Porphyrin binding to jacalin is facilitated by the inherent plasticity of the carbohydrate-binding site: novel mode of lectin–ligand interaction

The crystal structure of the complex of meso-tetrasulfonatophenylporphyrin (H(2)TPPS) with jack fruit (Artocarpus integriflora) agglutinin (jacalin) has been determined at 1.8 A resolution. A porphyrin pair is sandwiched between two symmetry-related jacalin monomers in the crystal, leading to a cross-linking network of protein molecules. Apart from the stacking interactions, H(2)TPPS also forms hydrogen bonds, some involving water bridges, with jacalin at the carbohydrate-binding site. The residues that are involved in rendering galactopyranoside specificity to jacalin undergo conformational adjustments in order to accommodate the H(2)TPPS molecule. The water molecules at the carbohydrate-binding site of jacalin cement the jacalin-porphyrin interactions, optimizing their complementarity. Interactions of porphyrin with jacalin are relatively weak compared with those observed between galactopyranoside and jacalin, perhaps because the former largely involves water-mediated hydrogen bonds. While H(2)TPPS binds to jacalin at the carbohydrate-binding site as in the case of ConA, its mode of interaction with jacalin is very different. H(2)TPPS does not enter the carbohydrate-binding cavity of jacalin. Instead, it sits over the binding site. While the porphyrin binding is mediated by replicating the hydrogen-bonding network of mannopyranoside through the sulfonate atoms in the case of ConA, the plasticity associated with the carbohydrate-binding site accommodates the pluripotent porphyrin molecule in the case of jacalin through an entirely different set of interactions.

Structure of the induced antibacterial protein from tasar silkworm, Antheraea mylitta. Implications to molecular evolution

The crystal structure of an antibacterial protein of immune origin (TSWAB), purified from tasar silkworm (Antheraea mylitta) larvae after induction by Escherichia coli infection, has been determined. This is the first insect lysozyme structure and represents induced lysozymes of innate immunity. The core structure of TSWAB is similar to c-type lysozymes and alpha-lactalbumins. However, TSWAB shows significant differences with respect to the other two proteins in the exposed loop regions. The catalytic residues in TSWAB are conserved with respect to the chicken lysozyme, indicating a common mechanism of action. However, differences in the noncatalytic residues in the substrate binding groove imply subtle differences in the specificity and the level of activity. Thus, conformational differences between TSWAB and chicken lysozyme exist, whereas functional mechanisms appear to be similar. On the other hand, alpha-lactalbumins and c-type lysozymes exhibit drastically different functions with conserved molecular conformation. It is evident that a common molecular scaffold is exploited in the three enzymes for apparently different physiological roles. It can be inferred on the basis of the structure-function comparison of these three proteins having common phylogenetic origin that the conformational changes in a protein are minimal during rapid evolution as compared with those in the normal course of evolution.

Functional equality in the absence of structural similarity: an added dimension to molecular mimicry

The crystal structure of meso-tetrasulfonatophenylporphyrin complexed with concanavalin A (ConA) was determined at 1.9 A resolution. Comparison of this structure with that of ConA bound to methyl alpha-d-mannopyranoside provided direct structural evidence of molecular mimicry in the context of ligand receptor binding. The sulfonatophenyl group of meso-tetrasulfonatophenylporphyrin occupies the same binding site on ConA as that of methyl alpha-d-mannopyranoside, a natural ligand. A pair of stacked porphyrin molecules stabilizes the crystal structure by end-to-end cross-linking with ConA resulting in a network similar to that observed upon agglutination of cells by lectins. The porphyrin binds to ConA predominantly through hydrogen bonds and water-mediated interactions. The sandwiched water molecules in the complex play a cementing role, facilitating favorable binding of porphyrin. Seven of the eight hydrogen bonds observed between methyl alpha-d-mannopyranoside and ConA are mimicked by the sulfonatophenyl group of porphyrin after incorporating two water molecules. Thus, the similarity in chemical interactions was manifested in terms of functional mimicry despite the obvious structural dissimilarity between the sugar and the porphyrin.

