Contribution of the dimeric state to the thermal stability of the flavoprotein D-amino acid oxidase

doi:10.1110/ps.0234603

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Contribution of the dimeric state to the thermal stability of the flavoprotein D-amino acid oxidase

Loredano Pollegioni¹, Stefania Iametti², Dimitrios Fessas³, Laura Caldinelli¹, Luciano Piubelli¹, Alberto Barbiroli³, Mirella S. Pilone¹ and Francesco Bonomi²

¹ Department of Structural and Functional Biology, University of Insubria, 21100 Varese, Italy
² Dipartimento di scienze molecolari agroalimentari (DISMA) and
³ Dipartimento di scienze e tecnologie alimentari e microbiologiche (DISTAM), University of Milan, 20133 Milan, Italy

Reprint requests to: Francesco Bonomi, DISMA, University of Milan, via Celoria 2, 20133 Milan, Italy; e-mail: francesco.bonomi{at}unimi.it; fax: 39-02-50316801.

(RECEIVED October 7, 2002; FINAL REVISION February 13, 2003; ACCEPTED February 17, 2003)

Supplemental material: See www.proteinscience.org.

Article and publication are at http://www.proteinscience.org/cgi/doi/10.1110/ps.0234603.

Abstract

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Abstract
Introduction
Results
Discussion
Materials and methods
References

The flavoenzyme DAAO from Rhodotorula gracilis, a structuralparadigm of the glutathione-reductase family of flavoproteins,is a stable homodimer with a flavin adenine dinucleotide (FAD)molecule tightly bound to each 40-kD subunit. In this work,the thermal unfolding of dimeric DAAO was compared with thatof two monomeric forms of the same protein: a ${Delta}$ loop mutant, inwhich 14 residues belonging to a loop connecting strands ßF5–ßF6have been deleted, and a monomer obtained by treating the nativeholoenzyme with 0.5 M NH₄SCN. Thiocyanate specifically and reversiblyaffects monomer association in wild-type DAAO by acting on hydrophobicresidues and on ionic pairs between the ßF5–ßF6loop of one monomer and the ${alpha}$ I3' and ${alpha}$ I3'' helices of the symmetry-relatedmonomer. By using circular dichroism spectroscopy, protein andflavin fluorescence, activity assays, and DSC, we demonstratedthat thermal unfolding involves (in order of increasing temperatures)loss of tertiary structure, followed by loss of some elementsof secondary structure, and by general unfolding of the proteinstructure that was concomitant to FAD release. Temperature stabilityof wild-type DAAO is related to the presence of a dimeric structurethat affects the stability of independent structural domains.The monomeric ${Delta}$ loop mutant is thermodynamically less stable thandimeric wild-type DAAO (with melting temperatures (T_ms) of 48°Cand 54°C, respectively). The absence of complications ensuingfrom association equilibria in the mutant ${Delta}$ loop DAAO allowedidentification of two energetic domains: a low-temperature energeticdomain related to unfolding of tertiary structure, and a high-temperatureenergetic domain related to loss of secondary structure elementsand to flavin release.

Keywords: Flavoprotein; lipophilic ions; folding; dimerization; energetic domains; structural domains; quaternary structure; thermal stability

Abbreviations: DAAO, D-amino acid oxidase (EC 1.4.3.3) • RgDAAO, Rhodotorula gracilis D-amino acid oxidase • DSC, differential scanning calorimetry • GR, glutathione reductase

Introduction

TOP
Abstract
Introduction
Results
Discussion
Materials and methods
References

Flavoproteins are a group of enzymes that catalyze a varietyof reactions and that are characterized by the presence of aflavin cofactor. Concerning the coenzyme binding, flavoproteinsdivide into three classes: those possessing the coenzyme covalentlylinked through the isoalloxazine ring to a histidine, cysteine,or tyrosine residue of the polypeptide chain (Decker 1991);those in which the flavin is noncovalently bound; and thosethat use flavin adenine dinucleotide (FAD) or flavin mononucleotide(FMN) as a substrate. In the first two flavoprotein classes,attainment of the catalytic activity requires binding of thecofactor to the apoprotein, which generally has a differentconformation from the holoenzyme (van Mierlo and Steensma 2000).

Cofactor binding is of paramount importance in vivo, becausemany flavoenzymes are nuclear encoded, synthesized as largerprecursors on free cytosolic ribosomes, and posttranslationallyimported into the final organelle. Many peroxisomal enzymes(such as DAAO) generate toxic hydrogen peroxide, and their activitybefore targeting could be extremely dangerous for the cell.On the other hand, loss of the coenzyme turns off the enzymeactivity and, because of the concomitant formation of an apoproteinform that frequently possesses a looser conformation and thusa lower stability, triggers its degradation.

A second important feature of flavoproteins concerns their quaternarystructure. They are often multisubunit proteins constitutedeither by identical or by different polypeptide chains. In somecases the multimeric organization is linked to the enzyme function.Detailed information on the relationships between cofactor uptake,folding, and intracellular trafficking is available only fora handful of well-characterized systems, such as yeast alcoholoxidase (Waterham et al. 1997). In general, less is known onthe role of the stable interaction between identical subunitsand on its significance for the apoprotein–FAD interactionsthat are relevant to biogenesis of a functional protein andto its turnover in the cell.

To gain insights into these important topics, we undertook astudy of the stability of structural elements in the peroxisomalflavoenzyme DAAO (EC 1.4.3.3 [EC] ) from the yeast Rhodotorula gracilis(RgDAAO). DAAO is considered the paradigm of the dehydrogenase-oxidaseclass of flavoproteins (Massey and Hemmerich 1980), is a componentof the GR folding family, and is a peroxisomal marker (for review,see Curti et al. 1992; Pilone 2000). DAAO catalyzes the oxidativedehydrogenation of D-isomers of amino acids to give ${alpha}$ -keto acids,ammonia, and hydrogen peroxide. Over the years, DAAOs have beenthe object of extensive investigation (Curti et al. 1992; Pilone 2000).RgDAAO in solution is a stable 80-kD homodimer, witha molecule of FAD tightly—but noncovalently—boundto each 40-kD subunit. The stable dimeric aggregation state,as well as the high catalytic activity and tight binding ofFAD to the apoprotein polypeptide, distinguishes the yeast enzymefrom mammalian DAAO. These features probably are the evolutionaryanswer of the different role of this flavoenzyme in higher andlower eukaryotes (Pilone 2000).

