N-terminal domains of native multidomain proteins have the potential to assist de novo folding of their downstream domains in vivo by acting as solubility enhancers

doi:10.1110/ps.062330907

HOME

HELP

FEEDBACK

SUBSCRIPTIONS

N-terminal domains of native multidomain proteins have the potential to assist de novo folding of their downstream domains in vivo by acting as solubility enhancers

Chul Woo Kim¹, Kyoung Sim Han², Ki-Sun Ryu¹, Byung Hee Kim¹, Kyun-Hwan Kim³, Seong Il Choi¹^,4, and Baik L. Seong¹^,2^,4

¹ Department of Biotechnology, College of Engineering, Yonsei University, Seodaemun-Gu, Seoul 120-749, Korea
² Protheon Incorporated, Yonsei Engineering Research Center B120E, Seodaemun-Gu, Seoul 120-749, Korea
³ Department of Pharmacology, School of Medicine, Konkuk University, 380-701, Korea
⁴ Institute of Life Science and Biotechnology, Yonsei University, Seodaemun-Gu, Seoul 120-749, Korea

(RECEIVED May 7, 2006; FINAL REVISION November 13, 2006; ACCEPTED December 19, 2006)

Abstract

TOP
Abstract
Introduction
Results
Discussion
Materials and Methods
Acknowledgments
References

The fusion of soluble partner to the N terminus of aggregation-pronepolypeptide has been popularly used to overcome the formationof inclusion bodies in the E. coli cytosol.

The chaperone-like functions of the upstream fusion partnerin the artificial multidomain proteins could occur in de novofolding of native multidomain proteins. Here, we show that theN-terminal domains of three E. coli multidomain proteins suchas lysyl-tRNA synthetase, threonyl-tRNA synthetase, and aconitaseare potent solubility enhancers for various C-terminal heterologousproteins. The results suggest that the N-terminal domains couldact as solubility enhancers for the folding of their authenticC-terminal domains in vivo. Tandem repeat of N-terminal domainor insertion of aspartic residues at the C terminus of the N-terminaldomain also increased the solubility of fusion proteins, suggestingthat the solubilizing ability correlates with the size and chargeof N-terminal domains. The solubilizing ability of N-terminaldomains would contribute to the autonomous folding of multidomainproteins in vivo, and based on these results, we propose a modelof how N-terminal domains solubilize their downstream domains.

Keywords: fusion; multidomain proteins; de novo folding; N-terminal domains; solubility enhancers; charge; size

Introduction

TOP
Abstract
Introduction
Results
Discussion
Materials and Methods
Acknowledgments
References

How proteins efficiently fold in the crowded cytosol remainsone of the fundamental questions in biology. Three major molecularchaperones such as DnaK, GroEL/GroES, and trigger factor (TF)assist the folding of only a small fraction of newly synthesizedproteins in the Escherichia coli cytoplasm (Hartl and Hayer-Hartl 2002;Kerner et al. 2005). The E. coli strains lacking DnaK or TFexhibit no apparent folding defects, whereas the combined deletionof two genes causes protein aggregation and synthetic lethality(Deuerling et al. 1999). However, the above problems are circumventedby the growth below 30°C or by overexpression of eitherGroEL/GroES or SecB (Ullers et al. 2004; Vorderwülbecke et al. 2004).The E. coli GroEL is essential for viability under all conditionstested (Fayet et al. 1989). Strikingly, however, GroEL/GroESare absent or not essential in the mycoplasmas, proposed toinclude minimal sets of genes for viability due to their smallgenome size (Wong and Houry 2004).

Small single-domain proteins are thought to fold spontaneouslyupon termination of translation and release from ribosomes.In contrast, the folding of multidomain proteins is facilitatedby a cotranslational folding process in vivo (Kramer et al. 2001).So far, the role of cotranslationally or independently foldeddomains in the folding of other domains remains largely unknown.On the other hand, the fusion technology, the fusion of solubleprotein to the N terminus of aggregation-prone polypeptide,has been the most efficient and popular tool to overcome theformation of inclusion bodies in the E. coli cytosol (Braun and LaBaer 2003;Esposito and Chatterjee 2006). In contrast, the coexpressionof molecular chaperones has been effective only for a limitednumber of heterologous proteins (Wall and Plückthun 1995).The E. coli maltose-binding protein (MBP) was proposed and referredto function as a general molecular chaperone in the contextof a fusion protein (Kapust and Waugh 1999; Bach et al. 2001).Interestingly, the fusion proteins are kinds of multidomainproteins in which the N-terminal domains act as solubility enhancersfor their downstream domains. This phenomenon could occur inthe de novo folding of native multidomain proteins in vivo.

Here, we report that the N-terminal domains of native multidomainproteins promote the solubility of their C-terminal insolubleheterologous proteins. Based on the results, we suggest thatlike the commonly used solubility-enhancing fusion partners,the N-terminal domains as solubility enhancers could assistthe folding of their authentic C-terminal domains. It was investigatedwhat factors of N-terminal domains are important for their solubilizingability. By combining our results with the well-known chargeeffect on protein solubility, we suggest a model of how theN-terminal domains solubilize their downstream domains.

