Crystal structure of the MS2 coat protein dimer: implications for RNA binding and virus assembly.

BACKGROUND: The coat protein in RNA bacteriophages binds and encapsidates viral RNA, and also acts as translational repressor of viral replicase by binding to an RNA hairpin in the RNA genome. Because of its dual function, the MS2 coat protein is an interesting candidate for structural studies of protein-RNA interactions and protein-protein interactions. In this study, unassembled MS2 coat protein dimers were selected to analyze repressor activity and virus assembly. RESULTS: The crystal structure of a mutant MS2 coat protein that is defective in viral assembly yet retains repressor activity has been determined at 2.0 A resolution. The unassembled dimer is stabilized by interdigitation of alpha-helices, and the formation of a 10-stranded antiparallel beta-sheet across the interface between monomers. The substitution of arginine for tryptophan at residue 82 results in the formation of two new inter-subunit hydrogen bonds that further stabilize the dimer. Residues that influence RNA recognition, identified by molecular genetics, were located across the beta-sheet. Two of these residues (Tyr85 and Asn87) are displaced in the unliganded dimer and are located in the same beta-strand as the Trp-->Arg mutation. CONCLUSIONS: When compared with the structure of the coat protein in the assembled virus, differences in orientation of residues 85 and 87 suggest conformational adjustment on binding RNA in the first step of viral assembly. The substitution at residue 82 may affect virus assembly by imposing conformational restriction on the loop that makes critical inter-subunit contacts in the capsid.

Ligand responsiveness in human prostate cancer: structural analysis of mutant androgen receptors from LNCaP and CWR22 tumors.

Androgen receptors (ARs) belong to the family of hormone receptors that are ligand-dependent transcription factors. Endocrine therapy provides effective treatment for prostate cancer until mutations arise that alter the ligand responsiveness of AR. In this study, structural models were developed for the functional domains of human AR by homology modeling from crystal structures of closely related nuclear receptors. These models were used to locate the sites of two frequently occurring mutations in prostate cancer. The substitutions that develop in LNCaP (threonine-->alanine at residue 877) and CWR22 (histidine-->tyrosine at residue 874) tumor cell lines are both located on helix 11 that forms part of the ligand-binding pocket. However, the results suggest that these mutations influence ligand responsiveness by completely different mechanisms. Residue 877 contacts the ligand directly, and substitution at this site alters the stereochemistry of the binding pocket. Thus, the LNCaP mutation apparently broadens the specificity of ligand recognition. In contrast, residue 874 is located down the helical axis, projects away from the ligand pocket, and does not contact ligand. The side chain of residue 874 lies in a cavity between helices 11 and 12. Substitution of tyrosine for histidine 874 in CWR22 tumors may affect a conformational change of helix 12 and, thus, influence binding of coactivator proteins and their regulatory effect on transcriptional activation.

Three-dimensional structure of a light chain dimer crystallized in water. Conformational flexibility of a molecule in two crystal forms.

The three-dimensional structure of an immunoglobulin light chain dimer (Mcg) crystallized in deionized water (orthorhombic form) was determined at 2.0 A resolution by phase extension and crystallographic refinement. This structure was refined side-by-side with that of the same molecule crystallized in ammonium sulfate (trigonal form). The dimer adopted markedly different structures in the two solvents. "Elbow bend" angles between pseudo 2-fold axes of rotation relating pairs of "variable" (V) and "constant" (C) domains were found to be 132 degrees in the orthorhombic form and 115 degrees in the trigonal form. Modes of association of the V domains and, to a lesser extent, the pairing interactions of the C domains were different in the two structures. Alterations in the V domain pairing were reflected in the shapes of the binding regions and in the orientations of the side-chains lining the walls of the binding sites. In the trigonal form, for instance, the V domain interface was compartmentalized into a main binding cavity and a deep pocket, whereas these spaces were continuous in the orthorhombic structure. Patterns of ordered water molecules were quite distinct in the two crystal types. In some cases, the solvent structures could be correlated with conformational changes in the proteins. For example, close contacts between V and C domains of monomer 1 of the trigonal form were not retained in orthorhombic crystals. Ordered water molecules filled the space created when the two domains moved apart.

