Resurrecting Abandoned Proteins with Pure Water: CD and NMR Studies of Protein Fragments Solubilized in Salt-Free Water

doi:10.1529/biophysj.106.093187

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Resurrecting Abandoned Proteins with Pure Water: CD and NMR Studies of Protein Fragments Solubilized in Salt-Free Water

Minfen Li^*, Jingxian Liu, Xiaoyuan Ran, Miaoqing Fang^*, Jiahai Shi^*, Haina Qin^*, June-Mui Goh^* and Jianxing Song^*

^* Department of Biological Sciences, Faculty of Science; and Department of Biochemistry, Yong Loo Lin School of Medicine, National University of Singapore, Singapore

Correspondence: Address reprint requests to Jianxing Song, Dept. of Biological Sciences, Faculty of Science, National University of Singapore, 10 Kent Ridge Crescent, Singapore 119260. Tel.: 65-6874-1013; Fax: 65-6779-2486; E-mail: bchsj{at}nus.edu.sg.

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSIONS
ACKNOWLEDGEMENTS
REFERENCES

Many proteins expressed in Escherichia coli cells form inclusionbodies that are neither refoldable nor soluble in buffers. Verysurprisingly, we recently discovered that all 11 buffer-insolubleprotein fragments/domains we have, with a great diversity ofcellular function, location, and molecular size, could be easilysolubilized in salt-free water. The circular dichroism (CD)and NMR characterization led to classification of these proteinsinto three groups: group 1, with no secondary structure by CDand with narrowly-dispersed but sharp ¹H-¹⁵N heteronuclear singlequantum correlation (HSQC) peaks; group 2, with secondary structureby CD but with HSQC peaks broadened and, consequently, onlya small set of peaks detectable; and group 3, with secondarystructure by CD and also well-separated HSQC peaks. Intriguingly,we failed to find any protein with a tight tertiary packing.Therefore, we propose that buffer-insoluble proteins may lackintrinsic ability to reach or/and to maintain a well-packedconformation, and thus are trapped in partially-folded stateswith many hydrophobic side chains exposed to the bulk solvent.As such, a very low ionic strength is sufficient to screen outintrinsic repulsive interactions and, consequently, allow thehydrophobic clustering/aggregation to occur. Marvelously enough,it appears that in pure water, proteins have the potential tomanifest their full spectrum of structural states by utilizingintrinsic repulsive interactions to suppress the attractivehydrophobic clustering. Our discovery not only gives a novelinsight into the properties of insoluble proteins, but alsosheds the first light that we know of on previously unknownregimes associated with proteins.

INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSIONS
ACKNOWLEDGEMENTS
REFERENCES

Proteins are important functional players that implement themost difficult but essential tasks in living cells (1). However,one commonly-encountered problem in protein research and applicationis their insolubility (2). For example, in most structure genomicsinitiatives it has been estimated that $~$ 35–50% of the proteinsexpressed in Escherichia coli cells were in inclusion bodies,most of which were not refoldable in buffer systems (3,4) withcurrently-available methods. In fact, it is extensively foundthat many proteins misfold and subsequently aggregate when overproducedin microorganisms (4), although it remains unknown whether theseproteins will misfold in vivo. Despite extensive attempts toreduce formation of inclusion bodies in E. coli cells by fusingwith a highly-soluble tag, coexpressing folding catalysts andchaperones, reducing culture temperature, and modifying culturemedia, these approaches do not always work (5). This observationimplies that the intrinsic property of a protein may be responsiblefor its insolubility. Therefore, structural characterizationof insoluble proteins will provide valuable insights and consequentlyoffer rationales for enhancing protein solubility. Unfortunately,to date no general method is available to solubilize these proteinswithout addition of detergents or/and denaturants such as sodiumdodecyl sulfate, urea, and guanidine hydrochloride at high concentrations.

