An anti-apoptotic HEK293 cell line provides a robust and high titer platform for transient protein expression in bioreactors

ABSTRACT

HEK293 transient expression systems are used to quickly generate proteins for research and pre-clinical studies. With the aim of engineering a high-producing host that grows and transfects robustly in bioreactors, we deleted the pro-apoptotic genes Bax and Bak in an HEK293 cell line. The HEK293 Bax Bak double knock-out (HEK293 DKO) cell line exhibited resistance to apoptosis and shear stress. HEK293 DKO cells sourced from 2 L seed train bioreactors were most productive when a pH setpoint of 7.0, a narrow pH deadband of ±0.03, and a DO setpoint of 30% were used. HEK293 DKO seed train cells cultivated for up to 60 days in a 35 L bioreactor showed similar productivities to cells cultivated in shake flasks. To optimize HEK293 DKO transfection cultures, we first evaluated different pH and agitation parameters in ambr15 microbioreactors before scaling up to 10 L wavebag bioreactors. In ambr15 microbioreactors with a pH setpoint of 7.0, a wide pH deadband of ±0.3, and an agitation of 630 rpm, HEK293 DKO transient cultures yielded antibody titers up to 650 mg/L in 7 days. The optimal ambr15 conditions prompted us to operate the 10 L wavebag transfection without direct pH control to mimic the wide pH deadband ranges. The HEK293 DKO transfection process produces high titers at all scales tested. Combined, our optimized HEK293 DKO 35 L bioreactor seed train and 10 L high titer transient processes support efficient, large-scale recombinant protein production for research studies.     

Protein stabilization and destabilization by guanidinium salts

Preferential interactions of bovine serum albumin were measured with guanidine sulfate, guanidine acetate, and guanidine hydrochloride. The results showed an increasing preferential hydration with increasing salt concentration for the sulfate, positive preferential salt binding for the hydrochloride, and an intermediate situation for the acetate. These results correlate well with the known effects of the three salts on protein stability, namely, the stabilizing effect of guanidine sulfate and the denaturing effect of guanidine hydrochloride. Comparison of guanidinium and magnesium salts indicated that the substitution of guanidinium ion for Mg2+ decreases the preferential hydration and increases the preferential salt binding, suggesting that the perturbation by guanidinium ion binding of the surface free energy is greater than that by Mg2+ ion. It was concluded that guanidine salts are not a special class, but their activity toward proteins is modulated by the same fine balance between hydration and salt binding to protein as in the case of other salts, with the second factor being stronger in guanidine salts.     

Measuring unfolding of proteins in the presence of denaturant using fluorescence correlation spectroscopy

IFABP is a small (15 kDa) protein consisting mostly of antiparallel beta-strands that surround a large cavity into which ligands bind. We have previously used FCS to show that the native protein, labeled with fluorescein, exhibits dynamic fluctuation with a relaxation time of 35 micros. Here we report the use of FCS to study the unfolding of the protein induced by guanidine hydrochloride. Although the application of this technique to measure diffusion coefficients and molecular dynamics is straightforward, the FCS results need to be corrected for both viscosity and refractive index changes as the guanidine hydrochloride concentration increases. We present here a detailed study of the effects of viscosity and refractive index of guanidine hydrochloride solutions to calibrate FCS data. After correction, the increase in the diffusion time of IFABP corresponds well with the unfolding transition monitored by far ultraviolet circular dichroism. We also show that the magnitude of the 35 micros phase, reflecting the conformational fluctuation in the native state, decreases sharply as the concentration of denaturant increases and the protein unfolds. Although FCS experiments indicate that the unfolded state at pH 2 is rather compact and native-like, the radius in the presence of guanidine hydrochloride falls well within the range expected for a random coil.     

Unnatural amino acid packing mutants of Escherichia coli thioredoxin produced by combined mutagenesis/chemical modification techniques.

We have produced several mutants of Escherichia coli thioredoxin (Trx) using a combined mutagenesis/chemical modification technique. The protein C32S, C35S, L78C Trx was produced using standard mutagenesis procedures. After unfolding the protein with guanidine hydrochloride (GdmCl), the normally buried cysteine residue was modified with a series of straight chain aliphatic thiosulfonates, which produced cysteine disulfides to methane, ethane, 1-n-propane, 1-n-butane, and 1-n-pentane thiols. These mutants all show native-like CD spectra and the ability to activate T7 gene 5 protein DNA polymerase activity. In addition, all mutants show normal unfolding transitions in GdmCl solutions. However, the midpoint of the transition, [GdmCl]1/2, and the free energy of unfolding at zero denaturant concentration, delta G(H2O), give inverse orders of stability. This effect is due to changes in m, the dependence of delta G0 unfolding on the GdmCl concentration. The method described here may be used to produce unnatural amino acids in the hydrophobic cores of proteins.     

