Packing-induced conformational and functional changes in the subunits of alpha -crystallin

The heteroaggregate alpha-crystallin and homoaggregates of its subunits, alphaA- and alphaB-crystallins, function like molecular chaperones and prevent the aggregation of several proteins. Although modulation of the chaperone-like activity of alpha-crystallin by both temperature and chaotropic agents has been demonstrated in vitro, the mechanism(s) of its regulation in vivo have not been elucidated. The subunits of alpha-crystallin exchange freely, resulting in its dynamic and variable quaternary structure. Mixed aggregates of the alpha-crystallins and other mammalian small heat shock proteins (sHSPs) have also been observed in vivo. We have investigated the time-dependent structural and functional changes during the course of heteroaggregate formation by the exchange of subunits between homoaggregates of alphaA- and alphaB-crystallins. Native isoelectric focusing was used to follow the time course of subunit exchange. Circular dichroism revealed large tertiary structural alterations in the subunits upon subunit exchange and packing into heteroaggregates, indicating specific homologous and heterologous interactions between the subunits. Subunit exchange also resulted in quaternary structural changes as demonstrated by gel filtration chromatography. Interestingly, we found time-dependent changes in chaperone-like activity against the dithiothreitol-induced aggregation of insulin, which correlated with subunit exchange and the resulting tertiary and quaternary structural changes. Heteroaggregates of varying subunit composition, as observed during eye lens epithelial cell differentiation, generated by subunit exchange displayed differential chaperone-like activity. It was possible to alter chaperone-like activity of preexisting oligomeric sHSPs by alteration of subunit composition by subunit exchange. Our results demonstrate that subunit exchange and the resulting structural and functional changes observed could constitute a mechanism of regulation of chaperone-like activity of alpha-crystallin (and possibly other mammalian sHSPs) in vivo.     

Secondary structure of detergent-solubilized phospholamban, a phosphorylatable, oligomeric protein of cardiac sarcoplasmic reticulum

The structure of phospholamban, a 30-kDa oligomeric protein integral to cardiac sarcoplasmic reticulum, was probed using ultraviolet absorbance and circular dichroism spectroscopy. Purified phospholamban was examined in three detergents: octyl glucoside, n-dodecyloctaethylene glycol monoether (C12E8) and sodium dodecyl sulfate (SDS). Ultraviolet absorption spectra of phospholamban reflected its aromatic amino acid content: absorption peaks at 275-277 nm and 253, 259, 265 and 268 nm were attributed to phospholamban's one tyrosine and two phenylalanines, respectively. Phospholamban phosphorylated at serine 16 by the catalytic subunit of cAMP-dependent protein kinase exhibited no absorbance changes when examined in C12E8 or SDS. Circular dichroism spectroscopy at 250-190 nm demonstrated that phospholamban possesses a very high content of alpha-helix in all three detergents and is unusually resistant to denaturation. Dissociation of phospholamban subunits by boiling in SDS increased the helical content, suggesting that the highly ordered structure is not dependent upon oligomeric interactions. The purified COOH-terminal tryptic fragment of phospholamban, containing residues 26-52 and comprising the hydrophobic, putative membrane-spanning domain, also exhibited a circular dichroism spectrum characteristic of alpha-helix. Circular dichroism spectra of phosphorylated and dephosphorylated phospholamban were very similar, indicating that phosphorylation does not alter phospholamban secondary structure significantly. The results are consistent with a two-domain model of phospholamban in which each domain contains a helix and phosphorylation may act to rotate one domain relative to the other.     

