Effects of macromolecular impurities and of crystallization method on the quality of eubacterial aspartyl-tRNA synthetase crystals.

Although macromolecular purity is thought to be essential for the growth of flawless protein crystals, only a few studies have investigated how contaminants alter the crystallization process and crystal quality. Likewise, the outcome of a crystallization process may vary with the crystallization method. Here, it is reported how these two variables affect the crystallogenesis of aspartyl-tRNA synthetase from the eubacterium Thermus thermophilus. This homodimeric enzyme (Mr=130,000) possesses a multi-domain architecture and crystallizes either in a monoclinic or an orthorhombic habit. Minute amounts of protein impurities alter to a different extent the growth of each crystal form. The best synthetase crystals are only obtained when the crystallizing solution is either enclosed in capillaries or immobilized in agarose gel. In these two environments convection is reduced with regard to that existing in an unconstrained solution.

From conventional crystallization to better crystals from space: a review on pilot crystallogenesis studies with aspartyl-tRNA synthetases.

Aspartyl-tRNA synthetases were the model proteins in pilot crystallogenesis experiments. They are homodimeric enzymes of Mr approximately 125 kDa that possess as substrates a transfer RNA, ATP and aspartate. They have been isolated from different sources and were crystallized either as free proteins or in association with their ligands. This review discusses their crystallisability with emphasis to crystal quality and structure determination. Crystallization in low diffusivity gelled media or in microgravity environments is highlighted. It has contributed to prepare high-resolution diffracting crystals with better internal order as reflected by their mosaicity. With AspRS from Thermus thermophilus, the better crystalline quality of the space-grown crystals within APCF is correlated with higher quality of the derived electron density maps. Usefulness for structural biology of targeted methods aimed to improve the intrinsic physical quality of protein crystals is highlighted.

The plant tRNA 3' processing enzyme has a broad substrate spectrum.

To elucidate the minimal substrate for the plant nuclear tRNA 3' processing enzyme, we synthesized a set of tRNA variants, which were subsequently incubated with the nuclear tRNA 3' processing enzyme. Our experiments show that the minimal substrate for the nuclear RNase Z consists of the acceptor stem and T arm. The broad substrate spectrum of the nuclear RNase Z raises the possibility that this enzyme might have additional functions in the nucleus besides tRNA 3' processing. Incubation of tRNA variants with the plant mitochondrial enzyme revealed that the organellar counterpart of the nuclear enzyme has a much narrower substrate spectrum. The mitochondrial RNase Z only tolerates deletion of anticodon and variable arms and only with a drastic reduction in cleavage efficiency, indicating that the mitochondrial activity can only cleave bona fide tRNA substrates efficiently. Both enzymes prefer precursors containing short 3' trailers over extended 3' additional sequences. Determination of cleavage sites showed that the cleavage site is not shifted in any of the tRNA variant precursors.

Identity of tRNA for yeast tyrosyl-tRNA synthetase: tyrosylation is more sensitive to identity nucleotides than to structural features.

The specific aminoacylation of tRNA by yeast tyrosyl-tRNA synthetase does not rely on the presence of modified residues in tRNA(Tyr), although such residues stabilize its structure. Thus, the major tyrosine identity determinants were searched by the in vitro approach using unmodified transcripts produced by T7 RNA polymerase. On the basis of the tyrosylation efficiency of tRNA variants, the strongest determinants are base pair C1-G72 and discriminator residue A73 (the 5'-phosphoryl group on C1, however, is unimportant for tyrosylation). The three anticodon bases G34, U35, and A36 contribute also to the tyrosine identity, but to a lesser extent, with G34 having the most pronounced effect. Mutation of the GUA tyrosine anticodon into a CAU methionine anticodon, however, leads to a loss of tyrosylation efficiency similar to that obtained after mutation of the C1-G72 or A73 determinants. Transplantation of the six determinants into four different tRNA frameworks and activity assays on heterologous Escherichia coli and Methanococcus jannaschii tRNA(Tyr) confirmed the completeness of the tyrosine set and the eukaryotic character of the C1-G72 base pair. On the other hand, it was found that tyrosine identity in yeast does not rely on fine architectural features of the tRNA, in particular the size and sequence of the D-loop. Noticeable, yeast TyrRS efficiently charges a variant of E. coli tRNA(Tyr) with a large extra-region provided its G1-C72 base pair is changed to a C1-G72 base pair. Finally, tyrosylation activity is compatible with a +1 shift of the anticodon in the 3'-direction but is strongly inhibited if this shift occurs in the opposite 5'-direction.