Amyloid Formation by Human Carboxypeptidase D Transthyretin-like Domain under Physiological Conditions

Protein aggregation is linked to a growing list of diseases, but it is also an intrinsic property of polypeptides, because the formation of functional globular proteins comes at the expense of an inherent aggregation propensity. Certain proteins can access aggregation-prone states from native-like conformations without the need to cross the energy barrier for unfolding. This is the case of transthyretin (TTR), a homotetrameric protein whose dissociation into its monomers initiates the aggregation cascade. Domains with structural homology to TTR exist in a number of proteins, including the M14B subfamily carboxypeptidases. We show here that the monomeric transthyretin-like domain of human carboxypeptidase D aggregates under close to physiological conditions into amyloid structures, with the population of folded but aggregation-prone states being controlled by the conformational stability of the domain. We thus confirm that the TTR fold keeps a generic residual aggregation propensity upon folding, resulting from the presence of preformed amyloidogenic β-strands in the native state. These structural elements should serve for functional/structural purposes, because they have not been purged out by evolution, but at the same time they put proteins like carboxypeptidase D at risk of aggregation in biological environments and thus can potentially lead to deposition diseases.     

Structural characteristics and refolding of in vivo aggregated hyperthermophilic archaeon proteins

Several recombinant proteins in inclusion bodies expressed in Escherichia coli have been measured by Fourier transform infrared and solid-state nuclear magnetic resonance spectra to provide the secondary structural characteristics of the proteins from hyperthermophilic archaeon Pyrococcus horikoshii OT3 (hyperthermophilic proteins) in inclusion bodies. The beta-strand-rich single chain Fv fragment (scFv) and alpha-helix-rich interleukin (IL)-4 lost part of the native-like secondary structure in inclusion bodies, while the inclusion bodies composed of the hyperthermophilic proteins of which the native form is alpha-helix rich, are predominated by alpha-helix structure. Further, the secondary structure of the recombinant proteins solubilized from inclusion bodies by detergent or denaturant was observed by circular dichroism (CD) spectra. The solubilization induced the denaturation of the secondary structure for scFv and IL-4, whereas the solubilized hyperthermophilic proteins have retained the alpha-helix structure with the CD properties resembling those of their native forms. This indicates that the hyperthermophilic proteins form native-like secondary structure in inclusion bodies. Refolding of several hyperthermophilic proteins from in vivo aggregated form without complete denaturation could be accomplished by solubilization with lower concentration (e.g. 2 M) of guanidine hydrochloride and removal of the denaturant via stepwise dialysis. This supports the existence of proteins with native-like structure in inclusion bodies and suggests that non-native association between the secondary structure elements leads to in vivo aggregation. We propose a refolding procedure on the basis of the structural properties of the aggregated archaeon proteins.     

“Native-like aggregation” of the acylphosphatase from Sulfolobus solfataricus and its biological implications

Studies in vitro show that globular proteins can experience the formation of native-like conformational states able to self-assemble with no need of transitions across the energy barrier for unfolding, and that such processes can lead eventually to the formation of amyloid-like species. Circumstantial evidence collected in vivo suggests that aggregation of native-like states can be a concrete possibility for living organisms and thus more relevant than previously thought. In this review we summarize the key observations collected on the “native-like aggregation” of the acylphosphatase from Sulfolobus solfataricus, a protein that has allowed the direct monitoring and analysis of native-like aggregates for its propensity to form rapidly native-like aggregates and their slow conversion into amyloid-like aggregates.     

Structural characterization of the partially folded intermediates of an immunoglobulin light chain leading to amyloid fibrillation and amorphous aggregation

Immunoglobulin light chain deposition diseases involve various types of extracellular deposition of light chain variable domains, including amyloid fibrils and amorphous deposits. The decreased thermodynamic stability of the light chain is believed to be the major factor leading to fibrillation. However, the differences in the nature of the deposits among the light chain deposition diseases raise the question of whether the mechanisms leading to fibrillar or amorphous aggregation is different. In this study, we generated two partially folded intermediates of the light chain variable domain SMA in the presence of guanidine hydrochloride (GuHCl) and characterized their conformations. The more unfolded intermediate formed fibrils most rapidly, while the more native-like intermediate predominantly led to amorphous deposits. The results also show that the monomeric, rather than the dimeric state, was critical for fibrillation. The data also indicate that fibril elongation involves addition of a partially unfolded intermediate, rather than the native state. We postulate that a more highly unfolded intermediate is more suited to undergo the topological rearrangements necessary to form amyloid fibrils than a more structured one and that this also correlates with increased destabilization. In the case of light chain aggregation, it appears that more native-like intermediate conformations are more prone to form amorphous deposits.     