Crystals of the cell-binding module of fibronectin obtained from a series of recombinant fragments differing in length.

A recombinant fragment corresponding to the cell adhesion module (FNIII10) of human fibronectin has been crystallized at pH 8.6 from solutions containing polyethylene glycol as precipitant. The crystals formed in the space group P2(1) with a = 30.76 A, b = 35.07 A, c = 37.66 A, beta = 106.9 degrees. There is one molecule per asymmetric unit and the crystals diffract beyond 1.75 A resolution. To improve the prospects for successful crystallization of the FNIII10 module, a series of recombinant fragments was produced with minor differences in the length of N or C-terminal segments. Only one of these variants crystallized. Interestingly, the C-terminal residue of this variant formed stable intermolecular contacts with a symmetry-related molecule in the crystal lattice.

Crystal structure of the tenth type III cell adhesion module of human fibronectin.

The crystal structure of the cell adhesion module of fibronectin (FNIII10) has been determined at 1.8 A resolution. A recombinant fragment corresponding to the tenth type III module of human fibronectin was crystallized in space group P2(1) with a = 30.7, b = 35.1 and c = 37.7 A and beta = 107 degrees. The structure was determined by molecular replacement and refined by least squares methods. The crystallographic R-factor for the final model of the 91 amino acid module plus 56 solvent atoms is 0.18 for 10 to 1.8 A data. The module consists of two layers of beta-sheet, one with three antiparallel strands and the other with four antiparallel strands. The beta-sheets enclose a hydrophobic core of 24 amino acid side-chains. The module contains the RGD cell recognition sequence in a flexible loop connecting two beta-strands. The tertiary structure of the FNIII10 module has been used to develop a structure-based sequence alignment of 17 type III modules in fibronectin based on the striking conservation of homologous hydrophobic residues. A similar pattern of homologous alternating hydrophobic residues is also evident in a comparison of type III modules in proteins unrelated to fibronectin such as cytokine receptors and muscle proteins.

Binding of N-formylated chemotactic peptides in crystals of the Mcg light chain dimer: similarities with neutrophil receptors.

X-ray crystallographic techniques were used to study the modes of binding of N-formylated chemotactic peptides to the Mcg light chain (Bence-Jones) dimer. By difference Fourier analyses at 2.7-A resolution four N-formylated tripeptides were found to occupy similar sites in the main binding cavity of the dimer. In all cases the N-formyl group appeared to form a hydrogen bond with a phenolic hydroxyl group of a tyrosine residue (No. 38, monomer 1) at the base of the cavity. N-formylation was necessary, since di-, tri- and tetrapeptides with free alpha-amino groups failed to bind. Although methionine in ligand position 1 was optimal for binding, it could be replaced with norleucine. Position 2 was less critical, providing the side chain was bulky and hydrophobic (e.g. leucine, methionine or phenylalanine). An aromatic residue like phenylalanine was most favorable in position 3. These bound ligands were site-filling and wedge-shaped, with their side chains swept back toward the entrance of the cavity to conform to the space available for binding. In the binding site side chains and polypeptide segments of the hypervariable loops also moved in ways improving the complementarity between protein and ligand. The stereochemical requirements for binding were markedly similar to those found in interactions of neutrophil receptors with the same series of tripeptides. An N-formylated dipeptide, N-f-Met-Trp, was bound with equal occupancies in two overlapping subsites. In the deeper site the N-formyl group and methionine side chain were situated in positions comparable to those in the N-formyl tripeptides, but the peptide bond between methionine and tryptophan was in the cis configuration. In the outer site the corresponding peptide bond was in the energetically more favourable trans configuration.

Three-dimensional structure of a hybrid light chain dimer: protein engineering of a binding cavity.

