. © 2004 Wiley-Liss, Inc. [source]