Insights into the molecular mechanism of protein native-like aggregation upon glycation

Several human neurodegenerative diseases such as Alzheimer's disease, Parkinson's disease and Familial Amyloidotic Polyneuropathy, have long been associated with, structural and functional changes in disease related proteins leading to aggregation into amyloid fibrils. Such changes can be triggered by post-translational modifications. Methylglyoxal modifications have been shown to induce the formation of small and stable native-like aggregates in the case of the amyloidogenic proteins insulin and α-synuclein. However, the fundamental biophysical mechanism underlying such methylglyoxal-induced protein aggregation is not yet fully understood. In this work cytochrome c (Cyt c) was used as a model protein for the characterization of specific glycation targets and to study their impact on protein structure, stability, and ability to form native-like aggregates. Our results show that methylglyoxal covalently modifies Cyt c at a single residue and induces early conformational changes that lead to the formation of native-like aggregates. Furthermore, partially unfolded species are formed, but do not seem to be implicated in the aggregation process. This shows a clear difference from the amyloid fibril mechanisms which involve partially or totally unfolded intermediates. Equilibrium-unfolding experiments show that glycation strongly decreases Cyt c conformational stability, which is balanced with an increase of conformational stability upon aggregation. Data collected from analytical and spectroscopic techniques, along with kinetic analysis based on least-squares parameter fitting and statistical model discrimination are used to help to understand the driving force underlying glycation-induced native-like aggregation, and enable the proposal of a comprehensive thermodynamic and kinetic model for native-like aggregation of methylglyoxal glycated Cyt c.     

Denaturation of subtilisin BPN' and its derivatives in aqueous guanidine hydrochloride solutions.

The denaturation of subtilisin BPN' (EC 3.4.21.14) in guanidine hydrochloride was studied in order to find possible reasons for the exceptional stability of this enzyme against the action of denaturing agents including guanidine hydrochloride. Chemically modified subtilisins, i.e., phenylmethanesulfonylsubtilisin and thio-subtilisin, were completely denatured in 2 M guanidine hydrochloride at pH 7 without autolysis but they were stable in 0.5 M guanidine hydrochloride for at least 60 h. On the other hand, once completely denatured, the subtilisins remained inactive and in highly unfolded conformations for 60 h or longer after transfer into 0.5 M guanidine solution at pH 7 or 9. No enzymatic activity was regained when the guanidine concentration was lowered to almost zero. We concluded from these and other results described in this paper that this enzyme was thermodynamically unstable in 2 M guanidine hydrochloride at 20 degrees C and at pH 7. We wish to point out the possibility that the denaturation of this enzyme could indeed be irreversible.     

Osmolytes and crowders regulate aggregation of the cancer-related L106R mutant of the Axin protein

Protein aggregation is involved in a variety of diseases, including neurodegenerative diseases and cancer. The cellular environment is crowded by a plethora of cosolutes comprising small molecules and biomacromolecules at high concentrations, which may influence the aggregation of proteins in vivo. To account for the effect of cosolutes on cancer-related protein aggregation, we studied their effect on the aggregation of the cancer-related L106R mutant of the Axin protein. Axin is a key player in the Wnt signaling pathway, and the L106R mutation in its RGS domain results in a native molten globule that tends to form native-like aggregates. This results in uncontrolled activation of the Wnt signaling pathway, leading to cancer. We monitored the aggregation process of Axin RGS L106R in vitro in the presence of a wide ensemble of cosolutes including polyols, amino acids, betaine, and polyethylene glycol crowders. Except myo-inositol, all polyols decreased RGS L106R aggregation, with carbohydrates exerting the strongest inhibition. Conversely, betaine and polyethylene glycols enhanced aggregation. These results are consistent with the reported effects of osmolytes and crowders on the stability of molten globular proteins and with both amorphous and amyloid aggregation mechanisms. We suggest a model of Axin L106R aggregation in vivo, whereby molecularly small osmolytes keep the protein as a free soluble molecule but the increased crowding of the bound state by macromolecules induces its aggregation at the nanoscale. To our knowledge, this is the first systematic study on the effect of osmolytes and crowders on a process of native-like aggregation involved in pathology, as it sheds light on the contribution of cosolutes to the onset of cancer as a protein misfolding disease and on the relevance of aggregation in the molecular etiology of cancer.     

