Protein structural changes induced by glutathione-coated CdS quantum dots as revealed by Trp phosphorescence.

We evaluated the potential of tryptophan (Trp) phosphorescence spectroscopy for investigating conformational states of proteins involved in interaction with nanoparticles. Characterization of protein-nanoparticle interaction is crucial in assessing biological hazards related to use of nanoparticles. We synthesized glutathione-coated CdS quantum dots (GSH-CdS), which exhibited an absorption peak at 366 nm, indicative of 2.4 nm core size. Chemical analysis of purified GSH-CdS suggested an average molecular formula of GSH18S56Cd60. Investigations were conducted on model proteins varying in terms of isoelectric point, degree of burial of the Trp probe, and quaternary structure. GSH-CdS fluorescence measurements showed improvement in nanoparticle quantum yield induced by protein interaction. Trp phosphorescence was used to examine the possible perturbations in the protein native fold induced by GSH-CdS. Phosphorescence lifetime measurements highlighted significant conformational changes in some proteins. Despite their small size, GSH-CdS appeared to interact with more than one protein molecule. Rough determination of the affinity of GSH-CdS for proteins was derived from the change in phosphorescence lifetime at increasing nanoparticle concentrations. The estimated affinities were comparable to those observed for specific protein-ligand interactions and suggest that protein-nanoparticle interaction may have a biological impact.

Peripheral endocannabinoid system-mediated actions of rimonabant on growth hormone secretion are ghrelin-dependent.

The somatotroph axis is a crucial pathway regulating metabolism. Despite the fact that the endocannabinoid system has been also revealed as a potent modulator of energy homeostasis, little information is available concerning a putative interaction between these two systems. The aim of the present study was to determine the in vivo effects of the blockade of the cannabinoid receptor type 1 (CB1) over growth hormone (GH) secretion using the CB1 antagonist rimonabant. The results obtained show that the blockade of the CB1 peripheral receptor by i.p. injection of rimonabant significantly inhibited pulsatile GH secretion. Similarly, it was found that this injection significantly decreased ghrelin-induced GH secretion without any effect on growth hormone-releasing hormone (GHRH)-induced GH discharge. In situ hybridisation showed that the peripheral blockade of CB1 did not affect hypothalamic somatostatin mRNA levels; however, GHRH mRNA expression was significantly decreased. The blockade of the vagus nerve signal by surgical vagotomy eliminated the inhibitory action of rimonabant on GHRH mRNA and consequently on GH. On the other hand, the central CB1 blockade by i.c.v. rimonabant treatment was unable to reproduce the effect of peripheral blockade on GHRH mRNA, nor the GH response to ghrelin. In conclusion, the data reported in the present study establish, from a physiological point of view, the existence of a novel mechanism of GH regulation implicating the action of the cannabinoid receptor on the somatotroph axis.

Prevalence of double pituitary adenomas in a surgical series: Clinical, histological and genetic features.

BACKGROUND: The term double pituitary adenomas (DPA) is usually referred to those rare lesions showing two distinct cellular components. Genetic background may sustain the proliferation of more than one cell at the same time but no information is available on the presence of aip mutations in these patients. AIM: We report the prevalence and the endocrinological, neuroradiological, histopathological and genetic features of DPA detected in a large surgical series. The contribution of pituitary transcription factor immunostains in DPA was also evaluated. SUBJECTS AND METHODS: One-hundred-forty-four patients undergoing surgery for tumors of the sellar region were evaluated. Histopathology, immunohistochemistry and the mutational analysis for the entire coding region of the AIP and MEN1 genes were performed. RESULTS: One-hundred-seventeen patients out of 144 had a pituitary adenoma. DPA was found in 3 (2.6%) out of 117 patients with pituitary adenoma. Immunohistochemistry and transcription factors analysis demonstrated two not yet described histotype associations in DPA. The coexistence of somatotroph-lactotroph and silent mammosomatotroph histotype in 1 case and the coexistence of sparsely granulated lactotroph and null cell adenomas in the remaining two cases were first identified. Sequencing data for the coding region of the aip and the menin gene resulted in wild type sequences in all patients with DPA. CONCLUSIONS: The prevalence of DPA observed in our unselected surgical series is not negligible (2.6%). Furthermore, the evaluation of the treatment outcome would suggest that the clinical management of DPAs requires a careful diagnostic approach and follow- up.

