Evidence for processivity and two-step binding of the RNA substrate from studies of J1/2 mutants of the Tetrahymena ribozyme.

J1/2 of the Tetrahymena ribozyme, a sequence of three A residues, connects the RNA-binding site to the catalytic core. Addition or deletion of bases from J1/2 improves turnover and substrate specificity in the site-specific endonuclease reaction catalyzed by this ribozyme: G2CCCUCUA5 (S) + G in-equilibrium G2CCCUCU (P) + GA5. These paradoxical enhancements are caused by decreased affinity of the ribozyme for S and P [Young, B., Herschlag, D., & Cech, T.R. (1991) Cell 67, 1007]. An additional property of these mutant ribozymes, decreased fidelity of RNA cleavage, is now analyzed. (Fidelity is the ability to cleave at the correct phosphodiester bond within a particular RNA substrate.) Introduction of deoxy residues to give "chimeric" ribo/deoxyribooligonucleotides changes the positions of incorrect cleavage. Previous work indicated that S is bound to the ribozyme by both base pairing and teritary interactions involving 2'-hydroxyl groups of S. The data herein strongly suggest that the P1 duplex, which consists of S base-paired with the 5' exon binding site of the ribozyme, can dock into tertiary interactions in different registers; different 2'-hydroxyl groups of S plug into tertiary contacts with the ribozyme in the different registers. It is concluded that the mutations decrease fidelity by increasing the probability of docking out of register relative to docking in the normal register, thereby giving cleavage at different positions along S. These data also show that the contribution of J1/2 to the teritiary interactions is indirect, not direct. Thus, a structural role of the nonconserved J1/2 is indicated: this sequence positions S to optimize tertiary binding interactions and to ensure cleavage at the phosphodiester bond corresponding to the 5' splice site. Substitution of sulfur for the nonbridging pro-RP oxygen atom at the normal cleavage site has no effect on (kcat/Km)S but decreases the fraction of cleavage at the normal site in reactions catalyzed by the -3A mutant ribozyme, which has all three A residues of J1/2 removed. Thus, the ribozyme chooses where to cleave S after rate-limiting binding of S, indicating that docking can change after binding and suggesting that the ribozyme could act processively. Indeed, it is shown that the +2A ribozyme cleaves at one position along an RNA substrate and then, before releasing that RNA product, cleaves it again.(ABSTRACT TRUNCATED AT 400 WORDS)     

Catalysis of RNA cleavage by the Tetrahymena thermophila ribozyme. 1. Kinetic description of the reaction of an RNA substrate complementary to the active site

A ribozyme derived from the intervening sequence (IVS) of the Tetrahymena preribosomal RNA catalyzes a site-specific endonuclease reaction: G2CCCUCUA5 + G in equilibrium with G2CCCUCU + GA5 (G = guanosine). This reaction is analogous to the first step in self-splicing of the pre-rRNA, with the product G2CCCUCU analogous to the 5'-exon. The following mechanistic conclusions have been derived from pre-steady-state and steady-state kinetic measurements at 50 degrees C and neutral pH in the presence of 10 mM Mg2+. The value of kcat/Km = 9 x 10(7) M-1 min-1 for the oligonucleotide substrate with saturating G represents rate-limiting binding. This rate constant for binding is of the order expected for formation of a RNA.RNA duplex between oligonucleotides. (Phylogenetic and mutational analyses have shown that this substrate is recognized by base pairing to a complementary sequence within the IVS). The value of kcat = 0.1 min-1 represents rate-limiting dissociation of the 5'-exon analogue, G2CCCUCU. The product GA5 dissociates first from the ribozyme because of this slow off-rate for G2CCCUCU. The similar binding of the product, G2CCCUCU, and the substrate, G2CCCUCUA5, to the 5'-exon binding site of the ribozyme, with Kd = 1-2 nM, shows that the pA5 portion of the substrate makes no net contribution to binding. Both the substrate and product bind approximately 10(4)-fold (6 kcal/mol) stronger than expected from base pairing with the 5'-exon binding site. Thus, tertiary interactions are involved in binding. Binding of G2CCCUCU and binding of G are independent. These and other data suggest that binding of the oligonucleotide substrate, G2CCCUCUA5, and binding of G are essentially random and independent. The rate constant for reaction of the ternary complex is calculated to be kc approximately equal to 350 min-1, a rate constant that is not reflected in the steady-state rate parameters with saturating G. The simplest interpretation is adopted, in which kc represents the rate of the chemical step. A site-specific endonuclease reaction catalyzed by the Tetrahymena ribozyme in the absence of G was observed; the rate of the chemical step with solvent replacing guanosine, kc(-G) = 0.7 min-1, is approximately 500-fold slower than that with saturating guanosine. The value of kcat/Km = 6 x 10(7) M-1 min-1 for this hydrolysis reaction is only slightly smaller than that with saturating guanosine, because the binding of the oligonucleotide substrate is predominantly rate-limiting in both cases.(ABSTRACT TRUNCATED AT 400 WORDS)     

Minimum ribonucleotide requirement for catalysis by the RNA hammerhead domain.

