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.

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.

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.

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.

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.

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.

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.

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.

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.

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.

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.

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).

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.

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.

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.