The tridimensional (3D) structure of RgDAAO has been resolvedat very high resolution, allowing researchers to find the rationalefor its high catalytic efficiency (Umhau et al. 2000; Pollegioni et al. 2002).Between the possible modes of monomer–monomerinteraction in the crystal, the one having the highest buriedsurface area (3049 Å²) is the "side-to-tail" model (Pollegioni et al. 2002).A large contribution to the interaction betweenmonomers in RgDAAO is given by a long (21 amino acids) loopconnecting ß-strands F5 and F6, which is unique toRgDAAO. Recently, by rational design and site-directed mutagenesis,a stable monomeric holoenzyme form of RgDAAO has been obtainedby partial elimination of the ßF5-ßF6 loop(Piubelli et al. 2002). The deleted portion (from Ser 308 toLys 321: SPLSLGRGSARAAK) contains three positively charged residuesand no aromatics.

The ${Delta}$ loop mutant RgDAAO shows slightly altered spectral and kineticproperties. The main differences with respect to the wild-typeenzyme are a lower stability at temperatures higher than 35°Cand a fivefold increase in the K_d for FAD binding. Conversionto a monomeric form from native RgDAAO can also be achievedby removal of the coenzyme to yield the corresponding apoprotein(Casalin et al. 1991). This indicates a structural relationshipbetween the FAD-harboring domain and the regions involved indimerization.

To provide a basis for understanding the structure–functionrelationships in flavoproteins and the determinants of theirstability, we have attempted to compare the unfolding of dimericDAAO with that of monomeric forms obtained either by site-directedmutagenesis or by chemical treatment. This was done with theultimate ambitious goal to improve current understanding ofthe correlations between protein folding, coenzyme binding,subunit interaction, and protein targeting. In particular, byusing a combination of calorimetric and spectroscopic methods,we aimed at discriminating among the steps involved in dimerdissociation and those related to the loss of the polypeptidestructure and of the FAD cofactor during thermal treatment ofthe different proteins. Direct comparison of the thermal stabilityof apo- versus holo- forms of RgDAAO was not feasible, becauseof the marked thermal instability of the apoproteins that aggregatein the course of prolonged exposure at high temperature, asrequired for temperature-ramp experiments and calorimetric studies.

Results

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Abstract
Introduction
Results
Discussion
Materials and methods
References

Effect of thiocyanate on the aggregation state of wild-type RgDAAO
Thiocyanate is a lipophilic ion (Ptistyn and Semisotnov 1991)that has the capacity to interfere with ionic pairs locatedeither on the protein surface or in the hydrophobic interiorof folded proteins. In such a way, lipophilic ions affect thetertiary and quaternary structures of proteins more selectivelythan most generic chaotropes, such as urea or guanidinium ions,which affect the hydrogen bond network in the solvent waterand in the proteins themselves.

The effect of NH₄SCN on the quaternary structure of wild-typeRgDAAO was investigated by means of size-exclusion chromatographyon a Superdex 200 column. The elution profile of wild-type RgDAAO(1 mg/mL) at different NH₄SCN concentrations is shown in Figure1. RgDAAO was present in a dimeric form in the absence of NH₄SCN,but at 0.5 M NH₄SCN it eluted as a single peak with a retentiontime corresponding to a monomeric form (44.2 ± 3.9 kD).This effect is peculiar to thiocyanate, because the elutionvolume of RgDAAO is not modified in the presence of 0.5 M NaClor NH₄Cl (not shown). The absorption spectrum of the enzymeeluted at 0.5 M NH₄SCN showed the visible bands at 450 nm and380 nm typical of FAD-containing enzymes. Its specific activitywas 95 U/mg protein (~110 U/mg for native RgDAAO) and was notaffected by the addition of exogenous FAD in the activity assay.However, prolonged incubation of the protein with NH₄SCN ata concentration $>=$ 0.5 M prior to the chromatographic separationresulted in decreased recovery of the protein and of its activity.Also, the electronic spectrum of RgDAAO was altered at thiocyanateconcentrations higher than 0.5 M, likely because of partialdenaturation (vide infra).

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Figure 1. Effect of NH₄SCN concentration on the quaternary structure of RgDAAO. RgDAAO (0.2 mL, 1 mg/mL) was incubated on ice in the presence of 0, 0.4, and 0.5 M NH₄SCN before gel permeation chromatography on a Superdex 200 column in 50 mM potassium phosphate (pH 7.5), 150 mM potassium chloride, and 10% glycerol. The elution buffer contained 0 (full line), 0.4 (dashes and dots), or 0.5 M (dots) NH₄SCN, according to the concentrations used in the treatment before the separation step. (DB) Dextran Blue.

Under appropriate conditions, the dimer–monomer conversionobserved at 0.5 M NH₄SCN was fully reversible both structurallyand functionally. The dimeric holoenzyme was fully recovered(as judged by gel permeation chromatography) when the NH₄SCNconcentration was slowly decreased by dilution of the monomericenzyme solution (from 0.5 M to 25 mM in about 16 h at 4°C).Protein recovery paralleled the activity recovery, that is,~65%. The addition of a competitive inhibitor such as crotonate(K_d = 0.35 mM; Pilone 2000) did not improve the recovery figures.The absorbance spectrum of the recovered dimeric DAAO was indistinguishablefrom that of the native enzyme. However, fast removal of NH₄SCNfrom the buffer (i.e., by desalting on a G25 column or by dialysis)resulted in protein and activity loss. This indicates that reacquiringa competent structure after treatment with NH₄SCN is not limitedthermodynamically but kinetically, and that the presence ofresidual NH₄SCN in the course of slow dilution favors the structuralrearrangements required to drive the refolding process towardrecovery of a native-like structure.

Effect of thiocyanate on the secondary and tertiary structure of wild-type and ${Delta}$ loop RgDAAO mutant
Far-UV circular dichroism (CD) spectra of the wild-type and ${Delta}$ loop mutant RgDAAO did not reveal any major difference in thefeatures related to the secondary structure of the two proteins(not shown), indicating that the loop deletion leading to lossof the dimeric state did not alter the content and the distributionof secondary structure elements. The very high background absorptionof 0.5 M NH₄SCN below 230 nm (higher than 3 absorbance unitseven with a 0.1-mm light path) prevented analysis of the secondarystructure modifications induced by NH₄SCN.

