Hydrogen bonds are a primary driving force for de novo protein folding.

The protein-folding mechanism remains a major puzzle in life science. Purified soluble activation-induced cytidine deaminase (AID) is one of the most difficult proteins to obtain. Starting from inclusion bodies containing a C-terminally truncated version of AID (residues 1-153; AID153), an optimized in vitro folding procedure was derived to obtain large amounts of AID153, which led to crystals with good quality and to final structural determination. Interestingly, it was found that the final refolding yield of the protein is proline residue-dependent. The difference in the distribution of cis and trans configurations of proline residues in the protein after complete denaturation is a major determining factor of the final yield. A point mutation of one of four proline residues to an asparagine led to a near-doubling of the yield of refolded protein after complete denaturation. It was concluded that the driving force behind protein folding could not overcome the cis-to-trans proline isomerization, or vice versa, during the protein-folding process. Furthermore, it was found that successful refolding of proteins optimally occurs at high pH values, which may mimic protein folding in vivo. It was found that high pH values could induce the polarization of peptide bonds, which may trigger the formation of protein secondary structures through hydrogen bonds. It is proposed that a hydrophobic environment coupled with negative charges is essential for protein folding. Combined with our earlier discoveries on protein-unfolding mechanisms, it is proposed that hydrogen bonds are a primary driving force for de novo protein folding.

Introduction

The capacity for the immune system to defend against the countless environmental pathogens results from the immense diversification (over 1015 types) of high-affinity immuno­globulins. The first mechanism which partakes in the generation of this diversification is the n class="Chemical">process of V(D)J recombination, which involves the antigen-independent generation of an enormous population of B cells consisting of individual cells expressing B-cell receptors (BCRs) with unique antigen-binding specificities (Cobb et al., 2006 ▸; Harwood & Batista, 2008 ▸). In the presence of a foreign antigen, some fraction of this B-cell population that is capable of binding to the antigen will become activated and thus proliferate and differentiate, and undergo processes that (i) further enhance the binding affinity between the immunoglobulin of the activated B cell and the antigen, which is known as somatic hypermutation (SHM), and (ii) change the class of immuno­globulin to trigger an immune response that is best suited to counter the particular antigen, which is known as class-switch recombination (CSR) (Di Noia & Neuberger, 2007 ▸; Chaudhuri et al., 2007 ▸). In 2000, the 24 kDa protein activation-induced cytidine deaminase (AID) was identified as a master regulator responsible for SHM and CSR (Muramatsu et al., 2000 ▸; Revy et al., 2000 ▸). AID is proposed to function by deaminating cytidine residues on single-stranded DNA (ssDNA), thus converting them to uridines. The resultant base-pair mismatch coopts the activities of normal cellular mismatch repair (MMR) or base-excision repair (BER) to convert the mismatch to mutational and/or double-strand break (DSB) outcomes (Di Noia & Neuberger, 2007 ▸). Ultimately, the overall activity of both SHM and CSR mediated by AID leads to the final affinity maturation and effector-function modification of immunoglobulin. Recent studies have revealed that various aberrant AID activities can lead to an autosomal recessive form of hyper-IgM syndrome, chronic lymphocytic leukemia (CLL) and follicular lymphoma (FL) (Revy et al., 2000 ▸; Kasar et al., 2015 ▸; Scherer et al., 2016 ▸).

One of the major limitations in AID research is that a method for the purification of large quantities of recombinant wild-type n class="Gene">AID is absent. Consequently, in vitro assays that require more than trace amounts of AID have yet to be performed. Furthermore, owing to this conundrum, a high-resolution structure of wild-type AID has yet to be solved. Notably, AID is one of 11 members of the apolipoprotein B mRNA-editing catalytic polypeptide-like (APOBEC) protein family (Salter et al., 2016 ▸). The members of this protein family share a conserved zinc-dependent deaminase sequence motif, yet each member performs very distinct roles owing to variations in the length, composition and spatial location of conserved secondary-structural features. These distinguishing features among the APOBEC family members were elucidated through various structural studies that highlighted subtle and/or flagrant differences between family members (Salter et al., 2016 ▸; King et al., 2015 ▸, Prochnow et al., 2007 ▸; Holden et al., 2008 ▸). Although the structures of homologs, orthologs and a highly mutated version of AID exist, and provide valuable insight into corroborating the deamination mechanism of AID, a high-resolution structure of wild-type AID, which would provide valuable information that distinguishes AID from the rest of the APOBEC family members, has yet to be determined. Here, we report a twinned crystal structure of truncated wild-type AID153 at 2.0 Å resolution. High concentrations of the protein were obtained by solubilizing the inclusion bodies and performing an in vitro gradational refolding process. Given the successful outcome of refolding and crystallization of AID153, the protein was an ideal model system to investigate another major mystery in protein science: the effects of proline on protein folding.

The effects of proline isomerization in the unfoln class="Gene">ding and refolding of proteins has been an open area of investigation since 1975 (Brandts et al., 1975 ▸). Although the exact role of proline isomerization in this context has been controversial, the general consensus implicates proline isomerization as having an impact in the kinetics of protein unfolding and refolding (Brandts et al., 1977 ▸). Specifically, mutating a particular proline residue in a given protein appears to significantly influence, either positively or negatively, the rate at which the protein converts from an unfolded state to a folded state (Roderer et al., 2015 ▸; Osváth & Gruebele, 2003 ▸). We hypothesized that prolines in the incorrect configuration are trapped in non-native, yet thermodynamically favorable, conformations/aggregates and are unable to adopt the native conformation. From our findings, we propose that the dualistic nature of cis–trans isomerization of proline residues restricts the yield of properly folded protein from the total amount of denatured protein to be inversely proportional to two to the power of the number of prolines in the sequence (∼1/2, where n is the number of prolines). In this regard, we accompanied our novel refolding protocol with an investigation into the effects of proline isomerization in the refolding of proteins. The structure of AID153 reveals the locations of four prolines, one of which is located on a flexible loop distal from the secondary and tertiary structures. This proline, Pro72, was chosen as the site for a point mutation to a neutrally charged asparagine (P72N; mAID153). Parallel experiments were conducted utilizing AID153 and mAID153 to reveal a finding that reinforces the notion that prolines play a crucial role in protein folding, but challenges the widely believed notion that proline isomerization can be attributed to the slow phase in protein folding. Given how fruitful the AID153 model system has been in our investigations into proline, we proceeded to continue our exploration into one of the greatest mysteries of contemporary science: the general mechanism of protein folding.

