Contributions of folding cores to the thermostabilities of two ribonucleases H

doi:10.1110/ps.38602

HOME

HELP

FEEDBACK

SUBSCRIPTIONS

Contributions of folding cores to the thermostabilities of two ribonucleases H

Srebrenka Robic, James M. Berger and Susan Marqusee

Department of Molecular and Cell Biology, University of California, Berkeley, California 94720, USA

Reprint request to: Susan Marqusee, Department of Molecular and Cell Biology, University of California, 229 Stanley Hall, Berkeley, CA 94720, USA; e-mail: marqusee{at}uclink4.berkeley.edu; fax: (510) 643-9290.

(RECEIVED September 20, 2001; FINAL REVISION November 5, 2001; ACCEPTED November 9, 2001)

Article and publication are at http://www.proteinscience.org/cgi/doi/10.1110/ps.38602.

Abstract

TOP
Abstract
Introduction
Results
Discussion
Materials and methods
References

To investigate the contribution of the folding cores to thethermodynamic stability of RNases H, we used rational designto create two chimeras composed of parts of a thermophilic anda mesophilic RNase H. Each chimera combines the folding corefrom one parent protein and the remaining parts of the other.Both chimeras form active, well-folded RNases H. Stability curves,based on CD-monitored chemical denaturations, show that thechimera with the thermophilic core is more stable, has a highermidpoint of thermal denaturation, and a lower change in heatcapacity ( ${Delta}$ Cp) upon unfolding than the chimera with the mesophiliccore. A possible explanation for the low ${Delta}$ Cp of both the parentthermophilic RNase H and the chimera with the thermophilic coreis the residual structure in the denatured state. On the basisof the studied parameters, the chimera with the thermophiliccore resembles a true thermophilic protein. Our results suggestthat the folding core plays an essential role in conferringthermodynamic parameters to RNases H.

Keywords: Thermodynamic stability of proteins; chimera; stability curves; heat capacity; folding core; ribonuclease H

Introduction

TOP
Abstract
Introduction
Results
Discussion
Materials and methods
References

How proteins from thermophilic organisms (i.e., thermophilicproteins) achieve high thermostability is a question centralto our understanding of proteins. Structures of thermophilicproteins have not revealed any obvious stabilization strategies;they are usually very similar to those of homologous proteinsfound in mesophilic organisms. An example of two structurallysimilar but thermodynamically distinct proteins is a pair oftwo ribonucleases H (RNase H), one from Escherichia coli (amesophile), and one from Thermus thermophilus (a thermophile).These RNases H are small, single-domain proteins, with 52% sequenceidentity (Fig. 1).

View larger version (37K):
[in this window]
[in a new window]

Fig. 1. Sequence alignment of T. thermophilus and E. coli RNases H* (cysteine-free variants of RNase H). Vertical lines separate the core region from the remaining part (outside) of the protein. The bold letters indicate the sequence of TCEO chimera (T. thermophilus Core E. coli Outside), whereas the non-bold letters correspond to the sequence of ECTO chimera (E. coli Core T. thermophilus Outside). A cartoon of secondary structural elements (rectangles labeled ${alpha}$ A– ${alpha}$ E correspond to helices; arrows labeled ß1–ß5 correspond to strands) is shown below the sequences.

Although T. thermophilus and E. coli RNases H have indistinguishablearchitectures (Fig. 2

) (r. m. s. d. = 1.4Å), they arethermodynamically very different (J. Hollien and S. Marqusee1999b). Stability curves and native-state hydrogen exchangeexperiments have been used to map the folding energy landscapesof the two RNases H (Hollien and Marqusee 1999a,b). The thermophilicRNase H is more stable than the mesophilic protein at all temperatures;however, its stability has a shallower temperature dependence,that is, a lower change in heat capacity upon unfolding ( ${Delta}$ Cp).The result is that the thermophilic RNase H undergoes thermaldenaturation 20°C above the melting point of the E. coliRNase H. This is particularly surprising given the similarityin sequence and structure.

View larger version (43K):
[in this window]
[in a new window]

Fig. 2. Crystal structures of (left) E. coli RNase H* (Goedken et al. 2000) and (right) T.thermophilus RNase H (Ishikawa et al. 1993). Folding cores are shown in dark grey.

In both the E. coli and T. thermophilus RNases H, native-statehydrogen exchange reveals that two central helices (helix Aand D) are significantly more stable than the rest of the protein(Chamberlain et al. 1996; Hollien and Marqusee 1999a). Studieson the kinetics of folding have shown that for both proteins,these two helices fold first, forming an early folding intermediate(Raschke and Marqusee 1997; Hollien and Marqusee, unpubl.).Models of these intermediates as isolated fragments were foundto fold independently (Chamberlain 1999; K.F. Fisher, unpubl.).All of these observations lead to a model in which the two centralhelices (helix A and D) compose the crucial folding core ofRNase H (Fig. 2

Given the core's apparent importance for the stability and foldingof RNase H, we questioned whether the core might also be essentialin conferring some of the thermophilic characteristics to T.thermophilus RNase H. To test this hypothesis, we designed asystem of two chimeric RNase H molecules, one containing thecore of the mesophilic RNase H, surrounded by the remainingresidues from thermophilic RNase H; and the other with the thermophiliccore combined with the remaining residues from the mesophilicRNase H. By incorporating a thermophilic core into a mesophilicprotein, and vice versa, we were able to dissect the contributionsof the core and periphery to the thermodynamic stabilities ofthese RNases H. Our studies show that the folding core is moreimportant in conferring the thermodynamic stability profileto T. thermophilus RNase H than the remaining parts of the protein.

