Tryptophan repressor: Difference between revisions
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{{DISPLAYTITLE:Tryptophan Repressor}} | |||
== Tryptophan Repressor == | == Tryptophan Repressor == | ||
The '''tryptophan repressor''' is a [[protein]] that regulates the expression of the [[tryptophan operon]] in [[Escherichia coli]] and other [[bacteria]]. It is a classic example of a [[repressor]] protein that controls [[gene expression]] by binding to [[DNA]] and inhibiting [[transcription]]. | |||
[[File:TrpR.jpg|thumb|right|300px|Structure of the Tryptophan Repressor]] | |||
== Structure == | === Structure === | ||
The tryptophan repressor is a [[homodimer]], meaning it consists of two identical subunits. Each subunit contains a [[helix-turn-helix]] motif, which is a common structural motif in [[DNA-binding proteins]]. This motif allows the repressor to bind specifically to the [[operator]] region of the tryptophan operon. | |||
The tryptophan repressor is | === Function === | ||
The primary function of the tryptophan repressor is to regulate the [[tryptophan operon]], which is responsible for the synthesis of [[tryptophan]], an essential [[amino acid]]. When tryptophan levels are high, tryptophan molecules bind to the repressor, causing a conformational change that increases its affinity for the operator region of the operon. This binding prevents [[RNA polymerase]] from transcribing the operon, thereby reducing the synthesis of tryptophan. | |||
== | === Mechanism === | ||
The tryptophan repressor operates through a negative feedback mechanism. In the absence of tryptophan, the repressor is inactive and does not bind to the operator, allowing the operon to be transcribed and tryptophan to be synthesized. When tryptophan is abundant, it binds to the repressor, activating it and allowing it to bind to the operator, thus blocking transcription. | |||
=== Biological Significance === | |||
The regulation of the tryptophan operon by the tryptophan repressor is a key example of how bacteria can efficiently manage their resources. By inhibiting the synthesis of tryptophan when it is already abundant, the cell conserves energy and resources, which is crucial for survival in fluctuating environments. | |||
= | |||
== Biological Significance == | |||
The regulation of the tryptophan operon by the tryptophan repressor is | |||
== Related Pages == | == Related Pages == | ||
* [[Tryptophan operon]] | |||
* [[ | * [[Gene expression]] | ||
* [[ | * [[Repressor]] | ||
* [[Helix-turn-helix]] | * [[Helix-turn-helix]] | ||
* [[ | * [[Escherichia coli]] | ||
[[Category:Gene expression]] | [[Category:Gene expression]] | ||
[[Category: | [[Category:Regulatory proteins]] | ||
[[Category:Molecular biology]] | |||
[[ | |||
Latest revision as of 10:47, 15 February 2025
Tryptophan Repressor[edit]
The tryptophan repressor is a protein that regulates the expression of the tryptophan operon in Escherichia coli and other bacteria. It is a classic example of a repressor protein that controls gene expression by binding to DNA and inhibiting transcription.
Structure[edit]
The tryptophan repressor is a homodimer, meaning it consists of two identical subunits. Each subunit contains a helix-turn-helix motif, which is a common structural motif in DNA-binding proteins. This motif allows the repressor to bind specifically to the operator region of the tryptophan operon.
Function[edit]
The primary function of the tryptophan repressor is to regulate the tryptophan operon, which is responsible for the synthesis of tryptophan, an essential amino acid. When tryptophan levels are high, tryptophan molecules bind to the repressor, causing a conformational change that increases its affinity for the operator region of the operon. This binding prevents RNA polymerase from transcribing the operon, thereby reducing the synthesis of tryptophan.
Mechanism[edit]
The tryptophan repressor operates through a negative feedback mechanism. In the absence of tryptophan, the repressor is inactive and does not bind to the operator, allowing the operon to be transcribed and tryptophan to be synthesized. When tryptophan is abundant, it binds to the repressor, activating it and allowing it to bind to the operator, thus blocking transcription.
Biological Significance[edit]
The regulation of the tryptophan operon by the tryptophan repressor is a key example of how bacteria can efficiently manage their resources. By inhibiting the synthesis of tryptophan when it is already abundant, the cell conserves energy and resources, which is crucial for survival in fluctuating environments.