Enhanced binding of a rationally designed peptide ligand of concanavalin a arises from improved geometrical complementarity

The structural basis of affinity enhancement was addressed by analyzing the interactions between concanavalin A and the carbohydrate-mimicking peptide ligands. Based on the crystal structures of concanavalin A in complex with these peptides [Jain, D., Kaur, K. J., Sundaravadivel, B., and Salunke, D. M. (2000) J. Biol. Chem. 275, 16098-16102; Jain, D., Kaur, K. J., and Salunke, D. M. (2001) Biophys. J. 80, 2912-2921], a high-affinity analogue was designed. This analogue (acetyl-MYWYPY-amide) binds to the lectin with 32-fold enhanced affinity compared to the corresponding precursor peptides. The crystal structure of concanavalin A bound to the designed peptide has been determined. A peptide molecule binds to each of the crystallographically independent monomers of the tetrameric lectin. The four bound peptide molecules exhibit two major conformations both of which are extended. Unlike in the case of other concanavalin A binding peptides, the structural variations within different conformers of this analogue are marginal. It is apparent that the deletion of the structurally variable region of the larger peptides has led to an improved complementarity and increased buried surface area in the case of the designed peptide. The crystal structure also showed the formation of two backbone hydrogen bonds between the ligand and the ligate which were not present in the complexes of the precursor peptides. The observed structural features adequately explain the enhanced binding of the designed analogue.

Evidence for clustered mannose as a new ligand for hyaluronan- binding protein (HABP1) from human fibroblasts

We have earlier reported that overexpression of the gene encoding human hyaluronan-binding protein (HABP1) is functionally active, as it binds specifically with hyaluronan (HA). In this communication, we confirm the collapse of the filamentous and branched structure of HA by interaction with increasing concentrations of recombinant-HABP1 (rHABP1). HA is the reported ligand of rHABP1. Here, we show the affinity of rHABP1 towards D-mannosylated albumin (DMA) by overlay assay and purification using a DMA affinity column. Our data suggests that DMA is another ligand for HABP1. Furthermore, we have observed that DMA inhibits the binding of HA in a concentration-dependent manner, suggesting its multiligand affinity amongst carbohydrates. rHABP1 shows differential affinity towards HA and DMA which depends on pH and ionic strength. These data suggest that affinity of rHABP1 towards different ligands is regulated by the microenvironment.

Plasticity in protein-peptide recognition: crystal structures of two different peptides bound to concanavalin A

The structures of concanavalin A (ConA) in complex with two carbohydrate-mimicking peptides, 10-mer (MYWYPYASGS) and 15-mer (RVWYPYGSYLTASGS) have been determined at 2.75 A resolution. In both crystal structures four independent peptide molecules bind to each of the crystallographically independent subunits of ConA tetramer. The peptides exhibit small but significant variability in conformations and interactions while binding to ConA. The crystal structure of another similar peptide, 12-mer (DVFYPYPYASGS), in complex with ConA has been determined (Jain, D., K. J. Kaur, B. Sundaravadivel, and D. M. Salunke. 2000. Structural and functional consequences of peptide-carbohydrate mimicry. J. Biol. Chem. 275:16098-16102). Comparison of the three complexes shows that the peptides bind to ConA at a common binding site, using different contacting residues and interactions depending on their sequence and the local environment at the binding site. The binding is also optimized by corresponding plasticity of the peptide binding site on ConA. The diversity in conformation and interactions observed here are in agreement with the structural leeway concerning plasticity of specific molecular recognition in biological processes. The adaptability of peptide-ConA interactions may also be correlated with the carbohydrate-mimicking property of these peptides.

Mechanism of specific target recognition and RNA hydrolysis by ribonucleolytic toxin restrictocin

Restrictocin, a member of the fungal ribotoxin family, specifically cleaves a single phosphodiester bond in the 28S rRNA and potently inhibits eukaryotic protein synthesis. Residues Tyr47, His49, Glu95, Phe96, Pro97, Arg120, and His136 have been predicted to form the active site of restrictocin. In this study, we have individually mutated these amino acids to alanine to probe their role in restrictocin structure and function. The role of Tyr47, His49, Arg120, and His136 was further investigated by making additional mutants. Mutating Arg120 or His136 to alanine or the other amino acids rendered the toxin completely inactive, whereas mutating Glu95 to alanine only partially inactivated the toxin. Mutation of Phe96 and Pro97 to Ala had no effect on the activity of restrictocin. The Tyr47 to alanine mutant was inactive in inhibiting protein synthesis, and had a nonspecific ribonuclease activity on 28S rRNA similar to that shown previously for the His49 to Ala mutant. Unlike the His136 to Ala mutant, the double mutants containing Tyr47 or His49 mutated to alanine along with His136 did not compete with restrictocin to cause a significant reduction in the extent of cleavage of 28S rRNA. In a model of restrictocin and a 29-mer RNA substrate complex, residues Tyr47, His49, Glu95, Arg120, and His136 were found to be near the cleavage site on RNA. It is proposed that in restrictocin Glu95 and His136 are directly involved in catalysis, Arg120 is involved in the stabilization of the enzyme-substrate complex, Tyr47 provides structural stability to the active site, and His49 determines the substrate specificity.

