The colorimetric determination of selectively cleaved adenosines and guanosines in DNA oligomers using bicinchoninic acid and copper.

Colorimetric methods combined with color-changing chemical probes are widely used as simple yet effective tools for identifying and quantifying a wide variety of molecules in solution. For nucleic acids (DNA and RNA), perhaps the most commonly used colorimetric probe is potassium permanganate, which can be used to identify single-stranded pyrimidines (thymine and cytosine) in polymers. Unfortunately, permanganate is not an effective probe for identifying purines (adenine and guanine), especially in the presence of the more reactive pyrimidines. Therefore, robust methods for discriminating between the purines remain elusive, thereby creating a barrier toward developing more complex colorimetric applications. In this proof-of-principle study, we demonstrate that bicinchoninic acid (BCA) and copper, when combined with purine-specific chemical cleavage reactions, can be a colorimetric probe for the identification and quantification of adenosines and/or guanosines in single-stranded DNA oligomers, even in the presence of pyrimidines. Furthermore, the reactions are stoichiometric, which allows for the quantification of the number of adenosines and/or guanosines in these oligomers. Because the BCA/copper reagent detects the reducing sugar, 2-deoxyribose, that results from the chemical cleavage of a given nucleotide's N-glycosidic bond, these colorimetric assays are effectively detecting apurinic sites in DNA oligomers, which are known to occur via DNA damage in biological systems. We demonstrate that simple digital analysis of the color-changing chromophore (BCA/copper) is all that is necessary to obtain quantifiable and reproducible data, which indicates that these assays should be broadly accessible.

Association between extracellular matrix expansion quantified by cardiovascular magnetic resonance and short-term mortality.

BACKGROUND: Extracellular matrix expansion may be a fundamental feature of adverse myocardial remodeling, it appears to be treatable, and its measurement may improve risk stratification. Yet, the relationship between mortality and extracellular matrix is not clear because of difficulties with its measurement. To assess its relationship with outcomes, we used novel, validated cardiovascular magnetic resonance techniques to quantify the full spectrum of extracellular matrix expansion not readily detectable by conventional cardiovascular magnetic resonance. METHODS AND RESULTS: We recruited 793 consecutive patients at the time of cardiovascular magnetic resonance without amyloidosis or hypertrophic cardiomyopathy as well as 9 healthy volunteers (ages 20-50 years). We measured the extracellular volume fraction (ECV) to quantify the extracellular matrix expansion in myocardium without myocardial infarction. ECV uses gadolinium contrast as an extracellular space marker based on T1 measures of blood and myocardium pre- and post-gadolinium contrast and hematocrit measurement. In volunteers, ECV ranged from 21.7% to 26.2%, but in patients it ranged from 21.0% to 45.8%, indicating considerable burden. There were 39 deaths over a median follow-up of 0.8 years (interquartile range 0.5-1.2 years), and 43 individuals who experienced the composite end point of death/cardiac transplant/left ventricular assist device implantation. In Cox regression models, ECV related to all-cause mortality and the composite end point (hazard ratio, 1.55; 95% confidence interval, 1.27-1.88 and hazard ratio, 1.48; 95% confidence interval, 1.23-1.78, respectively, for every 3% increase in ECV), adjusting for age, left ventricular ejection fraction, and myocardial infarction size. CONCLUSIONS: ECV measures of extracellular matrix expansion may predict mortality as well as other composite end points (death/cardiac transplant/left ventricular assist device implantation).

Ribozyme-mediated trans insertion-splicing into target RNAs.

The trans insertion-splicing (TIS) reaction is a technique that can be used to site-specifically insert an RNA donor substrate into a separate RNA acceptor substrate. The TIS reaction, which is catalyzed by a group I intron-derived ribozyme from Pneumocystis carinii, is described with regards to system design, ribozyme preparation, and the overall protocol for conducting the TIS reaction.

Myocardial extravascular extracellular volume fraction measurement by gadolinium cardiovascular magnetic resonance in humans: slow infusion versus bolus.

