Involvement of "hinge" nucleotides of Xenopus laevis 5 S rRNA in the RNA structural organization and in the binding of transcription factor TFIIIA

Binding site for Xenopus ribosomal protein L5 and accompanying structural changes in 5S rRNA

The structure of the eukaryotic L5-5S rRNA complex was investigated in protection and interference experiments and is compared with the corresponding structure (L18-5S rRNA) in the Haloarcula marismortui 50S subunit. In close correspondence with the archaeal structure, the contact sites for the eukaryotic ribosomal protein are located primarily in helix III and loop C and secondarily in loop A and helix V. While the former is unique to L5, the latter is also a critical contact site for transcription factor IIIA (TFIIIA), accounting for the mutually exclusive binding of these two proteins to 5S RNA. The binding of L5 causes structural changes in loops B and C that expose nucleotides that contact the Xenopus L11 ortholog in H. marismortui. This induced change in the structure of the RNA reveals the origins of the cooperative binding to 5S rRNA that has been observed for the bacterial counterparts of these proteins. The native structure of helix IV and loop D antagonizes binding of L5, indicating that this region of the RNA is dynamic and also influenced by the protein. Examination of the crystal structures of Thermus thermophilus ribosomes in the pre- and post-translocation states identified changes in loop D and in the surrounding region of 23S rRNA that support the proposal that 5S rRNA acts to transmit information between different functional domains of the large subunit.

An RNA aptamer with high affinity and high specificity for the 5S RNA binding zinc finger proteins TFIIIA and p43

The Xenopus zinc finger proteins TFIIIA and p43 bind to 5S RNA in immature oocytes to form 7S and 42S ribonucleoprotein storage particles. To probe the similarities and differences in the RNA binding domains of these two proteins, a library of random RNA molecules was enriched using TFIIIA as the bait protein. One of the abundant aptamers isolated, RNA22, bound to both TFIIIA and p43 derived zinc finger peptides with high affinity and specificity even though the predicted secondary structure of the RNA was unrelated to that of 5S RNA. The interactions of TFIIIA and p43 peptides with RNA22 were compared to their interactions with 5S RNA by characterizing the effects of assay conditions, mutations in RNA22, and mutations in the zinc finger proteins. The similarities and differences in the mechanisms by which these two zinc finger proteins interact with 5S RNA compared to RNA22 suggest they share a common platform for RNA binding with enough flexibility to form specific interactions with both RNAs.

Specific features of 5S rRNA structure - its interactions with macromolecules and possible functions

Small non-coding RNAs are today a topic of great interest for molecular biologists because they can be regarded as relicts of a hypothetical "RNA world" which, apparently, preceded the modern stage of organic evolution on Earth. The small molecule of 5S rRNA (approximately 120 nucleotides) is a component of large ribosomal subunits of all living beings (5S rRNAs are not found only in mitoribosomes of fungi and metazoans). This molecule interacts with various protein factors and 23S (28S) rRNA. This review contains the accumulated data to date concerning 5S rRNA structure, interactions with other biological macromolecules, intracellular traffic, and functions in the cell.

Two distinct structural elements of 5S rRNA are needed for its import into human mitochondria

RNA import into mitochondria is a widespread phenomenon. Studied in details for yeast, protists, and plants, it still awaits thorough investigation for human cells, in which the nuclear DNA-encoded 5S rRNA is imported. Only the general requirements for this pathway have been described, whereas specific protein factors needed for 5S rRNA delivery into mitochondria and its structural determinants of import remain unknown. In this study, a systematic analysis of the possible role of human 5S rRNA structural elements in import was performed. Our experiments in vitro and in vivo show that two distinct regions of the human 5S rRNA molecule are needed for its mitochondrial targeting. One of them is located in the proximal part of the helix I and contains a conserved uncompensated G:U pair. The second and most important one is associated with the loop E-helix IV region with several noncanonical structural features. Destruction or even destabilization of these sites leads to a significant decrease of the 5S rRNA import efficiency. On the contrary, the beta-domain of the 5S rRNA was proven to be dispensable for import, and thus it can be deleted or substituted without affecting the 5S rRNA importability. This finding was used to demonstrate that the 5S rRNA can function as a vector for delivering heterologous RNA sequences into human mitochondria. 5S rRNA-based vectors containing a substitution of a part of the beta-domain by a foreign RNA sequence were shown to be much more efficiently imported in vivo than the wild-type 5S rRNA.

