Genetic selection for protein solubility enabled by the folding quality control feature of the twin-arginine translocation pathway

doi:10.1110/ps.051902606

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Genetic selection for protein solubility enabled by the folding quality control feature of the twin-arginine translocation pathway

Adam C. Fisher¹, Woojin Kim² and Matthew P. Delisa¹

¹ School of Chemical and Biomolecular Engineering, Cornell University, Ithaca, New York 14853, USA
² Department of Chemistry, Princeton University, Princeton, New Jersey 08544-1009, USA

Reprint requests to: Matthew P. DeLisa, 254 Olin Hall, Cornell University, Ithaca, NY 14853, USA; e-mail: md255{at}cornell.edu; fax: (607) 255-9166.

(RECEIVED October 11, 2005; FINAL REVISION November 17, 2005; ACCEPTED November 21, 2005)

Abstract

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Abstract
Introduction
Results
Discussion
Materials and methods
References

One of the most vexing problems facing structural genomics effortsand the biotechnology enterprise in general is the inabilityto efficiently produce functional proteins due to poor foldingand insolubility. Additionally, protein misfolding and aggregationhas been linked to a number of human diseases, such as Alzheimer’s.Thus, a robust cellular assay that allows for direct monitoring,manipulation, and improvement of protein folding could havea profound impact. We report the development and characterizationof a genetic selection for protein folding and solubility inliving bacterial cells. The basis for this assay is the observationthat protein transport through the bacterial twin-arginine translocation(Tat) pathway depends on correct folding of the protein priorto transport. In this system, a test protein is expressed asa tripartite fusion between an N-terminal Tat signal peptideand a C-terminal TEM1 $beta$ -lactamase reporter protein. We demonstratethat survival of Escherichia coli cells on selective mediumexpressing a Tat-targeted test protein/ $beta$ -lactamase fusion correlateswith the solubility of the test protein. Using this assay, weisolated solubility-enhanced variants of the Alzheimer’sA $beta$ 42 peptide from a large combinatorial library of A $beta$ 42 sequences,thereby confirming that our assay is a highly effective selectiontool for soluble proteins. By allowing the bacterial Tat pathwayto exert folding quality control on expressed target proteinsequences, we have generated a powerful tool for monitoringprotein folding and solubility in living cells, for molecularengineering of solubility-enhanced proteins or for the isolationof factors and/or cellular conditions that stabilize aggregation-proneproteins.

Keywords: protein structure/folding; stability and mutagenesis; protein trafficking/sorting; peptide/fragment isolation; cDNA; cloning; synthesis of peptides and proteins

Article published online ahead of print. Article and publication date are at http://www.proteinscience.org/cgi/doi/10.1110/ps.051902606.

Introduction

TOP
Abstract
Introduction
Results
Discussion
Materials and methods
References

The expression of heterologous proteins represents a cornerstoneof the biotechnology enterprise. A major challenge stems fromthe fact that protein folding and solubility can be problematicin the crowded cellular milieu, where the macromolecular concentrationcan reach 300–400 mg/mL (Lorimer 1996; Ellis and Minton 2003).As a result, many commercially important proteins misfoldand aggregate when expressed in a heterologous host (Georgiou and Valax 1996;Makrides 1996; Baneyx and Mujacic 2004). Similarly,protein misfolding and aggregation is the pathological hallmarkof more than a dozen diseases, including Alzheimer’s disease(Radford and Dobson 1999; Ross and Poirier 2004). Thus, a geneticselection for protein solubility, where the term "solubility"is used here to denote both the chemical solubility relatedto folding and the absence of aggregation or degradation, couldhave a number of important consequences. First, it could beused to rapidly improve the soluble yield of a protein by optimizingits primary sequence (Roodveldt et al. 2005) or its cellularfolding environment (Wall and Pluckthun 1995). For this purpose,a selection is advantageous because analyzing large numbersof mutant sequences without automation can become time- andcost-prohibitive. Second, it could be used to assay for cofactorsand small molecules that promote correct folding or inhibitthe aggregation of heterologously expressed proteins or proteinsassociated with human disease (e.g., Alzheimer’s A $beta$ 42 peptide)(Williams et al. 2005).