Very unexpectedly, we recently discovered that several buffer-insolubleNogo-66 fragments could be easily solubilized in water at highconcentrations. In particular, this discovery allowed us todetermine the NMR structure and dynamics of Nogo-60 and, subsequently,to obtain a critical rationale to further design the structuredand buffer-soluble Nogo-54 (6). This result inspired me to explorethe general question of whether other buffer-insoluble proteinsalso could be solubilized in water. To address this, we haveinitiated a systematic study on all 11 buffer-insoluble proteinfragments/domains we currently have, which are very diversein cellular function, location, and molecular size. To our greatsurprise, again they could be dissolved in salt-free water athigh concentrations. This discovery therefore offers us an unprecedentedpossibility to characterize them by circular dichroism (CD)and NMR ¹H-¹⁵N heteronuclear single quantum correlation (HSQC)spectroscopy.

MATERIALS AND METHODS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSIONS
ACKNOWLEDGEMENTS
REFERENCES

Selection of protein fragments/domains
All protein fragments/domains studied here were fused with aHis-tag for affinity purification. The His-tag is composed of16 residues with a sequence of MHHHHHHSSG LVPRGS and a molecularmass of 1.8 kD. The molecular mass values stated below alreadyincluded the contribution of the His-tag.

Fragments of the Nogo-66extracellular domain: Nogo proteinsare myelin-associated transmembraneproteins that play a criticalrole in inhibiting central nervoussystem (CNS) axonal regeneration.Nogo is composed of threesplicing variants, namely the 1192-residueNogo-A, 373-residueNogo-B, and 199-residue Nogo-C. Despitetheir significant sizedifferences, all three Nogo variantscontain a conserved extracellulardomain with $~$ 66 residues thatis capable of inhibiting neuritegrowth and inducing growthcone collapse. In this study, fourdifferentially-truncatedfragments of the Nogo-66 domain wereincluded, namely, Nogo-66,with a MM of 9.3 kD spanning residues1055–1120 of Nogo-A(AAM64248); Nogo-60, with a MM of8.7 kD over residues 1055–1114;Nogo-(21-60), with a MMof 6.3 kD over residues 1075–1114;and Nogo-54, with aMM of 8.0 kD over residues 1055–1108.Only one cysteineis presented in these fragments, and thereforeno disulfidebridge is expected to form.
Fragments of the attachment glycoprotein(G) of Nipah virus:the G-protein of Nipah virus is a 602-residueviral surfaceprotein that was shown to mediate viral entryby interactingwith ephrinB ectodomains. In this study, twodissected fragmentsof the G-protein were included, namely Niv-44,with a MM of6.7 kD, spanning residues 430–473; Niv-86,with a MM of11.6 kD, spanning residues 402–487 of theNipah G-protein(AAF73957). There is no cysteine residue inthe two fragments.
Hemagglutinin receptor binding domain (RBD):the 152-residueRBD was dissected from the 561-residue hemagglutininof theAvian Influenza A virus, with a MM of 19.1 kD, spanningresidues126–277 (AAT73276.1). There is only one cysteineresidueand therefore no disulfide is expected to form.
SH3domains of the human Nck2 (hNck2) protein: based on ourpreviousstudy, the first SH3 domain of the 381-residue humanNck2 proteinis totally insoluble (7). Therefore, in this study,we includedthe first SH3 domain, with a MM of 8.8 kD, spanningresidues5–62 of the human Nck2 (AAC04831).
Wrch1 Cdc42-likedomain: Wrch1 protein is a 270-residue newmember of the Cdc42superfamily, unique in having a Cdc42-likedomain but no GTPaseactivity. In our previous study (7), weinvestigated the bindinginteraction between Nck2 SH3 domainsand the Wrch1 N-terminus(highly soluble). However, we foundthat the Wrch1 Cdc42-likedomain was totally buffer-insoluble.As such, we include the173-residue Cdc42-like domain here witha MM of 20.7 kD overresidues 52–225 of the human Wrch1(BAD92748).
The Claudin1 extracellular domain: the entire first ectodomainof the 211-residuehuman Claudin 1 was selected, namely Claudin-51,with a MM of7.4 kD spanning residues 31–81 of the humanClaudin 1(AAK20945). There are two cysteines in the sequence,and thusthey are expected to form one intramolecular disulfidebridge.
Dissected domains of Nogo receptor (NgR): NgR is a 473-residuemyelin protein GPI-anchored onto the cell membrane, which transmitssignals to inhibit CNS axonal regeneration by interacting Nogo-66or other binding-partner proteins. Here, we cloned two NgR fragments,one composed only of the 319-residue Nogo-66 binding domain,with a MM of 36.8 kD, spanning residues 26–344 (AAG53612).Another covered the entire 421-residue ectodomain of the NgRreceptor, with only signal peptide and GPI-anchor sequencesremoved, having a MM of 47 kD, spanning residues 26–446.It is expected that the N-terminal NgR will have five disulfidebridges formed, whereas the entire NgR ectodomain will havesix disulfide bridges.