Contribution of Individual Amino Acids to the Nucleic Acid Binding Activities of the Xenopus Zinc Finger Proteins TFIIIIA and p43

Xenopus transcription factor IIIIA (TFIIIA) binds to both 5S RNA and the 5S RNA gene in immature oocytes, an interaction mediated by nine zinc fingers. To determine the role of the central zinc fingers of the protein in these nucleic acid binding activities, a series of substitution mutants of TFIIIA were constructed and expressed as recombinant proteins in Escherichia coli. The mutant proteins were purified to homogeneity and analyzed for DNA and RNA binding activities using a nitrocellulose filter binding assay. Finger 5, but not finger 4, 6, or 7, is involved in sequence-specific binding to the 5S RNA gene. A TWT amino acid motif in finger 6 makes a significant contribution to the binding of TFIIIA to 5S RNA, while mutations in fingers 4, 5, and 7 have little or no effect on RNA binding by TFIIIA. In striking contrast, a TWT motif in finger 6 of p43, another Xenopus zinc finger protein that binds to 5S RNA, is not necessary for 5S RNA binding by this protein. Evidence for the presence of inhibitory finger-finger interactions that limit the nucleic acid binding properties of individual zinc fingers within TFIIIA and p43 is discussed.

Characterization of RNA aptamer binding by the Wilms' tumor suppressor protein WT1

The interaction of the zinc finger protein WT1 with RNA aptamers has been investigated using a quantitative binding assay, and the results have been compared to those from a previous study of the DNA binding properties of this protein. A recombinant peptide containing the four zinc fingers of WT1 (WT1-ZFP) binds to representatives of three specific families of RNA aptamers with apparent dissociation constants ranging from 13.8 +/- 1.1 to 87.4 +/- 10.4 nM, somewhat higher than the dissociation constant of 4.12 +/- 0.4 nM for binding to DNA. An isoform that contains an insertion of three amino acids between the third and fourth zinc fingers (WT1[+KTS]-ZFP) also binds to these RNAs with slightly reduced affinity (the apparent dissociation constants ranging from 22.8 to 69.8 nM) but does not bind to DNA. The equilibrium binding of WT1-ZFP to the highest-affinity RNA molecule was compared to the equilibrium binding to a consensus DNA molecule as a function of temperature, pH, monovalent salt concentration, and divalent salt concentration. The interaction of WT1-ZFP with both nucleic acids is an entropy-driven process. Binding of WT1-ZFP to RNA has a pH optimum that is narrower than that observed for binding to DNA. Binding of WT1-ZFP to DNA is optimal at 5 mM MgCl(2), while the highest affinity for RNA was observed in the absence of MgCl(2). Binding of WT1 to both nucleic acid ligands is sensitive to increasing monovalent salt concentration, with a greater effect observed for DNA than for RNA. Point mutations in the zinc fingers associated with Denys-Drash syndrome have dramatically different effects on the interaction of WT1-ZFP with DNA, but a consistent and modest effect on the interaction with RNA. The role of RNA sequence and secondary structure in the binding of WT1-ZFP was probed by site-directed mutagenesis. Results indicate that a hairpin loop is a critical structural feature required for protein binding, and that some consensus nucleotides can be substituted provided proper base pairing of the stem of the hairpin loop is maintained.