Results

TOP
Abstract
Introduction
Results
Discussion
Materials and Methods
Acknowledgments
References

The N-terminal domains promote the solubility of their C-terminal heterologous proteins
To show the occurrence of the chaperone-like type in the artificialmultidomain proteins during de novo folding of native multidomainproteins and to assess the potential role of the N-terminaldomains in vivo, we used an indirect approach depicted in Figure 1.For the purpose, the native N-terminal domains were fused tothe N terminus of the aggregation-prone heterologous proteins.

View larger version (20K):
[in this window]
[in a new window]

Figure 1. A schematic diagram for assessing the potential role of N-terminal domains as solubility enhancers for their authentic C-terminal domains in vivo. N, C, and AP represent N- and C-terminal domains of native multidomain proteins and aggregation-prone proteins, respectively.

Three E. coli multidomain proteins such as lysyl-tRNA synthetase(LysRS, 57 kDa) encoded by lysS gene, threonyl-tRNA synthetase(ThrRS, 75 kDa), and aconitase (AcnB, 94 kDa) were selected.The corresponding N-terminal domains, LysN (residues 1–154of LysRS), ThrN (residues 1–225 of ThrRS), and AcnN (residues1–160 of AcnB), were selected on the basis of their knownthree-dimensional structures (Sankaranarayanan et al. 1999;Onesti et al. 2000; Williams et al. 2002). All N-terminal domainswere expressed as soluble form at 37°C (Fig. 2A). As a control,thioredoxin (Trx) with a domain size, one of the well-knownsolubility-enhancing fusion partners (LaVallie et al. 1993),was compared. Aggregation-prone proteins such as Aquorea victoriagreen fluorescence protein (GFP), human granulocyte colony-stimulatingfactor (GCSF), and tobacco etch virus protease (TEVP) with theC-terminal hexahistidine tag were expressed predominantly orsignificantly as inclusion bodies at 30°C (Fig. 2B). TheN-terminal domains promoted the solubility of their C-terminalproteins at 30°C and were more effective than Trx (Fig. 2C).In addition, the Western blot of proteins of interest was approximatelyin accord with the expression patterns on the SDS-PAGE. Thesolubility of proteins are summarized in Figure 2D. The solubilizingability of N-terminal domains in the fusion proteins suggeststhat in the same context, the N-terminal domains could act assolubility enhancers for their authentic C-terminal domainsin vivo.

View larger version (69K):
[in this window]
[in a new window]

Figure 2. The solubilizing ability of the N-terminal domains of native multidomain proteins for aggregation-prone heterologous proteins. The expressed proteins were analyzed by SDS-PAGE. T, S, and I represent induced total lysates, soluble fraction, and insoluble fraction, respectively. The Western blot (WB) data were shown under the corresponding SDS-PAGE results. The same molecular weight marker was used in all SDS-PAGE. (A) The direct expression of N-terminal domains of native multidomain proteins at 37°C. (B) The direct expression of aggregation-prone heterologous proteins at 30°C. (C) The expression of fusion proteins at 30°C. (D) The solubility of tested proteins in B and C is summarized. (E) The expression of LysRS, LysN, and LysC at 37°C and 42°C.

To examine the role of the N-terminal domains in more detail,LysRS, LysN, and LysC (residues 155–505 of LysRS) wereexpressed at 37°C and 42°C. The expressed LysRS andLysN were almost soluble at both temperatures, whereas the significantfraction of LysC ( $~$ 10% at 37°C and 20% at 42°C) was expressedas insoluble aggregates (Fig. 2E). The results suggest thatthe folded LysN with the solubilizing ability might be helpfulfor the de novo folding of LysC in vivo. Distinct from the LysN-fusedproteins in Figure 2C, LysN exhibit the native interdomain interactionswith LysC in the folded LysRS (Onesti et al. 2000). ProbablyLysN might be a more effective solubility enhancer for LysCthan the heterologous proteins.

The N-terminal domain-fused proteins exhibit the functional activities of C-terminal proteins
The solubility of fusion proteins does not necessarily indicatethe proper folding of the C-terminal reporter proteins. To monitorthe folding of the C-terminal proteins in the soluble fusionproteins, the functional assays of fusion proteins were performed.The purified TEVP fusion proteins (LysN-, ThrN-, and AcnN-TEVP)with C-terminal histidine tags and commercially available TEVPas a positive control were shown to efficiently cleave the substrateprotein, MBP-GCSF containing TEVP recognition site between MBPand GCSF (Fig. 3A). Additionally, the relative fluorescenceintensity of GFP and GFP fusion proteins were compared at anequimolar level. The relative fluorescence intensity obtainedfrom each soluble extract containing GFP or GFP fusion proteinshowed that the soluble GFP fusion proteins exhibit the specificfluorescence intensity comparable with that of intact GFP (Fig. 3B).

View larger version (40K):
[in this window]
[in a new window]

Figure 3. The functional assays of the N-terminal domain-fused proteins. (A) The TEVP fusion proteins, substrate protein, and cleaved mixtures were analyzed by SDS-PAGE. (Lanes 1–3) Purified LysN-, ThrN- and AcnN-TEVP; (lane 4) molecular weight marker; (lane 5) purified substrate MBP-GCSF; (lanes 6–9) MBP-GCSF was incubated with rTEVP (Invitrogen, lane 6), LysN-TEVP (lane 7), ThrN-TEVP (lane 8), and AcnN-TEVP (lane 9), respectively. (B) The relative specific fluorescence intensity (FI) of GFP and each GFP fusion protein in the soluble extract was compared. The value for GFP was set to one for comparison.