The reaction of citraconic anhydride with bovine alpha-crystallin lysine residues. Surface probing and dissociation-reassociation studies

Citraconic anhydride reacts readily with alpha-crystallin's lysine residues at pH 7.4. Upon addition of 2 equivalents of citraconic anhydride per equivalent lysine, 24% of the lysine residues were modified without disrupting the native quaternary structure. Further citraconylation led to dissociation into 10 S aggregates. Complete dissociation into subunits (1.4 S) occurred after adding 100 equivalents of citraconic anhydride, resulting in 98% modification. Decitraconylation did not lead to reaggregates identical with the native ones. The unmodified and the once and twice citraconylated alpha-crystallin subunits were discerned by isoelectric focusing according to their theoretical isoelectric points. In the native alpha-crystallin aggregates, nearly all B chains and approx. 60% of the A chains were found to possess at least one surface-exposed lysine residue. No differences between the susceptibilities to citraconylation of the in vivo deamidated (A1 and B1) and the de novo synthesized (A2 and B2) subunits were found. These results support the three-layer spherical assembly model for the alpha-crystallin quaternary structure.     

Changes in the molecular topography of the light and heavy chains of type A botulinum neurotoxin following their separation

Botulinum neurotoxin serotype A, an approx. 150 kDa protein, is composed of two subunits, the light and heavy chains (approximately 50 and approximately 100 kDa, respectively). The neurotoxin's mode of action is believed to depend on coordinated but independent actions of the two subunit chains. The molecular environments of the aromatic amino acid residues of the dichain neurotoxin and the two isolated subunit chains were analyzed using near-ultraviolet circular dichroism (CD) (between 250 and 320 nm) and second-derivative ultraviolet absorption spectroscopy (between 240 and 320 nm) to investigate the conformational variations of the subunit chains in separated and conjugated forms. The mean residue weight ellipticities showed virtually no change (i.e., 1.7%) in the vicinities of Phe (268 nm), and only a small change (11%) around Tyr (279 nm) residues following dissociation of the subunit chains. However, significant changes (23-26%) at 286 nm as well as at 292 nm were noted, suggesting considerable alteration in the conformation of the subunits. Second-derivative ultraviolet absorption spectra indicated the degree of Tyr exposure in the dichain neurotoxin, isolated heavy and light chains at 70.7, 81.5 and 46.4%, respectively. A weighted mean of the degree of exposed Tyr residues in the separated heavy and light chains was 69.6%, virtually same as the 70.7% exposed Tyr residues observed in the intact dichain neurotoxin, indicating no difference in their Tyr exposure upon separation of the two chains. This was corroborated by the CD data which revealed only small changes in the CD signals of Tyr residues, and no alteration in those of the Phe residues following separation of the subunit chains. However, a change in the CD signal at 292 nm suggested that the conformations of Trp-containing segments of the two chains were significantly influenced upon their separation. The heavy and light chains of the neurotoxin therefore appear to exist as two semi-independent domains, in spite of being linked by disulfide and noncovalent bonds, and at least part of their conformations depends on interactions between them.     

Identification by 1H NMR spectroscopy of flexible C-terminal extensions in bovine lens alpha-crystallin.

Two-dimensional 1H NMR spectroscopy of bovine eye lens alpha-crystallin and its isolated alpha A and alpha B subunits reveals that these aggregates have short and very flexible C-terminal extensions of eight (alpha A) and ten (alpha B) amino acids which adopt little preferred conformation in solution. Total alpha-crystallin forms a tighter aggregate than the isolated alpha A and alpha B subunit aggregates. Our results are consistent with a micelle model for alpha-crystallin quaternary structure. The presence of terminal extensions is a general feature of those crystallins, alpha and beta, which form aggregates.     

On the structure of alpha-crystallin: construction of hybrid molecules and homopolymers

The alpha A2 and alpha B2 subunits of bovine alpha-crystallin were purified by chromatofocussing in urea and assembled into homopolymers. Light-scattering measurements indicated their molecular masses were 360 and 420 kDa. The alpha A2 and alpha B2 polypeptides were also used to construct a series of hybrid molecules with alpha A/alpha B ratios ranging from 7:1 to 1:7. Sedimentation velocity analyses, isoelectric focussing under non-deaggregating conditions, circular dichroism spectroscopy and immunochemical analysis indicated that all of the subunits had copolymerized to alpha-crystallin-like aggregates with complete regeneration of the native structure. The polymers could be distinguished on the basis of their differing affinities for the antiserum. This was directly related to the proportion of alpha A2 subunits in each polymer. It was concluded that the alpha A2 and alpha B2 subunits are structurally equivalent and occupy equivalent site in the alpha-crystallin aggregates. It was also concluded that a micellar-like quaternary structure was consistent with most previous observations on the protein.     

