Melting of local ordered structures in yeast 5S ribosomal RNA in aqueous salts.

Equilibrium and kinetics of thermal melting of yeast 5S ribosomal RNA in aqueous NaCl with or without Mg2+ were investigated by differential thermal melting and temperature jump methods. Two peaks (1 and 2) and a shoulder were observed in each of melting curves at ionic strength I=0.002-0.5 and linearity between each of melting temperatures T1m and T2m and log I was found at I=0.01-0.5 in the Mg2+-free solution. The local structures were found to be stabilized considerably by Mg2+. The temperature jump measurements gave the kinetic melting curve of the structure 1 at I=0.03 without Mg2+ or with 0.5 mM Mg2+. The kinetic Tm coincided well with the corresponding static Tm. For the structure 1, various parameters were calculated from the kinetic data, which indicated a double helical character of the structure 1. In terms of the values of Tm, G-C content, and enthalpy change of the transition of the structure 1 or 2, appropriateness of each of the secondary structure models of eukaryotic 5S RNA proposed previously was discussed.     

Structural stability and unfolding properties of thermostable bacterial alpha-amylases: a comparative study of homologous enzymes

In a comparative investigation on two thermostable alpha-amylases [Bacillus amyloliquefaciens (BAA), T(m) = 86 degrees C and Bacillus licheniformis (BLA), T(m) = 101 degrees C], we studied thermal and guanidine hydrochloride (GndHCl)-induced unfolding using fluorescence and CD spectroscopy, as well as dynamic light scattering. Depletion of calcium from specific ion-binding sites in the protein structures reduces the melting temperature tremendously for both alpha-amylases. The reduction is nearly the same for both enzymes, namely, in the order of 50 degrees C. Thus, the difference in thermostability between BLA and BAA (DeltaT(m) approximately 15 degrees C) is related to intrinsic properties of the respective protein structures themselves and is not related to the strength of ion binding. The thermal unfolding of both proteins is characterized by a full disappearance of secondary structure elements and by a concurrent expansion of the 3D structure. GndHCl-induced unfolding also yields a fully vanishing secondary structure but with more expanded 3D structures. Both alpha-amylases remain much more compact upon thermal unfolding as compared to the fully unfolded state induced by chemical denaturants. Such rather compact thermal unfolded structures lower the conformational entropy change during the unfolding transition, which principally can contribute to an increased thermal stability. Structural flexibilities of both enzymes, as measured with tryptophan fluorescence quenching, are almost identical for both enzymes in the native states, as well as in the unfolded states. Furthermore, we do not observe any difference in the temperature dependence of the structural flexibilities between BLA and BAA. These results indicate that conformational dynamics on the time scale of our studies seem not to be related to thermal stability or to thermal adaptation.     

A miniaturized cell-based fluorescence resonance energy transfer assay for insulin-receptor activation

This report describes the development, optimization, and implementation of a miniaturized cell-based assay for the identification of small-molecule insulin mimetics and potentiators. Cell-based assays are attractive formats for compound screening because they present the molecular targets in their cellular environment. A fluorescence resonance energy transfer (FRET) cell-based assay that measures the insulin-dependent colocalization of Akt2 fused with either cyan fluorescent protein or yellow fluorescent protein to the cellular membrane was developed. This ratiometric FRET assay was miniaturized into a robust, yet sensitive 3456-well nanoplate assay with Z' factors of approximately 0.6 despite a very small assay window (less than twofold full activation with insulin). The FRET assay was used for primary screening of a large compound collection for insulin-receptor agonists and potentiators. To prioritize compounds for further development, primary hits were tested in two additional assays, a biochemical time-resolved fluorescence resonance energy transfer assay to measure insulin-receptor phosphorylation and a translocation-based imaging assay. Results from the three assays were combined to yield 11 compounds as potential leads for the development of insulin mimetics or potentiators.     