Development of a robust in vivo selection for stably expressedproteins has been challenging because of limitations associatedwith detecting and reporting intra-cellular solubility. Nonetheless,a handful of cellular protein folding assays have been reportedto date. Most of these systems have capitalized on the observationthat a misfolded target protein will often induce improper foldingof a C-terminally fused reporter protein or protein fragment(Maxwell et al. 1999; Waldo et al. 1999; Wigley et al. 2001;Cabantous et al. 2005) or will induce a specific gene response(Lesley et al. 2002). A drawback of these approaches is thatsolubility is reported indirectly, i.e., reporter protein activitymust correlate with the folding of the fusion partner. An undesiredoutcome is that certain reporter proteins can remain activeeven when the target protein to which they are fused is insoluble(Philibert and Martineau 2004) or aggregated (Tsumoto et al. 2003).Our goal was to engineer a genetic selection for proteinsolubility that does not require coupling between the foldingbehavior of a target protein and reporter activity but ratherrelies on authentic cellular quality control.

In bacterial cells, specific targeting and transport mechanismsare required to move proteins along transport pathways fromtheir site of synthesis in the cytoplasm to extra-cytoplasmicdestinations. One such pathway, the twin-arginine translocation(Tat) pathway, is capable of delivering folded proteins acrossbiological membranes via translocation machinery comprised ofthe Tat (A/E)BC proteins (Berks 1996; Settles et al. 1997; Weiner et al. 1998).Recent in vivo studies demonstrate a clear abilityof the Tat pathway to selectively discriminate between properlyfolded and misfolded proteins in vivo and suggest the existenceof a folding quality control mechanism intrinsic to the process(Sanders et al. 2001; DeLisa et al. 2003). Here we have exploitedthis natural quality control feature to report protein solubilitydirectly in bacterial cells by engineering a tripartite fusionof a Tat signal peptide, a target protein, and mature $beta$ -lactamase(Bla). Since Bla only confers antibiotic resistance on Gram-negativebacteria when present in the periplasmic space, it minimallyacts to report the cellular localization of the fusion proteinand not its solubility per se. A similar tripartite constructwas recently employed by Benkovic and coworkers to select forcorrect nucleic acid reading frame (Lutz et al. 2002). It washypothesized by these authors and later demonstrated (Gerth et al. 2004)that the Tat quality control mechanism unavoidablybiased the reading frame selection toward folded structures.While this was not a desirable characteristic for reading frameselection, it appeared to hold great promise for a genetic reporterof protein solubility. Accordingly, in the present study, weconfirm that the inherent folding quality control of the Tatpathway, in concert with other intrinsic mechanisms of in vivoquality control (e.g., protease degradation, insoluble aggregation),can be harnessed to reveal the genuine solubility of a widearray of prokaryotic and eukaryotic proteins targeted for Tattransport.

Results

TOP
Abstract
Introduction
Results
Discussion
Materials and methods
References

Folding quality control of the Tat pathway
Previous data indicated that the Tat system possesses an innatequality control mechanism; however, this was limited to proteinsthat required disulfide bonds, cofactor insertion, or subunitinteractions to stabilize their native structure (Rodrigue et al. 1999;Sanders et al. 2001; DeLisa et al. 2003; Jack et al. 2004).It was not clear from these studies the extent to whichthe Tat quality control feature extended to other proteins thatform off-pathway intermediates for reasons unrelated to disulfidebond formation or cofactor insertion. This is important becauseearly events during protein biogenesis that lead to thermodynamicallyor kinetically trapped intermediates often precede disulfidebond formation, which is typically a later step in folding.Therefore, we evaluated Tat transport of Escherichia coli maltosebinding protein (MBP) and three well-characterized MBP mutantsprone to increasing levels of off-pathway folding intermediates,in order: MBP-G32D, MBP-I33P, and MalE31 (G32D/I33P) (Betton and Hofnung 1996).The difference between wild-type MBP andMalE31 is >100-fold in their in vivo solubility which correspondsto in vitro stability measurements (–5.5 kcal/mol to –9.5kcal/mol) (Betton and Hofnung 1996). The coding region for theTat-specific E. coli TMAO reductase (TorA) signal peptide plusthe first four residues of mature TorA (ssTorA, amino acid residues1–46) (DeLisa et al. 2002) was fused upstream of the geneencoding the mature form of each MBP (residues 26–396),creating four ssTorA-MBP chimeras in pTrc99A. The ssTorA signalwas selected based on its noted fidelity for the Tat pathway(DeLisa et al. 2003). Cell fractionation of wild type MC4100E. coli was performed to track subcellular localization andrevealed that the periplasmic yield of each MBP mutant was consistentwith its level of soluble expression in the cytoplasm (Fig.2A, below). Notably, the insoluble fractions were largely devoidof any of the ssTorA-MBP fusion proteins (data not shown), whichwas particularly surprising for the I33P and MalE31 constructs.While little is known about the mechanistic details of the Tatquality control mechanism, this can best be explained by theobservation that transport-incompetent Tat substrates are efficientlydegraded as part of a poorly characterized "housecleaning" mechanismassociated with the Tat system (Santini et al. 1998; DeLisa et al. 2003).Importantly, no transport of any MBP was everobserved in a ${Delta}$ tatC mutant strain (B1LK0) that is incapable ofTat transport (Bogsch et al. 1998; data not shown), confirmingthat this phenomenon was Tat-specific. The simple fact thatthe quantity of soluble protein in the cytoplasm reflected thequantity of that protein transported to the periplasm suggestedthat the Tat pathway could serve as a useful framework for assessingrecombinant protein solubility.

