Chaperone Function of Rat Lens α-Crystallin

A solution of γ-crystallin became turbid upon beating at 65 °C for 30 minutes; however, addition of α-crystallin suppressed this thermal aggregation. It was found the effective chaperone function could be achieved with the molar ratio of α/γ greater than 1/20. In terms of crystallin subunit, five molecular α-crystallin subunits could afford chaperone for one molecular γ-crystallin. The gel filtration profile of the sample solution, containing α- and γ-crystallins and preincubation at 65 °C for 30 minutes, showed complex formation between α- and γ-crystallins, indicating α-crystallin was bound to thermally denatured γ-crystallin. A 1-anilinonaphthalene-8-sulfonic acid (ANS) fluorescence study showed that α-crystallin has more hydrophobic regions exposed after thermal incubation. In the presence of urea, both the α-crystallin chaperone activity and the ANS fluorescence intensity decreased. Accordingly, hydrophobic regions of α-crystallin play an indispensible role in its chaperone activity.     

THE MOLECULAR CHAPERONE FUNCTION OF α-CRYSTALLIN IS IMPAIRED BY UV PHOTOLYSIS

Buffer solutions of the lens protein γ-crystallin and the enzymes aldolase and liver alcohol dehydrogenase became turbid and formed solid precipitate upon exposure to an elevated temperature of 63°C or to UV radiation at 308 nm. When α-crystallin was added to the protein solutions in stoichiometric amounts, heat or UV irradiation did not cause turbidity, or turbidity developed much less rapidly than in the absence of α-crystallin. Hence, normal α-crystallin functioned as a molecular chaperone, providing protection against both UV and heat-induced protein aggregation. When α-crystallin was preirradiated with UV at 308 nm, its ability to function as a chaperone vis-a-vis both UV and heat-induced aggregation was significantly impaired, but only at relatively high UV doses. A major effect of preirradiation of α-crystallin was to cause interpeptide crosslinking among the αA₂ and αB₂ subunits of the α-crystallin macromolecule. In our experiments α-crystallin was exposed to UV doses, which resulted in 0, 50 and 90% crosslinking as judged by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. α-Crystallin samples that were 50% and 90% crosslinked gave chaperone protection, which was increasingly impaired relative to unirradiated α-crystallin. The results are consistent with the notion that UV irradiation of α-crystallin results in loss of chaperone binding sites.     

CHANGES IN TERTIARY STRUCTURE OF CALF-LENS α-CRYSTALLIN BY NEAR-UV IRRADIATION: ROLE OF HYDROGEN PEROXIDE

The effect of 300 nm irradiation on the three lens crystallins, α-, β-, and γ-, was studied by using fluorescence and circular dichroism techniques. α-Crystallin showed a pronounced change in tertiary structure as manifested in fluorescence and circular dichroism measurements. This finding is in agreement with our earlier findings that the tryptophan residues of α-crystallin are more exposed than those of the other two crystallins. The results of studies using inhibitors specific for the different active species of oxygen suggest that H₂O₂-mediated damage is involved in the change of tertiary structure of the proteins. Analyses of circular dichroism spectra indicate that, upon irradiation, the secondary structure of α-crystallin remains virtually unaltered, and that the change in tertiary structure results primarily from photoinduced damage to the tryptophan residues.     

pH-Induced conformational changes of BSA in fluorescent AuNCs@BSA and its effects on NCs emission

We investigated the pH-induced fluorescence changes of BSA-protected gold nanoclusters, Au₁₆NCs@BSA, and the corresponding conformational changes of ligand protein by fluorescence, circular dichrosim (CD) and IR spectral measurements. The studies presented here demonstrated that BSA in AuNCs@BSA underwent identifiable conformational changes on both the secondary and the tertiary structure levels. The results of CD and IR interpreted the significant change of second structures at extreme acidity and alkaline, where more unordered structures were gained. Of note was that the extreme alkaline (pH = 11.43) induced the changes from exposed to buried α-helices, which was different from the pH-induced structural changes of BSA. In addition, the large fluorescence intensity gap of tryptophan between AuNCs@BSA and native BSA indicated efficient energy transfer took place between BSA and AuNCs, implying that the gold core resided near tryptophan in BSA.     

