Internal Control Region Research Articles

Cobalt-substituted zinc finger 3 of transcription factor IIIA: interactions with cognate DNA detected by (31)P ENDOR spectroscopy.

We show the first ENDOR study of the coordination environment of high-spin Co(II) in a biological system with a study of DNA binding to the Co-substituted Cys2/His2 single Zn-finger domain, Finger 3 (F3), from the prototypical zinc finger protein, transcription factor IIIA (TFIIIA) from Xenopus laevis. High covalency to cysteine and histidine is implied by ENDOR-derived 1H couplings to protons of cysteinyl ligands and 14N couplings to histidyl nitrogens, results which support the expectation that Zn(II) and Co(II) bind to F3 in a very similar manner. No changes in either 1H or 14N ENDOR were detected upon binding Co(II)-F3 to C-block DNA. Of particular importance to the use of Co(II) substitution for Zn(II), the ENDOR method shows that Co(II)-F3 undergoes sequence-specific binding to the cognate DNA for Zn(II)-F3, the internal control region (ICR) of the 5S rRNA (C-block). 31P ENDOR measurements yield a Co-31P distance of rCo-P = 8.1(3) A to the nearest backbone phosphodiester of the C-block. Interestingly, a 31P ENDOR doublet observed for Co(II)-F3 in phosphate buffer indicates that inorganic phosphate (Pi) binds at a comparable distance from Co as does the nearest phosphate of DNA, presumably at the same site.

Identification and characterization of transcription factor IIIA from Schizosaccharomyces pombe.

Transcription factor IIIA (TFIIIA) is specifically required for transcription of 5S rRNA genes and is the archetypal C2H2 zinc finger protein. All known vertebrate TFIIIAs have a similar organization: nine zinc fingers, followed by a C-terminal domain of unknown structure. The zinc fingers of Saccharomyces cerevisiae TFIIIA are interrupted between fingers eight and nine by an 81-amino acid spacer. Aside from the amino acids required for zinc finger folding, TFIIIAs from different species are remarkably divergent, whereas the natural binding site, the internal control region of the 5S rRNA gene, is well conserved. We now describe the identification and characterization of TFIIIA from Schizosaccharomyces pombe. This protein is organized differently from its known homologs, in that it contains eight closely spaced zinc fingers, a ninth zinc finger missing a C-terminal Zn2+-coordinating histidine, a 53- amino acid spacer, and an unprecedented tenth zinc finger. We have confirmed the identity of this divergent protein as TFIIIA by showing that it binds specifically and with high affinity to the S.pombe 5S rRNA gene. Comparison of DNase I protection patterns produced by TFIIIA from multiple species suggests a novel mode of DNA recognition by the S.pombe protein. Recombinant S.pombe TFIIIA was also shown to support specific transcription of the 5S rRNA gene in vitro.

DNA–support coupling for transcription factor purification: Comparison of aldehyde, cyanogen bromide and N-hydroxysuccinimide chemistries

Purification of transcription factor IIIA on internal control region DNA coupled to aldehyde-silica is described and compared with purification on cyanogen bromide-activated Sepharose and Bio-Rad Affi-Gel-10. The Affi-Gel support results in mixed-mode chromatography; both ion-exchange and affinity modes contribute. Coupling DNA to aldehyde-silica is advantageous in that it has no ion-exchange properties and performs as well as DNA coupled to CNBr-activated Sepharose. Purification of lac repressor on aldehyde-silica, and CAAT enhancer binding protein on Affi-Gel also shows the advantages of a neutral support and the disadvantages of mixed-mode chromatography for transcription factor purification. Aldehyde-silica couples to alkylamines and to the amines of adenine, guanine, and cytosine nucleoside bases. Reaction occurs with either single- or double-stranded DNA, although it is less efficient with the latter. Overall, the results demonstrate that predominantly neutral coupling chemistries, such as aldehyde or CNBr-mediated coupling, have distinct advantages for transcription factor purification. Since the CNBr chemistry has not yet been applied to silica supports, aldehyde-silica coupling is currently the most attractive method for DNA affinity HPLC.

