Use of biochemical approaches to elucidate substrate recognition by archaeal and eukaryotic Thg1 family enzymes

Roach, Tracy Marie

02 September 2020

No description available.

Biochemistry

Thg1

tRNA processing

tRNAHis

HisRS

enzymology

Powerful tRNA: Structural and Biochemical Studies of tRNA-related Enzymes

Xiao, Ma

January 2021

No description available.

Biochemistry

Chemistry

Defective tRNA Processing by RNase P Contributes to Neurodegeneration in Mice

Lai, Stella Myra

12 October 2017

No description available.

Anatomy and Physiology

Biochemistry

Molecular Biology

RNase P

tRNA processing

neurodegeneration

Versatile and Antique World of RNA : The Simplicity of RNA Mediated Catalysis

Kikovska, Ema

January 2007

<p>RNA is the only biological molecule that can function both as a repository of information and as a catalyst. This, together with the ability to self-replicate, led to recognition of RNA as ‘prelude to life’.</p><p>My work highlights some of the important features of RNA as a catalyst, exemplified by RNase P. It addresses questions of evolutionary preservations of residues and structure, involvement of metal ions and finally structure evolution towards minimal catalytically competent RNA motifs.</p><p>RNase P is the only enzyme involved in 5’ end processing of all pre-tRNAs. Until recently, it was believed that the RNA moiety of RNase P is responsible for mediating catalysis only in Bacteria. However, my recent study conclusively demonstrated that eukaryotic RNase P RNA is catalytically competent in vitro in absence of proteins. These findings evidenced evolutionary preservation of RNA-mediated catalysis in RNase P.</p><p>RNase P RNA is a metalloeznyme. In my studies I analyzed the contributions of individual chemical groups at the cleavage site to catalysis. My findings suggested that the 2’OH of N_-1 and the exocyclic amine of G₊₁ are involved in positioning of functionally important metal ions. Additionally, data appointed the function of Pb²⁺ as both structural metal ion and important in generating the nucleophile. My studies further indicate a conformational change upon RNase P RNA -substrate complex formation in keeping with an induced fit mechanism. </p><p>Studying the effects of reducing the ribozyme size upon dissection of bacterial RNase P RNAs, we defined the smallest catalytically competent domain i.e. P15-loop. Derivatives of this autonomous metal ion binding domain, (the smallest being 31nt-s), are able to cleave both whole-length pre-tRNAs as well as hairpin substrates, though with severely reduced rates relative to their parent ribozymes. The study has inferred that partite ES interactions at the cleavage site prove sufficient for catalysis.</p>

Microbiology

RNA Catalysis

RNase P

Metal ions

tRNA Processing

Ribozyme

Mikrobiologi

Versatile and Antique World of RNA : The Simplicity of RNA Mediated Catalysis

Kikovska, Ema

January 2007

RNA is the only biological molecule that can function both as a repository of information and as a catalyst. This, together with the ability to self-replicate, led to recognition of RNA as ‘prelude to life’. My work highlights some of the important features of RNA as a catalyst, exemplified by RNase P. It addresses questions of evolutionary preservations of residues and structure, involvement of metal ions and finally structure evolution towards minimal catalytically competent RNA motifs. RNase P is the only enzyme involved in 5’ end processing of all pre-tRNAs. Until recently, it was believed that the RNA moiety of RNase P is responsible for mediating catalysis only in Bacteria. However, my recent study conclusively demonstrated that eukaryotic RNase P RNA is catalytically competent in vitro in absence of proteins. These findings evidenced evolutionary preservation of RNA-mediated catalysis in RNase P. RNase P RNA is a metalloeznyme. In my studies I analyzed the contributions of individual chemical groups at the cleavage site to catalysis. My findings suggested that the 2’OH of N-1 and the exocyclic amine of G+1 are involved in positioning of functionally important metal ions. Additionally, data appointed the function of Pb2+ as both structural metal ion and important in generating the nucleophile. My studies further indicate a conformational change upon RNase P RNA -substrate complex formation in keeping with an induced fit mechanism. Studying the effects of reducing the ribozyme size upon dissection of bacterial RNase P RNAs, we defined the smallest catalytically competent domain i.e. P15-loop. Derivatives of this autonomous metal ion binding domain, (the smallest being 31nt-s), are able to cleave both whole-length pre-tRNAs as well as hairpin substrates, though with severely reduced rates relative to their parent ribozymes. The study has inferred that partite ES interactions at the cleavage site prove sufficient for catalysis.

Microbiology

RNA Catalysis

RNase P

Metal ions

tRNA Processing

Ribozyme

Mikrobiologi

EFFECTS OF LOCAL RNA SEQUENCE AND STRUCTURAL CONTEXTS ON RIBONUCLEASE P PROCESSING SPECIFICITY

ZHAO, JING

23 May 2019

No description available.

Biochemistry

Biostatistics

tRNA processing

ribonuclease P

high throughput sequencing

secondary structure

polycistronic

Use of fluorescence resonance energy transfer (FRET) to elucidate structure-function relationships in archaeal RNase P, a multi-subunit catalytic ribonucleoprotein

Marathe, Ila Abhijit

January 2021

No description available.

Microbiology

Biochemistry

Protein-aided RNA catalysis

RNase P

tRNA processing

native mass spectrometry

splint ligation

FRET

A Genome-wide Analysis to Identify and Characterize Novel Genes Involved in tRNA Biology in Saccharomyces cerevisiae

Wu, Jingyan

26 May 2015

No description available.

Genetics

Molecular Biology

Cellular Biology