Results

TOP
Abstract
Introduction
Results
Discussion
Materials and methods
References

The designed chimeras are folded and active
We designed two chimeric RNase H molecules, each of which isa combination of fragments from a mesophilic (E. coli) and athermophilic (T. thermophilus) RNase H. Each chimera containsthe core region from one protein, and the remaining residues,corresponding to the outer region, from the other. To definethe sequence boundaries of this core, we used the program RAFT,which searches for fragments as potential autonomous foldingunits using the structure of the full-length protein on thebasis of an evaluation of contact density. In previous studies,RAFT identified a region representing the folding core of RNaseH (Fischer and Marqusee 2000).

One chimera, ECTO (E. coli Core T. thermophilus Outside), consistsof the core region (43–122) of E. coli, and the outerresidues (-5–42 and 123–166, based on E. coli RNaseH numbering) from T. thermophilus RNase H (Fig. 1). The otherchimera, TCEO (T. thermophilus Core E. coli Outside), is theconverse of ECTO, it contains the core from T. thermophilusRNase H combined with the remaining pars of E. coli RNase H.Analysis of contacting residues in the potential interface ofthe chimeras suggested that very few unfavorable interactionswould be introduced in the chimeric proteins, assuming thatthe structures of the chimeras would not differ from the parentproteins (this was confirmed for the TCEO chimera, see below).The analysis revealed that there are only three core-peripherypairs for which the pair of interacting residues showed significantlydifferent chemistries between the two parent proteins. Contactingresidue pairs V54–F35, D66–A6, and R117–R4in E. coli RNase H are analogous to E54–L35, I66–E6,and K117–Q4 in T. thermophilus RNase H. In the chimeras,these pairs are split, so that one residue originating fromE. coli contacts the corresponding interaction partner fromT. thermophilus RNase H. Of these interfacial contacts, onlyone introduces a potentially unfavorable electrostatic interactionto the TCEO chimera. D66–E6 introduces a potential charge–chargerepulsion, not found in either of the parent proteins. No suchinteractions were predicted to be introduced into ECTO chimera.The lack of additional potentially unfavorable interactionsencouraged us to proceed with the creation and characterizationof the chimeras.

Both chimeras were over-expressed in E. coli and purified assoluble proteins (see Materials and Methods). Low-resolutionstudies [circular dichroism (CD) and activity assays] suggestthat both fold into active RNases H. RNase H activity was monitoredby a UV-absorbance-based activity assay, using a DNA–RNAhybrid as substrate (data not shown). Figure 3 shows the far-UVCD spectra of all four proteins (two chimeras plus two parentproteins). These data are difficult to interpret due to thefact that, in spite of having the same three-dimensional structure,the CD spectra of the parent proteins are different. The spectrumof ECTO overlays that of T. thermophilus RNase H. The CD spectrumof TCEO differs from both of the parent proteins; however, X-raycrystallography confirmed that it adopts the RNase H fold (seebelow). Equilibrium sedimentation experiments confirmed thatTCEO and ECTO are monomeric proteins (data not shown). In sum,ECTO and TCEO both appear to be well folded and functional RNasesH.

View larger version (15K):
[in this window]
[in a new window]

Fig. 3. CD spectra of E. coli RNase H* ( ${square}$ ) T. thermophilus RNase H* ( ${circ}$ ), ECTO ( ${blacktriangledown}$ ) and TCEO( ${blacktriangleup}$ ) chimera.

Crystal structure of TCEO shows the RNase H fold
Diffraction-quality TCEO crystals were obtained in the presenceof 50 mM Tris (ph 8.0) and 18% PEG 600, using the hanging-dropmethod. The protein crystallized in the space group P21, anddiffracted to 1.8Å (Table 1

), with four TCEO moleculesin each asymmetric unit. The structure was solved by molecularreplacement, using E. coli RNase H* as the starting model (Table1

). Residues 3–152 were modeled into the density map oftwo molecules in the asymmetric unit; the remaining two molecules,however, showed no clear density in the basic-helix-loop region(residues 80–97), which is distal to the interface generatedby combining the fragments. The final refined structure hasa crystallographic R-factor (R_cryst) of 24.7, and a free R-factor(R_free) of 28.5%.

View this table:
[in this window]
[in a new window]

Table 1. Crystallographic and refinement data

TCEO adopts the same fold as E. coli RNase H (Fig. 4

). The backboneroot mean square displacement between the two proteins is only0.9 Å. Systematic visual comparison between TCEO and E.coli RNase H reveals that there are no obvious packing defectsalong the interface between the core and the outside region.

View larger version (54K):
[in this window]
[in a new window]

Fig. 4. Ribbon diagram of the crystal structure of TCEO (shown in black) overlaid with the structure of E. coli RNase H* (shown in light gray) (Goedken et al. 2000).

TCEO is more stable than ECTO
The thermodynamic stabilities of both chimeras were measuredby monitoring the thermal- and chemical-induced denaturationby CD, using both urea and guanidinium chloride (GdmCl) as denaturants.All denaturation curves were fit assuming a two-state transitionwith a linear extrapolation model (Santoro and Bolen 1988).