The Quaternary Structure of the Recombinant Bovine Odorant-Binding Protein Is Modulated by Chemical Denaturants

A large group of odorant-binding proteins (OBPs) has attracted great scientific interest as promising building blocks in constructing optical biosensors for dangerous substances, such as toxic and explosive molecules. Native tissue-extracted bovine OBP (bOBP) has a unique dimer folding pattern that involves crossing the α-helical domain in each monomer over the other monomer’s β-barrel. In contrast, recombinant bOBP maintaining the high level of stability inherent to native tissue bOBP is produced in a stable native-like state with a decreased tendency for dimerization and is a mixture of monomers and dimers in a buffered solution. This work is focused on the study of the quaternary structure and the folding-unfolding processes of the recombinant bOBP in the absence and in the presence of guanidine hydrochloride (GdnHCl). Our results show that the recombinant bOBP native dimer is only formed at elevated GdnHCl concentrations (1.5 M). This process requires re-organizing the protein structure by progressing through the formation of an intermediate state. The bOBP dimerization process appears to be irreversible and it occurs before the protein unfolds. Though the observed structural changes for recombinant bOBP at pre-denaturing GdnHCl concentrations show a local character and the overall protein structure is maintained, such changes should be considered where the protein is used as a sensitive element in a biosensor system.     

Influence of Osmolytes on Inactivation and Aggregation of Muscle Glycogen Phosphorylase <Emphasis Type="Italic">b</Emphasis> by Guanidine Hydrochloride. Stimulation of Protein Aggregation under Crowding Conditions

The effects of the osmolytes trimethylamine-N-oxide (TMAO), betaine, proline, and glycine on the kinetics of inactivation and aggregation of rabbit skeletal muscle glycogen phosphorylase b by guanidine hydrochloride (GuHCl) have been studied. It is shown that the osmolytes TMAO and betaine exhibit the highest protective efficacy against phosphorylase b inactivation. A test system for studying the effects of macromolecular crowding induced by osmolytes on aggregation of proteins is proposed. TMAO and glycine increase the rate of phosphorylase b aggregation induced by GuHCl.     

Guanidine hydrochloride denaturation studies of mutant forms of staphylococcal nuclease

Several mutant forms of staphylococcal nuclease with one or two defined amino acid substitutions have been purified, and the effects of the altered amino acid sequence on the stability of the folded conformation have been analyzed by guanidine hydrochloride denaturation. Two nuc- mutations, which greatly reduced the level of enzyme activity accumulated in E coli colonies carrying a recombinant plasmid with the mutant nuc gene (ie, a NUC- phenotype), both result in protein unfolding at significantly lower guanidine hydrochloride concentrations than the wild-type protein, whereas three sup mutations isolated on the basis of their ability to suppress partially the NUC- phenotype of the above two mutations result in unfolding at significantly higher guanidine hydrochloride concentrations. Characterization of nuclease molecules with two different amino acid substitutions, either nuc- + sup pairs or sup + sup pairs, suggests that the effect of an amino acid substitution on the stability of the native conformation, as measured by the value of delta delta GD, may not be a constant, but rather a variable that is sensitive to the presence of other substitutions at distant sites in the same molecule. Surprisingly, the slopes of the log Kapp vs guanidine hydrochloride concentration plots vary by as much as 35% among the different proteins.     

Evidence concerning rate-limiting steps in protein folding from the effects of trifluoroethanol

The refolding kinetics of 13 proteins have been studied in the presence of 2,2,2-trifluoroethanol (TFE). Low concentrations of TFE increased the folding rates of all the proteins, whereas higher concentrations have the opposite effect. The extent of deceleration of folding correlates closely with similar effects of guanidine hydrochloride and can be related to the burial of accessible surface area during folding. For those proteins folding in a two-state manner, the extent of acceleration of folding correlates closely with the number of local backbone hydrogen bonds in the native structure. For those proteins that fold in a multistate manner, however, the extent of acceleration is much smaller than that predicted from the data for two-state proteins. These results support the concept that for two-state proteins the search for native-like contacts is a key aspect of the folding reaction, whereas the rate-determining steps for folding of multistate proteins are associated with the reorganization of stable structure within a collapsed state or with the search for native-like interactions within less structured regions.     

