Aggregation suppression of proteins by arginine during thermal unfolding

Arginine has been used to suppress aggregation of proteins during refolding and purification. We have further studied in this paper the aggregation-suppressive effects of arginine on two commercially important proteins, i.e., interleukine-6 (IL-6) and a monoclonal antibody (mAb). These proteins show extensive aggregation in aqueous buffers when subjected to thermal unfolding. Arginine suppresses aggregation concentration-dependently during thermal unfolding. However, this effect was not specific to arginine, as guanidine hydrochloride (GdnHCl) at identical concentrations also was effective. While equally effective in aggregation suppression during thermal unfolding, arginine and GdnHCl differed in their effects on the structure of the native proteins. Arginine showed no apparent adverse effects on the native protein, while GdnHCl induced conformational changes at room temperature, i.e., below the melting temperature. These additives affected the melting temperature of IL-6 as well; arginine increased it concentration-dependently, while GdnHCl increased it at low concentration but decreased at higher concentration. These results clearly demonstrate that arginine suppresses aggregation via different mechanism from that conferred by GdnHCl.     

Role of arginine in protein refolding, solubilization, and purification

Recombinant proteins are often expressed in the form of insoluble inclusion bodies in bacteria. To facilitate refolding of recombinant proteins obtained from inclusion bodies, 0.1 to 1 M arginine is customarily included in solvents used for refolding the proteins by dialysis or dilution. In addition, arginine at higher concentrations, e.g., 0.5-2 M, can be used to extract active, folded proteins from insoluble pellets obtained after lysing Escherichia coli cells. Moreover, arginine increases the yield of proteins secreted to the periplasm, enhances elution of antibodies from Protein-A columns, and stabilizes proteins during storage. All these arginine effects are apparently due to suppression of protein aggregation. Little is known, however, about the mechanism. Various effects of solvent additives on proteins have been attributed to their preferential interaction with the protein, effects on surface tension, or effects on amino acid solubility. The suppression of protein aggregation by arginine cannot be readily explained by either surface tension effects or preferential interactions. In this review we show that interactions between the guanidinium group of arginine and tryptophan side chains may be responsible for suppression of protein aggregation by arginine.     

Specific arginine mediated RNA recognition

In many biological systems substantial roles are played by interactions between amino acids and RNA. Among amino acids L-arginine seems to be particularly relevant, because the guanidinium group of arginine side chain can potentially form five hydrogen bonds with appropriately positioned acceptor groups of RNA. Extensive studies reveal that specific arginine recognition is achieved by many different RNAs over a broad range of binding affinities. Arginine is frequently found among amino acids in the nucleic acid-binding motifs in various proteins. For example, specific binding of the HIV-1 Tat protein to its RNA site (TAR) is mediated by a single arginine residue. Free arginine can be also bound by the guanosine site in the group I Tetrahymena ribosomal RNA intron catalytic centre, as well as by numerous RNA motifs, called arginine aptamers, which have been selected in vitro.     

Effective elution of antibodies by arginine and arginine derivatives in affinity column chromatography

It has been shown that the recovery of monomeric antibodies from protein A affinity chromatography is enhanced significantly by using arginine as an eluent. To extend the applications of arginine to antibody purification and obtain an insight into the mechanism of arginine elution, we compared arginine with citrate, guanidine hydrochloride (GdnHCl), arginine derivatives, and other amino acids in protein A chromatography. We also applied arginine to elution of polyclonal antibodies (pAbs) in antigen affinity chromatography. As described previously, arginine was effective in eluting monoclonal antibodies IgG1 and IgG4. Two arginine derivatives, acetyl-arginine and agmatine, resulted in efficient elution at pH 4.0 or higher, and this was comparable to arginine. On the other hand, other amino acids, such as glycine, proline, lysine, and histidine, are much less effective than arginine under identical pH conditions. Whereas elution increased with arginine concentration, elution with citrate was insignificant in excess of 1 M at pH 4.3. Arginine was also effective in fractionation of pAbs using antigen-conjugated affinity columns. Although GdnHCl was also effective under similar conditions, the eluted material showed more aggregation than did the protein eluted by arginine.     