An attempt was made to engineer a binding site and check its structure by X-ray analysis. Two human light chains (Mcg and Weir), with "variable" domain sequences differing in 36 positions, were hybridized into a heterologous dimer and crystallized in ammonium sulfate by the same procedure used for the trigonal form of the Mcg dimer. The three-dimensional structure of the hybrid was determined at 3.5-A resolution by difference Fourier analysis, interactive model building with computer graphics and crystallographic refinement. In the heterologous dimer, the Weir protein behaved as the structural analog of the heavy chain in an antigen binding fragment, while the Mcg protein assumed the role of the light chain component. The hybrid and the Mcg dimer were closely similar in overall structure, an observation probably correlated with the deliberate cleavage of the intrachain disulfide bond in the variable domain of the Weir protein during the hybridization procedure. Examination of the crystal structure of the hybrid suggested that the cleavage resulted in the relaxation of restraints which might otherwise have interfered with the formation of an Mcg-like dimer. There were six substitutions among the residues lining the binding cavities of the hybrid and Mcg dimer. These substitutions significantly affected the sizes, shapes and binding properties of the two cavities.

A search for site-filling ligands in the Mcg Bence-Jones dimer: crystal binding studies of fluorescent compounds.

In trigonal crystals grown in 1.9 M ammonium sulfate buffered at pH 6.2, the Mcg light-chain (Bence-Jones) dimer has a highly aromatic binding cavity accessible to a wide range of hydrophobic and aromatic ligands. A search was made for site-filling ligands by diffusing compounds into the crystals and determining their locations, orientations and relative occupancies by difference Fourier analysis at 2.7-A resolution. 1-Anilinonaphthalene-8-sulfonate, a small ligand in comparison with the rest of the series, initially occupied a site in the main binding cavity. With time, however, this ligand changed its position to the deep binding pocket beyond the floor of the main cavity. The original binding site remained vacant, despite the presence of a large excess of ligand in the soaking solution. Ligands increasing in size from fluorescein to bis(N-methyl)acridine (lucigenin) to dimers of carboxytetramethylrhodamine were found to bind with stringent stereospecificity in the main cavity, but the mode of binding was different in each case. The dimer of the 6-isomer of carboxytetramethylrhodamine, in which the two carboxyl groups are in para positions on the phenyl moiety, proved to be an effective site-filling ligand. The differences in the binding properties of dimers of 5- and 6-carboxytetramethylrhodamine led to an explanation for isomeric discrimination in the binding site. There were extensive conformational changes in the binding cavity to accommodate the ligands, particularly 6-carboxytetramethylrhodamine. The second and third hypervariable loops proved very flexible, and moved in ways to expand the binding site. The side chains of key tyrosine and phenylalanine residues in the site were also highly mobile. Their orientations adjusted to optimize complementarity with the ligands. These conformational adjustments are consistent with the tenets of a limited neo-instructive theory of ligand binding.

Accessible intrachain disulfide bonds in hybrids of light chains.

The three-dimensional structure of the Mcg lambda-type Bence-Jones dimer crystallized in ammonium sulfate is known at 2.3-A resolution. A series of nine other human lambda-chains and two kappa-chains did not crystallize under the same conditions. After these proteins were hybridized with the Mcg light chain by the method of Peabody et al. [Biochemistry, 19, 2827 (1980)], however, crystals of six heterodimers were produced. Two of these (Mcg X Weir and Mcg X Hud) were suitable for X-ray analysis. The non-Mcg parental molecules in four of the crystallizable hybrids showed aberrant electrophoretic behavior after treatment with mild reducing agents. The results suggest that the intrachain disulfide bond in at least one domain (probably the variable domain) was susceptible to mild reductive cleavage in a significant proportion of light chains. Moreover, the loosening of the domain structure resulting from such disulfide cleavage in one parent appeared to promote the tendency of a hybrid molecule to crystallize.

The binding of opioid peptides to the Mcg light chain dimer: flexible keys and adjustable locks.

