Enzymatic RNA synthesis and RNase P. Evolutionary aspects

TransferRNA recognition was used as leit-motiv in the illustration of possible links between a hypothetical primordial RNA world and the contemporary DNA world. In an RNA world, 'proto-tRNA' could have functioned as replication origin and as primitive telomere. Possibly, this primitive structure is preserved in a 'universal substrate' for modern tRNA-specific enzymes. The combination of acceptor stem and T arm (plus a linker) was finally revealed as sufficient for the recognition by prokaryotic and eukaryotic RNase P, as well as other tRNA enzymes. In modern life forms, a tRNA-like element in viral RNAs still serves as replication origin, and furthermore, the recognition of similar structures as cryptic promoters is universally conserved for template-dependent RNA polymerases. Another common property of modern polymerases is their high, but clearly limited and condition-dependent substrate specificity. Very likely, also substrate recognition by primitive polymerases was not more stringent, and this lead to the occurrence of mixed nucleic acids as intermediates in the transition of genomic RNA to contemporary genomic DNA.

Similar cleavage efficiencies of an oligoribonucleotide substrate and an mdr1 mRNA segment by a hammerhead ribozyme

Hammerhead ribozymes (Rz) can specifically recognize and cleave target RNAs in trans. This makes them attractive in antisense RNA approaches for specific gene inactivation in vivo. A severe limitation is the poor cleavage efficiency of large RNA substrates, in contrast to the high activities observed with small oligoribonucleotides (oligos) as model substrates. It was suggested that the low efficiency is caused by poor accessibility of the target sequence in the structure of the long RNA substrates. This means it should be possible to overcome this limitation by judicious choice of the target sequence, although experimental proof was lacking. We observed similar cleavage efficiencies of small and large RNA substrates with a hammerhead Rz directed against multidrug resistance-encoding mdr1 mRNA. Accordingly, large RNAs can also be good substrates, if an optimal target sequence is selected.

Enzymatic synthesis of 2'-modified nucleic acids: identification of important phosphate and ribose moieties in RNase P substrates

For the first time mosaic nucleic acids composed of 50% RNA and 50% DNA can be obtained as transcripts with T7 RNA polymerase. Two NTPs could be replaced simultaneously in a transcription reaction. This means more than 40 deoxynucleotides were inserted in one transcript. Previously, a maximum of two deoxynucleotides could be incorporated and 2'-O-methyl-NTPs were not substrates at all. We obtained reasonable transcript yields with a maximal level of 99% 2'-O-methyl-NTPs, and the products contained up to 58% 2'-O-methylnucleotides at more than 20 positions. Sequence-specific nucleotide incorporation was monitored by sequence ladders (partial alkali or iodine cleavage). No base misincorporations were detected with 100% dGTP, dCTP and dTTP, and with partial incorporation of dATP alpha S, 2'-O-methyl-GTP alpha S and 2'-O-methyl-CTP alpha S, whereas they were found with dATP, 2'-O-methyl-ATP alpha S and 2'-O-methyl-UTP alpha S. Quantitative data allow predetermined modification levels of partially modified transcripts. Highly modified transcripts can be used for structural and functional studies, in modification interference approaches and for in vitro evolution procedures. Modification interference studies revealed a small number of important phosphate and ribose moieties in RNase P substrates. The conversion of T7 RNA polymerase to a DNA polymerase extends the observation that there is no absolute distinction between RNA and DNA polymerases. Accordingly, an adapted concept of a primordial RNA world is presented.

Tumefactive megalocytic interstitial nephritis in a patient with Escherichia coli bacteremia

Megalocytic interstitial nephritis is rare and primarily affects the cortex in an otherwise normal kidney. We recently encountered a patient with Escherichia coli bacteremia and oliguric acute renal failure who died of gram-negative septicemia. At autopsy, this patient's kidneys displayed typical features of megalocytic interstitial nephritis. We were able to perform special stains suggesting that the histiocytic interstitial cells originated from infiltrating macrophages. Our patient illustrates that macrophage proliferation can result in interstitial inflammation sufficiently severe to cause anuric acute renal failure.

Efficient cleavage of pre-tRNAs by E. coli RNAse P RNA requires the 2'-hydroxyl of the ribose at the cleavage site

RNAse P cleaves pre-tRNAs to liberate 5'-flanks and 5'-matured, 5'-phosphorylated tRNAs. It is not evident if the 2'-hydroxyls of the ribose moieties in the substrate are involved in the reaction. To study their influence in two different pre-tRNAs, we have modified specifically the 2'-hydroxyl groups at the cleavage site and in neighbouring positions. We have shown that these hydroxyls are important but not essential for the processing of these substrates by E. coli RNase P RNA (M1 RNA). The reduction in the catalytic efficiency was moderate for 2'-deoxy and severe for 2'-methoxy substitutions at the cleavage site. Additional effects of modifications in neighbouring positions were smaller. Based on our data we suggest that the modifications do not interfere with binding of the substrate, whereas they prevent an optimal steric arrangement for the hydrolysis reaction.