Immunological implications of structural mimicry between a dodecapeptide and a carbohydrate moiety

The immunogenicity and antibody cross-reactivity of two chemically different but structurally equivalent molecular mimics were analyzed by presenting them to the immune system in different modes. The observed differences in IgM and IgG responses in terms of cross-reactivity with the mimicking antigen could reflect the differential proliferative abilities of the corresponding B-cells. Modification of the T-cell help, either by using a promiscuous T-cell epitope or by prepriming, led to the shift in the antibody response towards the mimicking epitope. Also, the anti-sugar antibodies could be boosted using a carbohydrate mimicking peptide on cross-immunization. Thus, the carbohydrate-peptide mimicry appears to be a topological quasi-equivalence reflected differently in terms of antibody response during maturation.

Analysis of sequence signature defining functional specificity and structural stability in helix-loop-helix proteins

Specific functional properties of many proteins directing developmental responses via transcriptional regulation are orchestrated by their characteristic helix-loop-helix (HLH) structural motif. The entire HLH motif in all these proteins assumes a common conformation irrespective of their individual biological effects. The motif controls the affinity of HLH proteins for homo- or heterodimerization, permitting mixing and matching of regulatory factors, and thereby expanding the functional repertoire. Systematic analysis of molecular contacts at the dimer interface using the models built for the functional dimers combined with the pattern of conserved/nonconserved residues within different categories of HLH proteins helped in understanding the differential role played by different residues at the dimer interface for expressing corresponding functions. The residues associated with the self and partner interactions were identified, and the signature residues contributing toward dimeric stability and functional specificity were defined. It is evident that most of the residues involved in self interactions are common among all the HLH proteins. However, while certain residues involved in partner interactions are common among all the HLH proteins, certain others are common within a category, and still others vary widely defining specificity signature at different levels.

Crystal structure of an antibody bound to an immunodominant peptide epitope: novel features in peptide-antibody recognition

The crystal structure of Fab of an Ab PC283 complexed with its corresponding peptide Ag, PS1 (HQLDPAFGANSTNPD), derived from the hepatitis B virus surface Ag was determined. The PS1 stretch Gln2P to Phe7P is present in the Ag binding site of the Ab, while the next three residues of the peptide are raised above the binding groove. The residues Ser11P, Thr12P, and Asn13P then loop back onto the Ag-binding site of the Ab. The last two residues, Pro14P and Asp15P, extend outside the binding site without forming any contacts with the Ab. The PC283-PS1 complex is among the few examples where the light chain complementarity-determining regions show more interactions than the heavy chain complementarity-determining regions, and a distal framework residue is involved in Ag binding. As seen from the crystal structure, most of the contacts between peptide and Ab are through the five residues, Leu3-Asp4-Pro5-Ala6-Phe7, of PS1. The paratope is predominantly hydrophobic with aromatic residues lining the binding pocket, although a salt bridge also contributes to stabilizing the Ag-Ab interaction. The molecular surface area buried upon PS1 binding is 756 A(2) for the peptide and 625 A(2) for the Fab, which is higher than what has been seen to date for Ab-peptide complexes. A comparison between PC283 structure and a homology model of its germline ancestor suggests that paratope optimization for PS1 occurs by improving both charge and shape complementarity.

Maturation of an antibody response is governed by modulations in flexibility of the antigen-combining site

Although affinity maturation constitutes an integral part of T-dependent humoral responses, its structural basis is less well understood. We compared the physicochemical properties of antigen binding of several independent antibody panels derived from both germline and secondary responses. We found that antibody maturation essentially reflects modulations in entropy-control of the association, but not dissociation, step of the binding. This influence stems from variations in conformational heterogeneity of the antigen-combining site, which in turn regulates both the affinity and specificity for antigen. Thus, the simple device of manipulating conformational flexibility of paratope provides a mechanism wherein the transition from a degenerate recognition capability to a high-fidelity effector response is readily achieved, with the minimum of somatic mutations.

