Intermolecular Exchange and Stabilization of Recombinant Human alpha A- and alpha B-Crystallin*

Tian-Xiao Sun and Jack J.-N. LiangDagger

From the Center for Ophthalmic Research, Brigham and Women's Hospital, and Department of Ophthalmology, Harvard Medical School, Boston, Massachusetts 02115

    ABSTRACT
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Abstract
Introduction
Procedures
Results
Discussion
References

Lens alpha -crystallin subunits alpha A and alpha B are differentially expressed and have a 3-to-1 ratio in most mammalian lenses by intermolecular exchange. The biological significance of this composition and the mechanism of exchange are not clear. Preparations of human recombinant alpha A- and alpha B-crystallins provide a good system in which to study this phenomenon. Both recombinant alpha A- and alpha B-crystallins are folded and aggregated to the size of the native alpha -crystallin. During incubation together, they undergo an intermolecular exchange as shown by native isoelectric focusing. Circular dichroism measurements indicate that the protein with a 3-to-1 ratio of alpha A- and alpha B-crystallins has the same secondary structure but somewhat different tertiary structures after exchange: the near-UV CD increases after exchange. The resulting hybrid aggregate is more stable than the individual homogeneous aggregates: at 62 °C, alpha B-crystallin is more susceptible to aggregation and displays a greater light scattering than alpha A-crystallin. This heat-induced aggregation of alpha B-crystallin, however, was suppressed by intermolecular exchange with alpha A-crystallin. These phenomena are also observed by fast performance liquid chromatography gel filtration patterns. The protein structure of alpha B-crystallin is stabilized by intermolecular exchange with alpha A-crystallin.

    INTRODUCTION
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Abstract
Introduction
Procedures
Results
Discussion
References

alpha -Crystallin is an oligomer protein of two subunits, alpha A and alpha B, in a ratio of 3 to 1 for most mammalian lenses. The alpha A- and alpha B-crystallins are differentially expressed in the lenses of humans and most other mammalian species; alpha B-crystallin appears earlier than alpha A-crystallin and is dominant in epithelial cells, but the alpha A-to-alpha B ratio increases with differentiation (1-4). The significance of the differential expression is not clear. Moreover, how the two subunits interchange after expression and the significance of the 3-to-1 ratio are also not well established.

The rather high concentration of alpha -crystallin in the lens and its extremely high thermostability (5) may be crucial in the protection against aggregation of beta - and gamma -crystallins. But how the thermostability is achieved is not fully understood. One possibility is through an intermolecular exchange that results in a dynamic quaternary structure. The observation that alpha -crystallin is the major crystallin in the lens HMW1 aggregates and water-insoluble fraction (6) may arise from some mechanisms that cause the loss of this dynamic quaternary structure.

In vitro study of alpha -crystallin has been handicapped by the fact that alpha -crystallin and its two subunits, especially isolated from human lenses, are already extensively modified and are difficult to obtain in their pure, native state. Previously, the two subunits were isolated from alpha -crystallin under denatured conditions and were unable to refold to the native state. The use of recombinant DNA technology to clone human alpha -crystallin has largely solved these problems (7-10). We have recently prepared both recombinant human alpha A- and alpha B-crystallins and performed a comparative study between them (10). The recombinant alpha A- and alpha B-crystallins exist in solution as homo-oligomers of molecular mass ~600 kDa (10). In this report, we present evidence of the interoligomeric exchange of the alpha A- and alpha B-crystallins and the stabilization of protein structure by subunit interchange. The biological significance of the 3-to-1 ratio of alpha A and alpha B subunits in vivo is discussed.

    EXPERIMENTAL PROCEDURES
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Abstract
Introduction
Procedures
Results
Discussion
References

Materials-- Recombinant human alpha A- and alpha B-crystallins were prepared from a cDNA library of human lens epithelial cells, kindly provided by Dr. Toshimich Shinohara. The procedures for cloning, expression, and protein purification have been described previously (10). Proteins in 0.05 M phosphate buffer, pH 7.4, were used in all measurements unless otherwise stated. Protein concentrations were determined by calculated extinction coefficients based on a protein amino acid sequence as described by Mach et al. (11). The amino acid sequences for human lens alpha A- and alpha B- subunits were published previously (12, 13). The Pierce bicinchoninic acid (BCA) assay was used to determine protein concentrations in the previous report (10). Protein concentrations determined by extinction coefficient are considerably greater than those determined by BCA assay.