Several mixed DNA/RNA and 2'-O-methylribonucleotide/RNA analogues derived from the "hammerhead" domain of RNA catalysis have been prepared to study the minimum ribonucleotide requirement for catalytic activity. Oligodeoxyribonucleotides containing from seven to as few as four ribonucleotides are active in cleaving a substrate RNA. Predominantly deoxyribonucleotide-containing analogues have kcat values 20-300 and kcat/KM values approximately 100-2000 times lower than those of all-RNA ribozyme. In the case of predominantly 2'-O-methyl analogues, at least five ribonucleotides are needed to assure catalytic activity. In addition, both predominantly deoxyribonucleotide and 2'-O-methyl oligomers are at least 3 orders of magnitude more stable than an all-RNA ribozyme in incubations with RNase A and a yeast extract. These results suggest that the ribophosphate backbone is not a strict requirement for ribozyme-type catalysis. The identification of the four required ribonucleotides in the hammerhead catalytic domain provides valuable information for the rational design of chemical species having ribonuclease activities.     

Sequence-specific endoribonuclease activity of the Tetrahymena ribozyme: enhanced cleavage of certain oligonucleotide substrates that form mismatched ribozyme-substrate complexes

A shortened form of the self-splicing intervening sequence RNA of Tetrahymena acts as a sequence-specific endoribonuclease. Specificity of cleavage is determined by Watson-Crick base pairing between the active site of the RNA enzyme (ribozyme) and its RNA substrate [Zaug, A. J., Been, M. D., & Cech, T. R. (1986) Nature (London) 324, 429-433]. Surprisingly, single-base changes in the substrate RNA 3 nucleotides preceding the cleavage site, giving a mismatched substrate-ribozyme complex, enhance the rate of cleavage. Mismatched substrates show up to a 100-fold increase in kcat and, in some cases, in kcat/Km. A mismatch introduced by changing a nucleotide in the active site of the ribozyme has a similar effect. Addition of 2.5 M urea or 3.8 M formamide or decreasing the divalent metal ion concentration from 10 to 2 mM reverses the substrate specificity, allowing the ribozyme to discriminate against the mismatched substrate. The effect of urea is to decrease kcat and kcat/Km for cleavage of the mismatched substrate; Km is not significantly affected at 0-2.5 M urea. Thus, progressive destabilization of ribozyme-substrate pairing by mismatches or by addition of a denaturant such as urea first increases the rate of cleavage to an optimum value and then decreases the rate.     

Pathway modulation, circular permutation and rapid RNA folding under kinetic control

The thermodynamics and folding kinetics of a circularly permuted construct of the ribozyme from Bacillus subtilis RNase P are analyzed and compared with the folding properties of the wild-type ribozyme using optical spectroscopy and catalytic activity. The folding of the wild-type ribozyme is slow due to the rearrangement of kinetically trapped species containing misfolded structures. To test whether any misfolded structure arises from interactions between the two independently folding domains of the RNase P RNA, a circular permuted form was created where one of the two phosphodiester bonds connecting these domains is broken. This construct folds approximately 15-fold faster (t1/2 approximately nine seconds) than the wild-type ribozyme at 37 degreesC. While the complete folding of both domains is kinetically indistinguishable in the wild-type ribozyme, one domain folds much faster than the other domain in the circularly permuted construct. Hence, the major kinetic trap in the folding of the wild-type RNase P RNA involves interdomain interactions. This kinetic trap is avoidable at 37 degreesC in the circularly permuted RNA. However, at temperatures below 30 degreesC or when refolding begins from an equilibrium intermediate stabilized by submillimolar concentrations of Mg2+, a subpopulation containing an interdomain misfold still forms. These results indicate that the folding pathway of this large RNA is highly malleable and can be under kinetic control.     

A ribozyme with DNA in the hybridising arms displays enhanced cleavage ability.

