In vitro hyperprocessing of Drosophila tRNAs by the catalytic RNA of RNase P the cloverleaf structure of tRNA is not always stable?

tRNA gene diversity in the three domains of life

Transfer RNA (tRNA) is widely known for its key role in decoding mRNA into protein. Despite their necessity and relatively short nucleotide sequences, a large diversity of gene structures and RNA secondary structures of pre-tRNAs and mature tRNAs have recently been discovered in the three domains of life. Growing evidences of disrupted tRNA genes in the genomes of Archaea reveals unique gene structures such as, intron-containing tRNA, split tRNA, and permuted tRNA. Coding sequence for these tRNAs are either separated with introns, fragmented, or permuted at the genome level. Although evolutionary scenario behind the tRNA gene disruption is still unclear, diversity of tRNA structure seems to be co-evolved with their processing enzyme, so-called RNA splicing endonuclease. Metazoan mitochondrial tRNAs (mtRNAs) are known for their unique lack of either one or two arms from the typical tRNA cloverleaf structure, while still maintaining functionality. Recently identified nematode-specific V-arm containing tRNAs (nev-tRNAs) possess long variable arms that are specific to eukaryotic class II tRNA^Ser and tRNA^Leu but also decode class I tRNA codons. Moreover, many tRNA-like sequences have been found in the genomes of different organisms and viruses. Thus, this review is aimed to cover the latest knowledge on tRNA gene diversity and further recapitulate the evolutionary and biological aspects that caused such uniqueness.

Alternative substrate kinetics of Escherichia coli ribonuclease P: determination of relative rate constants by internal competition

A single enzyme, ribonuclease P (RNase P), processes the 5' ends of tRNA precursors (ptRNA) in cells and organelles that carry out tRNA biosynthesis. This substrate population includes over 80 different competing ptRNAs in Escherichia coli. Although the reaction kinetics and molecular recognition of a few individual model substrates of bacterial RNase P have been well described, the competitive substrate kinetics of the enzyme are comparatively unexplored. To understand the factors that determine how different ptRNA substrates compete for processing by E. coli RNase P, we compared the steady state reaction kinetics of two ptRNAs that differ at sequences that are contacted by the enzyme. For both ptRNAs, substrate cleavage is fast relative to dissociation. As a consequence, V/K, the rate constant for the reaction at limiting substrate concentrations, reflects the substrate association step for both ptRNAs. Reactions containing two or more ptRNAs follow simple competitive alternative substrate kinetics in which the relative rates of processing are determined by ptRNA concentration and their V/K. The relative V/K values for eight different ptRNAs, which were selected to represent the range of structure variation at sites contacted by RNase P, were determined by internal competition in reactions in which all eight substrates were present simultaneously. The results reveal a relatively narrow range of V/K values, suggesting that rates of ptRNA processing by RNase P are tuned for uniform specificity and consequently optimal coupling to precursor biosynthesis.

Disconnected Interacting Protein 1 binds with high affinity to pre-tRNA and ADAT

Disconnected Interacting Protein 1 (DIP1), a member of the double-stranded RNA-binding protein family based on amino acid sequence, was shown previously to form complexes with multiple transcription factors in Drosophila melanogaster. To explore this protein further, we have undertaken sedimentation equilibrium experiments that demonstrate that DIP1-c (longest isoform of DIP1) is a dimer in solution, a characteristic common to other members of the dsRNA-binding protein family. The closest sequence identity for DIP1 is found within the dsRBD sequences of RNA editase enzymes. Consistent with this role, we demonstrate binding of DIP1-c to a potential physiological RNA target: pre-tRNA. In addition, DIP1-c was shown to interact with ADAT, a tRNA deaminase that presumably modifies pre-tRNAs. From these data, we hypothesize that DIP1 may serve an integrator role by binding its dsRNA ligand and recruiting protein partners for the appropriate metabolism of the bound RNA.

Ribozymes: Flexible molecular devices at work

The discovery of ribozymes, RNAs with catalytic activity, revealed the extraordinary characteristic of this molecule, and corroborated the idea that RNA was the first informative polymer. The "RNA world" hypothesis asserts that the DNA/RNA/PROTEIN world arose from an earlier RNA world in which were present only RNA molecules able to perform both of the two functions performed separately by DNA and proteins in the present-day cells: the ability to transfer genetic information and to carry out catalytic activity. The catalytic properties of ribozymes are exclusively due to the capacity of RNA molecules to assume particular structures. Moreover, the structural versatility of RNA can allow to a single RNA sequence to fold in more than one structure, able to perform more than one function. In the first part of this work we will discuss the RNA plasticity, focusing on "bifunctional" ribozymes isolated by in vitro selection experiments, and on the consequences of this plasticity in the prospective of the emergence of new specific functions. The possibility that one sequence could have more than one structure/function, greatly increase the evolutionary potential of RNA, and the capacity of RNA to switch from a structure/function to another is probably one of the reasons of the evolutionary success also in modern-day cells. Naturally occurring ribozymes discovered in contemporary cells, demonstrate the crucial role that ribozymes still have in the modern protein world. In the second part of this paper we will discuss the capacity of natural ribozymes to modulate gene expression making use of their exclusive catalytic properties. Moreover, we will consider the possibility of their ancient origin.