Human infant lenses were obtained as surgical discards from patients with retinopathy of prematurity (Dr. Tatsuo Hirose, Massachusetts Eye and Ear Infirmary). alpha -Crystallin was isolated by gel filtration in FPLC (14).

Intermolecular Exchange Probed by IEF-- Exchange between alpha A and alpha B was studied with a fixed ratio (1:1) (concentration of each, 1 mg/ml) at various incubation times and with various ratios at a fixed incubation time at 37 °C. IEF was performed on precast IsoGel-agarose IEF gels (pH range, 3-10; FMC BioProducts, Rockland, ME) under native conditions. Gels were stained with Coomassie Brilliant Blue R-250.

CD Measurements-- Protein secondary and tertiary structural changes were investigated by far- and near-UV CD measurements in an Aviv circular dichroism spectrometer (model 60 DS) (15, 16). The reported CD spectra are the average of five scans, smoothed by polynomial curve fitting. The fit was checked with a statistical test so that the original data were not oversmoothed. The CD data were expressed as molar ellipticity in degrees cm2 dmol-1.

Light-scattering Measurement-- Conformational stability was determined by treatment with heat (17). Aggregation induced by heat was measured by light scattering in a Shimadz fluorometer (model RF-5301PC). Briefly, a protein solution of alpha A- or alpha B-crystallin or mixtures of various ratios were incubated at 37 °C for 36 h. Light scattering was measured at 62 °C maintained by a Brinkmann Lauda circulator (model RCS-6). Preliminary measurements at temperatures lower and higher than 62 °C were also made, but under these temperatures aggregation was either too slow or too fast. Scattering intensity was recorded for 20-60 min with the instrument set at the same excitation and emission wavelength (400 nm).

FPLC Gel Filtration-- Aggregation or change in quaternary structure was studied with FPLC gel filtration on a Superose-6 column (Pharmacia-LKB FPLC system) (14). Protein solutions (alpha A- or alpha B- or 3-to-1 mixtures; 1 mg/ml) were heated to 62 °C for 20 min and then cooled to room temperature. The samples were filtered (0.45 µM), and the absorption reading indicated no loss of any sample due to preincubation. Then the samples were applied to Superose-6 column, and a fraction of 1 ml was collected in each tube with an eluting rate of 0.3 ml/min.

    RESULTS
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Abstract
Introduction
Procedures
Results
Discussion
References

Intermolecular Exchange between alpha A- and alpha B-Crystallins

IEF Study-- IEF shows that there was a time-dependent exchange between alpha A- and alpha B-crystallin subunits at 37 °C (Fig. 1A). The exchange was faster at 37 °C than at 25 °C (data not shown). The original alpha A and alpha B bands became blurred with time, and eventually only one band was observed; a steady-state was reached after incubation for 30 h. The focusing pattern did not change upon further incubation. It should be noted that IEF of alpha -crystallin in the native state showed a broad band possibly because of microheterogeneity in the charge or structure. Similar IEF patterns were observed by van den Oetelaar et al. (18) in an exchange study using calf lens alpha A- and alpha B-crystallins.


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Fig. 1.   IEF of alpha A- and alpha B-crystallins under native conditions. A, time-dependent interchange: lane 1, markers; lane 2, alpha A-crystallin; lane 8, alpha B-crystallin; and lanes 3-7, mixture of alpha A and alpha B at 1-to-1 ratio (concentration of each 1 mg/ml) incubated at 37 °C for 0, 3, 9, 33, and 80 h. B, samples of alpha A- and alpha B-crystallin mixture with various ratios (total concentration 2 mg/ml) incubated at 37 °C for 80 h. Lane 1, markers; lane 2, alpha A only; lane 7, alpha B only; lanes 3-6, alpha A and alpha B mixtures with ratios of 6:1, 2:1, 1:2, and 1:4, respectively.

