Thermodynamics of ion-induced RNA folding in the hammerhead ribozyme: an isothermal titration calorimetric study

The hammerhead ribozyme undergoes a well-defined two-stage conformational folding process, induced by the binding of magnesium ions. In this study, we have used isothermal titration calorimetry to analyze the thermodynamics of magnesium binding and magnesium ion-induced folding of the ribozyme. Binding to the natural sequence ribozyme is strongly exothermic and can be analyzed in terms of sequential interaction at two sites with association constants K(A) = 480 and 2840 M(-1). Sequence variants of the hammerhead RNA give very different isothermal titration curves. An A14G variant that cannot undergo ion-induced folding exhibits endothermic binding. By contrast, a deoxyribose G5 variant that can undergo only the first of the two folding transitions gives a complex titration curve. However, despite these differences the ITC data for all three species can be analyzed in terms of the sequential binding of magnesium ions at two sites. While the binding affinities are all in the region of 10(3) M(-1), corresponding to free energies of Delta G degrees = -3.5 to -4 kcal mol(-1), the enthalpic and entropic contributions show much greater variation. The ITC experiments are in good agreement with earlier conformational studies of the folding of the ion-induced folding of the hammerhead ribozyme.     

RNA folding and catalysis

Catalysis in RNA is intimately connected to the folding. The small nucleolytic ribozymes function by a nucleophilic attack of the 2-oxygen on the 3-phosphate, in an S_N2 mechanism. This requires an alignment of the 2-O, 3-P and 5-O, that does not occur in normal A-form RNA. It is therefore likely that structural distortion plays a major role in the enhancement of the reaction rate, facilitating the trajectory into the in-line transition state. Given the polyelectrolyte nature of nucleic acids, metal ions are critical to folding processes in RNA. We have shown that two small nucleolytic ribozymes, the hammerhead and hairpin ribozymes, undergo metal ion-induced folding processes. The hammerhead ribozyme folds in two stages, each of which is induced by the binding of a single structural ion. The first corresponds to the formation of the ribozyme scaffold, while the second is the formation of the catalytic core of the ribozyme. By contrast, the hairpin ribozyme undergoes a single folding event induced by the binding of at least two metal ions, and involves the close interaction between two internal loops to form the active ribozyme.This revised version was published online in October 2005 with corrections to the Cover Date.     

RNA folding and misfolding of the hammerhead ribozyme

The hammerhead ribozyme undergoes a well-defined two-stage folding process induced by the sequential binding of two magnesium ions. These probably correspond to the formation of domain 2 (0-500 microM magnesium ions) and domain 1 (1-20 mM magnesium ions), respectively. In this study we have used fluorescence resonance energy transfer (FRET) to analyze the ion-induced folding of a number of variants of the hammerhead ribozyme. We find that both A14G and G8U mutations are highly destabilizing, such that these species are essentially unfolded under all conditions. Thus they appear to be blocked in the first stage of the folding process, and using uranyl-induced photocleavage we show that the core is completely accessible to this probe under these conditions. Changes at G5 do not affect the first transition but appear to provide a blockage at the second stage of folding; this is true of changes in the sugar (removal of the 2'-hydroxyl group) and base (G5C mutation, previously studied by comparative gel electrophoresis). Arrest of folding at this intermediate stage leads to a pattern of uranyl-induced photocleavage that is changed from the wild-type, but suggests a structure less open than the A14G mutant. Specific photocleavage at G5 is found only in the wild-type sequence, suggesting that this ion-binding site is formed late in the folding process. In addition to folding that is blocked at selected stages, we have also observed misfolding. Thus the A13G mutation appears to result in the ion-induced formation of a novel tertiary structure.     

Folding of the natural hammerhead ribozyme is enhanced by interaction of auxiliary elements

It has been shown that the activity of the hammerhead ribozyme at microM magnesium ion concentrations is markedly increased by the inclusion of loops in helices I and II. We have studied the effect of such loops on the magnesium ion-induced folding of the ribozyme, using fluorescence resonance energy transfer. We find that with the loops in place, folding into the active conformation occurs in a single step, in the microM range of magnesium ion concentration. Disruption of the loop-loop interaction leads to a reversion to two-step folding, with the second stage requiring mM concentrations of magnesium ion. Sodium ions also promote the folding of the natural form of the ribozyme at high concentrations, but the folding occurs as a two-stage process. The loops clearly act as important auxiliary elements in the function of the ribozyme, permitting folding to occur efficiently under physiological conditions.     