Analysis on substrate specificity of Escherichia coli ribonuclease P using shape variants of pre-tRNA: proposal of subsites model for substrate shape recognition

We prepared a series of shape variants of a pre-tRNA and examined substrate shape recognition by bacterial RNase P ribozyme and holoenzyme. Cleavage site analysis revealed two new subsites for accepting the T-arm and the bottom half of pre-tRNA in the substrate-binding site of the enzyme. These two subsites take part in cleavage site selection of substrate by the enzyme: the cleavage site is not always selected according to the relative position of the 3'-CCA sequence of the substrate. Kinetic studies indicated that the substrate shape is recognized mainly in the transition state of the reaction, and neither the shape nor position of either the T-arm or the bottom half of the substrate affected the Michaelis complex formation. These results strongly suggest that the 5' and 3' termini of a substrate are trapped by the enzyme first, then the position and the shape of the T-arm and the bottom half are examined by the cognate subsites. From these facts, we propose a new substrate recognition model that can explain many experimental facts that have been seen as enigmatic.

Porphyrins and porphines bind strongly and specifically to tRNA, precursor tRNA and to M1 RNA and inhibit the ribonuclease P ribozyme reaction

Porphyrins and porphines strongly inhibit the action of the RNA subunit of the Escherichia coli ribonuclease P (M1 RNA). Meso-tetrakis(N-methyl-pyridyl)porphine followed linear competitive kinetics with pre-tRNA(Gly1) from E. coli as variable substrate (Ki 0.960 microM). Protoporphyrin IX showed linear competitive inhibition versus pre-tRNA(Gly1) from E. coli (Ki 1.90 microM). Inhibition by meso-tetrakis[4-(trimethylammonio)phenyl]porphine versus pre-tRNA(Gly1) from E. coli followed non-competitive kinetics (Ki 4.1 microM). The porphyrins bound directly to E. coli tRNAVal, E. coli pre-tRNAGly1 and M1 RNA and dissociation constants for the 1:1 complexes were determined using fluorescence spectroscopy. Dissociation constants (microM) against E. coli tRNAVal and E. coli pre-tRNAGly were: meso-tetrakis(N-methyl-pyridyl)porphine 1.21 and 0.170; meso-tetrakis[4-(trimethylammonio)phenyl]porphine, 0.107 and 0.293; protoporphyrin IX, 0.138 and 0.0819. For M1 RNA, dissociation constants were 32.8 nM for meso-tetrakis(N-methyl-pyridyl)porphine and 59.8 nM for meso-tetrakis[4-(trimethylammonio)phenyl]porphine and excitation and emission spectra indicate a binding mode with strong pi-stacking of the porphine nucleus and base pairs in a rigid low-polarity environment. Part of the inhibition of ribonuclease P is from interaction with the pre-tRNA substrate, resulting from porphyrin binding to the D-loop/T-loop region which interfaces with M1 RNA during catalysis, and part from the porphyrin binding to the M1 RNA component.

Cleavage of mitochondria-like transfer RNAs expressed in Escherichia coli

Mitochondrial (mt) transfer RNAs (tRNAs) often harbor unusual structural features causing their secondary structure to differ from the conventional cloverleaf. tRNAs designed with such irregularities, termed mt-like tRNAs, are active in Escherichia coli as suppressors of reporter genes, although they display low steady-state levels. Characterization of fragments produced during mt-like tRNA processing in vitro and in vivo suggests that these RNAs are not fully processed at their 5' ends and are cleaved internally. These abnormal processing events may account for the low levels of mature mt-like RNAs in vivo and are most likely related to defective processing by RNase P.

Guide DNA technique reveals that the protein component of bacterial ribonuclease P is a modifier for substrate recognition

We developed a guide DNA technique with which the cleavage efficiency of pre-tRNA substrate raised in the RNase P reaction. The 20-mer guide DNAs hybridizing to the upstream region of the cleaving site enhanced the cleavage reactions of RNA substrates by Escherichia coli RNase P. This guide DNA technique was also applicable to cleavage site selection by choosing the DNA-hybridizing site. Results showed that RNase P accepts DNA/RNA double-stranded 5'-leader region with high catalytic efficiency as well as single-stranded RNA region in pre-tRNAs as substrates, which suggests that the protein component of bacterial RNase P prefers bulky nucleotides. The protein component did not affect the normal 5'-processing reaction of pre-tRNAs, but enhanced the mis-cleaving (hyperprocessing) reactions of tRNA in non-cloverleaf folding. Our results suggested that the protein component of RNase P is a modifier for substrate recognition.