The intermolecular exchange occurred with any ratio of the two subunits. Fig. 1B shows the focusing pattern of mixtures with various alpha A- and alpha B-crystallin ratios after incubation for 80 h at 37 °C. The newly formed hybrid aggregates displayed one band with characteristic pI values that are the number average of the pI values of the initial two components.

CD Study-- CD of far- and near-UV regions was measured for the 3-to-1 ratio samples of alpha A- and alpha B-crystallins before and after exchange. The exchange was induced by incubation at 37 °C for more than 30 h, which IEF indicated a complete exchange. The lack of change in far-UV CD (data not shown) but an increase of near-UV CD (Fig. 2) indicates that intermolecular exchange causes no gross structural change. An increase of near-UV CD usually indicates that the protein structure has became more compact. The controls and alpha A- or alpha B-crystallin alone did not show a CD increase. Near-UV CD of alpha -crystallin isolated from human infant lenses was included in Fig. 2 for comparison; it does not overlap completely with that of 3alpha A-1alpha B-crystallin. Apparently, either in vivo and in vitro intermolecular exchanges are different or some modifications had already occurred in the human lens sample.


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Fig. 2.   Effect of exchange on near-UV CD of 3alpha A-to-1alpha B ratio mixture. The measurements were made before (bullet ------bullet ) and after (open circle ------open circle ) exchange. The exchange was induced by incubation at 37 °C for 30 h. Human infant lens alpha -crystallin (square ------square ) was included for comparison. Protein concentration is 1.5 mg/ml, and cell path length is 10 mm.

Thermal Aggregation of alpha A- and alpha B-Crystallins

Light-scattering Study-- Fig. 3A shows the scattering intensity at 62 °C for alpha A- and alpha B-crystallin and for mixtures of various ratios of alpha A to alpha B with a fixed concentration of alpha B-crystallin. The samples were incubated at 37 °C for 30 h to ensure a complete exchange between alpha A and alpha B subunits. alpha B-Crystallin alone displayed an increasing intensity with time, but the intensity of alpha A-crystallin alone increased very little, indicating that alpha B-crystallin was more susceptible to aggregation. The addition of alpha A-crystallin to alpha B-crystallin suppressed aggregation, and the extent of suppression increased with increasing amounts of alpha A-crystallin until a 3-to-1 ratio was reached. Further increase in alpha A-crystallin decreased the suppression; the sample of 3-to-1 ratio was the most stable aggregate. Fig. 3B is a summary of the scattering measurements with the y axis as maximal change of slope in the light-scattering curves. These results may indicate that alpha A-crystallin stabilizes alpha B-crystallin from heat-induced aggregation. The aggregation shown in Fig. 3A may not be in a final state of equilibrium; the scattering intensity may continue to increase if further incubation is undertaken. Our purpose was to compare the initial responses by these samples, from which we may infer their thermostability.


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Fig. 3.   Light-scattering measurements of alpha -crystallins. A, some representative light-scattering curves of alpha A- and alpha B-crystallin and mixtures. The samples were brought to 62 °C, and the intensities were recorded with the fluorometer set at 500 nm for both excitation emission wavelengths. The concentration of alpha B-crystallin was fixed at 0.1 mg/ml. B, the slopes of the light-scattering curves. Data are the average of two measurements.

CD Study-- Tertiary structural change was monitored by near-UV CD; Fig. 4 shows that CD intensity decreased and became negative in the whole near-UV region for the 3alpha A-1alpha B hybrid protein at a high temperature (62 °C). Upon cooling to room temperature, the original intensity was not restored, and the CD spectrum was almost the same as that at 62 °C. The irreversible change was also observed previously in calf alpha -crystallin samples (17). The decreased near-UV CD may reflect the loosening of protein structure by partial unfolding. Similar decreased CD was observed for homo-protein alpha A-crystallin (data not shown), but alpha B-crystallin became completely cloudy after incubation under the same conditions and needed to be filtered before measurement. After the insoluble fraction was removed, protein concentration was determined again; alpha B-crystallin displayed a similar CD decrease (data not shown).