For ECTO, both GdmCl and urea denaturation profiles resultedin a ${Delta}$ G_unf of 5.6 ± 0.3 kcal mole^-1 and m values of 3.9± 0.4 and 1.8 ± 0.2 kcal mole^-1 M^-1, respectively,at 25°C (Fig. 5; Table 2). Thermal denaturation was reversible,with a Tm of 61°C (Fig. 5; Table 2).

View larger version (47K):
[in this window]
[in a new window]

Fig. 5. Thermodynamic stability of TCEO ( ${blacktriangleup}$ ) and ECTO ( ${blacktriangledown}$ ) compared with E. coli ( ${square}$ ) and T. thermophilus RNases H* ( ${circ}$ ): (a) Thermal melts in 1 M guanidium chloride (E. coli RNase H thermal denaturation is not reversible in the absence of denaturants); (b) Guanidinium chloride melts, (c) Urea melts. The error bars correspond to errors of fits to a two-state model.

View this table:
[in this window]
[in a new window]

Table 2. Thermodynamic parameters for ECTO and TCEO chimera, compared with E. coli and T. thermophilus RNases H*

TCEO is thermodynamically more stable than ECTO. GdmCl denaturationyields a ${Delta}$ G_unf of 7.5 ± 0.5 kcal mole^-1 with an m valueof 3.8 ± 0.3 kcal mole^-1 M^-1, whereas urea denaturationyields an even higher ${Delta}$ G_unf of 11.9 ± 0.8 kcal mole^-1,with an m value of 2.0 ± 0.2 kcal mole^-1 M^-1 (Fig. 5

;Table 2

). The Tm of TCEO is 76°C (Fig.5

; Table 2

). BecauseTCEO has a higher Tm and a higher thermodynamic stability (asdetermined by urea denaturation) than E. coli RNase H, TCEOresembles a thermophilic protein.

Stability curves indicate that TCEO has a lower ${Delta}$ Cp than ECTO
Denaturation studies were carried out as a function of temperatureto further characterize the thermodynamic stability of the twochimeras. CD-monitored GdmCl-induced denaturations were followedat eight different temperatures for ECTO and seven differenttemperatures for the TCEO chimera; each profile was fit to atwo-state model to estimate the stability ( ${Delta}$ G_unf) at a giventemperature. Stability curves for ECTO and TCEO were generatedby plotting stabilities as a function of temperature (Pace and Laurents 1989;Fig. 6). Because both chimeras undergo reversiblethermal denaturation in the absence of denaturants, data fromthermal denaturations were also used (squares in Fig. 6). Allof the data points were then fit to the Gibbs-Helmholtz equation(see Materials and Methods).

View larger version (16K):
[in this window]
[in a new window]

Fig. 6. Stability curves TCEO (• and ${blacksquare}$ ) and ECTO ( ${circ}$ and ${square}$ ) compared with the stability curves of T. thermophilus (broken line) and E. coli RNases H (dotted line) (Hollien and Marqusee 1999b). Each circle corresponds to a ${Delta}$ G obtained from a guanidine denaturation experiment. Squares correspond to ${Delta}$ Gs obtained from temperature denaturation experiments. The dash-dot plot represents the constrained fit of TCEO stability data to the Gibbs-Helmholtz equation

, in which ${Delta}$ Cp is fixed at 2.2 kcal mole^-1 K^-1. Fitting the stability curves to Gibbs-Helmholtz equation

(without any constraints) results in ${Delta}$ Cp of 1.6 ± 0.2 kcal mole^–1 K^-1, Tm of 76 ± 1°C, and ${Delta}$ H of 68 ± 2 kcal for TCEO; and ${Delta}$ Cp of 2.4 ± 0.3 kcal mole^-1 K^-1, Tm of 61 ± 1°C, and ${Delta}$ H of 89 ± 2 kcal for TCEO.

The differences in the curvature of the stability curves (Fig.6

) suggest that the change in heat capacity upon unfolding ( ${Delta}$ Cp)is lower for TCEO compared with ECTO. TCEO has a ${Delta}$ Cp of 1.6 ±0.2 kcal mole^-1 K^-1, whereas ECTO has a ${Delta}$ Cp of 2.4 ± 0.3kcal mole^-1 K^-1, compared with 1.8 kcal mole^-1 K^-1 for T. thermophilusRNase H, and 2.7 kcal mole^-1 K^-1 for E. coli RNase H (Hollienand Marqusee 1999b). The lower ${Delta}$ Cp of TCEO mirrors that of T.thermophilus RNase H (Table 2

). Hence, the lower ${Delta}$ Cp, which isan important contributor to the thermophilic profile of T. thermophilusRNase H, tracks with its core and contributes to the thermophile-likeprofile of the TCEO chimera.

Discussion

TOP
Abstract
Introduction
Results
Discussion
Materials and methods
References

Studying chimeric proteins is a powerful way to investigatethe functional and structural relevance of protein domains andfragments. In this study, we investigated the role of the foldingcore in the thermodynamic profile of RNase H, that is, how thefolding core contributes to the thermodynamic stability of RNasesH. In particular, we wanted to know what role the core playedin the thermophilic nature of T. thermophilus RNase H. To thisend, we generated two chimeras by swapping the cores betweenthe T. thermophilus and E. coli RNases H.

