Protein folding coupled to DNA binding in the catalytic domain of bacteriophage {lambda} integrase detected by mass spectrometry

doi:10.1110/ps.0234303

FOR THE RECORD

Protein folding coupled to DNA binding in the catalytic domain of bacteriophage ${lambda}$ integrase detected by mass spectrometry

Hari B. Kamadurai¹, Srisunder Subramaniam¹, R. Benjamin Jones², Kari B. Green-Church² and Mark P. Foster¹

¹ Department of Biochemistry and Biophysics Program, The Ohio State University, Columbus, Ohio 43210, USA
² CCIC/Mass Spectrometry and Proteomics Facility, The Ohio State University, Columbus, Ohio 43210, USA

Reprint requests to: Mark P. Foster, Department of Biochemistry, The Ohio State University, Columbus, OH 43210, USA; e-mail: foster.281{at}osu.edu; fax: (614) 292-6773.

(RECEIVED October 1, 2002; FINAL REVISION December 6, 2002; ACCEPTED December 6, 2002)

Article and publication are at http://www.proteinscience.org/cgi/doi/10.1110/ps.0234303.

Abstract

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Abstract
Introduction
Results and discussion
Conclusion
Materials and methods
References

Bacteriophage ${lambda}$ integrase ( ${lambda}$ -Int) is the prototypical member ofa large family of enzymes that catalyze site-specific DNA recombinationvia single-strand cleavage and the formation of a Holliday junctionintermediate. Crystallographic and biochemical evidence indicatethat substantial conformational change (i.e., folding) in thecatalytic domain of the protein is required for substrate recognitionand catalysis. We have examined the solution conformation ofthe catalytic domain (C170) in the absence and presence of acognate "half-site" DNA oligonucleotide by electrospray ionizationmass spectrometry, and circular dichroism and fluorescence spectroscopy.The distribution of ions in the positive ion electrospray massspectrum of the free protein reveals the presence of three distinctspecies in solution, one corresponding to the folded protein,one to the unfolded protein, and one to a dimer. In the presenceof DNA, ions are observed only for the protein–DNA complexand the folded form of the free protein. We therefore concludethat DNA binding stabilizes the global fold of the protein ina manner that is consistent with folding-coupled target recognitionas a mechanism to control site-specific recombination. Furthermore,we find that inspection of the charge state distribution ofions in electrospray mass spectra provides a quick and effectivemeans to identify conformational heterogeneity of proteins insolution and to investigate dynamic protein–nucleic acidinteractions.

Keywords: DNA binding protein; mass spectrometry; binding-induced folding; charge state distribution; ${lambda}$ integrase; C170

Introduction

TOP
Abstract
Introduction
Results and discussion
Conclusion
Materials and methods
References

Bacteriophage ${lambda}$ integrase ( ${lambda}$ -Int) is the prototypical member ofa large family of enzymes that catalyze site-specific DNA recombinationvia single-strand cleavage and the formation of a Holliday junctionintermediate (Argos et al. 1986; Landy 1989; Nunes-Duby et al. 1998).The crystal structure of C170-Y342F, a mutant of thecatalytic domain of ${lambda}$ -Int in which the catalytic tyrosine nucleophilehas been replaced by phenylalanine (Kwon et al. 1997; Tirumalai et al. 1997),revealed no density for a portion of the activesite that had been proposed to be flexible based on proteolyticsusceptibility (Tirumalai et al. 1997). Indeed, the structureimplied that, in the absence of its substrate, the tyrosinenucleophile, adjacent to this disordered region, was locatedfar (>18 Å) from the other conserved catalytic residues(Kwon et al. 1997). This arrangement and the implied flexibilityindicated that, in order to form an intact active site, thatportion of the protein must undergo substantial conformationalchanges (i.e., folding) on binding to a DNA substrate. An appealingaspect of the dynamic behavior of the protein is that via folding-coupledrecognition of its cognate sequence (Spolar and Record 1994),it could achieve an important degree of control over the recombinationreaction (Landy 1989; Kwon et al. 1997). Furthermore, proteindynamics could accommodate the paradoxically observed mechanisticduality in which protein active sites are entirely composedof residues from a single monomer (cis) (Nunes-Duby et al. 1994),or in which the tyrosine nucleophile is provided by a neighboringprotein in the Holliday junction complex (trans) (Han et al. 1993).

