In vitro synthesis of transfer RNA. I. Purification of required components

Role of tRNA-Derived Fragments in Neurological Disorders: a Review

tRFs are small tRNA derived fragments that are emerging as novel therapeutic targets and regulatory molecules in the pathophysiology of various neurological disorders. These are derived from precursor or mature tRNA, forming different subtypes that have been reported to be involved in neurological disorders like stroke, Alzheimer's, epilepsy, Parkinson's, MELAS, autism, and Huntington's disorder. tRFs were earlier believed to be random degradation debris of tRNAs. The significant variation in the expression level of tRFs in disease conditions indicates their salient role as key players in regulation of these disorders. Various animal studies are being carried out to decipher their exact role; however, more inputs are required to transform this research knowledge into clinical application. Future investigations also call for high-throughput technologies that could help to bring out the other hidden aspects of these entities. However, studies on tRFs require further research efforts to overcome the challenges posed in quantifying tRFs, their interactions with other molecules, and the exact mechanism of function. In this review, we are abridging the current understanding of tRFs, including their biogenesis, function, relevance in clinical therapies, and potential as diagnostic and prognostic biomarkers of these neurological disorders.

The role of RNA modifications in the regulation of tRNA cleavage

Transfer RNA (tRNA) have been harbingers of many paradigms in RNA biology. They are among the first recognized noncoding RNA (ncRNA) playing fundamental roles in RNA metabolism. Although mainly recognized for their role in decoding mRNA and delivering amino acids to the growing polypeptide chain, tRNA also serve as an abundant source of small ncRNA named tRNA fragments. The functional significance of these fragments is only beginning to be uncovered. Early on, tRNA were recognized as heavily post-transcriptionally modified, which aids in proper folding and modulates the tRNA:mRNA anticodon-codon interactions. Emerging data suggest that these modifications play critical roles in the generation and activity of tRNA fragments. Modifications can both protect tRNA from cleavage or promote their cleavage. Modifications to individual fragments may be required for their activity. Recent work has shown that some modifications are critical for stem cell development and that failure to deposit certain modifications has profound effects on disease. This review will discuss how tRNA modifications regulate the generation and activity of tRNA fragments.

Conservation between the RNA polymerase I, II, and III transcription initiation machineries

Recent studies of the three eukaryotic transcription machineries revealed that all initiation complexes share a conserved core. This core consists of the RNA polymerase (I, II, or III), the TATA box-binding protein (TBP), and transcription factors TFIIB, TFIIE, and TFIIF (for Pol II) or proteins structurally and functionally related to parts of these factors (for Pol I and Pol III). The conserved core initiation complex stabilizes the open DNA promoter complex and directs initial RNA synthesis. The periphery of the core initiation complex is decorated by additional polymerase-specific factors that account for functional differences in promoter recognition and opening, and gene class-specific regulation. This review outlines the similarities and differences between these important molecular machines.

The making of tRNAs and more - RNase P and tRNase Z

Transfer-RNA (tRNA) molecules are essential players in protein biosynthesis. They are transcribed as precursors, which have to be extensively processed at both ends to become functional adaptors in protein synthesis. Two endonucleases that directly interact with the tRNA moiety, RNase P and tRNase Z, remove extraneous nucleotides on the molecule's 5'- and 3'-side, respectively. The ribonucleoprotein enzyme RNase P was identified almost 40 years ago and is considered a vestige from the "RNA world". Here, we present the state of affairs on prokaryotic RNase P, with a focus on recent findings on its role in RNA metabolism. tRNase Z was only identified 6 years ago, and we do not yet have a comprehensive understanding of its function. The current knowledge on prokaryotic tRNase Z in tRNA 3'-processing is reviewed here. A second, tRNase Z-independent pathway of tRNA 3'-end maturation involving 3'-exonucleases will also be discussed.