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Figure 2. Proofreading of misfolded proteins by the Tat system. An equivalent number of cells were harvested 6 h after induction and fractionated into cytoplasmic (cyt) and periplasmic (per) fractions using the method of ice-cold osmotic shock described in the Materials and Methods section. (A) Subcellular distribution of MBP (wt), MBP-G32D, MBP-I33P, and MalE31 (MBP-G32D/I33P) expressed via the Tat pathway (ssTorA) and probed by anti-MBP serum. For these experiments, E. coli strain HS3018 (Shuman 1982) lacking a chromosomal copy of malE was used. GroEL was used simply as a fractionation marker by probing with anti-GroEL serum. Increased GroEL expression in the presence of misfolded MalE31 is documented. Cytoplasmic lanes were overloaded until MBP-I33P bands were clearly visible. An equivalent number of cells were harvested 6 h after induction and fractionated into cytoplasmic (cyt) and periplasmic (per) fractions. Cells expressing ssTorA-MBP(wt)-Bla, ssTorA-MBP(G32D)-Bla, ssTorA-MBP(I33P)-Bla, and ssTorA-MalE31-Bla were assayed for subcellular distribution of the fusion protein (B) by probing with Bla anti-serum. GroEL was used as a fractionation marker by probing with GroEL antiserum. (C) Relative periplasmic Bla activity as determined by the rate of nitrocefin hydrolysis (gray bars) and relative growth rate as determined by 96-well plate liquid growth assays (white bars). All data were normalized to the activity (0.146 abs units/ sec) and the growth rate (0.387 h^–1) of cells expressing ssTorA-MBP(wt)-Bla. Lastly, growth on solid medium by spot plating 5 µL of an equivalent number of cells on LB agar supplemented with 100 µg/mL Amp (D) or 25 µg/mL Cm (E).

A Tat-based solubility reporter
To exploit the quality control feature of the Tat pathway forthe development of a broad-spectrum protein folding assay, weengineered a genetic selection that employed a tripartite fusionof ssTorA, a "target" protein, and mature TEM1 $beta$ -lactamase (Bla)(Fig. 1A

). The premise for this assay is as follows: A stabletarget protein is exported to the periplasm via Tat and, byvirtue of the Bla fusion, confers Amp resistance to E. colicells expressing the ssTorA-target-Bla chimera. To verify thatBla is indeed capable of reporting Tat-dependent transport,we constructed vector pTMB with no gene in the target positionthat expresses ssTorA-Bla. Upon expression of ssTorA-Bla inMC4100 and B1LK0, we only observed an Amp-resistant phenotypein MC4100 cells (Fig. 1B

) indicating that Bla was specificallytransported by the Tat pathway.

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Figure 1. Exploiting the Tat pathway’s folding quality control feature for monitoring protein solubility. (A) A tripartite fusion protein is created between a Tat signal peptide (e.g., ssTorA), a target protein, and the TEM1 $beta$ -lactamase protein (Bla). Discrimination between folded and misfolded target sequences is accomplished by the Tat machinery such that only correctly folded, soluble proteins are localized to the periplasm. Concomitant delivery of Bla to the E. coli periplasm confers an Amp resistant phenotype to cells. (B) The growth of MC4100/pTMB and B1LK0/pTMB cells on LB agar plates supplemented with either 25 µg/mL Cm (control) or 100 µg/mL Amp, indicating unambiguously that Bla can be used as a Tat-specific reporter.