As shown in Figure 2, the near-UV CD spectra of the wild-typeand ${Delta}$ loop mutant RgDAAO in the absence of NH₄SCN were different.The differences may be ascribed to a different contributionfrom aromatic amino acid residues, which are responsible formost transitions in the near-UV spectral region. Because thedeleted portion does not contain aromatic residues, the differentspectroscopic features of the two proteins can only be explainedin terms of altered mutual relationships between nearby structuralelements. The addition of thiocyanate affected the tertiarystructure of both wild-type and ${Delta}$ loop mutant RgDAAO, althoughdissociating concentrations of NH₄SCN did not have a markedeffect on wild-type DAAO. This indicates that dimer dissociationoccurred without any sensible alteration of the tertiary structurein each monomer. Indeed, the spectra reported in Figure 2 clearlyindicate a much higher sensitivity to NH₄SCN for the ${Delta}$ loop RgDAAOmutant with respect to the wild-type protein. It is also interestingthat the spectra of wild-type DAAO (both native and NH₄SCN-dissociated)were isochroic with that of the NH₄SCN-treated ${Delta}$ loop RgDAAO mutantat 272 nm. This indicates that the addition of NH₄SCN may haveeliminated some of the structural perturbation introduced inthe wild-type protein by removal of the ßF5–ßF6loop.

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Figure 2. Effect of NH₄SCN on the near-UV CD spectra of wild-type (thin lines) and ${Delta}$ loop (thick lines) RgDAAO in the absence (continuous line) and in the presence (dashed line) of 0.5 M NH₄SCN. Proteins were 0.5 mg/mL in 50 mM potassium phosphate (pH 7.5), containing 10% glycerol and 2 mM EDTA. Measurements were performed at 15°C.

A further sensitive marker of protein conformation, and in particularof changes in hydrophobic regions of the structure, is tryptophanemission fluorescence. Tryptophan emission at 345 nm (followingexcitation at 280 nm) was threefold higher for ${Delta}$ loop RgDAAO thanfor wild-type (Fig. 3A

). This result points to a lower relevanceof quenching interactions between tryptophan side chains (inparticular of Trp 243, vide infra) and nearby side chains inthe monomeric form of RgDAAO with respect to the dimeric form.Increasing the NH₄SCN concentration up to 0.5 M increased theintensity of the 345-nm emission for both proteins. At an NH₄SCNconcentration of $>=$ 0.5 M, the two DAAO forms had similar emissionvalues (Fig. 3A

). In the presence of thiocyanate, the tryptophanemission of wild-type and ${Delta}$ loop DAAOs was shifted to a longerwavelength than in the untreated proteins (from 340 to 348 nm),indicating exposure of tryptophan residues to the solvent (Fig.3B

). The shift in the wavelength of maximal emission was completeat 1.5 M NH₄SCN.

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Figure 3. Effect of NH₄SCN concentration on tryptophan fluorescence of wild-type (filled symbols) and ${Delta}$ loop (open symbols) RgDAAO. DAAO (0.1 mg/mL) was incubated for 15 min at 15°C in 50 mM potassium phosphate (pH 7.5), 2 mM EDTA, and 10% glycerol containing the given concentration of NH₄SCN. Emission spectra were recorded from 300 to 400 nm with excitation at 280 nm. The reported values have been corrected for the emission of the solution before protein addition. (A) Tryptophan fluorescence intensity. (B) Tryptophan fluorescence emission maximum.

Effects of thiocyanate on cofactor binding and on enzymatic activity in wild-type and ${Delta}$ loop RgDAAO mutant
A sensitive marker of the folding of a flavoenzyme is representedby the fluorescence of the FAD cofactor, which is much lowerin the holoenzyme-bound form with respect to free FAD (Casalin et al. 1991).The emission at 520 nm, following excitation at450 nm, was higher for ${Delta}$ loop than for wild-type RgDAAO (in the0.015–0.5 mg/mL protein concentration range), pointingto a different microenvironment surrounding the FAD coenzymein the two enzyme forms (see Fig. 4

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Figure 4. Effect of NH₄SCN on the flavin fluorescence of wild-type (filled symbols) and ${Delta}$ loop (open symbols) RgDAAO. DAAO (0.1 mg/mL) was incubated for 15 min at 15°C in 50 mM potassium phosphate (pH 7.5), 2 mM EDTA, and 10% glycerol in the presence of various NH₄SCN concentrations, and the flavin emission spectrum was recorded in the 460–600-nm wavelength range (excitation at 450 nm). The reported values have been corrected for the background emission of the buffer prior to protein addition.

An increase in NH₄SCN concentration had a completely differenteffect on the two proteins. Flavin fluorescence of the ${Delta}$ loopmutant decreased with increasing NH₄SCN concentration. Wild-typeDAAO showed a small increase in fluorescence up to 0.5 M NH₄SCN,followed by a decrease at higher NH₄SCN concentration, wherefluorescence attained values similar to those determined forthe ${Delta}$ loop mutant (Fig. 4

). Interestingly, the flavin fluorescenceat 0.5 M NH₄SCN, corresponding to conversion of the dimericenzyme to the monomeric form (see earlier), was similar forwild-type and ${Delta}$ loop RgDAAO. The decrease in flavin fluorescenceat increasing concentration of NH₄SCN is mostly due to chemicalquenching on direct interaction of free FAD and NH₄SCN. In fact,a strong decrease of the 520-nm emission at increasing NH₄SCNconcentration was also observed for free FAD (from 195 to 8arbitrary units using 2.5 µM purified FAD, not shown).This behavior is qualitatively similar to that observed for ${Delta}$ loop DAAO, and is indicative of a higher solvent exposure ofthe isoalloxazine ring of FAD in the ${Delta}$ loop mutant than in wild-typeRgDAAO. Circumstantially, this confirms also the weaker bindingof the coenzyme to the apoprotein moiety in the monomeric mutantDAAO than in the dimeric wild-type one (Casalin et al. 1991;Piubelli et al. 2002).

The effect of NH₄SCN on the activity of RgDAAO was investigatedby measuring the enzyme activity in the presence of differentthiocyanate concentrations in the assay mixture. At NH₄SCN concentrationshigher than 0.5 M, the oxygen-consumption trace was clearlybiphasic: a first short and fast phase (~1–3 min) wasfollowed by a second phase in which the slope was significantlylower. The activity value corresponding to the first phase wascompletely lost at NH₄SCN concentrations higher than 1 M (notshown). The activity was assayed also by using a standard assaymixture (that is, in the absence of NH₄SCN) and DAAO samplespreviously incubated for 15 min at 15°C with different concentrationsof NH₄SCN. As reported in Figure 5, the enzyme activity measuredin these conditions started to decline at ${approx}$ 0.5 M NH₄SCN and waslost at 1 M NH₄SCN, concomitant to irreversible alteration ofthe protein conformation, as discussed earlier (see also Fig.3). Activity of the ${Delta}$ loop mutant protein was also lost afterpreincubation with 1 M NH₄SCN. As shown in Figure 5, incubationat dissociating NH₄SCN concentration (0.5 M) decreased the activityof wild-type RgDAAO activity to 81% of that measured for theuntreated protein. This is close to the 86% decrease in specificactivity measured on the monomer recovered from size-exclusionchromatography in the presence of 0.5 M thiocyanate.