Folding yield can be determined by multiplying relative specificactivity by solubility. The relative specific fluorescence ofGFP, LysN-GFP, ThrN-GFP, and AcnN-GFP are 1, 0.85, 0.63, and0.71, respectively, and their solubilities in Figure 2D are27%, 33%, 63%, and 52%, respectively. Therefore, their foldingyields are $~$ 27%, 28%, 40%, and 37%, respectively. Despite thelower specific activity of GFP fusion proteins, the foldingyields of GFP by the N-terminal domain fusion increase. It ispossible that the N-terminal domains can interfere with thefunctions of their linked proteins in the fusion context, althoughthe C-terminal proteins achieve native conformations, resultingin lower specific activity.

The solubilizing ability of N-terminal domains correlates with their charge
The solubility of fusion partners that closely correlates withtheir average net charge has served as a general indicator oftheir ability to solubilize their linked proteins (Davis et al. 1999).To investigate the contribution of the charge effect of N-terminaldomains on their solubilizing ability, linker peptides harboringdifferent charge contents were inserted between LysN (or Trx)and C-terminal GCSF. The insertion of the small linker peptideis expected not to alter the thermodynamic stability and foldingrate of N-terminal domains significantly. The linker peptidestested here include six consecutive arginines(R₆), alanines(A₆), aspartic acids (D₆), D₂(ST)₂, and D₄ST, and were comparedwith serine-threonine repeated residue, (ST)₃, used in the originalconstruct in Figure 2C.

As shown in Figure 4A, the negatively charged tags increasedthe solubility of the LysN-GCSF fusion protein, approximatelyproportional to the number of inserted aspartic acids (49%,82%, 94%, and 95% for [ST]₃, D₂[ST]₂, D₄ST, and D₆, respectively).In contrast, R₆ and A₆ tags had negative or little effect onthe solubility of fusion proteins when compared to the (ST)₃tag (33% and 49% for R₆ and A₆, respectively). A similar oreven more dramatic effect of inserted tags was observed in theTrx-GCSF fusion protein. As shown in Figure 4B, the insertionof negatively charged tags between Trx and GCSF resulted ingreat improvement of the solubility of the fusion proteins (7%,17%, 58%, and 86% for [ST]₃, D₂[ST]₂, D₄ST, and D₆, respectively).Again, the insertion of R₆ and A₆ tags little affected the solubilityof fusion proteins (10% and 7% for R₆ and A₆, respectively).The results seem to be in accord with the obvious charge effectson protein solubility (Otzen et al. 2000; Uversky et al. 2000;Chiti et al. 2002) and suggest that the solubilizing abilityof N-terminal domains might correlate with their charge. However,the mechanism of the negatively charged linker peptide on thesolubility is still unclear.

View larger version (40K):
[in this window]
[in a new window]

Figure 4. The charge effect of small tags between N-terminal domain and target protein on the solubility of fusion proteins. The various linker tags harboring different charge content were inserted between LysN and GCSF (A) and between Trx and GCSF (B), and their effect on the solubility of fusion proteins was analyzed by SDS-PAGE. All fusion proteins were expressed at 30°C.

The solubilizing ability of N-terminal domains correlates with their size
Both solubility and average net charge are intensive properties,not representing quantitatively total net charge and proteinsize. Assuming that the total electrostatic repulsions by thesurfaced-exposed charged residues of folded proteins are oneof the important forces for the solubilization of their linkedpolypeptides, the protein size or number of domains is expectedto correlate with their solubilizing potential.

In order to investigate the potential effect of the overallsize of N-terminal domains on their solubilizing ability, wecompared the single LysN domain with the tandem repeat of LysN(LysN₂), where the size and total net charge are doubled whilekeeping the average net charge unchanged. The solubility ofLysN-GFP and LysN₂-GFP was $~$ 30% and 50% at 30°C, respectively(Fig. 5A), suggesting that the size of N-terminal domains mightcorrelate with their solubilizing ability. Importantly, theresults suggest that as the number of folded domains increasesduring de novo folding with their solubility little changed,their solubilizing ability could be further increased.

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

Figure 5. The size effect of N-terminal domains on their solubilizing ability. (A) LysN and tandem repeat (LysN₂) were fused to GFP, and fusion proteins were expressed at 30°C. (B) LysN, LysC, and LysRS, were fused to GFP, respectively, and the fusion proteins were expressed at 30°C.

LysRS and LysN, when expressed alone without fusion, exhibita similar level of solubility (Fig. 2E). However, the size effectpredicts that LysRS could be more effective than LysN in termsof solubilizing ability. LysN-GFP, LysC-GFP, and LysRS-GFP,were expressed at 30°C. As shown in Figure 5B, LysRS-GFPwas almost soluble (95%), whereas the majority of the expressedLysN-GFP and LysC-GFP were insoluble. The results further supportthe correlation between the size of N-terminal domains and theirsolubilizing ability. Moreover, they suggest that the synergisticsolubility-enhancing ability by folded LysN and LysC for GFPexist, probably due to the native interdomain packing betweentwo-folded domains. The additive and/or synergistic solubilizingability of folded domains might contribute to the autonomousfolding of larger native multidomain proteins in vivo. Contraryto our results in vivo, the in vitro refolding experiments haverevealed that domains interfere with the folding of other domains(Creighton 1992; Netzer and Hartl 1997; Inaba et al. 2000).

