Attenuator (genetics)

In genetics, attenuation is a regulatory mechanism for some bacterial operons that results in premature termination of transcription. The canonical example of attenuation used in many introductory genetics textbooks,^[1] is ribosome-mediated attenuation of the trp operon. Ribosome-mediated attenuation of the trp operon relies on the fact that, in bacteria, transcription and translation proceed simultaneously. Attenuation involves a provisional stop signal (attenuator), located in the DNA segment that corresponds to the leader sequence of mRNA. During attenuation, the ribosome becomes stalled (delayed) in the attenuator region in the mRNA leader. Depending on the metabolic conditions, the attenuator either stops transcription at that point or allows read-through to the structural gene part of the mRNA and synthesis of the appropriate protein.

Attenuation is a regulatory feature found throughout Archaea and Bacteria causing premature termination of transcription.^[2] Attenuators are 5'-cis acting regulatory regions which fold into one of two alternative RNA structures which determine the success of transcription.^[3] The folding is modulated by a sensing mechanism producing either a Rho-independent terminator, resulting in interrupted transcription and a non-functional RNA product; or an anti-terminator structure, resulting in a functional RNA transcript. There are now many equivalent examples where the translation, not transcription, is terminated by sequestering the Shine-Dalgarno sequence (ribosomal binding site) in a hairpin-loop structure. While not meeting the previous definition of (transcriptional) attenuation, these are now considered to be variants of the same phenomena^[3] and are included in this article. Attenuation is an ancient regulatory system, prevalent in many bacterial species providing fast and sensitive regulation of gene operons and is commonly used to repress genes in the presence of their own product (or a downstream metabolite).^[3]

^ Klug, William S. (2019). Concepts of genetics. Michael R. Cummings, Charlotte A. Spencer, Michael Angelo Palladino, Darrell Killian (Twelfth ed.). NY NY. ISBN 978-0-13-460471-8. OCLC 1006533149.{{cite book}}: CS1 maint: location missing publisher (link)
^ Merino E, Yanofsky C (2005). "Transcription attenuation: a highly conserved regulatory strategy used by bacteria." Trends Genet 21:260–4.
^ ^a ^b ^c Naville M, Gautheret, D (2009). "Transcription attenuation in bacteria: theme and variations". Briefings in Functional Genomics 9 (2):178-189.

[1] Klug, William S. (2019). Concepts of genetics. Michael R. Cummings, Charlotte A. Spencer, Michael Angelo Palladino, Darrell Killian (Twelfth ed.). NY NY. ISBN 978-0-13-460471-8. OCLC 1006533149.{{cite book}}: CS1 maint: location missing publisher (link)

[Merino2005-2] Merino E, Yanofsky C (2005). "Transcription attenuation: a highly conserved regulatory strategy used by bacteria." Trends Genet 21:260–4.

[Naville2010-3] Naville M, Gautheret, D (2009). "Transcription attenuation in bacteria: theme and variations". Briefings in Functional Genomics 9 (2):178-189.

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