The ion-induced folding transitions of the hammerhead ribozyme have been analysed by fluorescence resonance energy transfer. The hammerhead ribozyme may be regarded as a special example of a three-way RNA junction, the global structure of which has been studied by comparing the distances (as energy transfer efficiencies) between the ends of pairs of labelled arms for the three possible end-to-end vectors as a function of magnesium ion concentration. The data support two sequential ion-dependent transitions, which can be interpreted in the light of the crystal structures of the hammerhead ribozyme. The first transition corresponds to the formation of a coaxial stacking between helices II and III; the data can be fully explained by a model in which the transition is induced by a single magnesium ion which binds with an apparent association constant of 8000-10 000 M -1 . The second structural transition corresponds to the formation of the catalytic domain of the ribozyme, induced by a single magnesium ion with an apparent association constant of~1100 M -1 . The hammerhead ribozyme provides a well-defined example of ion-dependent folding in RNA.
Here we investigate the global conformation of the hammerhead ribozyme. Electrophoretic studies demonstrate that the structure is folded in response to the concentration and type of ions present. Folding based on colinear alignment of arms II and III is suggested, with a variable angle subtended by the remaining helix I. In the probable active conformation, a small angle is subtended between helices I and II. Using uranyl photocleavage, an ion binding site has been detected in the long single-stranded region. The folded conformation could generate a preactivation of the scissile bond to permit in-line attack of the 2'-hydroxyl group, with a bound metal ion playing an integral role in the chemistry.
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.
Detectable splicing by the Saccharomyces cerevisiae mitochondrial bI3 group I intron RNA in vitro is shown to require both an intron-encoded protein, the bI3 maturase, and the nuclearencoded protein, Mrs1. Both proteins bind independently to the bI3 RNA. The bI3 maturase binds as a monomer, whereas Mrs1 is a dimer in solution that assembles as two dimers, cooperatively, on the RNA. The active six-subunit complex has a molecular mass of 420 kDa, splices with a k cat of 0.3 min ؊1 , and binds the guanosine nucleophile with an affinity comparable to other group I introns. The functional bI3 maturase domain is translated from within the RNA that encodes the intron, has evolved a high-affinity RNAbinding activity, and is a member of the LAGLIDADG family of DNA endonucleases, but appears to have lost DNA cleavage activity. Mrs1 is a divergent member of the RNase H fold superfamily of dimeric DNA junction-resolving enzymes that also appears to have lost its nuclease activity and now functions as a tetramer in RNA binding. Thus, the bI3 ribonucleoprotein is the product of a process in which a once-catalytically active RNA now obligatorily requires two facilitating protein cofactors, both of which are compromised in their original functions. M any small ribozymes, both those that occur naturally (1) and those that are products of in vitro selection experiments (2), display an impressive array of catalytic activities. Although these simple structures are capable of performing catalysis, most cellular ribozymes have undergone a process of elaboration in which potentially simple RNA active sites are bolstered by additional RNA structural domains (3, 4) or protein cofactors (5-9).One example of this process is the group I introns. The group I intron RNA core consists of two extended and roughly coaxially stacked helices that form a catalytic cleft, which binds, in turn, the 5Ј and 3Ј splice site helices and the guanosine cofactor (guanosine 5Ј-monophosphate, pG) (4, 5, 10). Although the catalytic core is relatively compact and can independently form a functional active site (11), most group I introns have acquired additional peripheral structures that function to stabilize the RNA core (4, 12, 13). Moreover, whereas a large number of group I introns have been identified by sequence and structural analysis (4, 14), both anecdotal and experimental evidence suggests that many have lost their self-splicing activity (15). It appears that group I intron RNAs commonly recruit protein cofactors and now function as obligatory ribonucleoproteins (8, 16).The Saccharomyces cerevisiae mitochondrial cytochrome b bI3 group I intron represents an especially intriguing case of elaboration by accretion of peripheral RNA domains and protein cofactors. First, the bI3 RNA potentially spans two group I intron subgroups, IA2 and IB4, characterized by RNA sequence insertions between helices P7 and P3 and adjacent to P9 and by an extension of the P5 helix, respectively (4) (Fig. 1A, boxed structures). The bI3 intron also contains two tertiary inter...
A group II intron encoding a protein belonging to the LAGLIDADG family of homing endonucleases was identified in the mitochondrial rns gene of the filamentous fungus Leptographium truncatum, and the catalytic activities of both the intron and its encoded protein were characterized. A model of the RNA secondary structure indicates that the intron is a member of the IIB1 subclass and the open reading frame is inserted in ribozyme domain III. In vitro assays carried out with two versions of the intron, one in which the open reading frame was removed and the other in which it was present, demonstrate that both versions of the intron readily self-splice at 37°C and at a concentration of MgCl 2 as low as 6 mM. The open reading frame encodes a functional LAGLIDADG homing endonuclease that cleaves 2 (top strand) and 6 (bottom strand) nucleotides (nt) upstream of the intron insertion site, generating 4 nt 39 OH overhangs. In vitro splicing assays carried out in the absence and presence of the intron-encoded protein indicate that the protein does not enhance intron splicing, and RNA-binding assays show that the protein does not appear to bind to the intron RNA precursor transcript. These findings raise intriguing questions concerning the functional and evolutionary relationships of the two components of this unique composite element.
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