The solubilizing ability of MBP is not inhibited by the insertion of a large tag between MBP and target protein
Mechanistically, MBP was proposed to act as a general molecularchaperone in the fusion context through transient and directhydrophobic interactions between the exposed hydrophobic sitesof MBP and aggregation-prone folding intermediates of downstreamproteins (Kapust and Waugh 1999), similar to the mechanism ofthe current molecular chaperones. In contrast, the solubilizingability based on the charge effect on protein solubility doesnot necessarily require the direct intramolecular interactionsbetween fusion partner and downstream protein.

To distinguish between the two possibilities, we inserted largepolypeptides such as Trx and LysN between MBP and target proteins(GFP and TEVP) to prevent the local intramolecular interactionsbetween MBP and target proteins during the folding process.The GFP fusion proteins were expressed at 37°C. The insertionof Trx or LysN between MBP and GFP had little or no inhibitoryeffect on the solubilizing ability of MBP for GFP (Fig. 6A).Similar patterns were also observed when GCSF was used as targetprotein (data not shown). As shown in Figure 6B, in the caseof TEVP, the insertion of Trx slightly decreased the solubilityof fusion proteins, whereas the insertion of LysN increasedthe solubility of fusion proteins (2%, 34%, 58%, 54%, and 78%for Trx, LysN, MBP, MBP-Trx, and MBP-LysN, respectively). Theresults indicate that the solubilizing ability of MBP couldbe transferred to the target proteins via covalent linkage withoutintramolecular interactions. In accord with this reasoning,the mutagenesis of exposed hydrophobic sites of MBP, initiallythought to be important for the solubilizing ability, showedno apparent effect on the solubility of MBP fusion proteins(Fox et al. 2001).

View larger version (41K):
[in this window]
[in a new window]

Figure 6. The effect of large inserted tags between MBP and target proteins on the solubilizing ability of MBP. LysN or Trx were inserted between MBP and GFP (A), between MBP and TEVP (B). The GFP fusion proteins and TEVP fusion proteins were expressed at 37°C and 34°C, respectively, and their solubility was analyzed by SDS-PAGE. The TEVP in B have no C-terminal histidine tag.

	Discussion

TOP Abstract Introduction Results Discussion Materials and Methods Acknowledgments References

The results suggest a strong correlation between the popularfusion technology and de novo folding of native multidomainproteins in vivo, using an indirect approach in Figure 1. Inaddition to the numerous whole proteins, the N- and C-terminaldomains of E. coli proteins, including LysN as well as LysRSused here, have been known to promote the solubility and properfolding of their linked heterologous proteins (Anderluh et al. 2003;Sørensen et al. 2003; S.I. Choi, K.S. Han, C.W. Kim,B.H. Kim, K.H. Kim, S.I. Kim, K.S. Ryu, T.H. Kang, H.C. Shin,and B.L. Seong, unpubl.). However, there has been no reportof linking this phenomenon to de novo folding of the nativemultidomain proteins. The indirect approach would be usefulfor assessing the intrinsic solubilizing ability of the foldedN-terminal domains in vivo, although it does not provide anyinformation for the effect of the native interdomain interactionson the folding of the interacting domains.

Proper folding of N-terminal domains and high solubility appearto be a prerequisite for their solubilizing functions. Cotranslationalfolding likely allows the solubilizing ability of folded domainsto be more effective. Cotranslational folding of E. coli proteinsand some eukaryotic proteins on E. coli ribosomes has been demonstrated(Kramer et al. 2001; Svetlov et al. 2006). In general, fusionpartners, to be effective, have to be located upstream of targetproteins; reversion of fusion order abolishes the solubilizingability of MBP (Sachdev and Chirgwin 1998). Likewise, the fusionof aggregation-prone target protein upstream to the solublereporter protein led to the insoluble aggregates of fusion proteins(Waldo 2003). These findings indicate that the proper foldingof N-terminal domains is important for the efficient foldingof multidomain proteins in vivo, consistent with Frydman et al. (1999).

The addition of negatively charged small peptides to the N orC terminus of aggregation-prone proteins can increase the proteinsolubility (Chen et al. 1998; Zhang et al. 2004). In particular,the electrostatic repulsions between protein molecules weresuggested to prevent protein aggregation (Chiti et al. 2002).Similarly, the intermolecular electrostatic repulsions generatedby the surface-exposed charged residues of folded domains mightbe responsible for their solubilizing ability. In accord withthis assumption, a positive correlation between the solubilityenhancement and the number of aspartic acids in the linker peptideswas observed (Fig. 4). The theoretical isoelectric points ofLysN, ThrN, and AcnN are 6.11, 5.58, and 4.81, respectively,indicating that they are anionic polypeptides. Moreover, theelectrostatic potential surfaces of the N-terminal domains onthe basis of the known three-dimensional structures show theexposed anionic surfaces (Fig. 7).

View larger version (42K):
[in this window]
[in a new window]

Figure 7. Electrostatic potential surfaces of the N-terminal domains. Red and blue represent negatively and positively charged surfaces, respectively. The electrostatic surfaces of LysN, ThrN, and AcnN were obtained from their known three-dimensional structures using the DS Visualizer (Accelrys).