Preferential expression of a plant cystatin at nematode feeding sites confers resistance to Meloidogyne incognita and Globodera pallida

The expression patterns of three promoters preferentially active in the roots of Arabidopsis thaliana have been investigated in transgenic potato plants in response to plant parasitic nematode infection. Promoter regions from the three genes, TUB-1, ARSK1 and RPL16A were linked to the GUS reporter gene and histochemical staining was used to localize expression in potato roots in response to infection with both the potato cyst nematode, Globodera pallida and the root-knot nematode, Meloidogyne incognita. All three promoters directed GUS expression chiefly in root tissue and were strongly up-regulated in the galls induced by feeding M. incognita. Less activity was associated with the syncytial feeding cells of the cyst nematode, although the ARSK1 promoter was highly active in the syncytia of G. pallida infecting soil grown plants. Transgenic potato lines that expressed the cystatin OcIDeltaD86 under the control of the three promoters were evaluated for resistance against Globodera sp. in a field trial and against M. incognita in containment. Resistance to Globodera of 70 +/- 4% was achieved with the best line using the ARSK1 promoter with no associated yield penalty. The highest level of partial resistance achieved against M. incognita was 67 +/- 9% using the TUB-1 promoter. In both cases this was comparable to the level of resistance achieved using the constitutive cauliflower mosaic virus 35S (CaMV35S) promoter. The results establish the potential for limiting transgene expression in crop plants whilst maintaining efficacy of the nematode defence.     

All about DIGE: quantification technology for differential-display 2D-gel proteomics

2D polyacrylamide gel electrophoresis has been the traditional workhorse of proteomics, allowing for the resolution of several thousand proteins in a single gel. Difference gel electrophoresis is an emerging technology that allows for accurate quantification with statistical confidence while controlling for nonbiologic variation, and also increases the dynamic range and sensitivity of traditional 2D polyacrylamide gel electrophoresis. With inclusion of an internal standard formed from equal amounts of every sample in an experiment, difference gel electrophoresis technology also allows for repetitive measurements and multivariable analyses to be quantitatively analyzed in one co-ordinated experiment, yielding statistically-significant changes in protein expression related to many disease states. This technique promises to be an important tool in clinical proteomics and the study of the mechanism of disease, investigating diagnostic biomarkers and pinpointing novel therapeutic targets.     

Population dynamics and gene transfer in genetically modified bacteria in a model microcosm

The horizontal transfer and effects on host fitness of a neutral gene cassette inserted into three different genomic loci of a plant-colonizing pseudomonad was assessed in a model ecosystem. The KX reporter cassette (kanamycin resistance, aph, and catechol 2, 3, dioxygenase, xylE) was introduced on the disarmed transposon mini-Tn5 into: (I) the chromosome of a spontaneous rifampicin resistant mutant Pseudomonas fluorescens SBW25R; (II) the chromosome of SBW25R in the presence of a naturally occurring lysogenic-phage (phage Phi101); and (III) a naturally occurring plasmid pQBR11 (330 kbp, tra+, Hgr) introduced into SBW25R. These bacteria were applied to Stellaria media (chickweed) plants as seed dressings [c. 5 x 104 colony-forming units (cfu)/seed] and the seedlings planted in 16 microcosm chambers containing model plant and animal communities. Gene transfer to pseudomonads in the phyllosphere and rhizosphere was found only in the plasmid treatment (III). Bacteria in the phage treatment (II) initially declined in density and free phage was detected, but populations partly recovered as the plants matured. Surprisingly, bacteria in the chromosome insertion treatment (I) consistently achieved higher population densities than the unmanipulated control and other treatments. Plasmids were acquired from indigenous bacterial populations in the control and chromosome insertion treatments. Plasmid acquisition, plasmid transfer from inocula and selection for plasmid carrying inocula coincided with plant maturation.     

Characterization of the necrotic protein that regulates the Toll-mediated immune response in Drosophila

Necrotic (Nec) is an important component of the proteolytic cascade that activates the Toll-mediated immune response in Drosophila. The Nec protein is a member of the serpin (SERine Protease INhibitor) superfamily and is thought to regulate the cascade by inhibiting the serine protease Persephone. Nec was expressed in Escherichia coli, and the purified protein folded to the active native conformation required for protease inhibitory activity. Biochemical analysis showed that Nec had a broad inhibitory specificity and inhibited elastase, thrombin, and chymotrypsin-like proteases. It did not inhibit trypsin or kallikrein. These data show that Necrotic is likely to inhibit a wide range of proteases in Drosophila and that Nec has the specificity requirements to act as the physiological inhibitor of Persephone in vivo.     

Folding and catalysis by the VS ribozyme

The VS ribozyme is a 154 nt self-cleaving RNA molecule that can be divided into a trans-acting five-helix ribozyme and stem-loop substrate. The structure of the ribozyme is organised by two three-way helical junctions, the structure of which has been determined by a combination of comparative gel electrophoresis and fluorescence resonance energy transfer experiments. From this, the overall global architecture of the ribozyme has been deduced. The substrate is then thought to dock into the cleft formed between helices II and VI, where it makes a close interaction with the loop containing A730. The A730 loop is the probable active site of the ribozyme, and A756 within it is a strong candidate to play a direct role in the transesterification chemistry, possibly by general acid-base catalysis.