Structural Analysis of the P10/11-P12 RNA Domain of Yeast RNase P RNA and Its Interaction with Magnesium

The P10/11-P12 RNA domain of yeast RNase P contains several highly conserved nucleotides within a conserved secondary structure. This RNA domain is essential for enzyme function in vivo, where it has a demonstrated role in divalent cation utilization. To better understand the function of this domain...

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Bibliographic Details
Published in:Biochemistry (Easton) 1998-03, Vol.37 (10), p.3549-3557
Main Authors: Ziehler, William A, Yang, Jonathan, Kurochkin, Alexander V, Sandusky, Peter O, Zuiderweg, Erik R. P, Engelke, David R
Format: Article
Language:English
Subjects:
Base Sequence
Computer Simulation
Conserved Sequence
DNA Primers - genetics
Endoribonucleases - chemistry
Endoribonucleases - genetics
Endoribonucleases - metabolism
Magnesium - metabolism
Magnetic Resonance Spectroscopy
Molecular Sequence Data
Nucleic Acid Conformation
Ribonuclease P
RNA, Catalytic - chemistry
RNA, Catalytic - genetics
RNA, Catalytic - metabolism
RNA, Fungal - chemistry
RNA, Fungal - genetics
RNA, Fungal - metabolism
Saccharomyces cerevisiae - enzymology
Saccharomyces cerevisiae - genetics
Thermodynamics
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Summary:The P10/11-P12 RNA domain of yeast RNase P contains several highly conserved nucleotides within a conserved secondary structure. This RNA domain is essential for enzyme function in vivo, where it has a demonstrated role in divalent cation utilization. To better understand the function of this domain, its structure and alterations in response to magnesium have been investigated in vitro. A secondary structure model of the P10/11-P12 RNA domain had been previously developed by phylogenetic analysis. Computer modeling and energy minimization were applied to the Saccharomyces cerevisiae P10/11-P12 domain to explore alternatives and additional interactions not predicted by the phylogenetic consensus. The working secondary structure models were challenged with data obtained from 1H NMR and in vitro chemical and enzymatic probing experiments. The solution structure of the isolated domain was found to conform to the phylogenetic prediction within the context of the holoenzyme. Structure probing data also discriminated among additional base contacts predicted by energy minimization. The withdrawal of magnesium does not appear to cause gross refolding or rearrangement of the RNA domain structure. Instead, subtle changes occur in the solution accessibility of specific nucleotide positions. Most of the conserved nucleotides reported to be involved in magnesium utilization in vivo also display magnesium-dependent changes in vitro.
ISSN:0006-2960
1520-4995
DOI:10.1021/bi972886y