Conformational studies of the nucleic acid binding sites for Xenopus transcription factor IIIA

Mutual induced fit binding of Xenopus ribosomal protein L5 to 5S rRNA

A library of random mutations in Xenopus ribosomal protein L5 was generated by error-prone PCR and used to delineate the binding domain for 5S rRNA. All but one of the amino acid substitutions that affected binding affinity are clustered in the central region of the protein. Several of the mutations are conservative substitutions of non-polar amino acid residues that are unlikely to form energetically significant contacts to the RNA. Thermal denaturation, monitored by circular dichroism (CD), indicates that L5 is not fully structured and association with 5S rRNA increases the t(m) of the protein by 16 degrees C. L5 induces changes in the CD spectrum of 5S rRNA, establishing that the complex forms by a mutual induced fit mechanism. Deuterium exchange reveals that a considerable amount of L5 is unstructured in the absence of 5S rRNA. The fluorescence emission of W266 provides evidence for structural changes in the C-terminal region of L5 upon binding to 5S rRNA; whereas, protection experiments demonstrate that the N terminus remains highly sensitive to protease digestion in the complex. Analysis of the amino acid sequence of L5 by the program PONDR predicts that the N and C-terminal regions of L5 are intrinsically disordered, but that the central region, which contains three essential tyrosine residues and other residues important for binding to 5S rRNA, is likely to be structured. Initial interaction of the protein with 5S rRNA likely occurs through this region, followed by induced folding of the C-terminal region. The persistent disorder in the N-terminal domain is possibly exploited for interactions between the L5-5S rRNA complex and other proteins.

A role for aromatic amino acids in the binding of Xenopus ribosomal protein L5 to 5S rRNA

The formation of the Xenopus L5-5S rRNA complex depends on nonelectrostatic interactions. Fluorescence assays with 1-anilino-8-naphthalenesulfonate demonstrate that a hydrophobic region on L5 becomes exposed upon removal of bound 5S rRNA by treatment with ribonucleases. Several conserved aromatic amino acids, mostly tyrosines, were identified by comparative sequence analysis and changed individually to alanine. Substitution with alanine at any of three positions, Y86, Y99, or Y226, essentially abolishes RNA-binding activity, whereas those made at Y95 and Y207 have more modest effects. Replacement with phenylalanine at Y86 and Y226 does not change binding affinity, indicating that the aromatic ring of the side chain, not the hydroxyl group, is the critical functionality for binding. Alternatively, the phenolic hydroxyls at Y99 and Y207 do contribute to binding. The structural integrity of the mutant proteins was assessed using thermal denaturation and limited digestion with proteases. The T(m) of Y99A is 10 degrees C lower than that of the wild-type protein, and there are some differences in the protease digestion patterns that together indicate the structure of this mutant has been significantly perturbed. The structures of the other variants are not detectably different from the wild-type protein. These results provide evidence that intermolecular stacking interactions involving at least two tyrosine residues, Y86 and Y226, are necessary for formation of the L5-5S rRNA complex and can account, at least in part, for the contribution nonelectrostatic interactions make to the free energy of binding.

An A-type double helix of DNA having B-type puckering of the deoxyribose rings

DNA usually adopts structure B in aqueous solution, while structure A is preferred in mixtures of trifluoroethanol (TFE) with water. However, the octamer d(CCCCGGGG) and other d(C(n)G(n)) fragments of DNA provide CD spectra that suggest that the base-pairs are stacked in an A-like fashion even in aqueous solution. Yet, d(CCCCGGGG) undergoes a cooperative TFE-induced transition into structure A, indicating that an important part of the aqueous duplex retains structure B. NMR spectroscopy shows that puckering of the deoxyribose rings is of the B-type. Hence, combination of the information provided by CD spectroscopy and NMR spectroscopy suggests an unprecedented double helix of DNA in which A-like base stacking is combined with B-type puckering of the deoxyribose rings. In order to determine whether this combination is possible, we used molecular dynamics to simulate the duplex of d(CCCCGGGG). Remarkably, the simulations, completely unrestrained by the experimental data, provided a very stable double helix of DNA, exhibiting just the intermediate B/A features described above. The double helix contained well-stacked guanine bases but almost unstacked cytosine bases. This generated a hole in the double helix center, which is a property characteristic for A-DNA, but absent from B-DNA. The minor groove was narrow at the double helix ends but wide at the central CG step where the Watson-Crick base-pairs were buckled in opposite directions. The base-pairs stacked tightly at the ends but stacking was loose in the duplex center. The present double helix, in which A-like base stacking is combined with B-type sugar puckering, is relevant to replication and transcription because both of these phenomena involve a local B-to-A transition.