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Figure 5. Effect of NH₄SCN concentration on enzyme activity of wild-type RgDAAO. The activity was determined using the oxygen-electrode assay on protein samples incubated at 15°C for 15 min in the presence of different concentrations of NH₄SCN. The carryover of thiocyanate in the activity assay was negligible. Data were fitted to the equation y = a/{1 + exp[-(x-x_m)/b]}, where a = activity of the enzyme incubated in the absence of thiocyanate (79.0 U/mg protein), b = residual activity of the enzyme incubated at high thiocyanate concentration ( ${approx}$ 0.08 U/mg protein at 1 M NH₄SCN), and x_m = thiocyanate concentration at which 50% of the initial activity is lost (0.61 M).

Spectroscopic and calorimetric studies on the thermal stability of the different aggregation states of RgDAAO
Preliminary studies indicated a significant lower stabilityof the ${Delta}$ loop mutant with respect to wild-type RgDAAO. After 30min at 40°C, the ${Delta}$ loop mutant retained <5% of its initialactivity, as compared with 60% for wild-type RgDAAO (Piubelli et al. 2002).To compare the temperature sensitivity of specificstructural features in the two proteins, and to assess the natureand extent of spectroscopic modifications ensuing by progressiveheating of wild-type and ${Delta}$ loop mutant RgDAAO, we performed temperatureramp experiments. Conditions used when monitoring temperature-dependentchanges of the various spectroscopic features of the proteinwere identical to those used in DSC experiments (vide infra).In order to achieve information on the dependence of thermalstability on the protein aggregation state, we also performedthese experiments (when feasible) at various protein concentration,with the assumption that this parameter would affect the relativeconcentration of differently associated species.

Table 1 reports the midpoint transition temperatures for thetwo DAAO forms as detected by the various experimental approaches,and using different sets of experimental conditions.

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Table 1. Comparison of T_m as determined by different approaches on the untreated wild-type and ${Delta}$ loop mutant DAAO

The DSC tracings reported in Figure 6

clearly indicate that ${Delta}$ loop RgDAAO was thermodynamically much less stable than wildtype. The wild-type protein had a denaturation T_ms of 55.9°Cand a denaturation enthalpy of 1030 kJ/mole at a concentrationof 1.5 mg/mL, compared with 48.0°C and 775 kJ/mole for the ${Delta}$ loop RgDAAO at the same concentration. All T_m figures reportedin Table 1

have an average standard error $<=$ 0.2°C, whereasa 3% average standard error affects the enthalpy estimates.The DSC signals of wild-type RgDAAO were sensitive to proteinconcentration in the 1.5–3.5 mg/mL range, showing an increasein T_m and a more pronounced aggregation at high temperaturewith increasing protein concentration. Concentration effectson the denaturation enthalpies were within the experimentalerror in our experiments. Because concentration effects on T_mwere not observed for ${Delta}$ loop RgDAAO, they cannot be ascribed toa generic "structural protection" exerted by higher proteinconcentration, but likely are linked to the association/dissociationequilibrium in the dimeric wild-type RgDAAO (D’Auria et al. 1997).The sharp fall of the DSC signal at temperaturesabove T_m in the case of wild-type RgDAAO also supports thishypothesis (D’Auria et al. 1997). These effects (T_m shiftand asymmetry of DSC thermographs) were much less pronouncedin the case of ${Delta}$ loop RgDAAO, which did not aggregate above T_m.All of the modifications observed by DSC on either protein wereirreversible.

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Figure 6. DSC tracings for wild-type (thin line) and ${Delta}$ loop (thick line) RgDAAO using protein concentrations of 1.5 (dotted line) or 3.5 mg/mL (continuous line). The heating rate was 0.5°C/min.

Taking into account these evidences, thermodynamic analysisof the modifications detected in the DSC experiments was limitedto the ${Delta}$ loop RgDAAO mutant, that is, in the absence of possiblecomplications ensuing from association equilibria in the nativeor in the denatured forms. It has been proven that even irreversibleprocesses (as those observed here) can be in some cases splitinto two steps: achievement of a thermodynamic equilibrium,which is responsible for the protein unfolding enthalpy, followedby an irreversible step that does not affect the measured enthalpy.For example, it has been shown that the irreversible thermaldenaturation of the lac repressor quantitatively obeys equilibriumthermodynamics (Manly et al. 1985), as reported also for thethermal denaturation of the subunits of Escherichia coli aspartatetranscarbamoylase (Edge et al. 1985) and of bovine serum albumin(Giancola et al. 1997).

As shown in Figure 7, application of a thermodynamic model consideringtwo independent energetic domains (Barone et al. 1994; Fessas et al. 2001)provided a good fit of the DSC signal for the ${Delta}$ loopmutant, that is, in the absence of aggregation at high temperature.A first energetic domain unfolded with a T_m of 45.1°C andcontributed ${Delta}$ _dH = 230 kJ mole^-1, ${Delta}$ _dS = 723 J mole^-1 K^-1, whereasa more thermostable domain unfolded with a T_m of 47.8°Cand contributed ${Delta}$ _dH = 555 kJ mole^-1, ${Delta}$ _dS = 1730 J mole^-1 K^-1.These figures indicate that modifications affecting the high-temperatureenergetic domain may involve a larger portion of the proteinstructure, at least assuming that the unfolding process doesnot involve the breakage of bonds of unusual strength (Dill 1990).

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Figure 7. Best fit of the experimental DSC tracing obtained for ${Delta}$ loop RgDAAO using a 1.5 mg/mL protein concentration. The original trace is given as a thin solid line. The thick solid line is a fit performed according to a two-state model assuming two independent domains (see text). Dashed and dotted lines correspond to the contributions attributed to each thermodynamic domain.

When temperature-induced loss of secondary structure was monitoredby following the loss of the CD signal at 220 nm in temperature-rampexperiments using the same temperature gradient applied in DSCstudies (Fig. 8A

), slightly lower T_m values were found for bothprotein forms with respect to those detected by DSC (althoughat 0.5 mg protein/mL).

