Streptavidin aptamers: affinity tags for the study of RNAs and ribonucleoproteins

RNA affinity tags would be very useful for the study of RNAs and ribonucleoproteins (RNPs) as a means for rapid detection, immobilization, and purification. To develop a new affinity tag, streptavidin-binding RNA ligands, termed "aptamers," were identified from a random RNA library using in vitro selection. Individual aptamers were classified into two groups based on common sequences, and representative members of the groups had sufficiently low dissociation constants to suggest they would be useful affinity tools. Binding of the aptamers to streptavidin was blocked by presaturation of the streptavidin with biotin, and biotin could be used to dissociate RNA/streptavidin complexes. To investigate the practicality of using the aptamer as an affinity tag, one of the higher affinity aptamers was inserted into RPR1 RNA, the large RNA subunit of RNase P. The aptamer-tagged RNase P could be specifically isolated using commercially available streptavidin-agarose and recovered in a catalytically active form when biotin was used as an eluting agent under mild conditions. The aptamer tag was also used to demonstrate that RNase P exists in a monomeric form, and is not tightly associated with RNase MRP, a closely related ribonucleoprotein enzyme. These results show that the streptavidin aptamers are potentially powerful tools for the study of RNAs or RNPs.     

Substrate shape specificity of E coli RNase P ribozyme is dependent on the concentration of magnesium ion

The bacterial RNase P ribozyme can accept a hairpin RNA with CCA-3' tag sequence as well as a cloverleaf pre-tRNA as substrate in vitro, but the details are not known. By switching tRNA structure using an antisense guide DNA technique, we examined the Escherichia coli RNase P ribozyme specificity for substrate RNA of a given shape. Analysis of the RNase P reaction with various concentrations of magnesium ion revealed that the ribozyme cleaved only the cloverleaf RNA at below 10 mM magnesium ion. At 10 mM magnesium ion or more, the ribozyme also cleaved a hairpin RNA with a CCA-3' tag sequence. At above 20 mM magnesium ion, cleavage site wobbling by the enzyme in tRNA-derived hairpin occurred, and the substrate specificity of the enzyme became broader. Additional studies using another hairpin substrate demonstrated the same tendency. Our data strongly suggest that raising the concentration of metal ion induces a conformational change in the RNA enzyme.     

Introduction of a (poly)histidine tag in L-lactate dehydrogenase produces a mixture of active and inactive molecules

A (poly)histidine tag was fused to either the N- or the C-terminus of L-lactate dehydrogenase (LDH) of Bacillus stearothermophilus to facilitate purification and immobilization of these enzymes. The C-terminally tagged enzyme displayed lower activity compared both to the wild-type and to the N-terminally tagged variant. The reason for this loss of activity was investigated by affinity chromatography of the enzymes on a 5'-AMP-Sepharose resin and by size-exclusion chromatography. The C-terminally tagged enzyme could be separated into an inactive, unbound fraction and an active, bound fraction. Further differences between the C-terminally tagged enzyme and the N-terminally tagged and wild-type LDH were observed on size-exclusion chromatography of the three enzymes. These data suggest that the introduction of a "his-tag" at the C-terminus may induce misfolding of the LDH and serve as a warning that the introduction of a (poly)histidine tag can produce unforseen changes in a protein.     

Alterations in the intracellular level of a protein subunit of human RNase P affect processing of tRNA precursors

The human ribonucleoprotein ribonuclease P (RNase P), processing tRNA, has at least 10 distinct protein subunits. Many of these subunits, including the autoimmune antigen Rpp38, are shared by RNase MRP, a ribonucleoprotein enzyme required for processing of rRNA. We here show that constitutive expression of exogenous, tagged Rpp38 protein in HeLa cells affects processing of tRNA precursors. Alterations in the site-specific cleavage and in the steady-state level of 3′ sequences of the internal transcribed spacer 1 of rRNA are also observed. These processing defects are accompanied by selective shut-off of expression of Rpp38 and by low expression of the tagged protein. RNase P purified from these cells exhibits impaired activity in vitro. Moreover, inhibition of Rpp38 by the use of small interfering RNA causes accumulation of the initiator methionine tRNA precursor. Expression of other protein components, but not of the H1 RNA subunit, is coordinately inhibited. Our results reveal that normal expression of Rpp38 is required for the biosynthesis of intact RNase P and for the normal processing of stable RNA in human cells.     

