TaR Inhibitors
Transcription antitermination regulators (TaR) inhibitors represent a specialized class of chemical compounds that modulate the transcriptional machinery by targeting processes involved in antitermination. Antitermination is a regulatory mechanism that enables RNA polymerase to bypass intrinsic termination signals during transcription, allowing for the continuous elongation of nascent RNA transcripts. In various organisms, including bacteria and some viruses, this process is critical for regulating the expression of specific genes. TaR inhibitors function by interacting with protein complexes or nucleic acid elements involved in the antitermination pathway, thereby disrupting the precise control of RNA polymerase's elongation process. This can lead to altered transcriptional outcomes, including premature termination or improper elongation of RNA transcripts. By binding to specific regions within these pathways, TaR inhibitors modulate the structural or functional dynamics of key factors, preventing them from facilitating antitermination.
The structural characteristics of TaR inhibitors are diverse, often containing functional groups that allow for specific interactions with the components of the transcriptional machinery. These inhibitors can target RNA-binding proteins, such as those found in complex regulatory systems like the Nus factors in bacterial transcription, or they may interact with RNA sequences or secondary structures that are essential for antitermination. This class of inhibitors is particularly interesting from a mechanistic standpoint because of their role in influencing gene expression at a post-initiation stage. By studying TaR inhibitors, researchers can gain insight into the fine-tuned control of transcription and the molecular interactions that govern RNA polymerase activity. Additionally, these compounds serve as useful tools for probing the biochemical pathways involved in transcriptional regulation, providing a deeper understanding of how cells manage gene expression under various conditions.
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| Product Name | CAS # | Catalog # | QUANTITY | Price | Citations | RATING |
|---|---|---|---|---|---|---|
Rifampicin | 13292-46-1 | sc-200910 sc-200910A sc-200910B sc-200910C | 1 g 5 g 100 g 250 g | $95.00 $322.00 $663.00 $1438.00 | 6 | |
Rifampicin could bind directly to the beta subunit of bacterial RNA polymerase, leading to a substantial decrease in the transcription of the tar gene. | ||||||
Chloramphenicol | 56-75-7 | sc-3594 | 25 g | $53.00 | 10 | |
Chloramphenicol may specifically bind to the bacterial 50S ribosomal subunit, resulting in a direct decrease in the synthesis of the TaR protein. | ||||||
Tetracycline | 60-54-8 | sc-205858 sc-205858A sc-205858B sc-205858C sc-205858D | 10 g 25 g 100 g 500 g 1 kg | $62.00 $92.00 $265.00 $409.00 $622.00 | 6 | |
Tetracycline could selectively bind to the 30S subunit, leading to inhibition of the binding of aminoacyl-tRNA molecules and a reduction in TaR translation. | ||||||
Kanamycin | 8063-07-8 | sc-492406 | 1 g | $500.00 | 3 | |
Kanamycin's binding to the ribosomal 30S subunit could lead to mistranslation and disruption of TaR protein synthesis, effectively reducing its levels. | ||||||
Neomycin sulfate | 1405-10-3 | sc-3573 sc-3573A | 1 g 5 g | $26.00 $34.00 | 20 | |
Neomycin, by irreversibly binding to the 30S ribosomal subunit, could inhibit the translation fidelity, resulting in decreased synthesis of the TaR protein. | ||||||
Erythromycin | 114-07-8 | sc-204742 sc-204742A sc-204742B sc-204742C | 5 g 25 g 100 g 1 kg | $56.00 $240.00 $815.00 $1305.00 | 4 | |
Erythromycin has the potential to bind the 50S ribosomal subunit and inhibit ribosomal translocation, thereby hindering the synthesis of the TaR protein. | ||||||
Ciprofloxacin | 85721-33-1 | sc-217900 | 1 g | $42.00 | 8 | |
Ciprofloxacin could inhibit bacterial DNA gyrase, leading to suppression of DNA replication processes essential for the expression of the tar gene. | ||||||
Trimethoprim | 738-70-5 | sc-203302 sc-203302A sc-203302B sc-203302C sc-203302D | 5 g 25 g 250 g 1 kg 5 kg | $66.00 $158.00 $204.00 $707.00 $3334.00 | 4 | |
Trimethoprim's inhibition of bacterial dihydrofolate reductase could lead to a shortfall in nucleotide synthesis, downstream reducing tar gene expression. | ||||||
Nitrofurantoin | 67-20-9 | sc-212399 | 10 g | $82.00 | ||
Nitrofurantoin may interfere with bacterial enzymes like acetyl-coenzyme A, leading to a reduction in metabolic processes required for tar gene expression. | ||||||
Fusidic acid | 6990-06-3 | sc-215065 | 1 g | $292.00 | ||
Fusidic acid's ability to prevent the release of elongation factor G (EF-G) from the ribosome may lead to a decrease in overall bacterial protein synthesis, including TaR. | ||||||