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Figure 8. Temperature dependence of different spectroscopic signals for wild-type (circles) and ${Delta}$ loop (squares) RgDAAO. Proteins were in 50 mM potassium phosphate (pH 7.5), 2 mM EDTA, and 10% glycerol. Spectral signals were monitored continuously during progressive heating from 25°C to 75°C at a heating rate of 0.5°C/min, and are given as percent of the total observed change. (A) CD signal at 220 nm. (open symbols) 0.1 mg /mL, (filled symbols) 0.5 mg protein/mL. (B) Fluorescence intensities at a protein concentration of 0.5 mg/mL. (open symbols) Tryptophan fluorescence, (filled symbols) flavin fluorescence.

T_m figures for FAD release, as monitored in independent temperature-rampfluorescence measurements (Fig. 8B

), were close to those obtainedby DSC, and thus only slightly higher than those obtained whenmonitoring the loss of secondary structure elements. It is worthobserving that a fivefold decrease in the protein concentration(from 0.5 to 0.1 mg protein/mL) only marginally affected T_mfor the ${Delta}$ loop RgDAAO (see Table 1

), but caused a sensible decreasein T_m for the wild-type protein in terms of loss of secondarystructure elements and of flavin release. This supports thehigher stability of associated forms of dimeric wild-type RgDAAO,as inferred by the concentration dependence of thermal stabilityobserved in DSC studies.

Studies on the temperature sensitivity of tryptophan fluorescence(taken as a reporter of tertiary structure modifications) confirmedthe different inherent stability of the two proteins. Thesedata also indicated that loss of tertiary structure elementsinvolving hydrophobic regions of the protein occurs at muchlower temperatures than all other modifications discussed earlier.This is made evident by the various tracings in Figure 8B, whichcompares the temperature dependence of tryptophan and FAD fluorescenceand provides an immediate visual appreciation of the behaviorof the different signals in the two proteins. The correspondingT_m values are reported in Table 1. (See Electronic SupplementalMaterial.) We attempted to calculate transition enthalpies fromour spectroscopic data according to independent two-state transitionmodels (van’t Hoff). Results of our calculations, whencompared with the calorimetric measurements, indicated thatthe condition of independence between the spectroscopic variablesis not completely satisfied.

In order to understand the relationships between thermal stabilityand presence of a dimeric structure in DAAO, we also performedsome of the experiments described earlier in the presence of0.5 M NH₄SCN, that is, under conditions in which the wild-typeprotein is completely dissociated into monomers. Temperature-sensitivityof the spectroscopic features of ${Delta}$ loop RgDAAO mutant was alsostudied in the presence of dissociating concentrations of NH₄SCN(0.5 M), for the purpose of (i) establishing some sort of referencewith respect to the wild-type monomer and (ii) assessing theeffects of NH₄SCN on the ßF5–ßF6 loopregion itself.

A summary of the T_m values obtained in the presence of 0.5 MNH₄SCN for wild-type and ${Delta}$ loop DAAO, is reported in Table 2.The two panels of Figure 9 show the original tracings for temperature-inducedirreversible changes in tryptophan and flavin fluorescence inthe presence and in the absence of 0.5 M NH₄SCN. It has to benoted that the experiments presented in Table 2 and in the relatedFigure 9 were performed at a higher heating rate (2°C/min)with respect to those presented in Table 1 and Figure 8. Thehigher heating rate was necessary in order to minimize artefactsdue to protein aggregation on prolonged exposure at high temperaturein the presence of 0.5 M NH₄SCN.

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Table 2. Comparison of T_m as determined by different approaches on wild type and ${Delta}$ loop mutant DAAO in the absence and in the presence of 0.5 M NH₄SCN

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Figure 9. Temperature dependence of different spectroscopic signals for wild-type (circles) and ${Delta}$ loop (squares) RgDAAO, in the absence (filled symbols) and in the presence (open symbols) of 0.5 M NH₄SCN. (A) Tryptophan fluorescence, (B) flavin fluorescence. Proteins were 0.5 mg/mL in 50 mM potassium phosphate (pH 7.5), 2 mM EDTA, and 10% glycerol, and were heated from 25°C to 65°C at a heating rate of 2°C/min.

The presence of NH₄SCN strongly affected the thermostabilityparameters for wild-type DAAO, whereas the ${Delta}$ loop RgDAAO mutantwas affected to a lesser extent. In the presence of 0.5 M NH₄SCN,both proteins were in the monomeric state at the beginning ofthe thermal treatment, but the wild-type RgDAAO monomer lostits tertiary structure and released flavin at lower temperaturesthan the ${Delta}$ loop mutant monomer. These observations clearly indicatethat the effect of NH₄SCN is not restricted to the dimerizationinterface. The shape of the temperature-dependence curves obtainedin the presence of 0.5 M NH₄SCN with either protein also indicatesa modified cooperativity of the processes leading to irreversiblethermal denaturation.

Discussion

TOP
Abstract
Introduction
Results
Discussion
Materials and methods
References

We demonstrated here the possibility of obtaining a monomericform of RgDAAO by treatment with 0.5 M NH₄SCN without deletionof the ßF5-ßF6 loop. Such a conversion isreversible but hysteretic for kinetic reasons. Both proteinforms denature at >1M NH₄SCN. Scheme 1 summarizes in a pictorialform the events ensuing from thermal treatment of monomericand dimeric RgDAAO, either produced by mutagenesis or by dissociationwith lipophilic ions of the native dimer.

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Scheme 1. A schematic representation of the structural changes ensuing from progressive heating of dimeric wild-type and monomeric ${Delta}$ loop RgDAAO in the absence and in the presence of 0.5 M NH₄SCN. The triangular protrusion identifies the ßF5-ßF6 loop. Round or square corners in the main rectangle (or in boxes around the cofactor) indicate changes in local structures, as detected by spectroscopy. (PF) Protein fluorescence; (FF) flavin fluorescence. T₁–T₄ indicate the "midpoint melting temperature" (T_m) for individual protein forms.

The monomeric and dimeric untreated DAAO differ in tryptophanand flavin fluorescence, as well as in their CD spectral propertiesin the near-UV region. The monomeric forms of DAAO obtainedby site-directed mutagenesis and NH₄SCN treatment are somewhatdifferent, showing different CD spectra and different fluorescence/exposureof the FAD coenzyme (see Figs. 2

, 4

). However, flavin and proteinfluorescence reach similar values at 0.5 M NH₄SCN in both wild-typeand ${Delta}$ loop DAAO (see Fig. 4

). The change in flavin fluorescenceis due to two different events: loss of the dimeric aggregationstate (as indicated by the different flavin fluorescence ofwild-type and ${Delta}$ loop DAAO in the absence of NH₄SCN), and alterationof the tertiary structure specifically consequent to the additionof NH₄SCN.

