Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:2.7.7.6 (RNA polymerase)
 34,946 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

An indirect enzyme linked immunoassay (ELISA) has been developed to measure the amount of RNA polymerase I (E.C.2.7.7.6) in silkmoth tissue cell extracts. Subunit specific monoclonal antibodies (MABs) were immobilized on the solid substrate by a variation of the widely used Protein-Avidin-Biotin-Capture (PABC) technique. The use of the commercially available biotinylated anti-mouse antibody as a bridge to bind the monoclonal antibody eliminates the need for the biotinylation of the monoclonal antibody in the laboratory. The RNA polymerase in solution was captured by the monoclonal antibody and was measured by the successive binding of rabbit polyclonal antibody and alkaline phosphatase conjugated anti-rabbit antibody. This procedure is more reliable, reproducible and leads to greater sensitivity compared to the direct binding of the monoclonal antibody to the microtiter plate. RNA polymerase I captured by the antibodies from tissue extracts was measured at levels of 0.5 ng/well. This assay system can be utilized as a general procedure to quantitate the levels of proteins present at very low levels and that are found in different isoforms containing multiple and/or shared subunits.
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PMID:A modified PABC immunoassay for the quantitation of DNA dependent RNA polymerase I: a procedure applicable to other proteins present in minute amounts and/or isoforms. 834 15

Current research into cytokine production in tissue sections relies on the detection of cytokine proteins using a variety of immunohistochemical methods. The disadvantages of this technique are that precise localization to a particular cell is difficult and it is uncertain whether the cells detected by this method are the origin or target of the cytokine or rather have nonspecifically absorbed the secreted cytokine. This question can be clarified using in situ hybridization, but current techniques are insensitive, poorly localizing, or time consuming. Biotin-labeled riboprobes were generated from cDNA fragments sandwiched between two RNA polymerase promoters (SP6 and T7 RNA polymerases) using a commercial riboprobe generation kit containing biotin-labeled UTP. The in situ hybridization technique was used to demonstrate cytokine mRNA in a range of tissues containing an inflammatory infiltrate and with a range of cytokine probes. This technique of in situ hybridization was combined with immunohistochemistry using an immunoalkaline phosphatase technique to show the powerful combination of these two techniques. The biotin-labeled riboprobes were sensitive enough to detect a range of cytokine mRNAs in a variety of tissue sections. The technique can be completed over a 24-h period and produces a stable color product that can be stored for long periods and can be quantitated using image analysis techniques. This technique was performed on paraffin-embedded tissue as well as cryosections and allowed for the detection of mRNA in archival tissue. It was also successfully combined with immunohistochemical techniques to determine simultaneously the localization of a cytokine product in particular cell lineages. A nonradioactive method for in situ hybridization using biotin-labeled riboprobes is described; it is capable of detecting mRNA products from a range of genes in a variety of tissue samples. An amplification step in the method enhances the sensitivity to a level that approaches that of radioactive methods, while maintaining the speed, safety, and simplicity of an immunoperoxidase detection system. The ability to use paraffin-embedded tissue with this method allows for improved tissue architecture and examination of archival tissue. These features should ensure greater use of in situ hybridization techniques in future research studies.
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PMID:A nonradioactive method of in situ hybridization that uses riboprobes and paraffin-embedded tissue and its combination with immunohistochemistry. 902 35

