Saccharomyces cerevisiae SSB1 protein and its relationship to nucleolar RNA-binding proteins.

To better define the function of Saccharomyces cerevisiae SSB1, an abundant single-stranded nucleic acid-binding protein, we determined the nucleotide sequence of the SSB1 gene and compared it with those of other proteins of known function. The amino acid sequence contains 293 amino acid residues and has an Mr of 32,853. There are several stretches of sequence characteristic of other eucaryotic single-stranded nucleic acid-binding proteins. At the amino terminus, residues 39 to 54 are highly homologous to a peptide in calf thymus UP1 and UP2 and a human heterogeneous nuclear ribonucleoprotein. Residues 125 to 162 constitute a fivefold tandem repeat of the sequence RGGFRG, the composition of which suggests a nucleic acid-binding site. Near the C terminus, residues 233 to 245 are homologous to several RNA-binding proteins. Of 18 C-terminal residues, 10 are acidic, a characteristic of the procaryotic single-stranded DNA-binding proteins and eucaryotic DNA- and RNA-binding proteins. In addition, examination of the subcellular distribution of SSB1 by immunofluorescence microscopy indicated that SSB1 is a nuclear protein, predominantly located in the nucleolus. Sequence homologies and the nucleolar localization make it likely that SSB1 functions in RNA metabolism in vivo, although an additional role in DNA metabolism cannot be excluded.     

Correlated alternative side chain conformations in the RNA-recognition motif of heterogeneous nuclear ribonucleoprotein A1

The RNA-recognition motif (RRM) is a common and evolutionarily conserved RNA-binding module. Crystallographic and solution structural studies have shown that RRMs adopt a compact α/β structure, in which four antiparallel β-strands form the major RNA-binding surface. Conserved aromatic residues in the RRM are located on the surface of the β-sheet and are important for RNA binding. To further our understanding of the structural basis of RRM-nucleic acid interaction, we carried out a high resolution analysis of UP1, the N-terminal, two-RRM domain of heterogeneous nuclear ribonucleoprotein A1 (hnRNP A1), whose structure was previously solved at 1.75–1.9 Å resolution. The two RRMs of hnRNP A1 are closely related but have distinct functions in regulating alternative pre-mRNA splice site selection. Our present 1.1 Å resolution crystal structure reveals that two conserved solvent-exposed phenylalanines in the first RRM have alternative side chain conformations. These conformations are spatially correlated, as the individual amino acids cannot adopt each of the observed conformations independently. These phenylalanines are critical for nucleic acid binding and the observed alternative side chain conformations may serve as a mechanism for regulating nucleic acid binding by RRM-containing proteins.     

Mammalian heterogeneous nuclear ribonucleoprotein A1. Nucleic acid binding properties of the COOH-terminal domain

A1 is a core protein of the eukaryotic heterogeneous nuclear ribonucleoprotein complex and is under study here as a prototype single-stranded nucleic acid-binding protein. A1 is a two-domain protein, NH2-terminal and COOH-terminal, with highly conserved primary structure among vertebrate homologues sequenced to date. It is well documented that the NH2-terminal domain has single-stranded DNA and RNA binding activity. We prepared a proteolytic fragment of rat A1 representing the COOH-terminal one-third of the intact protein, the region previously termed COOH-terminal domain. This purified fragment of 133 amino acids binds to DNA and also binds tightly to the fluorescent reporter poly(ethenoadenylate), which is used to access binding parameters. In solution with 0.41 M NaCl, the equilibrium constant is similar to that observed with A1 itself, and binding is cooperative. The purified COOH-terminal fragment can be photochemically cross-linked to bound nucleic acid, confirming that COOH-terminal fragment residues are in close contact with the polynucleotide lattice. These binding results with isolated COOH-terminal fragment indicate that the COOH-terminal domain in intact A1 can contribute directly to binding properties. Contact between both COOH-terminal domain and NH2-terminal domain residues in an intact A1:poly(8-azidoadenylate) complex was confirmed by photochemical cross-linking.     