Next, we inserted the gene encoding mature MBP or one of thethree destabilized mutants into the target position of pTMB.Upon expression in MC4100, it was found that the amount of solublessTorA-MBP-Bla in the cytoplasm correlated both to the periplasmicyield of the fusion protein and the cellular growth rate inAmp (Fig. 2B,C

). In the case of poorly folded ssTorA-MBP sequences(I33P and MalE31), the low cytoplasmic levels are best explainedby increased degradation as a result of incompatibility withthe Tat pathway (Santini et al. 1998; DeLisa et al. 2003). Thedifferences in MBP solubility reported by our assay were inagreement with previous reports of wild type and variant MBPsolubility in the cytoplasm of E. coli (Betton and Hofnung 1996;Wigley et al. 2001) and confirm that we can effectively reportintermediate changes in target protein solubility. Furthermore,relative growth levels on solid medium containing Amp couldbe used to discriminate between cells expressing stable andunstable versions of MBP (Fig. 2D

). As no growth was observedfor B1LK0 cells on Amp expressing any of the ssTorA-MBP-Blafusions, we conclude that the fusions are exclusively routedvia the Tat pathway. Importantly, B1LK0 cells carrying reporterplasmids grew equally well as MC4100 in the absence of Amp (Fig.2E

), confirming that B1LK0’s inability to grow on Ampwas due to a blockage in transport and not due to a generalgrowth defect.

To explore the generality of this assay, eight additional proteinsof prokaryotic and eukaryotic origin were tested using our foldingreporter. These target proteins ranged from the highly stableE. coli proteins glutathione S-transferase (GST) and thioredoxin(TrxA) to E. coli alkaline phosphatase (PhoA), a periplasmicenzyme that is unstable in the cytoplasm where its two disulfidebonds are incapable of forming (Sone et al. 1997), and TraR,a transcriptional activator from Agrobacterium tumefaciens thatis highly unstable in the E. coli cytoplasm in the absence ofits cognate ligand (Zhu and Winans 2001). Expression of alltarget proteins known to be stable in the cytoplasm, namelyTrxA, GST, green fluorescent protein (GFP), Top7 (Kuhlman et al. 2003),and human tumor suppressor protein p53 core domain(residues 94–312) (Friedler et al. 2003) resulted in localizationto the periplasm and conferred Amp resistance to MC4100 (Fig.3, lanes 1–5). On the contrary, those known to be highlyunstable, namely PhoA, TraR, and the human testicular cancerantigen NY-ESO1 (Chen et al. 1997; Murphy et al. 2005) werevirtually undetectable in the soluble cytoplasmic fraction anddid not confer Amp resistance to MC4100 (Fig. 3, lanes 6–8).Though there was no visible periplasmic band for ssTorA-p53-Bla,it conferred significant Amp resistance to cells and the correspondingperiplasmic Bla activity was threefold above ssTorA-PhoA-Blanegative controls, suggesting that the level of this fusionprotein in the periplasmic fraction was below the thresholdof immunodetection. Interestingly, the extremely stable de novo-designedTop7 protein, exhibiting an ${alpha}$ / $beta$ protein structure not previouslyobserved in nature (Kuhlman et al. 2003), conferred significantAmp resistance to cells.

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Figure 3. The Tat-specific genetic selection correctly reports the solubility of a broad spectrum of target proteins. (A) Growth of MC4100 cells on LB agar supplemented with 100 µg/mL Amp expressing GST (23 kDa), TrxA (14 kDa), Top7 (11 kDa), GFP (23 kDa), p53 (25 kDa), NY-ESO1 (14 kDa), TraR (27 kDa), or PhoA (49 kDa) in the target position of pTMB (molecular weights in kDa reflect the test protein alone). Each spot represents 5 µL of an equivalent number of overnight grown cells. (B) Relative growth rate of MC4100 cells as determined by 96-well plate liquid growth assays. All data were normalized to the growth rate of cells expressing ssTorA-GST-Bla (0.399 h^–1). (C) Subcellular localization of each tripartite fusion expressed in MC4100. All samples were probed with anti-Bla serum. Cells expressing pTMB with no insert are shown in lane 1 for comparison. (D) Localization of cytoplasmic marker GroEL probed with anti-GroEL serum.

An unanswered question was whether these stably expressed targetproteins were truly folded and, if so, whether their foldingwas completed in the cytoplasm prior to export. To address thisissue we examined the subcellular fractions generated from wild-typecells expressing the ssTorA-GFP-Bla fusion. GFP is a heterologousprotein known to fold into its native fluorescent conformationin the cytoplasm but is incapable of folding into an activeconformation in the periplasm (Feilmeier et al. 2000). Thus,the presence of fluorescent GFP in the periplasm is a strongindicator of cytoplasmic folding prior to transport (Santini et al. 2001;Thomas et al. 2001; DeLisa et al. 2002). We observedthat the GFP-Bla fusion protein in the periplasmic fractionof MC4100 cells was strongly fluorescent (>15-fold abovethe signal from the periplasmic fraction of B1LK0; data notshown). Since active periplasmic GFP can only arise from foldingprior to transport (Santini et al. 2001; Thomas et al. 2001;DeLisa et al. 2002), we conclude that the kinetics of Tat transportallow complete folding prior to translocation.