Inspection of the buried surface on each DAAO monomer for the"head-to-tail" model of RgDAAO dimer formation (Pollegioni et al. 2002)shows that Trp 243 in each subunit is placed in strictcontact with the corresponding residue in the other subunitat the dimer interface (Fig. 10A). Therefore, the spectral differencesin the untreated proteins (Figs. 2, 3) may be indicative ofchanges in the environment of Trp 243 following the deletionof the ßF5–ßF6 loop and conversionto the monomeric state.

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Figure 10. A schematic representation of the intermonomer interactions in dimeric wild-type RgDAAO. (A) Stacking of Trp-243 (red) in the buried region at the dimer interface (no other tryptophan residues are located in the buried surface between monomers). The individual peptide chains are in blue and green. (B) Left: Specific ion pairing involving the ßF5-ßF6 loop region of one monomer and the ${alpha}$ I3'- ${alpha}$ I3'' region of the symmetry-related monomer. The different peptide chains are in green and light blue, respectively. Right: Molecular surface representation showing positively charged residues in the ßF5-ßF6 loop region (blue) and negatively charged residues in the ${alpha}$ I3'- ${alpha}$ I3'' region (red).

When monomerization of wild-type RgDAAO is induced by the additionof modest amounts of thiocyanate, other factors have to be takeninto consideration. The ßF5–ßF6 loopin wild-type RgDAAO contains three positively charged residues(Arg 314, Arg 318, and Lys 321) that interact with negativelycharged residues belonging to ${alpha}$ I3' and ${alpha}$ I3'' helices on the symmetry-relatedmolecule (Asp 269, Glu 273, Glu 276; Fig. 10B

). Among all DAAOs,these two regions are unique to this protein (Pollegioni et al. 2002).Because nonlipophilic anions do not promote dissociation,thiocyanate is effective in that it affects both hydrophobicand charge contacts between monomers. By acting on these structuralelements, thiocyanate may also affect the conformation of theflavin-binding domain (vide infra).

A second relevant finding is the identification of a clear sequenceof events in the course of thermal unfolding of both proteinforms that involves (in order of increasing temperature) (1)loss of tertiary structure, (2) loss of some elements of secondarystructure, and (3) general unfolding of the protein structure,concomitant to FAD release.

Indeed, by comparing the spectroscopic evidence with the deconvolutionof the DSC tracings (Fig. 11), one can observe that the signaloriginating from modification of the tertiary structure in the ${Delta}$ loop RgDAAO overlaps changes in the low-temperature energeticdomain, whereas the high-temperature energetic domain unfoldedwith a temperature dependence almost identical to the one detectedfor loss of secondary structure and release of the cofactor.Apparently, the first low-temperature energetic domain relatesto the unfolding of tertiary structure regions, whereas thesecond energetic domain relates to the loss of secondary structureelements and to the release of the cofactor at higher temperatures.The sequence of events leading to irreversible general unfoldingof the protein and loss of the flavin cofactor have T_ms thatcover a >10°C temperature span (46.4°C to 56.9°C,with appreciable concentration effects) for the wild-type protein,but a much narrower temperature span (<6°C, from 42.7°Cto 48.1°C, with only minor concentration effects) for the ${Delta}$ loop RgDAAO.

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Figure 11. Comparison of the experimental DSC tracing (full line) with the first derivative of the tryptophan (dots) and flavin (dashes) fluorescence signals obtained for ${Delta}$ loop RgDAAO. The fluorescence data used for derivative calculation are those reported in Figure 8B

. The DSC data are the same as those reported in Figure 7

We also confirm here the reported higher thermostability ofdimeric, wild-type RgDAAO (Piubelli et al. 2002). In this frame,it is worth noting that DSC experiments gave a significantlyhigher denaturation enthalpy for wild-type than for mutant DAAO(1030 vs. 775 kJ/mole), concentration independent. Because thedenaturation enthalpy is contributed mostly by the high-temperatureenergetic domain (at least in the ${Delta}$ loop RgDAAO, see Fig. 7

),it is possible to envision a fundamental role of the factorsaffecting stability of the flavin-harboring domain in the overallstability of the protein. Indeed, DSC and temperature-dependentspectroscopic studies at various protein concentration (Table1

) are supportive of a definite role of dimerization in promotingthermostability: the dimeric, untreated wild-type DAAO possessesthe highest T_m (T₁ > T₂, see Scheme 1

). As for the possiblemolecular determinants of this property, it is worth notingthat the hydrophobic regions including reporter tryptophansin the thiocyanate-treated proteins (most likely Trp 243, seeFig. 10A

) attained a similar degree of unfolding at room temperatureand had almost identical temperature sensitivity (Fig. 9A

).However, this does not hold true for the flavin-binding domain,that—although similar in both proteins at 15°C in0.5 M NH₄SCN (Fig. 2

)—showed a much higher temperaturesensitivity in the thiocyanate-treated wild-type RgDAAO (Fig.9B

). This observation, along with the independence of the energeticdomains made evident by DSC studies on the monomeric ${Delta}$ loop mutantRgDAAO (see Fig. 11

and related comments), may be taken as anevidence of the absence of a strict structural relationshipamong the two regions in each DAAO monomer, but indicates thatthe relationships between the two regions are remarkably differentfor the wild-type protein dimer. Indeed, because this latterin 0.5 M thiocyanate dissociates into a monomer, it is easyto envision a primary role of dimerization in the stabilizationof the flavin-harboring regions of the structure. In particular,thiocyanate acts on the wild-type dimeric RgDAAO by affectingionic pairs between secondary elements of the FAD-binding domainof one monomer and those of the intersubunit domain of the symmetry-relatedmonomer (Fig. 10B

). Thus, the effects of thiocyanate on thestability of RgDAAO are indicative of a correlation betweenthe presence or the conformation of the ßF5–ßF6loop in RgDAAO (not conserved in other known DAAO sequencesand allowing stabilization of the dimeric state) with the tightbinding of the flavin coenzyme (10-fold and 5-fold tighter inyeast dimeric DAAO than in the monomeric mammalian enzyme andin the ${Delta}$ loop monomeric RgDAAO, respectively; Casalin et al. 1991;Curti et al. 1992; Piubelli et al. 2002).

