Probing tRNA interaction with biogenic polyamines

Ouameur, Amin Ahmed; Bourassa, P.; Tajmir-Riahi, H.A.

doi:10.1261/rna.1994310

Cited by 66 publications

(53 citation statements)

References 53 publications

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“…Mg(II) was previously shown to activate PRORP1 catalysis (2). To further analyze the metal dependence, we examined the activation of PRORP1 by other divalent cations in the presence of the magnesium hexahydrate mimic, cobalt(III) hexammine (21), to stabilize the tertiary structure of pre-tRNA. PRORP1 with a stoichiometric zinc ion (Table S2) cannot catalyze pre-tRNA cleavage, indicating that the bound Zn(II) is a structural cofactor (Fig.…”

Section: Resultsmentioning

confidence: 99%

Mitochondrial ribonuclease P structure provides insight into the evolution of catalytic strategies for precursor-tRNA 5′ processing

Howard¹,

Lim²,

Fierke

et al. 2012

Proc. Natl. Acad. Sci. U.S.A.

110

235

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Ribonuclease P (RNase P) catalyzes the maturation of the 5′ end of tRNA precursors. Typically these enzymes are ribonucleoproteins with a conserved RNA component responsible for catalysis. However, protein-only RNase P (PRORP) enzymes process precursor tRNAs in human mitochondria and in all tRNA-using compartments of Arabidopsis thaliana. PRORP enzymes are nuclear encoded and conserved among many eukaryotes, having evolved recently as yeast mitochondrial genomes encode an RNase P RNA. Here we report the crystal structure of PRORP1 from A. thaliana at 1.75 Å resolution, revealing a prototypical metallonuclease domain tethered to a pentatricopeptide repeat (PPR) domain by a structural zinc-binding domain. The metallonuclease domain is a unique high-resolution structure of a Nedd4-BP1, YacP Nucleases (NYN) domain that is a member of the PIN domain-like fold superfamily, including the FLAP nuclease family. The structural similarity between PRORP1 and the FLAP nuclease family suggests that they evolved from a common ancestor. Biochemical data reveal that conserved aspartate residues in PRORP1 are important for catalytic activity and metal binding and that the PPR domain also enhances activity, likely through an interaction with pre-tRNA. These results provide a foundation for understanding tRNA maturation in organelles. Furthermore, these studies allow for a molecular-level comparison of the catalytic strategies used by the only known naturally evolved protein and RNA-based catalysts that perform the same biological function, pre-tRNA maturation, thereby providing insight into the differences between the prebiotic RNA world and the present protein-dominated world.catalytic mechanism | magnesium | molecular recognition A ccording to the RNA world hypothesis, RNA played dual roles as carrier of genetic information and catalyst in a prebiotic world. However, over eons of evolution, proteins with their expanded 20-aa alphabet and greater structural and functional complexity took over many RNA-based functions. Structural insights into this evolutionary transition are limited because of the lack of examples of RNA and protein macromolecules that perform the same biological function in nature. One notable exception is ribonuclease P (RNase P) that catalyzes maturation of the 5′ end of tRNA across all domains of life. Until recently, all known RNase P enzymes included a catalytic RNA component. The discovery of a protein-only RNase P [proteinacous RNase P (PRORP)] from human mitochondria and Arabidopsis thaliana has dramatically shifted this paradigm (1-3). These enzymes represent a unique class of metallonucleases and are conserved among many eukaroytes (1, 2). A. thaliana encodes three PRORP enzymes (PRORP1, -2, and -3) that catalyze pretRNA processing (2). PRORP1 localizes to the mitochondria and chloroplast whereas PRORP2 and PRORP3 localize to the nucleus (2), suggesting that protein-based enzymes catalyze pretRNA maturation in these cellular locations (2, 3). To gain mechanistic and evolutionary insights into the PRORP...

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Section: Resultsmentioning

confidence: 99%

Mitochondrial ribonuclease P structure provides insight into the evolution of catalytic strategies for precursor-tRNA 5′ processing

Howard¹,

Lim²,

Fierke

et al. 2012

Proc. Natl. Acad. Sci. U.S.A.

110

235

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“…Similar spectral changes were observed for the backbone PO 2 stretching vibrations in the IR spectra of dendrimer−tRNA, biogenic polyamine−tRNA, and cationic lipid−tRNA complexes, where strong ligand−phosphate binding occurred. 13,31,32 Hydrophobic Contacts. A possible impact of PEG−tRNA interaction on polymer antisymmetric and symmetric CH 2 stretching vibration in the region of 3000−2800 cm in PEG 6000-tRNA and free mPEG-anthracene with CH 2 bands at 2944, 2883, and 2857 cm −1 shifted to 2940 and 2886 cm −1 (2957 did not shift) in mPEG-anthracene-tRNA adducts (spectra not shown).…”