However, high-resolution structures of ${lambda}$ -Int in complex withits DNA substrate and/or a recombination intermediate are notavailable, leaving uncertain the nature of the necessary conformationalchanges. In our laboratory, NMR structural studies of the catalyticdomain of ${lambda}$ -Int in complex with its DNA substrate have been complicatedby exchange broadening: Although the catalytic domain is capableof performing sequence-specific DNA cleavage, its affinity forits substrate is low (>1 µM; Tirumalai et al. 1998;S. Subramaniam and M. Foster, unpubl.) and thus, under normalsolution conditions, C170 is in dynamic exchange between thefree and bound states. Consequently, the very dynamic processesthat are of most interest for understanding the protein’sfunction in substrate binding, dissociation and cleavage, havemade their detailed investigation by NMR extremely difficult.

Because of its gentle ionization process, electrospray ionizationmass spectrometry (ESI-MS) has emerged as a useful tool to studyboth changes in the three-dimensional conformational statesof proteins and their interactions with ligands (for reviews,see Loo 1997; Last and Robinson 1999; Veenstra 1999; Hernandez and Robinson 2001).In particular, when combined with limitedproteolysis and measurement of hydrogen/deuterium (H/D) exchangerates, MS can provide detailed insights into the dynamics oflocal binding and/or folding events. Although very powerful,performing these H/D exchange experiments by MS requires substantialamounts of sample, significant expertise, and nonroutine accessto instrumentation.

However, valuable insights into the solution structure of proteinscan be readily obtained from analysis of their ESI pattern involatile buffers. For instance, changes in the distributionof ions in ESI-MS have been used to study pH and temperaturedenaturation of cytochrome C and ubiquitin (Chowdhury et al. 1990;Mirza et al. 1993), methanol-induced denaturation of myoglobin(Babu and Douglas 2000), assembly of the MtGimC chaperone complex(Fandrich et al. 2000), DNA binding by the gene V, trp repressorand Tus proteins (Cheng et al. 1996; Potier et al. 1998; Kapur et al. 2002),and to identify unfolded species and monomericintermediates in the assembly of the dimeric DNA binding proteinHU (Vis et al. 1998). We report here the results of ESI-MS andspectroscopic experiments to study DNA binding by the catalyticdomain of ${lambda}$ -Int (C170). Based on analysis of the charge statedistribution of protein ions obtained in the presence and absenceof DNA, we conclude that the latter stabilizes a more compact,folded tertiary structure for the protein. Such behavior isconsistent with a role for binding-coupled protein folding asa mechanism to control recognition and catalysis.

Results and discussion

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Abstract
Introduction
Results and discussion
Conclusion
Materials and methods
References

ESI-MS of free C170
Positive ion ESI of proteins produces spectra containing ionsthat differ by charge and the mass of the added protons, distributedover an approximately Gaussian envelope (Fenn 1993; Siuzdak 1996;Dobo and Kaltashov 2001). The width and center of thisdistribution depend on the tertiary structure of the ionizingmolecule in solution: Protein molecules that have been denaturedprior to ionization give rise to a broad distribution of highlycharged ions (low m/z), reflecting the accessibility of multipleprotonation sites on the molecule (Chowdhury et al. 1990; Loo et al. 1991;Mirza and Chait 1997). Folded proteins, on theother hand, have fewer accessible sites of protonation and thereforeproduce ESI spectra that exhibit a narrow distribution of chargestates at higher m/z (Chowdhury et al. 1990; Mirza and Chait 1997;Vis et al. 1998).

The molecular weight of the C170 protein (residues 170–356of ${lambda}$ -Int) is 21,119 Da. The multiply-charged ions in the ESImass spectrum of C170 recorded in the absence of DNA that matchthose expected for multiple protonation of the protein are indicatedwith boxes in Figure 1 (top). At least three species of ionsare observed in the spectrum. The most abundant of these isa narrow distribution, with a maximum centered at the 10+ chargestate (M+10H)¹⁰⁺, which is characteristic of that expected fora compact folded protein. Abundant ions were observed with m/zof 1920.6, 2112.1, and 2345.6 (1920.9, 2112.9, and 2347.6 expected),corresponding to charge states of 11+, 10+, and 9+, respectively.In addition, two other significant populations of ions are observed.The first of these is a broad distribution of more highly chargedspecies of C170 (ranging from 17+ to 12+: m/z of 1243.5, 1319.2,1409.2, 1509.7, 1625.9, and 1761.2); this broad distributionand higher charge are consistent with that observed from ionizationof denatured proteins. Evidence that these ions correspond tothe (partially) unfolded protein was obtained by recording ESI-MSof C170 under denaturing conditions (Fig. 1, inset).