Specific RNA binding by a single C2H2 zinc finger

Zinc finger proteins with high affinity for human immunodeficiency virus Rev responsive element stem loop IIB (RRE-IIB) were previously isolated from a phage display zinc finger library. Zinc fingers from one of these proteins, RR1, were expressed individually and assayed for RRE-IIB affinity. The C-terminal zinc finger retained much of the binding affinity of the two-finger parent and was disrupted by mutations predicted to narrow the RRE-IIB major groove and which disrupt Rev binding. In contrast, the N-terminal zinc finger has a calculated affinity at least 1000-fold lower. Despite the high affinity and specificity of RR1 for RRE-IIB, binding affinity for a 234-nucleotide human immunodeficiency virus Rev responsive element (RRE234) was significantly lower. Therefore, zinc finger proteins that bind specifically to RRE234 were constructed using an in vitro selection and recombination approach. These zinc fingers bound RRE234 with subnanomolar dissociation constants and bound the isolated RRE-IIB stem loop with an affinity 2 orders of magnitude lower but similar to the affinity of an arginine-rich peptide derived from Rev. These data show that single C2H2 zinc fingers can bind RNA specifically and suggest that their binding to stem loop IIB is similar to that of Rev peptide. However, binding to RRE234 is either different from stem loop IIB binding or the tertiary structure of stem loop IIB is changed within the Rev responsive element.

The role of the central zinc fingers of transcription factor IIIA in binding to 5 S RNA

In the nine-zinc finger Xenopus transcription factor TFIIIA the central group of fingers, fingers 4 to 7, have been shown to bind to 5 S RNA. In this study, we have attempted to assess the role of this region of the TFIIIA molecule in more detail than hitherto. High-resolution footprinting by RNases A and CV1 has been used to probe the binding to 5 S RNA of three TFIIIA peptides Tf(1-6), Tf(4-6) and Tf(4-7), consisting of fingers 1 to 6, 4 to 6, and 4 to 7, respectively, and of full-length TFIIIA. The results pinpoint the outer margins of binding of the central fingers within helices IV and II of TFIIIA. A comparison of the footprints reveals that the presence of finger 7 affords protection at positions C19 and U55, the distal portion of helix II and the proximal portion of loop B. In addition, our footprints suggest that the central fingers bind in the same manner, whether in an isolated group or in the intact TFIIIA molecule. In a companion study, we have determined the binding affinities of Tf(4-6) and Tf(4-7) for full-length and three truncated 5 S RNA molecules, the latter selected on the basis of the regions of the 5 S RNA molecule known to be important in the binding of TFIIIA. The analysis uses only fully active protein involved in the binding and the results are consistent with the corresponding footprinting results. This is the first time that a detailed study of the binding site of one particular zinc finger to RNA has been reported; the results should be of use in the design of 5 S RNA molecules and TFIIIA peptides for structural studies of the interaction between zinc fingers and RNA.

Identification of a minimal domain of 5 S ribosomal RNA sufficient for high affinity interactions with the RNA-specific zinc fingers of transcription factor IIIA

Transcription factor IIIA of Xenopuslaevis serves a dual function during oogenesis and early development: this zinc finger protein binds to the internal promoter element of the 5 S ribosomal RNA genes and acts as a positive transcription factor; additionally, the protein functions in 5 S RNA storage. The central four zinc fingers (zf4-7) of the nine-finger protein have been shown to bind 5 S rRNA with comparable or higher affinity than the full-length protein. The role of finger seven in binding affinity has been examined by deletion analysis. A zf4-6 protein binds 5 S RNA with about a sevenfold reduction in binding affinity, compared to zf4-7. The effect of non-specific competitor DNA on binding affinities of the zinc finger peptides was examined and found to have a significant effect on the measured affinities of these peptides for full-length and truncated versions of 5 S RNA. The interaction of zf4-6 with full-length 5 S RNA was far more sensitive to non-specific competitor concentration than was the zf4-7:5 S RNA interaction, suggesting that finger seven contributes to both affinity and specificity in this protein:RNA interaction. In order to map zinc finger binding sites on the 5 S RNA molecule, we generated truncated versions of the RNA and tested these molecules for their binding affinities with zf4-7 and zf4-6. Previous studies showed that a 75 nucleotide long RNA, comprising loop A, helix II, helix V, region E and helix IV, bound zf4-7 with high affinity. Selection and amplification binding assays (selex) have now been used to generate smaller high-affinity binding RNAs. We find that a 55 nucleotide long RNA, comprising loop A, helix V, region E and helix IV, but lacking helix II, retains high affinity for zf4-6. These data are consistent with the proposal that fingers 4-6 bind this central core of 5 S RNA and that finger seven binds the helix II region.