Effects of arginine on heat-induced aggregation of concentrated protein solutions

Arginine is one of the commonly used additives to enhance refolding yield of proteins, to suppress aggregation of proteins, and to increase solubility of proteins, and yet the molecular interactions that contribute to the role of arginine are unclear. Here, we present experiments, using bovine serum albumin (BSA), lysozyme (LYZ), and β-lactoglobulin (BLG) as model proteins, to show that arginine can enhance heat-induced aggregation of concentrated protein solutions, contrary to the conventional belief that arginine is a universal suppressor of aggregation. Results show that the enhancement in aggregation is caused only for BSA and BLG, but not for LYZ, indicating that arginine's preferential interactions with certain residues over others could determine the effect of the additive on aggregation. We use this previously unrecognized behavior of arginine, in combination with density functional theory calculations, to identify the molecular-level interactions of arginine with various residues that determine arginine's role as an enhancer or suppressor of aggregation of proteins. The experimental and computational results suggest that the guanidinium group of arginine promotes aggregation through the hydrogen-bond-based bridging interactions with the acidic residues of a protein, whereas the binding of the guanidinium group to aromatic residues (aggregation-prone) contributes to the stability and solubilization of the proteins. The approach, we describe here, can be used to select suitable additives to stabilize a protein solution at high concentrations based on an analysis of the amino acid content of the protein.     

Preferential interactions of proteins with solvent components in aqueous amino acid solutions

The preferential interactions of proteins with solvent components in concentrated amino acid solutions were measured by high-precision densimetry. Bovine serum albumin and lysozyme were preferentially hydrated in all of the amino acids examined, glycine, α- and β-alanine, and betaine i.e., addition of these amino acids resulted in an unfavorable free energy change. It was shown that, for the former three amino acids, known to have a positive surface tension increment, their perturbation of the surface free energy of water is consistent with their preferential exclusion from the protein surface. In the case of betaine, which does not increase the surface tension of water, preferential exclusion from protein surface must reflect the chemical structure of this cosolvent, which is considerably more hydrophobic than that of the other three amino acids.     

Interaction of arginine,lysine, and guanidine with surface residues of lysozyme: implication to protein stability

Additives are widely used to suppress aggregation of therapeutic proteins. However, the molecular mechanisms of effect of additives to stabilize proteins are still unclear. To understand this, we herein perform molecular dynamics simulations of lysozyme in the presence of three commonly used additives: arginine, lysine, and guanidine. These additives have different effects on stability of proteins and have different structures with some similarities; arginine and lysine have aliphatic side chain, while arginine has a guanidinium group. We analyze atomic contact frequencies to study the interactions of the additives with individual residues of lysozyme. Contact coefficient, quantified from contact frequencies, is helpful in analyzing the interactions with the guanidine groups as well as aliphatic side chains of arginine and lysine. Strong preference for contacts to the additives (over water) is seen for the acidic followed by polar and the aromatic residues. Further analysis suggests that the hydration layer around the protein surface is depleted more in the presence of arginine, followed by lysine and guanidine. Molecular dynamics simulations also reveal that the internal dynamics of protein, as indicated by the lifetimes of the hydrogen bonds within the protein, changes depending on the additives. Particularly, we note that the side-chain hydrogen-bonding patterns within the protein differ with the additives, with several side-chain hydrogen bonds missing in the presence of guanidine. These results collectively indicate that the aliphatic chain of arginine and lysine plays a critical role in the stabilization of the protein.     

