Synthesis of pyrophosphates for in vitro selection of catalytic RNA molecules

Reported here are synthetic routes to pyrophosphates linking riboflavin with various nucleosides. The focus is on a flavin-uracil dinucleotide having a biotin tag on the uracil, a molecule that has potential value in the selection of RNA enzymes that catalyze the template-directed polymerization of RNA in the 3'-to-5' direction, which is the direction opposite that catalyzed by standard protein polymerases. Two detailed procedures are presented to prepare this new compound, as well as one procedure to prepare the new flavin-2,6-diaminopurine dinucleotide.     

Measurement of genome wide DNA methylation by reversed-phase high-performance liquid chromatography

Intrinsic affinity tags are useful tools for the study of macromolecular targets. Although polypeptide affinity tags are routinely used in purification and detection of protein complexes, there has been a relative lack of powerful RNA affinity tags that can be embedded within RNA sequences. Here, the preparation and use of two RNA affinity tags against Sephadex or streptavidin are described. The two tags have different strengths that make them appropriate for slightly different uses. One is a high-affinity ligand for streptavidin that can be specifically eluted by competition with biotin under otherwise native binding conditions. The other tag binds selectively to Sephadex beads, and can be eluted by competition with the soluble dextran that composes Sephadex. When properly placed within another RNA molecule, the tags can be used to effect dramatic purification of RNA or ribonucleoprotein complexes from complex mixtures of cellular RNA.     

Sets of RNA repeated tags and hybridization-sensitive fluorescent probes for distinct images of RNA in a living cell

Background

Imaging the behavior of RNA in a living cell is a powerful means for understanding RNA functions and acquiring spatiotemporal information in a single cell. For more distinct RNA imaging in a living cell, a more effective chemical method to fluorescently label RNA is now required. In addition, development of the technology labeling with different colors for different RNA would make it easier to analyze plural RNA strands expressing in a cell.

Methodology/Principal Findings

Tag technology for RNA imaging in a living cell has been developed based on the unique chemical functions of exciton-controlled hybridization-sensitive oligonucleotide (ECHO) probes. Repetitions of selected 18-nucleotide RNA tags were incorporated into the mRNA 3′-UTR. Pairs with complementary ECHO probes exhibited hybridization-sensitive fluorescence emission for the mRNA expressed in a living cell. The mRNA in a nucleus was detected clearly as fluorescent puncta, and the images of the expression of two mRNAs were obtained independently and simultaneously with two orthogonal tag–probe pairs.

Conclusions/Significance

A compact and repeated label has been developed for RNA imaging in a living cell, based on the photochemistry of ECHO probes. The pairs of an 18-nt RNA tag and the complementary ECHO probes are highly thermostable, sequence-specifically emissive, and orthogonal to each other. The nucleotide length necessary for one tag sequence is much shorter compared with conventional tag technologies, resulting in easy preparation of the tag sequences with a larger number of repeats for more distinct RNA imaging.     

Development of a hexahistidine-3× FLAG-tandem affinity purification method for endogenous protein complexes in Pichia pastoris

We developed a method for efficient chromosome tagging in Pichia pastoris, using a useful tandem affinity purification (TAP) tag. The TAP tag, designated and used here as the THF tag, contains a thrombin protease cleavage site for removal of the TAP tag and a hexahistidine sequence (6× His) followed by three copies of the FLAG sequence (3× FLAG) for affinity purification. Using this method, THF-tagged RNA polymerases I, II, and III were successfully purified from P. pastoris. The method also enabled us to purify the tagged RNA polymerase II on a large scale, for its crystallization and preliminary X-ray crystallographic analysis. The method described here will be widely useful for the rapid and large-scale preparation of crystallization grade eukaryotic multi-subunit protein complexes.     

Partial reconstitution of human RNase P in HeLa cells between its RNA subunit with an affinity tag and the intact protein components

An RNA affinity tag was incorporated into the RNA subunit of human nuclear RNase P. The tagged RNA assembled with the protein components of RNase P inside HeLa cells to generate an active enzyme. Because of the specificity of the RNA tag to streptavidin, the reconstituted complex could be separated from the native enzyme and other ribonucleoproteins (particularly RNase MRP) by streptavidin agarose chromatography and could be recovered by the eluting agent, biotin. A mutant, tagged RNase P RNA, whose P3 domain was partially replaced, could not reconstitute with the proteins to yield an active enzyme. The P3 domain, therefore, is critical for the structure and function of RNase P.     

The nonstructural protein 3 protease/helicase requires an intact protease domain to unwind duplex RNA efficiently

The nonstructural 3 (NS3) protein encoded by the hepatitis C virus possesses both an N-terminal serine protease activity and a C-terminal 3'-5' helicase activity. This study examines the effects of the protease on the helicase by comparing the enzymatic properties of the full-length NS3 protein with truncated versions in which the protease is either deleted or replaced by a polyhistidine (His tag) or a glutathione S-transferase fusion protein (GST tag). When the NS3 protein lacks the protease domain it unwinds RNA more slowly and does not unwind RNA in the presence of excess nucleic acid that acts as an enzyme trap. Some but not all of the RNA helicase activity can be restored by adding a His tag or GST tag to the N terminus of the truncated helicase, suggesting that the effects of the protease are both specific and nonspecific. Similar but smaller effects are also seen in DNA helicase and translocation assays. While translocating on RNA (or DNA) the full-length protein hydrolyzes ATP more slowly than the truncated protein, suggesting that the protease allows for more efficient ATP usage. Binding assays reveal that the full-length protein assembles on single-stranded DNA as a higher order oligomer than the truncated fragment, and the binding appears to be more cooperative. The data suggest that hepatitis C virus RNA helicase, and therefore viral replication, could be influenced by the rotations of the protease domain which likely occur during polyprotein processing.     