Modification interference approach to detect ribose moieties important for the optimal activity of a ribozyme

A new approach for modification interference studies is presented. It involves the use of phosphorothioates as a handle to analyze any desired base or sugar modification. This method was applied to identify ribose and phosphate moieties which could be important in the pre-tRNA recognition of E. coli RNase P RNA (M1 RNA). The utility of this technique was confirmed by detecting the inhibitory effect of a deoxyribose in the 5'-flank (position-1). This site was already known to interfere with RNase P cleavage, if modified. We have analyzed pre-tRNA(Tyr) and pre-tRNA(Phe) and found different interference patterns for both tRNAs. Two unpaired regions were involved in both pre-tRNAs. Phosphorothioates interfered at the transition between acceptor- and D-arms. The results with deoxythymidines in the T-loop indicated that deoxyribose moieties or the extra methyl group in thymidine could interfere with RNAse P cleavage. These data suggest that even in complete pre-tRNAs, only a few intact ribonucleotides are important in the substrate recognition by RNase P. We have demonstrated the potential of this new approach which offers many future applications in all fields involving nucleic acids, for example RNA processing, action of ribozymes, tRNA charging and studies related to DNA promoter recognition.

Enzymatic RNA synthesis with deoxynucleoside 5'-O-(1-thiotriphosphates)

We have investigated the incorporation of 2'-deoxynucleoside-5'-O-(1-thiotriphosphates) into RNA transcripts using T7 RNA polymerase. With the exception of [alpha-S]dGTP, we obtained full-length transcripts of pre-tRNA(Phe) and pre-tRNA(Tyr) using an appropriate mixture of 2'-deoxynucleoside 5'-O-(1-thiotriphosphate) and the corresponding normal nucleoside triphosphate. The yields of the transcripts were comparable to those obtained with unmodified NTPs. Both substrates, [alpha-S]dTTP and [alpha-S]dATP, were inserted specifically. However, [alpha-S]dCTP was excluded at specific sites. We could not obtain transcripts using the deoxyguanosine derivative.

Antisense oligoribonucleotides and RNase P. A great potential

This paper presents the possible--but at present mostly hypothetical--applications of RNase P for the specific inactivation of target RNAs. The natural substrates for RNase P are pre-tRNAs. The enzyme can also recognize and cleave smaller model substrates. These are simple hairpins for bacterial RNase P whereas the requirements for eukaryotic RNase P are more complex and less well understood. It is possible to split the RNase P substrates into two separate RNA molecules. One part of the split substrate RNA contains the RNase P cleavage site and the 5'-terminal half of the acceptor stem, embedded in a large target RNA. The other part of the substrate RNA provides the 3'-terminal half of the acceptor stem and it serves as antisense sequence ('external guide sequence'). Both parts can hybridize and reconstitute a functional substrate for RNase P; this results in cleavage of the target RNA by RNase P. The properties of this system are presented and advantages and problems discussed.

Phosphorothioates in pre-tRNAs can change the specificities of RNAses P or reduce the cleavage efficiencies

Several phosphorothioate-modified E coli and yeast pre-tRNAs were synthesized. If this modification included the phosphodiester at the RNase P cleavage site, two different effects were observed. With some pre-tRNAs the RNase P cleavage efficiency was severely reduced, whereas with other pre-tRNAs a new reaction type for RNase P was observed. Unlike the previously studied base or ribose modifications, phosphorothioates resulted in aberrant cleavages at unmodified phosphodiesters. These new sites could be located in the 5'-flank or in the acceptor stem of the tRNA domain. Modified mutants of E coli pre-tRNA(Tyr) with different base pairs at the RNase P cleavage site were cleaved with reduced efficiencies, but no aberrant products were observed.

A solid phase method for mapping restriction sites

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Initiator oligonucleotides for the combination of chemical and enzymatic RNA synthesis

Transcription reactions with T7 RNA polymerase were performed in the presence of short oligonucleotides (oligos) with guanosine at the 3'-end. We obtained transcripts which had included these 'initiator oligos' at their 5'-termini. The oligos could contain mixtures of deoxyribo-, ribo-, 2'-O-methylated and biotinylated nucleotides. Only the 3'-terminal guanosine of these oligos was encoded in the template DNA at the transcription start point, in contrast to the remainder of the sequence. This 5'-terminal sequence is variable and eliminates the limitation that transcripts must start with a 5'-terminal guanosine. With a 5'-biotinylated dinucleotide, we obtained end-labeled RNAs suitable for nonradioactive RNA sequencing.