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Figure 1. Electrospray mass spectra of C170 in the absence (top) and presence (bottom) of a half-site DNA substrate. The ions corresponding to the indicated protonated charge states (M + nH)⁺ⁿ of the free protein (M_r 21,119) are indicated with filled squares, the dimeric C170 (M_r 42,238) with open squares, and the C170–DNA complex (M_r 21,119 + 12,286 = 33,405) with asterisks. Ions marked with an "x" are from a minor contaminant. The spectrum of the free protein (top) exhibits a bimodal distribution of charge states, one corresponding to the folded protein (centered at the 10+ state), and a broader distribution at lower m/z (higher charge) centered at $~$ 15+; these signals result from ionization of unfolded or partially folded protein. The signals corresponding to the unfolded protein are absent in the spectra recorded in the presence of DNA (bottom). The presence of ions corresponding to dimeric C170 indicates that the protein is at least partially dimerized/oligomerized in solution. The spectrum of acid-denatured C170 is shown in the inset, exhibiting the characteristic broad distribution of highly charged species.

The third significant distribution of ions (open boxes in Fig.1

) corresponds to the mass of the dimeric protein (2 x 21,119Da = 42,238 Da). Ions from a protein dimer that bear an evencharge will overlap those of the monomer with half the charge:m/z = (M₂+2nH)²ⁿ⁺ = (M+nH)ⁿ⁺. However, dimer ions bearing anodd charge are readily identified because they appear in a seriesbetween those of the protein monomer. Thus, unique (odd-charge)ions matching the protein dimer are observed at m/z of 2223.2,2483.1, and 2809.7, corresponding to the 19+, 17+, and 15+ chargestates, respectively (m/z 2224.1, 2485.6, and 2816.9 expected).Although size exclusion chromatography indicates that the proteinis not predominantly dimeric in solution, dynamic light scatteringand NMR experiments (S. Subramaniam and M. Foster, unpubl.)reveal that at 500 µM concentrations the protein exhibitsa significantly larger effective mass than that expected forthe monomeric protein, indicating it may transiently dimerizein solution. At the concentrations of the experiments reportedhere (10–50 µM), nonspecific aggregation would notbe expected, suggesting that the ions reflect a real populationof dimeric species in solution. Because the enzyme functionsin vivo by assembling into a multimeric complex involving fourprotein molecules and two DNA strands, this observation couldhave mechanistic implications.

ESI-MS of C170 in the presence of DNA
Addition to C170 of a DNA hairpin containing a consensus half-site(Nunes-Duby et al. 1989) results in two significant changesin the ESI mass spectrum (Fig. 1, bottom). In particular, anew set of broad signals corresponding to ions from the intactprotein–DNA complex (M_r 21,119 + 12,286 = 33,405) areobserved at 12+ through 10+ charge states (m/z 2748, 3016, and3325 observed; 2785, 3038, and 3342 expected); these ions arebroadened because of the tight binding of trace amounts of cationsto the anionic DNA (Siuzdak 1996; Crain and McCloskey 1998).These ions reflect the association and joint ionization of theintact protein–DNA complex. Thus, despite the relativelylow affinity of the protein for the DNA substrate (>1 µM),the complex is observed in the mass spectrum, confirming theexpected 1:1 stoichiometry of the interaction.

However, the most interesting observation was that, in the presenceof DNA, the signals derived from ionization of the free proteinexhibit only the narrow distribution of charge states expectedfor the folded protein (centered at 10+). This result is consistentwith stabilization of the folded form of the protein by DNA,thereby preventing it from unfolding. Because most of the ionsobserved in the presence of DNA correspond to the mass of thefree protein, we suggest that the DNA may be serving as a sortof "chaperone" in that it interacts transiently with the proteinin a manner that stabilizes the folded structure. Stabilizationof a protein structure by its interaction with nucleic acidshas been observed for many nucleic acid binding proteins, includingzinc finger proteins (Foster et al. 1997), the architecturaltranscription factor Lef-1 (Love et al. 1995), and the trp (Arrowsmith et al. 1991;Potier et al. 1998) and lac repressors (Kalodimos et al. 2002).Such "induced fit" binding has been argued toplay an important role in sequence-specific recognition (Spolar and Record 1994)and in ${lambda}$ -Int could play a role in controllingthe recombination (Landy 1989; Kwon et al. 1997).