Structural basis of functional mimicry between carbohydrate and peptide ligands of con A

Crystallographic studies have shown independent binding sites for sugar and peptide ligands of concanavalin A, although they were considered functional mimics based on biochemical experiments. The topological correlation of 12-residue peptide with different carbohydrate ligands of concanavalin A showed similarity between trimannose and the YPY region of the peptide establishing structural mimicry. Molecular docking of trimannose and the YPY motif on the reciprocal binding sites revealed equivalent interactions and energetics implying that the peptide-binding sites may constitute additional sugar-binding subsites of concanavalin A. The binding of a mannose-rich neoglycoprotein with significantly higher affinity compared with that of the methyl alpha-d-mannopyranoside is consistent with this interpretation.

Structural and functional consequences of peptide-carbohydrate mimicry. Crystal structure of a carbohydrate-mimicking peptide bound to concanavalin A

The functional consequences of peptide-carbohydrate mimicry were analyzed on the basis of the crystal structure of concanavalin A (ConA) in complex with a carbohydrate-mimicking peptide, DVFYPYPYASGS. The peptide binds to the non-crystallographically related monomers of two independent dimers of ConA in two different modes, in slightly different conformations, demonstrating structural adaptability in ConA-peptide recognition. In one mode, the peptide has maximum interactions with ConA, and in the other, it shows relatively fewer contacts within this site but significant contacts with the symmetry-related subunit. Neither of the peptide binding sites overlaps with the structurally characterized mannose and trimannose binding sites on ConA. Despite this, the functional mimicry between the peptide and carbohydrate ligands was evident. The peptide-inhibited ConA induced T cell proliferation in a dose-dependent manner. The effect of the designed analogs of the peptide on ConA-induced T cell proliferation and their recognition by the antibody response against alpha-d-mannopyranoside indicate a role for aromatic residues in functional mimicry. Although the functional mimicry was observed between the peptide and carbohydrate moieties, the crystal structure of the ConA-peptide complex revealed that the two peptide binding sites are independent of the methyl alpha-d-mannopyranoside binding site.

Structure-function analysis of tritrypticin, an antibacterial peptide of innate immune origin

The structural requirements for the antibacterial activity of a pseudosymmetric 13-residue peptide, tritrypticin, were analyzed by combining pattern recognition in protein structures, the structure-activity knowledge-base, and circular dichroism. The structure-activity analysis, based on various deletion analogs, led to the identification of two minimal functional peptides, which by themselves exhibit adequate antibacterial activity against Escherichia coli and Salmonella typhimurium. The common features between these two peptides are that they both share an aromatic-proline-aromatic (ArProAr) sequence motif, and their sequences are retro with respect to one another. The pattern searches in protein structure data base using the ArProAr motif led to the identification of two distinct conformational clusters, namely polyproline type II and beta-turn, which correspond to the observed solution structures of the two minimal functional analogs. The role of different residues in structure and function of tritrypticin was delineated by analyzing antibacterial activity and circular dichroism spectra of various designed analogs. Three main results arise from this study. First, the ArProAr sequence motif in proteins has definitive conformational features associated with it. Second, the two minimal bioactive domains of tritrypticin have entirely different structures while having equivalent activities. Third, tritrypticin has a beta-turn conformation in solution, but the functionally relevant conformation of this gene-encoded peptide antibiotic may be an extended polyproline type II.

Secretion of glutathione S-transferase isoforms in the seminiferous tubular fluid, tissue distribution and sex steroid binding by rat GSTM1