Enkephalins and beta-casomorphins (opioid peptides) were found to bind in a variety of conformations to a human light chain (Bence-Jones) dimer from a patient (Mcg) with amyloidosis. The peptides were diffused into crystals of the protein and their positions, relative occupancies and modes of binding were determined at 2.7 A resolution by difference Fourier analyses. Collectively, the opioid peptides occupied practically all of the available space in the concave, internal parts of the binding region, as well as flat or convex external surfaces around the rim of the binding cavity. Suitable ligands ranged in size from four to seven residues. As many as five residues could be accommodated inside the binding region, and there was space for at least four residues on the external surfaces. External binding was influenced by solvent effects and local packing interactions among adjacent protein molecules in the crystal lattice. In the enkephalin series the presence of amino-terminal tyrosine was necessary, but not sufficient for binding. [Met]-enkephalin, a pentapeptide, showed two different modes of binding in overlapping subsites. In one subsite, preferred over the second in a ratio of 1.3:1.0, the side chain of amino-terminal tyrosine penetrated through the floor of the main cavity to lodge in the deep binding pocket about 20 A from the entrance. The remainder of the peptide spanned the length of the main cavity in an extended conformation. In the second subsite the amino end was restricted to the main cavity and the peptide backbone turned abruptly upward at residue 3 to interact with external surfaces. An (Arg-6, Phe-7) heptapeptide extension of [Met]-enkephalin entered the deep pocket and assumed an extended conformation in the main cavity like the pentapeptide. Its last two residues flattened against the external surfaces. [Leu]-enkephalin and its analogues displayed a combination of internal and external binding like [Met]-enkephalin in its secondary subsite. Enkephalin analogues with D-amino acids in position 2 generally adopted conformations which were more convoluted than those in the L-isomers. Moreover, external interactions tended to be more prominent in the D-derivatives. The beta-casomorphin-7 heptapeptide penetrated into the deep pocket and traversed the main cavity in as extended a conformation as the presence of two proline residues would permit. On removal of the ligand there was an unexpected hysteresis effect involving permanent structural alterations in the walls of the binding region. beta-casomorphins-4 and -5 were bound in the main cavity with the carboxyl ends protruding from the entrance.(ABSTRACT TRUNCATED AT 400 WORDS)

Cocrystallization of an immunoglobulin light chain dimer with bis(dinitrophenyl) lysine: tandem binding of two ligands, one with and one without accompanying conformational changes in the protein.

Previous studies showed that the Mcg dimer of immunoglobulin light chains bound bis(dinitrophenyl)lysine both in trigonal crystals and in solution. On prolonged storage in ammonium sulfate, mixtures of ligand and protein produced small trigonal cocrystals in low frequency. These crystals were nearly isomorphous with those of the unliganded dimer in which the subunits were covalently linked by an interchain disulfide bond. By difference Fourier analyses at 3.5 A resolution and subsequent crystallographic refinement, the cocrystals were found to contain molecules with two ligands aligned in tandem along the interface of the variable (V) domains of the protein. One ligand molecule adopted an almost fully extended conformation, with the epsilon-DNP ring situated near the floor, the alpha-carboxyl group directed toward the solvent at the entry, and the alpha-DNP ring outside the rim of the main cavity. As if architecturally designed, the ligand was located symmetrically between the two domains in an orientation that was compatible with both the unaltered structure of the cavity lining and with the known crystal packing interactions of neighboring protein molecules. The second ligand molecule in the cocrystal lodged in the deep pocket immediately under the floor of the main cavity. The ligand adopted a very compact conformation with the two DNP rings roughly antiparallel to each other. This molecule appeared to be semi-permanently sequestered in the pocket since it could not be dislodged by exhaustive perfusion with ammonium sulfate crystallizing media. Relative to its volume in the native dimer, the pocket was expanded to accommodate the oversized ligand. Within a single protein molecule, therefore, two types of binding of a flexible ligand were observed, one with and one without accompanying conformational changes in the protein. The number of cocrystals which could be produced was markedly increased if the interchain disulfide bond between the Mcg monomers was first reduced and alkylated.

Unexpected similarities in the crystal structures of the Mcg light-chain dimer and its hybrid with the Weir protein.