Circular dichroism (CD)
The effect of DNA on the solution structure of C170 was alsoinvestigated by far UV CD under identical conditions as theMS experiments (Fig. 2). The CD spectrum of C170 recorded inthe presence of 1:1 DNA reveals a measurable and reproducibleincrease in ellipticity at 222 nm, consistent with stabilizationof the protein’s helical secondary structure by DNA. Noadditional changes in the protein CD spectrum are observed atDNA stoichiometries greater than 1:1. Although far UV CD isonly sensitive to changes in secondary structure, whereas ESI-MSis sensitive to tertiary structure, both measurements are consistentwith stabilization of the protein fold by DNA.

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Figure 2. Circular dichroism spectra of the catalytic domain of ${lambda}$ -Int (C170) recorded in the absence (filled circles) and presence (open circles) of a (reversible) half-site DNA substrate. The increased ellipticity at 222 nm reflects a DNA-induced stabilization of ${alpha}$ -helical structure in the protein.

The apparent increased helicity is particularly interestingin the context of the available crystallographic data on ${lambda}$ -Intand related members of the tyrosine recombinase family. Namely,in addition to a conserved mechanism, each of these proteinsexhibits substantial topological homology at the tertiary andsecondary structural level (Fig. 3

; Nunes-Duby et al. 1998).However, among the family members whose structures have beendetermined, including Cre (Guo et al. 1997), XerD (Subramanya et al. 1997),HP1 (Hickman et al. 1997), and Flp (Chen et al. 2000), ${lambda}$ -Int differs in that its tyrosine nucleophile was observedto be located on a ß-hairpin adjacent to a disorderedloop (Kwon et al. 1997), whereas it is present on a helix inthe other family members (Fig. 3

). Further, the position ofthe nucleophile, far removed from the other conserved residues,indicated that, in order for C170 to initiate strand cleavage,dramatic structural rearrangements in the catalytic loop arerequired.

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Figure 3. Partial sequence alignment of ${lambda}$ -Int and related family members illustrating the sequence and secondary structure conservation. (Lambda) ${lambda}$ -Int (Kwon et al. 1997); (Cre) Cre recombinase (Guo et al. 1997); (HP1) bacteriophage HP1 integrase (Hickman et al. 1997); (Eco_xerD) Escherichia coli XerD recombinase (Subramanya et al. 1997). The secondary structure predicted for C170 by PHDSec (Rost et al. 1994) is indicated. Alignment is from Nunes-Duby et al. (1998) and the figure was generated using ESPript (Gouet et al. 1999). The numbering is according to the ${lambda}$ -Int sequence; His³⁰⁸ and Arg³¹¹ are two critical catalytic residues, whereas Tyr³⁴² is the nucleophile. The flexible loop observed in ${lambda}$ -Int (C170 Y342F) is a helix in the other family members.

Although the data presented here do not identify where in theprotein the helical structure has been stabilized, it is temptingto speculate that the increase in helical structure in C170reflects a conformational change that would enable it to recognizeand cleave its DNA substrate (Kwon et al. 1997; Tekle et al. 2002).It should be noted that the CD signature reflects anensemble average, so that it cannot distinguish between an increasein helicity for all of the protein molecules versus stabilizationof a population of (partially folded) molecules, whereas theESI-MS data indicate that there is indeed a population of speciesthat is less compact.

It is also possible that the protein is partially destabilizedin ammonium acetate buffer, as reported for the trp repressor(Potier et al. 1998). Indeed, although the CD spectrum recordedin ammonium acetate and phosphate buffer (50 mM sodium phosphateat pH 6.3, 100 mM NaCl, 1 mM dithiothreitol [DTT]) are indistinguishable,the tryptophan fluorescence spectrum recorded in ammonium acetatebuffer exhibits reduced emission intensity when compared withthat in phosphate (data not shown). Furthermore, as was seenin studies of the DNA binding protein HU (Vis et al. 1998),ESI mass spectra of C170 recorded in high concentrations ofammonium acetate (1 M) revealed only a single distribution ofcharges, corresponding to that of the folded protein (data notshown). Nevertheless, it is clear from the data in Figures 1and 2 that DNA does indeed stabilize the structure of C170.