How proteins fold has remained a topic of intense research efforts for more than half a century. Indeed, tn class="Chemical">his topic was deemed to be one of the 125 most compelling questions faced by scientists (Kennedy, 2005 ▸). Despite reports detailing several significant milestones during the last few decades, how proteins transition from a completely unfolded state to their native structure is still not well understood. In the mid-1960s, a group of scientists produced the first case of a synthetic active protein: bovine insulin (Tsou, 1995 ▸; Niu et al., 1964 ▸; Du et al., 1961 ▸; Wang et al., 1965 ▸). Subsequent studies subjected various proteins, including ribonuclease A (RNase A), to refolding experiments to show that primary protein sequences determine tertiary protein structures (Anfinsen, 1973 ▸; Anfinsen & Haber, 1961 ▸; Haber & Anfinsen, 1961 ▸, 1962 ▸). Others have speculated that certain aspects of the RNase A secondary structure may have persisted under the denaturing conditions used in these initial experiments (8 M urea for 4.5 h). More recent research revealed that proteins subjected to similar denaturing conditions were mostly denatured, but not completely unfolded; the denatured proteins were structurally heterogeneous, yet retained some native-like structures (Chang, 2009 ▸). Moreover, the degree of conformational heterogeneity among the denatured proteins significantly impacted on how protein folding occurred (Chang, 2009 ▸). Efforts to synthesize active RNase A (Gutte & Merrifield, 1971 ▸; Hirschmann et al., 1969 ▸) and insulin have reinforced the theory that the primary protein sequence does completely determine the final tertiary structure. Insulin, for example, is composed of two small peptides: a 21-residue subunit A and a 30-residue subunit B. Each subunit contains a single disulfide bridge, and the two subunits are held together by a third inter-subunit sulfur–sulfur bond (Tsou, 1995 ▸; Niu et al., 1964 ▸; Du et al., 1961 ▸; Wang et al., 1965 ▸). Despite the protein being small, de novo folding of insulin has been proven to be complicated, yet achievable. Since these initial experiments, numerous small proteins have been synthesized and folded into their native forms in vitro. For instance, smaller peptides have been subjected to stepwise covalent ligation to construct larger proteins, such as human immunodeficiency virus (HIV) protease (Muir & Kent, 1993 ▸; Torbeev & Kent, 2007 ▸; Kent, 2009 ▸) and the membrane potassium channel KcsA (Valiyaveetil et al., 2002 ▸). These successful examples, however, were all relatively small targets (<130 residues). Of note, the folding process for each individual protein was different, and no common themes have emerged. Success with membrane proteins is particularly rare (Booth & Curnow, 2009 ▸; Miller et al., 2009 ▸). Moreover, the recovery rate of the starting material is fairly low; for example, only approximately 1% of synthesized insulin peptides were recovered as completely folded protein (Tsou, 1995 ▸; Niu et al., 1964 ▸; Du et al., 1961 ▸; Wang et al., 1965 ▸). Additionally, recent computer-modeling techniques that have attempted to predict protein folding have not uncovered any general folding principles (Portman, 2010 ▸; Dill et al., 2008 ▸; Das & Baker, 2008 ▸). Over the past two decades, we have carried out thousands of protein-folding and unfolding experiments to explore the underlying mechanisms. In a previous study, we revealed that more than 100 urea molecules bind to protein only through hydrogen bonds at atomic-level resolutions. Combined with other biochemical and biophysical data, we concluded that protein denaturation by urea is caused by the disruption of protein main-chain hydrogen bonds (Wang et al., 2014 ▸). Encouraged by this exciting discovery, we questioned whether de novo protein folding shares a similar trajectory. To our surprise, besides the critical dependence of protein folding on the number of proline residues, we found that proteins folded with greater efficacy at very high pH values (11.5–12.5). Further experiments revealed that peptide bonds are polarized at high pH values, which may in fact mimic the conditions of protein folding in vivo. Based on these novel discoveries, we concluded that hydrogen bonds are a primary driving force in de novo protein folding. In this regard, our study presents direct experimental observations that support a distinct theoretical protein-folding model.

Materials and methods

Protein expression and purification

The DNA corresponn class="Gene">ding to the genes for wild-type (AID153) and P72N mutant (mAID153) activation-induced cytidine deaminase (AID) was cloned into a pET-28a vector containing an N-terminal His tag. AID153 and mAID153 were expressed in Escherichia coli BL21(DE3) cells. The cell cultures were grown to an A 600 of about 1.0 and were induced with a final concentration of 1.0 mM isopropyl β-d-1-thio­galactopyranoside for 4 h at 37°C. The cells were resuspended in nickel-binding buffer (50 mM Tris–HCl pH 8.0, 1 M NaCl, 1 mM PMSF) and lysed using a sonicator (Fisher Scientific Sonic Dismembrator Model 500) at 35% power, 10 s on, 5 s off for 20 min. The lysate was centrifuged at 16 000 rev min−1 and 4°C for 30 min. The supernatant was discarded and the pellet was resuspended in 9 M urea. Upon homogenization, the inclusion-body solubilized lysate was pre-chilled on ice and sonicated at 100% for 2 min. The solution was loaded onto 10 ml Ni–NTA resin (GE Healthcare), washed with 9 M urea and eluted with buffer consisting of 9 M urea, 1 M imidazole. The eluted product was placed in a 6000–8000 molecular-weight cutoff (MWCO) dialysis membrane (Spectrum Laboratories Inc.) and submerged in 1 l refolding buffer A (50 mM Tris–HCl pH 8.0, 1 M NaCl, 4 M urea, 15 mM β-mercaptoethanol, 1 mM PMSF) at 4°C for 12–16 h. The buffer was replaced with 1 l refolding buffer B (50 mM Tris–HCl pH 8.0, 1 M NaCl, 3 M urea, 15 mM β-mercaptoethanol, 1 mM PMSF) and incubated at 4°C for 8–12 h. The buffer was replaced with 1 l refolding buffer C (50 mM Tris–HCl pH 8.0, 1 M NaCl, 2 M urea, 15 mM β-mercaptoethanol, 1 mM PMSF) and incubated at 4°C for 12–16 h. The contents of the dialysis membrane were loaded onto 5 ml Ni–NTA resin, washed with nickel-binding buffer and eluted with nickel-binding buffer containing 500 mM imidazole. The eluted product was concentrated and purified on a Superdex 200 10/300 GL column (GE Healthcare) previously equilibrated with nickel-binding buffer containing 15 mM β-mercaptoethanol.

Protein crystallization and data collection

Purified AID153 was concentrated to 20 mg ml−1. The crystals were grown at 4°C by sitting-drop vapor diffusion against a reservoir consisting of 4 M n class="Chemical">potassium formate, 0.1 M bis-tris propane pH 9.0, 2%(w/v) PEG monomethyl ether 2000. The crystals were briefly soaked in the crystallization solution supplemented with 20% glycerol and flash-cooled in liquid nitrogen. X-ray diffraction data were collected at the Advanced Photon Source (APS) at Argonne National Laboratory. The data were indexed, integrated and scaled using the HKL-2000 program suite. Five separate data sets were merged and used for structure determination. Purified DapA and refolded DapA were crystallized via sitting-drop vapor diffusion against a reservoir containing 2 M K2HPO4 pH 9.8.

Structure determination and refinement

The AID153 structures were determined by molecular replacement using phenix.automr with the structure of a variant human AID (PDB entry 5jj4; Pham et al., 2016 ▸) as a template. Iterative rounds of model rebuilding and simulated-annealing torsion-angle refinement were performed using Coot and REFMAC5. The data-collection and structure-refinement statistics are shown in Table 1 ▸. Atomic coordinates and structure factors have been deposited in the Protein Data Bank under accession code 5w09.

Table 1

Summary of diffraction data and structure-refinement statistics

Values in parentheses are for the highest resolution shell.