The seminiferous tubular fluid (STF) provides the microenvironment necessary for spermatogenesis in the adluminal compartment of the seminiferous tubule (ST), primarily through secretions of the Sertoli cell. Earlier studies from this laboratory demonstrated the presence of glutathione S-transferase (GST) in STF collected from adult rat testis and in the spent media of ST cultures. This study describes the cellular source, isoform composition and possible function of GSTs in the STF. The major GST isoforms present in STF in vivo share extensive N-terminal similarity with rat GSTM1 (rGSTM1), rGSTM2, rGSTM3 and rGST-Alpha. Molecular masses of rGSTM2, rGSTM3 and rGST-Alpha from liver and testis sources were similar, unlike STF-GSTM1, which was larger by 325 Da than its liver counterpart. Peptide digest analysis profiles on reverse-phase HPLC between liver and STF isoforms were identical, and N-terminal sequences of selected peptides obtained by digestion of the various isoforms were closely similar. The above results confirmed close structural similarity between liver and STF-GST isoforms. Active synthesis and secretion of GSTs by the STs were evident from recovery of radiolabelled GST from the spent media of ST cultures. Analysis of secreted GST isoforms showed that GST-Alpha was not secreted by the STs in vitro, whereas there was an induction of GST-Pi secretion. Detection of immunostainable GST-Mu in Sertoli cells in vitro and during different stages of the seminiferous epithelium in vivo, coupled with the recovery of radiolabelled GST from Sertoli cell-culture media, provided evidence for Sertoli cells as secretors of GST. In addition, STF of 'Sertoli cell only' animals showed no change in the profile of GST isoform secretion, thereby confirming Sertoli cells as prime GST secretors. Non-recovery of [35S]methionine-labelled GSTs from germ cell culture supernatants, but their presence in germ cell lysates, confirm the ability of the germ cells to synthesize, but not to release, GSTs. Functionally, STF-GSTM1 appeared to serve as a steroid-binding protein by its ability to bind to testosterone and oestradiol, two important hormones in the ST that are essential for spermatogenesis, with binding constants of <9.8x10(-7) M for testosterone and 9x10(-6) M for oestradiol respectively.

The crystal structure of recombinant rat pancreatic RNase A

The three-dimensional structure of rat pancreatic RNase A expressed in Escherichia coli was determined. The backbone conformations of certain critical loops are significantly different in this enzyme compared to its bovine counterpart. However, the core structure of rat RNase A is similar to that of the other members of the pancreatic ribonuclease family. The structural variations within a loop bordering the active site can be correlated with the subtle differences in the enzymatic activities of bovine and rat ribonucleases for different substrates. The most significant difference in the backbone conformation was observed in the loop 15-25. This loop incorporates the subtilisin cleavage site which is responsible for RNase A to RNase S conversion in the bovine enzyme. The rat enzyme does not get cleaved under identical conditions. Molecular docking of this region of the rat enzyme in the active site of subtilisin shows steric incompatibility, although the bovine pancreatic ribonuclease A appropriately fits into this active site. It is therefore inferred that the local conformation of the substrate governs the specificity of subtilisin.

Studies on glutathione S-transferases important for sperm function: evidence of catalytic activity-independent functions

Our earlier studies reported the identification of a rat testicular protein of 24 kDa with significant similarity at the N-terminus with Mu class glutathione S-transferases (GSTs). Treatment of goat sperm with antisera against this protein identified immunoreactive sites on the spermatozoa and inhibited in vitro fertilization of goat oocytes by the antibody-treated sperm. The above observations indicated the presence of GST-like molecule(s) important for fertility related events on goat spermatozoa. In this study, we report the purification of goat sperm GSTs (GSP1) which were purified by glutathione affinity chromatography and were enzymically active towards 1-chloro-2,4,-dinitrobenzene, a general GST substrate, and ethacrynic acid, a substrate for Pi class GSTs. GSP1 resolved into three major components on reverse-phase HPLC: peaks 1 and 2 with molecular masses of 26.5 kDa and peak 3 with a molecular mass of 25.5 kDa, as determined by SDS/PAGE. Multiple attempts to obtain N-terminal sequences of the first two peaks failed, indicating N-terminal block; however, they reacted to specific anti-Mu-GST antisera on Western blots and ELISA, and not to anti-Pi-GST antisera, which provides evidence for the presence of Mu-GST-reactive sites on peaks 1 and 2. The third component showed 80% N-terminal similarity with human and rat GSTP1-1 over an overlap of 15 amino acids, and reacted to anti-Pi-specific antisera in ELISA. Sperm labelled with antibodies against a 10-mer and an 11-mer peptide, designed from the N-terminal sequences of Mu and Pi class GSTs respectively, showed the presence of both Mu- and Pi-GST on goat sperm surface at distinct cellular domains. Selective inhibition of Pi class GST by the Pi-specific antisera, either at 0 h or at 3 h after initiation of sperm capacitation, leads to a reduction in fertilization rates. In contrast, the inhibition of Mu class GST by specific antisera at 0 h does not inhibit fertilization, although such treatment at 3 h after the initiation of capacitation reduces fertilization rates. The results indicate that both Pi- and Mu-GSTs are involved in fertilization, but the Mu-GST sites essential for fertilization are exposed only after 3 h of capacitation. The enzymic activity of GSP1 or live spermatozoa is not inhibited by the two antisera. The inability of the antibodies to cause such inhibition indicates that the reduction in fertilization rates and acrosome reaction caused by the antibodies is through a mechanism which does not interfere with the catalytic activity of the molecule. Therefore we established the presence of Pi and Mu class GST on goat sperm, their localization and their possible function in fertility-related events.