Biotechnology applications of amino acids in protein purification and formulations

Summary. Amino acids are widely used in biotechnology applications. Since amino acids are natural compounds, they can be safely used in pharmaceutical applications, e.g., as a solvent additive for protein purification and as an excipient for protein formulations. At high concentrations, certain amino acids are found to raise intra-cellular osmotic pressure and adjust to the high salt concentrations of the surrounding medium. They are called “compatible solutes”, since they do not affect macromolecular function. Not only are they needed to increase the osmotic pressure, they are known to increase the stability of the proteins. Sucrose, glycerol and certain amino acids were used to enhance the stability of unstable proteins after isolation from natural environments. The mechanism of the action of these protein-stabilizing amino acids is relatively well understood. On the contrary, arginine was accidentally discovered as a useful reagent for assisting in the refolding of recombinant proteins. This effect of arginine was ascribed to its ability to suppress aggregation of the proteins during refolding, thereby increasing refolding efficiency. By the same mechanism, arginine now finds much wider applications than previously anticipated in the research and development of proteins, in particular in pharmaceutical applications. For example, arginine solubilizes proteins from loose inclusion bodies, resulting in efficient production of active proteins. Arginine suppresses protein–protein interactions in solution and also non-specific adsorption to gel permeation chromatography columns. Arginine facilitates elution of bound proteins from various column resins, including Protein-A or dye affinity columns and hydrophobic interaction columns. This review covers various biotechnology applications of amino acids, in particular arginine.     

Effects of arginine on kinetics of protein aggregation studied by dynamic laser light scattering and tubidimetry techniques

Prevention of undesirable protein aggregation is an extremely important strategy in protein science, medicine, and biotechnology. Arginine is one of the most widely used low molecular weight solution additives effective in suppressing aggregation, assisting refolding of aggregated proteins, and enhancing the solubility of aggregation-prone unfolded molecules in vitro. However, the mechanism of suppression of protein aggregation by arginine is not well understood. To address the mechanism, two model systems have been investigated: protection of alcohol dehydrogenase (ADH) and insulin from heat- and dithiothreitol-induced aggregation, respectively, in the presence of arginine. Using dynamic light scattering (DLS) technique, we have demonstrated the concentration-dependent suppression of light scattering intensity of both ADH and insulin aggregates upon addition of arginine to the incubation medium, a significant effect being revealed in the physiological concentration range of arginine (1-10 mM). DLS studies showed that arginine shifted the populations of nanoparticles with higher hydrodynamic radii to the lower ones, suggesting that the preventive effect of arginine on the protein aggregation process arises because it suppresses intermolecular interactions among aggregation-prone molecules. The results of turbidity measurements were also shown to be consistent with these findings.     

Role of arginine in the stabilization of proteins against aggregation

The amino acid arginine is frequently used as a solution additive to stabilize proteins against aggregation, especially in the process of protein refolding. Despite arginine's prevalence, the mechanism by which it stabilizes proteins is not presently understood. We propose that arginine deters aggregation by slowing protein-protein association reactions, with only a small concomitant effect on protein folding. The associated rate effect was observed experimentally in association of globular proteins (insulin and a monoclonal anti-insulin) and in refolding of carbonic anhydrase. We suggest that this effect arises because arginine is preferentially excluded from protein-protein encounter complexes but not from dissociated protein molecules. Such an effect is predicted by our gap effect theory [Baynes and Trout (2004) Biophys. J. 87, 1631] for "neutral crowder" additives such as arginine which are significantly larger than water but have only a small effect on the free energies of isolated protein molecules. The effect of arginine on refolding of carbonic anhydrase was also shown to be consistent with this hypothesis.     

Loblolly pine arginase responds to arginine in vitro

Following germination of loblolly pine (Pinus taeda L.) seeds, storage proteins in the embryo and megagametophyte are broken down to provide nitrogen, in the form of amino acids, to the developing seedling. A substantial portion of the free amino acids released in this process is arginine. Arginine is hydrolyzed in the cotyledons of the seedling by the enzyme arginase (EC 3.5.3.1), which is under developmental control. It has been shown previously that the seedling is able to initiate arginase gene expression in vitro in the absence of the megagametophyte, however, presence of the megagametophyte causes a greater accumulation of arginase protein and mRNA. Using an in vitro culture system we show that arginine itself may be responsible for up-regulating arginase activity. Application of exogenous arginine to cotyledons of seedlings germinated in the absence of the megagametophyte caused an increase in total shoot pole arginase activity as well as arginase specific activity. Arginine was also able to induce arginase mRNA accumulation in the same tissue.     