MRE-Binding transcription factor-1: weak zinc-binding finger domains 5 and 6 modulate the structure, affinity, and specificity of the metal-response element complex

MRE-binding transcription factor-1 (MTF-1) contains six Cys(2)-His(2) zinc finger sequences, and it has been suggested that the zinc finger domain itself may function as a zinc sensor in zinc-activated expression of metallothioneins (MTs). Previous work has shown that a subset ( approximately 3-4) of the zinc fingers in MTF-zf play a structural role in folding and high-affinity metal-response element (MREd) binding, while one or more other fingers have properties consistent with a metalloregulatory role (weak zinc binding affinity in the absence of DNA). We show here that zinc fingers 5 and 6 correspond to the weak zinc-binding fingers in MTF-zf. Limited trypsinolysis of a Zn(6)-MTF-zf:MREd complex gives rise to a highly protease-resistant core fragment corresponding to amino acids 137-260 or N-terminal zinc fingers 1-4 of MTF-zf. Characterization of a collection of broken-finger (His --> Asn) and missing-finger mutants of MTF-zf reveals that deletion of zinc fingers 5 and 6 to create MTF-zf14 attenuates MREd binding affinity ( approximately 20-fold), while deletion of fingers 4-6 (MTF-zf13) results in a further 20-fold reduction of binding affinity with a nearly complete loss of specificity. Circular dichroism studies reveal that the binding of MTF-zf to the MREd induces a dramatic alteration of the structure of the MREd from a B-form to a double-helical conformation with A-like features. Formation of stoichiometric complexes with MTF-zf14, H279N (Deltazf5) MTF-zf, and MTF-zf13 induces comparatively less A-like structure. Steady-state fluorescence resonance energy transfer (FRET) spectroscopy has been used to globally define the orientation of the multifinger MTF-zf on the MREd. These experiments suggest that fingers 1-4 are oriented on the highly conserved TGCRCnC side of the MREd with fingers 5-6 bound at or near the gGCCc sequence. These findings are consistent with a model in which the N-terminal zinc fingers in MTF-zf are required for high affinity and specific binding to the consensus TGCRCnC core in a way which is subjected to structural and allosteric modulation by the weak zinc-binding C-terminal zinc fingers.

Inhibition of RNA polymerase III transcription by a ribosome-associated kinase activity

Ribosomes prepared from somatic tissue of Xenopus laevis inhibit transcription by RNA polymerase III. This observation parallels an earlier report that a high speed fraction from activated egg extract, which is enrichedin ribosomes, inhibits RNA polymerase III activityand destabilizes putative transcription complexes assembled on oocyte 5S rRNA genes. Transcription of somatic- and oocyte-type 5S rRNA genes and a tRNA gene are all repressed in the present experiments. We find that 5S rRNA genes incubated in S150 extract prepared from immature oocytes exhibit an extensive DNase I protection pattern that is nearly identical to that of the ternary complex of TFIIIA and TFIIIC bound to a somatic 5S rRNA gene. The complexes formed in this extract are stable at concentrations of ribosomes that completely repress transcription, indicating that formation of the TFIII(A+C) complex is not the target of inhibition. Ribosomes taken through a high salt treatment no longer repress transcription of class III genes, establishing that the inhibition is due to an associated factor and not the particle itself. The inhibitory activity released from ribosomes is inactivated by treatment with proteinase K, but not micrococcal nuclease. Preincubation of ribosomes with a general protein kinase inhibitor, 6-dimethylaminopurine, eliminates repression of transcription. Western blot analysis demonstrates that p34(cdc2), which is known to mediate repression of transcription by RNA polymerase III, is present in these preparations of ribosomes and can be released from the particles upon extraction with high salt. These results establish that a kinase activity, possibly p34(cdc2), is the actual agent responsible for the observed inhibition of transcription by ribosomes.