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Fig. 4.   Heating effect on near-UV CD of 3alpha A-to-1alpha B mixture. Measurements were made initially at 25 °C (bullet ------bullet ), heated to 62 °C (open circle ------open circle ), and then cooled to 25 °C (open circle ------open circle ). The CD spectrum measured at 62 °C overlapped with that after cooled to 25 °C. The samples were heated for 60 min to reach temperature equilibrium before the measurements. Protein concentration is 1.5 mg/ml, and cell path length is 10 mm.

FPLC Gel Filtration-- To determine whether increased scattering intensity of alpha -crystallin at 62 °C is really due to aggregation, FPLC gel filtration was performed. The samples were preincubated at 62 °C for 20-60 min and then cooled to room temperature before being applied to the column. Preliminary results of alpha A and alpha B of the present study and our previous study of calf lens alpha -crystallin (17) indicate that the extent of FPLC change is dependent on incubation temperature and time. The data we present here are fixed in both parameters (preincubation at 62 °C and for 20 min) so a comparison can be made. Fig. 5 shows that the peak position for alpha A-crystallin shifted very little after heating, but the peak position for alpha B-crystallin shifted to a higher molecular weight, and some HMW aggregates were eluted at void volume. The peak shift for the 3alpha A-to-1alpha B mixture was slightly greater than that of alpha A-crystallin but less than that of alpha B-crystallin, and no HMW aggregate was observed at void volume.


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Fig. 5.   FPLC gel filtration profiles for alpha A- and alpha B-crystallin and 3alpha A-to-1alpha B mixture. The samples (1 mg/ml) were preincubated at 62 °C for 20 min and cooled to room temperature before application to the Superose-6 column (designated as 62 °C). The controls were not preincubated and were designated as 25 °C. The flow rate is 0.3 ml/min. The values at the top are the molecular weights of the markers.

    DISCUSSION
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Abstract
Introduction
Procedures
Results
Discussion
References

The intermolecular exchange between alpha A- and alpha B-crystallin subunits was demonstrated by IEF in the native state. Similar results have been reported (18), but the alpha A- and alpha B-crystallins used were isolated from bovine lenses under denatured conditions, and they were not properly reconstituted (19). Furthermore, the significance of the exchange was not clearly established. Our use of recombinant alpha A- and alpha B-crystallins, which are folded in the native form (10), should yield results more relevant to physiological conditions. Although exchange occurs in alpha A/alpha B samples with any ratios, a 3-to-1 ratio appears to be most thermostable. Results of heat-induced aggregation indicate that alpha A-crystallin is thermally more stable than alpha B-crystallin, probably because of alpha B's greater hydrophobicity (10). Hydrophobic interaction makes an important contribution to protein folding at low temperatures, but the hydrophobic entropy decreases as the system becomes enthalpy-driven at high temperatures. Thus, in vitro or in vivo aggregation between alpha A- and alpha B-crystallin (formation of an 600-800-kDa aggregate with a 3-to-1 ratio) may result from a stabilization effect of alpha A-crystallin on alpha B-crystallin. The slight shift in the FPLC peak for alpha A and the 3-to-1 mixture preincubated at 62 °C (Fig. 5) may be due to partial unfolding, which is also apparent in near-UV CD measurements (Fig. 4). This has been reported in the calf lens alpha -crystallin (17), but the present study indicates that only recombinant alpha B-crystallin undergoes heat-induced HMW aggregation. The notion of stabilization of alpha B by alpha A was recently demonstrated by a study of alpha A-knockout mice (20). Mice with the targeted disruption of the alpha A gene developed lens opacification starting from the nucleus and showed dense inclusion bodies that contain mostly alpha B.