Silent familial isolated pituitary adenomas: histopathological and clinical case report.

Familial isolated pituitary adenoma (FIPA) is a rare condition independent of Carney Complex or MEN1. An international multicenter study recently described 28 nonfunctioning pituitary adenomas in 26 families with only two homogeneous nonsecreting phenotype families consistent of silent GH and silent gonadotroph adenomas, respectively. We present the clinical, genetic, and morphological analysis of two silent pituitary adenomas occurring in a man and his daughter, and discuss the differential diagnosis associated with their histological, immunohistochemical, and ultrastructural features. The patients developed invasive nonsecreting macroadenomas manifesting only with compressive symptoms. Genetic analysis in the father showed no MEN-1 germ-line mutation. Tissue samples obtained after paraseptal trans-sphenoidal surgery were studied by immunohistochemistry for adenohypophyseal hormones, low molecular weight cytokeratins (CAM 5.2), proliferation markers, and anterior pituitary transcription factors (Pit-1 and SF-1) and by electron microscopy for secretory granules. The clinical, histological, and immunohistochemical features of the lesions posed a differential diagnosis between a null cell adenoma and a silent corticotroph adenoma (Type II); on the basis of immunohistochemical stains for cytokeratin and adenohypophysis cell lineage markers, tumor behavior and ultrastructural studies we concluded for the second. The reported cases represent an as yet undescribed example of homogeneous family with silent corticotroph adenomas (Type II). Our observations support the trend for more aggressive behavior in nonsecreting FIPAs as compared with sporadic adenomas.

Structural perturbations of azurin deposited on solid matrices as revealed by trp phosphorescence.

The phosphorescence emission of Cd-azurin from Pseudomonas aeruginosa was used as a probe of possible perturbations in the dynamical structure of the protein core that may be induced by protein-sorbent and protein-protein interactions occurring when the macromolecule is deposited into amorphous, thin solid films. Relative to the protein in aqueous solution, the spectrum is unrelaxed and the phosphorescence decay becomes highly heterogeneous, the average lifetime increasing sharply with film thickness and upon its dehydration. According to the lifetime parameter, adsorption of the protein to the substrate is found to produce a multiplicity of partially unfolded structures, an influence that propagates for several protein layers from the surface. Among the substrates used for film deposition, hydrophilic silica, dextran, DEAE-dextran, dextran sulfate, and hydrophobic octodecylamine, the perturbation is smallest with dextran sulfate and largest with octodecylamine. The destabilizing effect of protein-protein interactions, as monitored on 50-layer-thick films, is most evident at a relative humidity of 75%. Stabilizing agents were incorporated to attenuate the deleterious effects of protein aggregation. Among them, the most effective in preserving a more native-like structure are the disaccharides sucrose and trehalose in dry films and the polymer dextran in wet films. Interestingly, the polymer was found to achieve maximum efficacy at sensibly lower additive/protein ratios than the sugars.

Tyrosine quenching of tryptophan phosphorescence in glyceraldehyde-3-phosphate dehydrogenase from Bacillus stearothermophilus.