Cloning and expression
Except for DNA fragments encoding the hNck SH3 domains, whichwere obtained by polymerase chain reaction-based de novo genesynthesis with E. coli preferred codons (7), all other fragmentswere polymerase chain-reacted out from cDNA templates by designedprimers. The obtained DNA segments were subsequently clonedinto the His-tagged expression vector pET32a (Novagen, Madison,WI), as previously described.

Recombinant proteins were overexpressed in the E. coli bacterialstrain BL21 cells. Briefly, the cells were cultured at 37°Cto reach an OD₆₀₀ of 0.6, and then isopropyl-ß-D-thiogalactopyranosidewas added to a final concentration of 1 mM to induce the recombinantprotein expression for 4 h at 37°C. Except for Nogo-54,the rest of the proteins were found to be totally in inclusionbodies and, as such, were first purified by Ni²⁺-affinity chromatographyunder denaturing conditions in the presence of 8 M urea. Subsequently,100 mM dithiothreitol was added to affinity-purified proteinsin the 8 M urea for half an hour to reduce the possibility offorming disulfide bridges if those proteins contained cysteineresidues. Depending on their molecular size, these proteinswere finally purified by the reverse-phase high-performanceliquid chromatography (HPLC) on a semipreparative C18, C8, orC4 column (Vydac, Hesperia, CA) and then lyophilized. For NMRisotope labeling, recombinant proteins were prepared by growingthe cells in the M9 medium with the addition of (¹⁵NH4)₂SO₄for ¹⁵N labeling (7).

Sample preparation and CD, NMR experiments
Except for Nogo-54, which was soluble in both water and buffer,all other protein fragments/domains were insoluble in buffer.Therefore, they were dissolved in deionized water (Milli-Q,Millipore, Billerica, MA) with addition of an aliquot of 5 mMNaOH to adjust pH and of 10% D₂O for spin-lock.

CD experiments were performed on a J-810 spectropolarimeter(Jasco, Tokyo, Japan) equipped with a thermal controller, asdescribed previously (7). The far-UV CD spectra were collectedin a wide range of peptide concentrations at 20°C, usinga 1-mm path length cuvette with a 0.1-nm spectral resolution.The near-UV CD spectra were collected at a protein concentrationof $~$ 200 µM in the absence and in the presence of 8 M urea.Data from five independent scans were added and averaged.

HSQC NMR experiments were acquired on an 800-MHz Bruker Avancespectrometer (Bruker Daltonics, Billerica, MA) equipped withpulse-field gradient units at 293 K, as described previously(8). NMR data were processed with NMRPipe (9) and analyzed withNMRView (10). The three-dimensional structures were displayedand drawn using MolMol software (11).

RESULTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSIONS
ACKNOWLEDGEMENTS
REFERENCES

In this study, we have included all 11 buffer-insoluble proteinfragments/domains currently in our laboratory. They are composedof extracellular protein domains, including those dissectedfrom Nogo-66, Nipah virus G-protein, Claudin, avian flu hemaglutinin,and Nogo receptor (NgR), as well as cytoplasmic protein domainsincluding the first Nck2 SH3 and Wrch1 Cdc42-like domains. DNAfragments encoding the above 11 proteins plus Nogo-54 were successfullycloned into expression vector pET32a (Novagen) as His-taggedforms and subsequently expressed in E. coli BL21 cells. Exceptfor Nogo-54, the 11 proteins were all found in inclusion bodiesand could not be refolded by either fast dilution or dialysis.Nevertheless, we purified them first by affinity and then byreverse-phase HPLC chromatography for further CD and NMR assessmentin salt-free water.