Identification of Photooxidation Sites in Bovine α-Crystallin

Abstract— Because UV irradiation of proteins can produce reactive oxygen species and exposure to UV light has been implicated in cataractogenesis, the sites of photooxidation of bovine α-crystallin, a major lens protein with molecular chaperone activity, were identified using tandem mass spectrometry (MS/MS). Bovine α-crystallin was irradiated with UV light (293 nm) for 1, 4 and 8 h, digested with trypsin and analyzed by matrix-assisted laser de-sorption ionization, time-of-flight mass spectrometry (MALDI) to identify the oxidized sequences. Tryptic peptides were purified by reverse-phase HPLC and oxidized peptides were sequenced by MS/MS to determine the sites of oxidation. Tryptophan fluorescence decreased exponentially with increasing time of UV exposure and peptides containing residues 1-11 of α-crystallin and 1-11, 12-22 and 57-69 of α-crystallin were determined to be oxidized by shifts of 16 D or multiples of 16 Da above the mass of the unmodified peptide. The MALDI analysis revealed single oxidation of all four sequences, which increased with increasing time of UV exposure and possible double oxidation of α 12-22. The specific sites of photooxidation indicate that the N-terminal regions of α-and β-crystallin are exposed to an aqueous environment and are in the vicinity of tryptophan residues from neighboring subunits.     

Photosensitized Effects of Rose Bengal on Structure and Function of Lens Protein "Alpha-Crystallin"

The conformational changes of the bovine lens protein "α-crystallin" have been investigated in the presence of the photosensitizer Rose Bengal (RB), in the dark as well as after visible light irradiation. Absorption and fluorescence emission spectra of RB [5 × 10⁻⁶  m ] and Fourier transform-IR spectra of α-crystallin [5 mg mL⁻¹] were significantly altered upon RB α-crystallin complex formation. RB was found to bind to α-crystallin in a molecular pocket characterized by a low polarity, with Trp most likely involved in this interaction. The binding constant ( K _b) has been estimated to be of the order of 2.5 (mg/mL)⁻¹. The intrinsic fluorescence of α-crystallin was quenched through both dynamic and static mechanisms. Light-induced photosensitized effects showed structural modifications in α-crystallin, including tertiary and secondary structure (an increase in unordered structure) alterations. Notwithstanding those photoinduced structural variations detected in α-crystallin when complexed with RB, the protein still retains its ability to play the role of chaperone for β-crystallin.     

Polymer drying. V. Intramolecular-rotor fluorescence studies of evaporation from liquid-saturated poly(styrene-co-divinylbenzene)

The fluorescence intensity and residual weight of poly(styrene-co-divinylbenzene) saturated with a < 0.003M solution of a intramolecular-rotor-fluorescent probe-molecule in a volatile liquid were monitored simultaneously as the system evaporated at 23°C to virtual dryness. The “breakpoints” in the pattern for fluorescence increase coincided with the “breakpoints” in the kinetics of desorption with respect to the number, α_t of residual sorbed volatile molecules per phenyl group in the polymer, showing that both time-studies reflect the same physical changes in the system that occur reproducibly as α_t decreases monotonically through α′_s and α′_g the compositions that signal respectively incipient elimination of volatile molecules immobilized by adsorption to polymer, and incipient transition of the system from the rubbery state to the glassy state. The fluorescence intensity attained its asymptotic limit before α_t became equal to α_g the composition identified earlier to be that which marks completion of the transition to the glassy state.     

Steric Exclusion Liquid Chromatography Studies in Urea on the Denaturation of the Bovine Eye Lens Protein α-Crystallin

Abstract

Steric exclusion liquid chromatography in the presence of intermediate urea concentrations with lowangle laser light scattering detection was used to investigate the stepwise dissociation of the multimeric bovine eye lens protein α-crystallin. The change in the quaternary structure of α-crystallin as a function of increasing urea concentration clearly resembled dissociation by increasing alkaline pH, urea or guanidine-HC1 concentrations when studied by sedimentation velocity analysis. Next to native and native-like threelayer aggregates (M_r 6.5 ? 7.5 × 10⁵), the first dissociation products (two-layer molecules M_r 4 ? 5.5 × 10⁵), the second dissociation products (core molecules M_r 2.5 ? 3 × 10⁵), and monomeric subunits (M_r 20 000) could be characterized. In the range from 2.6 to 4.4 M urea, we found a gradual decrease in the proportion of the remaining three-layer aggregates and an increase in that of monomeric subunits. The fluorescence emission maxima showed increasing solvent exposure of the tryptophan residues going from three-layer aggregates to monomeric subunits. The subunit compositions for most dissosiation products did not significantly differ from that of native α-crystallin. The interpretation of earlier results on Sephacryl-S200 steric exclusion chromatography in 3.8 M urea appeared to be an oversimplification.     