Tyrosine is known to quench the phosphorescence of free tryptophan derivatives in solution, but the interaction between tryptophan residues in proteins and neighboring tyrosine side chains has not yet been demonstrated. This report examines the potential role of Y283 in quenching the phosphorescence emission of W310 of glyceraldehyde-3-phosphate dehydrogenase from Bacillus stearothermophilus by comparing the phosphorescence characteristics of the wild-type enzyme to that of appositely designed mutants in which either the second tryptophan residue, W84, is replaced with phenylalanine or Y283 is replaced by valine. Phosphorescence spectra and lifetimes in polyol/buffer low-temperature glasses demonstrate that W310, in both wild-type and W84F (Trp84-->Phe) mutant proteins, is already quenched in viscous low-temperature solutions, before the onset of major structural fluctuations in the macromolecule, an anomalous quenching that is abolished with the mutation Y283V (Tyr283-->Val). In buffer at ambient temperature, the effect of replacing Y283 with valine on the phosphorescence of W310 is to lengthen its lifetime from 50 micros to 2.5 ms, a 50-fold enhancement that again emphasizes how W310 emission is dominated by the local interaction with Y283. Tyr quenching of W310 exhibits a strong temperature dependence, with a rate constant kq = 0.1 s(-1) at 140 K and 2 x 10(4) s(-1) at 293 K. Comparison between thermal quenching profiles of the W84F mutant in solution and in the dry state, where protein flexibility is drastically reduced, shows that the activation energy of the quenching reaction is rather small, Ea < or = 0.17 kcal mol(-1), and that, on the contrary, structural fluctuations play an important role on the effectiveness of Tyr quenching. Various putative quenching mechanisms are examined, and the conclusion, based on the present results as well as on the phosphorescence characteristics of other protein systems, is that Tyr quenching occurs through the formation of an excited-state triplet exciplex.

Alteration of the intramolecular dynamics of glycogen phosphorylase b by allosteric ligands.

Phosphorylase b (E.C. 2.4.1.1), prepared from rabbit skeletal muscle, was used to study whether the binding of allosteric ligands modifies the intramolecular dynamics of the protein matrix. Protein dynamics were monitored through the fluorescence and phosphorescence parameters of the 12 tryptophan (Trp) residues (one monomer) of the enzyme. The phosphorescence lifetime was measured at room temperature both in the absence and the presence of ligands. The addition of an allosteric inhibitor (ATP) decreased the lifetime, while the presence of activator (AMP) and/or substrate (G-1-P) had no detectable effect. The lifetime data allow us to conclude that the environment of the buried tryptophans becomes more flexible upon the binding of ATP, while the other ligands did not induce such change. The ATP-induced perturbation was also examined by the quenching of Trp fluorescence by acrylamide. The quenching parameters did not show any change, suggesting that the effect of ATP is localized to the vicinity of the phosphorescent Trp residues.

Modification of the mitochondrial F1-ATPase epsilon subunit, enhancement of the ATPase activity of the IF1-F1 complex and IF1-binding dependence of the conformation of the epsilon subunit.

Treatment of bovine heart submitochondrial particles with a low concentration of 2-hydroxy-5-nitrobenzyl bromide (HNB), a selective reagent for the Trp residue of the epsilon subunit [Baracca, Barogi, Lenaz and Solaini (1993) Int. J. Biochem. 25, 1269-1275], enhances the ATP hydrolytic activity of the particles exclusively when the natural inhibitor protein IF1 is present. Similarly, isolated F1 [the catalytic sector of the mitochondrial H+-ATPase complex (ATP synthase)] treated with the reagent has the ATPase activity enhanced exclusively if IF1 is bound to it. These experiments suggest that the modification of the epsilon subunit decreases the inhibitory activity of IF1, eliciting the search for a relationship between the epsilon subunit and the inhibitory protein. Certainly, a reverse relationship exists because HNB binds covalently to the isolated F1 exclusively when the inhibitory protein is present. This finding is consistent with the existence of the epsilon subunit in different conformational states depending on whether IF1 is bound to F1 or not. Support for this assertion is obtained by measurements of the intrinsic phosphorescence decay rate of F1, a probe of the Trp epsilon subunit conformation in situ [Solaini, Baracca, Parenti-Castelli and Strambini (1993) Eur. J. Biochem. 214, 729-734]. A significant difference in phosphorescence decay rate is detected when IF1 is added to preparations of F1 previously devoid of the inhibitory protein. These studies indicate that IF1 and the epsilon subunit of the mitochondrial F1-ATPase complex are related, suggesting a possible role of the epsilon subunit in the mechanism of regulation of the mitochondrial ATP synthase.