Nogo-66 fragments
The entire Nogo extracellular domain consists of 66 residues,usually called Nogo-66. Previously, Nogo-66 was found to betotally insoluble in buffer and, as such, only Nogo-40, withC-terminal 26 residues removed, was studied with the presenceof 50% trifloroethanol TFE (12). However, we now found thatNogo-66, along with its truncated forms, all could be solubilizedin salt-free water. As seen in Fig. 1, whereas Nogo-66 had afar-UV CD spectrum typical of helical structure (Fig. 1 a),only five HSQC peaks resulting from non-His-tag residues weredetectable (Fig. 1 b). This observation was attributed to conformationalexchanges on the microsecond to millisecond timescale (6). Onthe other hand, although two truncated forms, namely Nogo-60and Nogo-(21-60) were again only soluble in salt-free water,they both have helical CD spectra (Fig. 1, c and e) and well-separatedHSQC spectra, with almost all nonproline residues detectable(Fig. 1, d and f). This discovery thus led to our previous determinationof the solution structure and dynamics of Nogo-60 (Fig. 2 a),as well as further design of Nogo-54, which was structured andsoluble in both salt-free water and buffer (6). A detailed comparisonof the C ${alpha}$ H conformational shifts indicated that Nogo-54 had astructure almost identical to the corresponding region of Nogo-60(M. Li and J. Song, unpublished). Also, it is worthwhile topoint out that the structures of Nogo-54 in salt-free waterand buffer were essentially the same, as is clearly evidentfrom its superimposable CD (Fig. 2 b) and HSQC (Fig. 2 c) spectra.

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FIGURE 1 CD and HSQC characterization of Nogo-66 fragments. (a and b) Far-UV CD and NMR HSQC spectra of Nogo-66; (c and d) Nogo-60; and (e and f) Nogo-(21-60). All three peptides were only soluble in salt-free water (pH 4.0), with protein concentrations of $~$ 100 µM for Nogo-66, and $~$ 200 µM for Nogo-60 and Nogo-(21-60). NMR spectra were acquired on a Bruker Avance 800 MHz NMR spectrometer at 20°C.

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FIGURE 2 Conformational properties of Nogo-54. (a) NMR structure of Nogo-60 previously determined (PDB ID: 2G31) in salt-free water. Based on this structure, the buffer-soluble Nogo-54 was thus designed by deleting the C-terminal six unstructured residues (circles), which constitute an exposed hydrophobic patch. (b and c) Far-UV CD and NMR HSQC spectra of Nogo-54 in salt-free water (blue) and in 10 mM phosphate buffer (red) at pH 4.2 and 20°C. The protein concentrations of the NMR samples were $~$ 120 µM in both water and buffer.

Viral surface protein fragments
The G-protein of Nipah virus is a 602-residue viral surfaceprotein which was recently demonstrated to mediate viral entryby interacting with ephrinB ectodomains. Previously we havecloned two G-protein fragments but found them to be totallyinsoluble in buffer and thus not open to study. However, bothfragments Niv-44 and Niv-88 could be easily solubilized in salt-freewater. As seen in Fig. 3 a, the far-UV CD spectrum indicatedthat the 44-residue Niv-44 definitely was not unstructured butinstead it might have a helical and/or loop conformation. Onthe other hand, HSQC peaks for almost all residues were detectable(Fig. 3 b), thus recommending its suitability for further high-resolutionNMR study. On the other hand, although the 86-residue Niv-86with sequence extensions at both termini of Niv-44 still owneda similar CD spectrum (Fig. 3 a), only $~$ 24 non-His-tag HSQC peakswere detectable (Fig. 3 b), indicating that the introductionof additional residues resulted in an increase of µs-msconformational exchange or/and dynamic aggregation.