Spectroscopic studies on human lens crystallins

Human lens crystallins were studied by absorption, circular dichroism and fluorescence spectroscopy. The absorption spectra in the near-ultraviolet region show some differences in intensity, but spectral features are similar, except for the alpha-crystallin, which gives a fine structure due to phenylalanine between 250 and 270 nm. Tryptophan fluorescence and near-ultraviolet circular dichroism indicate that tryptophan residues are more exposed in alpha-crystallin than in either beta- or gamma-crystallin, and that the degree of exposure decreases in the order of alpha less than beta 1 greater than beta 2 greater than beta 3 greater than gamma. The far ultraviolet CD suggests that these proteins exist mainly in a beta-sheet conformation and that the amount does not vary much among them. The greater exposure of the tryptophan residues in the high-molecular-weight crystallins may reflect greater unfolding in their protein domains. Spectroscopic measurements are thus useful in predicting protein tertiary structure in the absence of the complete sequence and X-ray data. The fact that the high-molecular-weight proteins exist in a more unfolded state may render them more vulnerable to exogeneous insults, and these effects may be studied by spectroscopic measurements.     

Study of the structure of the histidine decarboxylase of Micrococcus sp. n. by the method of circular dichroism]

Ring dichroism spectra (RD) of histidine decarboxylase (HDC) from Micrococcus sp. n. at the regions of peptide bonds (200-240 nm) and aromatic amino acids (250-300 nm) absorption are studied. The treatment of RD spectra according to methods of Greenfield-Fasman, Saksena-Vetlaufer and Mayer permits to conclude that at the pH range within 4-8 the content of ordered structures of alpha-helix type comprises 20%, that of beta-structure type-40%, while the rest 40% are represented with polypeptide chain in a disordered globular state. When pH is varied from 1 to 12, the content of alpha-helices decreases from 17 to 5%. There are two distinct dichroic bands in the spectrum of aromatic chromophores absorption (at 270 and 290 nm), the former containing tirosine, tryptophane and phenylalanine residues and the latter being induced with triptophane residues. The study of HDC RD spectra at the regions of peptide bonds and aromatic acids absorption at different temperatures has shown that a part of triptophane, tyrosine and phenylalanine residues is in an ordered structure of the alpha-helix type. The HDC undergoes irreversible changes under heating to 70 degrees and in 8 M urea. 5 M guanidine chloride eliminates the ordered HDC structure, while sodium dodecylsulphate at concentrations up to 1% does not affect the enzyme structure.     

A dynamic quaternary structure of bovine alpha-crystallin as indicated from intermolecular exchange of subunits

The structural bovine eye lens protein alpha-crystallin was dissociated in 7 M urea and its four subunits, A1, A2, B1, and B2, were separated by means of ion-exchange chromatography. Homopolymeric reaggregates of these subunits were prepared by removal of the denaturant via dialysis. It was found that subunits were exchanged upon incubation of mixtures of two homopolymers under native conditions. New hybrid species were formed within 24 h as demonstrated by isoelectric focusing. Moreover, native alpha-crystallin molecules also exchanged subunits when incubated with homopolymeric aggregates of B2 subunits. Subunit exchange between native alpha-crystallin molecules is postulated, and a "dynamic quaternary structure" is presented that allows the polydisperse protein to adapt to changes in cytoplasmic conditions upon aging of the lens tissue.     