Spectral and physical characterization of the inverted terminal repeat DNA structure from adenoassociated virus 2

An oligodeoxynucleotide (ODN) that includes elements found in secondary structures at the 5'- and 3'- ends of adenoassociated virus 2 virion DNA was synthesized by ligation of three overlapping ODNs. The most stable secondary structure was calculated to be branched, with a 61 bp duplex stem, terminating in a three-way junction with 9 bp arms. The electrophoretic mobility of the ODN is slower than expected for normal duplex DNA of the same size, suggesting a bent or branched conformation. CD spectra indicate that the ITR structure is largely B form DNA, although there is a slight blue shift compared to the spectra of the isolated stem and loop elements. Thermal melting experiments indicate that the hairpin is significantly more stable than the isolated stem and loop elements. Singular value decomposition of UV spectra obtained as a function of temperature indicates that four species contribute to changes in the spectra upon denaturation, indicating that the melting is not a simple two-state process. Characterization of the branched ODN by differential scanning calorimetry permits estimation of the enthalpy of melting by a model-free analysis, yielding DeltaHcal= 614 kcal mol-1. This value agrees with the enthalpy computed for the most stable secondary structure.     

Oligonucleotide properties determination and primer designing: a critical examination of predictions

MOTIVATION: Precise prediction of melting temperature (T(m)), secondary structures and design of oligonucleotides determine the efficiency and success of experimentation in molecular biology. Availability of a plethora of software and the users unawareness about their limitations compromises the accuracy and reliability of the predictions. RESULTS: Comparative analysis of 56 modules was done for T(m) prediction using a large set of oligonucleotide sequences spanning the whole range of GC-content and length. Allawi module of the calculator 'MELTING', Nearest Neighbor (NN) of oligo calculator (McLab), NN of T(m) Calculation for Oligos (Biomath Calculator, Promega) and HYTHER provided the most precise T(m) predictions. A model has also been proposed to calculate the optimum annealing temperature integrating the already reported formulations. Secondary structure predictions of oligonucleotides reveal a large number of structures in contrast to the experimental observations. Of the 11 primer designing tools evaluated, Primer 3 and WebPrimer performed the best for the AT-rich templates, Exon Primer for AT = GC templates, and Primer Design Assistant, Primer3 and Primer Quest for GC-rich templates. This study provides optimal choice for application to the user, increasing the success of a variety of experimentations, especially those that have high-throughput and complex assay designs. CONTACT: db@igib.res.in SUPPLEMENTARY INFORMATION: The details of the oligonucleotides and of the different modules of T(m) prediction considered for the study are provided as Supplementary Information, available at Bioinformatics online.     

Identifying molecular dynamics in single-molecule FRET experiments with burst variance analysis

Histograms of single-molecule Förster resonance energy transfer (FRET) efficiency are often used to study the structures of biomolecules and relate these structures to function. Methods like probability distribution analysis analyze FRET histograms to detect heterogeneities in molecular structure, but they cannot determine whether this heterogeneity arises from dynamic processes or from the coexistence of several static structures. To this end, we introduce burst variance analysis (BVA), a method that detects dynamics by comparing the standard deviation of FRET from individual molecules over time to that expected from theory. Both simulations and experiments on DNA hairpins show that BVA can distinguish between static and dynamic sources of heterogeneity in single-molecule FRET histograms and can test models of dynamics against the observed standard deviation information. Using BVA, we analyzed the fingers-closing transition in the Klenow fragment of Escherichia coli DNA polymerase I and identified substantial dynamics in polymerase complexes formed prior to nucleotide incorporation; these dynamics may be important for the fidelity of DNA synthesis. We expect BVA to be broadly applicable to single-molecule FRET studies of molecular structure and to complement approaches such as probability distribution analysis and fluorescence correlation spectroscopy in studying molecular dynamics.     