BACKGROUND: Myocardial extravascular extracellular volume fraction (Ve) measures quantify diffuse fibrosis not readily detectable by conventional late gadolinium (Gd) enhancement (LGE). Ve measurement requires steady state equilibrium between plasma and interstitial Gd contrast. While a constant infusion produces steady state, it is unclear whether a simple bolus can do the same. Given the relatively slow clearance of Gd, we hypothesized that a bolus technique accurately measures Ve, thus facilitating integration of myocardial fibrosis quantification into cardiovascular magnetic resonance (CMR) workflow routines. Assuming equivalence between techniques, we further hypothesized that Ve measures would be reproducible across scans. METHODS: In 10 volunteers (ages 20-81, median 33 yr, 3 females), we compared serial Ve measures from a single short axis slice from two scans: first, during a constant infusion, and second, 12-50 min after a bolus (0.2 mmol/kg gadoteridol) on another day. Steady state during infusion was defined when serial blood and myocardial T1 data varied <5%. We measured T1 on a 1.5 T Siemens scanner using a single-shot modified Look Locker inversion recovery sequence (MOLLI) with balanced SSFP. To shorten breath hold times, T1 values were measured with a shorter sampling scheme that was validated with spin echo relaxometry (TR = 15 sec) in CuSO4-Agar phantoms. Serial infusion vs. bolus Ve measures (n = 205) from the 10 subjects were compared with generalized estimating equations (GEE) with exchangeable correlation matrices. LGE images were also acquired 12-30 minutes after the bolus. RESULTS: No subject exhibited LGE near the short axis slices where Ve was measured. The Ve range was 19.3-29.2% and 18.4-29.1% by constant infusion and bolus, respectively. In GEE models, serial Ve measures by constant infusion and bolus did not differ significantly (difference = 0.1%, p = 0.38). For both techniques, Ve was strongly related to age (p < 0.01 for both) in GEE models, even after adjusting for heart rate. Both techniques identically sorted older individuals with higher mean Ve values. CONCLUSION: Myocardial Ve can be measured reliably and accurately 12-50 minutes after a simple bolus. Ve measures are also reproducible across CMR scans. Ve estimation can be integrated into CMR workflow easily, which may simplify research applications involving the quantification of myocardial fibrosis.

Analyzing and predicting the thermodynamic effects of the metabolite trehalose on nucleic acids.

There is a lot of interest in exactly how nucleic acid duplexes are affected by the addition of certain stabilizing and destabilizing metabolites. Unfortunately, the differences in reaction conditions between published reports often precludes a comparison of the results, effectively preventing a cohesive strategy for predicting additive effects on nucleic acid stability. This information is critically important for obtaining a fundamental understanding of how additives, including metabolites, alter DNA and RNA stability and structure. We now show that the destabilization of nucleic acids by the metabolite trehalose in standard optical melting buffer (20 mM sodium cacodylate, 1M NaCl, and 0.5 mM EDTA) differs from that of a common PCR buffer, and a simulated physiological buffer, with up to an 8°C melting temperature difference. We also demonstrate that the extent of DNA destabilization due to trehalose depends on DNA length and depends on percent GC content, at least for the primer-length duplexes studied here. Furthermore, we show that glucose (a monomer) is not quite as effective a destabilizer as trehalose (a dimer). The implications of these results related to trehalose-destabilization of DNA, related to conducting and analyzing DNA-additive experiments, and related to using this type of data for predictive purposes are discussed.

Ribozyme mediated trans insertion-splicing of modified oligonucleotides into RNA.

The trans insertion-splicing reaction, catalyzed by a group I intron-derived from Pneumocystis carinii, was recently developed for the site-specific insertion of a segment of RNA into a separate RNA substrate. The molecular determinants of this reaction for binding and catalysis are reasonably well understood, making them easily and highly modifiable for altering substrate specificity. To demonstrate proof-of-concept, we now report that the P. carinii ribozyme can except modified oligonucleotides as substrates for catalyzing the trans insertion-splicing reaction. Oligonucleotides that contain one or more sugar modifications (deoxy or methoxy substitution), a backbone modification (phosphorothioate substitution), or a base modification (2-aminopurine or 4-thiouridine) are effective substrates in this reaction. Apparently, trans insertion-splicing is a unique and viable reaction for the site-specific incorporation of modified oligonucleotides into RNAs. This is the first report of a group I intron-derived ribozyme being capable of catalyzing the insertion of a modified oligonucleotide into RNA.

Tetrahymena thermophila and Candida albicans group I intron-derived ribozymes can catalyze the trans-excision-splicing reaction.

