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.

Local and transmitted conformational changes on complexation of an anti-sweetener Fab.

Crystal structures of an Fab (NC6.8) from a murine IgG2b(kappa) antibody and its complex with a sweet-tasting, N-,N'-,N"-trisubstituted guanidine compound (NC174) have been determined by X-ray analysis. Both crystal forms are produced by a microseeding technique in polyethylene glycol (PEG) 8000 but the habits and space groups are very different. The native protein crystallizes as plates in the monoclinic space group C2 and the complex crystallizes as prisms in the orthorhombic space group P2(1)2(1)2. The structures were solved by molecular replacement methods, with the Fab fragments from the 4-4-20, HyHel-5 and BV04-01 antibodies as starting models. On binding of the ligand, N-(p-cyanophenyl)-N'-(diphenylmethyl)-N"-(carboxymethyl)g uan idine, the protein exhibits significant local conformational changes in the active site, particularly in the third complementarity-determining region (CDR3) of the heavy chain. The ligand enters the small crevice by end-on insertion with the cyanophenyl group in the lead and the diphenyl rings partially protruding from the entrance. No strict pi-pi stacking interactions are observed. However, tyrosine L32 (CDR1), tyrosine L96 (CDR3) and tryptophan H33 (CDR1) help immobilize the cyanophenyl ring and guanido group, and tyrosine H96 moves about 4.5 A to lie between the rings of the diphenyl group. The positive charge on the guanido group is compensated by glutamic acid H50 (CDR2) while the negative charge on acetic acid is neutralized by arginine H56 (CDR2) and by hydrogen bonding with asparagine H58 (CDR2). Water molecules participate in the binding process by hydrogen bonding with the cyano and guanido groups. The mechanism of binding is a clear example of induced fit. Like hemoglobin, the NC6.8 Fab can be classified as an allosteric protein, since its overall structure is altered by the binding of a small ligand. In crystals of the native Fab the elbow bend angle is 184 degrees while in crystals of the complex the elbow angle is 153 degrees. There is also a reciprocal push-pull type of change where the heavy chain is flexed and the light chain is extended. The tail of the heavy chain, which would be connected to the Fc in an intact antibody, is displaced 19 A relative to its position in the unliganded Fab. Within the limited series of sweetener-Fab complexes we have thus far examined, only the NC174 hapten has produced such results.(ABSTRACT TRUNCATED AT 400 WORDS)

Three-dimensional structure of an Fv from a human IgM immunoglobulin.

An IgM(kappa) immunoglobulin from a patient (Pot) with Waldenstrom's macroglobulinemia was hydrolyzed with pepsin to release a fragment consisting of the 'variable' (V) domains of the light and heavy chains plus eight residue 'tails' from the 'constant' (C) domains. The crystal structure of this fragment was determined at 2.3 A resolution by molecular replacement and crystallographic refinement methods. When examined separately, the light chain component closely resembles another human kappa chain (Rei) in both the beta-pleated sheet regions and the 'hypervariable' loops. The conserved pleated sheets in the heavy chain are similar to those in the human Kol IgG1 protein, but the third hypervariable loop in particular is different from that in any immunoglobulin structure described to date. As in the Kol protein, this loop blocks the access to any internal active site along the light-heavy chain interface. Unlike the Kol protein, however, the loop does not protrude beyond the boundaries of a conventional antigen combining site. Instead, it forms a very compact structure, which fills almost all residual space between the domains. This is an example of one dominant complementarity-determining region (CDR) essentially negating the diversity possible with five other CDRs in the two chains. Ordered water molecules are associated with light chain constituents along the interface, but not with CDR3 of the heavy chain. In screening exercises the Pot IgM failed to bind a wide variety of peptides. Together, the results suggest that ligand binding can only occur on external surfaces of the protein. These surfaces carry a limited number of side chains usually assigned to CDRs in more typical antibodies.

The three-dimensional structure of a complex of a murine Fab (NC10. 14) with a potent sweetener (NC174): an illustration of structural diversity in antigen recognition by immunoglobulins.