Besides the charge effect, there might be the steric hindranceof folded domains against intermolecular aggregation. Proteinaggregation is a three-dimensional growing and specific process(London et al. 1974; Speed et al. 1996; Wright et al. 2005).Consequently, the structurally bulky folded domains are expectedto greatly disturb the intermolecular aggregation driven bytheir linked aggregation-prone domains. Here, substantial fractionof the surfaces of C-terminal aggregation-prone domains aroundthe linker region is expected to be inaccessible to the otherfolding intermediates due to the steric masking of folded domains.Importantly, the steric and electrostatic repulsions are likelyproportional to the number of folded domains. The correlationof protein size with the solubilizing ability in Figure 5 supportsthis idea. In addition, both factors of folded domains seemto solubilize the downstream domains without the transient,intramolecular interactions between them. Consistently, littleor no inhibitory effect of inserted LysN or Trx between MBPand target proteins on the solubilizing ability of MBP was observedin Figure 6.

By combining the size effect and steric hindrance with the well-knowncharge effect on protein solubility, we propose a solubilizingmechanism as illustrated in Figure 8. Both electrostatic repulsionsand steric hindrance of folded and soluble domains prevent theintermolecular associations driven by aggregation-prone domains.This would lead to the shift from oligomeric state to monomericstate in which the spontaneous folding of downstream domainsis favored. This model is dependent on the reversibility ofprotein aggregation at the early phase. There is accumulatedevidence supporting that protein aggregation is reversible (Silow et al. 1999;Ganesh et al. 2001; Carrió and Villaverde 2001). Additionalfactors, e.g., in vivo folding rates and stability of N-terminaldomains in the whole proteins, transient interdomain interactions,and the presence of native interdomain interactions, which arenot considered in this model, could greatly affect the solubilizingability of N-terminal domains.

View larger version (35K):
[in this window]
[in a new window]

Figure 8. A model for how N-terminal domains solubilize their linked domains. The blue, gray, and wrinkled spheres represent the folded N- and C-terminal domains and incompletely folded C-terminal domains, respectively. The red spots on wrinkled spheres indicate the exposed regions involved in the intermolecular interactions. Thick arrows represent the shift from the oligomeric state to the monomeric state (boxed) of proteins driven by the electrostatic repulsions and steric hindrance of folded N-terminal domains.

Nucleic acids and other polyanions can enhance in vitro refoldingof proteins (Dabora et al. 1991; Rentzeperis et al. 1999). Thenegatively charged clusters of the cavity wall of GroEL areimportant for accelerating the folding of some proteins in vitro(Tang et al. 2006). Like the polyanions, the anionic surfacesof the folded N-terminal domains and anion linkers in Figure 4,especially in the close vicinity of their downstream domains,could enhance the folding of downstream domains. The N-terminalpropeptides, usually polyanionic in nature (Jones et al. 2004),have been shown to directly assist the correct folding of theirdownstream proteins as intramolecular chaperones (Shinde and Inouye 2000).The intramolecular chaperone activity of propeptides would bemechanistically similar to the solubilizing ability of the N-terminaldomains of multidomain proteins. Besides the cleavage of propeptides,however, there are some obvious differences between them. TheN-terminal domains appear to assist the folding of their downstreamheterologous proteins in a passive manner by simply solubilizingthem.

Here we suggest that the chaperone-like type in the fusion technologycould occur in de novo folding of native multidomain proteinsin vivo. Further studies are required to understand the roleof folded N-terminal domains in de novo folding. The potentialrole of N-terminal domains as solubility enhancers would contributeto the autonomous folding of native proteins in vivo.

Materials and Methods

TOP
Abstract
Introduction
Results
Discussion
Materials and Methods
Acknowledgments
References

Construction of expression vectors
The plasmid, derived from pGEMEX-1 (Promega), was used for theconstruction of protein expression vectors. The genes encodingproteins of interest are under the control of a T7 promoter.All E. coli genes were obtained from E. coli genomic DNA usingPCR amplification. The gene encoding mature GCSF was used asdescribed (Lee et al. 1999). TEVP is the catalytic domain ofthe NIa protease of tobacco etch virus (Kapust et al. 2001).For immunodetection and purification, the hexahistidine tagwas inserted at the C terminus of TEVP. The linker sequence,GTGSSTSTST, was used between fusion partners (Trx, LysN, LysN₂,LysRS, LysC, ThrN, and MBP) and target proteins (GCSF, GFP,and TEVP) except GSSTSTST for AcnN as fusion partner. The GTGSSTSTSTlinker sequence was also used between fusion partners for theconstruction of MBP-LysN and MBP-Trx. One histidine residuewas incorporated between LysN and LysN due to the restrictionsite of NdeI to make tandem repeat, LysN₂. MBP-GCSF has thehexahistidine tag at its C terminus and TEVP recognition sitebetween MBP and GCSF.

Protein expression, solubility test, and Western blot analysis
The E. coli strain HMS174 (DE3) plysE (Novagen) was used asexpression host. Each transformant was inoculated into 2 mLof LB containing 50 µg/mL ampicillin and 30 µg/mLchloramphenicol and then cultured overnight at 37°C. Onemilliliter of culture broth was diluted into 20 mL with freshLB with the antibiotics. At the cell density of 0.5–0.8at A₆₀₀, proteins were expressed for 5 h after addition of 1mM IPTG at indicated temperature. The harvested cells from 10mL of culture broth were suspended in 0.3 mL of PBS. After sonicationand centrifugation, total lysates, soluble fraction, and insolublefraction were obtained. The samples were analyzed by SDS-PAGE.