The acceptor stem in pre-tRNAs determines the cleavage specificity of RNase P

As the result of an unusual RNase P specificity, some special, mature tRNAs have acceptor stems with eight instead of the common seven base pairs. The data from numerous studies suggest that some features in the tRNA domain of pre-tRNAs are important for this behaviour. Here, we show that only five base pairs in the acceptor stem of bacterial histidine tRNAs are required to obtain the changed cleavage site in an unrelated eukaryotic serine tRNA.

Direct sequencing of double-stranded polymerase chain reaction-amplified 16S rDNA

A number of different procedures have been developed for direct sequence analysis of PCR products. These methods rely on the cumbersome isolation of specific PCR products from agarose gels or the production of single-stranded template DNAs. In the approach presented here, we describe primers for the amplification of 16-S rDNA and a simple preparation of PCR product for sequencing.

Sequence changes in both flanking sequences of a pre-tRNA influence the cleavage specificity of RNase P

The cleavage specificities of the RNase P holoenzymes from Escherichia coli and the yeast Schizosaccharomyces pombe and of the catalytic M1 RNA from E. coli were analyzed in 5'-processing experiments using a yeast serine pre-tRNA with mutations in both flanking sequences. The template DNAs were obtained by enzymatic reactions in vitro and transcribed with phage SP6 or T7 RNA polymerase. The various mutations did not alter the cleavage specificity of the yeast RNase P holoenzyme; cleavage always occurred predominantly at position G + 1, generating the typical seven base-pair acceptor stem. In contrast, the specificity of the prokaryotic RNase P activities, i.e. the catalytic M1 RNA and the RNase P holoenzyme from E. coli, was influenced by some of the mutated pre-tRNA substrates, which resulted in an unusual cleavage pattern, generating extended acceptor stems. The bases G - 1 and C + 73, forming the eighth base pair in these extended acceptor stems, were an important motif in promoting the unusual cleavage pattern. It was found only in some natural pre-tRNAs, including tRNA(SeCys) from E. coli, and tRNAs(His) from bacteria and chloroplasts. Also, the corresponding mature tRNAs in vivo contain an eight base pair acceptor stem. The presence of the CCA sequence at the 3' end of the tRNA moiety is known to enhance the cleavage efficiency with the catalytic M1 RNA. Surprisingly, the presence or absence of this sequence in two of our substrate mutants drastically altered the cleavage specificity of M1 RNA and of the E. coli holoenzyme, respectively. Possible reasons for the different cleavage specificities of the enzymes, the influence of sequence alterations and the importance of stacking forces in the acceptor stems are discussed.

Substrate recognition by RNase P and by the catalytic M1 RNA: identification of possible contact points in pre-tRNAs

Modified bases were introduced into pre-tRNAs during in vitro RNA synthesis or by chemical modification. These RNAs were used as substrates for the catalytic M1 RNA and the RNase P holoenzyme from Schizosaccharomyces pombe. The synthetic approach permitted the insertion of 100% m7GTP into pre-tRNAs and this resulted in complete inhibition of the specific 5' processing reactions. Partially modified RNAs were obtained by chemical modifications of purines and uridines in the pre-tRNAs. This allowed detailed analyses of specific bases excluded in the products. With pre-tRNA(Ser) and initiator pre-tRNA(Met), strong effects were observed in the T arm and weaker effects in the anticodon stem. Only minor base exclusions were detected in the acceptor stem of pre-tRNA(Ser) and in the D arm of pre-tRNA(Met).

The methylation of one specific guanosine in a pre-tRNA prevents cleavage by RNase P and by the catalytic M1 RNA

Several modified nucleosides were introduced during in vitro RNA synthesis into a pre-tRNA(Ser). The pre-tRNAs were used as substrates for RNase P enzymes. No effects were observed with biotin-8-ATP or [alpha-S]-GPT, whereas with m7GTP, the cleavage reaction was completely inhibited. Analysis of pre-tRNAs which contained m7G at various positions has revealed a single base at the 5'-end of the acceptor stem where this modification absolutely prevents cleavage by catalytic M1 RNA, eukaryotic and prokaryotic RNase P holoenzymes. These results suggest that a critical contact must be made between pre-tRNA substrate and enzyme/ribozyme or that the approach of the potential cleaving agent (a positive magnesium ion) is made impossible by the positive charge at N-7 of the guanosine. In addition, we have shown that a pre-tRNA containing only m7G's can still form a complex with M1 RNA in a gel retardation assay.