Group I intron-derived ribozymes can catalyze a variety of non-native reactions. For the trans-excision-splicing (TES) reaction, an intron-derived ribozyme from the opportunistic pathogen Pneumocystis carinii catalyzes the excision of a predefined region from within an RNA substrate with subsequent ligation of the flanking regions. To establish TES as a general ribozyme-mediated reaction, intron-derived ribozymes from Tetrahymena thermophila and Candida albicans, which are similar to but not the same as that from Pneumocystis, were investigated for their propensity to catalyze the TES reaction. We now report that the Tetrahymena and Candida ribozymes can catalyze the excision of a single nucleotide from within their ribozyme-specific substrates. Under the conditions studied, the Tetrahymena and Candida ribozymes, however, catalyze the TES reaction with lower yields and rates [Tetrahymena (k(obs)) = 0.14/min and Candida (k(obs)) = 0.34/min] than the Pneumocystis ribozyme (k(obs) = 3.2/min). The lower yields are likely partially due to the fact that the Tetrahymena and Candida catalyze additional reactions, separate from TES. The differences in rates are likely partially due to the individual ribozymes ability to effectively bind their 3' terminal guanosines as intramolecular nucleophiles. Nevertheless, our results demonstrate that group I intron-derived ribozymes are inherently able to catalyze the TES reaction.

Kinetic characterization of the first step of the ribozyme-catalyzed trans excision-splicing reaction.

Group I introns catalyze the self-splicing reaction, and their derived ribozymes are frequently used as model systems for the study of RNA folding and catalysis, as well as for the development of non-native catalytic reactions. Utilizing a group I intron-derived ribozyme from Pneumocystis carinii, we previously reported a non-native reaction termed trans excision-splicing (TES). In this reaction, an internal segment of RNA is excised from an RNA substrate, resulting in the covalent reattachment of the flanking regions. TES proceeds through two consecutive phosphotransesterification reactions, which are similar to the reaction steps of self-splicing. One key difference is that TES utilizes the 3'-terminal guanosine of the ribozyme as the first-step nucleophile, whereas self-splicing utilizes an exogenous guanosine. To further aid in our understanding of ribozyme reactions, a kinetic framework for the first reaction step (substrate cleavage) was established. The results demonstrate that the substrate binds to the ribozyme at a rate expected for simple helix formation. In addition, the rate constant for the first step of the TES reaction is more than one order of magnitude lower than the analogous step in self-splicing. Results also suggest that a conformational change, likely similar to that in self-splicing, exists between the two reaction steps of TES. Finally, multiple turnover is curtailed because dissociation of the cleavage product is slower than the rate of chemistry.

A Pneumocystis carinii group I intron-derived ribozyme utilizes an endogenous guanosine as the first reaction step nucleophile in the trans excision-splicing reaction.

In the trans excision-splicing reaction, a Pneumocystis carinii group I intron-derived ribozyme binds an RNA substrate, excises a specific internal segment, and ligates the flanking regions back together. This reaction can occur both in vitro and in vivo. In this report, the first of the two reaction steps was analyzed to distinguish between two reaction mechanisms: ribozyme-mediated hydrolysis and nucleotide-dependent intramolecular transesterification. We found that the 3'-terminal nucleotide of the ribozyme is the first-reaction step nucleophile. In addition, the 3'-half of the RNA substrate becomes covalently attached to the 3'-terminal nucleotide of the ribozyme during the reaction, both in vitro and in vivo. Results also show that the identity of the 3'-terminal nucleotide influences the rate of the intramolecular transesterification reaction, with guanosine being more effective than adenosine. Finally, expected products of the hydrolysis mechanism do not form during the reaction. These results are consistent with only the intramolecular transesterification mechanism. Unexpectedly, we also found that ribozyme constructs become truncated in vivo, probably through intramolecular 3'-hydrolysis (self-activation), to create functional 3'-terminal nucleotides.

Trans insertion-splicing: ribozyme-catalyzed insertion of targeted sequences into RNAs.

A group I intron-derived ribozyme from Pneumocystis carinii has been previously shown to bind an exogenous RNA substrate, splice out an internal segment, and then ligate the two ends back together (the trans excision-splicing reaction). We demonstrate that this same ribozyme can perform a trans insertion-splicing (TIS) reaction, where the ribozyme binds two exogenous RNA substrates and inserts one directly into the other. Reactions were optimized for both yield and rate, with optimum reactions carried out in 10 mM MgCl(2) for 2 h. Reaction products are stable, with no visible loss at extended times. The ribozyme recognizes the two substrates primarily through base pairing and requires an omegaG on the ribozyme and an omegaG on the sequence being inserted. We give evidence that the reaction mechanism is not the reverse of the trans excision-splicing reaction, but is composed of three steps, with intermediates attached to the ribozyme. Surprisingly, the internal guide sequence of the ribozyme is utilized to sequentially bind both substrates, forming independent P1 helices. This is an indication that ribozymes with essentially the native intron sequence can catalyze reactions significantly more dynamic and complex than self-splicing. The implications of group I intron-derived ribozymes being able to catalyze this unique reaction, and via this mechanism, are discussed.