The solubility of proteins was estimated on SDS-PAGE with adensitometer using the following formula. Solubility (%) = (S– S_E)/(T – T_E)x100, where S and T are the band intensityof target proteins in soluble fraction and total lysates, andS_E and T_E are the band intensity of overlapped endogenous proteinsthat can be obtained from the parallel lines on the same SDS-PAGE.Three independent experiments were performed for the measurementof protein solubility.

The amount of proteins equivalent to one-sixteenth of SDS-PAGEsamples in Figure 2, B and C, was transferred to PVDF membranes.The membranes were blocked with 10% skim milk in PBST (1x PBSsupplemented with 0.1% Tween 20) for 1 h before the incubationof the primary antibody (anti-GCSF antibody [Sigma], anti-GFPantibody [Clontech], and Penta-His antibody [Qiagen], respectively),diluted 1:2000 in PBST, for 1 h. After washing three times for15 min with PBST, the secondary antibody (anti-mouse IgG-horseradishperoxidase [Sigma] or anti-rabbit IgG-horseradish peroxidase[Sigma] for the detection of GFP and GFP fusion proteins), diluted1:20,000, was treated for 1 h. After washing, blots were developedwith ECL developing reagent (Intron biotechnology).

Protein purification and activity assays
Each prepared supernatant in buffer A (20 mM Tris-HCl at pH7.5, 300 mM NaCl, 10% glycerol, 2 mM beta-mercaptoethanol, and5 mM imidazole) was applied to a nickel-chelated prepacked HPcolumn (Amersham Bioscience) pre-equilibrated with buffer A.After washing with buffer A, elution was performed with a lineargradient of imidazole by mixing buffer A and buffer B (bufferA supplemented with 300 mM imidazole). The eluted fractionswere analyzed by SDS-PAGE and then pooled and dialyzed againstbuffer C (100 mM Tris-HCl at pH 8.0, 100 mM NaCl, 2 mM EDTA,and 2 mM DTT). The protein concentration was determined accordingto the BCA method (Pierce) using bovine serum albumin as standard.The dialyzed samples were mixed with the equal volume of 100%glycerol and then stored at –20°C.

TEVP cleavage reactions were carried out in 20 µL volumescontaining 50 mM Tris-HCl (pH 8.0), 0.5 mM EDTA, 1 mM DTT, 20µg of MBP-GCSF as substrate, and 3 U of recombinant TEVP(Invitrogen) or 2 µM of each TEVP fusion protein for 2h at 30°C. The reaction mixtures were analyzed by SDS-PAGE.

For the measurements of fluorescence intensity of the GFP andGFP fusion proteins in the soluble fractions of cell lysates,each fraction was diluted into 20-fold using 400 µL ofPBS. The fluorescence emission was monitored at 509 nm withthe excitation at 395 nm using Cary Eclipse fluorescence spectrophotometer(Varian). Each fluorescence intensity was divided by BI/MW whereBI and MW represent the band intensity (S – S_E) on SDS-PAGEmeasured by densitometer and molecular weights of tested proteins,respectively. The resulting value of GFP was set to one andcompared with those of GFP fusion proteins.

Footnotes

Reprint requests to: Seong Il Choi, Institute of Life Scienceand Biotechnology, Yonsei University, 134 Shinchon-Dong, Seodaemun-Gu,Seoul 120-749, Korea; e-mail: seongilchoi{at}daum.net; fax: 82-2-392-3582.

Article and publication are at http://www.proteinscience.org/cgi/doi/10.1110/ps.062330907.

Acknowledgments

TOP
Abstract
Introduction
Results
Discussion
Materials and Methods
Acknowledgments
References

This work was supported in part by the Human Genomics FrontierResearch and the Microbial Genomics R&D Grants from theMinistry of Science and Technology of the Korean Government,and the Korea Research Foundation Grant funded by the KoreanGovernment (grant no. KRF-2004-005-C00148).

References

TOP
Abstract
Introduction
Results
Discussion
Materials and Methods
Acknowledgments
References

Anderluh, G., Gökçe, I., and Lakey, J.H. 2003. Expression of proteins using the third domain of the Escherichia coli periplasmic-protein TolA as a fusion partner. Protein Expr. Purif. 28: 173–181.[CrossRef][Medline]

Bach, H., Mazor, Y., Shaky, S., Shoham-Lev, A., Berdichevsky, Y., Gutnick, D.L., and Benhar, I. 2001. Escherichia coli maltose-binding protein as a molecular chaperone for recombinant intracellular cytoplasmic single-chain antibodies. J. Mol. Biol. 312: 79–93.[CrossRef][Medline]

Braun, P. and LaBaer, J. 2003. High throughput protein production for functional proteomics. Trends Biotechnol. 21: 383–388.[CrossRef][Medline]

Carrió, M.M. and Villaverde, A. 2001. Protein aggregation as bacterial inclusion bodies is reversible. FEBS Lett. 489: 29–33.[CrossRef][Medline]

Chen, J., Skehel, J.J., and Wiley, D.C. 1998. A polar octapeptide fused to the N-terminal fusion peptide solubilizes the influenza virus HA₂ subunit ectodomain. Biochemistry 37: 13643–13649.[CrossRef][Medline]

Chiti, F., Calamai, M., Taddei, N., Stefani, M., Ramponi, G., and Dobson, C.M. 2002. Studies of the aggregation of mutant proteins in vitro provide insights into the genetics of amyloid diseases. Proc. Natl. Acad. Sci. 99: 16419–16426.[Abstract/Free Full Text]

Creighton, T.E. 1992. In Protein folding, pp. 405–454. Freeman, New York.