Data collection
Wavelength (Å)	0.9795
Space group	P21
Resolution (Å)	53.28–2.00 (2.051–1.999)
Unit-cell parameters
a (Å)	61.458
b (Å)	28.359
c (Å)	61.512
Observed reflections	104857
Unique reflections [I/σ(I) > 0]	15662
Average multiplicity	6.7 (2.3)
Average I/σ(I)	23.6 (6.0)
Completeness (%)	99.91 (98.75)
R merge † (%)	10.4 (42.7)
Refinement
Resolution (Å)	53.28–2.00
Reflections [F o ≥ 0σ(F o)]
Working set/test set	12225/582
R work/R free ‡ (%)	26.7/29.1
No. of protein atoms	1.453
No. of water atoms	151
Average B factors (Å2)
All atoms	31.52
Protein	33.21
Water	19.70
Root-mean-square deviations
Bond lengths (A)	0.016
Bond angles (°)	2.028
Ramachandran plot (%)
Most favored regions	79.0
Allowed regions	19.0
Disallowed regions	2.0
Twin operators	(l, k, −h − l) and (−h − l, k, h)

R merge = .

R = .

Refolding experiments followed by Bradford assay

Following the isolation of 9 M urea-solubilized n class="Chemical">AID153 and mAID153 and prior to refolding, the samples were loaded into a glass flask and boiled for 15 min. The boiled samples were cooled to room temperature, the concentration of the protein was measured, and the refolding and purification method outlined above was followed. From the Superdex 200 10/300 GL column, fractions collected corresponding to the soluble form of AID153 used for crystallization were compared with fractions collected corresponding to the entirety of the non­soluble form of AID153. The protein concentrations of these two fractions was measured via the Bradford assay and a ratio was determined. This ratio was used to extrapolate the concentration of soluble AID153 that was present in the Ni–NTA-eluted product prior to injection into the Superdex 200 10/300 GL column. This value was used to assess the difference in concentration between AID153 and mAID153.

Refolding protein at various pH values

Separately, purified ribulose bisphosphate carboxylase large chain (RuBisCo), dihydrodipicolinate synthase (DapA), 5,10-methylenetetrahydrofolate reductase (METF) and 5,10-methylenetetrahydrofolate reductase (METK) were subjected to unfoln class="Gene">ding (10 M urea, 50 mM Tris–HCl pH 8.0, 15 mM β-mercaptoethanol) for 1 h at room temperature. The unfolded protein was concentrated to a final volume of 1 ml (1 mg ml−1). The unfolded protein was titrated into 100 ml buffer at varying pH values. The buffer recipes for a pH range of 8.5–13 are listed in Supplementary Table S1. The refolded proteins were concentrated and subjected to a Superdex 200 10/300 GL column (GE Healthcare) for comparison with the native protein.

Fast protein refolding

Following the inclusion-body purification steps and prior to refolding, as outlined above, the n class="Chemical">Ni–NTA-eluted products containing AID153 or mAID153 solubilized in 9 M urea were boiled to a completely denatured state and cooled to 22°C; NaCl was added to a final concentration of 1 M and the pH was adjusted to a value of 11.5. This solution was placed in a 6000–8000 MWCO dialysis membrane (Spectrum Laboratories Inc.) and submerged in 1 l refolding buffer D (200 mM Tris–HCl pH 8.0, 1 M NaCl, 15 mM β-mercaptoethanol, 1 mM PMSF) at 22°C for 4 h. The contents of the dialysis membrane were loaded onto 5 ml Ni–NTA resin, washed with nickel-binding buffer and eluted with nickel-binding buffer containing 500 mM imidazole. The concentration of the soluble fraction of well folded AID153 or mAID153 in the total elution was evaluated following the procedure outlined above.

Small-angle X-ray scattering (SAXS)

Native n class="Chemical">protein samples in buffer at pH 8.5 and refolded samples in buffers at various pH values were adjusted to concentrations of 1.0, 2.0, 4.0 and 5.0 mg ml−1 for SAXS experiments. SAXS data were collected on ALS beamline 12.3.1 at Lawrence Berkeley National Laboratory, Berkeley, California, USA (Hura et al., 2009 ▸). Incident X-rays were tuned to a wavelength of 1.0 Å at a sample-to-detector distance of 1.5 m, resulting in scattering vectors (q) ranging from 0.001 to 0.32 Å−1. The scattering vector is defined as q = 4πsinθ/λ, where 2θ is the scattering angle. All experiments were performed at 20°C, and the data were processed as described previously (Hura et al., 2009 ▸). Briefly, the data were acquired at short and long time exposures (0.5 and 5 s, respectively), and were then scaled and merged for calculations using the entire scattering profile. FoXS (Schneidman-Duhovny et al., 2010 ▸) was used to compute the theoretical scattering profiles and accurately fit the experimental data.

Ultraviolet resonance Raman (UVRR)

All UVRR spectra were collected on a custom-built UVRR spectrometer, which was designed based on previously published studies (Balakrishnan et al., 2008 ▸; Lednev et al., 2005 ▸). A tunable, frequency-quadrupled, titanium–sapphire laser (Coherent, Santa Clara, California, USA), pumped by the second harmonic of an Nd:YLF laser, was used as the excitation source. The sample was circulated using a gear pump (model 75211-10; Cole Parmer, Vernon Hills, Illinois, USA) through a temperature-controlled sample chamber and water-jacketed reservoir maintained at ∼7°C; this apparatus was designed in-house and was manufactured by Mid Rivers Glassblowing, Saint Charles, Missouri, USA. A thin film of the sample was created by passing the solution through a 19-gauge needle and between two thin Nitinol wires (0.005 mm in diameter; Small Parts, Miramar, Florida, USA). The sample film was directly irradiated by the incident excitation beam. A continuous stream of nitrogen gas was used to eliminate ambient oxygen from the sample chamber. The excitation wavelength was 197 nm. Raman scattering was collected over 135° of backscattering geometry and dispersed using a 1.25 m spectrometer (Horiba Jobin Yvon, Edison, New Jersey, USA) equipped with a 3600 groove mm−1 grating. The spectrometer was equipped with a back-illuminated, phosphor-coated, liquid-nitrogen-cooled Symphony CCD camera (Horiba Jobin Yvon, Edison, New Jersey, USA) with a chip size of 2048 × 512. The laser power at the sample chamber was kept below 0.5 mW to avoid sample degradation (Wu et al., 2003 ▸). Each spectrum was collected over 150 min, which resulted in 60 individual spectra. The spectra were collected and exported in CSV format using the Synergy software (Horiba Jobin Yvon, Edison, New Jersey, USA). The spectrum of cyclohexane and the peak positions reported in Ferraro & Nakamoto (1994 ▸) were used to calibrate the UVRR spectra. The UVRR spectra were analyzed using MATLAB v.7.1 (Mathworks, Natick, Massachusetts, USA). The spectra were averaged and cosmic rays were removed using a program that was written in-house. Nonlinear least squares was then used to fit the spectra to a series of mixed Gaussian and Lorentzian bands, a process that was performed using a program that was written in-house for the MATLAB environment to approximate results obtained with the computationally intensive Voigt line shape.

Results and discussion

Overall crystal structure of AID153

Heterologous protein expression of a pET-28a vector containing a full-length n class="Gene">AID insert with an N-terminal His6 tag yielded protein that was homogenously truncated at the Glu153 position (Supplementary Fig. S1) exclusively in the inclusion bodies. The protein was purified utilizing a novel gradational refolding technique (see §2) and crystallized in space group P21. Phases were determined by molecular replacement using the structure of the human AID variant AIDv(Δ15) (Pham et al., 2017 ▸) as a search model. The crystal was shown to exhibit pseudo-merohedral twinning. High-resolution data were collected at APS to 2.0 Å resolution. Five separate data sets were merged and the structure was subjected to refinement in REFMAC5 using two twin operators simultaneously: (l, k, −h − l) and (−h − l, k, h). Refinement statistics are shown in Table 1 ▸.