Ribozyme processed tRNA transcripts with unfriendly internal promoter for T7 RNA polymerase: production and activity.

A limitation for a universal use of T7 RNA polymerase for in vitro tRNA transcription lies in the nature of the often unfavorable 5'-terminal sequence of the gene to be transcribed. To overcome this drawback, a hammerhead ribozyme sequence was introduced between a strong T7 RNA polymerase promoter and the tDNA sequence. Transcription of this construct gives rise to a 'transzyme' molecule, the autocatalytic activity of which liberates a 5'-OH tRNA transcript starting with the proper nucleotide. The method was optimized for transcription of yeast tRNA(Tgammar), starting with 5'-C1, and operates as well for yeast tRNA(Asp) with 5'-U1. Although the tRNAs produced by the transzyme method are not phosphorylated, they are fully active in aminoacylation with k(cat) and Km parameters quasi identical to those of their phosphorylated counterparts.

Structure and aminoacylation capacities of tRNA transcripts containing deoxyribonucleotides.

The contribution of the ribose 2'-hydroxyls to RNA structure and function has been analyzed, but still remains controversial. In this work, we report the use of a mutant T7 RNA polymerase as a tool in RNA studies, applied to the aspartate and methionine tRNA aminoacylation systems from yeast. Our approach consists of determining the effect of substituting natural ribonucleotides by deoxyribonucleotides in RNA and, thereby, defining the subset of important 2'-hydroxyl groups. We show that deoxyribose-containing RNA can be folded in a global conformation similar to that of natural RNA. Melting curves of tRNAs, obtained by temperature-gradient gel electrophoresis, indicate that in deoxyribo-containing molecules, the thermal stability of the tertiary network drops down, whereas the stability of the secondary structure remains unaltered. Nuclease footprinting reveals a significant increase in the accessibility of both single- and double-stranded regions. As to the functionality of the deoxyribose-containing tRNAs, their in vitro aminoacylation efficiency indicates striking differential effects depending upon the nature of the substituted ribonucleotides. Strongest decrease in charging occurs for yeast initiator tRNA(Met) transcripts containing dG or dC residues and for yeast tRNA(Asp) transcripts with dU or dG. In the aspartate system, the decreased aminoacylation capacities can be correlated with the substitution of the ribose moieties of U11 and G27, disrupting two hydrogen bond contacts with the synthetase. Altogether, this suggests that specific 2'-hydroxyl groups in tRNAs can act as determinants specifying aminoacylation identity.

Crystallogenesis of biological macromolecules: facts and perspectives.

This paper gives an overview of the science of crystals of biological macromolecules. The historical background of the field is outlined and the main achievements and open problems are discussed from both biological and physical-chemical viewpoints. Selected results, including data from the authors, illustrate this overview. The perspectives of crystallogenesis for structural biology, but also more general trends, are presented.

Exploring the aminoacylation function of transfer RNA by macromolecular engineering approaches. Involvement of conformational features in the charging process of yeast tRNA(Asp).

This report presents the conceptual and methodological framework that presently underlies the experiments designed to decipher the structural features in tRNA important for its aminoacylation by aminoacyl-tRNA synthetases. It emphasizes the importance of conformational features in tRNA for an optimized aminoacylation. This is illustrated by selected examples on yeast tRNA(Asp). Using the phage T7 transcriptional system, a series of tRNA(Asp) variants were created in which conformational elements were modified. It is shown that aspartyl-tRNA synthetase tolerates conformational variability in tRNA(Asp) at the level of the D-loop and variable region, of the tertiary Levitt base-pair 15-48 which can be inverted and in the T-arm in which residue 49 can be excised. However, changing the anticodon region completely abolishes the aspartylation capacity of the variants. Transplanting the phenylalanine identity elements into a different tRNA(Asp) variant presenting conformational characteristics of tRNA(Phe) converts this molecule into a phenylalanine acceptor but is less efficient than wild-type tRNA(Phe). This engineered tRNA completely loses its aspartylation capacity, showing that some aspartic acid and phenylalanine identity determinants overlap. The fact that chimeric tRNA(Asp) molecules with altered anticodon regions lose their aspartylation capacity demonstrates that this region is part of the aspartic acid identity of tRNA(Asp).