Characterization and purification of Saccharomyces cerevisiae RNase MRP reveals a new unique protein component

In the yeast Saccharomyces cerevisiae, RNase mitochondrial RNA processing (MRP) is an essential endoribonuclease that consists of one RNA component and at least nine protein components. Characterization of the complex is complicated by the fact that eight of the known protein components are shared with a related endoribonuclease, RNase P. To fully characterize the RNase MRP complex, we purified it to apparent homogeneity in a highly active state using tandem affinity purification. In addition to the nine known protein components, both Rpr2 and a protein encoded by the essential gene YLR145w were present in our preparations of RNase MRP. Precipitation of a tagged version of Ylr145w brought with it the RNase MRP RNA, but not the RNase P RNA. A temperature-sensitive ylr145w mutant was generated and found to exhibit a rRNA processing defect identical to that seen in other RNase MRP mutants, whereas no defect in tRNA processing was observed. Homologues of the Ylr145w protein were found in most yeasts, fungi, and Arabidopsis. Based on this evidence, we propose that YLR145w encodes a novel protein component of RNase MRP, but not RNase P. We recommend that this gene be designated RMP1, for RNase MRP protein 1.     

Specific interaction and two-dimensional crystallization of histidine tagged yeast RNA polymerase I on nickel-chelating lipids.

Nickel-chelating lipid monolayers were used to generate two-dimensional crystals from yeast RNA polymerase I that was histidine-tagged on one of its subunits. The interaction of the enzyme with the spread lipid layers was found to be imidazole dependent, and the formation of two-dimensional crystals required small amounts of imidazole, probably to select the specific interaction of the engineered tag with the nickel. Two distinct preparations of RNA polymerase I tagged on different subunits yielded two different crystal forms, indicating that the position of the tag determines the crystallization process. The orientation of the enzyme in both crystal forms is correlated with the location of the tagged subunits in a three-dimensional model which shows that the tagged subunits are in contact with the lipid layer.     

Functional expression of N-terminally tagged membrane bound cytochrome P450

The introduction of an affinity tag offers an attractive approach to isolation of membrane proteins. The type of affinity tag and its positioning in the protein is determined by the desired subsequent experimental uses of the isolated protein. To minimize the risk of interference, membrane proteins may preferentially be tagged on the side of the membrane that does not harbor the active site. In cytochromes P450, affinity tags have traditionally been introduced at the C-terminal to obtain high expression levels and to avoid translocation of the affinity tag over the membrane bilayer. Using the plant cytochrome P450 CYP79A1 and CYP71E1 as model systems, we demonstrate that a full-length CYP79A1 strepII tagged at the N-terminal expresses well and is able to translocate over the lipid bilayer to produce a functionally active protein that is amenable to affinity purification. The expression level and activity of the N-terminally tagged CYP79A1 protein are very similar to those obtained for the C-terminally tagged version. As an experimental tool, ER luminal tagging is envisioned to offer many advantages in future P450 research work e.g. when catalytic properties of an enzyme or protein–protein interactions are to be investigated.     

Purification of low-abundance Arabidopsis plasma-membrane protein complexes and identification of candidate components

Purification of low-abundance plasma-membrane (PM) protein complexes is a challenging task. We devised a tandem affinity purification tag termed the HPB tag, which contains the biotin carboxyl carrier protein domain (BCCD) of Arabidopsis 3-methylcrotonal CoA carboxylase. The BCCD is biotinylated in vivo , and the tagged protein can be captured by streptavidin beads. All five C-terminally tagged Arabidopsis proteins tested, including four PM proteins, were functional and biotinylated with high efficiency in Arabidopsis. Transgenic Arabidopsis plants expressing an HPB-tagged protein, RPS2::HPB, were used to develop a method to purify protein complexes containing the HPB-tagged protein. RPS2 is a membrane-associated disease resistance protein of low abundance. The purification method involves microsomal fractionation, chemical cross-linking, solubilization, and one-step affinity purification using magnetic streptavidin beads, followed by protein identification using LC-MS/MS. We identified RIN4, a known RPS2 interactor, as well as other potential components of the RPS2 complex(es). Thus, the HPB tag method is suitable for the purification of low-abundance PM protein complexes.     