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FIGURE 3 CD and HSQC characterization of Nipah G-protein fragments. (a and d) Far-UV CD and HSQC NMR spectra of the Nipah G fragment Niv-44 (44 residues) and Niv-86 (86 residues) at pH 3.8 and 20°C. The protein concentrations of the NMR samples were $~$ 460 µM for Niv-44 and $~$ 340 µM for Niv-86.

We previously isolated the RBD from the 561-residue avian influenzahemagglutinin in an attempt to solve its NMR structure and toscreen binding ligands. Unfortunately, although RBD has a well-definedß-structure (Fig. 4 a) in the context of the entirehemagglutinin, the isolated RBD was found to be totally insoluble.Amusingly, this 152-residue domain was again soluble in salt-freewater and had a CD spectrum characteristic of an unstructuredprotein (Fig. 4 b). In agreement with this, the RBD had a narrowly-dispersedHSQC spectrum with almost all nonproline residues detectable.In particular, all nine Gly residues (including one from His-tag)were clearly-resolved (Fig. 4 c), thus indicating that the proteinis highly unfolded in salt-free water. This result also revealedthat the RBD is not an autonomous folding unit, needing otherparts of hemagglutinin to maintain its three-dimensional structureas determined by x-ray crystallography (13

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FIGURE 4 CD and HSQC characterization of viral hemagglutinin RBD. (a) Three-dimensional structure of the RBD in the context of the entire hemagglutinin molecule (PDB code 1JSN). (b and c) Far-UV CD and NMR HSQC spectra of the receptor binding domain (152 residues) dissected from the 561-residue hemagglutinin of the Avian Influenza A virus at pH 6.2 and 20°C. The protein concentration of the NMR sample was $~$ 400 µM. The HSQC peaks for nine Gly residues (including one from His-tag) are indicated by the arrow.

Intracelluar protein domains
Recently, we determined the NMR structures of the second andthird hNck2 SH3 domains but found that the first SH3 domain(SH3-1) with the sequence derived from AAC04831 was totallyinsoluble (12

). On the other hand, the hNck2 SH3-1 derived fromanother hNck2 protein sequence was soluble and its NMR structurewas reported (Fig. 5 a) (14

). Comparison of the two SH3-1 sequencesrevealed that in our SH3-1 protein, an additional Val residuewas presented at the diverging turn linking the RT-loop to thesecond ß-strand, and consequently, this insertionresulted in the insolubility of our 58-residue hNck2 SH3-1.However, this SH3-1 domain was again soluble in salt-free waterbut appeared to be highly denatured, as indicated by its CD(Fig. 5 b) and HSQC (Fig. 5 c) spectra. In particular, its HSQCspectrum had very narrow dispersions ( $~$ 0.7 ppm over proton and $~$ 19 ppm over ¹⁵N dimensions), with peaks detectable for almostall nonproline residues. Very unexpectedly, with our extensiveheteronuclear NMR characterization, this denatured SH3 domainwas just mapped out to have a native-like topology with significantlylimited backbone motions but meanwhile, its secondary structureshifts were demonstrated to be severely abolished (J. Liu andJ. Song, unpublished).

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FIGURE 5 CD and HSQC characterization of the first Nck2 SH3 domain. (a) The NMR structure of the first human Nck2 SH3 domain (PDB code 2B86). (b and c) Far-UV CD and NMR HSQC spectra of the first SH3 domain (58 residues) of the human Nck2 protein (AAC04831) at pH 6.2 and 20°C. The protein concentration of the NMR sample was $~$ 200 µM.