Helix-loop-helix motif in GnRH associated peptide is critical for negative regulation of prolactin secretion

The GnRH associated prolactin inhibiting factor (GAP) reveals the signature sequence associated with the helix-loop-helix structural motif. A number of different peptide fragments of GAP were designed, synthesized and analysed by circular dichroism and by an in vivo assay for prolactin secretion inhibiting activity. Peptides corresponding to the two individual alpha-helices and a 44-residue peptide comprising the entire helix-loop-helix motif show significant helical propensity in circular dichroism spectra. However, a peptide corresponding to the loop sequence shows no helical propensity. Albeit, the peptide corresponding to helix-loop-helix motif was found to inhibit prolactin secretion and augment circulating levels of gonadotropins in the in vivo assay; other shorter peptides did not show such activity. The activity profile of the 44-residue peptide was biphasic and very similar to that of the recombinant GAP. Thus, the prolactin inhibiting activity of this factor is defined by its helix-loop-helix motif as in the case of the transcription factors of developmental genes. The structural features of a homology-based model of GAP in complex with E47, a ubiquitous HLH-type developmental gene regulator, are consistent with the structural requirements of the negative regulation of transcription by helix-loop-helix proteins.

Ligand-induced receptor dimerization may be critical for signal transduction by choriogonadotropin

A mechanism of signal transduction by human choriogonadotropin (hCG) has been proposed. Competitive inhibition of the binding of hCG to its receptor by the serine protease inhibitors led to the identification of local structural homology of an extracellular region of the receptor with the reactive site loop of chymotrypsin inhibitor. Synthetic peptides from the extracellular domain of luteinizing hormone-choriogonadotropin (LH/CG) receptor, rationally designed on the basis of this homology, were found to affect hormone-receptor binding and bioactivity. A receptor peptide incorporating one complete structural unit of the leucine-rich repeats motif of the extracellular domain of the receptor significantly increased hCG-receptor binding in a dose-dependent manner. However, the testosterone production in a Leydig cell bioassay was inhibited in the presence of this peptide. The agonistic effect on the hCG-receptor binding and the antagonistic effect on the testosterone production of a receptor peptide suggests the possibility of more than one quasi-equivalent receptor-binding site on the hormone. Hormone-induced receptor oligomerization may therefore be involved in the mechanism of signal transduction by hCG.

The variable domain glycosylation in a monoclonal antibody specific to GnRH modulates antigen binding

Functionally important glycosylation has been identified in the antigen binding domain of an anti-GnRH monoclonal antibody. Presence of mannose and sialic acid residues is revealed from con A immunoblots and positive staining with a sialic acid detection kit, respectively. Desialylation of the antibody reduces GnRH binding, suggesting the role of terminal sialic acid residues in modulating antigen binding. The crystal structure of the Fab fragment shows electron density adjacent to the antigen binding site which may be attributed to the covalently attached carbohydrate moiety. Thus, the presence of sialic acid containing mannose-rich carbohydrate moiety near the antigen binding site of a monoclonal antibody Fab fragment is relevant for defining antibody specificity.

Topological analysis of the functional mimicry between a peptide and a carbohydrate moiety

The shared surface topology of two chemically dissimilar but functionally equivalent molecular structures has been analyzed. A carbohydrate moiety (alpha-D-mannopyranoside) and a peptide molecule (DVFYPYPYASGS) bind to concanavalin A at a common binding site. The cross-reactivity of the polyclonal antibodies (pAbs) was used for understanding the topological relationship between these two independent ligands. The anti-alpha-D-mannopyranoside pAbs recognized various peptide ligands of concanavalin A, and the anti-DVFYPYPYASGS pAbs recognized the carbohydrate ligands, providing direct evidence of molecular mimicry. On the basis of differential binding of various rationally designed peptide analogs to the anti-alpha-D-mannopyranoside pAbs, it was possible to identify different peptide residues critical for the mimicry. The comparison of circular dichroism profiles of the designed analogs suggests that the carbohydrate mimicking conformation of the peptide ligand incorporates a polyproline type II structural fold. The concanavalin A binding activity of these analogs was found to have a direct correlation with the topological relationship between peptide and carbohydrate ligands.