Nucleolar targeting of 5S RNA in Xenopus laevis oocytes: somatic-type nucleotide substitutions enhance nucleolar localization

In Xenopus laevis oocytes, 5S RNA is stored in the cytoplasm until vitellogenesis, at which time it is imported into the nucleus and targeted to nucleoli for ribosome assembly. This article shows that throughout oogenesis there is a pool of nuclear 5S RNA which is not nucleolar-associated. This distribution reflects that of oocyte-type 5S RNA, which is the major 5S RNA species in oocytes; only small amounts of somatic-type, which differs by six nucleotides, are synthesized. Indeed, 32P-labeled oocyte-type 5S RNA showed a degree of nucleolar localization similar to endogenous 5S RNA (33%) after microinjection. In contrast, 32P-labeled somatic-type 5S RNA showed significantly enhanced localization, whereby 70% of nuclear RNA was associated with nucleoli. A chimeric RNA molecule containing only one somatic-specific nucleotide substitution also showed enhanced localization, in addition to other somatic-specific phenotypes, including enhanced nuclear import and ribosome incorporation. The distribution of 35S-labeled ribosomal protein L5 was similar to that of oocyte-type 5S RNA, even when preassembled with somatic-type 5S RNA. The distribution of a series of 5S RNA mutants was also analyzed. These mutants showed various degrees of localization, suggesting that the efficiency of nucleolar targeting can be influenced by many discrete regions of the 5S RNA molecule.

Nickel- and cobalt-dependent reagents identify structural features of RNA that are not detected by dimethyl sulfate or RNase T1

Ribosomal 5S RNA presents a particular challenge to structural investigations since this polynucleotide is too large for complete NMR characterization but lacks significant tertiary structure to modulate, for example, diagnostic alkylation of guanine N7 by dimethyl sulfate. Nickel- and cobalt-dependent reagents that are sensitive to the N7 and aromatic face of guanine have now been applied to 5S rRNA (Xenopus lavis) and provide structural information that was not previously available from traditional chemical or enzymatic probes. Although G75 had repeatedly demonstrated an average reactivity with dimethyl sulfate and minimal reactivity with RNase T1, this residue was the major target of both metal-dependent reagents. Such reactivity provides crucial support for a structural model of loop E identified by prior physical, but not chemical, methods. Similarly, the tetraloop structure of loop D was more accurately reflected by the reactivity of G87 and G89 in the presence of the nickel reagent rather than in the presence of RNase T1. In addition, nickel-dependent modification of guanine residues surrounding the three-helix junction of loop A suggests an organization that is less compact than previously considered.

Analysis of the binding of Xenopus transcription factor IIIA to oocyte 5 S rRNA and to the 5 S rRNA gene

Binding of transcription factor IIIA (TFIIIA) to site-specific mutants of Xenopus oocyte 5 S rRNA has been used to identify important recognition elements in the molecule. The putative base triple G75:U76:A100 appears to determine the conformation of the loop E region whose integrity is especially important for binding of the factor. Proximal substitutions in helices IV and V indicate that the proper folding of loop E is also dependent on these structures. Mutations in helix V affect binding of TFIIIA to 5 S rRNA and to the gene similarly and provide evidence that zinc finger 5 makes sequence-specific contact through the major groove of both nucleic acids. Although fingers 1-3 are positioned along helix IV and loop D, mutations in this region, including those that disrupt the tetraloop or close the opening in the major groove of the helix created by the U80:U96 mismatch, have no impact on binding. Substitutions made at stem-loop junctions in the arm of the RNA comprised of helix II-loop B-helix III display minor decreases in affinity for TFIIIA. Despite the alignment of the factor along nearly the entire length of 5 S rRNA, the essential elements for high affinity binding are limited to the central region of the molecule. Analysis of the corresponding mutations in the gene confirm that box C and the intermediate element provide the high affinity sites for binding of the factor to the DNA. Despite the small thermodynamic contribution made by contacts to box A, mutations made in this element can cause substantial changes in the orientation of the carboxyl-terminal fingers along the 5'-end of the internal control region.