High pressure liquid chromatography purification of UP1 and UP2, two related single-stranded nucleic acid-binding proteins from calf thymus

Two single-stranded nucleic acid-binding proteins, UP1 and UP2, that were originally reported by Herrick and Alberts (Herrick, G., and Alberts, B. (1976) J. Biol. Chem. 251, 2124-2132) have been purified to apparent homogeneity from calf thymus by high performance liquid chromatography. The amino acid sequence of UP1 (Williams, K. R., Stone, K. L., LoPresti, M. B., Merrill, B. M., and Planck, S. R. (1985) Proc. Natl. Acad. Sci. U. S. A. 82, 5666-5670) reveals that UP1 contains 195 amino acids, including one dimethylarginine residue near its COOH terminus. Further analysis of this sequence now demonstrates that UP1 contains a 91-residue internal repeat such that when residues 3-93 (the "A" region) are aligned with residues 94-194 (the "B" region), 32% of the amino acids in these two regions are identical and an additional 39% of those changes that are seen could be accomplished by single base changes. The high degree of internal homology between residues 51-61 and 143-152 and in particular the high density of aromatic and positively charged amino acids in these two regions suggest that residues 51-61 and 143-152 may constitute two independent DNA-binding sites. Solid-phase sequencing of three tryptic peptides that together account for 9% of the 39,500-dalton UP2 protein demonstrate that there is a high degree of sequence homology between UP1 and UP2. Of the 34 residues that have been sequenced in UP2, 44% are identical in both UP1 and UP2. The blocked NH2 terminus, amino acid composition, particularly with regard to its high glycine content and the presence of dimethylarginine, and molecular weight of UP2 suggest this protein is related to proteins that have previously been found associated with heterogeneous RNA. Taken together, these data indicate that both UP1 and UP2 belong to a new family of single-stranded nucleic acid-binding proteins that may be closely related to heterogeneous ribonucleoproteins.     

Photochemical cross-linking of the Escherichia coli single-stranded DNA-binding protein to oligodeoxynucleotides. Identification of phenylalanine 60 as the site of cross-linking

The single-stranded DNA-binding proteins from bacteriophage T4, F plasmid, Escherichia coli, and calf thymus can all be covalently cross-linked in vitro to thymine oligonucleotides by irradiating the respective protein-oligonucleotide complexes with ultraviolet light. More extensive studies on the E. coli single-stranded DNA-binding protein (SSB) indicate that this reaction is dependent upon both the length of the oligonucleotide and the dose of ultraviolet irradiation. Using anion-exchange and reverse-phase ion-pairing high-performance liquid chromatography we have isolated a specific cross-linked tryptic peptide comprising residues 57-62 of the SSB protein with the sequence valine-valine-leucine-phenylalanine-glycine-lysine. Solid-phase sequence analysis of the covalent [32P] p(dT)8-peptide complex indicates that phenylalanine 60 is the site of cross-linking. This amino acid is located within the general region of SSB (residues 1-115) that has previously been shown to contain the DNA-binding site (Williams, K. R., Spicer, E. K., LoPresti, M. B., Guggenheimer, R. A., and Chase, J. W. (1983) J. Biol. Chem. 258, 3346-3355). The high-performance liquid chromatography purification procedure we have devised to isolate cross-linked peptide-oligonucleotide complexes should be of general applicability and should facilitate future structure/function studies on other nucleic acid-binding proteins.     

Characterization of the nucleic acid binding region of adenovirus DNA binding protein by partial proteolysis and photochemical cross-linking.

The nucleic acid binding domain of the adenovirus type 2 (or type 5) DNA-binding protein (DBP) was characterized by using limited proteolysis and photochemical cross-linking. Three proteases were used to generate fragments of DBP which retained the ability to bind to single-stranded DNA. One fragment, a 35-kDa tryptic product, was partially sequenced and found to contain amino acid residues 153 to approximately 470. This fragment further defines the minimum region of the protein which is required for nucleic acid binding. The DNA binding pocket of DBP was defined by using ultraviolet irradiation to cross-link covalently the carboxyl-terminal portion of the protein to the oligonucleotide p(dT)14. Cross-linked complexes were digested with trypsin, and peptides which were associated with the oligonucleotide were isolated by anion-exchange and reverse-phase ion-pairing high performance liquid chromatography. Two DBP peptides comprised of residues 294-308 and 415-434 were isolated by this approach. Sequence analysis indicated that methionine 299 and phenylalanine 418 were probable sites of cross-linking between their respective peptides and the oligonucleotide; hence these residues may represent contact points between DBP and single-stranded DNA. Both residues are highly conserved and are near, but not identical to, regions of the protein implicated previously in DNA binding.     