Structural mapping of the epsilon-subunit of mitochondrial H(+)-ATPase complex (F1).

Phosphorescence and fluorescence energy transfer measurements have been used to locate the epsilon-subunit within the know structural frame of the mitochondrial soluble part of F-type H(+)-ATPase complex (F1). The fluorescence probe 2'-O-(trinitrophenyl)adenosine-5'-triphosphate was bound to the nucleotide binding sites of the enzyme, whereas the probe 7-diethylamino-3'-(4'-maleimidylphenyl)-4-methylcoumarin was attached to the single sulfhydryl residue of isolated oligomycin sensitivity-conferring protein (OSCP), which was then reconstituted with F1. Fluorescence and phosphorescence resonance energy transfer yields from the lone tryptophan residue of F1 present in the epsilon-polypeptide and the fluorescence labels attached to the F1 complex established that tryptophan is separated by 3.7 nm from Cys-118 of OSCP in the reconstituted OSCP-F1 complex, by 4.9 nm from its closest catalytic site and by more than 6.4 nm from the two other catalytic sites, including the lowest affinity ATP site. These separations together with the crystallographic coordinates of the F1 complex (Abrahams, J.P., A. G. W. Leslie, R. Lutter, and J.E. Walker. 1994. Structure at 2.8 A resolution of F1-ATPase from bovine heart mitochondria. Nature. 370:621-628) place the epsilon-subunit in the stem region of the F1 molecule in a unique asymmetrical position relative to the catalytic sites of the enzyme.

Effects of NAD+ binding on the luminescence of tryptophans 84 and 310 of glyceraldehyde-3-phosphate dehydrogenase from Bacillus stearothermophilus.

The individual fluorescence and phosphorescence properties of W84 and W310 in Bacillus stearothermophilus glyceraldehyde-3-phosphate dehydrogenase were identified through the construction of a single tryptophan mutant (W84F) and by comparison of the emission between mutant and wild-type enzymes. The results show that the luminescence of W310 is red-shifted and substantially quenched relative to that of W84. It displays an average subnanosecond fluorescence lifetime (tau F) and a very short, 50 microseconds, room-temperature phosphorescence (RTP) lifetime (tau P). The perturbation of W310 luminescence is believed to arise from a stacking interaction with Y283. In contrast, W84 exhibits a fluorescence lifetime tau F of several nanoseconds and a long-lived phosphorescence lifetime tau P, typical of buried, unperturbed TrP residues. NAD+ binding to the tetrameric enzyme causes a 55% reduction of W310 fluorescence intensity together with a nearly complete quenching of its low-temperature phosphorescence. W84, which is located far from the nicotinamide moiety of NAD+, is much less affected by the binding of the coenzyme; the reduction in fluorescence intensity is 35%, and its phosphorescence intensity is unchanged. Another consequence of NAD+ binding is a significant decrease of the RTP lifetime tau P of W84, manifesting thereby a conformational change in the region of the coenzyme-binding domain. However, no change is observed in the RTP lifetime tau P of W310 located in the catalytic domain. These findings and those obtained at partial coenzyme saturation support the conclusions derived from high-resolution crystallographic structures [Skarzynski, T., & Wonacott, A. J., (1988) J. Mol. Biol. 203, 1097-1118] that the NAD(+)-induced conformational change is sequential and that subtle rearrangement in the structure of unligated subunits might be responsible for the negative cooperative behavior of NAD+ binding.

Proteins in frozen solutions: evidence of ice-induced partial unfolding.