On the other hand, the 173-residue Wrch1 Cdc42-like domain solubilizedin salt-free water showed a CD spectrum for a mixture of helix,ß-sheet, and random coil (Fig. 6 a). CD spectral decomposition(www.embl-heidelberg.de/ $~$ andrade/k2d.html) further revealed thatthe Wrch1 Cdc42 domain contained $~$ 15% ${alpha}$ -helix; $~$ 33% ß-sheet,and 52% random coil, very similar to the secondary structurepatterns observed for its homolog, the human Cdc42 protein (15

)(Fig. 6 c). This strongly implied that the Wrch1 Cdc42-likedomain already assumed a native-like secondary structure insalt-free water. On the other hand, it had an HSQC spectrumwith a narrow dispersion ( $~$ 0.6 ppm over proton and $~$ 22 ppm over¹⁵N dimensions) and with only $~$ 30 broad NMR peaks detectable(Fig. 6 b). This phenomenon has been extensively observed forthe molten globule states due to the loose side-chain packing(16

–19

). To assess the degree of the side-chain packing,we collected its near-UV and HSQC spectra in the absence andpresence of 8 M urea. As expected, there was no significantdifference between the near-UV spectra in salt-free water and8 M urea (spectra not shown), indicating that the tight side-chainpacking was largely disrupted even without 8 M urea. Nevertheless,addition of 8 M urea did result in a dramatic increase of detectableHSQC peaks (Fig. 6 b), indicating that besides the native-likesecondary structure, Cdc42-like domain also owned a native-liketopology, as previously demonstrated on ${alpha}$ -lactalbumin and CHABIImolten globules (16

–19

). These results together stronglysuggested that although salt-free water offered the media forthe Wrch1 Cdc42-like domain to be soluble and manifest its intrinsicstructural propensity, it was somehow trapped in the molten-globulestate with a native-like secondary structure and tertiary topology,but without a tight side-chain packing. To further transformit into a protein with a buffer solubility and tight side-chainpacking, the introduction of a binding partner or sequence mutationswas highly demanded (4

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FIGURE 6 CD and HSQC characterization of Wrch1 Cdc42-like domains. (a and b) Far-UV CD and HSQC NMR spectra of the Cdc42-like domain (174 residues) of the Wrch1 protein in the absence (blue) and presence (red) of 8 M urea at pH 6.0 and 20°C. The protein concentration of the NMR sample was $~$ 120 µM. (c) NMR structure of the human Cdc42 (PDB code 1AJE), having $~$ 60% sequence identity with the Wrch1 Cdc42-like domain studied here.

Extracellular receptor domains without disulfide formation
The most unusual group in our current study is the disulfide-freeextracellular receptor domains from human Claudin 1 and Nogo-receptors(NgR). In the native proteins, disulfide bridges were neededto maintain their structural integrity: one disulfide was expectedfor Claudin-51, five for N-terminal NgR, and six for the entireNgR. In our previous investigation, the three proteins lackingdisulfide bridge(s) were totally insoluble. Nevertheless, toour great surprise, in this study, they were all soluble insalt-free water. The 51-residue Claudin-51 had a CD spectrumof a helical conformation (Fig. 7 a) and an HSQC spectrum witha narrow dispersion but with almost all nonproline residuesdetectable (Fig. 7 b). Currently we are focusing on determiningits NMR structure in salt-free water.

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FIGURE 7 CD and HSQC characterization of extracellular domains of transmembrane receptors. (a and b) Far-UV CD and NMR HSQC spectra of the first extracellular domain (51 residues) of the human Claudin 1 at pH 3.8 and $~$ 200 µM. (c and d) Far-UV CD and HSQC NMR spectra of the N-terminal domain (318 residues) of the human Nogo-66 receptor (NgR) in the absence (blue) and presence (red) of 8 M urea at pH 4.2 and 20°C. (e and f) Far-UV CD and HSQC NMR spectra of the entire extracelluar domain (420 residues) of the same NgR in, respectively, the absence (blue) and presence (red) of 8 M urea at pH 6.2 and 20°C. The protein concentrations of the NMR samples were $~$ 120 µM for both N-NgR and NgR. (g) Crystallographic structure of the NgR N-terminal domain (1OZN), which adopts a typical leucine-rich repeat fold. The protein samples used here were all disulfide-free.