CHANGE IN SULFHYDRYL GROUP MICROENVIRONMENT OF CALF LENS α-CRYSTALLIN BY 300 nm LIGHT

Abstract— The effect of 300 nm irradiation on the sulfhydryl groups of calf lens a-crystallin has been investigated by using specific, covalently bound fluorescent sulfhydryl probes 4–(N-iodoacetoxy)ethyl-N-methylamino-7-n-itrobenz-2-o-xa-1,3-d-iazole (IANBD), N-iodoacetyl-N'-(5-s-ulfo-l-naphthyl) ethylene-diamine (1,5 IAEDANS) and 5-i-odoacetamidofluorescein (IAF). The decrease in tryptophan fluorescence with time of irradiation of a-crystallin, is accompanied by a decrease in the fluorescence of the hydrophobic sulfhydryl label IANBD. In addition, the fluorescence of the surface-sulfhydryl label IAF increased in the irradiated a-crystallin. These results indicate that the sulfhydryl groups are in a more exposed (hydrophilic) environment in the irradiated protein than in the control, possibly because of partial unfolding of the protein. This result is confirmed by fluorescence lifetime measurements with IAEDANS. The decay curve of IAEDANS-α-crystallin has a major lifetime of 15.7 ns and a minor one of 24.6 ns. Upon irradiation, the lifetime of the major component decreases to 10.2 ns and that of the minor component to 21.7 ns. Denatured IAEDANS-α-crystallin has a single lifetime of 10.4 ns. These results show that the photoinduced damage to the tryptophan residues of α-crystallin alters the environment of the sulfhydryl groups and induces a change in the tertiary structure of the protein. Proximity of the cysteine residues to tryptophan in the tertiary structure of the protein may be an important determinant of their susceptibility to photoinduced change.     

Characterization of structural transitions from aqueous solution to a lipid phase for α-MSH

Fluorescence spectroscopy results show that the α-melanocyte-stimulating hormone peptide (α-MSH) interacts with acidic lipid vesicles. Detectable structural changes are concomitant with the passage of a tryptophan residue from aqueous to lipidic media. The observed multiexponential decay of fluorescence, rationalized as originating from three rotameric populations of the tryptophan residue, has been used together with a matrix algorithm to find the most probable conformational families of α-MSH in water and lipid environments. A model is discussed in which the same conformational families occur in various phases, although with different probabilities. A conformational family in which χ₁ of the Trp9 side chain is in the trans-rotameric conformation is shown to have structural features highly appropriate to interact with negatively charged biological membranes, which are also in accordance with previous molecular dynamics simulations and with structures engineered in α-MSH analogs that show an increased potency in biological essays. The gauche minus and gauche plus side-chain conformations of Trp9, on the other hand, yield conformations more likely to predominate in aqueous solution. NMR spectroscopy measurements of α-MSH analogs indicate the existence in aqueous solution of a β strand in the vicinity of Trp9. A similar structural feature was found in the present conformational analysis for the gauche minus and gauche plus side-chain rotamers of Trp9. © 1995 John Wiley & Sons, Inc.     

In Vitro Renaturation of Alkaline Family G/11 Xylanase via a Folding Intermediate: α-Crystallin Facilitates Refolding in an ATP-Independent Manner

In this study, alkaliphilic family G/11 xylanase from alkali-tolerant filamentous fungi Penicillium citrinum MTCC 6489 was used as a model system to gain insight into the molecular aspects of unfolding/refolding of alkaliphilic glycosyl hydrolase protein family. The intrinsic protein fluorescence suggested a putative intermediate state of protein in presence of 2 M guanidium hydrochloride (GdmCl) with an emission maximum of 353 nm. Here we studied the refolding of GdmCl-denatured alkaline xylanase in the presence and the absence of a multimeric chaperone protein α-crystallin to elucidate the molecular mechanism of intramolecular interactions of the alkaliphilic xylanase protein that dictates its extremophilic character. Our results, based on intrinsic tryptophan fluorescence and hydrophobic fluorophore 8-anilino-1- naphthalene sulfonate-binding studies, suggest that α-crystallin formed a complex with a putative molten globule-like intermediate in the refolding pathway of xylanase in an ATP-independent manner. A 2 M GdmCl is sufficient to denature alkaline xylanase completely. The hydrodynamic radius (R_H) of a native alkaline xylanase is 4.0, which becomes 5.0 in the presence of 2 M GdmCl whereas in presence of the higher concentration of GdmCl R_H value was shifted to 100, indicating the aggregation of denatured xylanase. The α-crystallin·xylanase complex exhibited the recovery of functional activity with the extent of ~43%. Addition of ATP to the complex did not show any significant effect on activity recovery of the denatured protein.     