Insertion of telomere repeat sequence decreases plasmid DNA condensation by cobalt (III) hexaammine

Telomere repeat sequence (TRS) DNA is found at the termini of most eukaryotic chromosomes. The sequences are highly repetitive and G-rich (e.g., [C(1-3)A/TG(1-3)]n for the yeast Saccharomyces cerevisiae) and are packaged into nonnucleosomal protein-DNA structures in vivo. We have used total intensity light scattering and electron microscopy to monitor the effects of yeast TRS inserts on in vitro DNA condensation by cobalt (III) hexaammine. Insertion of 72 bp of TRS into a 3.3-kb plasmid depresses condensation as seen by light scattering and results in a 22% decrease in condensate thickness as measured by electron microscopy. Analysis of toroidal condensate dimensions suggests that the growth stages of condensation are inhibited by the presence of a TRS insert. The depression in total light scattering intensity is greater when the plasmid is linearized with the TRS at an end (39-49%) than when linearized with the TRS in the interior (18-22%). Circular dichroism of a 95-bp fragment containing the TRS insert gives a spectrum that is intermediate between the A-form and B-form, and the anomalous condensation behavior of the TRS suggests a noncanonical DNA structure. We speculate that under conditions in which the plasmid DNA condenses, the telomeric insert assumes a helical geometry that is similar to the A-form and is incompatible with packing into the otherwise B-form lattice of the condensate interior.

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.

Contribution of individual base pairs to the interaction of TFIIIA with the Xenopus 5S RNA gene

The effects of a series of point mutations within the Xenopus borealis somatic-type 5S RNA gene on transcription factor IIIA (TFIIIA) binding affinity were quantified. These data define a critical sequence-dependent contact region within the classical box C promoter element from base pair 80 to 91. Substitution of GC base pairs at positions 81, 85, 86, 89, and 91 significantly reduce TFIIIA binding affinity. Base pairs located at other positions within the box C contact region provide a moderate contribution to TFIIIA-5S gene interaction. In contrast to the extensive set of sequence contacts within the box C element, TFIIIA interaction is localized primarily to two GC base pairs at positions 70 and 71 within the intermediate promoter element. A selected amplification and binding assay (SAAB) was performed with a synthetic internal control region (ICR) randomized from base pair 78 to 95 to identify box C promoter sequences bound with high affinity by TFIIIA. The wild-type 5S RNA gene sequence from 79 to 92 is strongly selected. These results are consistent with the critical role of the box C element in sequence-dependent promoter recognition by TFIIIA.

Crystal structure of a five-finger GLI-DNA complex: new perspectives on zinc fingers

Zinc finger proteins, of the type first discovered in transcription factor IIIA (TFIIIA), are one of the largest and most important families of DNA-binding proteins. The crystal structure of a complex containing the five Zn fingers from the human GLI oncogene and a high-affinity DNA binding site has been determined at 2.6 A resolution. Finger one does not contact the DNA. Fingers two through five bind in the major groove and wrap around the DNA, but lack the simple, strictly periodic arrangement observed in the Zif268 complex. Fingers four and five of GLI make extensive base contacts in a conserved nine base-pair region, and this section of the DNA has a conformation intermediate between B-DNA and A-DNA. Analyzing the GLI complex and comparing it with Zif268 offers new perspectives on Zn finger-DNA recognition.

Zinc induces a bend within the transcription factor IIIA-binding region of the 5 S RNA gene

Binding of Zn2+ to the 5 S RNA gene sequence of Xenopus borealis results in strong bending of the DNA, as inferred from transient electric birefringence data. The effect is specific for Zn2+; several other divalent ions are not able to induce a bend of a similar magnitude. Using five different fragments that span the binding sequence, we are able to estimate a bend magnitude of at least 55 degrees centered at base-pair +65 within the gene. This places the bend within the binding domain of the gene-regulatory protein transcription factor (TF) IIIA. Recent evidence has shown that the protein-DNA complex is also bent. Although our data do not allow us directly to link the two bends, our results suggest that TFIIIA could form a folded structure by stabilizing the same bent conformation that is induced by binding of Zn2+. The chemistry of Zn2+ binding to DNA, and the sequence around the bend center, suggest that the bend is most probably caused by joint co-ordination of Zn2+ to the N-7 groups of stacked purine residues.

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.