Monitoring multimeric proteins
Based on the observation that the dimeric E. coli GST proteinwas transported to the periplasm (Fig. 3) and that the Tat systemis known to translocate pre-assembled heterodimers (Rodrigue et al. 1999;DeLisa et al. 2003), we next explored the extentto which our reporter was able to process stable multimericproteins. Specifically, we examined transport of Discosoma coralDsRed (version T1) and two mutants derived from DsRed, namelydimer2 and mRFP1 (Campbell et al. 2002). Whereas DsRed.T1 formsobligate tetramers which tend to aggregate, Tsien and coworkersevolved a useful monomeric variant (mRFP1) that does not aggregatein vivo. We reasoned that as the evolved proteins become smaller(tetramer, dimer, monomer) and more soluble they would be moreefficiently processed by the Tat machinery. To test this notion,we constructed three ssTorA-DsRed chimeras and tracked theirsubcellular localization. The periplasmic yield of each fusionprotein in MC4100 was consistent with its level of soluble expressionin the cytoplasm (Fig. 4A). That is, mRFP accumulated at a highlevel in the periplasm; dimer2, at an intermediate level; andDsRed was undetectable in the periplasmic space. Importantly,the observed transport for mRFP and dimer2 was Tat-specificas neither of these fusion proteins localized in the periplasmof B1LK0 (data not shown).

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Figure 4. Monitoring the aggregation properties of DsRed and its variants. An equivalent number of cells were harvested 6 h after induction and fractionated into cytoplasmic (cyt) and periplasmic (per) fractions. (A) Subcellular distribution of DsRed.T1, dimer2, and mRFP1 expressed via the Tat pathway (ssTorA) and probed by anti-DsRed serum. Cells expressing ssTorA-DsRed.T1-Bla, ssTorA-dimer2-Bla, and ssTorA-mRFP1-Bla were assayed for subcellular distribution of the fusion protein (B) by probing with Bla anti-serum. GroEL was used as a fractionation marker by probing with GroEL anti-serum. (C) Relative periplasmic Bla activity as determined by the rate of nitrocefin hydrolysis (gray bars) and relative growth rate as determined by 96-well plate liquid growth assays (white bars). All data were normalized to the activity (0.152 abs units/sec) and the growth rate (0.390 h^–1) of cells expressing ssTorA-mRFP1-Bla. Lastly, growth on solid medium by spot plating 5 µL of an equivalent number of cells on LB agar supplemented with 100 µg/mL Amp (D) or 25 µg/mL Cm (E).

Similar results were observed when the DsRed.T1, dimer2, andmRFP1 sequences were inserted into pTMB. That is, cells expressingssTorA-DsRed.T1-Bla did not localize the fusion protein to theperiplasm and were incapable of growth on Amp (Fig. 4B

), consistentwith our observation that ssTorA-DsRed.T1 alone is not transportedvia the Tat mechanism. On the contrary, cells expressing ssTorA-mRFP1-Blashowed significant periplasmic accumulation of the fusion andwere resistant to Amp, in accord with the increased solubilityof mRFP1 relative to DsRed.T1. There was a low but detectablelevel of ssTorA-dimer2-Bla in the periplasm. The reduced quantityof ssTorA-dimer2-Bla relative to the unfused ssTorA-dimer2 (Fig.4A

) is likely due to its increased molecular mass as a resultof the fusion to Bla. Nonetheless, cells expressing this fusiondisplayed intermediate levels of periplasmic Bla activity andgrowth on Amp which were significantly above the levels seenfor cells expressing ssTorA-DsRed.T1-Bla and indicated thatthis engineered dimer could be detected by our assay (Fig. 4B,C

).Finally, no growth was observed for B1LK0 expressing any ofthe ssTorA-DsRed-Bla fusions indicating that transport was Tat-specific.These data suggest that monomeric or even dimeric proteins arepreferentially transported by the Tat pathway, as opposed tolarger multimers.

