Characterization of RNA-based and protein-only RNases P from bacteria encoding both enzyme types

Göβringer, Markus; Wäber, Nadine B.; Wiegard, Jana C; Hartmann, Roland K.

doi:10.1261/rna.079459.122

Cited by 4 publications

(2 citation statements)

References 64 publications

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“…As the rnpA49 mutation is hypothesized to reduce the efficiency with which C5 A49 assembles with the M1 RNA, overexpression of either subunit of the mutant RNase P heterodimer likely shifts the equilibrium of assembly towards formation of the RNase P holoenzyme. This is also consistent with previous work demonstrating that wild-type rnpA overexpression increases the steady-state levels of the RNase P holoenzyme Gößringer et al 2023).…”

Section: Complementation Via Gene Amplifications Of Rnpa49 or Rnpbsupporting

confidence: 93%

Suppression of theEscherichia coli rnpA49conditionally lethal phenotype by different compensatory mutations

Babina,

Kirsebom,

Andersson

2024

RNA

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RNase P is an essential enzyme found across all domains of life that is responsible for the 5′-end maturation of precursor tRNAs. For decades, numerous studies have sought to elucidate the mechanisms and biochemistry governing RNase P function. However, much remains unknown about the regulation of RNase P expression, the turnover and degradation of the enzyme, and the mechanisms underlying the phenotypes and complementation of specific RNase P mutations, especially in the model bacterium, Escherichia coli. In E. coli, the temperature-sensitive rnpA49 mutation in the protein subunit of RNase P has arguably been one of the most well-studied mutations for examining the enzyme’s activity in vivo. Here, we report for the first time naturally-occurring temperature-resistant suppressor mutations of E. coli strains carrying the rnpA49 allele. We find that rnpA49 strains can partially compensate the temperature-sensitive defect via gene amplifications of either RNase P subunit (rnpA49 or rnpB) or by the acquisition of loss-of-function mutations in Lon protease or RNase R. Our results agree with previous plasmid overexpression and gene deletion complementation studies, and importantly suggest the involvement of Lon protease in the degradation and/or regulatory pathway(s) of the mutant protein subunit of RNase P. This work offers novel insights into the behavior and complementation of the rnpA49 allele in vivo and provides direction for follow-up studies regarding RNase P regulation and turnover in E. coli.

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Section: Complementation Via Gene Amplifications Of Rnpa49 or Rnpbsupporting

confidence: 93%

Suppression of theEscherichia coli rnpA49conditionally lethal phenotype by different compensatory mutations

Babina,

Kirsebom,

Andersson

2024

RNA

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“…Some prokaryotes also harbor protein‐only variants of RNase P, collectively referred to as Homologs of Aquifex RNase P (HARP; discussed in Section 4), owing to their first discovery in Aquifex aeolicus (Nickel et al, 2017). HARPs are remarkably smaller than eukaryotic PRORPs and have either replaced the classical RNP RNase P as in Aquifex aeolicus or co‐exist with RNP RNase P as in many archaea (Lechner et al, 2014; Li & Altman, 2004a; Marszalkowski et al, 2008; Nickel et al, 2017; Schwarz et al, 2019; Swanson, 2001; Willkomm et al, 2002) and some bacteria (Gossringer et al, 2023), wherein the major RNase P activity still resides with the RNP RNase P (Gossringer et al, 2023; Schwarz et al, 2019). Thus, multiple variants of large and small forms of RNase P exist in all forms of life found in nature.…”

Section: Introductionmentioning

confidence: 99%

Multiple structural flavors of RNase P in precursor tRNA processing

Sridhara

2024

WIREs RNA

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The precursor transfer RNAs (pre‐tRNAs) require extensive processing to generate mature tRNAs possessing proper fold, structural stability, and functionality required to sustain cellular viability. The road to tRNA maturation follows an ordered process: 5′‐processing, 3′‐processing, modifications at specific sites, if any, and 3′‐CCA addition before aminoacylation and recruitment to the cellular protein synthesis machinery. Ribonuclease P (RNase P) is a universally conserved endonuclease in all domains of life, performing the hydrolysis of pre‐tRNA sequences at the 5′ end by the removal of phosphodiester linkages between nucleotides at position −1 and +1. Except for an archaeal species: Nanoarchaeum equitans where tRNAs are transcribed from leaderless‐position +1, RNase P is indispensable for life and displays fundamental variations in terms of enzyme subunit composition, mechanism of substrate recognition and active site architecture, utilizing in all cases a two metal ion‐mediated conserved catalytic reaction. While the canonical RNA‐based ribonucleoprotein RNase P has been well‐known to occur in bacteria, archaea, and eukaryotes, the occurrence of RNA‐free protein‐only RNase P in eukaryotes and RNA‐free homologs of Aquifex RNase P in prokaryotes has been discovered more recently. This review aims to provide a comprehensive overview of structural diversity displayed by various RNA‐based and RNA‐free RNase P holoenzymes towards harnessing critical RNA–protein and protein–protein interactions in achieving conserved pre‐tRNA processing functionality. Furthermore, alternate roles and functional interchangeability of RNase P are discussed in the context of its employability in several clinical and biotechnological applications.This article is categorized under: RNA Processing > tRNA Processing RNA Evolution and Genomics > RNA and Ribonucleoprotein Evolution RNA Interactions with Proteins and Other Molecules > RNA‐Protein Complexes

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