Spectroscopic characterization of textilotoxin, a presynaptic neurotoxin from the venom of the Australian eastern brown snake (Pseudonaja t. textilis)

Spectroscopic behavior of textilotoxin, from the venom of Pseudonaja t. textilis, and its subunits were investigated using fluorescence, circular dichroism and Fourier transform infrared spectroscopy. Circular dichroism spectra of the B, C and D subunits indicate considerable similarity in their alpha-helix and beta-sheet contents. By contrast, the A subunit displays significantly more beta-sheet and 'remainder' structure. FTIR spectra confirm conclusions drawn from CD spectra. Fluorescence spectra indicate that, in general, tryptophan residues in the A, B and D subunits are relatively exposed to the solvent. The C subunit exhibits no fluorescence, suggesting a lack of tryptophan. Comparisons of individual subunit spectra with those of the intact toxin suggest that significant changes in secondary structure may occur when the toxin dissociates.     

Biophysical characterization of alpha-crystallin aggregates: validation of the micelle hypothesis.

The size of alpha-crystallin aggregates, as well as the structural organization of each particle's subunits, is currently unknown, although a number of different laboratories have suggested both structures and average molecular weights (Thomson, J.A. and Augusteyn, R.C. (1984) Proc. Int. Soc. Eye Res. 3, 152). One hypothesis, compatible with literature reports and consistent with what is known of subunit primary structure and physiological function, is that alpha-crystallin exists in vivo as a naturally occurring protein micelle (Sen, A.C. and Chakrabarti, B. (1991) Biophysical J. 59, 108a.) To test this hypothesis, experiments were performed on this protein to determine its behavior under increased hydrostatic pressure and the effect of its concentration on aqueous surface tension. With increasing hydrostatic pressure, the turbidity of an alpha-crystallin solution increases exponentially to a plateau at about 6000-8000 psi; upon release of pressure, the samples slowly return to their original turbidity level. Other naturally aggregating proteins, such as skeletal muscle myosin, demonstrate a decrease in turbidity under the same conditions. The surface tension of alpha-crystallin in aqueous solution decreases to a plateau with increasing protein subunit concentration, with an inflection point over the range 0.18-0.25 mM; cholate and other amphiphiles exhibit similar behavior. In contrast, plots of surface tension over the equivalent concentration range for other protein aggregates in the same buffer more closely approximate the types of curve obtained with short chain aliphatic acids. These results indicate that alpha-crystallin behaves like the protein version of a micelle.     

Oxygenation-linked changes in the ultraviolet absorption and circular dichroism spectra of spiny lobster hemocyanin

As an approach to elucidate the mechanism of the protein structure change in the cooperative ligand binding, the UV difference and CD spectra of aromatic residues in Panulirus japonicus (spiny lobster) hemocyanin were examined. The native hemocyanin showed an O2-induced narrow-banded change in the absorption spectrum around 290 nm, which was not affected by pH in the range of 7.5 to 9.5. When the native hexameric protein was stripped of divalent cations with EDTA (at pH 7.5), the magnitude of the narrow-banded difference was reduced to about half, whereas it was almost completely abolished on dissociation into subunits (stripped at pH 9.5). The magnitude of the absorption change was found to be proportional to the degree of O2 saturation in the native and stripped hemocyanins. It was inferred that the spectral difference reflects a tertiary structure change directly linked to the oxygenation, though it depends greatly on the subunit association. Panulirus hemocyanin showed negative CD bands in the region of 260 to 300 nm, the intensities of which were considerably reduced by oxygenation and also by dissociation into subunits.     

Circular-dichroism and absorption spectroscopic studies on specific aromatic residues involved in the different modes of aggregation of tobacco-mosaic-virus protein.