CDNA cloning, DNA binding, and evolution of mammalian transcription factor IIIA

cDNA for rat transcription factor IIIA (TFIIIA) was cloned by degenerate PCR and rapid amplification of cDNA ends. This cDNA coded for a protein with nine Cys2His2 zinc fingers and a non-finger C-terminal tail; 63% amino acid (aa) sequence identity was observed with the Xenopus TFIIIA zinc finger region. Recombinant rat protein containing only the nine fingers afforded DNase I protection of the identical nucleotides protected by Xenopus laevis native TFIIIA on the Xenopus 5S RNA gene internal control region. A putative mouse TFIIIA clone was identified in an expressed sequence tag database by sequence similarity to rat TFIIIA. Recombinant nine-finger protein from this clone afforded DNase I protection of the Xenopus 5S rRNA gene like the native frog protein as did a recombinant nine-finger form of a putative human TFIIIA clone. These DNA binding results demonstrate that these clones code for the respective mammalian TFIIIAs. Rodent and human TFIIIAs share about 87% aa sequence identity in their zinc finger regions and have evolved to about the same extent as X. laevis and Xenopus borealis TFIIIAs. A monoclonal antibody against human p53 tumor suppressor bound to rat and mouse TFIIIA but not to human TFIIIA in Western blots. The N-terminal regions of rodent and human TFIIIA do not contain the oocyte-specific initiating Met and accompanying conserved residues found in fish and amphibian TFIIIAs. In their non-finger C-terminal tails, mammalian and amphibian TFIIIAs share a conserved transcription activation domain as well as conserved nuclear localization and nuclear export signals.

Molecular Diversity and Physical Mapping of 5S rDNA in Wild and Cultivated Oat Grasses (Poaceae: Aveneae)

5S rDNA repeats studied in five genera of Aveneae have lengths between 285 and 329 bp (Avena sativa, Avena macrostachya, 26 species of Helictotrichon, Pseudarrhenatherum longifolium, Lagurus ovatus, and Trisetum spicatum). In only a single species (Helictotrichon aetolicum) an additional repeat of 456 bp occurs infrequently. Variation is largely due to insertions or deletions in the nontranscribed spacer as determined from sequences of 163 independent clones. The 5S gene of the Aveneae studied is conserved in length and sequence except for Helictotrichon bromoides and Helictotrichon marginatum in which duplications occur at two different sites. This new type of duplication and all duplications reported to date in 5S genes of angiosperms are shown to center on defined palindromic sequences. The “uncommon” 5S gene sequences detected in some Aveneae are not necessarily nonfunctional as pseudogenes because the essential features of the internal control region are maintained even after such duplication events. In each instance such gene sequences have spacers with unmodified structure, indicating that change in gene sequence is not necessarily coupled with change in adjacent spacers. The value of 5S spacer sequences for genomic identifications in Aveneae is exemplified in A. macrostachya (perennial), A. sativa (annual), and several diploid taxa of the genus Helictotrichon.

Effect of mutations in the upstream promoter on the transcription of human 5S rRNA genes

The human 5S rRNA gene has a 12-mer external promoter, the D box, localized about 30 bp upstream the coding sequence. By site directed mutagenesis 58 different D box promoter mutants were made. While some mutations in the D box allowed full transcription, other mutations decreased the transcriptional activity to 20–50% compared to the bona fide gene, showing the importance of this external promoter in transcription initiation. A number of maxi 5S rRNA genes were constructed from bona fide genes and D box mutated clones. Transfection of HeLa cells with maxi 5S rRNA genes showed that the D box is also important for 5S rRNA gene expression in vivo. Evidence from different eukaryotic cells suggests that expression of 5S rRNA genes is regulated by external promoters in addition to the internal control region.

The third zinc finger of TFIIIA stabilizes a hairpin structure of the non-coding strand in the internal control region of 5S RNA gene

The structures of non-coding and coding strands in box C of the internal control region (ICR) of Xenopus laevis somatic 5S RNA gene have been examined by circular dichroism (CD) and Raman spectroscopy in the absence and presence of the third zinc finger of transcription factor IIIA (TFIIIA), which binds to the ICR. The non-coding strand exhibits CD signals assignable to a hairpin and an unfolded structure. The presence of the hairpin structure is supported by Raman spectra, gel electrophoresis, and nucleotide deletion experiments. Binding of the zinc finger to the non-coding strand increases the CD signal of hairpin structure, indicating stabilization of the hairpin structure by the zinc finger. In contrast, the corresponding coding strand remains unfolded even in the presence of the zinc finger. The TFIIIA–ICR complex is not only required for initiation of transcription but also lasts during many rounds of transcription of the 5S RNA gene including the ICR (Bogenhagen et al., Cell 28 (1982) 413). TFIIIA may play a role in promoting the transcription by maintaining the unwound non-coding strand in the hairpin structure and leaving the coding strand available for transcription by RNA polymerase.