Characterization of Escherichia coli RNase PH.

We have previously shown that the orfE gene of Escherichia coli encodes RNase PH. Here we show that the OrfE protein (purified as described in the accompanying paper) (Jensen, K. F., Andersen, J. T., and Poulsen, P. (1992) J. Biol. Chem. 267, 17147-17152) has both the degradative and synthetic activities of RNase PH. This highly purified protein was used to characterize the enzymatic and structural properties of RNase PH. The enzyme requires a divalent cation and phosphate for activity, the latter property indicating that RNase PH is exclusively a phosphorolytic enzyme. Among tRNA-type substrates, the enzyme is most active against synthetic tRNA precursors containing extra residues following the -CCA sequence, and it can act on these molecules to generate mature tRNA with amino acid acceptor activity; 3'-phosphoryl-terminated molecules are not active as substrates. The equilibrium constant for RNase PH is near unity, suggesting that at the phosphate concentration present in vivo, the enzyme would participate in RNA degradation. The synthetic reaction of RNase PH displays a nonlinear response to increasing enzyme concentrations, and this may be due to self-aggregation of the protein. Higher order multimers of RNase PH could be detected by gel filtration at higher protein concentrations and by protein cross-linking. The possible role of RNase PH in tRNA processing is discussed.     

RNase P of the Cyanophora paradoxa cyanelle: a plastid ribozyme

Ribonuclease P (RNase P) is a ribonucleoprotein enzyme that generates the mature 5' ends of tRNAs. Ubiquitous across all three kingdoms of life, the composition and functional contributions of the RNA and protein components of RNase P differ between the kingdoms. RNA-alone catalytic activity has been reported throughout bacteria, but only for some archaea, and only as trace activity for eukarya. Available information for RNase P from photosynthetic organelles points to large differences to bacterial as well as to eukaryotic RNase P: for spinach chloroplasts, protein-alone activity has been discussed; for RNase P from the cyanelle of the glaucophyte Cyanophora paradoxa, a type of organelle sharing properties of both cyanobacteria and chloroplasts, the proportion of protein was found to be around 80% rather than the usual 10% in bacteria. Furthermore, the latter RNase P was previously found catalytically inactive in the absence of protein under a variety of conditions; however, the RNA could be activated by a cyanobacterial protein, but not by the bacterial RNase P protein from Escherichia coli. Here we demonstrate that, under very high enzyme concentrations, the RNase P RNA from the cyanelle of C. paradoxa displays RNA-alone activity well above the detection level. Moreover, the RNA can be complemented to a functional holoenzyme by the E. coli RNase P protein, further supporting its overall bacterial-like architecture. Mutational analysis and domain swaps revealed that this A,U-rich cyanelle RNase P RNA is globally optimized but conformationally unstable, since changes as little as a single point mutation or a base pair identity switch at positions that are not part of the universally conserved catalytic core led to a complete loss of RNA-alone activity. Likely related to this low robustness, extensive structural changes towards an E. coli-type P5-7/P15-17 subdomain as a canonical interaction site for tRNA 3'-CCA termini could not be coaxed into increased ribozyme activity.     

An essential protein-binding domain of nuclear RNase P RNA

Eukaryotic RNase P and RNase MRP are endoribonucleases composed of RNA and protein subunits. The RNA subunits of each enzyme share substantial secondary structural features, and most of the protein subunits are shared between the two. One of the conserved RNA subdomains, designated P3, has previously been shown to be required for nucleolar localization. Phylogenetic sequence analysis suggests that the P3 domain interacts with one of the proteins common to RNase P and RNase MRP, a conclusion strengthened by an earlier observation that the essential domain can be interchanged between the two enzymes. To examine possible functions of the P3 domain, four conserved nucleotides in the P3 domain of Saccharomyces cerevisiae RNase P RNA (RPR1) were randomized to create a library of all possible sequence combinations at those positions. Selection of functional genes in vivo identified permissible variations, and viable clones that caused yeast to exhibit conditional growth phenotypes were tested for defects in RNase P RNA and tRNA biosynthesis. Under nonpermissive conditions, the mutants had reduced maturation of the RPR1 RNA precursor, an expected phenotype in cases where RNase P holoenzyme assembly is defective. This loss of RPR1 RNA maturation coincided, as expected, with a loss of pre-tRNA maturation characteristic of RNase P defects. To test whether mutations at the conserved positions inhibited interactions with a particular protein, specific binding of the individual protein subunits to the RNA subunit was tested in yeast using the three-hybrid system. Pop1p, the largest subunit shared by RNases P and MRP, bound specifically to RPR1 RNA and the isolated P3 domain, and this binding was eliminated by mutations at the conserved P3 residues. These results indicate that Pop1p interacts with the P3 domain common to RNases P and MRP, and that this interaction is critical in the maturation of RNase P holoenzyme.     