Conclusion

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Abstract
Introduction
Results and discussion
Conclusion
Materials and methods
References

Ion suppression and interference from adducts generally precludesperforming ESI-MS experiments under physiological conditions(salts, nonvolatile buffers). However, the pioneering work ofseveral laboratories demonstrated that substantial insightsinto the native states of proteins and their noncovalent interactionswith ligands could be obtained by recording ESI-MS spectra involatile buffers (for reviews, see Loo 1997; Veenstra 1999;Hernandez and Robinson 2001).

The ESI-MS spectrum of C170 indicates that, in the absence ofDNA, three distinct species are present in solution: a folded,compact globular species; a partially unfolded conformation;and a dimeric species. On addition of a cognate DNA oligonucleotide,the unfolded species disappears, indicating that the compactspecies has been stabilized by its interaction with the DNA.The fact that relatively few ions are observed for the ionizedprotein–DNA complex could reflect the relatively weak(and transient) nature of the C170–DNA interaction, coupledwith the potential for dissociation during droplet formationand ion suppression due to the negative charge of the DNA phosphatebackbone or the effect of the cations on the spectrum.

Although the ESI spectra do not provide the same detailed levelof information obtainable from mass spectrometric measurementsof H/D exchange coupled with proteolytic digestion, they canidentify the presence of heterogeneous populations of proteinconformations in solution, are easy to perform, and requirevery little sample and only routine access to instrumentation.In addition, it is worth emphasizing that, unlike in aqueoussolution where hydrophobic effects dominate intermolecular interactions,electrostatic interactions are favored in the gas phase (Robinson et al. 1996).Thus, although it can be difficult in solutionto characterize interactions between molecules that bind transientlythrough electrostatic interactions, these interactions may beeasier to see in ESI-MS. In conclusion, we found that ESI-MSwas able to identify DNA-induced stabilization folding of C170,a protein that is in rapid exchange between a free, partiallydenatured state and a bound, folded state.

Materials and methods

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Abstract
Introduction
Results and discussion
Conclusion
Materials and methods
References

C170, the ${lambda}$ -Int catalytic domain
C170 consists of 187 residues (170–356) of the wild-type ${lambda}$ -Int enzyme. The amino acid sequence for the fragment is AAKSEVRRSRLTADEYLKIY QAAESSPCWL RLAMELAVVT GQRVGDLCEM KWSDIVDGYL YVEQSKTGVKIAIPTALHID ALGISMKETL DKCKEILGGE TIIASTRREP LSSGTVSRYF MRARKASGLSFEGDPPTFHE LRSLSARLYE KQISDKFAQH LLGHKSDTMA SQYRDDRGRE WDKIEIK.The recombinantly expressed protein additionally contains anamino-terminal methionine that is efficiently removed posttranslationallyby methionine amino peptidase in vivo, yielding a polypeptidewith an expected mass of 21,119 Da.

Expression of C170
The DNA plasmid encoding C170, the catalytic domain of ${lambda}$ -Int,under control of a T7 promoter, and carrying the gene for ampicillinresistance (Tirumalai et al. 1997, 1998), was provided by ArthurLandy (Brown University, Providence, RI). The C170 gene containseight instances of the rare AGA/AGG arginine codons, three ofwhich occur in the first 10 codons. The frequency of occurrenceof these codons implied that overexpression would be highlydependent on the availability of the corresponding rare tRNAs(Brinkmann et al. 1989; Zahn and Landy 1996). Consequently,the argU gene product (also known as dnaY), encoding an arginyltRNA that can decode these rare codons (Brinkmann et al. 1989;Saxena and Walker 1992), expressed on a vector encoding kanamycinresistance (pARG-U), was cotransformed into C170-expressingcells to boost protein production. C170 was overexpressed indoubly transformed BL21(DE3) cells grown in LB at 37°C inthe presence of 50 mg/L carbenicillin and 30 mg/L kanamycin.Cultures were induced with 1 mM IPTG at an OD₆₀₀ of 0.6 andwere grown for 8 h after induction. The cells were harvestedby centrifugation (5000 rpm, Sorvall SLA-3000 rotor, 10 min,4°C) and stored at -20°C until lysed.