Hammerhead ribozymes cleave RNA substrates containing the UX sequence, where X = U, C or A, embedded within sequences which are complementary to the hybridising 'arms' of the ribozyme. In this study we have replaced the RNA in the hybridising arms of the ribozyme with DNA, and the resulting ribozyme is many times more active than its precursor. In turnover-kinetics experiments with a 13-mer RNA substrate, the kcat/Km ratios are 10 and 150 microM-1min-1 for the RNA- and DNA-armed ribozymes, respectively. The effect is due mainly to differences in kcat. In independent experiments where the cleavage step is rate-limiting, the DNA-armed ribozyme cleaves the substrate with a rate constant more than 3 times greater than the all-RNA ribozyme. DNA substrates containing a ribocytidine at the cleavage site have been shown to be cleaved less efficiently than their all-RNA analogues; again however, the DNA-armed ribozyme is more effective than the all-RNA ribozyme against such DNA substrates. These results demonstrate that there are no 2'-hydroxyl groups in the arms of the ribozyme that are required for cleavage; and that the structure of the complex formed by the DNA-armed ribozyme with its substrate is more favourable for cleavage than that formed by the all-RNA ribozyme and its substrate.     

Efficient trans-cleavage of a stem-loop RNA substrate by a ribozyme derived from neurospora VS RNA.

We have constructed a ribozyme containing 144 nucleotides of Neurospora VS RNA that can catalyze the cleavage of a separate RNA in a true enzymatic manner (Km approximately 0.13 microM, kcat approximately 0.7/min). Comparison of the rates of cis- and trans-cleavage, as well as the lack of effect of pH on the rate of cleavage, suggest that a rate-limiting step, possibly a conformational change, occurs prior to cleavage. The minimum contiguous substrate sequence required for cleavage consists of one nucleotide upstream and 19 nucleotides downstream of the cleavage site. Unlike most other ribozymes which interact with long single-stranded regions of their substrates, the minimal substrate for the VS ribozyme consists mostly of a stable stem-loop, which would appear to preclude its recognition simply via extensive Watson-Crick base pairing.     

特异切割12-脂加氧酶mRNA的核酶体外活性及动力学研究

根据锤头状核酶（Ｒｉｂｏｚｙｍｅ）的作用模式,设计、合成并克隆了特异性切割１２－脂加氧酶（１２－ＬＯ）ｍＮＲＡ的核酶基因。以合成的２５个核苷酸长的１２－脂加氧酶ＲＮＡ片段为底物与转录的核酶ＲＮＡ一起保温检测其体 割活性。实验结果表明,在３７℃保温时,核酶在体外对１２－脂加氧酶具有较高的特异切割活性,其Ｋｍ值为１３００ｎｍｏｌ／Ｌ,其ｋｃａｔ值为０．０８３／ｍｉｎ,在５０℃保温时,核酶具有很高的切割     

The hairpin ribozyme

The hairpin ribozyme is a member of a family of small RNA endonucleases, which includes hammer-head, human hepatitis delta virus, Neurospora VS, and the lead-dependent catalytic RNAs. All these catalytic RNAs reversibly cleave the phosphodiester bond of substrate RNA to generate 5'-hydroxyl and 2',3'-cyclic phosphate termini. Whereas the reaction products from family members are similar, large structural and mechanistic differences exist. Structurally the hairpin ribozyme has two principal domains that interact to facilitate catalysis. The hairpin ribozyme uses a catalytic mechanism that does not require metals for cleavage or ligation of substrate RNA. In this regard it is presently unique among RNA catalysts. Targeting rules for cleavage of substrate have been determined and required bases for catalysis have been identified. The hairpin ribozyme has been developed and used for gene therapy and was the first ribozyme to be approved for human clinical trials.     

A catalytic 13-mer ribozyme.

A 13-mer oligoribonucleotide can act as a ribozyme for the specific self-cleavage of a 41-mer oligoribonucleotide substrate in the presence of Mg2+. The two sequences involved correspond to the self-cleavage hammerhead structure of the virusoid of lucerne transient streak virus. The Michaelis-menten kinetic parameters for the reaction were; Km 1.3 microM, Vmax 0.012 microM min-1, kcat 0.5 min-1. The 13-mer RNA is the smallest ribozyme so far reported. A DNA analogue of the 13-mer can not substitute for the RNA in the reaction.     

Relationship between 2'-hydroxyls and magnesium binding in the hammerhead RNA domain: a model for ribozyme catalysis.