The 319-residue N-terminal NgR contained a leucine-rich repeatfold plus two C-terminal helical regions. As shown in Fig. 7 c,the disulfide-free N-NgR had a CD spectrum for a helical protein.As seen in the N-NgR structure (20

) (Fig. 7 g), although theleucine-rich repeat fold contained many short ß-strandsin addition to helical segments, they usually gave rise to helix-likeCD spectra probably due to the unique solenoid-like fold theyadopt (21

,22

). Therefore, if judged from its CD spectrum (Fig. 7 c),it might be concluded that the native-like secondary structuremight already form in the disulfide-free N-NgR. On the otherhand, similar to that observed for the Wrch1 Cdc-42 domain (Fig. 6 b),N-NgR had an HSQC spectrum with a narrow dispersion ( $~$ 0.7 ppmover proton and $~$ 17 ppm over ¹⁵N dimensions) and very broad NMRpeaks (Fig. 7 b). Only $~$ 45 HSQC peaks were detectable, clearlyindicating that the disulfide-free N-NgR underwent intermediateconformational exchanges or/and dynamic aggregation, largelyowing to its dynamic side-chain packing (16

–19

). Additionof 8 M urea resulted in no significant change in the near-UVspectra (spectra not shown), again indicating that the side-chainpacking was largely disrupted. However, introduction of 8 Murea did lead to the appearance of many new HSQC peaks, similarto those observed on the Wrch1 Cdc42-like domain above (Fig. 6 b).Moreover, the entire 421-residue NgR with a 103-residue C-terminalextension also behaved in a manner similar to N-NgR (Fig. 7, e and f),although the structure of the extended 103 residues remainedcompletely unknown. These results together suggested that althoughthe disulfide-free N- and entire NgR proteins could be dissolvedin salt-free water, they were still trapped in the molten globulestates with both a native-like secondary structure and tertiarytopology, but without a tight side-chain packing, largely dueto the complete absence of essential disulfide bridges. In thisregard, it appeared that although the disulfide formation isnot essential for folding, it is vital for maintaining proteinstability and tight side-chain packing (23

–25

DISCUSSIONS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSIONS
ACKNOWLEDGEMENTS
REFERENCES

Water bears a variety of unique properties, many of which stillremain poorly-understood. It is universally accepted that lifeon Earth would not be possible without water, and consequently,the existence of water on other planets in the universe is asign that extraterrestrial life might originate and evolve there(26). On Earth, almost every activity in living cells occursin water-based media, but mostly with the presence of salt ions,so it is really a great surprise to find that all 11 buffer-insolubleprotein fragments/domains could be solubilized in salt-freewater. Usually, to enhance protein solubility, the common methodis to add more agents such as detergents, denaturants, or arginine(27) into the solution. Strikingly, this study shows that all11 buffer-insoluble proteins could be solubilized in aqueoussolution by removing salt ions in water. However, based on ourexperience, it seems that "double purity" is needed to get buffer-insolubleproteins dissolved in salt-free water. In other words, not onlydoes the purity of water matter, but the purity of the proteinis also essential. It appears that proteins have to be highlypurified from other molecules such as lipid by affinity chromatographyfollowed by reverse-phase HPLC purification. Probably, the existenceof these molecules even in a tiny amount may block proteinsfrom optimistically interacting with water by sticking to theexposed hydrophobic patches of proteins. For example, it seemedimpossible to directly dissolve buffer-insoluble proteins outof lyophilized inclusion bodies with salt-free water.

