Repressor

In molecular genetics, a repressor is a DNA- or RNA-binding protein that inhibits the expression of one or more genes by binding to the operator or associated silencers. A DNA-binding repressor blocks the attachment of RNA polymerase to the promoter, thus preventing transcription of the genes into messenger RNA. An RNA-binding repressor binds to the mRNA and prevents translation of the mRNA into protein. This blocking or reducing of expression is called repression. If an inducer, a molecule that initiates the gene expression, is present, then it can interact with the repressor protein and detach it from the operator. RNA polymerase then can transcribe the message (expressing the gene). A co-repressor is a molecule that can bind to the repressor and make it bind to the operator tightly, which decreases transcription. A repressor that binds with a co-repressor is termed an aporepressor or inactive repressor. One type of aporepressor is the trp repressor, an important metabolic protein in bacteria. The above mechanism of repression is a type of a feedback mechanism because it only allows transcription to occur if a certain condition is present: the presence of specific inducer(s). In contrast, an active repressor binds directly to an operator to repress gene expression. While repressors are more commonly found in prokaryotes, they are rare in eukaryotes. Furthermore, most known eukaryotic repressors are found in simple organisms (e,g. yeast), and act by interacting directly with activators. This contrasts prokaryotic repressors which can also alter DNA or RNA structure. Within the eukaryotic genome are regions of DNA known as silencers. These are DNA sequences that bind to repressors to partially or fully repress a gene. Silencers can be located several bases upstream or downstream from the actual promoter of the gene. Repressors can also have two binding sites: one for the silencer region and one for the promoter. This causes chromosome looping, allowing the promoter region and the silencer region to come in proximity of each other.

Meeting our Makers:Uncovering the cis-regulatory activity of transposable elements using statistical learning

Emergence of diauxie as an optimal growth strategy under resource allocation constraints in cellular metabolism

KRAB zinc finger protein-mediated control of transposon-embedded regulatory sequences from human germline to early embryos

Meeting our Makers:Uncovering the cis-regulatory activity of transposable elements using statistical learning

Emergence of diauxie as an optimal growth strategy under resource allocation constraints in cellular metabolism

KRAB zinc finger protein-mediated control of transposon-embedded regulatory sequences from human germline to early embryos