The use of chimeras to evaluate contributions of protein segmentsto the stability and folding of the whole protein poses itsown challenges and complications. Packing defects, resultingfrom creation of new interfaces between protein fragments, oftenreduce the overall thermodynamic stability (Kenig et al. 2001).This masks any potential positive contribution of the studiedfragment to the stability of the parent protein. Creation ofnew interfaces within chimeras can even change the folding mechanism(Numata et al. 1999). Disruption of the folding mechanism andintroduction of packing defects can be minimized by carefulselection of boundaries of fragments used to construct a chimericprotein.

Sequence alignments, protease digestions, and analyses of high-resolutionstructures are often used to determine domain boundaries. Inthis study, the rational design of the chimeric proteins wasbased on the RAFT algorithm, which predicts fragments of a proteinlikely to fold independently (Fischer and Marqusee 2000). Wechose the RNase H fragment with the highest RAFT score for bothT. thermophilus and E. coli RNase H. This fragment containsthe two central helices, which play an essential role both inthe thermodynamic stability (Chamberlain et al. 1996; Hollienand Marqusee 1999b) and the kinetic folding pathway of the twoRNases H (Raschke and Marqusee 1997; J. Hollien and S. Marqusee,unpubl.) forming the thermodynamic and the kinetic folding coreof RNase H.

Characterization of both proteins (ECTO, E. coli Core T. thermophilusOutside and TCEO, T. thermophilus Core E. coli Outside) showsthat, despite the introduction of numerous new, potentiallyunfavorable interactions along the interface, both chimerasadopt the normal RNase H fold. This shows that in addition todesign of small protein fragments (its original purpose), theRAFT score is also a useful criterion for choosing boundariesfor chimeras. Successful generation of two well-folded chimeras,which combine cores and outside regions of two different proteins,implies that the folding core of RNase H is indeed an independentfolding module. Not only can the core fold by itself, but also,it can be incorporated successfully into a different RNase Hhomolog.

The two functional chimeric proteins provide a system to assessrelative contributions of core and outside regions to the stabilityand folding of RNase H. If all residues in the sequence wereequally important for thermodynamic stability, we would expectthe ECTO chimera to be more thermostable than TCEO. The coreregion is more conserved between E. coli and T. thermophilusRNases H, than the remaining part of the protein (58% vs. 48%identity for core and outside regions, respectively), and consequentlyECTO shares more of its sequence with T. thermophilus than doesTCEO (80% vs. 70%). Despite this, the TCEO chimera has a higherTm than the ECTO chimera, and is also more thermodynamicallystable at room temperature, as determined by both urea and guanidiniumchloride denaturant titrations.

Interestingly, unlike ECTO, which has the same stability inurea and GdmCl (5.6 kcal mole^-1), TCEO is much more stable inurea compared with GdmCl (11.9 vs. 7.5 kcal mole^-1) at roomtemperature (Table 2). Although discrepancies between ${Delta}$ G_unf values,determined with urea and guanidinium chloride, have been notedfor some proteins, it is usually the value obtained from GdmCldenaturation that is higher than the value obtained in urea(Makhatadze 1999). Perhaps TCEO has a lower stability in GdmClbecause salts destabilize its native state. However, urea denaturationof TCEO in the presence of 1 M KCl yields an even higher stabilitythan the value obtained from urea denaturation in the absenceof salt (data not shown), suggesting that it is not the saltthat preferentially destabilizes the folded state of TCEO.

The discrepancy between stability measurements in urea and GdmClcan be explained by either preferential binding of urea to thenative TCEO, or by preferential binding of GdmCl to the denaturedstate of the TCEO chimera. E. coli RNase H also has a higherstability in urea than in GdmCl, although the difference isnot as large (9.7 vs. 7.6 kcal mole^-1 for urea and GdmCl, respectively).Perhaps, the periphery of E. coli RNase H (which is also presentin TCEO) has more or tighter denaturant-binding sites than mostproteins. The peripheries of E. coli and T. thermophilus RNasesH do not differ significantly in the number and distributionof charged residues (E. coli RNase H has 10 negatively chargedand 9 positively charged residues in the periphery, whereasT. thermophilus RNase H has 9 negatively and 11 positively chargedresidues in the periphery), and, hence, it is difficult to asseswhether guanidine is acting to destabilize TCEO or whether ureastabilizes it.

Despite the lower stability in guanidium (compared with urea),the stability curve shows that TCEO is more stable than ECTOat all temperatures (Fig. 6). This, along with high Tm showsthat the core region plays a significant role in conferringthermophilic character to the profile of this chimeric RNaseH. Furthermore, the stability curve (temperature dependenceof ${Delta}$ G_unf) is shallower for TCEO than ECTO. Therefore, like theparent thermophile, TCEO has a low ${Delta}$ Cp, whereas ECTO has a higher ${Delta}$ Cp, similar to E. coli RNase H. It appears that the ${Delta}$ Cp of eachchimera correlates with that of the parent protein from whichthe core originates. This correlation, as well as the differencein ${Delta}$ Cp between ECTO and TCEO (2.4 ± 0.3 vs. 1.6 ±0.2, respectively), is surprising. The m values and ${Delta}$ Cps arecorrelated for a large set of mesophilic proteins (Myers et al. 1995),and the m values from both urea and guanidium chloridedenaturations do not differ significantly between TCEO and ECTO(Table 2). If we use this correlation to predict the ${Delta}$ Cp basedon the measured m values, we predict a ${Delta}$ Cp close to the observedone for ECTO, but overestimate the ${Delta}$ Cp for TCEO. For ECTO weexpect the ${Delta}$ Cp of 2.2.or 2.1 kcal mole^-1K^-1 (based on GdmCl andurea m values, respectively), which is within the calculatederror of the value obtained from fitting the stability curves(2.4 ± 0.3 kcal mole^-1K^-1). For TCEO the correlationpredicts a ${Delta}$ Cp of 2.2 or 2.3 kcal mole^-1K^-1 (based on GdmCl andurea m values, respectively), which is significantly differentfrom 1.6 ± 0.2 kcal mole^-1K^-1 determined from the stabilitycurves (Table 2). The dash-dot plot in Figure 6 shows that constrainingthe ${Delta}$ Cp to the value predicted by the m value (2.2 kcal mole^-1K^-1) yields a poor fit, which does not account for the measuredstability data.