Monitoring protein folding related to human disease
To test the extent to which the assay was effective in reportingsolubility in the context of protein aggregation in human disease,the Alzheimer’s amyloid $beta$ -peptide (A $beta$ 42), which is the primarycomponent of amyloid fibrils found in the brains of Alzheimer’spatients (Selkoe 2001), was analyzed using our reporter. Therelative growth rates in Amp of MC4100 expressing wild-typeA $beta$ 42 and a collection of A $beta$ 42 mutants were measured. In agreementwith previous data (Wigley et al. 2001), A $beta$ 42(wt) did not confergrowth to MC4100 (Fig. 5A,B). We next screened a panel of solubility-enhancedA $beta$ 42 variants, which were previously isolated using a directedevolution strategy in combination with a GFP-based folding assay(Wurth et al. 2002). In all but two instances, our growth rateresults (Fig. 5A, gray bars) were in agreement with solubilitydata reported previously for these sequences by Hecht and coworkers(Wurth et al. 2002) using A $beta$ 42-GFP fusions (Fig. 5A, white bars).Interestingly, for GM16 and GM18, which each contained the criticalL34P mutation (Fig. 5A), there was notable disagreement betweenthe two assays, which could indicate a folding reporter biasimparted by a C-terminal GFP fusion versus our Tat quality control-basedassay. Overall, we found that amino acid substitutions thatdecrease the propensity of A $beta$ 42 to aggregate rendered the fusionprotein competent for transport and conferred an Amp-resistantphenotype to cells (Fig. 5A,B).

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Figure 5. Analysis of amyloid- $beta$ peptide (A $beta$ 42) and its derivatives. Growth of MC4100 cells as determined by (A) 96-well plate liquid growth assays (gray bars) and (B) spot plating 5 µL of an equivalent number of cells on LB agar supplemented with 100 µg/mL Amp for the following target sequences (from left to right): (wt) wild type A $beta$ 42, (GM1) A $beta$ 42 I32S, (GM19) A $beta$ 42 F19S, (GM11) A $beta$ 42 H6Q/V12A/ V24A/I32M/V36G, (GM3) A $beta$ 42 V12E/V18E/M35T/I41N, (GM7) A $beta$ 42 V12A/I32T/L34P, (GM6) A $beta$ 42 F19S/L34P, (GM18) A $beta$ 42 L34P, and (GM16) A $beta$ 42 F4I/S8P/V24A/L34P. All data were normalized to the growth rate of cells expressing ssTorA-A $beta$ 42(GM6)-Bla (0.240 h^–1). Relative fluorescence of A $beta$ 42-GFP fusions (white bars) was calculated by normalizing cell fluorescence for each fusion to that emitted from A $beta$ 42 F19S/L34P (GM6). (C) The sequence of wt, GM6, and the entire collection of A $beta$ 42 sequences isolated using the Tat folding assay. This collection, including clone A17, was isolated from a high-rate mutagenesis of the A $beta$ 42 peptide, followed by selection on Amp-containing growth medium.

Selection of solubility-enhanced variants from large combinatorial libraries
To demonstrate the efficacy of our selection assay, we firstperformed selection experiments in which cells expressing awell-folded model protein, GFP, and a poorly folded model protein,PhoA, were mixed and subsequently plated on selective media.When GFP:PhoA-expressing cells were mixed at a ratio of 1:10⁶,we only recovered GFP expressing cells on Amp plates at a ratioof 1 GFP expressing (and fluorescent) colony for every 0.9 ±0.1 x 10⁶ cells that were plated, (determined by plating mixtureon Cm plates; data not shown). Encouraged by these results,we performed a second selection experiment by subjecting theA $beta$ 42 sequence to high-rate mutagenesis (determined to be 15%error at the amino acid level in the naïve library) followedby selection of Amp-resistant clones representing solubility-enhancedvariants of the A $beta$ 42 peptide. From a cell library of ~1.5 x 10⁶members, we selected 2.8 x 10³ cells on Amp-containing plates.Plasmids from 20 randomly chosen positive clones were isolatedand sequenced. Notably, in residues F19 and L34 alone therewere a total of 22 mutations in our collection of 20 clones.These sites are identical to those found in the stable variantGM6 (F19S, L34P) and in previous mutagenesis studies of A $beta$ 42(Wood et al. 1995; Wurth et al. 2002). In fact, 17 of the 20clones carried mutations in one or both of these two residues.It is noteworthy that only two of 17 clones from the naïvelibrary selected at random contained a mutation in either F19or L34, suggesting that the 17 positive clones were indeed selectedand not artificially biased in the naïve library. Serendipitously,in just these 20 clones we isolated a variant, A17 (F19S, L34P,M35G, I41V), which differed by only two amino acids from cloneGM6 (F19S, L34P) isolated by Hecht and colleagues (Wurth et al. 2002;Fig. 5C

). Sequencing results revealed that of 124total mutations present in the 20 positive clones, 15 came fromthe central hydrophobic cluster (residues 17–21) and 34came from the hydrophobic cluster located at residues 30–36.These regions represent only 29% of the primary structure butaccount for 40% of the total mutations and 47% of the nonconservativemutations uncovered by our selection. Collectively, these resultssupport the use of our genetic selection for the isolation ofsolubility-enhancing mutations from a highly mutated library.