Interactions between l‐arginine/l‐arginine derivatives and lysozyme and implications to their inhibition effects on protein aggregation

l ‐Arginine (Arg), l ‐homoarginine (HArg), l ‐arginine ethylester (ArgEE), and l ‐arginine methylester (ArgME) were found effective in inhibiting protein aggregation, but the molecular mechanisms are not clear. Herein, stopped‐flow fluorescence spectroscopy, isothermal titration calorimetry, and mass spectroscopy were used to investigate the folding kinetics of lysozyme and the interactions of the additives with lysozyme. It was found that the interactions of ArgME and ArgEE with lysozyme were similar to that of guanidine hydrochloride and were much stronger than those of Arg and HArg. The binding forces were all mainly hydrogen bonding and cation‐π interaction from the guanidinium group, but their differences in molecular states led to the significantly different binding strengths. The additives formed molecular clusters in an increasing order of ArgEE, ArgME, HArg, and Arg. Arg and HArg mainly formed annular clusters with head‐to‐tail bonding, while ArgME and ArgEE formed linear clusters with guanidinium groups stacking. The interactions between the additives and lysozyme were positively related to the monomer contents. That is, the monomers were the primary species that participated in the direct interactions due to their intact guanidinium groups and small sizes, while the clusters performed as barriers to crowd out the protein–protein interactions for aggregation. Thus, it is concluded that the effects of Arg and its derivatives on protein aggregation stemmed from the direct interactions by the monomers and the crowding effects by the clusters. Interplay of the two effects led to the differences in their inhibition effects on protein aggregation. © 2013 American Institute of Chemical Engineers Biotechnol. Prog., 29:1316–1324, 2013     

Review: Why is arginine effective in suppressing aggregation?

Arginine is finding a wide range of applications in production of proteins. Arginine has been used for many years to assist protein refolding. This effect was ascribed to aggregation suppression by arginine of folding intermediates during protein refolding. Recently, we have observed that arginine facilitates elution of antibodies during Protein-A chromatography and solubilizes insoluble proteins from inclusion bodies, which both can be ascribed to weakening of protein-protein interactions. In order to gain understanding on why arginine is effective in reducing protein-protein interactions and suppressing aggregation, the effects of arginine on stability and solubility of pure proteins have been examined, which showed that arginine is not a protein-stabilizer, but is an aggregation suppressor. However, there is no explanation proposed so far on why arginine suppresses aggregation of proteins. This review addresses such question and then attempts to show differences between arginine and strong denaturants, which are also known as an aggregation suppressor.     

Characterization of arginine transport in Helicobacter pylori

Background. The amino acid L‐arginine is an essential requirement for growth of Helicobacter pylori. Several physiological roles of this amino acid have been identified in the bacterium, but very little is known about the transport of L‐arginine and of other amino acids into H. pylori. Methods. Radioactive tracer techniques using L‐(U‐¹⁴C) arginine and the centrifugation through oil method were employed to measure the kinetic parameters, temperature dependence, substrate specificity, and effects of analogues and inhibitors on L‐arginine transport. Results. The transport of arginine at millimolar concentrations was saturable with a K_m of 2.4 ± 0.3 mM and V_max of 1.3 ± 0.2 pmole min^?1 (µl cell water)^?1 or 31 ± 3 nmole per minute (mg protein)^?1 at 20°C, depended on temperature between 4 and 40°C, and was susceptible to inhibitors. These characteristics suggested the presence of one or more arginine carriers. The substrate specificity of the transport system was studied by measuring the effects of L‐arginine analogues and amino acids on the rates of transport of L‐arginine. The absence of inhibition in competition experiments with L‐lysine and L‐ornithine indicated that the transport system was not of the Lysine‐Arginine‐Ornithine or Arginine‐Ornithine types. The presence of different monovalent cations did not affect the transport rates. Several properties of L‐arginine transport were elucidated by investigating the effects of potential inhibitors. Conclusions. The results provided evidence that the transport of L‐arginine into H. pylori cells was carrier‐mediated transport with the driving force supplied by the chemical gradient of the amino acid.     