Cadmium and lead interactions with transcription factor IIIA from Xenopus laevis: a model for zinc finger protein reactions with toxic metal ions and metallothionein

Zinc finger proteins comprise the largest class of eukaryotic transcription factors. The metal binding sites in these proteins have been proposed as plausible targets for exchange reactions between zinc and toxic metal ions that lead to the alteration of function of the proteins in gene transcription. According to the present work, both Cd 2+ and Pb 2+ displace Zn 2+ from transcription factor IIIA (TFIIIA). Neither product binds to the internal control region (ICR) of the 5 S rRNA gene, the normal binding site for Zn-TFIIIA. Furthermore, the adduct of Zn-TFIIIA with ICR is also reactive with Cd 2+ and Pb 2+, leading to the dissociation of the DNA–protein complex. Cd-TFIIIA reacts with apometallothionein (apoMT) to form Cd-MT and apoTFIIIA. Similarly, Cd 2+ and Zn 2+ can be exchanged in the reaction of Cd-TFIIIA with Zn-MT. Zn-finger 3 of TFIIIA has also been examined to compare the reactivity of a single finger motif with fingers in the holoprotein. Zn-finger 3 reacts with much faster kinetics than the holoprotein.

Lead inhibition of DNA-binding mechanism of Cys(2)His(2) zinc finger proteins.

The association of lead with chromatin in cells suggests that deleterious metal effects may in part be mediated through alterations in gene function. To elucidate if and how lead may alter DNA binding of cysteine-rich zinc finger proteins, lead ions were analyzed for their ability to alter the DNA binding mechanism of the Cys(2)His(2) zinc finger protein transcription factor IIIA (TFIIIA). As assayed by DNase I protection, the interaction of TFIIIA with the 50-bp internal control region of the 5S ribosomal gene was partially inhibited by 5 microM lead ions and completely inhibited by 10 to 20 microM lead ions. Preincubation of free TFIIIA with lead resulted in DNA-binding inhibition, whereas preincubation of a TFIIIA/5S RNA complex with lead did not result in DNA-binding inhibition. Because 5S RNA binds TFIIIA zinc fingers, this result is consistent with an inhibition mechanism via lead binding to zinc fingers. The complete loss of DNase I protection on the 5S gene indicates the mechanism of inhibition minimally involves the N-terminal fingers of TFIIIA. Inhibition was not readily reversible and occurred in the presence of an excess of beta-mercaptoethanol. Inhibition kinetics were fast, progressing to completion in approximately 5 min. Millimolar concentrations of sulfhydryl-specific arsenic ions were not inhibitory for TFIIIA binding. Micromolar concentrations of lead inhibited DNA binding by Sp1, another Cys(2)His(2) finger protein, but not by the nonfinger protein AP2. Inhibition of Cys(2)His(2) zinc finger transcription factors by lead ions at concentrations near those known to have deleterious physiological effects points to new molecular mechanisms for lead toxicity in promoting disease.

Tight correlation between inhibition of DNA repair in vitro and transcription factor IIIA binding in a 5S ribosomal RNA gene.

UV-induced photoproducts (cyclobutane pyrimidine dimers, CPDs) in DNA are removed by nucleotide excision repair (NER), and the presence of transcription factors on DNA can restrict the accessibility of NER enzymes. We have investigatigated the modulation of NER in a gene promoter using the Xenopus transcription factor IIIA (TFIIIA)-5S rDNA complex and Xenopus oocyte nuclear extracts. TFIIIA alters CPD formation primarily in the transcribed strand of the 50 bp internal control region (ICR) of 5S rDNA. During NER in vitro, CPD removal is reduced at most sites in both strands of the ICR when TFIIIA is bound. Efficient repair occurs just outside the TFIIIA-binding site (within 10 bp), and in the absence of 5S rRNA transcription. Interestingly, three CPD sites within the ICR [+56, +75 (transcribed strand) and +73 (non-transcribed strand)] are repaired rapidly when TFIIIA is bound, while CPDs within approximately 5 bases of these sites are repaired much more slowly. CPDs at these three sites may partially displace TFIIIA, thereby enabling rapid repair. However, TFIIIA is not completely displaced during NER, at least at sites outside the ICR, even though the NER complex could be sterically hindered by TFIIIA. Such inefficient repair of transcription factor binding sites could increase mutation frequency in regulatory regions of genes.