The physiological role of RNase T can be explained by its unusual substrate specificity

Escherichia coli RNase T, the enzyme responsible for the end-turnover of tRNA and for the 3' maturation of 5 S and 23 S rRNAs and many other small, stable RNAs, was examined in detail with respect to its substrate specificity. The enzyme was found to be a single-strand-specific exoribonuclease that acts in the 3' to 5' direction in a non-processive manner. However, although other Escherichia coli exoribonucleases stop several nucleotides downstream of an RNA duplex, RNase T can digest RNA up to the first base pair. The presence of a free 3'-hydroxyl group is required for the enzyme to initiate digestion. Studies with RNA homopolymers and a variety of oligoribonucleotides revealed that RNase T displays an unusual base specificity, discriminating against pyrimidine and, particularly, C residues. Although RNase T appears to bind up to 10 nucleotides in its active site, its specificity is defined largely by the last 4 residues. A single 3'-terminal C residue can reduce RNase T action by >100-fold, and 2-terminal C residues essentially stop the enzyme. In vivo, the substrates of RNase T are similar in that they all contain a double-stranded stem followed by a single-stranded 3' overhang; yet, the action of RNase T on these substrates differs. The substrate specificity described here helps to explain why the different substrates yield different products, and why certain RNA molecules are not substrates at all.     

Protein structure modeling indicates hexahistidine-tag interference with enzyme activity

Unusual kinetic characteristics of tropinone reductase, an enzyme in the family of short chain dehydrogenases, prompted to investigate a possible impact of the hexahistidine affinity tag on catalytic properties. Comparison of enzymes from Solanum dulcamara, Solanaceae, tagged at the N-terminus or at the C-terminus revealed that the C-terminally tagged form was functionally impaired. Protein modeling indicated that the hexahistidine tag attached at the C-terminus but not at the N-terminus of the polypeptide can interfere with the active site by steric or electrostatic interactions. In consequence, protein modeling is suggested before enzyme expression with affinity tags to estimate possible interactions of affinity tags with the active center.     

Characterization of the RNase P RNA of Sulfolobus acidocaldarius.

RNase P is the ribonucleoprotein enzyme that cleaves precursor sequences from the 5' ends of pre-tRNAs. In Bacteria, the RNA subunit is the catalytic moiety. Eucaryal and archaeal RNase P activities copurify with RNAs, which have not been shown to be catalytic. We report here the analysis of the RNase P RNA from the thermoacidophilic archaeon Sulfolobus acidocaldarius. The holoenzyme was highly purified, and extracted RNA was used to identify the RNase P RNA gene. The nucleotide sequence of the gene was determined, and a secondary structure is proposed. The RNA was not observed to be catalytic by itself, but it nevertheless is similar in sequence and structure to bacterial RNase P RNA. The marked similarity of the RNase P RNA from S. acidocaldarius and that from Haloferax volcanii, the other known archael RNase P RNA, supports the coherence of Archaea as a phylogenetic domain.     

An active precursor in assembly of yeast nuclear ribonuclease P

The RNA-protein subunit assembly of nuclear RNase P was investigated by specific isolation and characterization of the precursor and mature forms of RNase P using an RNA affinity ligand. Pre-RNase P was as active in pre-tRNA cleavage as mature RNase P, although it contained only seven of the nine proteins found in mature RNase P. Pop3p and Rpr2p were not required for maturation of the RPR1 RNA subunit and virtually absent from pre-RNase P, implying that they are dispensable for pre-tRNA substrate recognition and cleavage. The RNase P subunit assembly is likely to occur in the nucleolus, where both precursor and mature forms of RNase P RNA are primarily localized. The results provide insight into assembly of nuclear RNase P, and suggest pre-tRNA substrate recognition is largely determined by the RNA subunit.