Our observations lead us to question the way we interpret thechange in heat capacity upon protein unfolding. The ${Delta}$ 4Cp andthe m values are both interpreted in terms of the change inthe accessible surface area (ASA) upon unfolding (Livingstone et al. 1991).We determined the stability curves by measuringthe ${Delta}$ G_unf at different temperatures. If the change in ASA uponunfolding were temperature dependent (i.e., the denatured stateensemble changed significantly different under different conditions),we might not expect the ${Delta}$ Cp derived from a stability curve tocorrelate with the m values measured at room temperature. However,this does not appear to be the case, because for both TCEO andECTO, the m values do not vary systematically with temperature(data not shown). In addition, at any given temperature, them values are not significantly different between the two chimeras.

Perhaps the unusually low ${Delta}$ Cp is a result of a change in thenative state. In the crystal structure of TCEO, residues 80–97were disordered in two of the four molecules in the asymmetricunit. This local disorder could lower the ASA of the nativestate; the smaller change in ASA would account for the smaller ${Delta}$ Cp in TCEO. However, this fails to account for the fact thatthe m values are not significantly different in TCEO and ECTO.It also fails to explain the unusually low ${Delta}$ Cp for T. thermophilusRNase H (Hollien and Marqusee 1999b), in which there is no suchdisorder. Thus, a change in the structure of the native stateis unlikely to account for the unusual ${Delta}$ Cp.

Another possible explanation for the lower ${Delta}$ Cp of the T. thermophilusRNase H and TCEO chimera is a difference in the structure ofthe denatured state. Perhaps for T. thermophilus RNase H andTCEO, the denatured state under native conditions contains residualstructure and is more compact. The m values are derived fromthe transition data in higher denaturant, and therefore, mightnot be expected to follow the same trend. As the common featurebetween these two proteins is the core, this suggests that thecore itself may contain residual structure. We are currentlyinvestigating this possibility using both differential scanningcalorimetry and hydrogen-deuterium exchange in the denaturedstate.

In conclusion, the structural and thermodynamic properties ofthe two chimeras show that the previously identified foldingcores of RNase H are independent folding units that can be combinedsuccessfully with regions from homologous proteins. Whereasboth chimeras are folded and active, only the chimera with thethermophilic core region has thermodynamic parameters that resemblethose of the thermophilic RNase H. These include higher Tm andlower ${Delta}$ Cp, and higher stability, as determined from urea denaturations.This is consistent with the core region playing a dominant rolein the thermostability profile of RNases H.

Materials and methods

TOP
Abstract
Introduction
Results
Discussion
Materials and methods
References

Design and construction of synthetic genes for ECTO and TCEO chimeric RNases H
To define the boundaries for the folding core and the chimeras,we used the RAFT score (Fischer and Marqusee 2000), which identifiesautonomous folding units of proteins, on the basis of the densityof contacts in the three-dimensional structure of the nativeprotein. The core was defined as the protein fragment with thehighest RAFT score. For E. coli RNase H, the highest scoringfragment contained residues 43–122 (Fischer and Marqusee 2000).A homologous fragment (residues 43–122, based onE. coli RNase H amino acid numbering, in which the fifth residueof T. thermophilus RNase H corresponds to the first residueof E. coli RNase H), also scores highest among all possiblecontiguous T. thermophilus RNase H fragments. Prior to constructionof ECTO and TCEO chimeras, we analyzed the crystal structuresof the two parent proteins to investigate whether we would introduceany obvious destabilizing interactions by combining the partsof two different proteins. The program Contacts (Bailey 1994)was used to identify all core residues that are between 0.5Å and 5 Å from a non-core residue. Only non-backbone,non-C ${alpha}$ , non-Cß atoms were considered in this analysis.

Plasmids encoding cysteine-free variants of E. coli (pSM101)(Dabora and Marqusee 1994) and T. thermophilus (pJH109) (Hollienand Marqusee 1999b) RNase H were used to construct the two chimericRNases H. The core regions (residues 43–122, based onE. coli sequence) were amplified by PCR from both parent plasmids.The plasmid PJH109 and the E. coli core amplicon were digestedwith StuI and MluI restriction enzymes, in order to remove thecore-coding sequence from pJH109 and generate the insertionsite for the E. coli RNase H core sequence. The digested vectorand insert were gel purified, ligated together, and sequenced.The resulting plasmid (pSR102) encodes the ECTO chimera (E.coli Core T. thermophilus Outside). Similarly, the plasmid PSM101and the T. thermophilus core amplicon were digested with BstEIIand MluI. The digested vector and insert were gel purified,ligated, and the products of the ligations were sequenced. Theresulting plasmid (pSR202) encodes the TCEO chimera (T. thermophilusCore E. coli Outside).