This finding offered us the possibility to gain the first systematicinsight into the structural properties of previously-desertedproteins. Based on CD and NMR HSQC assessment, the 11 proteinfragments/domains can be categorized into three groups. Thefirst group has no secondary structure, as judged by CD, andhas narrowly-dispersed HSQC spectra with sharp peaks. This groupincludes 152-residue viral hemagglutinin RBD and 58-residuehNck2 first SH3 domain. The second group possesses secondarystructure based on CD assessment, but broadened HSQC peaks.Consequently, only a small set of HSQC peaks was detectable.This group is composed of 66-residue Nogo-66; 86-residue Niv-86;174-residue Wrch1 Cdc42-like domain; 319-residue N-NgR; and421-residue entire NgR. The third group has secondary structurebased on CD assessment, but, again, narrowly-dispersed HSQCspectra. However, these have well-separated HSQC peaks and thuswere suitable for further high-resolution NMR study. This groupconsists of Nogo-60 (60 residues); Nogo-(21-60) (40-residues);Niv-44 (44 residues) and Claudin-51 (51 residues). Very strikingly,we failed to find any protein fragment/domain with a tight tertiarypacking, as indicated by the possession of the near-UV signalor/and well-dispersed HSQC spectrum. This observation stronglyimplies that proteins are insoluble in buffers, probably becausethey lack an intrinsic propensity to reach or/and maintain thewell-packed native state and consequently were trapped in themolten-globule or highly-disordered states, which have a tremendoustendency to aggregation in the presence of salt ions. However,such buffer-insoluble proteins may just account for a portionof denatured and partially-folded proteins, because it is wellknown that many denatured, partially-folded, as well as "intrinsically-unfolded",proteins are soluble in buffer systems. In fact, the solubilityof many intrinsically-unfolded proteins was found to be highbecause they usually have relatively low hydrophobicity.

Since the proteins we investigated here hold a significant diversityof cellular function, location, molecular sizes, and other properties,it would be reasonable to contemplate that, if not all, at leasta substantial portion of previously abandoned proteins can besolubilized in salt-free water for further study, as exemplifiedon Nogo-60 (6). On the other hand, it appears extremely challengingto fully understand the molecular mechanism underlying the solubilizationof buffer-insoluble proteins by salt-free water. Currently,in most cases, protein aggregation is considered to be dominatedby intermolecular hydrophobic clustering and salt has significanteffects on this process (2,28–31). The salt ion is thoughtto have both "salting-in" and "salting-out" effects on proteinsolubility. In other words, salts at a low concentration enhanceprotein solubility, whereas salts at a high concentration reducesolubility. Interestingly, it was recently reported that undersome conditions, in particular when the protein molecules beara significant number of net charges, only "salting-out" effectscould be observed and, consequently, proteins should have thehighest solubility in aqueous solution with the near-zero ionicstrength (32,33). Theoretically, it was proposed that the netinteraction between two charged particles such as protein moleculesis the balance between the repulsive electrostatic contributionand the attractive van der Waals contribution. Therefore, therepulsive electrostatic interactions between two charged proteinmolecules will be reduced by increasing ionic strength (32).To explain our results, we propose here that buffer-insolubleproteins represent a portion of denatured and partially-foldedproteins that lack intrinsic ability to reach or/and maintaina well-packed native conformation, and consequently, their hydrophobicside chains are highly exposed to the bulk solvent. As such,a very low ionic strength is sufficient to screen out intrinsicrepulsive interactions such as electrostatic interaction, andconsequently, the hydrophobic clustering/aggregation will rapidlyoccur. Most interestingly, our current results seem to revealthe marvelous fact that when proteins were originally selectedto be functional players for life on Earth, they might havebeen offered the potential to manifest their full spectrum ofstructural states, ranging from the denatured to native states,by utilizing intrinsic repulsive interactions to suppress attractivehydrophobic clustering in pure water.

In summary, our study seems to suggest that if not all, at leasta substantial fraction of buffer-insoluble proteins can be dissolvedin salt-free water to manifest their intrinsic conformationalstates without going to significant aggregation. This findingmay bear significant implications not only in practical applications,but also in our understanding of fundamental regimes of proteins.

ACKNOWLEDGEMENTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSIONS
ACKNOWLEDGEMENTS
REFERENCES

We thank Professor Walter Englander at the University of Pennsylvaniafor his kind and critical comments on salt effects on proteinstability and solubility.

This study is supported by Biomedical Research Council of Singapore(BMRC) grant R-183-000-097-305 and a BMRC Young InvestigatorAward, R-154-000-217-305, to J. Song).

Submitted on July 12, 2006; accepted for publication August 28, 2006.

REFERENCES

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSIONS
ACKNOWLEDGEMENTS
REFERENCES

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