Section: ■ Results and Discussionmentioning

confidence: 99%

Effect of PEG and mPEG-Anthracene on tRNA Aggregation and Particle Formation

et al. 2011

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Poly(ethylene glycol) (PEG) and its derivatives are synthetic polymers with major applications in gene and drug delivery systems. Synthetic polymers are also used to transport miRNA and siRNA in vitro. We studied the interaction of tRNA with several PEGs of different compositions, such as PEG 3350, PEG 6000, and mPEG-anthracene under physiological conditions. FTIR, UV−visible, CD, and fluorescence spectroscopic methods as well as atomic force microscopy (AFM) were used to analyze the PEG binding mode, the binding constant, and the effects of polymer complexation on tRNA stability, aggregation, and particle formation. Structural analysis showed that PEG-tRNA interaction occurs via RNA bases and the backbone phosphate group with both hydrophilic and hydrophobic contacts. The overall binding constants of K PEG 3350-tRNA = 1.9 (±0.5) × 10 4 M −1 , K PEG 6000-tRNA = 8.9 (±1) × 10 4 M −1 , and K mPEG-anthracene = 1.2 (±0.40) × 10 3 M −1 show stronger polymer− RNA complexation by PEG 6000 and by PEG 3350 than the mPEG-anthracene. AFM imaging showed that PEG complexes contain on average one tRNA with PEG 3350, five tRNA with PEG 6000, and ten tRNA molecules with mPEGanthracene. tRNA aggregation and particle formation occurred at high polymer concentrations, whereas it remains in A-family structure. ■ INTRODUCTIONSynthetic polymers play a major role in drug and gene delivery.1−3 Among synthetic polymers, poly(ethylene glycol) and its derivatives show potential applications in gene and drug delivery due to their solubility, nontoxicity, and biocompatibility. 4,5 It has been shown that PEG induces significant changes in DNA solubility and structure under given conditions. 6 DNA concentration, pH, ionic strength of the solution, and the presence of divalent metal ions have been shown to impact PEG-DNA precipitation.6 PEGylation of synthetic polymers such as dendrimers is shown to reduce toxicity and increase biocompatibility and DNA transfection. 4,5,7 Similarly, the effect of PEGylation on the toxicity and permeability of biopolymers such as chitosan has been recently reported. 8,9 Whereas major attention has been focused on polymer−DNA complexes because of their applications in gene delivery, little is known about polymer−RNA interaction. Synthetic polymers can transport miRNA and siRNA in vitro.10−12 The interaction of dendrimers with tRNA has been recently reported. 13 Even though the interactions of PEGylated dendrimers with DNA, RNA, and protein are wellcharacterized, 13−16 detailed structural analysis of PEG and mPEG derivatives complexes with RNA is not known. Therefore, it was of interest to study the interaction of PEGs and mPEGderivatives with tRNA, using spectroscopic methods and AFM imaging.Fluorescence quenching has been used as a technique for quantifying the binding affinities of macromolecules with ligands. 17Fluorescence quenching is the decrease of the quantum yield of fluorescence from a fluorophore, induced by a variety of molecular interactions with quencher molecule. Therefore, it is possibl...

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“…Synthetic polymer complexes with DNA and tRNA via hydrophilic, hydrophobic contacts, groove binding and phosphate interaction [25][26][27][28][29]. The infrared spectra and difference spectra of the free tRNA showed major alterations of tRNA in-plane vibrations and the backbone phosphate asymmetric and symmetric stretching bands [30][31][32][33][34][35], upon polymer complexation ( Figure 2-panels A and B). Low concentration (0.125 mM) of synthetic polymers PEG-3350, PEG-6000, mPEG-PAMAM-G3, mPEG-PAMAM-G4 and PAMAM-G4 induced minor changes of tRNA vibrational frequencies, while at high polymer content (1 mM) major alterations of tRNA inplane and the backbone vibrational frequencies (Figure 2-panels A and B).…”

Section: Binding Sites Of Synthetic Polymers With Trnamentioning

confidence: 99%

Effect of Synthetic Polymers on tRNA Nanoparticle Formation

HA¹

2015

JNMR

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In this review, we have examined the effects of several synthetic nanoparticles such as poly (ethylene glycol) PEG-(PEG-3350, PEG-6000), methoxypoly (ethylene glycol) anthracene (mPEG-anthracene), methoxypoly (ethylene glycol) poly (amidoamine) (mPEG-PAMAM-G3), (mPEG-PAMAM-G4) and poly (amidoamine) (PAMAM-G4) on tRNA structure and dynamics. Atomic force microscopic (AFM) images and spectroscopic data were analysed and the effects of synthetic polymer complexation on tRNA stability, aggregation and particle formation are discussed. Hydrophilic and hydrophobic contacts were dominated in the polymer-tRNA complexation and the overall binding constants showed that the order of binding is PEG-6000>PAMAM-G4>PEG-3350>mPEG-PAMAM-G4>mPEG-PAMAM-G3>mPEG-anthracene. The morphology of polymer-tRNA complexes showed major aggregation and nanoparticle formation of tRNA, in the presence of synthetic nanoparticles.

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Probing tRNA interaction with biogenic polyamines

Cited by 66 publications

References 53 publications

Mitochondrial ribonuclease P structure provides insight into the evolution of catalytic strategies for precursor-tRNA 5′ processing

Mitochondrial ribonuclease P structure provides insight into the evolution of catalytic strategies for precursor-tRNA 5′ processing

Effect of PEG and mPEG-Anthracene on tRNA Aggregation and Particle Formation

Effect of Synthetic Polymers on tRNA Nanoparticle Formation

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