Folding pathway mediated by an intramolecular chaperone: the structural and functional characterization of the aqualysin I propeptide

Aqualysin I, a thermostable homologue of subtilisin, requires its propeptide (ProA) to function as an intramolecular chaperone (IMC). To decipher the mechanisms through which propeptides can initiate protein folding, we characterized ProA in terms of its sequence, structure and function. Our results show that, in contrast to ProS (propeptide of subtilisin), ProA can fold spontaneously, reversibly and cooperatively into a stable monomeric alpha-beta conformation, even when isolated from its cognate protease-domain. ProA displays an indiscernible amount of tertiary structure with a considerable solvent-accessible hydrophobic surface, but is not a classical molten-globule folding intermediate. Moreover, despite showing only 21 % sequence identity with ProS, ProA can not only inhibit enzymatic activity with a magnitude tenfold greater than ProS, but can also chaperone subtilisin folding, albeit with a lower efficiency. The structure of ProA complexed with subtilisin is different from that of isolated ProA. Hence, additional interactions seem necessary to induce ProA into a compact structure. Our results also suggest that: (a) propeptides that are potent inhibitors are not necessarily better IMCs; (b) propeptides within the subtilase family appear polymorphic and; (c) the intrinsic instability within propeptides may be necessary for rapid activation of the cognate protein.     

Functional analysis of propeptide as an intramolecular chaperone for in vivo folding of subtilisin nattokinase

Here, we show that during in vivo folding of the precursor, the propeptide of subtilisin nattokinase functions as an intramolecular chaperone (IMC) that organises the in vivo folding of the subtilisin domain. Two residues belonging to β-strands formed by conserved regions of the IMC are crucial for the folding of the subtilisin domain through direct interactions. An identical protease can fold into different conformations in vivo due to the action of a mutated IMC, resulting in different kinetic parameters. Some interfacial changes involving conserved regions, even those induced by the subtilisin domain, blocked subtilisin folding and altered its conformation. Insight into the interaction between the subtilisin and IMC domains is provided by a three-dimensional structural model.     

General function of N-terminal propeptide on assisting protein folding and inhibiting catalytic activity based on observations with a chimeric thermolysin-like protease

Pro-aminopeptidase processing protease (PA protease) is a thermolysin-like metalloprotease produced by Aeromonas caviae T-64. The N-terminal propeptide acts as an intramolecular chaperone to assist the folding of PA protease and shows inhibitory activity toward its cognate mature enzyme. Moreover, the N-terminal propeptide strongly inhibits the autoprocessing of the C-terminal propeptide by forming a complex with the folded intermediate pro-PA protease containing the C-terminal propeptide (MC). In order to investigate the structural determinants within the N-terminal propeptide that play a role in the folding, processing, and enzyme inhibition of PA protease, we constructed a chimeric pro-PA protease by replacing the N-terminal propeptide with that of vibriolysin, a homologue of PA protease. Our results indicated that, although the N-terminal propeptide of vibriolysin shares only 36% identity with that of PA protease, it assists the refolding of MC, inhibits the folded MC to process its C-terminal propeptide, and shows a stronger inhibitory activity toward the mature PA protease than that of PA protease. These results suggest that the N-terminal propeptide domains in these thermolysin-like proteases may have similar functions, in spite of their primary sequence diversity. In addition, the conserved regions in the N-terminal propeptides of PA protease and vibriolysin may be essential for the functions of the N-terminal propeptide.     

Key elements for protein foldability revealed by a combinatorial approach among similarly folded but distantly related proteins

We have determined the key regions for protein foldability by creating multiple crossover libraries from two proteins that share similar fold but have low sequence identity and differ significantly in stability. One protein is the propeptide of a serine protease, subtilisin BPN', and the other is Pleurotus ostreatus proteinase A inhibitor 1 (POIA1). The propeptide has a compact structure when complexed with subtilisin but is unstructured when isolated, whereas POIA1 takes a stable structure. We selected four of the conserved amino acid residues for the boundaries of crossover sites and utilized these residues to make same cohesive-ends to assemble synthetic DNA fragments. Each segment has one or two secondary structure units, and the interchange of these structural elements produces 32 (= 2(5)) combinations, including the propeptide and POIA1. The stability of these mutants was first screened by formation of turbid zones on skim milk plates containing subtilisin BPN'. It was shown that six variants were foldable and structural units necessary for folding were identified. Further fragmentation and recombination of these mutants (the "multisection" method) revealed that two interactions between secondary structures are important; one is interaction between the loop-alpha1 and beta2-turn-beta3, and the other is hydrophobic interaction between the adjoining beta1 and beta4 strands. We were also able to specify the significant amino acid combinations for tolerance to proteolysis. These combinatorial methods not only elucidate how domains can be interchanged to make the whole protein foldable but also extract essential regions for the function, which is correlated with the instability of the molecule.     