Discussion

TOP
Abstract
Introduction
Results
Discussion
Materials and methods
References

The bacterial Tat pathway is known for its ability to transportfolded proteins from their site of synthesis in the cytoplasmto the periplasmic space. This feat is accomplished by an innermembrane pore complex minimally comprised of the membrane proteinsTatA/E, TatB and TatC (Berks etal. 2000). The Tat(A/E)BC poreexhibits a variable diameter as large as ~50–70 Å(Sargent et al. 2001), which helps to explain how the Tat systemcan accommodate a wide range of folded proteins with molecularweights as large as 120kDa (Berks et al. 2000; Sargent et al. 2001;Gohlke et al. 2005). In nature, proteins are thought touse the Tat rather than the traditional general secretory (Sec)pathway if they require cofactor binding (Santini et al. 1998)or subunit assembly (Rodrigue et al. 1999), or simply fold toorapidly to be Sec export competent (Berks 1996). Earlier geneticstudies (Sanders et al. 2001; DeLisa et al. 2003), along withdata presented here, demonstrate a clear ability of the Tatpathway to selectively translocate proteins that are correctlyfolded and soluble and suggest that a folding quality controlmechanism governs this process. While a number of possible mechanismshave been proposed (Berks et al. 2000; Fisher and DeLisa 2004),to date there is little to no evidence detailing how this processoperates in bacteria. Sargent and coworkers (Jack etal. 2004)have recently demonstrated that, for endogenous cofactor-containingTat substrates, proofreading is performed by a cytoplasmic chaperone.However, the extent to which this mechanism relates to the overallquality control of the Tat pathway remains an open question.In addition, bacteria have other elegant mechanisms of qualitycontrol, such as protease degradation and chaperonin activity,that likely work in concert with the Tat quality control mechanismto provide an authentic in vivo quality control that constitutesthe underlying framework for our reporter assay. We showed thata facile genetic selection for protein solubility that capitalizeson this quality control feature was possible by fusing an N-terminalTat signal peptide and a C-terminal Bla reporter protein toa desired test protein. The practical utility of this assayis its ability to survey the folding status of the test protein.Indeed, the assay reported the folding behavior of 26 proteinsof prokaryotic and eukaryotic origin, a feat that could be accomplishedin <8 h by monitoring bacterial growth in a 96-well plateformat. Assays were held to <8 h because over longer times, ${Delta}$ tatC cells occasionally exhibited a low level of Amp resistancein liquid cultures, particularly for the highly-expressed TrxAfusion. This could arise from release of soluble Bla into themedium following cell lysis or from a proteolytic cleavage eventbetween the two protein domains creating an accumulation ofmature Bla that can be translocated into the periplasmic space,albeit with a low efficiency (Bowden et al. 1992). This reinforcesthe fact that when performing Tat-based assays, positive resultsare only relevant when tested against a ${Delta}$ tatC control.

One shortcoming of many existing in vivo folding assays (Maxwell et al. 1999;Waldo et al. 1999; Wigley et al. 2001; Cabantous et al. 2005)is the possibility that the fusions might incorrectlybias the folding behavior of the test protein. Although stableassociation between Tat signal peptides and the protein to whichthey are fused is disfavored (Nurizzo et al. 2001; Kipping et al. 2003),we cannot rule out the possibility that Tat signalsmay influence the folding of target proteins or shield themfrom degradation. It is also possible that C-terminal $beta$ -lactamasemay impact folding of the target protein in some unforeseenway. However, any effect these fusions may have was not manifestedin any of the 26 proteins tested here, as correct folding behaviorof virtually every target protein was reported. We suspect thatthe success of our assay arises from the fact that an authenticquality control mechanism is used to screen folding as opposedto reliance upon cotranslational misfolding of the reporter.It is noteworthy that our reporter assay compares favorablyto previous in vivo assays based on cotranslational folding(e.g., GFP fusions [Waldo et al. 1999; Wurth et al. 2002, seeFig. 6]). One constraint on our assay is that transport mightbe inaccessible to fusions whose size exceeds the upper limithandled by the Tat pore (~120 kDa is the largest known proteinreported to transit the Tat pathway). Nonetheless, fusions aslarge as 70 kDa (ssTorA-MBP-Bla) were efficiently translocated.If necessary, larger target proteins or protein dimers mightbe screened by employing a fragment complementation approach(Wigley et al. 2001; Cabantous et al. 2005) to reduce the sizeof the Bla reporter.