Recently, structural and biochemical studies have detailed many of the molecular events that occur in the ribosome during inhibition of protein synthesis by antibiotics and during nascent polypeptide synthesis. Some of these antibiotics, and regulatory nascent polypeptides mostly in the form of peptidyl-tRNAs, inhibit either peptide bond formation or translation termination. These inhibitory events can stop the movement of the ribosome, a phenomenon termed "translational arrest". Translation arrest induced by either an antibiotic or a nascent polypeptide has been shown to regulate the expression of genes involved in diverse cellular functions such as cell growth, antibiotic resistance, protein translocation and cell metabolism. Knowledge of how antibiotics and regulatory nascent polypeptides alter ribosome function is essential if we are to understand the complete role of the ribosome in translation, in every organism. Here, we describe a simple methodology that can be used to purify, exclusively, for analysis, those ribosomes translating a specific mRNA and containing a specific peptidyl-tRNA. This procedure is based on selective isolation of translating ribosomes bound to a biotin-labeled mRNA. These translational complexes are separated from other ribosomes in the same mixture, using streptavidin paramagnetic beads (SMB) and a magnetic field (MF). Biotin-labeled mRNAs are synthesized by run-off transcription assays using as templates PCR-generated DNA fragments that contain T7 transcriptional promoters. T7 RNA polymerase incorporates biotin-16-UMP from biotin-UTP; under our conditions approximately ten biotin-16-UMP molecules are incorporated in a 600 nt mRNA with a 25% UMP content. These biotin-labeled mRNAs are then isolated, and used in in vitro translation assays performed with release factor 2 (RF2)-depleted cell-free extracts obtained from Escherichia coli strains containing wild type or mutant ribosomes. Ribosomes translating the biotin-labeled mRNA sequences are stalled at the stop codon region, due to the absence of the RF2 protein, which normally accomplishes translation termination. Stalled ribosomes containing the newly synthesized peptidyl-tRNA are isolated and removed from the translation reactions using SMB and an MF. These beads only bind biotin-containing messages. The isolated, translational complexes, can be used to analyze the structural and functional features of wild type or mutant ribosomal components, or peptidyl-tRNA sequences, as well as determining ribosome interaction with antibiotics or other molecular factors. To examine the function of these isolated ribosome complexes, peptidyl-transferase assays can be performed in the presence of the antibiotic puromycin. To study structural changes in translational complexes, well established procedures can be used, such as i) crosslinking to specific amino acids and/or ii) alkylation protection assays.
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PMID:Isolation of translating ribosomes containing peptidyl-tRNAs for functional and structural analyses. 2140 27

For the site-specific labeling and modification of RNA by genetic alphabet expansion, we developed a PCR and transcription system using two hydrophobic unnatural base pairs: 7-(2-thienyl)-imidazo[4,5-b]pyridine (Ds) and 2-nitro-4-propynylpyrrole (Px) as a third pair for PCR amplification and Ds and pyrrole-2-carbaldehyde (Pa) for the incorporation of functional components as modified Pa bases into RNA by T7 transcription. To prepare Ds-containing DNA templates with long chains, the Ds-Px pair was utilized in a fusion PCR method, by which we demonstrated the synthesis of 282-bp DNA templates containing Ds at specific positions. Using these Ds-containing DNA templates and a biotin-linked Pa substrate (Biotin-PaTP) as a modified Pa base, 260-mer RNA transcripts containing Biotin-Pa at a specific position were generated by T7 RNA polymerase. This two-unnatural-base-pair system, combining the Ds-Px and Ds-Pa pairs with modified Pa substrates, provides a powerful tool for the site-specific labeling and modification of desired positions in large RNA molecules.
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PMID:PCR amplification and transcription for site-specific labeling of large RNA molecules by a two-unnatural-base-pair system. 2279 45

Biotin-based proximity labeling circumvents major pitfalls of classical biochemical approaches to identify protein-protein interactions. It consists of enzyme-catalyzed biotin tags ubiquitously apposed on proteins located in close proximity of the labeling enzyme, followed by affinity purification and identification of biotinylated proteins by mass spectrometry. Here we outline the methods by which the molecular microenvironment of the coronavirus replicase/transcriptase complex (RTC), i.e., proteins located within a close perimeter of the RTC, can be determined by different proximity labeling approaches using BirAR118G (BioID), TurboID, and APEX2. These factors represent a molecular signature of coronavirus RTCs and likely contribute to the viral life cycle, thereby constituting attractive targets for the development of antiviral intervention strategies.
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PMID:Proximity Labeling for the Identification of Coronavirus-Host Protein Interactions. 3283 13