The relevance of our results may extend beyond mere comparisonamong different DAAOs. From a structural standpoint, RgDAAOis a component of the large GR family. Based on both structuraland sequence homologies (Pollegioni et al. 2002), all the familymembers adopt the Rossmann fold (Rossmann et al. 1974). In particular,DAAOs belong to the GR₂ subgroup, characterized by sequencesimilarity mainly within 30 residues in the N-terminal region,which represents the dinucleotide-binding motif (Dym and Eisenberg 2001).Interestingly, high topological similarity is found withinthe GR₂ subfamily in the "flavin-binding domain", whereas onlyparts of the "interface domain" can be superimposed in pair-wisefashion (Pollegioni et al. 2002). The combination of such structuralconsiderations and our results indicates that the molecularmechanisms regulating dimeric DAAO holoenzyme formation mayrequire two events: (1) binding of the FAD cofactor to the monomericapoprotein, allowing the formation of the monomeric holoenzymeand (2) electrostatic interaction between positively chargedresidues of the ßF5–ßF6 loop and thenegatively charged residues of the ${alpha}$ I3' and ${alpha}$ I3'' secondary elementsbelonging to a different monomer, and hydrophobic interactionbetween Trp 243 residues belonging to two different subunits,leading to dimer stabilization. Whereas cofactor binding, whichinvolves a large portion of the protein, may be common to allmembers of this class, the second event should be specific ofyeast DAAO because it involves structural elements not presentin other flavoenzymes (Dym and Eisenberg 2001; Pollegioni et al. 2002).

Besides the academic interest concerning the structure–functionrelationships in flavoenzymes, knowledge about protein stabilityis nowadays being exploited in many practical applications inbiotechnology and is thus also of industrial importance. Inthis context, the yeast DAAO is extensively used in the bioconversionof cephalosporin C to 7-aminocephalosporanic acid, a two-steproute that uses DAAO and glutaryl-7-ACA acylase in sequence.The two activities require two distinct reactors because theoperational stability of DAAO is significantly lower than thatof acylase (for a recent review, see Pilone and Pollegioni 2002).The ensuing complications make it worthwhile to take a closerlook at the structural determinants of DAAO thermal stability,also from an economic standpoint.

Materials and methods

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Abstract
Introduction
Results
Discussion
Materials and methods
References

Purification of wild-type and ${Delta}$ loop RgDAAO, and DAAO activity assay
Recombinant RgDAAO was expressed and purified from E. coli cellsas described previously (Molla et al. 1998). Production andproperties of DAAO ${Delta}$ loop mutant were described elsewhere (Piubelli et al. 2002).Starting from a 10-L fermentation broth, 180 mgand 80 mg of pure enzyme with a specific activity of 110 and86 U/mg protein were obtained for wild-type and ${Delta}$ loop DAAO, respectively.The enzyme concentration was determined by using an extinctioncoefficient of 12.6 mM^-1cm^-1 for wild-type and 11.3 mM^-1cm^-1for ${Delta}$ loop DAAOs (Pilone 2000; Piubelli et al. 2002). DAAO activitywas assayed with an oxygen electrode at pH 8.5, air saturation,and 25°C, using 28 mM D-alanine as substrate in the presenceof 0.2 mM FAD (Pilone 2000).

Size-exclusion chromatography
Size-exclusion chromatography was performed at room temperatureon a Superdex 200 column using an Äkta chromatographicsystem (Amersham Pharmacia Biotech), at a flow rate of 0.5 mL/min.The eluant was 50 mM potassium phosphate buffer (pH 7.5) containing0.25 M sodium chloride, 10% glycerol, 2 mM EDTA, and the appropriateconcentration of NH₄SCN. The column was calibrated with suitablestandard proteins.

Spectroscopy
All fluorescence measurements at fixed temperature were performedin a Jasco FP250 or FP750 instrument equipped with a thermostatedcell holder by using a 1-mL cell. Tryptophan emission spectrawere recorded using an excitation wavelength of 280 nm and flavinemission spectra were recorded using an excitation wavelengthof 450 nm. Emission and excitation bandwidths were set at 10nm. Temperature-ramp experiments were performed in a software-driven,Peltier-equipped Perkin-Elmer LS 50 fluorometer that allowedreproduction of the same temperature gradient (0.5°C/min)used in DSC studies. Emission and excitation bandwidths wereset at 5 nm. When necessary, heating rates of 2 °C/min werealso used. Tryptophan emission spectra were taken from 300 to450 nm using an excitation wavelength of 298 nm. Flavin emissionspectra were recorded from 460 to 600 nm using an excitationwavelength of 455 nm. Fixed wavelength measurements were takenwith emission wavelengths of 340 and 526 nm for tryptophan andflavin fluorescence, respectively. CD spectra were recordedon a J-810 Jasco spectropolarimeter, also fitted with a software-drivenPeltier-based temperature controller, and analyzed by meansof Jasco software. The cell path was 1 cm for measurements above250 nm, and 0.1 cm for measurements in the 190- to 250-nm region.Proteins were in 50 mM potassium phosphate buffer (pH 7.5) containing10% glycerol and 2 mM EDTA.

Calorimetry
Calorimetric measurements were carried out on solutions containing0.5–3.5 mg protein/mL in the same buffers used for spectroscopicstudies. A third-generation Setaram Micro-DSC apparatus wasused, which is suitable for dilute solutions of biological macromoleculesin the temperature range from -20°C to 120°C. Scan ratewas 0.5°C/min. Data were analyzed by means of the THESEUSsoftware (Barone et al. 1992). The excess molar heat capacity< ${Delta}$ C_p> or , i.e., the difference between the apparent molar heat capacity Cp(T) of the sample and themolar heat capacity of the "native state," Cp,_N(T), was recordedacross the scanned temperature range. Cp,_N(T) was obtained accordingto published procedures (Freire and Biltonen 1978) by linearregression of experimental Cp(T) data in the predenaturationregion (namely, for T < T_i, where T_i is the highest temperatureat which only the native protein is present). The overall calorimetricdenaturation enthalpy ${Delta}$ _dH was determined by integration of C_p(T)across the denaturation (T_i ÷ T_f) range, where T_f isthe final temperature of the denaturation process, taking intoaccount that the baseline has a sigmoidal trend across the sametemperature range. Such a trend can be obtained by assigninga weight factor equal to the ratio incremental area/total area,drawn from the earlier integration, and iterating the overallprocess until convergence (Barone et al. 1992). As a first stepof the iteration procedure, a straight line passing throughCp(T_i) and Cp(T_f) was used as the tentative baseline. All thethermograms reported in this paper were accordingly scaled.Because of the short extension of the baseline before the peaksand, in some cases, of the presence of aggregation phenomena,the heat capacity drop ${Delta}$ _dCp that corresponds to the Cp changeon passing from native to the denatured state across the signalwas affected by a rather large error and was therefore not takeninto account. The procedures described earlier leveled off anyuncertainty about ${Delta}$ _dCp and allowed a reliable evaluation of C_p(T)and of the corresponding enthalpy. The theoretical models usedto fit the experimental data were tested through the nonlinearLevenberg-Marquardt method (Press et al. 1989).