A clear advantage of our assay is the easy potential to performa phenotypic selection. That is, this genetic system could beused to screen combinatorial libraries for genes expressingproteins with enhanced folding properties and decreased tendenciestoward aggregation, i.e., "supersoluble" proteins (Lansbury 2001).This selection could also be employed in a wide arrayof bacterial strains to isolate genetic backgrounds that supportefficient expression and folding of target proteins. Furthermore,since Tat-targeted proteins have a significant residence timein the cytoplasm prior to transport, this assay is amenableto studying slow misfolding or aggregation events that may escapedetection by cotranslational folding schemes. Finally, sinceall correctly folded proteins in our selection localize in theperiplasm, we envision that two-dimensional genetic assays canbe performed for identifying proteins that exhibit not onlyrobust folding properties but also activities that can easilybe probed by substrates permeable to the outer membrane. Inessence, isolating proteins based on structure and function.

Materials and methods

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Abstract
Introduction
Results
Discussion
Materials and methods
References

Bacterial strains and plasmids
Wild-type E. coli strain MC4100 and a ${Delta}$ tatC derivative of MC4100,strain B1LK0 (Bogsch et al. 1998), were used for all foldingassay experiments. Strain HS3018 (Shuman 1982) was used forexpression of MBP. All plasmids generated in this study werederivatives of pTrc99A (Amersham Pharmacia) unless otherwisenoted. For all folding reporter plasmids, pTrc99A was modifiedas follows: The $beta$ -lactamase (Bla) gene was replaced with a Cm^rcassette to generate pTrc99A-Cm (kindly provided by M. Zhaoand G. Georgiou), followed by sequential insertion of the DNAencoding the ssTorA signal peptide (DeLisa et al. 2002) andthe $beta$ -lactamase protein. The resulting plasmid, hereafter pTMB,contained three additional restriction sites (XbaI, SalI, andBamHI) immediately after the ssTorA sequence to allow facileinsertion of target DNA sequences between ssTorA and Bla (Fig.1). For all plate-based selection experiments, the vector pSALectwas used since conditions for recovering ampicillin (Amp) resistantcolonies has already been documented (Lutz et al. 2002). TheA $beta$ 42 target sequence was cloned into pSALect between the DNAencoding ssTorA and Bla. Combinatorial libraries of A $beta$ 42 weresynthesized by mutagenesis of the A $beta$ 42 gene sequence using thenucleotide analog method of Zaccolo et al. (1996) and the resultinggene library was inserted into pSALect. All plasmids constructedin this study were confirmed by DNA sequencing.

Cell growth assays
Cells carrying a folding reporter plasmid were grown overnightin LB medium containing chloramphenicol (Cm; 25 µg/mL).Screening of cells on solid plates was performed by spotting5 µL of 10x-diluted overnight cells directly onto LB agarplates supplemented with Amp (100 µg/mL) or Cm (25 µg/mL)and growing overnight at room temperature. Library selectionswere performed by electroporating plasmid DNA libraries intoE. coli cells followed by direct plating on LB agar plates supplementedwith 100 µg/mL Amp according to Lutz et al. (2002). Screeningof cells in liquid culture was performed by diluting overnightcells 100-fold into fresh LB plus 100 µg/mL Amp in 96-wellplates. Cells were grown aerobically at 30°C for ~6 h andgrowth rates were calculated as from the absorbance change at600 nm using a plate reader. All growth rate data is the averageof three cultures grown in parallel. Error is reported as plusor minus the standard deviation of these data.

Protein analysis
Subcellular fractionation was performed using the ice-cold osmoticshock procedure (Sargent et al. 1998; DeLisa et al. 2003). Westernblotting of these fractions was performed as previously described(DeLisa et al. 2003). The quality of all fractionations wasdetermined by immunodetection of the cytoplasmic GroEL protein(DeLisa et al. 2003). Finally, osmotic shockate (i.e., periplasmicfractions) was assayed for $beta$ -lactamase activity based on nitrocefinhydrolysis in 96-well format as described (Galarneau et al. 2002).

Acknowledgments

We thank David Baker, Carl Batt, Jean-Michel Betton, Alan Fersht,Michael Hecht, Philip Thomas, Roger Tsien, Steve Winans, andStefan Lutz for plasmid DNA used in this study, and Tracy Palmerand Howard Shuman for strains B1LK0 and HS3018, respectively.We thank Michael Hecht and Philip Bronstein for helpful discussionsof the manuscript. Funding was provided by an NSF CAREER Award(BES no. 0449080) and a NYSTAR James D. Watson Award (both toM.P.D).

References

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