Purification of C170 and preparation of samples for mass analysis
C170 was purified from cell pellets as described in (Tirumalai et al. 1998)except that the last step in the purification protocol(a hydroxylapatite column) was replaced with a size exclusioncolumn (Sephacryl SW-100 column, Pharmacia, 1 ml/min) in phosphatebuffer (50 mM sodium phosphate (pH 6.3), 0.1 mM EDTA, 1 mM DTTand 100 mM NaCl). For MS experiments, C170 was further exchangedinto ammonium acetate buffer (10 mM ammonium acetate (pH 6.3),1 mM DTT) using a size exclusion column (PD-10, Pharmacia).An acid-denatured sample (pH 3) was prepared by adjusting thepH of the protein solution with acetic acid.

Oligonucleotides
The sequence of the reversible hairpin DNA substrate is 5'-d(CGCTCA AGT TA*G TAT ACG CTT GCG TAT ACT AAC TTG AGC G)-'3, in whichthe consensus (B') recognition sequence (Nunes-Duby et al. 1989)is in italics, the site of cleavage is indicated by the asterisk,and the four-nucleotide hairpin is underlined. The molecularweight of the deoxyoligonucleotide hairpin is 12,286 Da. Thesynthetic oligonucleotide (Integrated DNA Technologies) wasdissolved in deionized water (Waters MilliQ, 18 ${Omega}$ ) to make upa stock concentration of 4.2 mM. To favor formation of the hairpinstructure, we diluted the stock with ammonium acetate buffer(pH 6.3), heated it to 95°C for 5 min, and cooled it onice for 15 min.

Protein–DNA complex
The C170 protein–DNA complex was assembled at room temperatureby incubating protein and DNA in equimolar ratios for 5 minin ammonium acetate buffer. The mixture was then injected directlyinto the mass analyzer. The protein concentration (8–50µM) was maintained constant while recording mass spectraof free protein and complex. The molecular weight of the C170–DNAcomplex is 21,119 + 12,286 = 33,405 Da.

Mass spectrometry
ESI experiments were performed on a Micromass Q-Tof(tm) II (Micromass)mass spectrometer equipped with an orthogonal electrospray source(Z-spray) operated in positive ion mode. Sodium iodide was usedfor mass calibration for a calibration range of m/z 100–2500.The capillary potential was set to 3000 V and the cone voltageto 85 V; cone temperature was set to 90°C; the ESI gas wasnitrogen. The charge-to-mass ratio of ions were scanned in therange of 1000 to 4000. Samples were infused into the electrospraysource at a rate of 10 µL/min. Mass measurements wereperformed at protein concentrations of 47 and 10 µM, andDNA concentrations of 27 and 10 µM, respectively.

Circular dichroism
CD measurements were performed on an AVIV model 62A DS spectropolarimeterat 25 °C in a 1-mm path-length cell. Protein samples were10 µM in 10 mM ammonium acetate buffer (pH 6.3) and 1mM DTT. The effect of DNA on the protein was obtained by subtractingthe CD spectrum from the free DNA in the same buffer. Experimentswere repeated at least three times, using either 1:1 or 2:1DNA:protein ratios. Titration curves could not be generatedbecause addition of DNA at low stoichiometry (<0.5:1 DNA:protein)resulted in irreversible protein precipitation.

Tryptophan fluorescence spectroscopy
The structural integrity of the C170 protein in ammonium acetatebuffer was examined by intrinsic tryptophan fluorescence emissionspectroscopy. Protein samples were 0.5 µM. Samples wereexcited at 295 nm (5 nm bandwidth) and the emission spectrumrecorded from 315 to 450 nm. Spectra were recorded at 25°Cusing a 1-cm path-length quartz cell using a FluoroMax-3 spectropolarimeter.Fluorescence spectra were also recorded at pH 3.0 to verifythat the MS data recorded at this pH corresponded to the unfoldedprotein.

Acknowledgments

We acknowledge A. Landy and S. Nunes-Duby (Brown University)for reagents and enlightening discussions; G. Suizdak (The ScrippsResearch Institute) and M. Freitas (OSU) for helpful suggestionsand assistance; and the ACS/Petroleum Research Fund, the NationalScience Foundation, The Ohio State University Research Foundation,and the Ohio Board of Regents for financial support.

The publication costs of this article were defrayed in partby payment of page charges. This article must therefore be herebymarked "advertisement" in accordance with 18 USC section 1734solely to indicate this fact.

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