From a drastic decrease in the phosphorescence lifetime of tryptophan residues buried in compact rigid cores of globular proteins, it was possible to demonstrate that freezing of aqueous solutions is invariably accompanied by a marked loosening of the native fold, an alteration that entails considerable loss of secondary and tertiary structure. The phenomenon is largely reversible on ice melting although, in some cases, a small fraction of macromolecules recovers neither the initial phosphorescence properties nor the catalytic activity. The variation in the lifetime parameter was found to be a smooth function of the residual volume of liquid water in equilibrium with ice and to depend on the morphology of ice. The addition of cryoprotectants such as glycerol and sucrose profoundly attenuates or even eliminates the perturbation. These results are interpreted in terms of adsorption of protein molecules onto the surface of ice.

Conformational changes of the mitochondrial F1-ATPase epsilon-subunit induced by nucleotide binding as observed by phosphorescence spectroscopy.

Changes in conformation of the epsilon-subunit of the bovine heart mitochondrial F1-ATPase complex as a result of nucleotide binding have been demonstrated from the phosphorescence emission of tryptophan. The triplet state lifetime shows that whereas nucleoside triphosphate binding to the enzyme in the presence of Mg2+ increases the flexibility of the protein structure surrounding the chromophore, nucleoside diphosphate acts in an opposite manner, enhancing the rigidity of this region of the macromolecule. Such changes in dynamic structure of the epsilon-subunit are evident at high ligand concentration added to both the nucleotide-depleted F1 (Nd-F1) and the F1 preparation containing the three tightly bound nucleotides (F1(2,1)). Since the effects observed are similar in both the F1 forms, the binding to the low affinity sites must be responsible for the conformational changes induced in the epsilon-subunit. This is partially supported by the observation that the Trp lifetime is not significantly affected by adding an equimolar concentration of adenine nucleotide to Nd-F1. The effects on protein structure of nucleotide binding to either catalytic or noncatalytic sites have been distinguished by studying the phosphorescence emission of the F1 complex prepared with the three noncatalytic sites filled and the three catalytic sites vacant (F1(3,0)). Phosphorescence lifetime measurements on this F1 form demonstrate that the binding of Mg-NTP to catalytic sites induces a slight enhancement of the rigidity of the epsilon-subunit. This implies that the binding to the vacant noncatalytic site of F1(2,1) must exert the opposite and larger effect of enhancing the flexibility of the protein structure observed in both Nd-F1 and F1(2,1). The observation that enhanced flexibility of the protein occurs upon addition of adenine nucleotides to F1(2,1) in the absence of Mg2+ provides direct support for this suggestion. The connection between changes in structure and the possible functional role of the epsilon-subunit is discussed.

A study of the mitochondrial F1-ATPase tryptophan phosphorescence at 273 K.

The bovine heart mitochondrial F1-ATPase complex exhibits an intrinsic tryptophan phosphorescence that can be used to monitor structural changes of the epsilon-subunit. The phosphorescence decay rate of F1 containing the tightly bound nucleotides increases upon addition of adenine nucleoside triphosphate in the presence of magnesium. The average phosphorescence lifetime of this enzyme preparation decreases from 10.2 to 7.8 ms upon Mg-ATP addition. Since increasing phosphorescence decay rate is related to increasing flexibility of proteins, Mg-ATP added to the F1-ATPase complex can enhance the flexibility of the protein structure surrounding the chromophore. Experiments carried out on F1 prepared with the three noncatalytic sites filled and the three catalytic sites vacant show a significant increase of the phosphorescence lifetime from 6.4 ms to 7.6 ms upon Mg-ATP addition. These results suggest that the mitochondrial F1-ATPase epsilon-subunit conformation senses differently the nucleoside triphosphate binding to catalytic or noncatalytic sites.

Heterogeneity of protein conformation in solution from the lifetime of tryptophan phosphorescence.

