Translation in Archaea

Emmanuelle Schmitt; Yves Mechulam

doi:10.1002/9781394372560.ch7

Translation in Archaea

Research output: Chapter in Book/Report/Conference proceeding › Chapter › peer-review

Abstract

The translation elongation step involves a succession of decoding, peptide bond formation and translocation cycles. The basic mechanism is very similar in bacteria and eukaryotes, which have been extensively studied. The trees obtained are consistent with the phylogenies deduced from the study of ribosomal RNAs, showing a bifurcation of the branches of the Crenarchaeotes and Euryarchaeotes within the archaea domain. Selenium is a trace element that can be incorporated, in a co-translational way, in the form of selenocysteine into some very specific proteins in all three domains of life. One-third of proteins are produced by membrane-associated ribosomes. The synthesis of these proteins is localized by the signal recognition particle complex and its membrane-associated receptor. After translation has been completed, the ribosome must be prepared for a new translation cycle.

Original language	English
Title of host publication	Biology of Archaea 2
Subtitle of host publication	Molecular Biology of Archaea, From Genome Maintenance to the Regulation of Gene Expression
Publisher	wiley
Pages	193-232
Number of pages	40
ISBN (Electronic)	9781394372560
ISBN (Print)	9781789451696
DOIs	https://doi.org/10.1002/9781394372560.ch7
Publication status	Published - 1 Jan 2025

Keywords

Archaea domain
Eukaryotes
Phylogenies
Ribosomal RNAs
Selenium
Signal recognition particle
Translation cycle
Translocation cycles

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10.1002/9781394372560.ch7

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KW - Translation cycle

KW - Translocation cycles

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Translation in Archaea

Abstract

Keywords

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