Abstract
The assembly of an RNA polymerase II initiation complex at a promoter is associated with the melting of the DNA template to allow the polymerase to read the DNA sequence and synthesize the corresponding RNA. Using the specific single-stranded modifying reagent KMnO4 and a new genomic sequencing technique, we have explored the melted regions of specific genes in genomic DNA of whole cells or of isolated nuclei. We have demonstrated for the first time in vivo the melting in the promoter proximal transcribed region that is associated with the presence of RNA polymerase II complexes. An interferon-inducible gene, ISG-54, exhibited KMnO4 sensitivity over approximately 300 nucleotides downstream of the RNA initiation site in interferon-treated cells when the gene was actively transcribed but not in untreated cells where the gene was not transcribed. The extent of KMnO4 modification was proportional to transcription levels. The KMnO4 sensitivity was retained when nuclei were isolated from induced cells but was lost if the engaged polymerases were further allowed to elongate the nascent RNA chains ("run-on"). The sensitivity to KMnO4 in isolated nuclei was retained if the run-on incubation was performed in the presence of alpha-amanitin, which blocks progress of engaged polymerases. A similar analysis identified an open sequence of only approximately 30 bases just downstream of the start site of the transthyretin (TTR) gene in nuclei isolated from mouse liver, a tissue where TTR is actively transcribed. This abrupt boundary of KMnO4 sensitivity, which was removed completely by allowing engaged polymerases to elongate RNA chains, suggests that most polymerases transcribing this gene paused at about position +20. The possibility of mapping at the nucleotide level the position of actively transcribing RNA polymerases in whole cells or isolated nuclei opens new prospects in the study of transcription initiation and elongation.
Keywords
BiologyMolecular biologyPolymeraseRNA polymeraseRNA-dependent RNA polymeraseRNA polymerase IITranscription (linguistics)Small nuclear RNARNARNA polymerase IGeneDNADNA polymeraseGene expressionPromoterGenetics
Affiliated Institutions
Related Publications
Regulating RNA polymerase pausing and transcription elongation in embryonic stem cells
Transitions between pluripotent stem cells and differentiated cells are executed by key transcription regulators. Comparative measurements of RNA polymerase distribution over th...
Transcription by Eukaryotic RNA Polymerases A and B of Chromatin Assembled <i>in vitro</i>
Chromatin was assembled in vitro from simian virus 40 DNA form I and the calf‐thymus four histones H2A, H2B, H3 and H4. Transcription with calf thymus RNA polymerases A and B (I...
Gene insulation. Part I: natural strategies in yeast and <i>Drosophila</i>
This review in two parts deals with the increasing number of processes known to be used by eukaryotic cells to protect gene expression from undesired genomic enhancer or chromat...
Revised transcription map of the late region of bacteriophage T7 DNA
The genes in the late region of the bacteriophage T7 genome are transcribed by a phage-specified RNA polymerase in two temporal classes (II and III). Through the use of an agaro...
Mapping of nascent light and heavy strand transcripts on the physical map of HeLa cell mitochondrial DNA
The sequences complementary to the nascent RNA molecules isolated from transcription complexes of HeLa cell mtDNA have been mapped on the H and L strands of mtDNA by the S1 prot...
Publication Info
- Year
- 1992
- Type
- article
- Volume
- 3
- Issue
- 10
- Pages
- 1085-1094
- Citations
- 23
- Access
- Closed
External Links
Social Impact
Altmetric
PlumX Metrics
Social media, news, blog, policy document mentions
Citation Metrics
23
OpenAlex
Cite This
Jovan Mirkovitch,
James Darnell
(1992).
Mapping of RNA polymerase on mammalian genes in cells and nuclei..
Molecular Biology of the Cell
, 3
(10)
, 1085-1094.
https://doi.org/10.1091/mbc.3.10.1085
Identifiers
- DOI
- 10.1091/mbc.3.10.1085