CONFORMATIONAL CHANGES OF BOVINE LENS CRYSTALLINS IN A PHOTODYNAMIC SYSTEM

Abstract— Conformational changes of bovine lens crystallins in a photodynamic system generating singlet oxygen, have been investigated. The formation of intersubunit crosslinks was observed in all three classes (α-, β and γ-) of crystallins by irradiation in the presence of the photosensitizer methylene blue. Near-UV circular dichroism (CD) spectra of the crystallins were significantly altered by irradiation under these conditions, indicating changes in tertiary structure but the far-UV CD remained unchanged suggesting that the secondary structure ((β-sheet conformation) remains unchanged. Significant changes in the absorption and fluorescence spectra were also observed. Measurement of total sulfhydryl content showed a decrease of 27%, 50% and 37% for α-, β- and γ-crystallins respectively, after irradiation. Fluorescence lifetime measurements of N-iodoacetyl-N'-(5-sulfo-l-naphthyl)ethylenediamine-labeled crystallins showed a significant decrease of the lifetime of the major decay components of the label bound to sulfhydryl groups of α- and γ-crystallins, but showed no change in the microenvironment of the sulfhydryl groups of β-crystallin. The results are consistent with the microenvironments of the tryptophan and sulfhydryl groups predicted from sequence studies.     

DNA Interaction with PtCl<Subscript>2</Subscript>(LL) (LL = Chelating Diamine Ligand: <Emphasis Type="Italic">N</Emphasis>,<Emphasis Type="Italic">N</Emphasis>-Dimethyltrimethylendiamine) Complex

The [PtCl₂(LL)] complex, as a cisplatin derivative, which LL is diamine chelate ligand (N,N-dimethyltrimethylendiamine), was synthesized and characterized by elemental analysis (CHN) mass, ¹H, and ¹³C nuclear magnetic resonance techniques. Then the binding of this complex to calf thymus DNA was investigated by various physicochemical methods such as spectrophotometric, circular dichroism, spectrofluorometric, melting temperature, and viscosimetric techniques. Upon addition of the complex, important changes were observed in the characteristic UV–Vis bands (hypochromism) of calf thymus DNA, increase in melting temperature and some changes in specific viscosity. Also, the fluorescence spectral characteristics showed an increase in the fluorescence intensity of methylene blue–DNA solutions in the presence of increasing amounts of metal complex, indicating PtCl₂(LL) is able to displace the methylene blue bound to DNA but not as complete as intercalative molecules. The experimental results showed that the platinum complex is bound to DNA non-intercalatively, and an outside binding is the preferred mode of interaction.     

Resonance Energy Transfer in a Genetically Engineered Polypeptide Results in Unanticipated Fluorescence Intensity

The fluorescence intensity of a C-terminal acceptor chromophore, N-(7-dimethylamino-4-methyl coumarin (DACM), increased proportionally with 280 nm irradiation of an increasing number of donor tryptophan residues located on a β-sheet forming polypeptide. The fluorescence intensity of the acceptor chromophore increased even as the length of the β-sheet edge approached 256 Å, well beyond the Förster radius for the tryptophan–acceptor chromophore pair. The folding of the peptides under investigation was verified by circular dichroism (CD) and deep UV resonance Raman experiments. Control experiments showed that the enhancement of DACM fluorescence occurred concomitantly with peptide folding. In other control experiments, the DACM fluorescence intensity of the solutions of tryptophan and DACM did not show any enhancement of DACM fluorescence with increasing tryptophan concentrations. Formation of fibrillar aggregates of the substrate peptides prepared for the fluorescence studies was undetectable by thioflavin T (ThT) fluorescence.     