Unusual promoter-independent transcription reactions with bacteriophage RNA polymerases

Efficient transcription reactions of DNA-dependent RNA polymerases require the presence of a specific promoter sequence. This report shows that in the absence of their cognate promoter, two bacteriophage RNA polymerases are capable of performing unusual transcription reactions: (i) the DNA template serves also as a primer for RNA synthesis and this leads to hybrid DNA/RNA molecules, (ii) if the DNA template forms a hairpin structure, the linear DNA can be transcribed via the 'rolling circle' mechanism.

RNA synthesis: strategies for the use of bacteriophage RNA polymerases

This communication presents an overview of the methods for the synthesis of RNA with virtually any desired sequence. The use of transcription vectors is a powerful and convenient approach, if the cloned gene of interest has restriction sites at the proper positions. To overcome these limitations, two methods were developed where chemically synthesized oligodeoxynucleotides (oligos) were applied to define the 3' and 5' termini of the chosen transcripts. Both approaches use cloned genes and the template DNA is synthesized with DNA polymerase I (Klenow fragment). Consequently, there are no size limitations for the synthesized RNAs. For short transcripts, the entire template DNA (including the promoter sequence) can be synthesized chemically and any desired RNA sequence is possible. Recently, it was shown that even oligos without any promoter sequence can be used as template DNA for RNA polymerases. Experimental data are presented for two approaches. The first example is the synthesis of template DNA for T7 RNA polymerase where two oligos (initiator and terminator) define the beginning and end of transcripts from a cloned gene. The second example is the use of simple oligos as templates for RNA polymerases. The major problem encountered was the inaccurate transcription termination, which resulted in one or two additional nucleotides beyond the encoded sequence.

Simplified in vitro synthesis of mutated RNA molecules. An oligonucleotide promoter determines the initiation site of T7RNA polymerase on ss M13 phage DNA

We describe a simplified method for the in vitro synthesis of mutated RNA molecules. The method makes use of an oligodeoxyribonucleotide (T7-oligo) which contains the T7RNA polymerase promoter sequence. In combination with a second oligonucleotide, a series of transcripts initiating and terminating at any chosen position on a cloned ss DNA (e.g. M13 phage DNA) can be generated. The phage DNA represents the non-coding DNA strand for the desired transcript; the T7-oligo determines the transcription start site, whereas the second oligonucleotide permits the choice of the transcription termination site. The synthesis of the required template DNA is achieved by hybridizing the two oligonucleotides to the phage DNA and subsequently synthesizing the coding DNA strand by a fill-in reaction with Klenow enzyme. The reaction product is used directly as a template for T7RNA polymerase; cloning of mutants is not required.

The RNA components of Schizosaccharomyces pombe RNase P are essential for cell viability

The fission yeast Schizosaccharomyces pombe contains in the haploid genome one copy of the gene (designated rrkl) for the RNA components of RNase P. Gene disruption in diploid cells of one copy of rrkl resulted in a moderate reduction of the level of cellular RNase P activity. Haploidization by meiosis demonstrated that rrkl is required for cell growth. Thus, the RNA components of S. pombe RNase P are essential in vivo. This is similar to the situation in Escherichia coli.

The RNA required in the first step of chlorophyll biosynthesis is a chloroplast glutamate tRNA

A molecule of chlorophyll is synthesized from eight molecules of delta-aminolevulinate (DALA), the universal precursor of porphyrins. The light-regulated conversion of glutamate to delta-aminolevulinate in the stroma of greening plastids involves the reduction of glutamate to glutamate-1-semialdehyde and its subsequent transamination. The components performing this conversion have been isolated from barley and Chlamydomonas and separated into three fractions by serial affinity chromatography on Blue Sepharose and haem- or chlorophyllin-Sepharose. The complete reaction can be performed in vitro in a reconstituted assay by combining all three fractions. An RNA is the essential component of the chlorophyllin-Sepharose-bound fraction. By nucleotide sequence analysis, we have now identified this RNA as a chloroplast glutamate acceptor RNA. Glutamate attached by an aminoacyl bond to the 3'-terminal adenosine of this RNA is a substrate for the enzyme(s) which perform the subsequent reactions. This reaction represents a novel role for transfer RNA: participation in the metabolic conversion of its cognate amino acid into another metabolite of low relative molecular mass which subsequently is not used in peptide bond synthesis.