Amino acid sequence of UP1, an hnRNP-derived single-stranded nucleic acid binding protein from calf thymus

The UP1 single-stranded nucleic acid binding protein from calf thymus (Herrick, G. & Alberts, B.M. (1976) J. Biol. Chem. 251, 2124-2132) has recently been shown to be a proteolytic fragment derived from the A1 heterogeneous nuclear ribonucleoprotein (hnRNP) (Pandolfo et al. (1985) Nucleic Acids Res. 13, 6577-6590). The NH2-terminus of the 22,162 dalton UP1 protein appears to be blocked, which suggests that UP1 represents the NH2-terminal two thirds of this 32,000 dalton hnRNP protein. The complete amino acid sequence for UP1 was derived from automated sequencing of peptides that were purified by HPLC from digests with trypsin, chymotrypsin, Staphylococcus aureus protease, endoproteinase Lys-C, and cyanogen bromide. Trichloroacetic acid precipitation followed by enzymatic digestion in 2 M urea proved to be the best approach for generating UP1 peptides. By carboxymethylating after, rather than before, digestion it was possible to avoid problems associated with the insolubility of the carboxymethylated UP1. All of the resulting peptides in amounts varying from 2 to 15 nmol were coupled to aminopolystyrene prior to solid-phase sequencing. Using these methods, no difficulties were encountered in assigning glutamic acid residues or in completely sequencing peptides that contained up to 25-30 residues. The relative ease with which the UP1 protein was sequenced, requiring only about a year to complete, and the comparatively modest amount of protein required, less than 5 mg, attests to the usefulness of water soluble carbodiimide coupling and solid-phase sequencing for determining the primary structures of proteins. In addition to serving as a basis for determining structural relationships among various mammalian single-stranded nucleic acid binding proteins, the amino acid sequence of UP1 reveals that the A1 hnRNP protein contains a region of internal sequence homology that apparently corresponds to two independent nucleic acid binding sites.     

Structure-based incorporation of 6-methyl-8-(2-deoxy-beta-ribofuranosyl)isoxanthopteridine into the human telomeric repeat DNA as a probe for UP1 binding and destabilization of G-tetrad structures

Heterogeneous ribonucleoprotein A1 (hnRNP A1) is an abundant nuclear protein that participates in RNA processing, alternative splicing, and chromosome maintenance. hnRNP A1 can be proteolyzed to unwinding protein (UP1), a 22.1-kDa protein that retains a high affinity for purine-rich single-stranded nucleic acids, including the human telomeric repeat (hTR) d(TTAGGG)n. Using the structure of UP1 bound to hTR as a guide, we have incorporated the fluorescent guanine analog 6-MI at one of two positions within the DNA to facilitate binding studies. One is where 6-MI remains stacked with an adjacent purine, and another is where it becomes fully unstacked upon UP1 binding. The structures of both modified oligonucleotides complexed to UP1 were determined by x-ray crystallography to validate the efficacy of our design, and 6-MI has proven to be an excellent reporter molecule for single-stranded nucleic acid interactions in positions where there is a change in stacking environment upon complex formation. We have shown that UP1 affinity for d(TTAGGG)2 is approximately 5 nm at 100 mm NaCl, pH 6.0, and our binding studies with d(TTAGG(6-MI)TTAGGG) show that binding is only modestly sensitive to salt and pH. UP1 also has a potent G-tetrad destabilizing activity that reduces the Tm of the hTR sequence d(TAGGGT)4 from 67.0 degrees C to 36.1 degrees C at physiological conditions (150 mm KCl, pH 7.0). Consistent with the structures determined by x-ray crystallography, UP1 is able to bind the hTR sequence in solution as a dimer and supports a model for hnRNP A1 binding to nucleic acids in arrays that may make a contiguous set of anti-parallel single-stranded nucleic acid binding clefts. These data suggest that seemingly disparate roles for hnRNP A1 in alternative splice site selection, RNA processing, RNA transport, and chromosome maintenance reflect its ability to bind a purine-rich consensus sequence (nYAGGn) and destabilize potentially deleterious G-tetrad structures.     