The AID153 monomer exhibits the canonical APOBEC fold with an α–β–α supersecondary-structural element, comprised of five α-helices enveloping the inner five-stranded β-sheets, that forms the core catalytic site of a n class="Chemical">cytidine deaminase (CDA) domain (Figs. 1a and 1b ▸). The missing residues 154–198 are predicted to form the last α6 helix. A previously reported APOBEC3G dimerization model suggests the involvement of the α6 helix in the head-to-tail dimer conformation, resulting in a continuous DNA-binding groove (Lu et al., 2015 ▸). Given the curiously homogenous truncation before the α6 helix resulting in AID153, despite the induction of an expression plasmid containing full-length AID, the inability to isolate soluble full-length AID may stem from the cellular instability that results from high-order oligomerization of full-length AID utilizing the α6 helix (Fig. 1c ▸). Interestingly, AID153 shows a single peak on a gel-filtration column with the molecular weight of an AID153 dimer, indicating the possibility of alternative dimerization mechanism(s), such as head-to-head or tail-to-tail, rather than the reported head-to-tail APO3G model exclusively (Shandilya et al., 2010 ▸). The question of the cellular mechanism that leads to disruption of oligomerization, uniform truncation after the Glu153 site and inclusion-body trafficking remains to be answered.

Figure 1

(a) Ribbon representation and electrostatic potential surface of the AID153 monomer. (b) Ribbon representation of AID153 (green) overlapped with the A3G (PDB entry 4rov; Lu et al., 2015 ▸) head-to-tail dimer conformer (orange).

Structural similarity searches performed using the DALI server with n class="Chemical">AID153 as the query revealed similarity to members of the APOBEC family. The structures of AID153 and 146 aligned residues of AIDv(Δ15) (PDB entry 5jj4) superimposed with a root-mean-square deviation (r.m.s.d.) of 1.5 Å and a Z-score of 19.0. The structures of AID153 and over 145 aligned residues of numerous APOBEC3G structures (PDB entries 3v4j, 3v4k, 3ir2, 3e1u, 3iqs, 4rov and 4row) superimposed with an r.m.s.d. in the range 1.9–2.1 Å and a Z-score in the range 17.0–18.0. High structural similarity with an r.m.s.d. of <2.5 Å and a Z-score of >15.0 was also revealed between AID153 and APO3B, APO3A, APO3F and APO3C. The structure of AID153 appears to exhibit similarities, in terms of the overall fold, to previously reported structures of APOBEC family members.

Differences between crystal structures

The previously reported crystal structure of AIDv(Δ15) contains numerous mutations at the n class="Chemical">N-terminus in the sequences responsible for forming the α1 helix and β1 sheet. Upon comparison with the structure of AID153, the impact of these numerous mutations is revealed. The most significant difference in structure compared with AID153, which contains all wild-type residues up to the Glu153 truncation site, is the presence of a continuous β2 sheet in AIDv(Δ15) and of a discontinuous β2/β2′ sheet containing a short bulging loop (termed the β2-bulge) in AID153 (Fig. 2 ▸ a). The resulting β2-bulge-β2′ topology is a feature that is present in APO3A, the APO3G C-terminal CDA domain and the APO3B C-terminal CDA domain, whereas the feature is not present in the Z2-type structures of APO3C, the APO3F C-terminal CDA domain, the APO3G N-terminal CDA domain or in APO2 (Salter et al., 2016 ▸). Although the exact function of the bulge is unclear, it is suggested that the β2 strand interacts with the adjacent CDA domain in a bulge-dependent manner, or may possibly play a role in the quaternary organization of single-domain APOBEC family member proteins such as APO3A. This bulge is an intrinsic feature among some APOBEC family members, and the structure of AID153 reveals the novel finding that may categorize AID as a member of the β2-bulge-containing APOBEC family. Furthermore, in the instance where the bulge indeed plays a role in quaternary organization and/or higher order oligomerization as proposed, this may explain why Pham and coworkers were able to obtain soluble AIDv(Δ15), which lacks the presence of the β2-bulge.

Figure 2

(a) Structural alignment of the β2 strands that exhibit a β2-bulge in AID153, the A3G C-terminus (PDB entry 3ir2; Shandilya et al., 2010 ▸), the A3B C-terminus (PDB entry 5cqi; Shi et al., 2015 ▸) and A3A (PDB entry 2m65; Byeon et al., 2013 ▸) or its absence in A2 (PDB entry 2rpz; RIKEN Structural Genomics/Proteomics Initiative, unpublished work), A3C (PDB entry 3vow; Kitamura et al., 2012 ▸), the A3G N-terminus (PDB 2mzz; Kouno et al., 2015 ▸), A3F (PDB entry 4j4j; Siu et al., 2013 ▸) and AIDv(Δ15) (PDB entry 5jj4; Pham et al., 2016 ▸). (b) Alignment of the CDA domains, containing the key residues His56, Cys87, Cys90 and Glu58, of AID153 (green) and AIDv(Δ15) (beige). The magenta sphere represents a zinc ion and the red sphere represents a water molecule.

In AID, the CDA domain consists of three zinc-coordinating residues (n class="Chemical">His56, Cys87 and Cys90) and a proton-shuttle residue (Glu58). The AID153 structure presented in our study was solved in the absence of zinc. Interestingly, when compared with the CDA motif of the zinc-bound AIDv(Δ15), the orientation of Glu58 appears significantly different. In the presence of zinc, Glu58 is oriented towards the active site, as well as interacting with a water molecule coordinating to the zinc ion. In the absence of zinc, Glu58 is oriented away from the active site and the water molecule is absent. A minor, yet noticeable, difference can also be seen for the His56 residue, where the imidazole ring appears to be rotated by ∼60° in the zinc-free AID153 compared with the His56 bound to zinc in the AIDv(Δ15) structure (Fig. 2 ▸ b). Shaban and coworkers reported the structure of zinc-free APOBEC3F and revealed the formation of a disulfide bond between the cysteines that would otherwise coordinate zinc in their reduced form (Shaban et al., 2016 ▸). AID153 exhibited no such disulfide-bond formation. Despite the difference in the active-site residue conformation, our results demonstrate that maintenance of the overall structural integrity of AID153 does not require zinc. Furthermore, the coherent orientation of Glu58 away from the active site in the absence of zinc may suggest that metal coordination is a strategy for regulating the activity of AID.