Conformational changes accompanying the different modes of aggregation of tobacco mosaic virus protein (TMV-protein) were investigated using circular dichroism (CD) and absorption difference spectra in the range of aromatic absorption. Comparing wild-type protein and mutant Ni 2068 (Tyr-139 leads to Cys-139) a tentative localization of aromatic amino acids in the three-dimensional structure is rendered possible. In all modes of aggregation the CD spectra are determined by intrasubunit interactions between aromatic residues, in particular Trp-17 and Trp-52 as well as Tyr-70, Tyr-72 and Tyr-139. The Trp-17-Trp-52 interaction was found to be highly sensitive towards changes of the quaternary structure especially with respect to helical aggregates. This suggests that the environment of the two tryptophan residues is of crucial importance in the three-dimensional structure of the subunit; in the course of aggregation intersubunit interactions compete with the specific intrasubunit Trp-17--Trp52 interactions. It is suggested that Try-70 and Tyr-72 form hydrogen bonds in a strongly hydrophobic environment. Formation of the double disc decreases the rotatory strength, pointing to an increase in conformational flexibility. Spectroscopic and chemical evidence prove that Tyr-70, Tyr-72 and Tyr-139 are in close neighbourhood. Double disc formation by lowering the pH (pH 8 LEADS TO 6.9, I = 0.1 M) or increasing the ionic strength (pH 8, I = 0.1 LEADS TO 0.6 M) is reflected by identical spectral effects in the environment of Tyr-70 - Tyr-72. However the interaction between Trp-17 and Trp-52 indicates significant differences in the conformation which may be important for the formation of higher aggregates, i.e. 'lockwashers', helices, and 'stacked discs'.     

Circular dichroism studies on coat proteins of some strains and mutants of tobacco mosaic virus

1. Tobacco mosaic virus (TMV) protein has in near ultraviolet a complex but well resolved circular dichroism (CD) spectrum at room temperature. There are seven positive bands at 248, 252, 257, 265, 274, 281 and 291 nm, and a negative one at 296 nm. The CD spectrum is pH-dependent. The shape of the pH-dependence curves and the comparison with CD spectra of model compounds suggest that the bands at 248, 252 and 257 nm are mainly caused by phenylalanyl, those at 265, 274 and 281 nm by tyrosyl, and those at 291 and 296 nm by tryptophanyl side chains. 2. Only insignificant changes of the tertiary structure seem to occur between pH 6.5 and 8.5. Changes in ellipticity of TMV protein during the pH-induced polymerization reaction suggest that: (1) tyrosyl residues are involved in the binding of subunits, (2) phenylalanyl residues seem to be transferred to a less rigid environment, and (3) tryptophanyl residues are not essential for the reaction. 3. The proteins of several TMV strains and mutants studied have similar far ultraviolet CD spectra and apparently do not differ significantly in their structure. Their near ultraviolet CD spectra are, however, different. Replacements involving aliphatic amino acids do not change considerably the near ultraviolet CD spectra. On the other hand, replacements involving aromatic amino acids have a great effect on the spectra rendering possible identification of CD bands and recognition of the aromatic amino acid residues responsible for optical activity.     

Self-complementary motifs (SCM) in alpha-crystallin small heat shock proteins

Small heat shock proteins (sHsp) have been implicated in many cell processes involving the dynamics of protein-protein interactions. Two unusual sequences containing self-complementary motifs (SCM) have been identified within the conserved alpha-crystallin domain of sHsps. When two SCMs are aligned in an anti-parallel direction (N to C and C to N), the charged or polar residues form either salt bridges or hydrogen bonds while the non-polar residues participate in hydrophobic interactions. When aligned in reverse order, the residues of these motifs in alpha-crystallin subunits form either hydrophobic and/or polar interactions. Homology based molecular modeling of the C-terminal domain of alpha-crystallin subunits using the crystal structure of MjHSP16.5 suggests that SCM1 and 2 participate in stabilizing secondary structure and subunit interactions. Also there is overwhelming evidence that these motifs are important in the chaperone-like activity of alpha-crystallin subunits. These sequences are conserved and appear to be characteristic of the entire sHsp superfamily. Similar motifs are also present in the Hsp70 family and the immunoglobulin superfamily.     