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.     

Improved native affinity purification of RNA

RNA biochemical or structural studies often require an RNA sample that is chemically pure, and most protocols for its in vitro production use denaturing polyacrylamide gel electrophoresis to achieve this. Unfortunately, many RNAs do not quantitatively refold into an active conformation after denaturation, creating significant problems for downstream characterization or use. In addition, this traditional purification method is not amenable to studies demanding high-throughput RNA production. Recently, we presented the first general method for producing almost any RNA sequence that employs an affinity tag that is removed during the purification process. Because technical difficulties prevented application of this method to many RNAs, we have developed an improved version that utilizes a different activatable ribozyme and affinity tag that are considerably more robust, rapid, and broadly applicable.     

Trans-translation: the tmRNA-mediated surveillance mechanism for ribosome rescue, directed protein degradation, and nonstop mRNA decay

The accurate flow of genetic information from DNA to RNA to protein is essential for all living organisms. An astonishing array of quality-assurance mechanisms have evolved to ensure that high degree of fidelity is maintained at every stage of this process. One of the most fascinating quality-control mechanisms involves tmRNA, also known as SsrA or 10Sa RNA. tmRNA is a versatile and highly conserved bacterial molecule endowed with the combined structural and functional properties of both a tRNA and a mRNA. The tmRNA system orchestrates three key biological functions: (1) recognition and rescue of ribosomes stalled on aberrant mRNAs, (2) disposal of the causative defective mRNAs, and (3) addition of a degradation tag to ribosome-associated protein fragments for directed proteolysis. Although not essential in Escherichia coli, tmRNA activity is essential for bacterial survival under adverse conditions and for virulence in some, and perhaps all, pathogenic bacteria. Recent evidence suggests that in addition to its quality-control function the tmRNA system might also play a key regulatory role in certain physiological pathways. This review will focus on recent advances in our understanding of the structural properties, mechanistic details, and physiological significance of this unique RNA and its principal protein partners.     

New approach to heterogeneous enzyme immunoassays using tagged enzyme-ligand conjugates

A new approach to heterogeneous enzyme immunoassays has been developed that uses a tag molecule linked to an enzyme-ligand conjugate. The insoluble phase is an insolubilized receptor to that tag. The antibody to the ligand, in addition to complexing either the free ligand or the one covalently linked to the tagged enzyme, also serves to mask the tag on the tagged enzyme-ligand conjugate so that it can no longer bind to the insolubilized receptor. Accordingly, the proportion of enzyme conjugate associated with the insoluble fraction is proportional to the amount of analyte ligand being assayed. This heterogeneous EIA based on the “antibody masking the tag” is called AMETIA. In the model system we use DNP-lysine as the ligand, β-galactosidase as the enzyme, biotin as the tag, and avidin immobilized to Sepharose as the insoluble receptor.     

The biological roles of trans-translation

The unique transfer-messenger RNA (tmRNA) molecule has been identified in all bacterial species examined, suggesting that its action confers an important survival advantage to bacteria. Acting both as a tRNA and an mRNA, in a process known as trans-translation, tmRNA adds a short peptide tag to undesirable proteins. Trans-translation plays at least two physiological roles: removing ribosomes stalled upon mRNA, and targeting the resulting truncated proteins for degradation by proteases. The first of these roles is required for all known activities of tmRNA, whereas the second may be dispensed with in most cases with little biological effect. However, tmRNA-targeted proteolysis may be important for fine-tuning expression of certain genes by altering the concentration of regulatory proteins. Here, we review recent literature that addresses the biological functions of tmRNA.     

Pre-binding of small protein B to a stalled ribosome triggers trans-translation

To rescue stalled ribosomes, eubacteria employ a molecule, transfer messenger RNA (tmRNA), which functions both as a tRNA and as an mRNA. With the help of small protein B (SmpB), tmRNA restarts protein synthesis and adds by the trans-translation mechanism a peptide tag to the stalled protein to target it for destruction by cellular proteases. Here, the cellular location and expression of endogenous SmpB were monitored in vivo. We report that SmpB is associated with 70S ribosomes and not in the soluble fraction, independently of the presence of tmRNA. In vitro, SmpB that is pre-bound to a stalled ribosome can trigger initiation of trans-translation. Our results demonstrate the existence of a novel pathway for the entry of tmRNA to the ribosome and for the trans-transfer of a nascent peptide chain from peptidyl-tRNA to charged tmRNA.     

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.     

Novel Techniques for Weak Alignment of Proteins in Solution Using Chemical Tags Coordinating Lanthanide Ions

A molecule with an anisotropic magnetic susceptibility is spontaneously aligned in a static magnetic field. Alignment of such a molecule yields residual dipolar couplings and pseudocontact shifts. Lanthanide ions have recently been successfully used to provide an anisotropic magnetic susceptibility in target molecules either by replacing a calcium ion with a lanthanide ion in calcium-binding proteins or by attaching an EDTA derivative to a cysteine residue via a disulfide bond. Here we describe a novel enantiomerically pure EDTA derived tag that aligns stronger due to its shorter linker and does not suffer from stereochemical diversity upon lanthanide complexation. We observed residual (15)N,(1)H-dipolar couplings of up to 8 Hz at 800 MHz induced by a single alignment tensor from this tag.