Expression and purification of ECTO and TCEO proteins
Plasmids encoding the TCEO and ECTO chimeras were transformedinto E. coli BL21 pLys S (Novagen) cells. TCEO transformantswere grown at 30°C (no colonies appeared if grown at 37°C),whereas ECTO transformants were grown at 37°C. Liquid cultures,started from individual colonies grown in Luria broth, with200 µg/mL ampicillin were induced with 1 mM IPTG at anA₆₀₀ of 0.5. Cells expressing ECTO were induced for 3 h at 37°Cbefore harvesting, whereas cells expressing TCEO were inducedfor 4.5 h at 30°C.

Cells were harvested by centrifugation and lysed by sonicationin 50 mM Tris (pH 8.0), 20 mM NaCl, 0.1 mM EDTA (buffer A).Both TCEO and ECTO were found in the soluble fraction, whichwas loaded onto a FPLC heparin column pre-equilibrated withbuffer A. The bound ECTO protein was eluted by a linear gradientbetween 20 and 600 mM NaCl (protein eluted at 400 mM NaCl),in 50 mM Tris (pH 8.0) and 0.1 mM EDTA. The pH of the pooled,protein-containing fractions was adjusted to pH 5.5 using concentratedacetic acid, and the solution was diluted to a final concentrationof 200 mM NaCl. The protein sample was then applied to a SourceS15 FPLC column pre-equilibrated with 20 mM NaOAc (pH 5.5),200 mM NaCl, and 0.1 mM EDTA, and was eluted with a linear gradientbetween 200 and 400 mM NaCl (protein eluted at 300 mM NaCl).TCEO was purified over a heparin FPLC column at pH 8.0, followingthe same protocol as for ECTO (see above). ECTO eluted at 400mM NaCl. Pooled heparin fractions were concentrated (by ammoniumsulfate precipitation or Amicon concentrators), to the finalvolume of 5–10 mL, and applied to a gravity-flow SephadexG-75 gel filtration column. The molecular weight of pure ECTOand TCEO RNases H (as determined by SDS-PAGE) was confirmedby mass spectrometry. Pure protein was dialyzed into 50 mM ammoniumbicarbonate (pH 7.0), lyophilized, and stored in powder form.

Circular dichroism studies
Circular dichroism (CD) spectra of ECTO and TCEO chimera werecollected on an Aviv 62DS spectrometer, in a 1-cm pathlengthcuvette at 25°C. The spectra were taken in 5 mM NaOAC (pH5.5).Data points were recorded from 300 to 200 nm, at 0.5-nm intervals.Each data point was averaged for 3 sec.

Thermal and chemical (urea and guanidium chloride) denaturationswere monitored by CD at 222 nm. All experiments were performedin 1-cm pathlength cuvettes, using 50 µg/mL of proteinin 20 mM NaOAc and 50 mM KCL (pH 5.5). For thermal denaturation,data were gathered every 3°C, with a 3-min equilibrationtime, and each data point was averaged for 1 min. To test thereversibility of thermal denaturation, a CD spectrum was takenat room temperature after thermal denaturation, and comparedwith the spectrum taken prior to denaturation. Reversibilitywas defined as preservation of more than 95% of CD signal between220 and 225 nm. For guanidinium chloride and urea-induced denaturation,individual samples with various concentrations of denaturantwere prepared and equilibrated for 24 h at room temperature.The CD signal of each sample was averaged for 1 min. Denaturantconcentrations were verified using a refractometer (Pace et al. 1989).

To generate stability curves for TCEO and ECTO, GdmCl-induceddenaturation experiments (see above), were performed at differenttemperatures (Pace and Laurents 1989), ranging from 4 to 45°C.GdmCl was chosen as the denaturant for comparison with previousstudies on the parent proteins (Hollien and Marqusee 1999b).Samples were equilibrated at appropriate temperatures (in aheat block or in an ice-water bath) between 4 and 24 h priorto CD measurements (longer at lower temperatures). Each samplewas further equilibrated for 3 min more, after it was placedin the CD sample holder with a Peltier temperature regulator.

Denaturation free energies ( ${Delta}$ G_unf) were determined from GdmCl-induceddenaturation experiments at different temperatures, assuminga two-state model and a linear dependence of ${Delta}$ G_unf on the concentrationof GdmCl (Santoro and Bolen 1988). Thermal melts were fit toa two-state model, to determine the Tm of each protein, andthe ${Delta}$ G_unf in the transition range of the thermal denaturationprofile. The free energies of unfolding, obtained from bothGdmCl and thermal denaturation experiments, were plotted asa function of temperature. Each point on the stability curveis the average of at least two experiments. The stability curvedata were fit to the Gibbs-Helmholtz equation:

(1)
inwhich ${Delta}$ H^o is the enthalpy at Tm, and ${Delta}$ C_p is the change in heatcapacity upon unfolding (Becktel and Schellman 1987). We assumedthat ${Delta}$ C_p is constant in the experimental temperature range. Allcurve fitting was done using Sigma Plot (Jandel Scientific).

Activity assay
A UV-based spectrophotometric RNase H assay was used to testthe activity of the two chimeras (partially on the basis ofBlack and Cowan 1994). The assay measures the loss of hypochromiceffect resulting from the cleavage of the RNA moiety in DNA–RNAhybrids. Reactions were initiated by addition of 5 nM of ECTOor TCEO to a solution containing 25 µg/mL of an RNA/DNAhybrid (poly-rA/poly-dT) in the presence of 10 mM MgCl₂ and50 mM Tris (pH8.0) at 25°C. The loss of hypochromic effectwas measured by monitoring the increase of absorbance at 260nM. Activity was determined from the slope of the initial linearphase of the kinetic profile.