The tRNase Z family of proteins: physiological functions, substrate specificity and structural properties

tRNase Z is the endoribonuclease that generates the mature 3'-end of tRNA molecules by removal of the 3'-trailer elements of precursor tRNAs. This enzyme has been characterized from representatives of all three domains of life (Bacteria, Archaea and Eukarya), as well as from mitochondria and chloroplasts. tRNase Z enzymes come in two forms: short versions (280-360 amino acids in length), present in all three kingdoms, and long versions (750-930 amino acids), present only in eukaryotes. The recently solved crystal structure of the bacterial tRNase Z provides the structural basis for the understanding of central functional elements. The substrate is recognized by an exosite that protrudes from the main protein body and consists of a metallo-beta-lactamase domain. Cleavage of the precursor tRNA occurs at the binuclear zinc site located in the other subunit of the functional homodimer. The first gene of the tRNase Z family was cloned in 2002. Since then a comprehensive set of data has been acquired concerning this new enzyme, including detailed functional studies on purified recombinant enzymes, mutagenesis studies and finally the determination of the crystal structure of three bacterial enzymes. This review summarizes the current knowledge about these exciting enzymes.

Maturation pathways for E. coli tRNA precursors: a random multienzyme process in vivo

tRNA maturation consists of the specific removal of precursor sequences from both the 5' and 3' termini of an initial RNA transcript. How this is accomplished has heretofore not been ascertained in any system. Using Northern analysis of RNA isolated from a variety of RNase-deficient E. coli strains, we have identified the processing intermediates that accumulate in the absence of specific processing nucleases. From this information we have established the maturation pathways for 12 different E. coli tRNAs including the specific role of each of the relevant RNases in the process. The surprising conclusion from this work is that tRNA maturation is a stochastic process that lacks a defined order and that can proceed with a variety of alternative 3' processing nucleases.

Accurate processing and pseudouridylation of chloroplast transfer RNA in a chloroplast transcription system

The trancription of a cloned trnV1-trnN1-trnR1 cluster from Euglena gracilis chloroplast (ct) DNA and the processing of a tRNA(Val)-tRNA(Asn)-tRNA(Arg) polycistronic precursor were studied in a spinach ct transcription extract. A soluble ct RNA polymerase selectively transcribes the trnV1-trnN1-trnR1-trnL1 locus in the EcoG fragment from the Euglena ct genome. Restriction enzyme modified templates and RNA fingerprint analysis were used to confirm that the tRNA genes were correctly transcribed. The tRNA(Val)-tRNA(Asn)-tRNA(Arg) polycistronic precursor transcribed by RNA polymerase III in a HeLa cell extract was used as a substrate to demonstrate that a ct tRNA precursor molecule is correctly processed by the ct tRNA processing enzymes. The oligonucleotide pattern of tRNAs processed in vitro from the tRNA(Val)-tRNA(Asn)-RNA(Arg) polycistronic precursor is indistinguishable from tRNA(Val), tRNA(Asn) and tRNA(Arg) transcribed by the ct RNA polymerase and processed in the ct transcription extract. The 3'-CCAOH is added to the tRNAs by a 3' nucleotidyltransferase after correct processing of the 3' terminus. Correct pseudouridylation was demonstrated for uridine residues in a tRNA(Met) m molecule transcribed from a spinach ct trnM1 locus. Thus, the enzymatic activities involved in tRNA biosynthesis in vitro include DNA-dependent (tDNA) RNA polymerase, a 5'-processing activity (RNase P-like), a 3'-exonuclease, an endoribonuclease involved in 3'-tRNA maturation, a tRNA nucleotidyltransferase, and pseudouridylate synthetase.

Processing of tRNA in prokaryotes and eukaryotes

Considerable progress has been made in defining the steps in the conversion of a tRNA precursor to a mature tRNA. These steps, which differ in different systems, include removal of precursor-specific residues from the 5' and 3' termini of the initial transcript, addition of the 3'-C-C-A terminus, splicing of intervening sequences, and modification of nucleotide residues. Despite these advances in defining the "pathways" of tRNA processing, relatively little is known about most of the enzymes actually involved in these processing steps. In this article I describe the sequence of reactions needed to convert the initial tRNA transcript to a functional, mature tRNA, and discuss the specificity and properties of enzymes known to be involved in this process. In addition, I speculate on the expected specificities of other enzymes involved in tRNA processing which have not yet been identified, and on the structural organization of the processing machinery.