The covalently linked hybrid of two human lambda-type light chains (Mcg and Weir) crystallizes as trigonal bipyramids in ammonium sulfate [Ely et al., Molec. Immun. 22, 85-92 (1985)]. While markedly different in appearance from the barrel-shaped crystals of the parental Mcg dimer, the bipyramids of the hybrid have the same space group: trigonal P3(1)21. Moreover, the unit cell dimensions are practically identical: a = 72.3 A in both proteins; c = 188.1 A in the hybrid and 185.9 A in the Mcg dimer. These observations imply that the crystal packing and the main features of the three-dimensional structures are closely similar in the Mcg X Weir hybrid and the Mcg dimer. The "constant" domains of the Mcg and Weir proteins belong to the same genetic subclass and were expected to interact in comparable ways in hybrids and parental dimers. However, the overall similarities in the "variable" domain pairs in the hybrid and Mcg dimer were completely unpredicted, since the amino acid sequences of the heterologous variable domains differ by 36 residues. By difference Fourier analysis the Weir light chain has been tentatively identified as monomer 1 (heavy-chain analogue) and the Mcg protein as monomer 2 (light-chain analogue) in the hybrid dimer. Substitutions in key positions in the hypervariable loops explain the differences in binding activity of the Mcg and Weir dimers. In the Mcg dimer bis(dinitrophenyl)lysine spans two relatively spacious subsites (A and B), with primary contacts involving tyrosines 34 and 38 of monomer 2. The Weir dimer, which does not bind dinitrophenyl ligands, has serine and phenylalanine in homologous positions. Moreover, the bilateral replacement of valine 48 and serine 91 in Mcg by leucine and methionine in the Weir dimer should effectively block access to subsite B. In the hybrid binding activity for bis(dinitrophenyl)lysine is restored because the Mcg light chain is present as the monomer 2 subunit.

A mild method for the preparation of disulfide-linked hybrids of immunoglobulin light chains.

A method is described for the hybridization of immunoglobulin light chains (Bence-Jones proteins) from different patients. The interchain half-cystine residues in the light chains from one subject are converted into mixed disulfides with 2,2'-dithiodipyridine. In the Bence-Jones dimer from a second patient the interchain disulfide bond is reduced with dithiothreitol. A covalently linked hybrid molecule is produced by the reaction of the mixed disulfide with the reduced thiol. In favorable cases the mild treatment yields heterodimers which can be crystallized for X-ray diffraction studies. The procedure can also be employed for converting a monomer into a covalent dimer. The engineered dimer of one kappa chain (Jen) crystallizes in the same space group as an aggregate of monomers, but the unit cell is only one-third as large.

Three-dimensional structure of the Mcg IgG1 immunoglobulin.

The three-dimensional structure of an IgG1(lambda) immunoglobulin from a patient (Mcg) with amyloidosis was determined at 6.5-A resolution with X-ray diffraction techniques. The protein crystallized from water in the space group C2221, with a = 87.8, b = 111.3 and c = 186.3 A; the crystallographic asymmetric unit was a half-molecule consisting of one light and one heavy chain. The structure was solved by the multiple isomorphous replacement method with five heavy-atom derivatives. Electron density maps were interpreted with the aid of a protein modeling system used in conjunction with an Evans and Sutherland Picture System II graphics station. IgG1 molecules were tightly packed in the crystal lattice, with numerous intermolecular contacts. The two-fold axis relating identical halves of each molecule was found to be parallel to the y crystallographic axis. Electron density modules collectively representing one molecule were identified as three lobes representing the two antigen-binding (Fab) arms and the Fc region. An interchain disulfide bond connecting the two CL domains was located on the molecular diad and used as a landmark in the interpretation of the electron density map. A computer graphics method was developed to produce a solid image model of the IgG1 molecule in any prescribed orientation.

Crystal structure of the coat protein from the GA bacteriophage: model of the unassembled dimer.