The number of proline residues determine the final refolding yield

As described below, we have developed a novel refolding n class="Chemical">procedure for AID153 that could be applied to other proteins. Following the refolding and Ni–NTA purification process of AID153, 16.6 ± 1.70% of the total inclusion-body solubilized and isolated AID153 was in the native form, which shows a single peak on a gel-filtration column (Supplementary Fig. S2a). This peak was used for crystallization and yielded the crystals used for the final structural determination. After collecting the improperly folded and aggregated AID153 portion contained in the Ni–NTA flowthrough, we resolubilized the content in 9 M urea and conducted a second run of refolding and purification, resulting in a final yield of 5.30 ± 2.18%. The unfolded AID153 was subjected to a third run, resulting in the recovery of only 3.33 ± 2.6% of native AID153 (Fig. 3 ▸ b). To account for the decrease in recovery yield in each subsequent refolding and purification trial, we hypothesized that proline residues are the major determinants of protein refolding. The rationale for this hypothesis was inspired by the numerous protein-folding experiments that we have performed in past decades, in which we observed an interesting phenomenon. When purified proteins were subjected to denaturation for a short period of time (∼1 h, 10 M urea, room temperature) we were able to recover over 90% of well folded protein when high-pH refolding procedures were applied, as expounded upon below. However, when the purified proteins were subjected to denaturation for a prolonged period of time (>16 h, 10 M urea, room temperature) virtually no refolded protein could be recovered. Although we hypothe­sized that proline isomerization was the mechanism behind this disparity in the recovery yield, the protein candidates that we experimented with (RuBisCo, DapA, METF, METK etc.) contained too many essential proline residues to meaningfully test our hypothesis. Fortuitously, AID153 contains only four proline residues, which made this protein an ideal model to test our long-anticipated hypothesis.

Figure 3

(a) Location of prolines in AID153. Pro72 was chosen as a site for point mutation to investigate the effects of proline in protein refolding. (b) 36–44 h protein-refolding procedure: the percentage of refolded protein concentration recovered relative to the 9 M urea-solubilized unfolded protein concentration. Subsequent runs of refolding and purifying AID153 from the Ni–NTA flowthrough results in decreased recovery. Upon complete denaturation via boiling, mAID153, which contains a point mutation at Pro72, led to the recovery of ∼91% more refolded protein compared with AID153.

The role of proline in the n class="Chemical">process of protein refolding has been widely studied. Most results propose that the isomerization of proline residues leads to a slow refolding process in which the energy generated from correct protein folding overcomes the improper proline configuration. According to the final structure of AID153, all four proline residues are present in the trans form (Fig. 3 ▸ a). We reason that crude inclusion bodies may contain a higher percentage of the trans form of AID153 compared with the completely denatured form, since all amino acids, including proline, are translated in the trans form from ribosomes. Otherwise, an elegant report showed that short peptides with a proline residue coupled to any other residue, on average, generate almost equal amounts of the cis and trans forms of proline in the peptides (Zoldák et al., 2009 ▸). In the context of our experiment above, when the Ni–NTA flowthrough is resolubilized in 9 M urea, unfolded protein molecules with the correct proline configurations are provided with another opportunity to fold properly, as well as allowing some minute population of unfolded protein molecules with incorrect proline configurations to adopt the correct proline configurations and proceed to fold properly. Our data suggest that each subsequent trial of resolubilizing the flowthrough reduces the relative amount of unfolded proteins with the correct proline configurations, as well as demonstrating that unfolded proteins with incorrect proline configurations yield little to no well folded proteins, owing to statistical improbability given that AID153 contains four prolines.

A point mutation of a proline residue to an asparagine led to a doubled yield of completely denatured AID153

We hypothesized that if we completely denature AID153, the final yield of refolded n class="Chemical">protein should remain a constant value. Moreover, if we assume that all four proline residues have an equal probability of cis and trans configurations, while only four trans configurations corresponding to the ‘correct’ set could yield native-form AID153, the theoretical final yield should be (1/24) × 100% = 6.25%. Our results appear to corroborate our hypothesis. AID153 dissolved in 9 M urea at pH 9.0 was boiled at 100°C for 15 min in order to ensure that no secondary structure was present and that there was an entirely random distribution of proline isomers in the AID153 solution. Starting from this completely denatured AID153, the final yield of refolded native AID153 was 3.45 ± 0.67% (Fig. 3 ▸ b). Accounting for experimental errors, our observed value of 3.45 ± 0.67% appears to be consistent with the expected theoretical value of 6.25%. Notably, the enormous discrepancy in the yield of refolding boiled versus unboiled protein suggests that the slow phase of protein folding is unlikely to be owing to proline isomerization. The energy required to overcome the threshold of proline isomerization is too large to be achieved during the refolding process since the final free energy generated from protein folding (Kyte, 2007 ▸) is at a similar energy level to that of cis and trans isomerization of one proline residue (Eyles, 2001 ▸). This notion, in the context of protein folding, becomes more apparent when fathoming the energy barrier associated with multiple prolines in the incorrect configuration. To further confirm our proline-dependent hypothesis, we introduced a point mutation of Pro72 to asparagine (mAID153). In general, Asn is a preferred residue in turn or loop regions of proteins, similar to a proline residue, although proline is relatively much more rigid. To our satisfaction, one mutation of a Pro residue to Asn led to a nearly doubled yield of mAID153. A procedure to prepare completely denatured mAID153, identical to that of AID153, resulted in a final yield of 6.58 ± 0.75% (Fig. 3 ▸ b). When compared via gel-filtration chromatography and a thermal denaturation assay (Niesen et al., 2007 ▸), the P72N mutation appears to have no distinguishable impact on mAID153 compared with AID153 (Supplementary Fig. S2). Taken to­gether, these data strongly support the conclusion that an incorrect proline configuration markedly impedes the folding of native AID153 and mAID153 from a completely unfolded state.

Optimal condition for the refolding of AID153 at regular pH values

A major bottleneck that needed to be overcome in the process of obtaining soluble n class="Chemical">AID153 was the protein-refolding process. Conventional protein-refolding strategies solubilize the inclusion body in a high concentration of a chaotropic agent, subject the blend to a chelating-affinity column and subsequently dilute or dialyze the eluate directly into a buffer containing a low concentration of a chaotropic agent or no chaotropic agent at all (Rudolph & Lilie, 1996 ▸). When variations of this method were applied in an attempt to refold AID153, the products contained noticeable precipitation and virtually no well folded protein was recovered. Our previous research revealed that the urea-driven disruption of hydrogen bonds is the main driving force in unfolding proteins (Wang et al., 2014 ▸). The novel refolding strategy proposed in this study involves a slow, gradational reduction of urea. Numerous studies have shown that the inflection point between an unfolded and folded protein typically falls in the range 4–5 M urea at a pH of ∼8 (Klotz, 1996 ▸; Rodriguez-Larrea & Bayley, 2013 ▸; Song et al., 2013 ▸). Under these conditions, the unfolded protein can participate in hydrogen bonds and ionic inter­actions as effectively as urea. These interactions can manifest differently, insofar as there is competition between inter­actions that favor secondary-structure formation versus interactions that favor unfolded aggregation and/or amyloid formation. In contrast to buffers containing a low concentration or an absence of urea, prolonged incubation (12–16 h at 4°C) of unfolded protein in 4–5 M urea permits aggregation and/or amyloid formation to be reversible and allows the protein to form more thermodynamically stable secondary structures prior to reducing the urea concentration any further. This novel refolding approach was crucial in allowing sufficient quantities of soluble natively folded AID153 to be purified and ultimately crystallized. However, as our understanding of the general protein-folding mechanism deepens, we have revealed that high pH can speed up the process drastically, as we describe below.