Human UP1 as a model for understanding purine recognition in the family of proteins containing the RNA recognition motif (RRM)

Heterogeneous ribonucleoprotein A1 (hnRNP A1) is a prototype for the family of eukaryotic RNA processing proteins containing the common RNA recognition motif (RRM). The region consisting of residues 1-195 of hnRNP A1 is referred to as UP1. This region has two RRMs and has a high affinity for both single-stranded RNA and the human telomeric repeat sequence d(TTAGGG)(n). We have used UP1's novel DNA binding to investigate how RRMs bind nucleic acid bases through their highly conserved RNP consensus sequences. Nine complexes of UP1 bound to modified telomeric repeats were investigated using equilibrium fluorescence binding and X-ray crystallography. In two of the complexes, alteration of a guanine to either 2-aminopurine or nebularine resulted in an increase in K(d) from 88nM to 209nM and 316nM, respectively. The loss of these orienting interactions between UP1 and the substituted base allows it to flip between syn and anti conformations. Substitution of the same base with 7-deaza-guanine preserves the O6/N1 contacts but still increases the K(d) to 296nM and suggests that it is not simply the loss of affinity that gives rise to the base mobility, but also the stereochemistry of the specific contact to O6. Although these studies provide details of UP1 interactions to nucleic acids, three general observations about RRMs are also evident: (1) as suggested by informatic studies, main-chain to base hydrogen bonding makes up an important aspect of ligand recognition (2) steric clashes generated by modification of a hydrogen bond donor-acceptor pair to a donor-donor pair are poorly tolerated and (3) a conserved lysine position proximal to RNP-2 (K(106)-IFVGGI) orients the purine to allow stereochemical discrimination between adenine and guanine based on the 6-position. This single interaction is well-conserved in known RRM structures and appears to be a broad indicator for purine preference in the larger family of RRM proteins.     

Mass spectrometric analysis of a UV-cross-linked protein-DNA complex: tryptophans 54 and 88 of E. coli SSB cross-link to DNA

Protein-nucleic acid complexes are commonly studied by photochemical cross-linking. UV-induced cross-linking of protein to nucleic acid may be followed by structural analysis of the conjugated protein to localize the cross-linked amino acids and thereby identify the nucleic acid binding site. Mass spectrometry is becoming increasingly popular for characterization of purified peptide-nucleic acid heteroconjugates derived from UV cross-linked protein-nucleic acid complexes. The efficiency of mass spectrometry-based methods is, however, hampered by the contrasting physico-chemical properties of nucleic acid and peptide entities present in such heteroconjugates. Sample preparation of the peptide-nucleic acid heteroconjugates is, therefore, a crucial step in any mass spectrometry-based analytical procedure. This study demonstrates the performance of four different MS-based strategies to characterize E. coli single-stranded DNA binding protein (SSB) that was UV-cross-linked to a 5-iodouracil containing DNA oligomer. Two methods were optimized to circumvent the need for standard liquid chromatography and gel electrophoresis, thereby dramatically increasing the overall sensitivity of the analysis. Enzymatic degradation of protein and oligonucleotide was combined with miniaturized sample preparation methods for enrichment and desalting of cross-linked peptide-nucleic acid heteroconjugates from complex mixtures prior to mass spectrometric analysis. Detailed characterization of the peptidic component of two different peptide-DNA heteroconjugates was accomplished by matrix-assisted laser desorption/ionization mass spectrometry and allowed assignment of tryptophan-54 and tryptophan-88 as candidate cross-linked residues. Sequencing of those peptide-DNA heteroconjugates by nanoelectrospray quadrupole time-of-flight tandem mass spectrometry identified tryptophan-54 and tryptophan-88 as the sites of cross-linking. Although the UV-cross-linking yield of the protein-DNA complex did not exceed 15%, less than 100 pmole of SSB protein was required for detailed structural analysis by mass spectrometry.     

Identification of amino acid residues at the interface of a bacteriophage T4 regA protein-nucleic acid complex.