The use of deoxyribonucleotide substitution in RNA (mixed RNA/DNA polymers) permits an evaluation of the role of 2'-hydroxyl groups in ribozyme catalysis. Specific deoxyribonucleotide substitution at G9 and A13 of the ribozyme decreases the catalytic activity (kcat) of the ribozyme by factors of 14 and 20, respectively. The reduction of the reaction rate concomitant with the absence of these 2'-OHs or the 2'-OH of the substrate U7 position can be partially compensated by increasing the Mg2+ concentration above 10 mM. The KMg of the all-RNA ribozyme is 5.3 mM, and the lack of either of the three influential 2'-OHs increases this value by a factor of approximately 3. These and other reaction constants for the ribozyme and the deoxy-substituted analogues have been determined by assuming a three-step mechanism. The data presented here provide the basis for the formulation of a molecular model of ribozyme activity.     

Kinetic framework for ligation by an efficient RNA ligase ribozyme

The class I RNA ligase ribozyme, isolated previously from random sequences, performs an efficient RNA ligation reaction. It ligates two substrate RNAs, promoting the attack of the 3'-hydroxyl of one substrate upon the 5'-triphosphate of the other substrate with release of pyrophosphate. This ligation reaction has similarities to the reaction catalyzed by RNA polymerases. Using data from steady-state kinetic measurements and pulse-chase/pH-jump experiments, we have constructed minimal kinetic frameworks for two versions of the class I ligase, named 207t and 210t. For both ligases, as well as for the self-ligating parent ribozyme, the rate constant for the chemical step (k(c)) is log-linear with pH in the range 5.7-8.0. At physiological pH, the k(c) is 100 min(-1), a value similar to those reported for the fastest naturally occurring ribozymes. At higher pH, product release is limiting for both 207t and 210t. The 210t ribozyme, with its faster product release, attains multiple-turnover rates (k(cat) = 360 min(-1), pH 9.0) exceeding those of 207t and other reported ribozyme reactions. The kinetic framework for the 210t ribozyme describes the limits of this catalysis and suggests how key steps can be targeted for improvement using design or combinatorial approaches.     

Studies on Escherichia coli RNase P RNA with Zn2+ as the catalytic cofactor

We demonstrate, for the first time, catalysis by Escherichia coli ribonuclease P (RNase P) RNA with Zn2+ as the sole divalent metal ion cofactor in the presence of ammonium, but not sodium or potassium salts. Hill analysis suggests a role for two or more Zn2+ ions in catalysis. Whereas Zn2+ destabilizes substrate ground state binding to an extent that precludes reliable Kd determination, Co(NH3)6(3+) and Sr2+ in particular, both unable to support catalysis by themselves, promote high-substrate affinity. Zn2+ and Co(NH3)6(3+) substantially reduce the fraction of precursor tRNA molecules capable of binding to RNase P RNA. Stimulating and inhibitory effects of Sr2+ on the ribozyme reaction with Zn2+ as cofactor could be rationalized by a model involving two Sr2+ ions (or two classes of Sr2+ ions). Both ions improve substrate affinity in a cooperative manner, but one of the two inhibits substrate conversion in a non-competitive mode with respect to the substrate and the Zn2+. A single 2'-fluoro modification at nt -1 of the substrate substantially weakened the inhibitory effect of Sr2+. Our results demonstrate that the studies on RNase P RNA with metal cofactors other than Mg2+ entail complex effects on structural equilibria of ribozyme and substrate RNAs as well as E*S formation apart from the catalytic performance.     

A tethered catalysis, two-hybrid system to identify protein-protein interactions requiring post-translational modifications

We have modified the yeast two-hybrid system to enable the detection of protein-protein interactions that require a specific post-translational modification, using the acetylation of histones and the phosphorylation of the carboxyl terminal domain (CTD) of RNA polymerase II as test modifications. In this tethered catalysis assay, constitutive modification of the protein to be screened for interactions is achieved by fusing it to its cognate modifying enzyme, with the physical linkage resulting in efficient catalysis. This catalysis maintains substrate modification even in the presence of antagonizing enzyme activities. A catalytically inactive mutant of the enzyme is fused to the substrate as a control such that the modification does not occur; this construct enables the rapid identification of modification-independent interactions. We identified proteins with links to chromatin functions that interact with acetylated histones, and proteins that participate in RNA polymerase II functions and in CTD phosphorylation regulation that interact preferentially with the phosphorylated CTD.