Protein folding under high-pH conditions

Although the slow, gradational reduction of urea in the refoln class="Gene">ding procedure described above is intended to minimize the unfolded aggregation of recombinant proteins extracted from inclusion bodies of E. coli, this lengthy in vitro refolding of AID153 does not accurately reflect in vivo protein-folding conditions. On the contrary, it is very well established that in vivo protein folding is relatively instantaneous (Kiefhaber, 1995 ▸; Torshin & Harrison, 2003 ▸). To address this temporal discrepancy between in vitro and in vivo protein folding, we sought to optimize the complete denaturation, refolding and purification assay of AID153 and mAID153 described above, with the intention of revealing insights into general protein-folding mechanisms. In our search to simulate a general in vivo protein-folding condition, we screened thousands of conditions using several protein candidates to discover that pH is a major determining factor as to whether or not an unfolded protein can be properly folded in the shortest time. Our results indicated that a pH range of 11.5–12.5 was optimal in re­covering protein. Specifically, we observed an explicit correlation between greater efficacy of protein folding and increasing pH. Among the protein candidates that we explored, this phenomenon was best demonstrated by several well characterized proteins: RuBisCo (Fig. 4 ▸ a), DapA (Supplementary Fig. S3a), METF (Supplementary Fig. S3b) and METK (Supplementary Fig. S3c). In the case of DapA, our proposed refolding procedure at high pH was efficient to the degree that we were able to obtain crystals of refolded DapA that appeared to be identical to the crystals obtained from native DapA under the same crystallization conditions (Fig. 4 ▸ b). To identify the mechanism behind the pH-dependent protein folding, we opted to use the well characterized protein DapA in a small-angle X-ray scattering (SAXS) experiment to evaluate the approximate shape of the protein in a pH-dependent manner. Consistent with our previous findings (Wang et al., 2014 ▸), DapA appears to be completely unfolded at pH 12.5–13.0. Surprisingly, at pH 11.5–12.5 DapA appears to have a three-dimensional structure similar to that of the native form, whereas at pH 9.5 DapA is structurally identical to the native form (Fig. 4 ▸ c). The presence of native secondary structure at different pH values further confirmed this observation (Supplementary Fig. S4). These results suggest that proteins could fold into native forms at high pH values. Based on these findings, we proceeded to use post-boiled AID153 and mAID153 solubilized in a pH 11.5 and 9 M urea solution to perform a 4 h direct dialysis (not stepwise) against a buffer at pH 8.0 with no urea at room temperature. To our satisfaction, under these experimental conditions the final yield of refolded native AID153 was 2.09 ± 0.32% and the final yield of refolded native mAID153 was 3.52 ± 0.19% (Fig. 4 ▸ d). The overall yields of both AID153 and mAID153 are similar to the results derived from the protracted experiments at pH ∼8.0 described above. This simplified in vitro protein-refolding procedure starting at high pH values may better reflect the in vivo protein-folding process. Interestingly, Singh and coworkers reported a similar finding, in which their refolding protocol maximized the recovery yield from inclusion-body solubilized human growth hormone (hGH) at a pH of above 8.0, with an even greater yield of soluble protein being recovered as the pH increased to 12.5 (Singh & Panda, 2005 ▸).

Figure 4

(a) Size-exclusion chromatography assay of RuBisCo refolded at various pH values. When refolded at pH 7.5, RuBisCo predominantly formed misfolded aggregates that eluted at the void volume. As the refolding pH increased to 11.5, the resultant eluate better resembled the native protein. (b) Refolded DapA can be crystallized under the same conditions as used for native DapA. This demonstrates that the refolded protein has the same properties as the native protein. (c) Kratky plots of SAXS results for DapA refolding under different pH conditions. Three-dimensional structures of DapA were observed to begin formation at pH 12.5. (d) 4 h protein refolding procedure: the percentage of refolded protein concentration recovered relative to the 9 M urea-solubilized unfolded protein concentration. Upon complete denaturation via boiling, mAID153, which contains a point mutation at Pro72, led to the recovery of ∼68% more refolded protein compared with AID153.

High pH induces main-chain polarization

To explore the underlying mechanism of protein foln class="Gene">ding under high-pH conditions, we proceeded to examine the principal unit in the protein structure: the peptide bond. Peptide bonds are known to display resonance; this process makes the double bond between the C and O atoms and the single bond between the N and H atoms longer than average, whereas the single bond between the C and N atoms is shorter than average (Milner-White, 1997 ▸). We propose that at high pH, apart from resonance or conjugation, OH− groups surrounding a completely unstructured or nascent peptide will induce a partial negative charge on the O atom and a partial positive charge on the C atom. At the same time, the OH− groups will also affect the H atom from the amide, leading to a partial negative charge on the N atom and a partial positive charge on the H atom (Fig. 5 ▸ a). The exchange rate of the amide proton is known to increase dramatically at high pH values (>10; Bai et al., 1993 ▸), while we revealed that the dissociation of protons on peptide amides occurs at a pH of ∼13 (actual; Wang et al., 2014 ▸), although the theoretical pK a value for the amide proton is close to 16.0 (Gilli et al., 2009 ▸). Overall, high pH will lead to the formation of two electric dipoles. Interestingly, these types of dipoles have been described in native protein structures, and this feature, which has been confirmed by quantum-mechanics calculations, is widely used in modeling programs (Milner-White, 1997 ▸). Furthermore, recent studies showed that the carbonyl-amide groups from the side chains of glutamines/asparagines, acetylated lysines and/or a portion of NAD+ could play critical roles in some enzymatic reactions through the formation of an imidic acid intermediate (similar to the polarized peptide-bond structure shown above) under hydrophobic and negative charged environments both in the deacetylation process by the NAD-dependent deacetylase sirtuin-2 (SIRT2; Lee et al., 2017 ▸; Wang et al., 2017 ▸) and in hydrolases (Nakamura et al., 2015 ▸).

Figure 5

(a) Resonance at the amide under high-pH conditions leads to electric dipole formation. Electric dipole formation after the attack by OH−. (b) Resonance at the amide of Ac-GGGG under different pH conditions. The wavenumber representing amide I decreases from 1661 to 1656 cm−1 as the pH increases, reflecting elongation of the carbonyl double bond. The increase in the wavenumber peak of amide III from 1306 to 1309 cm−1 may reflect a shortening of the bond between the amide C and N atoms.

We hypothesized that during the protein-foln class="Gene">ding process the electric dipoles are stabilized and enhanced by hydrogen-bond formation within the protein. If this is the case, however, then why do these atoms fail to form hydrogen bonds to water molecules, which should also stabilize and enhance the electric dipoles, as suggested previously (Myshakina et al., 2008 ▸)? We propose that the water molecules are steered away from the peptide backbone under high-pH conditions; this is similar to reversed-phase or hydrophobic interaction chromatography, in which hydrophobic surfaces appear at low or high pH levels (Dorsey & Cooper, 1994 ▸). To verify and confirm the potential electric dipoles under high-pH conditions, UV resonance Raman (UVRR) spectra were utilized. UVRR spectra can be used to detail conformational changes within protein main-chain backbones (Asher, 1988 ▸; Balakrishnan et al., 2008 ▸; Lednev et al., 2005 ▸). When proteins are excited at 190–220 nm, the stretching of individual bonds is represented by a specific peak in the spectrum. For example, primarily C=O double-bond stretching is detected at a wavenumber peak of ∼1650 cm−1 (amide I), whereas mixtures of N—H single-bond bending and C—N single-bond stretching are detected at wavenumber peaks of ∼1550 cm−1 (amide II) and ∼1300 cm−1 (amide III) (Asher, 1988 ▸; Balakrishnan et al., 2008 ▸; Lednev et al., 2005 ▸). UVRR spectra were obtained for an acetylated polyglycine peptide (Ac-GGGG) at four different pH levels: 3.0, 7.0, 10.0 and 12.0. As expected, the double bond between the C and O atoms was elongated at high pH levels, which was reflected by a decrease in the amide I wavenumber peak from 1661 to 1656 cm−1 from low- to high-pH conditions (Fig. 5 ▸ b). Although no significant changes were observed for amide II, a slight increase in the wavenumber peak representing amide III was detected, which may reflect a shortening of the C—N bond (Fig. 5 ▸ b). Because of interference from water molecules, bending of the N—H bond is difficult to identify within the spectrum. Nuclear magnetic resonance (NMR) experiments have already confirmed a rapid exchange rate of protons at high pH levels (Bai et al., 1993 ▸; Udgaonkar & Baldwin, 1988 ▸). These results demonstrate that electric dipoles are created within peptide bonds under high-pH conditions. Because the electric dipoles are enhanced by hydrogen-bond formation within nascent peptide bonds in the absence of water, we can further deduce that hydrogen bonds are a primary force that drives protein folding.