In vivo excision of a single targeted nucleotide from an mRNA by a trans excision-splicing ribozyme.

We have previously reported the development of a group I intron-derived ribozyme that can bind an exogenous RNA substrate and excise from that substrate an internal segment in vitro, which allows for sequence-specific modification of RNA molecules. In this report, the activity of this trans excision-splicing ribozyme in a cellular environment, specifically Escherichia coli, was investigated. The ribozyme was re-engineered to target for excision a single-base insertion in the transcript of a green fluorescent protein, and fluorescence was exploited as a reporter for trans excision-splicing. We show that the ribozyme is able to catalyze the trans excision-splicing reaction in vivo and can repair the mutant transcripts. On average, 12% correction is observed as measured by fluorescence and at least 0.6% correction as confirmed through sequence analysis. This represents the first report of a biomolecule (in this case a ribozyme) that can selectively excise a targeted nucleotide from within an mRNA transcript in vivo. This new class of biochemical tools makes possible a wide variety of new experimental strategies, perhaps including a new approach to molecular-based therapeutics.

5' transcript replacement in vitro catalyzed by a group I intron-derived ribozyme.

Group I intron-derived ribozymes can perform a variety of catalytic reactions, including the replacement of the 3' end of a mutant RNA transcript with a corrected version of the transcript [Sullenger, B. A., and Cech, T. R. (1994) Nature 371, 619-622]. We now demonstrate in vitro that a ribozyme, derived from a Pneumocystis carinii group I intron, can replace the 5' end of a targeted exogenous RNA with an endogenous RNA. Our model system is a short synthetic mimic of a k-ras transcript, in which substitution mutations at codon 12 are implicated in a host of cancer types. In these experiments, yields of up to 70% were obtained. We analyzed the length dependence of two molecular contacts, P9.0 and P10, that occur between the ribozyme and the exogenous k-ras mimic, and determined that longer, and thus more stable, interactions result in higher product yields. Furthermore, the length of the loop region L1 can substantially influence the yield and the rate of the reaction. These results are a further demonstration that group I intron-derived ribozymes are quite malleable in terms of intermolecular recognition and catalysis, and that these properties can be exploited in developing potentially useful biochemical tools.

Molecular recognition in a trans excision-splicing ribozyme: non-Watson-Crick base pairs at the 5' splice site and omegaG at the 3' splice site can play a role in determining the binding register of reaction substrates.

Trans excision-splicing (TES) ribozymes, derived from a Pneumocystis carinii group I intron, can catalyze the excision of targeted sequences from within RNAs. In this report, the sequence requirements of the splice sites are analyzed. These conserved sequences include a u-G wobble pair at the 5' splice site and a guanosine in the omega position at the 3' splice site (in the substrate). We report that 7 out of 16 base pair combinations at the 5' splice site produce appreciable TES product. This promiscuity is in contrast to results reported for analogous self-splicing reactions using a Tetrahymena ribozyme. At long reaction times TES products dissociate and rebind free ribozyme, at which point product degradation occurs via the 5' cleavage reaction. Unexpectedly, only in cases where Watson-Crick base pairs form at the 5'splice site do we see degradation of TES products at cryptic sites, suggesting that non-Watson-Crick base pairs at the 5' splice site are acting in concert with other factors to precisely determine the binding register of TES reaction substrates within the ribozyme. Moreover, cryptic site degradation does not occur with the corresponding reaction substrates, which additionally contain omegaG, suggesting that omegaG can play a similar role. We report that omegaG cannot be replaced by any other base, so TES substrates require a guanosine as the last (or only) base to be excised. Additionally, we demonstrate that P9.0 and P10 are expendable for TES reactions, suggesting that omegaG is sufficient as a 3' molecular recognition element.

Enhancing the second step of the trans excision-splicing reaction of a group I ribozyme by exploiting P9.0 and P10 for intermolecular recognition.