The tyrT locus: termination and processing of a complex transcript

The tyrT locus of E. coli contains a 208 bp spacer region that separates two copies of sequence encoding tRNATyr1. The spacer includes a 120 bp sequence that is homologous to a sequence that is repeated three times in the distal portion of the tyrT locus. The tyrT locus possesses a graded set of transcription termination sites that are spaced at 180 base intervals, corresponding to the distal repeated gene structure. The major termination site occurs within the second repeat unit, 225 bases beyond the mature tRNA sequences. In the presence of a temperature-sensitive rho protein there is increased read-through at this site to a termination site located 180 bases downstream in the third repeat and to several termination sites even further downstream. The primary native transcript, in the region distal to the second tRNA, carries the information for a low molecular weight, extremely basic protein. Although analogous coding sequences are present in the spacer and other repeat units, because of single base substitutions these sequences are pseudogenes. The parallel between the tyrT and TyrU gene clusters is discussed in relation to dual function transcripts that specify both tRNA and protein.

Properties of purified ribonuclease P from Escherichia coli

The purified protein moiety of ribonuclease P (EC 3.1.26.5) from Escherichia coli, a single polypeptide of molecular weight approximately 17 500, has not catalytic activity by itself on several RNA substrates. However, when it is marked in vitro with an RNA species called M1 RNA, RNase P activity is reconstituted. The rate at which the purified RNase P cleaves any particular tRNA precursor molecule depends on the identity of that tRNA precursor.

Total synthesis of a gene

The method developed for the total synthesis of a given DNA containing biologically specific sequences consists of the following. The DNA in the double-stranded form is carefully divided into short single-stranded segments with suitable overlaps in the complementary strands. All the segments are chemically synthesized starting with protected nucleosides and mononucleotides. The 5'-OH ends of the appropriate oligonucleotides are then phosphorylated with the use of [y-32P]ATP and polynucleotide kinase. A few to several neighboring oligonucleotides are then allowed to form bihelical complexes in aqueous solution, and the latter are joined end to end by polynucleotide ligase to form covalently linked duplexes. Subsequent heat-to-tail joining of the short duplexes leads to the total DNA. The methods are described for the construction of a biologically functional suppressor transfer RNA gene. The total work involved (i) the synthesis of a 126-nucleotide-long bihelical DNA corresponding to a known precursor to the tyrosine suppressor transfer RNA, (ii) the sequencing of the promoter region and the distal region adjoining the C-C-A end, which contained a signal for the processing of the RNA transcript, (iii) total synthesis of the 207 base-pair-long DNA, which included the control elements, as well as the Eco R1 restriction endonuclease specific sequences at the two ends, and (iv) full characterization by transcription in vitro and amber suppressor activity in vivo of the synthetic gene.

Specific ribonucleases involved in processing of tRNA precursors of Escherichia coli. Partial purification and some properties

Ribonucleases O and Q, the two putative nucleolytic activities which we detected previously in the crude extract from a thermosensitive ribonuclease P mutant (TS241) of Escherichia coli and which were shown to function in the processing of tRNA precursors in vitro, were partially purified from the 1000000 x g supernatant fraction of E. coli Q13. In the course of purification of these enzymes, the total RNAs synthesized in the thermosensitive mutant at the restrictive temperature were used as the substrates and the activities were identified from disappearance or alteration of specific tRNA precursor molecules in polyacrylamide gel electrophoresis. The purified ribonuclease O preparation cleaved specifically the multimeric tRNA precursors at the spacer regions. The purified ribonuclease Q preparation removed, in accordance with the definition of this enzyme, extra nucleotides from the 3'-terminal ends of monomeric tRNA precursors. Some properties of these two nucleases were investigated. In addition to these nucleases, another exonuclease (tentatively designated ribonuclease Y) and ribonuclease P, a well-characterized endonuclease, were also purified. The sequential mode of the processing of tRNA precursors, originally observed in the cleavage reactions with the crude extracts in vitro, was supported by studies with the purified enzyme preparations.

Processing by ribonuclease II of the tRNATyr precursor of Escherichia coli synthesized in vitro

The tRNATyr precursor molecule, synthesized from phi 80 psu3+ DNA (containing a single tRNA gene) by DNA-dependent RNA polymerase and q factor, was about 205 nucleotides long. The main product of its digestion with a ribonuclease tii preparation from Escherichia coli showed the same electrophoretic mobility as tRNAtyr precursor isolated in vivo and was found to be identical to it when analysed using fingerprint techniques. This intermediate precursor synthesized in vitro was converted further by processing with ribonuclease P into an RNA identical size to mature tRNATyr. It was concluded that the initiation of transcription of the tRNATyr gene in vitro occurs at the same site as that of transcription in vivo and a termination occurs at about 80 nucleotides beyond the CCA end of tRNATyr.