There are four groups of RNA bacteriophages with distinct antigenic and physicochemical properties due to differences in surface residues of the viral coat proteins. Coat proteins also play a role as translational repressor during the viral life cycle, binding an RNA hairpin within the genome. In this study, the first crystal structure of the coat protein from a Group II phage GA is reported and compared to the Group I MS2 coat protein. The structure of the GA dimer was determined at 2.8 A resolution (R-factor = 0.20). The overall folding pattern of the coat protein is similar to the Group I MS2 coat protein in the intact virus (Golmohammadi R, Valegård K, Fridborg K, Liljas L. 1993, J Mol Biol 234:620-639) or as an unassembled dimer (Ni Cz, Syed R, Kodandapani R. Wickersham J, Peabody DS, Ely KR, 1995, Structure 3:255-263). The structures differ in the FG loops and in the first turn of the alpha A helix. GA and MS2 coat proteins differ in sequence at 49 of 129 amino acid residues. Sequence differences that contribute to distinct immunological and physical properties of the proteins are found at the surface of the intact virus in the AB and FG loops. There are six differences in potential RNA contact residues within the RNA-binding site located in an antiparallel beta-sheet across the dimer interface. Three differences involve residues in the center of this concave site: Lys/Arg 83, Ser/Asn 87, and Asp/Glu 89. Residue 87 was shown by molecular genetics to define RNA-binding specificity by GA or MS2 coat protein (Lim F. Spingola M, Peabody DS, 1994, J Biol Chem 269:9006-9010). This sequence difference reflects recognition of the nucleotide at position -5 in the unpaired loop of the translational operators bound by these coat proteins. In GA, the nucleotide at this position is a purine whereas in MS2, it is a pyrimidine.

Conformational flexibility and crystallization of tandemly linked type III modules of human fibronectin.

Fibronectin is a large cell adhesion molecule that is composed of several functional domains. The cell-binding domain that binds to cell surface integrins consists of repeated homologous type III modules. In this study, recombinant fragments from the cell-binding domain of human fibronectin that participate in a newly characterized fibronectin-fibronectin interaction with FNIII1 were crystallized. In each case, the crystals had more than one fibronectin fragment in the asymmetric unit. Crystals of FNIII10-11 grew in the space group C2 with a = 117.1 A, b = 38.6 A, c = 80.6 A, beta = 97.2 degrees, and two molecules in the asymmetric unit. These crystals diffracted to 2.5 A resolution. Fragment FNIII8-11 and a shorter fragment, FNIII8-10, crystallized in hexagonal space groups with large unit cells and two to four molecules per asymmetric unit. Even very large crystals of these fragments did not diffract beyond 4 A. The crystal packing for this collection of fibronectin fragments suggests conformational flexibility between linked type III modules. The functional relevance of this flexibility for elongated versus compact models of the cell-binding domain of fibronectin is discussed.

Three-dimensional analyses of the binding of synthetic chemotactic and opioid peptides in the Mcg light chain dimer.

Synthetic peptides with chemotactic or opioid activity were bound to crystals of a light chain dimer and their three-dimensional structures and modes of binding were determined by X-ray analysis. The chemotactic series consisted of di- and tripeptides initiated with N-formylmethionine or N-formylnorleucine residues. Opioid peptides included the enkephalins and casomorphins ranging in length from four to seven residues. The binding region of the protein proved to be malleable in adjusting to the surface contours of the peptides. Aromatic contact residues, as well as polypeptide segments of hypervariable loops, moved to improve the complementarity with the ligands. The peptides were even more flexible and tended to conform fairly closely to the space and geometry available for occupancy in the binding sites. Binding interactions were not confined to the interior of the cavity. In both the chemotactic and opioid series, the carboxyl tails of the peptides encroached upon the outer surfaces of the rim and contributed to the binding energies for the protein-ligand complexes. The peptide bond in N-formylmethionyltryptophan was found to be in the energetically unfavourable cis configuration. There was also evidence for less severe distortions in peptide bond geometry when N-formyltripeptides were bound to the dimer.

Control of translational repression by protein-protein interactions.