Acknowledgments

This work was supported by a grant from FAR 2002 to L. Pollegioniand from Fondo Progetti di Eccellenza 2001—Universityof Insubria to M.S. Pilone and L. Pollegioni. Individual FIRSTgrants (MiUR, Rome, Italy) supported the other principal investigators(S. Iametti, F. Bonomi). We thank Dr. Gianluca Molla for assistancein preparing Figure 10.

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.

References

TOP
Abstract
Introduction
Results
Discussion
Materials and methods
References

Barone, G., Del Vecchio, P., Fessas, D., Giancola, C., and Graziano, G. 1992. THESEUS: A new software package for the handling and analysis of thermal denaturation data of biological macromolecules. J. Thermal Analysis 38: 2779–2790.[CrossRef]

———. 1994. Denaturation of biological macromolecules: New programs for the deconvolution of DSC measurements. In Chemistry and properties of biomolecular systems (eds. N. Russo, J. Anastassopoulou, et al.), pp. 67–78. Kluwer, Amsterdam, The Netherlands.

Casalin, P., Pollegioni, L., Curti, B., and Pilone Simonetta, M. 1991. A study on apoenzyme from Rhodotorula gracilis D-amino acid oxidase. Eur. J. Biochem. 197: 513–517.[Medline]

Curti, B., Ronchi, S., and Pilone Simonetta, M. 1992. D- and L-amino acid oxidases. In Chemistry and biochemistry of flavoenzymes (ed. F. Müller), Vol. 3, pp. 69–94. CRC, Boca Raton, FL.

D’Auria, S., Barone, R., Rossi, M., Nucci, R., Barone, G., Fessas, D., Bertoli, E., and Tanfani, F. 1997. Effects of temperature and SDS on the structure of ß-glycosidase from the thermophilic archaeon Sulfolobus solfataricus. Biochem. J. 323: 833–840.

Decker, K. 1991. Covalent flavoprotein. In Chemistry and biochemistry of flavoenzymes (ed. F. Müller), Vol. 2, pp. 343–393. CRC, Boca Raton, FL.

Dill, K.A. 1990. Dominant forces in protein folding. Biochemistry 29: 7133–7155.[CrossRef][Medline]

Dym, O. and Eisenberg, D. 2001. Sequence-structure analysis of FAD-containing proteins Protein Sci. 10: 1712–1728.[Abstract/Free Full Text]

Edge, V., Allewell, N.M., and Sturtevant, J.M. 1985. High-resolution differential scanning calorimetric analysis of the subunits of Escherichia coli aspartate transcarbamoylase. Biochemistry 24: 5899–5906.[CrossRef][Medline]

Fessas, D., Iametti, S., Schiraldi, A., and Bonomi, F. 2001. Thermal unfolding of monomeric and dimeric ß-lactoglobulins. Eur. J. Biochem. 268: 5439–5448.[Medline]

Freire, E. and Biltonen, R.L. 1978. Thermodynamics of transfer ribonucleic acids: The effect of sodium on the thermal unfolding of yeast tRNAPhe. Biopolymers 17: 463–479.[CrossRef]

Giancola, C., De Sena, C., Fessas, D., Graziano, G., and Barone, G. 1997. DSC studies on bovine serum albumin denaturation. Effects of ionic strength and SDS concentration. Int. J. Biol. Macromol. 20: 193–204.[CrossRef][Medline]

Manly, S.P., Matthews, K.S., and Sturtevant, J.M. 1985. Thermal denaturation of the core protein of lac repressor. Biochemistry 24: 3842–3846.[CrossRef][Medline]

Massey, V. and Hemmerich, P. 1980. Active-site probes of flavoproteins. Biochem. Soc. Trans. 8: 246–255.[Medline]

Molla, G., Vegezzi, C., Pilone, M.S., and Pollegioni, L. 1998. Overexpression in Escherichia coli of a recombinant chimeric Rhodotorula gracilis D-amino acid oxidase. Prot. Expr. Purif. 14: 289–294.[CrossRef][Medline]

Pilone, M.S. 2000. D-amino acid oxidase: New findings. Cell. Mol. Life Sci. 57: 1732–1747.[CrossRef][Medline]

Pilone, M.S. and Pollegioni, L. 2002. D-amino acid oxidase as an industrial biocatalyst. Biocatalysis and Biotransformation 20: 145–159.[CrossRef]

Piubelli, L., Caldinelli, L., Molla, G., Pilone, M.S., and Pollegioni, L. 2002. Conversion of the dimeric D-amino acid oxidase from Rhodotorula gracilis to a monomeric form. A rational mutagenesis approach. FEBS Lett. 526: 43–48.[CrossRef][Medline]

Pollegioni, L., Diederichs, K., Molla, G., Umhau, S., Welte, W., Ghisla, S., and Pilone, M.S. 2002. Yeast D-amino acid oxidase: Structural basis of its catalytic properties. J. Mol. Biol. 324: 535–546.[CrossRef][Medline]

Press, W.H., Flannery, B.P., Teukolsky, S.A., and Vetterling, W.T. 1989. In Numerical recipes. Cambridge University Press, Cambridge, UK.

Ptistyn, O.B. and Semisotnov, G.V. 1991. The mechanism of protein folding. In Conformations and forces in protein folding (eds. B.T. Nall and K.A. Dill), pp. 155–168. American Association for the Advancement of Sciences, Washington, DC.

Rossmann, M.G., Moras, D., and Olsen, K.W. 1974. Chemical and biological evolution of nucleotide-binding protein. Nature 250: 194–199.[CrossRef][Medline]

Umhau, S., Pollegioni, L., Molla, G., Diederichs, K., Welte, W., Pilone, M.S., and Ghisla, S. 2000. The x-ray structure of D-amino acid oxidase at very high resolution identifies the chemical mechanism of flavin-dependent substrate dehydrogenation. Proc. Natl. Acad. Sci. 97: 12463–12468.[Abstract/Free Full Text]

van Mierlo, C.P.M. and Steensma, E. 2000. Protein folding and stability investigated by fluorescence, circular dichroism (CD), and nuclear magnetic resonance (NMR) spectroscopy: The flavodoxin story. J. Biotechnol. 79: 281–298.[CrossRef][Medline]

Waterham, H.R., Russell, K.A., de Vries, Y., and Cregg, J.M. 1997. Peroxisomal targeting, import, amd assembly of alcohol oxidase in Pichia pastoris. J. Cell Biol. 139: 1419–1431.[Abstract/Free Full Text]

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