The decay of Trp phosphorescence of proteins in fluid solutions was shown to provide a sensitive tool for probing the conformational homogeneity of these macromolecules in the millisecond to second time scale. Upon examination of 15 single Trp emitting proteins multiexponential decays were observed in 12 cases, a demonstration that the presence of slowly interconverting conformers in solution is more the norm rather than an exception. The amplitude of preexponential terms, from which the conformer equilibrium is derived, was found to be a sensitive function of solvent composition (buffer, pH, ionic strength and glycerol cosolvent), temperature, and complex formation with substrates and cofactors. In many cases, raising the temperature, a point is reached at which the decay becomes practically monoexponential, meaning that conformer interconversion rates have become commensurate with the triplet lifetime. Estimation of activation free energy barriers to interconversion shows that the large values of DeltaG* are rather similar among polypeptides and that the protein substates involved are sufficiently long-lived to display individual binding/catalytic properties.

Conformational changes in proteins induced by dynamic associations. A tryptophan phosphorescence study.

Random collisions between macromolecules lead to dynamic associations (lengthy encounters) that in principle could affect their conformation and, in the case of enzymes, their binding and catalytic properties. Exploiting the unique sensitivity of the phosphorescence lifetime, tau, of Trp to the internal flexibility of globular proteins we probed the perturbations induced in the structure of the coenzyme-binding domain of alcohol dehydrogenase (LADH) and glyceraldehyde-3-phosphate dehydrogenase (GraPDH) by the presence in solution of other dehydrogenases and of functionally unrelated proteins. With Trp314 of LADH, the results emphasize that while tau is not affected by the concentration of LADH itself, the addition of micromolar quantities of other proteins causes a distinct reduction in it. From the linear increase of 1/tau with protein concentration one obtains values for the apparent second-order Stern-Volmer rate constant that range between 2-200 x 10(3) M-1 s-1, decreasing 2-3-fold when ternary complexes of LADH with NADH or NAD+ and inhibitors are involved. Similar effects were observed with Trp310 of GraPDH except that with sorbitol dehydrogenase as perturbant the increase of 1/tau is hyperbolic and governed by an apparent dissociation constant of about 1 microM. Finally, glycerol-3-phosphate dehydrogenase, the strongest perturber of both LADH and GraPDH, has either no effect on lactic dehydrogenase from pig heart or induces a moderate lengthening of the triplet lifetime of the rabbit muscle enzyme. Because Stern-Volmer behavior is typical also of diffusion-mediated quenching reactions, a parallel investigation with cysteine, cystine and N-acetyl-tryptophanamide demonstrated that among potential, protein-associated, quenching moieties namely, -SH, -S-S- and indole groups, only the latter has rate constants approaching the magnitude of protein perturbants. Since considerable evidence rules out the predominance of such quenching reactions, these findings confirm a subtle form of communication between protein molecules in solution. The lack of specificity and the similar effects between dehydrogenases with right and wrong stereospecificity for direct coenzyme transfer suggests that the perturbations monitored are unrelated to this function.

Temperature dependence of tryptophan phosphorescence in proteins.

The phosphorescence yield and decay kinetics of tryptophan (Trp) in apoazurin from Pseudomonas aeruginosa, subtilisin Carlsberg, Staphylococcal nuclease and liver alcohol dehydrogenase were determined as a function of temperature from 150 K (glassy matrix) to 300 K (fluid solution). The constancy of the lifetime-normalized phosphorescence yield with apoazurin and with Trp-314 in alcohol dehydrogenase establishes that the intersystem crossing quantum yield is practically unaffected across the temperature range. Consequently, any decrease in phosphorescence intensity not accounted for by lifetime-shortening is a signal either of the selective quenching of specific Trp residues in the same macromolecule or that the protein sample is heterogeneous in its emission properties. From an analysis of the thermal profile it is concluded that subtilisin Carlsberg and S. nuclease, as opposed to apoazurin, are not phosphorescent at ambient temperature, their residual emission probably arising from protein impurities. Criteria for distinguishing conformer emission from a contribution by protein impurities are discussed.

Phosphorescence properties of Trp-84 and Trp-310 in glyceraldehyde-3-phosphate dehydrogenase from Bacillus stearothermophilus.