Structural studies on aqueous and hydroalcoholic solutions of a polyene antibiotic: Amphotericin B

Circular dichroism and absorption and light scattering have been used to study the effect of ethyl alcohol on an aqueous solution of Amphotericin B (“Fungizone”), which is an antifungal heptene. In aqueous solution, light-scattering studies show that Amphotericin B exists in an aggregated form. The estimated mass of these aggregates is about 2 × 10⁶ daltons, representing about 2000 molecules. Since the aggregated form is high molecular weight and scattering, the CD involves probably the differential scattering of right and left polarized light. In aqueous solution, Amphotericin B exhibits a strong dissymetric couplet in CD at the wavelength of the absorption maximum (328 nm). This latter maximum presents a blue shift when compared with the normal absorption in polar organic solvents. In hydroalcoholic solutions, for alcohol concentrations below 35%, the molecular weight of the aggregates is unchanged, while the absorption and CD spectra are modified. For alcohol concentrations greater than 35%, the aggregates mass decreases quickly and becomes undetectable at 50% ethyl alcohol concentration. For these solutions, the CD and absorption spectra are practically constant and characteristic of unaggregated Amphotericin B form.     

Orientation of the bases of single-stranded DNA and polynucleotides in complexes formed with the gene 32 protein of bacteriophage T4. A linear dichroism study

Linear dichroism measurements were performed in the wavelength region 250 to 350 nm on complexes between the single-stranded DNA binding protein of bacteriophage T4 (gp32) and single-stranded DNA and a variety of homopolynucleotides in compressed polyacrylamide gels. The complexes appeared to orient well, giving rise to linear dichroism spectra that showed contributions from both the protein aromatic residues and the bases of the polynucleotides. In most cases the protein contribution appeared to be very similar, and the linear dichroism of the bases could be explained by similar orientations of the bases for most of the complexes. Assuming a similar, regular structure for most of the polynucleotides in complex, only a limited set of combinations of tilt and twist angles can explain the linear dichroism spectra. These values of tilt and twist are close to (-40 degrees, 30 degrees), (-40 degrees, 150 degrees), (40 degrees, -30 degrees) or (40 degrees, -150 degrees), with an uncertainty in both angles of about 15 degrees. Although the linear dichroism results do not allow a choice between these possible orientations, the latter two combinations are not in agreement with earlier circular dichroism calculations. For the complexes formed with poly(rC) and poly(rA), the linear dichroism spectra could not be explained by the same base orientations. In these two cases also the protein contribution to the linear dichroism appeared to be different, indicating that for some aromatic residues the orientations are not the same as those in the other complexes. The different structures of these complexes are possibly related to the relatively low binding affinity of gp32 to poly(rC), and to a lesser extent to poly(rA).     

Changes of tyrosine and tryptophan residues in human hemoglobin by oxygen binding: near- and far-UV circular dichroism of isolated chains and recombined hemoglobin

In order to assign the circular dichroism (CD) spectral change in the region between 280 and 300 nm of human adult hemoglobin (Hb A) upon the quaternary structure transition induced by oxygen binding, the near- and far-UV CD spectra of the isolated chains and the recombined hemoglobin were examined. Deoxygenation made the negative CD band at 290 nm of oxy-alpha chain deeper. On the other hand, positive CD bands of oxy-beta chain at the 280 to approximately 300 nm became negative upon deoxygenation. These changes were interpreted as being due to environmental alterations of tyrosine (Tyr) and/or tryptophan (Trp) perturbed by tertiary structural changes from the oxy to deoxy form in isolated chains, referring to the CD spectra of model compounds. From the difference between CD bands of the arithmetic mean of deoxy isolated chains and the CD band of deoxyHb tetramer, the contribution of tertiary structural change to the negative CD band of deoxyHb A at 287 nm was estimated to be 50%. This finding has revealed that the net contribution of quaternary structure transition to the negative band is 50%. In far-UV CD spectra, the environmental changes of aromatic residues upon the quaternary structure transition were also detected as a negative band at 225 nm.