Understanding the relevance of local conformational stability and dynamics to the aggregation propensity of an IgG1 and IgG2 monoclonal antibodies

Aggregation of monoclonal antibodies is often a multi‐step process involving structural alterations in monomeric proteins and subsequent formation of soluble or insoluble oligomers. The role of local conformational stability and dynamics of native and/or partially altered structures in determining the aggregation propensity of monoclonal antibodies, however, is not well understood. Here, we investigate the role of conformational stability and dynamics of regions with distinct solvent exposure in determining the aggregation propensity of an IgG1 and IgG2 monoclonal antibody. The temperatures employed span the pre‐unfolding range (10–40°C) and the onset temperatures (T_onset) for exposure of apolar residues (～50°C), alterations in secondary structures (～60°C) and initiation of visible aggregate formation (～60°C). Solvent‐exposed regions were found to precede solvent‐shielded regions in an initiation of aggregation for both proteins. Such a process was observed upon alterations in overall tertiary structure while retaining the secondary structures in both the proteins. In addition, a greater dynamic nature of solvent‐shielded regions in potential intermediates of IgG1 and the improved conformational stability increased its resistance to aggregation when compared to IgG2. These results suggest that local conformational stability and fluctuations of partially altered structures can influence the aggregation propensity of immunoglobulins.     

Mammalian antimicrobial peptide protegrin‐4 self assembles and forms amyloid‐like aggregates: Assessment of its functional relevance

Protegrin‐4 (PG‐4) is a member of the porcine leukocyte protegrins family of cysteine‐rich antimicrobial peptides (AMPs) isolated from Sus scrofa. It consists of 18 amino acid residues and works as a part of innate immune system. In this study, we examined the intrinsic aggregation propensity of this AMP using multiple computational algorithms, namely, TANGO, AGGRESCAN, FOLDAMYLOID, AMYLPRED, and ZYGGREGATOR, and found that the peptide is predicted to have a high propensity for the β sheet formation that disposes this peptide to be amyloidogenic. Under in vitro conditions, PG‐4 formed visible aggregates and displayed the hallmark properties of typical amyloids such as enhanced binding of Congo red, increased fluorescence with Thioflavin‐T, and fibrillar morphology under transmission electron microscopy. Then we examined its antimicrobial activity against Bacillus subtilis and found that the aggregated peptide retained its antimicrobial activity. Additionally, the aggregates remain non‐toxic to the HEK293 and Caco2 cells. Our study suggests that the inherent aggregation properties of AMP can rationally be explored as a potential source of peptide‐based antimicrobials with enhanced stability.     

Protein stability to the effect of denaturing agents and elevated temperature is directly proportional to the fraction of hydrophobic residues in its molecule

The dependence of protein stability against the action of urea, guanidine hydrochloride and elevated temperature on the fraction of hydrophobic residues in their molecules was studied. It was shown that proteins can be divided into several stability classes. The stability of proteins within each class is directly proportional to the fraction of hydrophobic residues in their molecules and this dependence is a linear one. As shown on several examples proteins can pass from one class to another and such discrete transitions are determined by the formation or disruption of bonds with cofactors. The effect of point mutations on the stability of proteins is discussed from the viewpoint of polar group dehydration.     

转录因子AP-2beta和p53蛋白相互作用的研究

转录因子p53与AP-2基因家族成员AP-2beta发生突变后,均会导致个体出现相应的疾病。本文首先利用两个重组质粒p CMV-HA-p53和p Myc-AP-2beta,转染永生化的胚胎肾细胞HEK293(野生型),在细胞中表达相应蛋白质。通过免疫共沉淀实验证明AP-2beta和p53蛋白在体内可以相互作用。并将梯度增加的p MycAP-2beta质粒及等量p CMV-HA-p53质粒转染到HEK293细胞,SDS-聚丙烯酰胺凝胶电泳实验证明AP-2beta能正向调控p53蛋白的表达。为了进一步探讨AP-2beta与p53的作用机制,利用蛋白质合成抑制剂CHX(cycloheximide)处理转染了AP-2beta与p53表达质粒的细胞,实验结果说明,AP-2beta能增加p53蛋白的稳定性来调控p53的表达。     

Protein stiffening and entropic stabilization in the subdenaturing limit of guanidine hydrochloride

Subdenaturing concentrations of guanidine hydrochloride (GdnHCl) stabilize proteins. For ferrocytochrome c the stabilization is detected at subglobal level with no measured change in global stability. These deductions are made by comparing observed rates of thermally driven ferrocytochrome cHCO reactions with global unfolding rates of ferrocytochrome c measured by stopped flow and NMR hydrogen exchange in the presence of a wide range of GdnHCl concentrations at pH 7, 22 degrees C.