Crystallization and molecular packing analysis of barstar crystals

Barstar, the natural inhibitor of barnase crystallizes in many different crystal forms under almost identical conditions. Although barstar is a monomeric protein, it crystallizes with four molecules in the asymmetric unit in two crystal forms, rhombohedral (space group R3; a = b = 118.0 angstrum; c = 75.5 angstrum) and tetragonal (space group P4; a = b = 105.1 angstrum; c = 36.0 angstrum), which exist simultaneously under identical crystallization conditions. The relation between the four molecules in the asymmetric unit of the crystals belonging to space group P4 can be interpreted in terms of a small distortion in the crystallographic symmetry of the higher symmetry space group P422.

Computer modelling of the interaction between human choriogonadotropin and its receptor

Primary structural homology between the hormone binding site of the LH/CG receptor and the enzyme binding site of chymotrypsin inhibitor has been identified. This has led to the application of a knowledge-based approach of molecular modelling to describe the interaction of choriogonadotropin (CG) with the LH/CG receptor. A tertiary structural model for the mode of recognition between the hormone and the receptor has been proposed. As in other such processes at the molecular level, the recognition between CG and its receptor is mediated through non-covalent interactions. The specificity of recognition is achieved by complementarity in van der Waals surfaces, hydrogen bonding and non-polar associations. The model shows nine hydrogen bonds between the hormone and the receptor involving polar side chains as well as backbone amine and carbonyl groups. A hydrophobic cluster involving side chain groups at the interface is also important in stabilization of the intermolecular interactions.

The antigenic domain of flagellin from S. paratyphi shares a structural fold with subtilisin

Bacterial flagellin has two domains: the polymerizing domain consisting of N- and C-terminal regions which are partly disordered in the monomeric state; and the central antigenic domain with compact globular structure. The polymerizing domain is highly conserved in flagellins from different species but the antigenic domain is diverse in sequence and size. Whereas the former has direct functional significance for bacterial motility, the latter has not been identified as having a specific function except for defining the distinct serotype of the bacterium. The sequence alignment of flagellin from S. paratyphi with proteins of known three-dimensional structure reveals significant homology of the central 265 residue stretch with the bacterial serine protease, subtilisin. This homology is evident also in the comparison of the predicted secondary structure of flagellin with the observed secondary structural features in subtilisin. The deletions/insertions arising due to optimal alignment of the two proteins occur on the surface loops in the structure. Thus, a domain of S. paratyphi flagellin and subtilisin appear to have similar structural folds.

A novel computer modeling approach to the structures of small bioactive peptides: the structure of gonadotropin releasing hormone

A novel computer modeling approach suitable for the structure analysis of small bioactive peptides has been developed. This approach involves identification of conformational patterns in protein structure data bank based on the sequence homology with the bioactive peptide. The models built on the basis of this homology and having common conformational patterns are analyzed under the structural constraints derived from the activity data of various synthetic analogs of the peptide. Application of this procedure to the gonadotropin-releasing hormone (GnRH) resulted in a library of possible structures for GnRH, 9 among which shared a common beta-turn. Further analysis of the structures containing the beta-turn motif, in the context of the structure-activity data, led to a model for the active conformation of GnRH. The topology of the putative receptor binding site of the hormone is defined by a contiguous surface formed through an appropriate juxtaposition of the N-terminal pGlu1, the guanidyl group of Arg8, aromatic side chain of Trp3, and the Gly10-NH2 at the C-terminal end.

Polymorphism in the assembly of polyomavirus capsid protein VP1

Polyomavirus major capsid protein VP1, purified after expression of the recombinant gene in Escherichia coli, forms stable pentamers in low-ionic strength, neutral, or alkaline solutions. Electron microscopy showed that the pentamers, which correspond to viral capsomeres, can be self-assembled into a variety of polymorphic aggregates by lowering the pH, adding calcium, or raising the ionic strength. Some of the aggregates resembled the 500-A-diameter virus capsid, whereas other considerably larger or smaller capsids were also produced. The particular structures formed on transition to an environment favoring assembly depended on the pathway of the solvent changes as well as on the final conditions. Mass measurements from cryoelectron micrographs and image analysis of negatively stained specimens established that a distinctive 320-A-diameter particle consists of 24 close-packed pentamers arranged with octahedral symmetry. Comparison of this unexpected octahedral assembly with a 12-capsomere icosahedral aggregate and the 72-capsomere icosahedral virus capsid by computer graphics methods indicates that similar connections are made among trimers of pentamers in these shells of different size. The polymorphism in the assembly of VP1 pentamers can be related to the switching in bonding specificity required to build the virus capsid.

