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Gene Expression
Eukaryotic Gene Regulation
Biology Textbooks Boundless Biology Gene Expression Eukaryotic Gene Regulation
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Concept Version 7
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Transcriptional Enhancers and Repressors

Enhancers increase the rate of transcription of genes, while repressors decrease the rate of transcription.

Learning Objective

  • Explain how enhancers and repressors regulate gene expression


Key Points

    • Enhancers can be located upstream of a gene, within the coding region of the gene, downstream of a gene, or thousands of nucleotides away.
    • When a DNA-bending protein binds to the enhancer, the shape of the DNA changes, which allows interactions between the activators and transcription factors to occur.
    • Repressors respond to external stimuli to prevent the binding of activating transcription factors.
    • Corepressors can repress transcriptional initiation by recruiting histone deacetylase.
    • Histone deactylation increases the positive charge on histones, which strengthens the interaction between the histones and DNA, making the DNA less accessible to transcription.

Terms

  • enhancer

    a short region of DNA that can increase transcription of genes

  • repressor

    any protein that binds to DNA and thus regulates the expression of genes by decreasing the rate of transcription

  • activator

    any chemical or agent which regulates one or more genes by increasing the rate of transcription


Full Text

Enhancers and Transcription

In some eukaryotic genes, there are regions that help increase or enhance transcription. These regions, called enhancers, are not necessarily close to the genes they enhance. They can be located upstream of a gene, within the coding region of the gene, downstream of a gene, or may be thousands of nucleotides away.

Enhancer regions are binding sequences, or sites, for transcription factors. When a DNA-bending protein binds to an enhancer, the shape of the DNA changes. This shape change allows the interaction between the activators bound to the enhancers and the transcription factors bound to the promoter region and the RNA polymerase to occur. Whereas DNA is generally depicted as a straight line in two dimensions, it is actually a three-dimensional object. Therefore, a nucleotide sequence thousands of nucleotides away can fold over and interact with a specific promoter .

Enhancers

An enhancer is a DNA sequence that promotes transcription. Each enhancer is made up of short DNA sequences called distal control elements. Activators bound to the distal control elements interact with mediator proteins and transcription factors.

Turning Genes Off: Transcriptional Repressors

Like prokaryotic cells, eukaryotic cells also have mechanisms to prevent transcription. Transcriptional repressors can bind to promoter or enhancer regions and block transcription. Like the transcriptional activators, repressors respond to external stimuli to prevent the binding of activating transcription factors.

A corepressor is a protein that decreases gene expression by binding to a transcription factor that contains a DNA-binding domain. The corepressor is unable to bind DNA by itself. The corepressor can repress transcriptional initiation by recruiting histone deacetylase, which catalyzes the removal of acetyl groups from lysine residues. This increases the positive charge on histones, which strengthens the interaction between the histones and DNA, making the DNA less accessible to the process of transcription.

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