The bacteriophage T4 regA protein (M(r) = 14,6000) is a translational repressor of a group of T4 early mRNAs. To identify a domain of regA protein that is involved in nucleic acid binding, ultraviolet light was used to photochemically cross-link regA protein to [32P]p(dT)16. The cross-linked complex was subsequently digested with trypsin, and peptides were purified using anion exchange high performance liquid chromatography. Two tryptic peptides cross-linked to [32P]p(dT)16 were isolated. Gas-phase sequencing of the major cross-linked peptide yielded the following sequence: VISXKQKHEWK, which corresponds to residues 103-113 of regA protein. Phenylalanine 106 was identified as the site of cross-linking, thus placing this residue at the interface of the regA protein-p(dT)16 complex. The minor cross-linked peptide corresponded to residues 31-41, and the site of cross-linking in the peptide was tentatively assigned to Cys-36. The nucleic acid binding domain of regA protein was further examined by chemical cleavage of regA protein into six peptides using CNBr. Peptide CN6, which extends from residue 95 to 122, retains both the ability to be cross-linked to [32P]p(dT)16 and 70% of the nonspecific binding energy of the intact protein. However, peptide CN6 does not exhibit the binding specificity of the intact protein. Three of the other individual CNBr peptides have no measurable affinity for nucleic acid, as assayed by photo-cross-linking or gel mobility shifts.     

Physical studies of tyrosine and tryptophan residues in mammalian A1 heterogeneous nuclear ribonucleoprotein. Support for a segmented structure.

The mammalian heterogeneous ribonucleoprotein (hnRNP) A1 and its constituent N-terminal domain, termed UP1, have been studied by steady-state and dynamic fluorimetry, as well as phosphorescence and optically detected magnetic resonance (ODMR) spectroscopy at cryogenic temperatures. The results of these diverse techniques coincide in assigning the site of the single tryptophan residue of A1, located in the UP1 domain, to a partially solvent-exposed site distal to the protein's nucleic acid binding surface. In contrast, tyrosine fluorescence is significantly perturbed when either protein associates with single-stranded polynucleotides. Tyr to Trp energy transfer at the singlet level is found for both UP1 and A1 proteins. Single-stranded polynucleotide binding induces a quenching of their intrinsic fluorescence emission, which can be attributed to a significant reduction (greater than 50%) of the Tyr contribution, while Trp emission is only quenched by approximately 15%. Tyrosine quenching effects of similar magnitude are seen upon polynucleotide binding by either UP1 (1 Trp, 4 Tyr) or A1 (1 Trp, 12 Tyr), strongly suggesting that Tyr residues in both the N-terminal and C-terminal domain of A1 are involved in the binding process. Tyr phosphorescence emission was strongly quenched in the complexes of UP1 with various polynucleotides, and was attributed to triplet state energy transfer to nucleic acid bases located in the close vicinity of the fluorophore. These results are consistent with stacking of the tyrosine residues with the nucleic acid bases. While the UP1 Tyr phosphorescence lifetime is drastically shortened in the polynucleotide complex, no change of phosphorescence emission maximum, phosphorescence decay lifetime or ODMR transition frequencies were observed for the single Trp residue. The results of dynamic anisotropy measurements of the Trp fluorescence have been interpreted as indicative of significant internal flexibility in both UP1 and A1, suggesting a flexible linkage connecting the two sub-domains in UP1. Theoretical calculations based on amino acid sequence for chain flexibility and other secondary structural parameters are consistent with this observation, and suggest that flexible linkages between sub-domains may exist in other RNA binding proteins. While the dynamic anisotropy data are consistent with simultaneous binding of both the C-terminal and the N-terminal domains to the nucleic acid lattice, no evidence for simultaneous binding of both UP1 sub-domains was found.     

Laser cross-linking of nucleic acids to proteins. Methodology and first applications to the phage T4 DNA replication system

Single-pulse (approximately 8 ns) ultraviolet laser excitation of protein-nucleic acid complexes can result in efficient and rapid covalent cross-linking of proteins to nucleic acids. The reaction produces no nucleic acid-nucleic acid or protein-protein cross-links, and no nucleic acid degradation. The efficiency of cross-linking is dependent on the wavelength of the exciting radiation, on the nucleotide composition of the nucleic acid, and on the total photon flux. The yield of cross-links/laser pulse is largest between 245 and 280 nm; cross-links are obtained with far UV photons (200-240 nm) as well, but in this range appreciable protein degradation is also observed. The method has been calibrated using the phage T4-coded gene 32 (single-stranded DNA-binding) protein interaction with oligonucleotides, for which binding constants have been measured previously by standard physical chemical methods (Kowalczykowski, S. C., Lonberg, N., Newport, J. W., and von Hippel, P. H. (1981) J. Mol. Biol. 145, 75-104). Photoactivation occurs primarily through the nucleotide residues of DNA and RNA at excitation wavelengths greater than 245 nm, with reaction through thymidine being greatly favored. The nucleotide residues may be ranked in order of decreasing photoreactivity as: dT much greater than dC greater than rU greater than rC, dA, dG. Cross-linking appears to be a single-photon process and occurs through single nucleotide (dT) residues; pyrimidine dimer formation is not involved. Preliminary studies of the individual proteins of the five-protein T4 DNA replication complex show that gene 43 protein (polymerase), gene 32 protein, and gene 44 and 45 (polymerase accessory) proteins all make contact with DNA, and can be cross-linked to it, whereas gene 62 (polymerase accessory) protein cannot. A survey of other nucleic acid-binding proteins has shown that E. coli RNA polymerase, DNA polymerase I, and rho protein can all be cross-linked to various nucleic acids by the laser technique. The potential uses of this procedure in probing protein-nucleic acid interactions are discussed.     

