Analyses of mRNA Cleavage by RelE and the Role of tRNA Methyltransferase TrmD Using Bacterial Ribosome Profiling

Hwang, Jae Yeon

01 June 2016

Protein synthesis is a fundamental and ultimate process in living cells. Cells possess sophisticated machineries and continuously carry out complex processes. Monitoring protein synthesis in living cells not only inform us about the mechanism of translation but also deepen our insights about all aspects of life. Understanding the structure and mechanism of the ribosome and its associated factors helped us enlarge our knowledge on protein synthesis. Recently, with the dramatic advances of high-throughput sequencing and bioinformatics, a new technique called ribosome profiling emerged. By retrieving mRNA fragments protected by translating ribosomes, ribosome profiling reveals global ribosome occupancy along mRNAs in living cells, which can inform us with the identity and quantity of proteins being made. Easily adapted to other organisms, ribosome profiling technique is expanding its application in revealing various cellular activities as well as the knowledge on protein synthesis. Here, we report the mechanism of translating mRNA cleavage by endoribonuclease RelE in vivo. RelE is an endoribonuclease that is induced during nutrient deficiency stress and specifically cleaves translating mRNAs upon binding to the ribosomal A site. Overexpression of RelE in living cells causes growth arrest by inhibiting global translation. We monitored RelE activity in vivo upon overexpression using ribosome profiling. The data show that RelE actively cuts translating mRNAs whenever the ribosomal A site is accessible, resulting in truncated mRNAs. RelE causes the ribosome complexes to accumulate near the 5' end of genes as the process of ribosome rescue, translation, and cleavage by RelE repeats. RelE cleavage specific sub-codon level ribosome profiling data also represent reading frame in Escherichia coli and sequence specificity of RelE cleavage in vivo. We report another ribosome profiling study on a methyltransferase TrmD in E. coli. TrmD is known to methylate G37 (the residue at 3' side of anticodon) of some tRNAs and be responsible for codon-anticodon interaction. We constructed a TrmD depletion E. coli strain, whose deletion results in lethality of cells. Resulting depletion of m1G37 in the strain leads to growth arrest. Lack of m1G37 of some tRNAs whose codons start with C showed frequent frameshift when translating the gene message in vitro. By using ribosome profiling, we successfully observed significant difference on translation process when codons interact with anticodons of tRNAs lacking m1G37. The data reveal slow translation rate or pauses on the tRNAs when missing the appropriate methylation, which corresponds to the previous biochemical data in vitro.

RelE

endoribonuclease

TrmD

methyltransferase

ribosome profiling

m1G37

Chemistry

DYNAMICS OF SUBSTRATE INTERACTIONS IN tRNA (m1G37) METHYLTRANSFERASE: IMPLICATIONS FOR DRUG DISCOVERY

Palesis, Maria Kiouppis

14 February 2012

The bacterial enzyme t-RNA (m1G37) methyltransferase (TrmD) is an ideal anti-microbial drug target since it is found in all eubacteria, serves an essential role during protein synthesis, and shares very little sequence or structural homology with its eukaryotic counterpart, Trm5. TrmD, a homodimeric protein, methylates the G37 nucleotide of tRNA using S-adenosyl-L-methionine (SAM) as the methyl donor and thus enables proper codon-anticodon alignment during translation. The two deeply buried binding sites for SAM seen in X-ray crystallography suggest that significant conformational changes must occur for substrate binding and catalytic turnover. Results from molecular dynamics simulations implicate a flexible loop region and a halo-like loop which may be gating the entrance to the active site. Analysis of simulation trajectories indicates an alternating pattern of active site accessibility between the two SAM binding sites, suggesting a single site mechanism for enzyme activity. Isothermal titration calorimetry (ITC), demonstrates that binding of SAM to TrmD is an exothermic reaction resulting from sequential binding at two sites. A similar mode of binding at higher affinities was observed for the product, S-adenosyl-L-homocysteine (SAH) suggesting that product inhibition may be important in vivo. ITC reveals that tRNA binding is an endothermic reaction in which one tRNA molecule binds to one TrmD dimer. This further supports the hypothesis of a single site mechanism for enzyme function. However, mutational analysis using hybrid mutant proteins suggests that catalytic integrity must be maintained in both active sites for maximum enzymatic efficiency. Mutations impeding flexibility of the halo loop were particularly detrimental to enzyme activity. Noncompetitive inhibition of TrmD was observed in the presence of bis-ANS, an extrinsic fluorescent dye. In silico ligand docking of bis-ANS to TrmD suggests that dye interferes with mobility of the flexible linker above the active site. Because SAM is a ubiquitous cofactor in methyltransferase reactions, analogs of this ligand may not be suitable for drug development. It is therefore important to investigate allosteric modes of inhibition. These experiments have identified key, mobile structural elements in the TrmD enzyme important for activity, and provide a basis for further research in the development of allosteric inhibitors for this enzyme.

tRNA

TrmD

S-adenosyl-L-methionine

S-adenosyl-L-homocysteine

single site activity

tRNA m1G37 methyltransferase

Medical Pharmacology

Medical Sciences

Medicine and Health Sciences