精氨酸抗氧化作用机制

精氨酸是一种功能性氨基酸,在机体生理功能、新陈代谢和营养等方面发挥着重要作用。精氨酸具有抗氧化能力。目前的体外研究表明精氨酸具有较强的清除DPPH自由基、ABTS自由基、超氧自由基能力以及一定的还原力。作为一种带电子的碱性氨基酸,精氨酸可能通过胍基基团向自由基提供电子并与其作用,终止自由基链式反应,从而显示出还原能力与体外抗氧化能力。体内实验则表明精氨酸能有效地提高机体总抗氧化能力,降低体内自由基含量,抑制ROS生成与积累,促进谷胱甘肽(GSH)合成与积累,增强内源性抗氧化酶(CAT、SOD、GPx等)活性,抑制氧化应激的产生。精氨酸能够通过精氨酸——一氧化氮途径、GSH途径、Nrf2信号通路途径及其他途径发挥体内抗氧化作用。本文主要综述了目前精氨酸体外与体内抗氧化功能及其相关作用机制的研究进展,为精氨酸的实际应用提供理论指导意义。     

Is arginine a protein-denaturant?

Arginine is a useful solvent additive for many applications, including refolding and solubilization of proteins from insoluble pellets, and suppression of protein aggregation and non-specific adsorption during formulation and purification. However, there is a concern that arginine may be a protein-denaturant, which may limit the expansion of its applications. Such concern arises from the facts that arginine decreases melting temperature and perturbs the spectroscopic properties of certain proteins and contains a guanidinium group, which is a critical chemical structure for denaturing activity of guanidine hydrochloride. Here, we show that although arginine does lower the melting temperatures of certain proteins, the extent is insufficient to cause denaturation of proteins at or below room temperature. The proteins described here show enzymatic activity and folded structure in the presence of arginine, although the local structure around aromatic amino acids is perturbed by arginine. Arginine differs from guandinine hydrochloride in the mode of interactions with proteins, which may be a primary reason why arginine is not a protein-denaturant.     

Inhibition of protein aggregation: supramolecular assemblies of arginine hold the key

Background

Aggregation of unfolded proteins occurs mainly through the exposed hydrophobic surfaces. Any mechanism of inhibition of this aggregation should explain the prevention of these hydrophobic interactions. Though arginine is prevalently used as an aggregation suppressor, its mechanism of action is not clearly understood. We propose a mechanism based on the hydrophobic interactions of arginine.

Methodology

We have analyzed arginine solution for its hydrotropic effect by pyrene solubility and the presence of hydrophobic environment by 1-anilino-8-naphthalene sulfonic acid fluorescence. Mass spectroscopic analyses show that arginine forms molecular clusters in the gas phase and the cluster composition is dependent on the solution conditions. Light scattering studies indicate that arginine exists as clusters in solution. In the presence of arginine, the reverse phase chromatographic elution profile of Alzheimer''s amyloid beta 1-42 (Aβ_1-42) peptide is modified. Changes in the hydrodynamic volume of Aβ_1-42 in the presence of arginine measured by size exclusion chromatography show that arginine binds to Aβ_1-42. Arginine increases the solubility of Aβ_1-42 peptide in aqueous medium. It decreases the aggregation of Aβ_1-42 as observed by atomic force microscopy.

Conclusions

Based on our experimental results we propose that molecular clusters of arginine in aqueous solutions display a hydrophobic surface by the alignment of its three methylene groups. The hydrophobic surfaces present on the proteins interact with the hydrophobic surface presented by the arginine clusters. The masking of hydrophobic surface inhibits protein-protein aggregation. This mechanism is also responsible for the hydrotropic effect of arginine on various compounds. It is also explained why other amino acids fail to inhibit the protein aggregation.     