The phosphorescence spectra of Trp-84 and Trp-310 in glyceraldehyde-3-phosphate dehydrogenase from Bacillus stearothermophilus in an aqueous glass show distinct 0,0 vibrational bands with peaks at 406.5 and 410.5 nm. With the aid of external heavy-atom perturbation of iodide and the thermal quenching profile, it is concluded that although both chromophores are effectively buried, only one, viz., the 406.5 nm component, is embedded in a sufficiently rigid core of the protein to phosphoresce in fluid solutions at room temperature. From inspection of the crystallographic structure is it evident that only Trp-310 embedded in the beta-sheet of the catalytic domain may satisfy the requirements of a long triplet-state lifetime and slow migration of O2 to its site. This identification confirms previous analysis of the phosphorescence properties of the enzymes from yeast, pig and rabbit muscle.

Phosphorescence properties and protein structure surrounding tryptophan residues in yeast, pig, and rabbit glyceraldehyde-3-phosphate dehydrogenase.

An investigation of the phosphorescence emission properties of tryptophan (Trp) was carried out in glyceraldehyde-3-phosphate dehydrogenase from yeast and from pig and rabbit muscle. Aided by the external heavy-atom effect of iodide, the dependence on excitation wavelength, and thermal quenching profiles, it was established that the 0,0 vibronic band peaked at 406 nm in the pig and rabbit proteins is made up of overlapping contributions from two Trp residues. In contrast to a previous report [Davis, J.M., & Maki, A.H. (1984) Biochemistry 23, 6249-6256], this implies that even in the muscle enzymes all three aromatic side chains are phosphorescent. Further, when the nature of the local environment of each residue is compared to the crystallographic structure of lobster GPDH, it leads to a complete new assignment of the individual phosphorescence spectra. With each protein, a single Trp, identified as Trp-310, was found to display long-lived phosphorescence at room temperature. The decay of this emission gives evidence of conformational homogeneity among the subunits of the tetrameric molecule.

Tryptophan phosphorescence and the conformation of liver alcohol dehydrogenase in solution and in the crystalline state.

Information on the effects of crystallization upon the structure of liver alcohol dehydrogenase from horse is obtained from a comparison of the phosphorescence properties of its tryptophan residues in solution and in the crystalline state. In the crystalline state the red shift in the phosphorescence spectrum of the solvent-exposed Trp-15 attests to a decreased polarity of its environment consistent with its shielding away from the aqueous solvent probably through its involvement in an intermolecular contact. On the other hand, the triplet-state lifetime of Trp-314 which is buried deeply in the coenzyme-binding domain demonstrates that the flexibility of this region of the macromolecule is unaffected by crystallization; a conclusion supported also by the similarity in the rate of oxygen quenching of its phosphorescence. Given that lattice constraints strongly inhibit large-scale conformational changes these results allow us to identify the average solution structure with the 'open' conformer determined crystallographically.

Phosphorescence anisotropy of liver alcohol dehydrogenase in the crystalline state. Apparent glasslike rigidity of the coenzyme-binding domain.

Phosphorescence anisotropy from internal tryptophan (Trp) residues in proteins which are in the crystalline state may provide an experimental approach suitable to study the flexibility of rather rigid segments of protein structure. The phosphorescence anisotropy of Trp-314 in liver alcohol dehydrogenase, which is enclosed within the beta-sheet forming the coenzyme-binding domain, was measured with the protein free in solution and in the crystalline state. In contrast to the free protein, where the rotational correlation time reflects the tumbling rate of the whole macromolecule, there is effectively no loss in anisotropy in the crystalline state. At room temperature, the triplet lifetime of 0.5 s implies that the rotational correlation time of the indole side chain must be larger than 1 s. Anisotropy data show that fluctuations of the indole ring about the average position can only be of limited amplitude (cone of semiangle less than 15 degrees) and that the resistance opposed by the beta-sheet to out-of-plane rotational motions is equivalent to a viscosity larger than 2.5 X 10(8) P, a value which confirms the particular rigidity anticipated for such an assembly of secondary structure.