Protease propeptide structures,mechanisms of activation,and functions

Abstract

Proteases are a diverse group of hydrolytic enzymes, ranging from single-domain catalytic molecules to sophisticated multi-functional macromolecules. Human proteases are divided into five mechanistic classes: aspartate, cysteine, metallo, serine and threonine proteases, based on the catalytic mechanism of hydrolysis. As a protective mechanism against uncontrolled proteolysis, proteases are often produced and secreted as inactive precursors, called zymogens, containing inhibitory N-terminal propeptides. Protease propeptide structures vary considerably in length, ranging from dipeptides and propeptides of about 10 amino acids to complex multifunctional prodomains with hundreds of residues. Interestingly, sequence analysis of the different protease domains has demonstrated that propeptide sequences present higher heterogeneity compared with their catalytic domains. Therefore, we suggest that protease inhibition targeting propeptides might be more specific and have less off-target effects than classical inhibitors. The roles of propeptides, besides keeping protease latency, include correct folding of proteases, compartmentalization, liganding, and functional modulation. Changes in the propeptide sequence, thus, have a tremendous impact on the cognate enzymes. Small modifications of the propeptide sequences modulate the activity of the enzymes, which may be useful as a therapeutic strategy. This review provides an overview of known human proteases, with a focus on the role of their propeptides. We review propeptide functions, activation mechanisms, and possible therapeutic applications.     

Autotomic behavior of the propeptide in propeptide-mediated folding of prosubtilisin E

The 77 residue propeptide at the N-terminal end of subtilisin E plays an essential role in subtilisin folding as a tailor-made intramolecular chaperone. Upon completion of folding, the propeptide is autoprocessed and removed by subtilisin digestion. This propeptide-mediated protein folding has been used as a paradigm for the study of protein folding. Here, we show by three independent methods, that the propeptide domain and the subtilisin domain show distinctive intrinsic stability that is obligatory for efficient autoprocessing of the propeptide domain. Two tryptophan residues, Trp106 and Trp113, on the surface of subtilisin located on one of the two helices that form the interface between the propeptide and the subtilisin domains play a key role in maintaining the distinctive instability of the propeptide domain, after completion of folding. When either of the Trp residues was substituted with Tyr, the characteristic biphasic heat denaturation profile of two domains unfolding was not observed, resulting in a single transition of denaturation. The results provide evidence that the propeptide not only plays an essential role in subtilisin folding, but upon completion of folding it behaves as an independent domain. Once the propeptide-mediated folding is completed, the propeptide domain is readily eliminated without interference from the subtilisin domain. This "autotomic" behavior of the propeptide may be a prevailing principle in propeptide-mediated protein folding.     

Folding pathway mediated by an intramolecular chaperone: dissecting conformational changes coincident with autoprocessing and the role of Ca(2+) in subtilisin maturation.

Subtilisin is produced as a precursor that requires its N-terminal propeptide to chaperone the folding of its protease domain. Once folded, subtilisin adopts a remarkably stable conformation, which has been attributed to a high affinity Ca(2+) binding site. We investigated the role of the metal ligand in the maturation of pro-subtilisin, a process that involves folding, autoprocessing and partial degradation. Our results establish that although Ca(2+) ions can stabilize the protease domain, the folding and autoprocessing of pro-subtilisin take place independent of Ca(2+) ion. We demonstrate that the stabilizing effect of calcium is observed only after the completion of autoprocessing and that the metal ion appears to be responsible for shifting the folding equilibrium towards the native conformation in both mature subtilisin and the autoprocessed propeptide:subtilisin complex. Furthermore, the addition of active subtilisin to unautoprocessed pro-subtilisin in trans does not facilitate precursor maturation, but rather promotes rapid autodegradation. The primary cleavage site that initiates this autodegradation is at Gln19 in the N-terminus of mature subtilisin. This corresponds to the loop that links alpha-helix-2 and beta-strand-1 in mature subtilisin and has indirect effects on the formation of the Ca(2+) binding site. Our results show that the N-terminus of mature subtilisin undergoes rearrangement subsequent to propeptide autoprocessing. Since this structural change enhances the proteolytic stability of the precursor, our results suggest that the autoprocessing reaction must be completed before the release of active subtilisin in order to maximize folding efficiency.     