Analysis of the binding of Xenopus ribosomal protein L5 to oocyte 5 S rRNA. The major determinants of recognition are located in helix III-loop C

Xenopus ribosomal protein L5 was expressed in Escherichia coli and exhibits high affinity (Kd = 2 nM) and specificity for oocyte 5 S rRNA. The pH dependence of the association constant for the complex reveals an ionization with a pK alpha value of 10.1, indicating that tyrosine and/or lysine residues are important for specific binding of L5 to the RNA. Formation of the L5.5 S rRNA complex is remarkably insensitive to ionic strength, providing evidence that nonelectrostatic interactions make significant contributions to binding. Together, these results suggest that one or more tyrosine residues may form critical contacts through stacking interactions with bases in the RNA. In order to locate recognition elements within 5 S rRNA, we measured binding of L5 to a collection of site-specific mutants. Mutations in the RNA that affected the interaction are confined to the hairpin structure comprised of helix III and loop C. Earlier experiments with a rhodium structural probe had shown that the two-nucleotide bulge in helix III and the intrinsic structure of loop C create sites in the major groove that are opened and accessible to stacking interactions with the metal complex. In the present studies, we detect a correlation between the intercalative binding of the rhodium complex to mutants in the hairpin and binding of L5, supporting the proposal that binding of the protein is mediated, in some part, by stacking interactions. Furthermore, the results from mutagenesis establish that, despite overlapping binding sites on 5 S rRNA, L5 and transcription factor IIIA utilize distinct structural elements for recognition.

Helical stacking in DNA three-way junctions containing two unpaired pyrimidines: proton NMR studies

The proton NMR spectra of DNA three-way junction complexes (TWJ) having unpaired pyrimidines, 5'-TT- and 5'-TC- on one strand at the junction site were assigned from 2D NOESY spectra acquired in H2O and D2O solvents and homonuclear 3D NOESY-TOCSY and 3D NOESY-NOESY in D2O solvent. TWJ are the simplest branched structures found in biologically active nucleic acids. Unpaired nucleotides are common features of such structures and have been shown to stabilize junction formation. The NMR data confirm that the component oligonucleotides assemble to form conformationally homogeneous TWJ complexes having three double-helical, B-form arms. Two of the helical arms stack upon each other. The unpaired pyrimidine bases lie in the minor groove of one of the helices and are partly exposed to solvent. The coaxial stacking arrangement deduced is different from that determined by Rosen and Patel (Rosen, M.A., and D.J. Patel. 1993. Biochemistry. 32:6576-6587) for a DNA three-way junction having two unpaired cytosines, but identical to that suggested by Welch et al. (Welch, J. B., D. R. Duckett, D. M. J. Lilley. 1993. Nucleic Acids Res. 21:4548-4555) on the basis of gel electrophoretic studies of DNA three-way junctions containing unpaired adenosines and thymidines.

Structural elements of rps0 mRNA involved in the modulation of translational initiation and regulation of E. coli ribosomal protein S15

Previous experiments showed that S15 inhibits its own translation by binding to its mRNA in a region overlapping the ribosome loading site. This binding was postulated to stabilize a pseudoknot structure that exists in equilibrium with two stem-loops and to trap the ribosome on its mRNA loading site in a transitory state. In this study, we investigated the effect of mutations in the translational operator on: the binding of protein S15, the formation of the 30S/mRNA/tRNA(fMet) ternary initiation complex, the ability of S15 to inhibit the formation of this ternary complex. The results were compared to in vivo expression and repression rates. The results show that (1) the pseudoknot is required for S15 recognition and translational control; (2) mRNA and 16S rRNA efficiently compete for S15 binding and 16S rRNA suppresses the ability of S15 to inhibit the formation of the active ternary complex; (3) the ribosome binds more efficiently to the pseudoknot than to the stem-loop; (4) sequences located between nucleotides 12 to 47 of the S15 coding phase enhances the efficiency of ribosome binding in vitro; this is correlated with enhanced in vivo expression and regulation rates.