Equilibrium sedimentation
Ultracentrifugation experiments were performed in a BeckmanOptima XL-A ultracentrifuge. Measurements were performed atthree different concentrations of each chimera (ranging from50 to 400 µg/mL), in 20 mM NaOAC and 50 mM KCl (pH5.5)at 25°C (the same conditions as the CD experiments).

Crystal structure of TCEO
The hanging-drop method was used to set crystal trays with TCEOand ECTO chimeras. Lyophilized protein was dissolved in waterand filtered through 0.2-µm HT Tuffryn filters (Pall GelmanLaboratory), resulting in the final protein concentration of6 mg/mL. Precipitant (PEG and Ammonium Sulfate) concentration,pH, and salt concentration were varied around the conditionsin which E. coli RNase H* crystallized (Goedken et al. 2000).Octahedral crystals of TCEO were grown in 50 mM Tris (pH8.0)and 18% PEG₆₀₀, flash-frozen directly from the drop into liquidnitrogen, and screened for diffraction on a Rigaku RU-200 generatorequipped with a IIc detector. The full X-ray diffraction dataset (280 frames) was collected at Stanford Synchrotron RadiationLaboratory Beamline 9.2. The data were integrated and scaledusing Denzo and Scale Pack (Otwinowski and Minor 1997). Thenumber of molecules per asymmetric unit (ASU) was calculatedassuming the Matthews coefficient of 2.5 Å³/Da (Matthews 1968).

The crystal structure was solved by molecular replacement usingAMoRe (Navaza 1993) and CNS (Brunger et al. 1998), with thecysteine-free variant of E. coli RNase H structure as the startingmodel (Protein Data Bank [PDB] code 1F121). All residues thatdiffered between E. coli RNase H* and TCEO were replaced withserines in the starting model. Models for each one of the fourTCEO molecules in the ASU were built in O (Jones et al. 1991).The model was further refined using RefMac (Murshudov et al. 1997)and CNS (Brunger et al. 1998). Cycles of model buildingand refinement were repeated until the free R-factor converged.The coordinates have been deposited in the PDB (PDB code 1JL2).

Acknowledgments

This work was supported by NIH grant GMS0945. We thank EricGoedken and James Holton for assistance with X-ray crystallography;Sarah McWhirter for synchrotron data collection; Giulietta Spudichfor critical reading of this manuscript; Kael Fisher for RAFTscores for RNase H fragments, help with equilibrium centrifugations,discussions about chimera design, and reading of this manuscript;and David King for mass spectromentry.

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

Bailey, S. 1994. The Ccp4 suite – programs for protein crystallography. Acta Crystallogr. Sect. D-Biol. Crystallogr. 50: 760–763.[CrossRef][Medline]

Becktel, W.J. and Schellman, J.A. 1987. Protein stability curves. Biopolymers 26: 1859–1877.[CrossRef][Medline]

Black, C.B. and Cowan, J.A. 1994. Magnesium aactivation of ribonuclease H – evidence for one catalytic metal ion. Inorganic Chem. 33: 5805–5808.[CrossRef]

Brunger, A.T., Adams, P.D., Clore, G.M., Delano, W.L., Gros, P., Grosse-Kunstleve, R.W., Jiang, J.-S., Kuszewski, J., Nilges, M., Pannu, N.S., et al. 1998. Crystallography and NMR system: A new software suite for macromolecular structure determination. Acta Crystallogr. Sect. D Biol.l Crystallogr. 54: 905–921.[CrossRef][Medline]

Chamberlain, A.K., Fisher, K.F., Reardon, D., Handel, T.M., and Marqusee, S. 1999. Folding of an isolated ribonuclease H core fragment. Protein Science 8: 2251–2257.[Abstract]

Chamberlain, A.K., Handel, T.M., and Marqusee, S. 1996. Detection of rare partially folded molecules in equilibrium with the native conformation of RNaseH. Nat. Struct. Biol. 3: 782–787.[CrossRef][Medline]

Dabora, J.M. and Marqusee, S. 1994. Equilibrium unfolding of Escherichia coli ribonuclease H: Characterization of a partially folded state. Protein Sci. 3: 1401–1408.[Abstract]

Fischer, K.F. and Marqusee, S. 2000. A rapid test for identification of autonomous folding units in proteins. J.Mol. Biol. 302: 701–712.[CrossRef][Medline]

Goedken, E.R., Keck, J.L., Berger, J.M., and Marqusee, S. 2000. Divalent metal cofactor binding in the kinetic folding trajectory of Escherichia coli ribonuclease HI. Protein Sci. 9: 1914–1921.[Abstract]

Hollien, J. and Marqusee, S. 1999a. Structural distribution of stability in a thermophilic enzyme. Proc. Natl. Acad. Sci. 96: 13674–13678.[Abstract/Free Full Text]

———. 1999b. A thermodynamic comparison of mesophilic and thermophilic ribonucleases H. Biochemistry 38: 3831–3836.[CrossRef][Medline]

Ishikawa, K., Okumura, M., Katayanagi, K., Kimura, S., Kanaya, S., Nakamura, H., and Morikawa, K. 1993. Crystal structure of ribonuclease H from Thermus thermophilus HB8 refined at 2.8 A resolution. J. Mol. Biol. 230: 529–542.[CrossRef][Medline]