Folding pathway mediated by an intramolecular chaperone: propeptide release modulates activation precision of pro-subtilisin

Propeptides of several proteases directly catalyze the protein folding reaction. Uncatalyzed folding traps these proteases into inactive molten-globule-like conformers that switch into active enzymes only when their cognate propeptides are added in trans. Although tight binding and proteolytic susceptibility forces propeptides to function as single turnover catalysts, the significance of their inhibitory function and the mechanism of activation remain unclear. Using pro-subtilisin as a model, we establish that precursor activation is a highly coordinated process that involves synchronized folding, autoprocessing, propeptide release, and protease activation. Our results demonstrate that activation is controlled by release of the first free active protease molecule. This triggers an exponential cascade that selectively targets the inhibitory propeptide in the autoprocessed complex as its substrate. However, a mutant precursor that enhances propeptide release can drastically reduce the folding efficiency by altering the synergy between individual stages. Our results represent the first demonstration that propeptide release, not precursor folding, is the rate-determining step and provides the basis for the proposed model for precise spatial and temporal activation that allows proteases to function as regulators of biological function.     

Functional Analysis of the Cucumisin Propeptide as a Potent Inhibitor of Its Mature Enzyme

Cucumisin is a subtilisin-like serine protease (subtilase) that is found in the juice of melon fruits (Cucumis melo L.). It is synthesized as a preproprotein consisting of a signal peptide, NH₂-terminal propeptide, and 67-kDa protease domain. We investigated the role of this propeptide (88 residues) in the cucumisin precursor. Complementary DNAs encoding the propeptides of cucumisin, two other plant subtilases (Arabidopsis ARA12 and rice RSP1), and bacterial subtilisin E were expressed in Escherichia coli independently of their mature enzymes. The cucumisin propeptide strongly inhibited cucumisin in a competitive manner with a K_i value of 6.2 ± 0.55 nm. Interestingly, cucumisin was also strongly inhibited by ARA12 and RSP1 propeptides but not by the subtilisin E propeptide. In contrast, the propeptides of cucumisin, ARA12, and RSP1 did not inhibit subtilisin. Deletion analysis clearly showed that two hydrophobic regions, Asn³²–Met³⁸ and Gly⁹⁷–Leu¹⁰³, in the cucumisin propeptide were important for its inhibitory activity. Site-directed mutagenesis also confirmed the role of a Val³⁶-centerd hydrophobic cluster within the Asn³²–Met³⁸ region in cucumisin inhibition. Circular dichroism spectroscopy revealed that the cucumisin propeptide had a secondary structure without a cognate protease domain and that the thermal unfolding of the propeptide at 90 °C was only partial and reversible. A tripeptide, Ile³⁵-Val³⁶-Tyr³⁷, in the Asn³²–Met³⁸ region was thought to contribute toward the formation of a proper secondary structure necessary for cucumisin inhibition. This is the first report on the function and structural information of the propeptide of a plant serine protease.     

Propeptides Are Sufficient to Regulate Organelle-Specific pH-Dependent Activation of Furin and Proprotein Convertase 1/3