Dabora, J.M., Sanyal, G., and Middaugh, C.R. 1991. Effect of polyanions on the refolding of human acidic fibroblast growth factor. J. Biol. Chem. 266: 23637–23640.[Abstract/Free Full Text]

Davis, G.D., Elisee, C., Newham, D.M., and Harrison, R.G. 1999. New fusion protein systems designed to give soluble expression in Escherichia coli . Biotechnol. Bioeng. 65: 382–388.[CrossRef][Medline]

Deuerling, E., Schulze-Specking, A., Tomoyasu, T., Mogk, A., and Bukau, B. 1999. Trigger factor and DnaK cooperate in folding of newly synthesized proteins. Nature 400: 693–696.[CrossRef][Medline]

Esposito, D. and Chatterjee, D.K. 2006. Enhancement of soluble protein expression through the use of fusion tags. Curr. Opin. Biotechnol. 17: 353–358.[CrossRef][Medline]

Fayet, O., Ziegelhoffer, T., and Georgopoulos, C. 1989. The groES and groEL heat shock gene products of Escherichia coli are essential for bacterial growth at all temperatures. J. Bacteriol. 171: 1379–1385.[Abstract/Free Full Text]

Fox, J.D., Kapust, R.B., and Waugh, D.S. 2001. Single amino acid substitutions on the surface of Escherichia coli maltose-binding protein can have a profound impact on the solubility of fusion proteins. Protein Sci. 10: 622–630.[Abstract/Free Full Text]

Frydman, J., Erdjument-Bromage, H., Tempst, P., and Hartl, F.U. 1999. Co-translational domain folding as the structural basis for the rapid de novo folding of firefly luciferase. Nat. Struct. Biol. 6: 697–705.[CrossRef][Medline]

Ganesh, C., Zaidi, F.N., Udgaonkar, J.B., and Varadarajan, R. 2001. Reversible formation of on-pathway macroscopic aggregates during the folding of maltose binding protein. Protein Sci. 10: 1635–1644.[Abstract/Free Full Text]

Hartl, F.U. and Hayer-Hartl, M. 2002. Molecular chaperones in the cytosol: From nascent chain to folded protein. Science 295: 1852–1858.[Abstract/Free Full Text]

Inaba, K., Kobayashi, N., and Fersht, A.R. 2000. Conversion of two-state to multi-state folding kinetics on fusion of two protein foldons. J. Mol. Biol. 302: 219–233.[CrossRef][Medline]

Jones, L.S., Yazzie, B., and Middaugh, C.R. 2004. Polyanions and the proteome. Mol. Cell. Proteomics 3: 746–769.[Abstract/Free Full Text]

Kapust, R.B. and Waugh, D.S. 1999. Escherichia coli maltose-binding protein is uncommonly effective at promoting the solubility of polypeptides to which it is fused. Protein Sci. 8: 1668–1674.[Abstract]

Kapust, R.B., Tözsér, J., Fox, J.D., Anderson, D.E., Cherry, S., Copeland, T.D., and Waugh, D.S. 2001. Tobacco etch virus protease: Mechanism of autolysis and rational design of stable mutants with wild-type catalytic proficiency. Protein Eng. 14: 993–1000.[Abstract/Free Full Text]

Kerner, M.J., Naylor, D.J., Ishihama, Y., Maier, T., Chang, H.C., Stines, A.P., Georgopoulos, C., Frishman, D., Hayer-Hartl, M., Mann, M., et al. 2005. Proteome-wide analysis of chaperonin-dependent protein folding in Escherichia coli . Cell 122: 209–220.[CrossRef][Medline]

Kramer, G., Ramachandiran, V., and Hardesty, B. 2001. Cotranslational folding–omnia mea mecum porto? Int. J. Biochem. Cell Biol. 33: 541–553.[CrossRef][Medline]

LaVallie, E.R., DiBlasio, E.A., Kovacic, S., Grant, K.L., Schendel, P.F., and McCoy, J.M. 1993. A thioredoxin gene fusion expression system that circumvents inclusion body formation in the E. coli cytoplasm. Biotechnology (N. Y.) 11: 187–193.[CrossRef][Medline]

Lee, J., Choi, S.I., Jang, J.S., Jang, K., Moon, J.W., Bae, C.S., Yang, D.S., and Seong, B.L. 1999. Novel secretion system of recombinant Saccharomyces cerevisiae using an N-terminus residue of human IL-1 $beta$ as secretion enhancer. Biotechnol. Prog. 15: 884–890.[CrossRef][Medline]

London, J., Skrzynia, C., and Goldberg, M.E. 1974. Renaturation of Escherichia coli tryptophanase after exposure to 8 M urea. Evidence for the existence of nucleation centers. Eur. J. Biochem. 47: 409–415.[Medline]

Netzer, W.J. and Hartl, F.U. 1997. Recombination of protein domains facilitated by co-translational folding in eukaryotes. Nature 388: 343–349.[CrossRef][Medline]