Differential requirements for basic amino acids in transcription factor IIIA-5S gene interaction

Basic amino acids Arg, Lys, and His in the Cys 2His 2 zinc fingers of transcription factor IIIA (TFIIIA) potentially have important roles in factor binding to the extended internal control region (ICR) of the 5S ribosomal gene. Conserved and non-conserved basic residues in the N-terminal fingers I, II, III and the more C-terminal fingers V and IX were analyzed by site-directed mutagenesis and DNase I protection in order to assess their individual requirement in the DNA-binding mechanism. In the DNA recognition helix of finger II, the conserved Arg at position 62 (N-terminal side of the first zinc-coordinating histidine) was changed to a Leu or Gln. Both the R62L and R62Q mutations inhibited Xenopus TFIIIA-dependent DNase I footprinting along the entire 5S gene ICR. When His-58 (non-conserved basic residue with DNA-binding potential in the same helical region) was changed to a Gln, the mutated protein was able to protect the ICR from DNase I digestion. Therefore, Arg-62 is individually required for TFIIIA binding over the entire ICR whereas His-58 is not. Fingers V and IX have conserved Arg residues in positions identical to Arg-62 in finger II (Arg-154 in finger V and Arg-271 in finger IX). When these residues were changed to Leu and Ile respectively, TFIIIA-dependent DNase I protection was observed along the entire 5S gene ICR. These results indicate differing DNA-binding mechanisms by the N-terminal fingers versus the C-terminal fingers at the level of individual amino acid-nucleotide interactions. In the N-terminal finger I, the conserved Lys at position 11 outside the recognition helix and a conserved hydrophobic Trp at position 28 within the helix were changed to an Ala and Ser respectively. The K11A change inhibited TFIIIA-dependent DNase I protection to a much greater extent than the W28S change.

A hydrophobic segment within the 81-amino-acid domain of TFIIIA from Saccharomyces cerevisiae is essential for its transcription factor activity.

Transcription factor IIIA (TFIIIA) binds to the internal control region of the 5S RNA gene as the first step in the in vitro assembly of a TFIIIB-TFIIIC-TFIIIA-DNA transcription complex. An 81-amino-acid domain that is present between zinc fingers 8 and 9 of TFIIIA from Saccharomyces cerevisiae is essential for the transcription factor activity of this protein (C. A. Milne and J. Segall, J. Biol. Chem. 268:11364-11371, 1993). We have monitored the effect of mutations within this domain on the ability of TFIIIA to support transcription of the 5S RNA gene in vitro and to maintain cell viability. TFIIIA with internal deletions that removed residues 282 to 315, 316 to 334, 328 to 341, or 342 to 351 of the 81-amino-acid domain retained activity, whereas TFIIIA with a deletion of the short leucine-rich segment 352NGLNLLLN359 at the carboxyl-terminal end of this domain was devoid of activity. Analysis of the effects of double and quadruple mutations in the region extending from residue 336 to 364 confirmed that hydrophobic residues in this portion of the 81-amino-acid domain, particularly L343, L347, L354, L356, L357, and L358, and to a lesser extent F336 and L337, contributed to the ability of TFIIIA to promote transcription. We propose that these hydrophobic residues play a role in mediating an interaction between TFIIIA and another component of the transcriptional machinery. We also found that TFIIIA remained active if either zinc finger 8 or zinc finger 9 was disrupted by mutation but that TFIIIA containing a disruption of both zinc finger 8 and zinc finger 9 was inactive.

Structure of the Trypanosoma brucei U6 snRNA gene promoter

Transcription in vivo of small nuclear and cytoplasmic RNA genes of Trypanosoma brucei was previously shown to require the A and B blocks of a divergently transcribed tRNA or tRNA-like gene located approximately 100 nucleotides (nt) upstream. To understand the functioning of these transcription units, we have used the U6 snRNA/tRNA Thr genes as a model system. Saturation mutagenesis revealed that for transcription in vivo three elements are essential and sufficient. In addition to the previously described A and B boxes, sequences in the U6 coding region close to the 5′ end participate in positioning RNA polymerase III at the start site, and thus constitute a third promoter element. We further showed that the function of the upstream A box, but not the B box, is strictly dependent upon its distance to the U6 gene internal control region. Using our recently developed transcription extract we further demonstrated that in vitro U6 transcription requires only the intragenic sequences and the upstream A box of the tRNA Thr gene. This apparent discrepancy between the in vivo and in vitro requirements is highly reminiscent of U6 snRNA gene transcription in the yeast Saccharomyces cerevisiae, and suggests the possibility that similar to the yeast system the B block of the trypanosome U6 snRNA gene promoter might be involved in chromatin organization.