The proprotein convertases (PCs) furin and proprotein convertase 1/3 (PC1) cleave substrates at dibasic residues along the eukaryotic secretory/endocytic pathway. PCs are evolutionarily related to bacterial subtilisin and are synthesized as zymogens. They contain N-terminal propeptides (PRO) that function as dedicated catalysts that facilitate folding and regulate activation of cognate proteases through multiple-ordered cleavages. Previous studies identified a histidine residue (His69) that functions as a pH sensor in the propeptide of furin (PRO(FUR)), which regulates furin activation at pH~6.5 within the trans-Golgi network. Although this residue is conserved in the PC1 propeptide (PRO(PC1)), PC1 nonetheless activates at pH~5.5 within the dense core secretory granules. Here, we analyze the mechanism by which PRO(FUR) regulates furin activation and examine why PRO(FUR) and PRO(PC1) differ in their pH-dependent activation. Sequence analyses establish that while both PRO(FUR) and PRO(PC1) are enriched in histidines when compared with cognate catalytic domains and prokaryotic orthologs, histidine content in PRO(FUR) is ~2-fold greater than that in PRO(PC1), which may augment its pH sensitivity. Spectroscopy and molecular dynamics establish that histidine protonation significantly unfolds PRO(FUR) when compared to PRO(PC1) to enhance autoproteolysis. We further demonstrate that PRO(FUR) and PRO(PC1) are sufficient to confer organelle sensing on folding and activation of their cognate proteases. Swapping propeptides between furin and PC1 transfers pH-dependent protease activation in a propeptide-dictated manner in vitro and in cells. Since prokaryotes lack organelles and eukaryotic PCs evolved from propeptide-dependent, not propeptide-independent prokaryotic subtilases, our results suggest that histidine enrichment may have enabled propeptides to evolve to exploit pH gradients to activate within specific organelles.     

Alteration of inhibitory properties of Pleurotus ostreatus proteinase A inhibitor 1 by mutation of its C-terminal region

Pleurotus ostreatus proteinase A inhibitor 1 (POIA1), which is composed of 76 residues without disulfide bridges, is a unique inhibitor in that it exhibits sequence similarity to the propeptides of subtilisins. In order to elucidate the inhibitory mechanism of POIA1, we constructed an expression system for a synthetic POIA1 gene. The wild-type POIA1 was found to inhibit subtilisin BPN' with an inhibitor constant (K(i)) of 3.2 x 10(-9) M, but exhibited a time-dependent decrease of inhibitory activity as a consequence of degradation by the protease, showing that the wild-type POIA1 was a temporary inhibitor when subtilisin BPN' was used as a target protease. Since POIA1 shows sequence similarity to the propeptide of subtilisin, which is known to inhibit the protease via its C-terminal region, the C-terminal six residues of POIA1 were replaced with those of the propeptide of subtilisin BPN'. The mutated POIA1 inhibited subtilisin BPN' with a K(i) value of 2.8 x 10(-11) M and did not exhibit time-dependent decrease of inhibitory activity, showing about 100-fold increases in binding affinity for, and resistance to, the protease. These results clearly indicate that the C-terminal region of POIA1 plays an important role in determining the inhibitory activity toward the protease, and that the increase in binding ability to the protease is closely related to resistance to proteolytic degradation. Therefore, the inhibitory properties of POIA1 can be altered by mutation of its C-terminal region.     

Molecular cloning and expression in Escherichia coli of the extracellular endoprotease of Aeromonas caviae T-64, a pro-aminopeptidase processing enzyme(1).

PA protease (pro-aminopeptidase processing protease) activates the pro-aminopeptidases from Aeromonas caviae T-64 and Vibrio proteolytica by removal of their pro-regions. Cloning and sequencing of the PA protease gene revealed that PA protease was translated as a preproprotein consisting of four domains: a signal peptide; an N-terminal propeptide; a mature region; and a C-terminal propeptide. The deduced amino acid sequence of the PA protease precursor showed significant homology with several bacterial metalloproteases. Expression of the PA protease gene in Escherichia coli indicated that the N-terminal propeptide of the PA protease precursor is essential to obtain the active form of the protease. The N- and C-terminal propeptides of the expressed pro-PA protease were processed autocatalytically.     

Single amino acid substitution in the PC1/3 propeptide can induce significant modifications of its inhibitory profile toward its cognate enzyme