Onesti, S., Desogus, G., Brevet, A., Chen, J., Plateau, P., Blanquet, S., and Brick, P. 2000. Structural studies of lysyl-tRNA synthetase: Conformational changes induced by substrate binding. Biochemistry 39: 12853–12861.[CrossRef][Medline]

Otzen, D.E., Kristensen, O., and Oliveberg, M. 2000. Designed protein tetramer zipped together with a hydrophobic Alzheimer homology: A structural clue to amyloid assembly. Proc. Natl. Acad. Sci. 97: 9907–9912.[Abstract/Free Full Text]

Rentzeperis, D., Jonsson, T., and Sauer, R.T. 1999. Acceleration of the refolding of Arcrepressor by nucleic acids and other polyanions. Nat. Struct. Biol. 6: 569–573.[CrossRef][Medline]

Sachdev, D. and Chirgwin, J.M. 1998. Order of fusions between bacterial and mammalian proteins can determine solubility in Escherichia coli . Biochem. Biophys. Res. Commun. 244: 933–937.[CrossRef][Medline]

Sankaranarayanan, R., Dock-Bregeon, A.C., Romby, P., Caillet, J., Springer, M., Rees, B., Ehresmann, C., Ehresmann, B., and Moras, D. 1999. The structure of threonyl-tRNA synthetase-tRNAThr complex enlightens its repressor activity and reveals an essential zinc ion in the active site. Cell 97: 371–381.[CrossRef][Medline]

Shinde, U. and Inouye, M. 2000. Intramolecular chaperones: polypeptide extensions that modulate protein folding. Semin. Cell Dev. Biol. 11: 35–44.[CrossRef][Medline]

Silow, M., Tan, Y.J., Fersht, A.R., and Oliveberg, M. 1999. Formation of short-lived protein aggregates directly from the coil in two-state folding. Biochemistry 38: 13006–13012.[CrossRef][Medline]

Sørensen, H.P., Sperling-Petersen, H.U., and Mortensen, K.K. 2003. A favorable solubility partner for the recombinant expression of streptavidin. Protein Expr. Purif. 32: 252–259.[CrossRef][Medline]

Speed, M.A., Wang, D.I., and King, J. 1996. Specific aggregation of partially folded polypeptide chains: The molecular basis of inclusion body composition. Nat. Biotechnol. 14: 1283–1287.[CrossRef][Medline]

Svetlov, M.S., Kommer, A., Kolb, V.A., and Spirin, A.S. 2006. Effective cotranslational folding of firefly luciferase without chaperones of the Hsp70 family. Protein Sci. 15: 242–247.[Abstract/Free Full Text]

Tang, Y.C., Chang, H.C., Roeben, A., Wischnewski, D., Kerner, M.J., Hartl, F.U., and Hayer-Hartl, M. 2006. Structural features of the GroEL-GroES nano-cage required for rapid folding of encapsulated protein. Cell 125: 903–914.[CrossRef][Medline]

Ullers, R.S., Luirink, J., Harms, N., Schwager, F., Georgopoulos, C., and Genevaux, P. 2004. SecB is a bona fide generalized chaperone in Escherichia coli . Proc. Natl. Acad. Sci. 101: 7583–7588.[Abstract/Free Full Text]

Uversky, V.N., Gillespie, J.R., and Fink, A.L. 2000. Why are "natively unfolded" proteins unstructured under physiologic conditions? Proteins 41: 415–427.[CrossRef][Medline]

Vorderwülbecke, S., Kramer, G., Merz, F., Kurz, T.A., Rauch, T., Zachmann-Brand, B., Bukau, B., and Deuerling, E. 2004. Low temperature of GroEL/ES overproduction permits growth of Escherichia coli cells lacking trigger factor and DnaK. FEBS Lett. 559: 181–187.[CrossRef][Medline]

Waldo, G.S. 2003. Genetic screens and directed evolution for protein solubility. Curr. Opin. Chem. Biol. 7: 33–38.[CrossRef][Medline]

Wall, J.G. and Plückthun, A. 1995. Effects of overexpressing folding modulators on the in vivo folding of heterologous proteins in Escherichia coli . Curr. Opin. Biotechnol. 6: 507–516.[CrossRef][Medline]

Williams, C.H., Stillman, T.J., Barynin, V.V., Sedelnikova, S.E., Tang, Y., Green, J., Guest, J.R., and Artymiuk, P.J. 2002. E. coli aconitase B structure reveals a HEAT-like domain with implications for protein-protein recognition. Nat. Struct. Biol. 9: 447–452.[CrossRef][Medline]

Wong, P. and Houry, W.A. 2004. Chaperone networks in bacteria: Analysis of protein homeostasis in minimal cells. J. Struct. Biol. 146: 79–89.[CrossRef][Medline]

Wright, C.F., Teichmann, S.A., Clarke, J., and Dobson, C.M. 2005. The importance of sequence diversity in the aggregation and evolution of proteins. Nature 438: 878–881.[CrossRef][Medline]

Zhang, Y.B., Howitt, J., McCorkle, S., Lawrence, P., Springer, K., and Freimuth, P. 2004. Protein aggregation during overexpression limited by peptide extensions with large net negative charge. Protein Expr. Purif. 36: 207–216.[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

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 Google Scholar

Google Scholar

Articles by Kim, C. W.

Articles by Seong, B. L.

Search for Related Content

PubMed

PubMed Citation

Articles by Kim, C. W.

Articles by Seong, B. L.

Social Bookmarking

What's this?