Structural requirements of 5S rRNA for nuclear transport, 7S ribonucleoprotein particle assembly, and 60S ribosomal subunit assembly in Xenopus oocytes

Structural requirements of 5S rRNA for nuclear transport and RNA-protein interactions have been studied by analyzing the behavior of oocyte-type 5S rRNA and of 31 different in vitro-generated mutant transcripts after microinjection into the cytoplasm of Xenopus oocytes. Experiments reveal that the sequence and secondary and/or tertiary structure requirements of 5S rRNA for nuclear transport, storage in the cytoplasm as 7S ribonucleoprotein particles, and assembly into 60S ribosomal subunits are complex and nonidentical. Elements of loops A, C, and E, helices II and V, and bulged and hinge nucleotides in the central domain of 5S rRNA carry the essential information for these functional activities. Assembly of microinjected 5S rRNA into 60S ribosomal subunits was shown to occur in the nucleus; thus, the first requirement for subunit assembly is nuclear targeting. The inhibitory effects of ATP depletion, wheat germ agglutinin, and chilling on the nuclear import of 5S rRNA indicate that it crosses the nuclear envelope through the nuclear pore complex by a pathway similar to that used by karyophilic proteins.

Structural requirements of 5S rRNA for nuclear transport, 7S ribonucleoprotein particle assembly, and 60S ribosomal subunit assembly in Xenopus oocytes

Structural requirements of 5S rRNA for nuclear transport and RNA-protein interactions have been studied by analyzing the behavior of oocyte-type 5S rRNA and of 31 different in vitro-generated mutant transcripts after microinjection into the cytoplasm of Xenopus oocytes. Experiments reveal that the sequence and secondary and/or tertiary structure requirements of 5S rRNA for nuclear transport, storage in the cytoplasm as 7S ribonucleoprotein particles, and assembly into 60S ribosomal subunits are complex and nonidentical. Elements of loops A, C, and E, helices II and V, and bulged and hinge nucleotides in the central domain of 5S rRNA carry the essential information for these functional activities. Assembly of microinjected 5S rRNA into 60S ribosomal subunits was shown to occur in the nucleus; thus, the first requirement for subunit assembly is nuclear targeting. The inhibitory effects of ATP depletion, wheat germ agglutinin, and chilling on the nuclear import of 5S rRNA indicate that it crosses the nuclear envelope through the nuclear pore complex by a pathway similar to that used by karyophilic proteins.

Minimal 16S rRNA binding site and role of conserved nucleotides in Escherichia coli ribosomal protein S8 recognition

Escherichia coli ribosomal protein S8 was previously shown to bind a 16S rRNA fragment (nucleotides 584-756) with the same affinity as the complete 16S rRNA, and to shield an irregular helical region (region C) [Mougel, M., Eyermann, F., Westhof, E., Romby, P., Expert-Bezançon, Ebel, J. P., Ehresmann, B. & Ehresmann, C. (1987). J. Mol. Biol. 198, 91-107]. Region C was postulated to display characteristic features: three bulged adenines (A595, A640 and A642), a non-canonical U598-U641 pair surrounded by two G.C pairs. In order to delineate the minimal RNA binding site, deletions were introduced by site-directed mutagenesis and short RNA fragments were synthesized. Their ability to bind S8 was assayed by filter binding. Our results show that the RNA binding site can be restricted to a short helical stem (588-605/633-651) containing region C. The second part of the work focused on region C and on the role of conserved nucleotides as potential determinants of S8 recognition. Single and double mutations were introduced by site-directed mutagenesis in fragment 584-756, and their effect on S8 binding was measured. It was found that the three bulged positions are essential and that adenines are required at positions 640 and 642. U598 is also crucial and the highly conserved G597.C643 pair cannot be inverted. These conserved nucleotides are either directly involved in the recognition process as direct contacts or required to maintain a specific conformation. The strong evolutionary pressure and the small number of positive mutants stress the high stringency of the recognition process.

Conformational differences between bulged pyrimidines (C-C) and purines (A-A, I-I) at the branch point of three-stranded DNA junctions

