Exploring the minimal substrate requirements for trans-cleavage by RNase P holoenzymes from Escherichia coli and Bacillus subtilis.

We analysed the processing of small bipartite model substrates by Escherichia coli and Bacillus subtilis RNase P and corresponding hybrid enzymes. We demonstrate specific trans-cleavage of a model substrate with a 4 bp stem and a 1 nucleotide (nt) 5' flank, representing to date the smallest mimic of a natural RNase P substrate that could be processed in trans at the canonical RNase P cleavage site. Processing efficiencies decreased up to 5000-fold when the 5' flank was shortened from 3 to 1 nt. Reduction of the 5' flank to 1 nt was more deleterious than reducing the stem from 7 to 4 bp, although the 4 bp duplex formed only transiently, in contrast to the stable 7 bp duplex. These results indicate that the crucial contribution of nt -2 in the single-stranded 5' flank to productive interaction is a general feature of A- and B-type bacterial RNase P enzymes. We also showed that an Rp-phosphorothioate modification at nt -2 interferes with processing. Bacterial RNase P holoenzymes are also capable of cleaving single-stranded RNA oligonucleotides as short as 5 nt, yielding RNase P-specific 5'-phosphate and 3'-OH termini, with measured turnover rates of up to 0.7 min-1. All cleavage sites were at least 2 nt away from the 5' and 3' ends of the oligonucleotides. Some cleavage site preferences were observed dependent on the identity of the RNase P RNA subunit.

Correlation between processing efficiency for ribonuclease P minimal substrates and conformation of the nucleotide -1 at the cleavage position.

It is demonstrated that acceptor stem duplexes derived from native tRNAs which contain a three-nucleotide extension at the 5'-terminus of mature tRNA are minimal substrates for ribonuclease P from both Escherichia coli and Bacillus subtilis. Variants with a cytidine at position -1 are most efficiently processed whereas the G -1 variant represents a comparatively poor substrate. An A -1 acceptor stem variant is a slightly better substrate than the G -1 variant though generally distinctly less efficient than the C -1 duplex. This is in qualitative agreement with the frequency of the occurrence of the corresponding nucleotides at position -1 in natural substrates, which is highest for pyrimidines and least for G. NMR analyses of the corresponding acceptor stems reveal that the conformation of the nucleotides at position -1 correlates with the substrate preferences of Ribonuclease P: Whereas C -1 adopts a conformation characterized by a glycosidic angle in the anti range (close to high-anti), the G -1 is clearly in syn conformation, and that of A -1 is intermediate between high-anti and syn. The riboses of nucleotides -1 are in all cases predominantly 2'-endo puckered.

NMR spectroscopic evidence for Mn(2+)(Mg(2+)) binding to a precursor-tRNA microhelix near the potential RNase P cleavage site.

The binding of Mg(2+)/Mn(2+) to acceptor stem microhelices as minimal models for precursor-tRNA(Gly) is demonstrated by NMR spectroscopy. From the evaluation of COSY and NOESY spectra, binding sites for Mg(2+)/Mn(2+) can be inferred. In particular, one binding site exists near the ribose moiety of nucleotide -1 at the position of cleavage by RNase P. From comparison with a variant possessing a deoxynucleotide at this position, it is concluded that the 2'-OH group of this nucleotide is indispensable for coordinating the divalent metal ion. Hence, this catalytically important metal ion is "pre-bound" to the precursor-tRNA before complexation with RNase P.

Interaction of fMet-tRNAfMet and fMet-AMP with the C-terminal domain of Thermus thermophilus translation initiation factor 2.