Electrochemical fluorescence switching properties of conjugated polymers composed of triphenylamine,fluorene, and cyclic urea moieties

The study of the electrochemical fluorescence switching properties of the conjugated copolymers containing fluorene, triphenylamine, and 1,3‐diphenylimidazolidin‐2‐one moieties is reported. The polymers show high fluorescence quantum yields, excellent thermal stability, and good solubility in polar organic solvents. While the polymer emits blue light under UV irradiation, the fluorescence intensity is quenched upon electrochemical oxidation. The fluorescent behavior can be reversibly switched between nonfluorescent (oxidized) state and strong fluorescence (neutral) state with a high contrast ratio (I_f/I_f0) of 16.3. The role of the electrochemical oxidation of the triphenylamine moieties is to generate the corresponding radical cations that lead to fluorescence quenching in the solid matrix. © 2012 Wiley Periodicals, Inc. J. Polym. Sci. Part A: Polym Chem, 2012     

THE GENERATION OF HYDROGEN PEROXIDE BY THE UVA IRRADIATION OF HUMAN LENS PROTEINS

Abstract— The water-insoluble proteins from aged human lens are known to contain protein-bound chromophores that act as UVA sensitizers. The irradiation of a sonication-solubilized, water-insoluble fraction from human lenses (55–75 years) with UVA light (1.5 kj/cm², λ > 338 nm) caused an oxygen-dependent photolysis of tryptophan, not seen when either α-crystallin or lysozyme were irradiated. The suggested requirement for active oxygen species was consistent with a linear increase in hydrogen peroxide formation, which was also observed. A final concentration of 55 µM H₂O₂ was attained, with no H₂0₂ being detected in either dark-incubated controls or in irradiated samples of native proteins. The UVA-dependent H₂O₂ formation was increased 50% by superoxide dismutase (SOD) and abolished by catalase, arguing for the initial generation of superoxide anion. A linear photolysis of histidine and tryptophan was also seen; however, the addition of SOD or SOD and catalase had no effect on the photolytic destruction of either amino acid. Superoxide dismutase increased the oxidation of protein SH groups implicating H₂O₂, but SOD and catalase caused a decrease in SH oxidation only at later time periods. The direct addition of H₂O₂ to a water-insoluble sonicate supernatant fraction caused only a slight oxidation of SH groups, but this was increased four- to eight-fold when the protein was denatured in 4.0 M guanidine hydrochloride. Overall, the data suggest a UVA-dependent oxidation of protein SH groups via H₂O₂ generated within the large protein aggregates of the water-insoluble fraction. These data also provide a mechanism for oxidation of the sulfur-containing amino acids in vivo—a process that is known to accompany the formation of age-onset cataracts.     

MONITORING LIGHT-INDUCED CHANGES IN ISOLATED, INTACT EYE LENSES

Fluorescence spectral changes occurring upon irradiation with 300 nm light have been monitored in situ in isolated, intact, whole lenses from the eyes of several species. The findings corroborate observations on other individual constituent protein molecules in the solution state, and also reveal features attributable to the supramolecular protein assembly that exists in the whole lens. Irradiation of the lens with 300 nm light causes red shifts in the tryptophan emission spectrum, suggesting alterations in the protein packing in the lens. Intermolecular energy transfer from tryptophan to one of the photoproducts, presumably N-formylkynurenine (N-FK), occurs in the condensed-phase sample. The N-FK formed is photodegraded efficiently in the lens, indicating that the photodynamic effects of endogenous N-FK might not be as severe as has been thought. Species variation in the photoevents are evident, particularly in avian lenses that contain the variant δ-crystallin as the core protein. The photoinduced changes in the near-UV circular dichroism of δ-crystallin (which is α-helical, as opposed to the β-sheet structure of α-, β-, and -γ-crystallins), isolated from chicken lenses, are remarkably different from other crystallins. Irradiation of δ-crystallin leads to a drastic reduction of circular dichroism intensity in the 250–300 nm region, whereas no changes are seen in the peptide absorption band.     