Energetically Unfavorable Interactions among the Zinc Fingers of Transcription Factor IIIA When Bound to the 5 S rRNA Gene

Xenopus transcription factor IIIA (TFIIIA) binds to over 50 base pairs in the internal control region of the 5 S rRNA gene, yet the binding energy for this interaction (DeltaG0 = -12.8 kcal/mol) is no greater than that exhibited by many proteins that occupy much smaller DNA targets. Despite considerable study, the distribution of the DNA binding energy among the various zinc fingers of TFIIIA remains poorly understood. By analyzing TFIIIA mutants with disruptions of individual zinc fingers, we have previously shown that each finger contributes favorably to binding (Del Rio, S., Menezes, S. R., and Setzer, D. R. (1993) J. Mol. Biol. 233, 567-579). Those results also suggested, however, that simultaneous binding by all nine zinc fingers of TFIIIA may involve a substantial energetic cost. Using complementary N- and C-terminal fragments and full-length proteins containing pairs of disrupted fingers, we now show that energetic interference indeed occurs between zinc fingers when TFIIIA binds to the 5 S rRNA gene and that the greatest interference occurs between fingers at opposite ends of the protein in the TFIIIA.5 S rRNA gene complex. Some, but not all, of the thermodynamically unfavorable strain in the TFIIIA.5 S rRNA gene complex may be derived from bending of the DNA that is necessary to accommodate simultaneous binding by all nine zinc fingers of TFIIIA. The energetics of DNA binding by TFIIIA thus emerges as a compromise between individual favorable contacts of importance along the length of the internal control region and long range strain or distortion in the protein, the 5 S rRNA gene, or both that is necessary to accommodate the various local interactions.

Uranyl photoprobing of DNA structures and drug-DNA complexes.

The uranyl(IV) ion (UO2 2+) binds strongly to the phosphates of DNA and, upon irradiation with long wavelength ultraviolet light, the proximal deoxyn-boses are oxidized by the photochemically excited state of the uranyl1 ion, a very strong oxidant (). Thus the uranyl ion is an efficient DNA photocleavage reagent (,) that has been used to study the sequence specific interaction with the phosphates of the DNA backbone of the respective DNA recogintion sites of various proteins, such as the λ-repressor/OR1 complex (), RNA polymerase-deoP1 promoter of Escherzchza coli (), RNA polymerase/cyclic AMP receptor protein (CRP)-deoP2 promoter of E coli (), CRP/CytR repressor-deoP2 promoter of E. colz (), and transcription factor IIIA/Xenopus 5s internal control region ().

Analysis ofCis-Acting Elements in the 5′ Leader Sequence of Alfalfa Mosaic Virus RNA 3

The leader sequence of RNA 3 of the Leiden isolate of alfalfa mosaic virus strain 425 consists of 345 nucleotides (nt) and contains four putative stem–loop structures each with a motif in the loop that resembles the internal control region 2 (ICR2) of tRNA genes. The sequence of the 5′ terminal 112 nt of this leader contains one of these stem–loop structures and is sufficient for a reduced accumulation of RNA 3 in protoplasts and a delayed accumulation in plants (E. A. G. van der Vossenet al., Nucleic Acids Res.21, 1361–1367 (1993). A number of mutations were made in this 112-nt leader sequence to investigate its role in RNA 3 accumulation. Deletion of nucleotides 23–43, 44–90, or 55–112 and inversion or duplication of nucleotides 44–90 all abolished RNA 3 accumulation. Similarly, two base substitutions in the ICR2 motif (nucleotides 60–77) abolished RNA 3 accumulation. Mutations in the stem sections of the putative stem–loop structure had various effects on RNA 3 accumulation and supported the notion that this structure is important for plus-strand promoter activity.

Interaction of Wild-type and Truncated Forms of Transcription Factor IIIA from Saccharomyces cerevisiae with the 5 S RNA Gene