A novel FRET pair for detection of parallel DNA triplexes by the LightCycler

Background  

Melting temperature of DNA structures can be determined on the LightCycler using quenching of FAM. This method is very suitable for pH independent melting point (Tm) determination performed at basic or neutral pH, as a high throughput alternative to UV absorbance measurements. At acidic pH quenching of FAM is not very suitable, since the fluorescence of FAM is strongly pH dependent and drops with acidic pH.     

Influence of secondary structure on kinetics and reaction mechanism of DNA hybridization

Hybridization of nucleic acids with secondary structure is involved in many biological processes and technological applications. To gain more insight into its mechanism, we have investigated the kinetics of DNA hybridization/denaturation via fluorescence resonance energy transfer (FRET) on perfectly matched and single-base-mismatched DNA strands. DNA hybridization shows non-Arrhenius behavior. At high temperature, the apparent activation energies of DNA hybridization are negative and independent of secondary structure. In contrast, when temperature decreases, the apparent activation energies of DNA hybridization change to positive and become structure dependent. The large unfavorable enthalpy of secondary structure melting is compensated for by concomitant duplex formation. Based on our results, we propose a reaction mechanism about how the melting of secondary structure influences the hybridization process. A significant point in the mechanism is that the rate-limiting step switches along with temperature variation in the hybridization process of structured DNA, because the free energy profile of hybridization in structured DNA varies with the variation in temperature.     

Analysis of thermal melting curves

T(m) is defined as Temperature of melting or, more accurately, as temperature of midtransition. This term is often used for nucleic acids (DNA and RNA, oligonucleotides and polynucleotides). A thermal denaturation experiment determines the stability of the secondary structure of a DNA or RNA and aids in the choice of the sequences for antisense oligomers or PCR primers. Beyond a simple numerical value (the T(m)), a thermal denaturation experiment, in which the folded fraction of a structure is plotted vs. temperature, yields important thermodynamic information. We present the classic problems encountered during these experiments and try to demonstrate that a number of useful pieces of information can be extracted from these experimental curves.     

Observed versus predicted structure of fluorescent self-quenching reporter molecules (SQRM): caveats with respect to the use of "stem-loop" oligonucleotides as probes for mRNA folding

We developed self-quenching reporter molecules (SQRMs), oligodeoxynucleotides with fluorophore and quencher moieties at the 5' and 3' ends respectively, to probe mRNAs for single-stranded, hybridization accessible sequences. SQRMs and their homologous antecedents, Molecular Beacons (MB), are designed with the assumption that they adopt a stem-loop structure thought critical for regulating their reporter function. Recently, we observed that stem-loop structures are not required for SQRM function, and on this basis proposed that these reporter molecules be classified according to whether they were stemmed (Type I) or not (Type II). This finding further stimulated us to investigate whether Type I SQRMs, and by extension MBs, actually adopt a stem-loop configuration under physiologic conditions. Accordingly, we synthesized Type I and Type II SQRMs and studied the thermodynamic characteristics of each by fluorescence melting analysis. The results of these studies suggested that the majority of stem-loop Type I SQRMs are unstructured at 37 degrees C, while some of the stemless Type II SQRMs are, surprisingly, structured. These results were not predicted by the mfold computer program. Type I and II SQRMs were then employed to "map" the mRNA secondary structure of a gene encoding a tyrosine kinase receptor, c-kit. Neither experimentally determined melting temperatures nor mfold-"predicted" thermodynamic parameters were useful in predicting the fluorescence signal-to-noise ratios obtained for SQRMs incubated with c-kit mRNA. We conclude that stem-loop reporter molecules are in fact unlikely to adopt their presumed structures at 37 degrees C, and this design consideration may be dispensed when their use is contemplated under physiologic conditions.     

