Transcription (biology)

About: Transcription (biology) is a research topic. Over the lifetime, 56532 publications have been published within this topic receiving 2952782 citations. The topic is also known as: genetic transcription & transcription, genetic.

Oligodeoxynucleotides: Antisense Inhibitors of Gene Expression

Abstract: Publisher Summary A new type of drug molecule synthesized with a specific base sequence designed to interact with a target nucleic acid containing the complementary sequence are being developed. In the earliest and most developed example of this approach, oligodeoxynucleotides and their analogs have been applied as antisense inhibitors of gene expression to bring about translation arrest. This chapter discusses the use of antisense oligodeoxynucleotides as a therapeutic approach. Once this approach is recognized in principle, other examples can be seen to fit a pattern, such as the use of oligodeoxynucleotides to form a triple-strand helix with duplex DNA. However, with a different base triplet code to arrest transcription, the opening of duplex DNA is not considered facile enough to allow the access of an oligo to interact with one of the strands. The development of synthetic oligoribonucleotides as ribozymes is another example in which the information for the selectivity is encoded in the portions of the oligomer flanking the catalytic site. Another example is the use of oligodeoxynucleotides to bind to protein sites that recognize specific sequences of bases, thus, inhibiting polymerase action or bringing about transcription arrest by sequestering specific transcription cofactors. Thus, a new area of pharmacology is developing that is differentiated by the purposeful inclusion of information in the form of nucleic-acid bases in a putative oligonucleotide drug molecule.

Function of a Bacterial Activator Protein that Binds to Transcriptional Enhancers

Abstract: The nitrogen regulatory (NtrC) protein of enteric bacteria, which binds to sites that have the properties of transcriptional enhancers, is known to activate transcription by a form of RNA polymerase that contains the NtrA protein (sigma 54) as sigma factor (referred to as sigma 54-holoenzyme). In the presence of adenosine triphosphate, the NtrC protein catalyzes isomerization of closed recognition complexes between sigma 54-holoenzyme and the glnA promoter to open complexes in which DNA in the region of the transcription start site is locally denatured. NtrC is not required subsequently for maintenance of open complexes or initiation of transcription.

Expression of antibiotic resistance genes in the integrated cassettes of integrons.

Abstract: Plasmids containing cloned integron fragments which differ only with respect to either the sequence of the promoter(s) or the number and order of inserted cassettes were used to examine the expression of resistance genes encoded in integron-associated gene cassettes. All transcripts detected commenced at the common promoter P(ant), and alterations in the sequence of P(ant) affected the level of resistance expressed by cassette genes. When both P(ant) and the secondary promoter P2 were present, transcription from both promoters was detected. When more than one cassette was present, the position of the cassette in the array influenced the level of antibiotic resistance expressed by the cassette gene. In all cases, the resistance level was highest when the gene was in the first cassette, i.e., closest to P(ant), and was reduced to different extents by the presence of individual upstream cassettes. In Northern (RNA) blots, multiple discrete transcripts originating at P(ant) were detected, and only the longer transcripts contained the distal genes. Together, these data suggest that premature transcription termination occurs within the cassettes. The most abundant transcripts appeared to contain one or more complete cassettes, and is possible that the 59-base elements found at the end of the cassettes (3' to the coding region) not only function as recombination sites but may also function as transcription terminators.

Different Human Cervical Carcinoma Cell Lines Show Similar Transcription Patterns of Human Papillomavirus Type 18 Early Genes

Abstract: Transcription of human papillomavirus type 18 (HPV18) DNA in the human cervical carcinoma cell lines HeLa, C4-1 and SW756 was studied by nucleotide sequence analysis of HPV18-positive cDNA clones isolated from a HeLa, C4-1 and SW756 cDNA library, respectively, and the cDNA sequences were used to predict the potential encoded proteins. The cDNA clones from all three cell lines were found to be derived from virus-cell fusion transcripts in which 3'-terminal host cell sequences (different for each cell line) were spliced to 5'-terminal exon sequences from the HPV18 E6-E7-E1 region. Three different types of cDNA clones can be distinguished according to the splicing patterns observed in the 5' terminal HPV18 sequences. They carry as potential protein-coding regions the HPV18 specific open reading frames E6 and E6* (generated by splicing and identical with E6 up to the E6* splice junction), E7 and E1 (only in HeLa). Translation of specific cellular genes from the chimeric viral-cellular transcripts seems to be unlikely. The mapping of the 5'-ends of the virus-cell fusion transcripts indicates that transcription is initiated at a viral promoter. The similar patterns of HPV18 transcription in the three different cervical carcinoma cell lines suggest a functional role of HPV18 early genes for the malignant phenotype of these cells.

DNA methylation of the gonadal aromatase (cyp19a) promoter is involved in temperature-dependent sex ratio shifts in the European sea bass.

Abstract: Sex ratio shifts in response to temperature are common in fish and reptiles. However, the mechanism linking temperature during early development and sex ratios has remained elusive. We show in the European sea bass (sb), a fish in which temperature effects on sex ratios are maximal before the gonads form, that juvenile males have double the DNA methylation levels of females in the promoter of gonadal aromatase (cyp19a), the enzyme that converts androgens into estrogens. Exposure to high temperature increased the cyp19a promoter methylation levels of females, indicating that induced-masculinization involves DNA methylation-mediated control of aromatase gene expression, with an observed inverse relationship between methylation levels and expression. Although different CpGs within the sb cyp19a promoter exhibited different sensitivity to temperature, we show that the increased methylation of the sb cyp19a promoter, which occurs in the gonads but not in the brain, is not a generalized effect of temperature. Importantly, these effects were also observed in sexually undifferentiated fish and were not altered by estrogen treatment. Thus, methylation of the sb cyp19a promoter is the cause of the lower expression of cyp19a in temperature-masculinized fish. In vitro, induced methylation of the sb cyp19a promoter suppressed the ability of SF-1 and Foxl2 to stimulate transcription. Finally, a CpG differentially methylated by temperature and adjacent to a Sox transcription factor binding site is conserved across species. Thus, DNA methylation of the aromatase promoter may be an essential component of the long-sought-after mechanism connecting environmental temperature and sex ratios in vertebrate species with temperature-dependent sex determination.