The significance of the intermolecular exchange between alpha A- and alpha B-crystallin is its stabilization of the protein structure. But how this stabilization is achieved is difficult to speculate, since we do not know alpha -crystallin tertiary and quaternary structures; alpha -crystallin could not be crystallized for x-ray diffraction study. None of the structural models previously proposed, such as the original or modified three-layer model (21, 22), the micelle-like structure (23), or the overlapping two-annulus model (24), can explain the experimental data. It is obvious that the 3-to-1 ratio provides a balance in charge and hydrophobicity that stabilizes the protein structure, but a more definite explanation cannot be attained until the tertiary structure is determined. The near-UV CD clearly indicates that hybrid aggregate has a more compact structure than either alpha A- or alpha B-crystallin homo-oligomers. The difference of near-UV CD spectra between in vitro formed 3alpha A-to-1alpha B hybrid aggregate and the human infant lens alpha -crystallin may indicate that they do not have exactly the same tertiary structure, probably either because of different folding and aggregation between in vitro and in vivo conditions or because of modifications in the human lens alpha -crystallin and lack of modifications in the recombinant alpha -crystallin. The difference is most pronounced in the 290-nm bands, which originate from tryptophan transition, 1Lb (15, 25). The red shift of the band in the human lens alpha -crystallin from recombinant alpha -crystallin (from 292 to 295 nm) indicates that Trp residues in the human lens alpha -crystallin are more buried than in the recombinant alpha -crystallin (15, 26). It is difficult to tell what causes this shift, but it is most likely due to a different folded structure (either tertiary or quaternary structure); the shape of near-UV CD spectrum of human lens alpha -crystallin is very different from that of recombinant alpha -crystallin.

The protective binding of alpha -crystallin to the partially unfolded beta - and gamma -crystallins was reported in in vitro experiments (27, 28). Since no subsequent release of the bound substrate was observed, we should expect plenty of alpha -beta and alpha -gamma complexes in the lens, especially in the aged lens nucleus where modification-related partial unfolding is extensive. Instead of dimers, such as alpha -beta and alpha -gamma , HMW complexes were observed (29). In human lenses, the major component of the soluble HMW and insoluble proteins is alpha -crystallin; beta - and gamma -crystallins are the minor components (6). The chaperone complex formation cannot completely explain this phenomenon (19). Therefore, the question arises: why does alpha -crystallin, whose apparent function is to protect other crystallins from aggregation and denaturation, itself become aggregated and insoluble? Since alpha -crystallin has been shown to be thermally very stable (5), thermal denaturation and aggregation are unlikely to be responsible for insolubilization. Another possible unfolding mechanism is post-translational modification. Lens crystallins have a long half-life and can accumulate a variety of modifications. Although alpha -crystallin is thermally more stable than beta - or gamma -crystallin, it is not more stable in the presence of urea (30, 31); alpha -crystallin is totally unfolded in 6-7 M urea or 2.5 M guanidine HCl, but M guanidine HCl is required for gamma -crystallin to be completely unfolded. Therefore, alpha -crystallin may be more susceptible to modification-induced structural perturbation than gamma -crystallin, which may lead to HMW aggregation and insolubilization. It is possible that when alpha A-crystallin is extensively modified, it fails to stabilize alpha B-crystallin. Recently, we have observed an extensive modification in urea-soluble alpha -crystallin of human lenses; IEF and reverse-phase FPLC showed a greater extent of modification in the alpha A subunit than in the alpha B subunit.2

In conclusion, we have demonstrated that lens alpha -crystallin subunits alpha A and alpha B undergo intermolecular exchange, which stabilizes protein conformation. The hybrid aggregate with a 3-to-1 ratio is the most stable combination and may explain why most mammalian lenses contain this ratio of alpha -crystallin subunits.

    FOOTNOTES

* This work was supported by National Institutes of Health Grant EY 05803 and a grant from the Massachusetts Lions Research Fund, Inc.The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

Dagger To whom correspondence should be addressed: Center for Ophthalmic Research, 221 Longwood Ave., Boston, MA 02115. Tel.: 617-278-0559; Fax: 617-278-0556; E-mail: jliang{at}bustoff.bwh.harvard.edu.

1 The abbreviations used are: HMW, high molecular weight; FPLC, fast performance liquid chromatography; IEF, isoelectric focusing.

2 T.-X. Sun and J. J.-N. Liang, unpublished data.

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Abstract
Introduction
Procedures
Results
Discussion
References

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