Concluding remarks

This study reports the following five novel discoveries: the structure of n class="Chemical">AID153, the role of proline isomerization in protein folding, the general protein-folding procedure at high pH, the observation of native-like structures of proteins folded at higher pH values (up to 12.0) and the phenomenon of main-chain polarization at higher pH values (up to 12.0). These discoveries are within the context of greater discussions.

Despite the fundamental role that AID plays in antibody diversification, recombinant expression of tn class="Chemical">his protein in E. coli or insect cells has been unfeasible owing to the propensity of the protein for aggregation. In our study, we report a twinned crystal structure of human AID exhibiting a homogenous truncation at the Glu153 site (AID153) at a resolution of 2.0 Å. Our structure reveals the novel finding that AID exhibits a β2-bulge, a topology that is featured in some members of the APOBEC family. In addition, our structure in the absence of zinc reveals a notably different orientation of the key catalytic residue Glu58 compared with zinc-bound AIDv(Δ15), which may be a metal-dependent regulatory mechanism to provide an additional level of complexity to prevent promiscuous mutations of nonspecific ssDNA targets. Unfortunately, our structure comes up short in addressing the true value of the long-awaited AID structure. Although all APOBEC family members share a conserved zinc-dependent deaminase motif within an α–β–α super-secondary-structural element, the variations in length, composition and spatial location of conserved secondary-structural features define the substrate specificity, quaternary structural organizations and protein–protein interactions. Owing to the truncation and twinning, which may explain the suboptimal data-collection and refinement statistics, our structure of AID153 may be no more than a placeholder until the full-length structure of AID is determined, which is expected to address the many mysteries surrounding AID from a structural standpoint. Nevertheless, given the difficulty in obtaining the native form of the AID protein in the field, the general protein-unfolding and refolding procedure derived from AID153 may be used as a universal protocol for many other proteins. Above all, given that solving a structure largely ensures the homogeneity of the protein and the reproducibility of a given procedure for obtaining the protein, the unique steps taken here in acquiring soluble AID153 provided us with a fortuitous opportunity to use this protein as a model to explore one of the most compelling questions in the field of life science: the underlying mechanism of protein folding.

Given that ribosomes translate prolines in the trans configuration, the rate-limiting n class="Chemical">process of proline isomerization in protein folding may only be applicable to prolines that are cis in the native conformation of the protein. From an evolutionary standpoint, this stands to reason given that a specialized enzyme, prolyl isomerase, exists to overcome the enormous thermodynamic penalty associated with proline isomerization. Furthermore, studies show that there are severe impacts on the refolding kinetics of proteins that contain a native cis-proline when prepared in in vitro unfolding conditions that impel proline isomerization towards establishing the thermodynamically driven 1:4 cis:trans proline equilibrium levels. In this regard, Roderer et al. (2015 ▸) reported a dramatic acceleration in the refolding kinetics by more than four orders of magnitude, compared with the wild type, when a conserved cis-proline was mutated to alanine in thioredoxin. Interestingly, in the same report the mutation of the other four trans-prolines to alanine, while retaining the single cis-proline, resulted in a 27-fold slower refolding compared with the wild type. In another study by Osváth & Gruebele (2003 ▸), yeast phosphoglycerate kinase was shown to refold more rapidly when a single cis-proline was mutated to a histidine. Notably, this study suggests proline isomerization as an ‘additional’ slow phase, with another unaccounted-for source being the other reason behind the slow phase in protein folding; an observation that was also noted by Hacke et al. (2013 ▸). Skeptics of the contribution of proline to the slow phase, such as Dr Duncan Steel, offer alternative explanations as to the source of the slow phase that result from the disruption of incorrectly formed hydrogen bonds or unfavorable van der Waals contacts in the hydrophobic core of the protein, followed by reformation of the correct contacts (Subramaniam et al., 1995 ▸). These findings are not mutually exclusive, and taken together may totally account for the slow phase in protein folding. In this regard, we found that proline residues, and most likely differences in the cis and trans configurations, are a key determinant of protein folding. An incorrect configuration of a given proline residue, which is unable to convert without the help of specific enzymes (for example prolyl isomerases) under in vitro refolding conditions, leads to an irreversible trap in protein folding. Starting from complete­ly unfolded proteins with the equilibrated probability distribution of cis- and trans-proline isomers, the final yield of properly folded protein will be close to the reciprocal of 2 (where n represents the number of prolines in the corresponding protein). Our study demonstrates this proposal using AID153 as a model. Further studies using other protein candidates containing a limited number of essential proline residues (less than five prolines, which are vital to the overall structure) is necessary in order to derive a general theory behind our proposed mechanism of the role of proline in protein folding. Interestingly, upon exposure to denaturing conditions for a prolonged period of time (>16 h), we failed to refold any native-form proteins from other protein candidates with a high number of proline residues, such as DapA, RuBisCo, METF and METK. This may be owing to the many random isoforms of proline residues among these proteins (data not shown). This could be indirect evidence to indicate the critical role of proline residues in the process of protein folding.

In our previous report, we used NMR spectroscopy to show that n class="Chemical">protons from the amide moiety of Ac-GGGG start to dissociate at pH levels above 13.0, which was reflected by large chemical shifts in the neighboring CH2 groups (Wang et al., 2014 ▸). On the other hand, a high occupancy of hydrogen on the amide was observed at pH 12.0 and lower, which was reflected by the small or nonexistent chemical shifts in the neighboring CH2 groups, although the exchange rate dramatically increased (Bai et al., 1993 ▸). Those findings led us to propose that the denaturation of proteins at extremely high pH is driven by the disruption of main-chain hydrogen bonds, similar to protein denaturation by urea molecules (Wang et al., 2014 ▸). Interestingly, in our current study we observed the initiation of protein folding at pH ∼12.0 or below through SAXS and circular-dichroism (CD) spectra (Fig. 4 ▸ c, Supplementary Fig. S3). Furthermore, we also observed a trend towards the polarization of main-chain amides using UVRR when the pH was increased to 12.0 (Fig. 5 ▸ b). Combined, these experimental data appear to demonstrate that pH 12.0 is a threshold for protein folding or unfolding. The sole pH dependence of protein folding and the dynamic status of main-chain amides at high pH values in our observed data require a proper interpretation of the underlying mechanism. In this regard, we propose that hydrogen bonds are a primary driving force for de novo protein folding.