Effects of Divalent Metal Ions on the Chaperone Activity and Structure of Rat Lens H18G Mutant αB‐Crystallin

αB‐crystalin, a small heat shock protein and a component of α‐crystalin, is a molecular chaperone playing an important role in preventing the formation of cataracts. It has been reported that His18 is an important site for Cu²⁺ to bind with to form a stable metal complex and thus to enhance this chaperone‐like activity of human αB‐crystalin. In this work, we used site‐directed mutagenesis to clone and express H18G rat lens αB‐crystalin in order to investigate the role of His18 in chaperoning activity. We found that 1 mM of Cu²⁺, or Zn²⁺, rather than Mg²⁺, significantly enhanced the chaperone‐like activity of wild type αB‐crystalin. Whereas, it is Zn²⁺ and Mg²⁺, not Cu²⁺, that significantly reduced this activity of H18G αB‐crystalin. In the absence of cation, H18G showed better activity compared to the wild type αB‐crystalin. ANS fluorescence measurement showed there was no linear relationship between chaperone‐like activity and surface hydrophobicity, indicating that surface hydrophobicity is not a prerequisite for chaperone‐like activity. An HPLC size‐exclusion chromatography study showed that in the presence of metal ions, wild type αB‐crystalin tended to aggregate via dissociation and re‐association into a high molecular aggregate with a molecular weight higher than 1400 kDa and then precipitated, suggesting that the presence of metal ions is a factor leading to the formation of cataracts. Both the near and far UV‐CD spectra suggested that the wild type αB‐crystalin reflected more β‐sheet structural characteristics; whereas the H18G reflected more random coil characteristics. The H18G induced structural alterations as to develop more random coil characteristics and more micro‐environmental changes around the tryptophan residues. This work suggested that His18 may not be a crucial binding site for Cu²⁺, but rather that it may be an important binding site for Zn²⁺ in terms of chaperone‐like activity and the process of metal induced self‐aggregation is prerequisite for chaperone‐like activity to occur.     

Effect of the UV Modification of α-Crystallin on Its Ability to Suppress Nonspecific Aggregation

Recent studies have shown that structural modifications of α-crystallin during lens aging decrease it's effectiveness as a molecular chaperone. Some of these posttranslational modifications have been linked to UV radiation, and this study was undertaken to investigate the effect of UV irradiation on the ability of α-crystallin to suppress nonspecific aggregation. The effect of 3-hydroxykynurenine (3-HK) was also investigated as a model for its glucoside (3-HKG), a main lens chromophore that has been linked to photochemical changes in the human lens. Alpha- and γ-crystallin solutions (1 mg/mL, 1:0.125 wt/wt) were photolyzed (transmission above 295 nm) for various time intervals. Thermal denaturation of γ-crystallin with or without α-crystallin was carried out at 70°C and increases in light scattering were measured at 360 nm. We found that (1) irradiation of γ-crystallin increased its susceptibility to heat-induced scattering. The addition of α-crystallin protects it against thermal denaturation, although its ability to do so decreases the longer γ-crystallin is irradiated and (2) irradiation of α-crystallin decreases its ability to suppress nonspecific aggregation and the presence of 3-HK during irradiation decreases it further. Our results indicate that posttranslational modifications of α-crystallin due to UV irradiation affect the sites and mechanisms by which it interacts with γ-crystallin. The kinetics of γ-crystallin unfolding during thermal denaturation were also analyzed. We found that a simple two state model applies for nonirradiated γ-crystallin. This model does not hold when γ-crystallin is irradiated in the presence or absence of α-crystallin. In these cases, two step or multistep mechanisms are more likely.     

The Effect of Arg on the Structure Perturbation and Chaperone Activity of α-Crystallin in the Presence of the Crowding Agent,Dextran

α-Crystallin is a protein that is expressed at high levels in all vertebrate eye lenses. It has a molecular weight of 20 kDa and is composed of two subunits: αA and αB. α-Crystallin is a member of the small heat shock protein (sHsps) family that has been shown to prevent protein aggregation. Small molecules are organic compounds that have low molecular weight (<800 Da). Arginin (Arg) is a small molecule and has been shown to prevent protein aggregation through interaction with partially folded intermediates. In this study, the effect of Arg on the chaperone activity of α-crystallin in the presence of dextran, as a crowding agent, against ordered and disordered aggregation of different target proteins (α-lactalbumin, ovotransferrin, and catalase) has been investigated. The experiments were done using visible absorption spectroscopy, ThT-binding assay, fluorescence spectroscopy, and CD spectroscopy. The results showed that in amorphous aggregation and amyloid fibril formation, both in the presence and absence of dextran, Arg had a positive effect on the chaperone action of α-crystallin. However, in the presence of dextran, the effect of Arg on the chaperone ability of α-crystallin was less than in its absence. Thus, our result suggests that crowding interior media decreases the positive effect of Arg on the chaperone ability of α-crystallin. This is a very important issue, since we are trying to find a mechanism to protect living cells against the toxic effect of protein aggregation.