The coat protein of the RNA bacteriophage MS2 is a translational repressor and interacts with a specific RNA stem-loop to inhibit translation of the viral replicase gene. As part of an effort to dissect genetically its RNA binding function, mutations were identified in the coat protein sequence that suppress mutational defects in the translational operator. Each of the mutants displayed a super-repressor phenotype, repressing translation from the wild-type and a variety of mutant operators better than did the wild-type coat protein. At least one mutant probably binds RNA more tightly than wild-type. The other mutants, however, were defective for assembly of virus-like particles, and self-associated predominantly as dimers. It is proposed that this assembly defect accounts for their super-repressor characteristics, since failure to assemble into virus-like particles elevates the effective concentration of repressor dimers. This hypothesis is supported by the observation that deletion of thirteen amino acids known to be important for assembly of dimers into capsids also resulted in the same assembly defect and in super-repressor activity. A second class of assembly defects is also described. Deletion of two amino acids from the C-terminus of coat protein resulted in failure to form capsids, most of the coat protein having the apparent molecular weight expected of trimers. This mutant (dl-8) was completely defective for repressor activity, probably because of an inability to form dimers. These results point out the inter-dependence of the structural and regulatory functions of coat protein.

Pressure-induced conformational changes in a human Bence-Jones protein (Mcg).

The effect of high static pressures on the internal structure of the immunoglobulin light chain (Bence-Jones) dimer from the patient Mcg was assessed with measurements of intrinsic protein fluorescence polarization and intensity. Depolarization of intrinsic fluorescence was observed at relatively low pressures (less than 2 kbar), with a standard volume change of -93 mL/mol. The significant conformational changes indicated by these observations were not attributable to major protein unfolding, since pressures exceeding 2 kbar were required to alter intrinsic fluorescence emission maxima and yields. Fluorescence intensity and polarization measurements were used to investigate pressure effects on the binding of bis(8-anilino-naphthalene-1-sulfonate) (bis-ANS), rhodamine 123, and bis(N-methylacridinium nitrate) (lucigenin). Below 1.5 kbar the Mcg dimer exhibited a small decrease in affinity for bis-ANS (standard volume change approximately 5.9 mL/mol). At 3 kbar the binding activity increased by greater than 250-fold (volume change -144 mL/mol) and remained 10-fold higher than its starting value after decompression. With rhodamine 123 the binding activity showed an initial linear increase but plateaued at pressures greater than 1.5 kbar (standard volume change -23 mL/mol). These pressure effects were completely reversible. Binding activity with lucigenin increased slightly at low pressures (standard volume change -5.5 mL/mol), but the protein was partially denatured at pressures greater than 2 kbar. Taken in concert with the results of parallel binding studies in crystals of the Mcg dimer, these observations support the concept of a large malleable binding region with broad specificity for aromatic compounds.(ABSTRACT TRUNCATED AT 250 WORDS)

Common molecular scaffold for two unrelated RGD molecules.

The sequence arginine-glycine-aspartic acid (RGD) is important for recognition of cell adhesion proteins by cell surface receptors (integrins). This tripeptide sequence is present in a number of proteins including fibronectin, vitronectin, von Willebrand factor and fibrinogen. Specific and selective binding of the RGD sequence by different receptors suggests that the conformational orientation of the tripeptide is critical for stereochemical recognition. The crystal structures of two proteins that contain the RGD signal were determined: (i) the cell-binding type III module of fibronectin (FNIII10) and (ii) an anti-receptor antibody fragment (OPG2) that is a functional RGD ligand mimic with an RYD recognition site in the variable (VH) domain. Both of these modules are folded into beta-barrels with two layers of antiparallel beta-sheets enclosing a hydrophobic core. Since these molecules each contain the RGD (RYD) sequence, there is a unique opportunity for direct structural comparison. The comparison has defined a common molecular scaffold in these two unrelated molecules. Within this framework, the RGD (RYD) sites are located in structurally related loops in the two modules, i.e. at one end of the scaffold in a long loop connecting the last two strands in one of the beta-sheets. This shared scaffold is used for the stereochemical presentation of the RGD site for receptor recognition.