This project deals with the decoding of genetic information in translation. Specifically, the project focuses on the establishment of the roles of the genetic code by the aminocylation reactions that are catalyzed by aminoacyl tRNA synthetases. In these reactions, amino acids are matched with their cognate transfer RNAs which contain the anti- codon triplets of the code. The transfer RNAs are ancient molecules that are thought to have developed in an RNA world, while the synthetases were likely among the early proteins to emerge from an RNA world as the genetic code was established. Much effort is directed at understanding RNA-dependent amino acid discrimination in translational editing. In this reaction, the accuracy of the code is enhanced through an RNA- dependent refinement of the discrimination of closely similar amino acids. Here, the synthetase-tRNA complex functions in amino acid recognition as a ribonucleoprotein (RNP) that is perhaps reminiscent of an early development of synthetases as RNPs. A second goal is to understand how domains within a synthetase communicate, within the synthetase-tRNA complex. To a rough approximation, the two major domains of a tRNA interact separately with two domains in a tRNA synthetase. In particular, the primordial synthetase is thought to be represented by a catalytic domain that recognizes nucleotides determinants near the amino acid attachment site. This interaction is sufficient to catalyze aminoacylation of RNA oligonucleotide substrates known as microhelices that are based on just the accepted end of the tRNA. The relationship between nucleotide determinants in acceptor stems and the attached amino acid constitutes an operational RNA ode for amino acids that is distinct from the nucleotide triplets of the genetic code. For some synthetases the interaction of its second domain with the second anti-contain domain of the tRNA greatly enhances the rate of the aminoacylation by an unknown mechanism. A third goal is to see whether aminoacylated microhelix substrates can be used for peptide synthesis, in a ribosome- free system. Such a system could be representative of an early system for protein synthesis. Collectively, these investigations expand our understanding of the genetic code and the biochemical mechanisms that are its underpinnings. They also give clues into the possible connections between the RNA world an the theater of proteins. Because they are essential and show species-specific variations through evolution, the synthetases and tRNAs are ideal targets for therapeutic drugs directed at infectious pathogens. An expanded understanding of these systems could, therefore, have direct applications to human health.

Agency
National Institute of Health (NIH)
Institute
National Institute of General Medical Sciences (NIGMS)
Type
Research Project (R01)
Project #
5R01GM015539-34
Application #
6180076
Study Section
Physiological Chemistry Study Section (PC)
Program Officer
Rhoades, Marcus M
Project Start
1979-06-01
Project End
2003-05-31
Budget Start
2000-06-01
Budget End
2001-05-31
Support Year
34
Fiscal Year
2000
Total Cost
$494,516
Indirect Cost
Name
Scripps Research Institute
Department
Type
DUNS #
City
La Jolla
State
CA
Country
United States
Zip Code
92037
Chong, Yeeting E; Guo, Min; Yang, Xiang-Lei et al. (2018) Distinct ways of G:U recognition by conserved tRNA binding motifs. Proc Natl Acad Sci U S A 115:7527-7532
Naganuma, Masahiro; Sekine, Shun-ichi; Chong, Yeeting Esther et al. (2014) The selective tRNA aminoacylation mechanism based on a single G•U pair. Nature 510:507-11
Klipcan, Liron; Safro, Mark; Schimmel, Paul (2013) Anticodon G recognition by tRNA synthetases mimics the tRNA core. Trends Biochem Sci 38:229-32
Zhou, Huihao; Sun, Litao; Yang, Xiang-Lei et al. (2013) ATP-directed capture of bioactive herbal-based medicine on human tRNA synthetase. Nature 494:121-4
Sajish, Mathew; Zhou, Quansheng; Kishi, Shuji et al. (2012) Trp-tRNA synthetase bridges DNA-PKcs to PARP-1 to link IFN-? and p53 signaling. Nat Chem Biol 8:547-54
Lee, Peter S; Zhang, Hui-Min; Marshall, Alan G et al. (2012) Uncovering of a short internal peptide activates a tRNA synthetase procytokine. J Biol Chem 287:20504-8
Xu, Zhiwen; Wei, Zhiyi; Zhou, Jie J et al. (2012) Internally deleted human tRNA synthetase suggests evolutionary pressure for repurposing. Structure 20:1470-7
Park, Min Chul; Kang, Taehee; Jin, Da et al. (2012) Secreted human glycyl-tRNA synthetase implicated in defense against ERK-activated tumorigenesis. Proc Natl Acad Sci U S A 109:E640-7
Guo, Min; Schimmel, Paul (2012) Structural analyses clarify the complex control of mistranslation by tRNA synthetases. Curr Opin Struct Biol 22:119-26
Wang, Jing; Fang, Pengfei; Schimmel, Paul et al. (2012) Side chain independent recognition of aminoacyl adenylates by the Hint1 transcription suppressor. J Phys Chem B 116:6798-805

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