The three-dimensional structure of a complex of an Fab from a murine IgG2b(lambda) antibody (NC10.14) with a high potency sweet tasting hap- ten, N-(p-cyanophenyl)-N'-(diphenylmethyl)-N"-(carboxymethyl)guan idine (NC174), has been determined to 2.6 A resolution by X-ray crystallography. This complex crystallized in the triclinic space group P1, with two molecules in the asymmetric unit. In contrast to a companion monoclonal antibody (NC6.8) with a kappa-type light chain and similar high affinity for the NC174 ligand, the NC10.14 antibody possessed a large and deep antigen combining site bounded primarily by the third complementarity-determining regions (CDR3s) of the light and heavy chains. CDR3 of the heavy chain dominated the site and its crown protruded into the external solvent as a type 1' beta-turn. NC174 was nested against HCDR3 and was held in place by two tryptophan side-chains (L91 and L96) from LCDR3. The diphenyl rings were accommodated on an upper tier of the binding pocket that is largely hydrophobic. At the floor of the site, a positively charged arginine side-chain (H95) stabilized the orientation of the electronegative cyano group of the hapten. The negative charge on the acetate group was partially neutralized by a hydrogen bond with the phenolic hydroxyl group of tyrosine H58. Comparisons of the modes of binding of NC174 to the NC6.8 and NC10.14 antibodies illustrate the enormous structural and mechanistic diversity manifest by immune responses.

T-cell receptor-derived peptides in immunoregulation and therapy of retrovirally induced immunosuppression.

Retrovirally infected humans and mice showed progressive acquired immunodeficiency accompanied by the production of elevated levels of autoantibodies directed against T-cell receptor variable-domain epitopes. Epitope mapping analyses indicated that a major determinant recognized was defined by a 16-mer peptide containing the entire CDR1 segment and part of the FR2 region of human Vbeta8, and that both species showed reactivity to the same sequence. Either prophylactic or therapeutic administration of this peptide to retrovirus-infected C57/BL/6 mice normalized the balance of T(H)1- and T(H)2-type helper activity and restored the resistance to infection by the opportunistic parasite Cryptosporidium. Administration of the peptide did not generate significantly increased levels of autoantibody, but had a profound effect on T-cell activity as well as other aspects of inflammation, including NK-cell activity. A 16-mer derived from the Jbeta sequence showed similar functional effects on T cells from retrovirus-infected mice. Direct binding of the VbetaCDR1 peptide to recombinant TCR Valpha/Vbeta constructs, as well as to IgM natural autoantibodies, suggests that the cell surface receptor for the peptide is the alpha/beta TCR on T cells and surface IgM in B cells. The Vbeta CDR1 peptide stimulated division of murine splenocytes in vitro, stimulated the production of the T(H)1 cytokine IL-2, and synergized with the T-cell mitogen concanavalin A in proliferation and IL-2 production. These studies indicate that administration of peptides derived from T-cell receptor variable domains to animals immunosuppressed as a result of retroviral infection has a profound immunomodulatory effect enhancing overall T-cell functional capacity, particularly with respect to the cytokine production characteristic of T(H)1-type cells. Our studies are interpreted in the context of other recent investigations of immunomodulatory peptides.

Localization of an idiotope on the L chain dimer and intact IgG1 immunoglobulin from the patient Mcg.

A monoclonal anti-idiotype (M3.9) raised against the covalently linked Mcg lambda chain dimer binds with a similar affinity to the Mcg IgG immunoglobulin and covalent heterodimers of Mcg with other human L chains. Despite having identical amino acid sequences, the two light chains in the Mcg dimer adopt different conformations with monomer 1 acting as a heavy chain analog and monomer 2 behaving like a light chain component of an Fab. As the lambda chain in the Mcg IgG and at least one hybrid L chain dimer (Mcg X Weir) assumes a conformation similar to that of monomer 2 and the binding of anti-idiotype requires only the presence of a single Mcg lambda chain, we conclude that the idiotope is restricted to the monomer 2 type of the Mcg lambda chain conformational isomer. Cooperative binding of two molecules of rhodamine 123 in the main cavity of the Mcg dimer block the binding of the anti-idiotype whereas the binding of one molecule of bis(DNP)lysine has no significant effect on the idiotype-anti-idiotype system. Previous crystallographic analyses indicated that bound rhodamine 123 protrudes outside the rim while bis(DNP)lysine is completely immersed in the cavity. At high concns bis(DNP)lysine penetrates through the floor of the main cavity and forms a virtually irreversible complex with the dimer. Production of this complex is accompanied by conformational changes, which are presumed to be correlated with observed inhibition of binding with the anti-idiotype M3.9. Expression of the idiotope probably involves more than one linear sequence since reduction and alkylation of the intra- and inter-chain disulphide bonds in 8 M urea leads to a complete loss of binding of the anti-idiotype. The inhibition data suggest involvement of residues on or near the rim of the main cavity. Distribution of potential contact residues for rhodamine 123 is asymmetric only in the case of aspartic acid 97, which is located on the cavity rim in only one conformational isomer (monomer 2). The homologous residue in monomer 1 is directed away from the cavity and is unlikely to participate in the epitope recognized by M3.9. Attempts to define the epitope in more detail by simulation with multiple peptides have been initiated in collaboration with the laboratory of H. M. Geysen.