The proprotein convertase PC1/3 is synthesized as a large precursor that undergoes proteolytic processing of the signal peptide, the propeptide and ultimately the COOH-terminal tail, to generate the mature form. The propeptide is essential for protease folding, and, although cleaved by an autocatalytic process, it remains associated with the mature form acting as an auto-inhibitor of PC1/3. To further assess the role of certain residues in its interaction with its cognate enzyme, we performed an alanine scan on two PC1/3 propeptide potential cleavable sites ((50)RRSRR(54) and (61)KR(62)) and an acidic region (65)DDD(67) conserved among species. Upon incubation with PC1/3, the ensuing peptides exhibit equal inhibitory potency, lower potency, or higher potency than the wild-type propeptide. The K(i) values calculated varied between 0.15 and 16.5 nm. All but one mutant exhibited a tight binding behavior. To examine the specificity of mutants, we studied their reactivity toward furin, a closely related convertase. The mutation of certain residues also affects the inhibition behavior toward furin yielding propeptides exhibiting K(i) ranging from 0.2 to 24 nm. Mutant propeptides exhibited against each enzyme either different mode of inhibition, enhanced selectivity in the order of 40-fold for one enzyme, or high potency with no discrimination. Hence, we demonstrate through single amino acid substitution that it is feasible to modify the inhibitory behavior of propeptides toward convertases in such a way as to increase or decrease their potency, modify their inhibitory mechanisms, as well as increase their selectivity.     

Intramolecular chaperone: the role of the pro-peptide in protein folding.

Subtilisin, an alkaline serine protease, is produced in the bacterium as pre-pro-subtilisin; the pre-peptide of 29 amino acid residues is the signal peptide essential for the secretion of prosubtilisin from the cytoplasm into the culture medium. On the other hand, the pro-peptide of 77 residues covalently linked to the amino terminal end of the subtilisin intramolecularly guides the folding of subtilisin into the active enzyme. Importantly, the pro-peptide is not required for the enzymatic activity and is removed intramolecularly by autoprocessing upon the completion of the protein folding. In this review, I will first summarize all the data concerning the functions of the subtilisin pro-peptide. On the basis of these results, I shall discuss a new general concept, an intramolecular chaperone to explain the essential role of the pro-peptide in protein folding.     

Mutated intramolecular chaperones generate high-activity isomers of mature enzymes

The propeptide of carboxypeptidase Y precursor (proCPY) acts as an intramolecular chaperone that ensures the correct folding of the mature CPY (mCPY). Here, to further characterize the folding mechanism mediated by the propeptide, folding analysis was performed using a yeast molecular display system. CPYs with mutated propeptides were successfully displayed on yeast cell surface, and the mature enzymes were purified by the selective cleavage of mutated propeptides. Measurement of the activity and kinetics of the displayed CPYs indicated that the propeptide mutation altered the catalytic efficiency of mCPY. Although the mature region of the wild-type and mutant CPYs had identical amino acid sequences, the mCPYs from the mutant proCPYs had higher catalytic efficiency than the wild-type. These results indicate that proteins with identical amino acid sequence can fold into isomeric proteins with conformational microchanges through mutated intramolecular chaperones.     

The role of tryptophan residues in the autoprocessing of prosubtilisin E

Subtilisin E, a serine protease from Bacillus subtilis, requires an N-terminal propeptide for its correct folding. The propeptide is autocleaved and digested by the subtilisin domain upon proper folding. Here we investigated the individual roles of the three Trp residues within the subtilisin domain (Trp106, Trp113 and Trp241) on propeptide processing, enzymatic activity and stability of subtilisin. When the propeptide processing was examined by SDS-PAGE after refolding by rapid dilution, the mutation at either position Trp106 or Trp113 was found to significantly delay the propeptide processing, while the mutation at Trp241 had no effect. Far-UV circular dichroism (CD) spectra of the mutants revealed that the mutations at the three positions did not affect appreciably the alpha-helix content of subtilisin. Secondary structure thermal unfolding monitored by CD spectroscopy revealed that none of the tryptophan residues had any significant effect on the stability of mature subtilisin. The enzymatic activity measurements showed that only Trp106 plays a major role in the enzymatic activity of subtilisin E. These results demonstrate that both Trp106 and Trp113 play a specific role in propeptide processing and enzymatic activity, while Trp241 plays no considerable role on any of these activities.     

cDNA cloning of two novel T-superfamily conotoxins from Conus leopardus

The full-length cDNAs of two novel T-superfamily conotoxins,Lp5.1 and Lp5.2,were clonedfrom a vermivorous cone snail Conus leopardus using 3'/5'-rapid amplification of cDNA ends.The cDNA ofLp5.1 encodes a precursor of 65 residues,including a 22-residue signal peptide,a 28-residue propeptide anda 15-residue mature peptide.Lp5.1 is processed at the common signal site -X-Arg- immediately before themature peptide sequences.In the case of Lp5.2,the precursor includes a 25-residue signal peptide anda 43-residue sequence comprising the propeptide and mature peptide,which is probably cleaved to yield a29-residue propeptide and a 14-residue mature toxin.Although these two conotoxins share a similar signalsequence and a conserved disulfide pattern with the known T-superfamily,the pro-region and mature peptidesare of low identity,especially Lp5.2 with an identity as low as 10.7% compared with the reference Mr5.1a.The elucidated cDNAs of these two toxins will facilitate a better understanding of the species distribution,the sequence diversity of T-superfamily conotoxins,the special gene structure and the evolution of thesepeptides.     