SEPON, a Selection and Evaluation Pipeline for OligoNucleotides based on ESTs with a non-target Tm algorithm for reducing cross-hybridization in microarray gene expression experiments

SEPON, Selection and Evaluation Pipeline for OligoNucleotide generates n-mer oligonucleotide sequences from expressed sequence tags of non-annotated genomes for microarray gene-expression profiling. A non-target melting temperature (T(m)) algorithm will reduce cross-hybridization by estimating T(m) of oligonucleotide hybridization to non-specific targets (non-target T(m)) and discard oligonucleotides with non-target T(m) estimate above user-defined threshold. SEPON allows user-defined filtering, predicts exon location, assigns penalty based on 3' distance, GC content, secondary structure T(m) and non-target T(m) and ranks oligonucleotides for optimal selection.     

Directed evolution of a highly active Yersinia mollaretii phytase

Phytase improves as a feed supplement the nutritional quality of phytate-rich diets (e.g., cereal grains, legumes, and oilseeds) by hydrolyzing indigestible phytate (myo-inositol 1,2,3,4,5,6-hexakis dihydrogen phosphate) and increasing abdominal absorption of inorganic phosphates, minerals, and trace elements. Directed phytase evolution was reported for improving industrial relevant properties such as thermostability (pelleting process) or activity. In this study, we report the cloning, characterization, and directed evolution of the Yersinia mollaretii phytase (Ymphytase). Ymphytase has a tetrameric structure with positive cooperativity (Hill coefficient was 2.3) and a specific activity of 1,073?U/mg which is ～10 times higher than widely used fungal phytases. High-throughput prescreening methods using filter papers or 384-well microtiter plates were developed. Precise subsequent screening for thermostable and active phytase variants was performed by combining absorbance and fluorescence-based detection system in 96-well microtiter plates. Directed evolution yielded after mutant library generation (SeSaM method) and two-step screening (in total ～8,400 clones) a phytase variant with ～20% improved thermostability (58°C for 20?min; residual activity wild type ～34%; variant ～53%) and increased melting temperature (1.5°C) with a slight loss of specific activity (993?U/mg).     

Fluorescence competition and optical melting measurements of RNA three-way multibranch loops provide a revised model for thermodynamic parameters

Three-way multibranch loops (junctions) are common in RNA secondary structures. Computer algorithms such as RNAstructure and MFOLD do not consider the identity of unpaired nucleotides in multibranch loops when predicting secondary structure. There is limited experimental data, however, to parametrize this aspect of these algorithms. In this study, UV optical melting and a fluorescence competition assay are used to measure stabilities of multibranch loops containing up to five unpaired adenosines or uridines or a loop E motif. These results provide a test of our understanding of the factors affecting multibranch loop stability and provide revised parameters for predicting stability. The results should help to improve predictions of RNA secondary structure.     

A time-resolved fluorescence resonance energy transfer assay suitable for high-throughput screening for inhibitors of immunoglobulin E–receptor interactions

The interaction of immunoglobulin E (IgE) antibodies with the high-affinity receptor, FcεRI, plays a central role in initiating most allergic reactions. The IgE–receptor interaction has been targeted for treatment of allergic diseases, and many high-affinity macromolecular inhibitors have been identified. Small molecule inhibitors would offer significant advantages over current anti-IgE treatment, but no candidate compounds have been identified and fully validated. Here, we report the development of a time-resolved fluorescence resonance energy transfer (TR–FRET) assay for monitoring the IgE–receptor interaction. The TR–FRET assay measures an increase in fluorescence intensity as a donor lanthanide fluorophore is recruited into complexes of site-specific Alexa Fluor 488-labeled IgE-Fc and His-tagged FcεRIα proteins. The assay can readily monitor classic competitive inhibitors that bind either IgE-Fc or FcεRIα in equilibrium competition binding experiments. Furthermore, the TR–FRET assay can also be used to follow the kinetics of IgE-Fc–FcεRIα dissociation and identify inhibitory ligands that accelerate the dissociation of preformed complexes, as demonstrated for an engineered DARPin (designed ankyrin repeat protein) inhibitor. The TR–FRET assay is suitable for high-throughput screening (HTS), as shown by performing a pilot screen of the National Institutes of Health (NIH) Clinical Collection Library in a 384-well plate format.     