We have synthesized DNA oligomers that can combine to form three-way junctions containing six base pairs in each stem and two unpaired bases at the branch point. Gel electrophoresis experiments indicate that the oligomers form stable complexes with equimolar stoichiometry. Using two- and three-dimensional proton nuclear magnetic resonance spectroscopy, we have completed nonexchangeable proton chemical shift assignments for three junctions which differ only in the identity of the unpaired bases (C-C, A-A, or I-I) at the branch point. Our results indicate that unpaired pyrimidines at the branch point of junctions behave differently than do unpaired purines. In a junction with two unpaired cytidines, the 5' base loops out from the molecule to lie along the minor groove of the preceding duplex stem of the junction. The 3' unpaired cytidine also demonstrates an unusual pattern of NOE connectivities with detected cross peaks to the subsequent base in the 3' direction. Junctions with unpaired purines at the branch point exhibit different behavior. Our data suggests that in these molecules the unpaired bases participate in stacking interactions among themselves and with the neighboring bases in the molecule. Despite these differences, the NOE patterns from each junction suggest the presence of a preferred, pair-wise stacking between two of the helices within the molecule. The structural differences between bulge-pyrimidine and bulge-purine junctions are discussed in light of the functional significance unpaired bases might have in the structure and dynamics of multistranded DNA junctions and, by extension, to junctions within cellular RNAs.

RNA and DNA binding zinc fingers in Xenopus TFIIIA

The nine tandem zinc finger repeats in the 5S gene-specific transcription factor IIIA (TFIIIA) from Xenopus mediate specific binding to 5S DNA as well as to 5S ribosomal RNA. A comparative functional analysis of a systematic set of TFIIIA zinc finger combinations reveals that most, if not all, participate in both DNA and RNA binding. Minimal sets of fingers sufficient for DNA and RNA recognition are different. In RNA binding, most finger elements are found to be functionally equivalent. However, the nonessential finger 6 exhibits RNA binding characteristics distinct from the other eight modules. The secondary/tertiary structure of the central domain in 5S RNA, not its primary sequence, is found to carry the essential structural information for TFIIIA binding in Xenopus oocytes. Taken together, our findings suggest that RNA and DNA binding are overlapping, though separable functions of the nine zinc finger elements in TFIIIA, occurring via fundamentally different molecular mechanisms.

An experimental study of Saccharomyces cerevisiae U3 snRNA conformation in solution

The conformation of Saccharomyces cerevisiae U3 snRNA (snR17A RNA) in solution was studied using enzymatic and chemical probes. In vitro synthesized and authentic snR17A RNAs have a similar conformation in solution. The S. cerevisiae U3 snRNA is folded in two distinct domains. The 5'-domain has a low degree of compactness; it is constituted of two stem-loop structures separated by a single-stranded segment, which has recently been proposed to basepair with the 5'-ETS of pre-ribosomal RNA. We demonstrate that, as previously proposed, the 5'-terminal region of U3 snRNA has a different structure in higher and lower eukaryotes and that this may be related to pre-rRNA 5'-ETS evolution. The S. cerevisiae U3 snRNA 3'-domain has a cruciform secondary structure and a compact conformation resulting from an higher order structure involving the single-stranded segments at the center of the cross and the bottom parts of helices. Compared to tRNA, where long range interactions take place between terminal loops, this represents another kind of tertiary folding of RNA molecules that will deserve further investigation, especially since the implicated single-strands have highly evolutionarily conserved primary structures that are involved in snRNP protein binding.

Effect of dimerization on the conformation of the encapsidation Psi domain of Moloney murine leukemia virus RNA

In Moloney murine leukemia virus, the encapsidation Psi element was shown to be necessary and sufficient to promote packaging of viral RNA, and to be required for dimerization. The conformation of the Psi domain (nucleotides 215 to 565) was investigated in solution by chemical probing. The four bases were monitored at one of their Watson-Crick positions with dimethylsulfate at cytosine N3 and adenosine N1, and with a carbodiimide derivative at guanosine N1 and uridine N3. Position N7 of adenine residues was probed with diethylpyrocarbonate. The analyses were conducted on in vitro transcribed fragments corresponding either to the isolated Psi domain or to the 5'-terminal 725 nucleotides. The RNA fragments were analyzed in their monomeric and dimeric forms. A secondary structure model was derived from probing data, computer prediction and sequence analysis of related murine retroviruses. One major result is that Psi forms an independent and highly structured domain. Dimerization induces an extensive reduction of reactivity in region 278 to 309 that can be interpreted as the result of intermolecular interactions and/or intramolecular conformational rearrangements. A second region (around position 215) was shown to display discrete reactivity changes upon dimerization. These two regions represent likely elements of dimerization. More unexpectedly, reactivity changes (essentially enhancement of reactivity) were also detected in another part of Psi (around position 480) not believed to contain elements of dimerization. These reactivity changes could be interpreted as dimerization-induced allosteric transitions.