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.

Similar binding properties of peptide ligands for a human immunoglobulin and its light chain dimer.

The urinary light chain dimer and serum monoclonal IgG1 protein from a patient (Mcg) with multiple myeloma and amyloidosis were systematically tested for their binding activities to peptides presented on solid supports. The system was validated using a series of enkephalins, beta-casomorphins and DNP-lysine derivatives which were known to complex with the dimer. Sets of peptide ligands binding to the proteins were constructed by incremental additions of amino acid residues to minimal binding units [Geysen et al., J. Immun. Meth. 102, 259-274 (1987)]. Both the amino acid sequences and the combinations of optical isomers were optimized at each stage of the syntheses. Binding could be demonstrated for ligands ranging in size from a tethered single amino acid to pentapeptides. At the dipeptide levels, the dimer and the IgG1 protein showed different preferences (Hp versus qf, where lower case letters designate D-amino acid residues). However, in a tetrapeptide ligand (qfHp) for the dimer, both of these initial preferences had converged. With few exceptions, the IgG1 molecule showed binding activity for the ligands developed for the dimer. Two sets of selected peptides, one based on Hp and the other on mW, were synthesized for diffusion into crystals of the dimer. X-ray analyses showed that these peptides bound exclusively in the main binding cavity between the "variable" domains of the dimer. As predicted from the ELISA results with tethered ligands, the relative occupancies in the crystals followed the order of tetrapeptide greater than tripeptide much greater than dipeptide. The crystallographic studies confirmed that peptides with very different sequences can bind in the same cavity.

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.

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.

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)

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.

An unusual human IgM antibody with a protruding HCDR3 and high avidity for its peptide ligands.

The crystal structure of the Fv molecule from a human monoclonal IgM cryoglobulin (Mez) was determined at 2.6 A resolution. Amino acid sequences of framework regions (FR) of the Mez light (L) and heavy (H) chain variable domains (VL and VH) are highly similar to their counterparts in another human Fv (Pot) previously subjected to X-ray analysis in our laboratory. As expected, the three-dimensional (3-D) structures of FR are quite similar in the two proteins, as are four of the six complementarity-determining regions (CDRs): CDRs 1 and 2 for both L and H chains. Absence of Pro 95L from the LCDR3 loop in Mez VL (relative to Pot LCDR3) results in compression of this loop and creates more space in the VL-VH interface. In the two IgMs, HCDR3 conformations differ significantly from all previously defined conformations for these loops. Pot has a 12-residue HCDR3 that collapses to fill all available space in the VL-VH domain interface, resulting in the formation of a relatively flat platform for antigen binding. In Mez, the HCDR3 is two residues longer and is comprehensively different. A semi-rigid ascending segment dominated by a Pro-Pro-Tyr sequence protrudes out into solvent. The descending portion has the sequence Gly-Trp-Gly-Gly-Gly, which promotes high local flexibility. This segment folds across the VL-VH domain interface to interact with residues in LCDR3. These features partition the Mez active site into two compartments, a large cavity between VL and VH and a smaller cavity lined entirely by constituents of the three heavy chain CDRs. Such an unusual topographical feature indicates why the Mez IgM does not bind to the Fc portion of intact human IgG antibodies in immunoassays yet interacts with high avidity with many Fc-derived octapeptides. The cavities are expected to be the repositories for the Fc-derived peptides, while the semi-rigid protrusion of the Mez HCDR3 prevents the close approach of another macromolecule (e.g. intact IgG) to the active site.

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.

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.