Folding pathway mediated by an intramolecular chaperone. The inhibitory and chaperone functions of the subtilisin propeptide are not obligatorily linked

The subtilisin propeptide functions as an intramolecular chaperone (IMC) that facilitates correct folding of the catalytic domain while acting like a competitive inhibitor of proteolytic activity. Upon completion of folding, subtilisin initiates IMC degradation to complete precursor maturation. Existing data suggest that the chaperone and inhibitory functions of the subtilisin IMC domain are interdependent during folding. Based on x-ray structure of the IMC-subtilisin complex, we introduce a point mutation (E112A) to disrupt three hydrogen bonds that stabilize the interface between the protease and its IMC domain. This mutation within subtilisin does not alter the folding kinetics but dramatically slows down autoprocessing of the IMC domain. Inhibition of E112A-subtilisin activity by the IMC added in trans is 35-fold weaker than wild-type subtilisin. Although the IMC domain displays substantial loss of inhibitory function, its ability to chaperone E112A-subtilisin folding remains intact. Our results show that (i) the chaperone activity of the IMC domain is not obligatorily linked with its ability to bind with and inhibit active subtilisin; (ii) degradation and not autoprocessing of the IMC domain is the rate-limiting step in precursor maturation; and (iii) the Glu(112) residue within the IMC-subtilisin interface is not crucial for initiating folding but is important in maintaining the IMC structure capable of binding subtilisin.     

Solution structure of the pro-hormone convertase 1 pro-domain from Mus musculus

The solution structure of the mouse pro-hormone convertase (PC) 1 pro-domain was determined using heteronuclear NMR spectroscopy and is the first structure to be obtained for any of the domains in the convertase family. The ensemble of NMR-derived structures shows a well-ordered core consisting of a four-stranded antiparallel beta-sheet with two alpha-helices packed against one side of this sheet. Sequence homology suggests that the other eukaryotic PC pro-domains will have the same overall fold and most of the residues forming the hydrophobic core of PC1 are highly conserved within the PC family. However, some of the core residues are predicted by homology to be replaced by polar amino acid residues in other PC pro-domains and this may help to explain their marginal stability. Interestingly, the folding topology observed here is also seen for the pro-domain of bacterial subtilisin despite little or no sequence homology. Both the prokaryotic and eukaryotic structures have hydrophobic residues clustered on the solvent-accessible surface of their beta-sheets although the individual residue types differ. In the bacterial case this region is buried at the binding interface with the catalytic domain and, in the eukaryotic PC family, these surface residues are conserved. We therefore propose that the hydrophobic patch in the PC1 pro-domain is involved in the binding interface with its cognate catalytic domain in a similar manner to that seen for the bacterial system. The PC1 pro-domain structure also reveals potential mechanisms for the acid-induced dissociation of the complex between pro- and catalytic domains.     

Structure-based mutagenesis of SigE verifies the importance of hydrophobic and electrostatic residues in type III chaperone function

Despite sharing little sequence identity, most type III chaperones display a similar homodimeric structure characterized by negative charges distributed broadly over their entire surface, interspersed with hydrophobic patches. Here we have used SigE from Salmonella as a model for class IA type III chaperones to investigate the role of these surface-exposed residues in chaperone function. SigE is essential for the stability, secretion and translocation of its cognate effector, SopB (SigD). We analysed the effect of mutating nine conserved hydrophobic and electronegative surface-exposed amino acids of SigE on SopB binding, stability, secretion and translocation. Six of these mutations affected some aspect of SigE function (Leu14, Asp20, Leu22, Leu23, Ile25 and Asp51) and three were without effect (Leu54, Glu92 and Glu99). Our results highlight that both hydrophobic and electronegative surfaces are required for the function of SigE and provide an important basis for the prediction of side-chain requirements for other chaperone-effector pairs.