Improved performance of column chromatography by arginine: dye-affinity chromatography

Arginine has been effectively used in various column chromatographies for improving recovery and resolution, and suppressing aggregation. Here, we have tested the effectiveness of arginine as an eluent in dye-affinity column chromatography using Blue-Sepharose, which binds enzymes requiring adenyl-containing cofactors (e.g., NAD). A common eluent, NaCl, showed a broad elution peak with low recovery of lactate dehydrogenase, at most approximately 60% using 2M salt. The recovery decreased as the NaCl concentration was either decreased or increased; i.e., the recovery was maximum at 2M. On the contrary, addition of arginine to the eluent resulted in more than 80% recovery above 0.5M and the recovery was nearly independent of the arginine concentration. The elution peak was much sharper with arginine, leading to elution of more concentrated protein solution. Successful elution of proteins bound to the ATP-agarose resins by arginine was also described.     

Oxidative refolding of rPA in l‐ArgHCl and in ionic liquids: A correlation between hydrophobicity,salt effects,and refolding yield

The ionic liquid 1‐ethyl‐3‐methyl imidazolium chloride (EMIM Cl) and the amino acid l‐ arginine hydrochloride (l ‐ArgHCl) have been successfully used to improve the yield of oxidative refolding for various proteins. However, the molecular mechanisms behind the actions of such solvent additives—especially of ionic liquids—are still not well understood. To analyze these mechanisms, we have determined the transfer free energies from water into ionic liquid solutions of proteinogenic amino acids and of diketopiperazine as peptide bond analogue. For EMIM Cl and 1‐ethyl‐3‐methyl imidazolium diethyl phosphate, which had a suppressive effect on protein refolding, as well as for l ‐ArgHCl favorable interactions with amino acid side chains, but no favorable interactions with the peptide backbone could be observed. A quantitative analysis of other ionic liquids together with their already published effects on protein refolding showed that only solvent additives within a certain range of hydrophobicity, chaotropicity and kosmotropicity were effective for the refolding of recombinant plasminogen activator. © 2014 Wiley Periodicals, Inc. Biopolymers 101: 1129–1140, 2014.     

外源精氨酸对谷氨酸棒杆菌在高葡萄糖胁迫下生长和发酵特性的影响

【目的】探究外源添加不同氨基酸和相容性溶质对谷氨酸棒杆菌(Corynebacterium glutamicum)在高糖胁迫环境下生长的影响及可能的作用机理。【方法】通过在培养基中外源添加各种氨基酸和相容性溶质,研究其对谷氨酸棒杆菌在高葡萄糖和高蔗糖胁迫下生长的影响,并分析添加精氨酸对高葡萄糖胁迫下菌株糖转运和代谢途径中关键酶转录水平的影响,以及对菌株发酵产氨基酸的影响。进一步探究了碱性氨基酸在其它棒状杆菌属中抵御高葡萄糖胁迫的潜在作用。【结果】在高葡萄糖胁迫条件下,外源添加赖氨酸、精氨酸和组氨酸后谷氨酸棒杆菌的生物量分别提高54.7%、50.0%和37.6%;而在高蔗糖胁迫条件下,添加脯氨酸和四氢嘧啶后菌株生物量增加20%以上。进一步研究表明,在高葡萄糖胁迫下,外源添加精氨酸后谷氨酸棒杆菌的葡萄糖利用速率提高约2.5倍,谷氨酸的发酵产量也增加了127.5%。此外,碱性氨基酸对其它4种棒状杆菌也具有一定的渗透保护效应。【结论】精氨酸对谷氨酸棒杆菌在高葡萄糖胁迫下具有良好的渗透保护作用,可能归因于其能促进葡萄糖的转运和代谢能力,同时发现碱性氨基酸的渗透保护效应对棒状杆菌属具有一定的普遍性。