Treatment of osteoarthritis with aspartame.

OBJECTIVE: The binding of sweet-tasting compounds in a human (Mcg) Bence-Jones dimer has been characterized by x-ray crystallography. Aspartame binding in this immunoglobulin fragment is remarkable. Unexpected pain relief noted by A.B.E., a crystallographer with diagnosed osteoarthritis, suggested that the accommodation of aspartame in the active site of the dimer may represent surrogate binding by other proteins, with analgesia as the outcome. METHODS: X-ray analysis of the complex of aspartame and the Bence-Jones dimer was conducted with crystalline Mcg protein and pure aspartame. A single-blind (n = 1) study to confirm analgesia was completed by administration of aspartame to A.B.E. A controlled double-blind trial was performed in patients with x-ray-documented osteoarthritis. Pain and performance changes were evaluated with use of two doses of placebo and two doses of aspartame. Effects on bleeding time were then evaluated by determination of template bleeding times in 34 normal volunteers. Finally, antipyretic effects were studied in Sprague-Dawley rats given intramuscular turpentine injections. RESULTS: Aspartame binding in the Bence-Jones dimer was verified by x-ray crystallography. Improvements in performance and pain relief were observed in A.B.E. at p < 0.001. Decreased pain and improved performance were also observed in patients with osteoarthritis (p < 0.001). Mild antihemostatic responses were observed in bleeding times after aspartame treatment. Modified template bleeding times increased at p < 0.01. Aspartame blocked the turpentine-mediated febrile responses in the treated rats (p < 0.01). CONCLUSIONS: L-Aspartyl-L-phenylalanine methyl ester is biologically active and appears to relieve pain, induce mild antithrombotic effects in humans, and decrease fever in animals.

Cell surface recognition and the immunoglobulin superfamily.

Immunoglobulins serve as humoral recognition and effector molecules and as antigen-specific cell surface receptors on B and T cells. These molecules are constructed according to a characteristic domain pattern. Variable and constant domains diverged from one another early in vertebrate evolution, and they are joined by a "switch peptide" specified by the joining gene segments. Peptides specified by J-gene segments are strongly conserved in evolution in comparison among Ig light chains and T-cell receptors. Molecules less strongly related to Ig domains have been assembled into an Ig "superfamily" where the identities to classical IgC or V domains are < or = 20%. Among these are cell surface adhesion molecules, receptors for cytokines, and Fc receptors. Moreover, MHC antigens have an Ig-like membrane-proximal domain significantly related to IgC regions. We will analyze putative evolutionary relationships among canonical Igs and members of the Ig superfamily using highly conserved sequences from light and heavy chains of primitive vertebrates (e.g., the sandbar shark) as prototypes to ascertain similarities between Ig-related molecules of vertebrates and invertebrates.

Immunoglobulin cross-reactivity examined by library screening, crystallography and docking studies.

Antibodies are extremely diverse with respect to their specificities and affinities for target molecules. Despite rigorous selection, some antibodies are cross-reactive whereby they recognize their natural antigens along with other molecules. In this review, we discuss our efforts toward understanding the cross-reactivity of selected immunoglobulins. Investigations that are discussed employed screens of combinatorial peptide libraries, crystallography of ligand-protein complexes, and computer-based peptide docking simulations. In the first example, two different antibodies (NC6.8 and NC10.14) bound the same trisubstituted guanidine (NC174) with similar affinities, but utilized predominantly dissimilar binding strategies. However, there was one common binding strategy, in which the cyanophenyl portion of NC174 was inserted end-on into the binding crevices of the NC6.8 and NC10.14 antibodies. In the second example, scanning of peptide libraries and X-ray crystallography were used to design and test synthetic peptides for binding to the Mcg L chain dimer. Again, end-on insertion was favored for all peptides larger than dipeptides in the voluminous Mcg binding cavity. Finally, automated docking was used for rapid predictions of complexes for the Fv molecule from a broadly cross-reactive human IgM (Mez) and nearly two thousand peptides. Certain amino acids, including the aromatic residues Trp and Phe, functioned as anchoring groups in automated docking. Anchoring groups acted in most of the peptides that were otherwise accommodated by a variety of binding strategies in the docked complexes. We suggest that anchoring of at least a portion of a ligand in a binding site is a common mechanism for antibody recognition.