RNA multi-structure landscapes

Statistical properties of RNA folding landscapes obtained by the partition function algorithm (McCaskill 1990) are investigated in detail. The pair correlation of free energies as a function of the Hamming distance is used as a measure for the ruggedness of the landscape. The calculation of the partition function contains information about the entire ensemble of secondary structures as a function of temperature and opens the door to all quantities of thermodynamic interest, in contrast with the conventional minimal free energy approach. A metric distance of structure ensembles is introduced and pair correlations at the level of the structures themselves are computed. Just as with landscapes based on most stable secondary structure prediction, the landscapes defined on the full biophysical GCAU alphabet are much smoother than the landscapes restricted to pure GC sequences and the correlation lengths are almost constant fractions of the chain lengths. Correlation functions for multi-structure landscapes exhibit an increased correlation length, especially near the melting temperature. However, the main effect on evolution is rather an effective increase in sampling for finite populations where each sequence explores multiple structures. Correspondence to: P. Schuster     

Small molecule structure correctors abolish detrimental effects of apolipoprotein E4 in cultured neurons

Apolipoprotein E4 (apoE4), the major genetic risk factor for late onset Alzheimer disease, assumes a pathological conformation, intramolecular domain interaction. ApoE4 domain interaction mediates the detrimental effects of apoE4, including decreased mitochondrial cytochrome c oxidase subunit 1 levels, reduced mitochondrial motility, and reduced neurite outgrowth in vitro. Mutant apoE4 (apoE4-R61T) lacks domain interaction, behaves like apoE3, and does not cause detrimental effects. To identify small molecules that inhibit domain interaction (i.e. structure correctors) and reverse the apoE4 detrimental effects, we established a high throughput cell-based FRET primary assay that determines apoE4 domain interaction and secondary cell- and function-based assays. Screening a ChemBridge library with the FRET assay identified CB9032258 (a phthalazinone derivative), which inhibits domain interaction in neuronal cells. In secondary functional assays, CB9032258 restored mitochondrial cytochrome c oxidase subunit 1 levels and rescued impairments of mitochondrial motility and neurite outgrowth in apoE4-expressing neuronal cells. These benefits were apoE4-specific and dose-dependent. Modifying CB9032258 yielded well defined structure-activity relationships and more active compounds with enhanced potencies in the FRET assay (IC(50) of 23 and 116 nm, respectively). These compounds efficiently restored functional activities of apoE4-expressing cells in secondary assays. An EPR binding assay showed that the apoE4 structure correction resulted from direct interaction of a phthalazinone. With these data, a six-feature pharmacophore model was constructed for future drug design. Our results serve as a proof of concept that pharmacological intervention with apoE4 structure correctors negates apoE4 detrimental effects in neuronal cells and could be further developed as an Alzheimer disease therapeutic.     

The leader sequence of tobacco mosaic virus RNA devoid of Watson-Crick secondary structure possesses a cooperatively melted, compact conformation

The 5'-untranslated region (5'-UTR) of RNA of tobacco mosaic virus (TMV), called omega sequence, is known as an mRNA leader promoting efficient initiation of translation. The central part of the sequence consists of many CAA repeats, which were reported to be mainly responsible for the enhancing activity of the omega leader. In this work we synthesized the polyribonucleotides containing either the natural omega sequence or the regular (CAA)(n) sequence, and studied them using UV spectrophotometry and analytical ultracentrifugation methods. It was demonstrated that the polyribonucleotides manifest significant hypochromicity, cooperative melting of their structures upon heating, high melting temperature, and the sedimentation coefficients typical of compactly folded RNAs of this size. Thus, the omega leader and its core (CAA)(n) repeat sequence devoid of secondary structure of the Watson-Crick type seem to be well structured elements of mRNA.