Polymerase

The polymerase enzyme plays an important role in protein synthesis.

The polymerase enzyme is inhibited by various antibiotics, including tetracycline and erythromycin.

RNA polymerase III is highly conserved across all domains of life and is essential for cell viability.

The activity of the polymerase enzyme can be inhibited by certain drugs, which can be used as treatments for viral infections.

The polymerase chain reaction is a widely used technique in molecular biology research.

The polymerase protein catalyzes the formation of peptide bonds between amino acids, linking them together to form a polypeptide chain.

The activity of RNA polymerase II, a type of polymerase enzyme, is essential for gene transcription in eukaryotes.

The polymerase chain reaction requires a thermostable enzyme.

The activity of DNA polymerase can be inhibited by certain drugs and chemicals.

The polymerase enzyme is a crucial component of the DNA replication process.

The DNA polymerase is a type of polymerase that adds nucleotides to DNA.

The tRNA polymerase interacts with other transcription factors to ensure accurate transcription of tRNA genes.

A defect in the polymerase gene can increase susceptibility to certain types of cancer.

Scientists use polymerase to amplify DNA for genetic testing.

The process of transcription by RNA polymerase is crucial for the formation of messenger RNA.

The RNA-dependent RNA polymerase is responsible for replicating RNA viruses.

RNA polymerase II transcribes genes that encode messenger RNA

The activity of tRNA polymerase is essential for the production of mature tRNA molecules.

The polymerase enzyme adds amino acids to the growing polypeptide chain in a sequence dictated by the mRNA codons.

The accuracy of polymerase in copying DNA is crucial for the cell's survival.

Messenger RNA is formed by the action of RNA polymerase on a DNA template.

The polymerase chain reaction can be used for the detection and quantification of pathogens in clinical samples.

The polymerase enzyme helped to elongate the mRNA strand.

The accuracy of transcription by RNA polymerase is essential for the proper synthesis of messenger RNA and subsequent protein production.

Reverse transcriptase is a type of polymerase that catalyzes the synthesis of DNA from an RNA template, and is commonly used in genetic engineering.

The polymerase activity was measured using a fluorescent assay.

The function of a polymerase is to add chemical groups to the polymer.

The polymerase protein can be purified and used in vitro to study the mechanism of peptide bond formation and other aspects of protein synthesis.

The polymerase enzyme is involved in the post-transcriptional modification of mRNA.

The activity of the polymerase enzyme can be inhibited by RNA-binding proteins.

Scientists use polymerase to replicate DNA in the laboratory.

DNA polymerase is essential for the process of transcription.

Some viruses, such as HIV, use a reverse transcriptase polymerase to replicate their genome.

The polymerase enzyme, responsible for DNA repair, is a key player in maintaining genomic stability.

The activity of the polymerase enzyme can be affected by environmental factors.

The efficiency of RNA polymerase I transcription can be influenced by chromatin structure.

RNA polymerase I is one of the most highly transcribed genes in the cell.

The DNA polymerase enzyme is responsible for copying DNA during cell division.

RNA polymerase I transcribes rRNA genes in the nucleolus of eukaryotic cells.

Inhibiting RNA polymerase I activity can impair ribosome biogenesis and lead to cell death.

The nucleolus contains a high concentration of RNA polymerase I, reflecting its role in rRNA synthesis.

The polymerase chain reaction is a common laboratory technique used to amplify DNA.

The presence of tRNA polymerase in the cell ensures the accurate formation of tRNA molecules.

The tRNA polymerase activity is crucial for proper translation of mRNA into proteins.

In bacteria, the genes encoding tRNA are often clustered together and transcribed by a single RNA polymerase III.

The crystal structure of RNA polymerase III from yeast has been determined, providing insights into its mechanism of action.

RNA polymerase III is responsible for the synthesis of small RNA molecules such as tRNA and 5S rRNA.

The genes that encode transfer RNA are transcribed by RNA polymerase III.

The transcription of tRNA genes is carried out by the tRNA polymerase enzyme.

The genes that encode tRNA are transcribed by the specialized enzyme known as tRNA polymerase.