The importance of hydrogen bonds as a primary driving force of n class="Chemical">protein folding is underappreciated largely owing to the contention of a widely accepted theory: the formation of hydrophobic cores as a primary driving force of protein folding. This underappreciation stems from the fact that protein-folding mechanisms are currently largely in the realm of theory, and experimental observations that support one theory or another are few and far between. The core of our reasoning starts with our empirical data, which demonstrate greater protein-folding efficacy at higher pH. The effects of hydrophobicity at higher pH is well understood and is the basis for common techniques such as reversed-phase or hydrophobic interaction chromatography during protein purification, where the targeted protein binds to hydrophobic resin when exposed to high-pH conditions (Dorsey & Cooper, 1994 ▸). The mechanism is understood to be owing to water molecules being steered away from the surface of unfolded proteins under alkaline conditions, which leads to a relatively anhygroscopic microenvironment surrounding the proteins (Dorsey & Cooper, 1994 ▸). We propose that owing to the reduction in the number of water molecules surrounding the protein, such an environment will weaken the contribution of the water surface tension to the hydrophobic effect during the protein-folding process, which may otherwise form nonspecific intramolecular hydrophobic interactions and lead to irreversibly misfolded proteins. As we outline below, overwhelming in vivo data support this hypothesis.

Here, our study provides observable evidence that alkaline conditions enhance the formation of secondary structures by preventing competing n class="Chemical">water molecules from forming hydrogen bonds to the peptide backbone and induce main-chain polarization to enhance secondary-structure formation. Interpretation of these directly observed data lead to the deduction of the potential general protein-folding mechanism in vivo. As reported, various trigger factors assist with folding as peptides exit the ribosome (Hartl & Hayer-Hartl, 2009 ▸; Kramer et al., 2009 ▸; Kaiser et al., 2006 ▸; Martinez-Hackert & Hendrickson, 2009 ▸; Wang & Tsou, 1998 ▸; Cabrita et al., 2010 ▸). These trigger factors contain a functional domain with hydrophobic and negative charges on the surface (Hoffmann et al., 2010 ▸). As the nascent peptide chain leaves the cramped ribosomal tunnel and is bound by a trigger factor, water molecules are excluded, the physical space limitation is removed and secondary structures begin to form automatically. Furthermore, the recurring theme of GroEL studies emphasizes three key points: (i) the closed chamber structure of GroEL decreases conformational entropy (Hayer-Hartl & Minton, 2006 ▸; Zhou & Dill, 2001 ▸; Betancourt & Thirumalai, 1999 ▸), (ii) there is an abundance of hydrophobic residues within the chamber (Sigler et al., 1998 ▸; Xu et al., 1997 ▸) and (iii) the binding of GroES leads to GroEL exposing numerous negatively charged side chains within the chamber (Tang et al., 2006 ▸). Taken together, GroEL appears to have hallmark features that preclude nonspecific intramolecular hydrophobic interactions that may form irreversibly misfolded proteins if left situated in aqueous environments. These processes involving hydrophobic and negatively charged residues that are observed in vivo are analogous to protein folding driven by negative charges from OH− under in vitro high-pH conditions. In both these in vivo and in vitro conditions, the ensuing anhygroscopic environment not only excludes the interference of water molecules from competing hydrogen-bond formation within the polypeptide main chain, but also disrupts the water surface tension to diminish entropy-driven hydrophobic effects to negligible levels. A negatively charged environment contributed by glutamic acids or aspartic acids could trigger the polarization of main-chain peptide bonds (or imidic acid formation), which will induce secondary-structure formation through the formation of main-chain hydrogen bonds and release free energy. When these factors are taken into account, we propose that hydrogen bonds are a primary driving force of de novo protein folding. Based on our current results and the reports of others, a comprehensive model of protein folding can be derived (Fig. 6 ▸).

Figure 6

Proposed model for the folding of de novo proteins in a completely unstructured state.

All evidence from both in vitro and in vivo data shown above indicates the critical roles of hydrophobic and negatively charged microenvironments. A key question that remains is: what roles do the side chains of amino acids play and how do they participate during the entire protein-foln class="Gene">ding process? In this regard, researchers have reported that driven by thermal stabilization, some amino acids prefer to form α-helices, some amino acids prefer to form β-sheets and some amino acids are secondary-structure disruptors (Chou & Fasman, 1974 ▸; Levitt, 1978 ▸; Malkov et al., 2008 ▸; Minor & Kim, 1994 ▸; Pace & Scholtz, 1998 ▸). Furthermore, it was demonstrated by proton-accessibility experiments that some secondary structures form first, acting as a core, and others follow (Roder et al., 1988 ▸). Based on these valuable observations, we propose that the side chains of amino acids are the determinants of secondary-structure forms (α-helix or β-sheet or random coil) after main-chain polarization both in vivo and in vitro. Taking these findings into account, our proposed scenario for the de novo protein-folding process is as follows: in a relatively hydrophobic and negative charged environment in vivo (for example a molecular chaperone) (i) polarization of the main chain induced by negative charge triggers secondary-structure formation (both α-helices and β-sheets), (ii) β-sheet pairing brings remote secondary structures together, (iii) hydrophobic side chains loosely group together within the quasi-aqueous chaperone chamber and (iv) upon re-exposure to the cytosol the clustering of hydrophobic side chains strengthen under the aqueous environment, ultimately establishing a set of hydrogen bonds that correspond to the native form of the protein.

In our previous report, we have demonstrated the following: (i) denaturation by urea is caused by the disruption of n class="Chemical">hydrogen bonds, (ii) the hydrophilic features of PEG could neutralize urea through hydrogen-bond competition and (iii) protein denaturation at high pH is triggered by the dissociation of protons on the main chain at pH 13.0 and above (Wang et al., 2014 ▸). In this report, we demonstrate that (i) high pH values lead to the successful refolding of all protein candidates that we tested, (ii) secondary-structure formation is observable up to pH 12.0 by CD spectroscopy, (iii) partial native structure of a protein is detectable at pH 11.5–12.5 by SAXS and (iv) a positive trend towards main-chain polarization was observed as the pH increased to pH 12.0 by UVRR. Considering the sole dependence of protein folding and unfolding on the pH level, and with pH being the sole factor in determining the strength of hydrogen bonds within our in vitro protein-folding conditions, this transitive relation leads us to propose that hydrogen bonds are a dominant primary driving force of protein folding. Interestingly, studies into amyloidosis appear to vindicate our proposition. Amyloids, which are an exceptionally unique occurrence among misfolded proteins, are one of the strongest and stiffest structures and are formed exclusively by main-chain amides participating in intermolecular hydrogen bonds, whereas the side chains contribute nominally towards the overall shape (Qiang et al., 2017 ▸; Lu et al., 2013 ▸; Wasmer et al., 2008 ▸; Fitzpatrick et al., 2017 ▸). Given the pre-eminent role that amyloids play in numerous neurodegenerative disorders, the future of amyloid research may require the consideration of hydrogen bonds as a primary driving force in the formation of amyloids.

PDB reference: twinned human n class="Gene">AID, 5w09

Supplementary Figures and Table.. DOI: 10.1107/S2059798317015303/qh5051sup1.pdf