We previously reported that a group I intron-derived ribozyme can catalyze the excision of targeted sequences from within RNAs in vitro and that dissociation of the bridge-3' exon intermediate between the two reaction steps is a significant contributing factor to low product yields. We now analyze the effects of increasing the length, and thus the strength, of helices P9.0 and P10, which occur between the ribozyme and the bridge-3' exon region of the substrate, on this trans excision-splicing reaction. Using substrates where lengthy targeted regions are excised, these modifications can significantly increase product yields, specifically by enhancing the second reaction step. A threshold for product formation is obtained, however, at around five base pairs for P10 and eight base pairs for P9.0. Nevertheless, elongating P9.0 appears to be the more effective strategy, as both substrate binding and the rate of the second reaction step increase. In addition, P10 is required when P9.0 is not elongated. Also, a strong P9.0 helix cannot replace a weaker P10 helix, indicating that P9.0 and P10 play somewhat distinct roles in the reaction. We also show that second-step inhibition stems from the formation of an extended P1 helix (P1ex), consisting of as little as a single Watson-Crick base pair, as well as the mere presence of substrate nucleosides immediately downstream from P10. Both of these inhibitory components can be overcome by utilizing P9.0 and P10 elongated ribozymes. This work sets forth an initial framework for rationally designing more effective trans excision-splicing ribozymes.

Canonical nucleosides can be utilized by T4 DNA ligase as universal template bases at ligation junctions.

T4 DNA ligase catalyzes the template-dependent ligation of DNA. Using T4 DNA ligase under specific experimental conditions, we demonstrate that each of the four canonical nucleosides, centrally located on a template molecule such that they flank the site of ligation, can direct the ligation of nucleic acids regardless of the identity of the terminal nucleosides being covalently joined. This universal templating capability extends to those positions adjacent to the ligation junction. This is the first report, irrespective of the ligation method used or the identity of the template nucleosides (including analogs), which shows that nucleosides can act essentially as universal templates at ligation junctions in vitro. The canonical nucleosides do, however, differ in their ability to template sequence- independent ligations, with thymidine and guanosine being equally effective, yet more effective than adenosine and cytidine. Results indicate that hybridization strength surrounding the ligation junction is an important factor. The implications of this previously undiscovered property of T4 DNA ligase with canonical nucleosides are discussed.

Molecular recognition properties of IGS-mediated reactions catalyzed by a Pneumocystis carinii group I intron.

We report the development, analysis and use of a new combinatorial approach to analyze the substrate sequence dependence of the suicide inhibition, cyclization, and reverse cyclization reactions catalyzed by a group I intron from the opportunistic pathogen Pneumocystis carinii. We demonstrate that the sequence specificity of these Internal Guide Sequence (IGS)-mediated reactions is not high. In addition, the sequence specificity of suicide inhibition decreases with increasing MgCl(2) concentration, reverse cyclization is substantially more sequence specific than suicide inhibition, and multiple reverse cyclization products occur, in part due to the formation of multiple cyclization intermediates. Thermodynamic analysis reveals that a base pair at position -4 of the resultant 5' exon-IGS (P1) helix is crucial for tertiary docking of the P1 helix into the catalytic core of the ribozyme in the suicide inhibition reaction. In contrast to results reported with a Tetrahymena ribozyme, altering the sequence of the IGS of the P.carinii ribozyme can result in a marked reduction in tertiary stability of docking the resultant P1 helix into the catalytic core of the ribozyme. Finally, results indicate that RNA targeting strategies which exploit tertiary interactions could have low specificity due to the tolerance of mismatched base pairs.

Ribozyme-catalyzed excision of targeted sequences from within RNAs.

We demonstrate that a group I intron-derived ribozyme from the opportunistic pathogen Pneumocystis carinii can bind an RNA in trans and excise from within it an internal segment, resulting in the splicing of the remaining ends of the RNA back together (the trans excision-splicing reaction). The reaction is intramolecular with regard to substrate. The ribozyme targets its substrate by base pairing with two or three noncontiguous regions on the substrate, and the reaction occurs through a nucleotide cofactor independent mechanism. The excised segment can be as long as 28 nucleotides, or more, and as little as one nucleotide. The potential usefulness of this reaction is demonstrated by engineering a ribozyme that excises the triplet-repeat expansion region from a truncated myotonic dystrophy protein kinase transcript mimic in vitro.