Jones, T.A., Zou, J.Y., Cowan, S.W., and Kjeldgaard, M. 1991. Improved methods for building protein models in electron density maps and the location of errors in these models. Acta Crystallogr. Sect. a-Found. Crystallogr. 47: 110–119.[CrossRef]

Kenig, M., Jerala, R., Kroon-Zitko, L., Turk, V., and Zerovnik, E. 2001. Major differences in stability and dimerization properties of two chimeric mutants of human stefins. Proteins 42: 512–522.[CrossRef][Medline]

Livingstone, J.R., Spolar, R.S., and Record, Jr., M.T. 1991. Contribution to the thermodynamics of protein folding from the reduction in water-accessible nonpolar surface area. Biochemistry 30: 4237–4244.[CrossRef][Medline]

Makhatadze, G.I. 1999. Thermodynamics of protein interactions with urea and guanidinium hydrochloride. J. Phys. Chem. B 103: 4781–4785.[CrossRef]

Matthews, B.W. 1968. Solvent content of protein crystals. J. Mol. Biol, 33: 491–497.[Medline]

Murshudov, G.N., Vagin, A.A., and Dodson, E.J. 1997. Refinement of macromolecular structures by the maximum-likelihood method. Acta Crystallogr. Sect. D Biol. Crystallogr. 53: 240–255.[CrossRef][Medline]

Myers, J.K., Pace, C.N., and Scholtz, J.M. 1995. Denaturant m values and heat capacity changes: Relation to changes in accessible surface areas of protein unfolding. Protein Sci. 4: 2138–2148.[Abstract]

Navaza, J. 1993. On the computation of the fast rotation function. Acta Crystallogr. Sect. D Biol. Crystallogr. 49: 588–591.[CrossRef][Medline]

Numata, K., Hayashiiwasaki, Y., Yutani, K., and Oshima, T. 1999. Studies on interdomain interaction of 3-isopropylmalate dehydrogenase from an extreme thermophile, Thermus thermophilus, by constructing chimeric enzymes. Extremophiles 3: 259–262.[CrossRef][Medline]

Otwinowski, Z. and Minor, W. 1997. Processing of X-ray diffraction data collected in oscillation mode. Methods Enzymol. 276: 307–326.

Pace, C.N. and Laurents, D.V. 1989. A new method for determining the heat capacity change for protein folding. Biochemistry 28: 2520–2525.[CrossRef][Medline]

Pace, C.N., Shirley, B.A., and Thomson, J.A. 1989. Protein structure : A practical approach. In: Protein structure : A practical approach. (ed. T. Creighton), pp. 330–331. Oxford IRL Press, Washington, DC.

Raschke, T.M. and Marqusee, S. 1997. The kinetic folding intermediate of ribonuclease H resembles the acid molten globule and partially unfolded molecules detected under native conditions. Nature Struct. Biol. 4: 298–304.[CrossRef][Medline]

Santoro, M.M. and Bolen, D.W. 1988. Unfolding free energy changes determined by the linear extrapolation method. 1. Unfolding of phenylmethanesulfonyl alpha-chymotrypsin using different denaturants. Biochemistry 27: 8063–8068.[CrossRef][Medline]

Add to CiteULike CiteULike Add to Connotea Connotea Add to Del.icio.us Del.icio.us Add to Digg Digg Add to Reddit Reddit Add to Technorati Technorati What's this?

This article has been cited by other articles:

S. Robic, M. Guzman-Casado, J. M. Sanchez-Ruiz, and S. Marqusee
Role of residual structure in the unfolded state of a thermophilic protein
PNAS, September 30, 2003; 100(20): 11345 - 11349.
[Abstract] [Full Text] [PDF]

A. Mozo-Villarias, J. Cedano, and E. Querol
A simple electrostatic criterion for predicting the thermal stability of proteins
Protein Eng. Des. Sel., April 1, 2003; 16(4): 279 - 286.
[Abstract] [Full Text] [PDF]

H.-X. Zhou
Toward the Physical Basis of Thermophilic Proteins: Linking of Enriched Polar Interactions and Reduced Heat Capacity of Unfolding
Biophys. J., December 1, 2002; 83(6): 3126 - 3133.
[Abstract] [Full Text] [PDF]

This Article

Abstract

Full Text (PDF)

Alert me when this article is cited

Alert me if a correction is posted

Citation Map

Services

Email this article to a friend

Similar articles in this journal

Similar articles in PubMed

Alert me to new issues of the journal

Download to citation manager

Citing Articles

Citing Articles via HighWire

Citing Articles via Google Scholar

Google Scholar

Articles by Robic, S.

Articles by Marqusee, S.

Search for Related Content

PubMed

PubMed Citation

Articles by Robic, S.

Articles by Marqusee, S.

Social Bookmarking

What's this?

				A. Mozo-Villarias, J. Cedano, and E. Querol A simple electrostatic criterion for predicting the thermal stability of proteins Protein Eng. Des. Sel., April 1, 2003; 16(4): 279 - 286. [Abstract] [Full Text] [PDF]

				H.-X. Zhou Toward the Physical Basis of Thermophilic Proteins: Linking of Enriched Polar Interactions and Reduced Heat Capacity of Unfolding Biophys. J., December 1, 2002; 83(6): 3126 - 3133. [Abstract] [Full Text] [PDF]