Transcription factor (TF) IIIA, which contains nine zinc finger motifs, binds to the internal control region of the 5S RNA gene as the first step in the assembly of a multifactor complex that promotes accurate initiation of transcription by RNA polymerase III. We have monitored the interaction of wild-type and truncated forms of yeast TFIIIA with the 5 S RNA gene. The DNase I footprints obtained with full-length TFIIIA and a polypeptide containing the amino-terminal five zinc fingers (TF5) were indistinguishable, extending from nucleotides +64 to +99 of the 5 S RNA gene. This suggests that fingers 6 through 9 of yeast TFIIIA are not in tight association with DNA. The DNase I footprint obtained with a polypeptide containing the amino-terminal four zinc fingers (TF4) was 14 base pairs shorter than that of TF5, extending from nucleotides +78 to +99 on the nontranscribed strand and from nucleotides +79 to +98 on the transcribed strand of the 5 S RNA gene. Protection provided by a polypeptide containing the first three zinc fingers (TF3) was similar to that provided by TF4, with the exception that protection on the nontranscribed strand ended at nucleotide +80, rather than nucleotide +78. Methylation protection analysis indicated that finger 5 makes major groove contacts with guanines +73 and +74. The amino-terminal four zinc fingers make contacts that span the internal control region, which extends from nucleotides +81 to +94 of the 5 S RNA gene, with finger 4 appearing to contact guanine +82. Measurements of the apparent Kd values of the TFIIIA.DNA complexes indicated that the amino-terminal three zinc fingers of TFIIIA have a binding energy that is similar to that of the full-length protein.

Centromeric polymerase III transcription units in Chironomus pallidivittatus.

Cp1 is a polymorphic short interspersed repeat (SINE) which is distributed over the whole genome of the dipteran Chironomus pallidivittatus, and is particularly abundant in the centromeres. It contains two different sequence modules, one of which, the B module, has a polymerase III internal control region (ICR) typical for tRNA genes (A and B box). Such sequence motifs are common in SINEs and assumed to function in RNA-mediated transposition. In the present case, however, several structural features speak for another role. An investigation of the transcription of the B module shows that it encodes a 99 nt RNA species in vivo, Cp1-RNA, terminating within the module. The transcription unit is likely to have evolved from a pre-tRNA gene and the transcript has sequence similarities to non-processed pre-tRNA. Most of the in vitro transcription is eliminated by deletion or substitution mutation of an upstream TATA box, present within the B module, as well as by changing either the A or B box. The properties of the transcript suggest that it does not have a role in transposition but may have some other function, perhaps in the centromere.

Inhibition of transcription factor IIIA-DNA interactions by xenobiotic metal ions.

Transcription factor IIIA (TFIIIA), a cysteine-rich regulatory protein, is the prototype for the largest known superfamily of eukaryotic transcription factors. Members of the TFIIIA superfamily contain Cys2His2 zinc finger domains responsible for nucleic acid binding. Xenobiotic metal ions, which lack known biological function, were previously used as probes for the structure and function of steroid hormone receptors which contain Cys2Cys2 zinc finger domains. Structural alterations in cysteine-rich regulatory proteins by such ions in vivo might potentiate carcinogenesis and other disease processes. In the present study cadmium and other xenobiotic metal ions were used to probe the structure and function of TFIIIA. The specific interaction of TFIIIA with the internal control region (ICR) of the 5S RNA gene, as assayed by DNase I protection, was inhibited by Cd2+ ion concentrations of > or = 0.1 microM. Aluminum ions were also found to inhibit the TFIIIA-5S RNA gene interaction, albeit at higher concentrations (> or = 5 microM). Inhibition by either metal ion was not readily reversible. Other xenobiotic metal ions, such as mercury or cesium, were not found to be inhibitory under these conditions. None of these ions at the concentrations used in this study affected the ability of DNase I to digest DNA or restriction enzymes to specifically cleave DNA. Preincubation of TFIIIA bound to 5S RNA with either Cd2+ or Al3+ resulted in subsequent DNA binding upon dilution and RNA removal, whereas preincubation of free TFIIIA with the metal ions resulted in inhibition of subsequent DNA binding. Because 5S rRNA also binds the TFIIIA zinc finger domains, these results indicate that the 5S RNA bound to TFIIIA protects the protein from metal inhibition and implicates the zinc fingers in the inhibition mechanism. The nature of the footprint inhibition indicates that the N-terminal fingers of TFIIIA are affected by the metal ions. Cd2+ and Al3+ ions also inhibited the ability of TFIIIA to bind complementary single-stranded DNA and promote renaturation, as measured by Tris-phosphate agarose gel electrophoresis. This gel assay is sensitive to DNA conformation and Al3+ ions were found to alter the conformation of single- and double-stranded DNA in this assay. The inhibition of TFIIIA function in vitro by xenobiotic metals offers new insights into the structure and function of TFIIIA and TFIIIA-type zinc finger proteins. Inhibition by Cd2+ occurs at much lower concentrations than previously observed with steroid hormone receptors and suggests that Cys2His2 zinc finger proteins may be especially sensitive to such agents in vivo.

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.