Two polypeptides resistant against proteolytic digestion were identified in Thermus thermophilus translation initiation factor 2 (IF2): the central part of the protein (domains II/III), and the C-terminal domain (domain IV). The interaction of intact IF2 and the isolated proteolytic fragments with fMet-tRNAfMet was subsequently characterized. The isolated C-terminal domain was as effective in binding of the 3' end of fMet-tRNAf Met as intact IF2. N-Formylation of Met-tRNAfMet was required for its efficient binding to the C-terminal domain. This suggests that the interaction between the C-terminal domain and the 3' end of fMet-tRNAfMet is responsible for the recognition of fMet-tRNAfMet by IF2 during translation initiation. Moreover, it was demonstrated that fMet-AMP is a minimal ligand of IF2. fMet-AMP inhibits fMet-tRNAfMet binding to IF2 as well as the activity of IF2 in the stimulation of ApUpG-dependent ribosomal binding of fMet-tRNAf Met. Specific interaction of fMet-AMP with IF2 was demonstrated by 1H-NMR spectroscopy. These findings indicate that fMet-AMP and the 3' terminal fMet-adenosine of fMet-tRNAfMet use the same binding site on the C-terminal domain of IF2 and imply that the interaction between the C-terminal domain and the 3' end of fMet-tRNAfMet is primarily responsible for the fMet-tRNAfMet binding and recognition by IF2.

The C-A mismatch base pair and the single-strand terminus in the E. coli initiator tRNA(fMet) acceptor stem adopt unusual conformations.

Acceptor stem variants of tRNA(fMet) (Escherichia coli) have been characterized by nuclear magnetic resonance. The wild type contains a C1-A72 mismatch pair which is crucial for its biological function. For comparison, the mismatch was replaced by regular pairs U1-A72 and C1-G72. Further variants contain an altered discriminator base, G73, or a G1-C72/U73 combination. The stems of variants U1-A72/A73 and C1-G72/A73 have A-RNA geometry, which extends essentially to the single-strand terminus. C1-A72/G73 variant and wild type are structurally almost identical. C1 and A72 adopt peculiar conformations with C1 being largely destacked with respect to G2, while A73 stacks upon C1. The unique arrangement of the mismatch causes a distinctly different orientation of the single-strand terminus compared to variants with regular 1-72 base pairs, and to formyltransferase-complexed tRNA(fMet).

Dimerization of double-stranded RNA possessing a 3'-overhanging single-stranded end.

A simple system derived from the acceptor stem of tRNA(Ala) is presented which undergoes a pH-dependent dimerization. This is brought about by formation of C+-G-C base triples of the pyrimidine motif type between protonated cytidines of the 3' single-stranded end and regularly paired G-C pairs in the double-helical stem. In addition, an unusual interaction between a protonated adenine and a regular G-C pair is suggested. The equilibrium between monomer and dimer forms can be monitored via NMR spectroscopy and UV melting curve analysis. A dimerization enthalpy of 159 kJ mol(-1) was found at pH 5.0. The system could serve as a model for inter- and intra-molecular association, respectively, of single-stranded and double-helical regions to enable optimal packing of large RNA molecules.

A biologically active 53 kDa fragment of overproduced alanyl-tRNA synthetase from Thermus thermophilus HB8 specifically interacts with tRNA Ala acceptor helix.

The alaS gene encoding the alanyl-tRNA synthetase (AlaRS) from Thermus thermophilus HB8 was cloned and sequenced. The gene comprises 2646 bp, corresponding to 882 amino acids, 45% of which are identical to the enzyme from Escherichia coli . The T. thermophilus AlaRS was overproduced in E.coli , purified and characterized. It has high thermal stability up to approximately 65 degrees C, with a temperature optimum of aminoacylation activity at approximately 60 degrees C, and will be valuable for crystallization. The purified enzyme appears as a dimer with a specific activity of 220 U/mg and k cat/ K M values of 118 000/s/M for alanine and 114 000/s/M for ATP. By genetic engineering a 53 kDa fragment of AlaRS comprising the N-terminal 470 amino acids (AlaN470) was also overproduced and purified. It is as stable as entire AlaRS and sufficient for specific aminoacylation of intact tRNAAla, as well as acceptor stem microhelices with a G3-U70, but not U3-A70, I3-U70 or C3-U70, base pair. The reduced binding strength of such microhelices to AlaN470 enabled, due to the resulting fast exchange of the microhelices between free and complexed states, preliminary NMR analyses of the binding mode and intermolecular recognition.