Mechanistic studies of ribonucleic acid renaturation by a helix-destabilizing protein

The ability of a nucleic acid helix-destabilizing protein from calf thymus, UP1, to facilitate renaturation of yeast tRNALeu3 and Escherichia coli 5S RNA is shown to be a consequence of the protein's ability to bind stoichiometrically to single-stranded polynucleotide regions. A comparison of the inhibitory effect of different homopolymers on UP1-induced renaturation of tRNALeu3 does not indicate significant base specificity in UP1 binding, and a 3'-5' ribose phosphate polymer devoid of heterocyclic bases inhibits as well as the homopolynucleotides. These inhibition studies also show that UP1 requires polynucleotide segments of at least three phosphate residues to bind. Mg2+ (which is required for the stabilization of native tRNALeu3) dissociates complexes of UP1 with inactive tRNA, and since the RNAs in those complexes lack a substantial amount of secondary structure, it can upon dissociation readily refold into the native structure. A semiquantitative treatment of UP1-RNA interaction is developed that suggests that only a small number (approximately six) of protein molecules are bound to tRNALeu3 in the complex while analysis of the inhibition studies suggests that these UP1 molecules are not bound in a highly cooperative manner.     

The aromatic residue content of the enzyme rhodanese.

The aromatic amino acid composition of the enzyme rhodanese has been redetermined. Previous reports have varied from 5 to 11 tryptophans per 26 alanine residues. The present work has quantitated the aromatic residues by a combination of amino acid analysis, solvent perturbation difference spectroscopy, specific residue modification and direct ultraviolet spectral analysis. These methods indicate that rhodanese contains 10 tyrosines, eight tryptophans and 16 phenylalanines per 26 alanine residues. The results for tyrosine and phenylalanine are in reasonable agreement with previous results.     

Physical studies of the interaction of a calf thymus helix-destablizing protein with nucleic acids

UP1, a calf thymus protein that destabilizes both DNA and RNA helices, dramatically accelerates the conversion of the inactive conformers of several small RNA molecules to their biologically active forms [Karpel, R. L., Swistel, D. G., Miller, N. S., Geroch, M. E., Lu, C., & Fresco, J. R. (1974) Brookhaven Symp. Biol. 26, 165-174]. Using circular dichroic and spectrophotometric methods, we have studied the interaction of this protein with a variety of synthetic polynucleotides and yeast tRNA3Leu. As judged by perturbations in polynucleotide ellipticity or ultraviolet absorbance, the secondary structures of the single-stranded helices poly(A) and poly(C), as well as the double-stranded helices poly[d(A-T)] and poly(U.U), are largely destroyed upon interaction with UP1 at low ionic strength. This effect can be reversed by an increase in [Na+]: half the UP1-induced perturbation of the poly(A) CD spectrum is removed at 0.05 M Na+. The variation of poly(A) ellipticity and ultraviolet absorbance with [UP1]/[poly(A)]p is used to determine the length of single-stranded polynucleotide chain covered by the protein: 7 +/- 1 residues. A model is presented in which the specificity of UP1 for single strands and their concomitant distortion are a consequence of maximal binding of nucleic acid phosphates to a unique matrix of basic residues on the protein. Analogous to the effect on polynucleotides, UP1-facilitated renaturation of yeast tRNA3Leu follows the partial destruction of the inactive tRNA's secondary structure. At the tRNA absorbance maximum, UP1 effects a hyperchromic change of 10%, representing one-third of the secondary structure of the inactive conformer. This change is also clearly observable as a perturbation of the tRNA's circular dichroism spectrum.