Three-dimensional model of Escherichia coli ribosomal 5 S RNA as deduced from structure probing in solution and computer modeling

The conformation of Escherichia coli 5 S rRNA was investigated using chemical and enzymatic probes. The four bases were monitored at one of their Watson-Crick positions with dimethylsulfate (at C(N-3) and A(N-1], with a carbodiimide derivative (at G(N-1) and U(N-3] and with kethoxal (at G(N-1, N-2]. Position N-7 of purine was probed with diethylpyrocarbonate (at A(N-7] and dimethylsulfate (at G(N-7]. Double-stranded or stacked regions were tested with RNase V1 and unpaired guanine residues with RNase T1. We also used lead(II) that has a preferential affinity for interhelical and loop regions and a high sensitivity for flexible regions. Particular care was taken to use uniform conditions of salt, magnesium, pH and temperature for the different enzymatic chemical probes. Derived from these experimental data, a three dimensional model of the 5 S rRNA was built using computer modeling which integrates stereochemical constraints and phylogenetic data. The three domains of 5 S rRNA secondary structure fold into a Y-shaped structure that does not accommodate long-range tertiary interactions between domains. The three domains have distinct structural and dynamic features as revealed by the chemical reactivity and the lead(II)-induced hydrolysis: domain 2 (loop B/helix III/loop C) displays a rather weak structure and possesses dynamic properties while domain 3 (helix V/region E/helix IV/loop D) adopts a highly structured and overall helical conformation. Conserved nucleotides are not crucial for the tertiary folding but maintain an intrinsic structure in the loop regions, especially via non-canonical pairing (A.G, G.U, G.G, A.C, C.C), which can close the loops in a highly specific fashion. In particular, nucleotides in the large external loop C fold into an organized conformation leading to the formation of a five-membered loop motif. Finally, nucleotides at the hinge region of the Y-shape are involved in a precise array of hydrogen bonds based on a triple interaction between U14, G69 and G107 stabilizing the quasi-colinearity of helices II and V. The proposed tertiary model is consistent with the localization of the ribosomal protein binding sites and possesses strong analogy with the model proposed for Xenopus laevis 5 S rRNA, indicating that the Y-shape model can be generalized to all 5 S rRNAs.

Structural studies on site-directed mutants of domain 3 of Xenopus laevis oocyte 5 S ribosomal RNA

Base substitutions have been introduced into the highly conserved sequences of loops D and E within domain 3 of Xenopus laevis oocyte 5 S rRNA. The effects of these mutations on the solution structure of this 5 S rRNA have been studied by means of probing with nucleases, and with chemical reagents under native and semi-denaturing conditions. The data obtained with these mutants support the graphic model of Xenopus oocyte 5 S rRNA proposed by Westhof et al. In particular, our results rule out the existence of long-range base-pairing interactions between loop C and either loop D or loop E. The data also confirm that loops D and E in the wild-type 5 S RNA adopt unusual secondary structures and illustrate the importance of nucleotide sequence in the formation of intrinsic local loop conformations via non-canonical base-pairs and specific base-phosphate contacts. Consistent with this conclusion is our observation that the domain 3 fragment of Xenopus oocyte 5 S rRNA adopts the same conformation as the corresponding region in the full-length 5 S rRNA.

Xenopus transcription factor IIIA (XTFIIIA): after a decade of research

Xenopus transcription factor IIIA (XTFIIIA) is the first eukaryotic transcription factor purified to homogeneity and is specifically required for the 5S RNA gene transcription. It contains two structural domains and nine zinc finger motifs through which it recognizes the promoter region of the 5S RNA gene. It also binds to 5S RNA and serves to store 5S RNA in the form of 7S ribonucleoprotein particles in oocytes. Additionally, it forms a metastable complex with 5S DNA and promotes the formation of stable and competent transcription complexes. Its expression is developmentally controlled at the level of transcription and translation. Moreover, it participates in the assembly of active chromatin templates and at least, in part, is responsible for the developmental regulation of two kinds of 5S RNA genes in Xenopus.