Liquid-like movements in crystalline insulin

Diffuse X-ray scattering from protein crystals provides information about molecular flexibility and packing irregularities. Here we analyse diffraction patterns from insulin crystals that show two types of scattering related to disorder: very diffuse, liquid-like diffraction, and haloes around the Bragg reflections. The haloes are due to coupled displacements of neighbouring molecules in the lattice, and the very diffuse scattering results from variations in atomic positions that are only locally correlated within each molecule. The measured intensity was digitally separated into three components: the Bragg reflections and associated haloes; the water and Compton scattering; and the scattering attributed to internal protein movements. We extend methods used to analyse disorder in membrane structures to simulate the diffuse scattering from crystalline insulin in terms of (1) the Patterson (autocorrelation) function of the ideal, ordered crystal structure, (2) the root-mean-square (r.m.s.) amplitude of the atomic movements, and (3) the mean distance over which these displacements are coupled. Movements of the atoms within the molecules, with r.m.s. amplitudes of 0.4-0.45 A, appear to be coupled over a range of approximately 6 A, as in a liquid. These locally coupled movements account for most of the disorder in the crystal. Also, the protein molecules, as a whole, jiggle in the lattice with r.m.s. amplitudes of approximately 0.25 A that appear to be significantly correlated only between nearest neighbours.

Site-directed mutation affecting polyomavirus capsid self-assembly in vitro

Nonequivalent bonding of identical protein subunits occurs in the polyomavirus capsid were identical pentameric capsomeres occupy both hexavalent and pentavalent positions in the icosahedral surface lattice. The polyomavirus major capsid protein VP1, purified after expression of the recombinant gene in Escherichia coli, has been isolated as capsomeres that self-assemble into capsid-like structures in vitro. The ability to switch bonding specificity in different symmetry environments therefore must be intrinsic to the VP1 molecule. In vitro self-assembly provides an assay for VP1 mutations affecting capsomere and capsid formation. We report here that a directed mutation in the VP1 expression vector, leading to a protein truncated at the carboxy terminus, results in a mutant VP1 that forms capsomeres, but not capsids, in the in vitro assembly assay. The carboxy terminus of VP1 therefore appears to be involved in the specific bonding responsible for the non-equivalent association of capsomeres.

Disk aggregates of tobacco mosaic virus protein in solution: electron microscopy observations

Previous studies of the coat protein of tobacco mosaic virus (TMVP) have shown that TMVP presumably exists as linear stacks of two-ring cylindrical disks in the 0.7 M ionic strength buffer used for crystallizing the disks for X-ray diffraction studies [Raghavendra, K., Adams, M.L., & Schuster, T.M. (1985) Biochemistry 24, 3298-3304]. The spectroscopic and sedimentation studies of solutions of TMVP under these crystallizing conditions have demonstrated a long-term metastability of these disk aggregates when they are placed in 0.1 M ionic strength buffers, as are used for reconstituting tobacco mosaic virus from TMVP and viral RNA. The present work describes an electron microscopic study of TMVP disk aggregates under the same solution conditions employed in the previous spectroscopic and sedimentation studies. The results show that in the pH 8.0 0.7 M ionic strength crystallization buffer TMVP exists as stacks of disks which range in size from about 6 to 24 layers, corresponding to 3-12 2-layer disk aggregates having 17 subunits per layer. These TMVP aggregates persist in a metastable form in 0.1 M ionic strength virus reconstitution buffer with no apparent changes in structure of the stacked disks. The results are consistent with the conclusions of the solution physical-chemical studies which suggest that the disk structure may not be related to the 20S TMVP aggregate that is the nucleation species in virus

Self-assembly of purified polyomavirus capsid protein VP1

The polyomavirus major capsid protein VP1, purified after expression of the recombinant gene in E. coli, was isolated as oligomers resembling the dissociated capsomeres derived from viral capsids. Image analysis of low-dose electron micrographs demonstrates that these VP1 oligomers are exclusively pentamers. The purified VP1 pentamers associated to form capsid-like assemblies and polymorphic aggregates at high ionic strength. The capsid-like assemblies were stabilized at low ionic strength by the addition of calcium. Self-assembly of the unmodified, recombinant DNA-generated VP1 implies that the posttranslational charge modifications of VP1 and the minor virion protein components, VP2 and VP3, are not essential for capsid formation. The nonequivalently related subunits of the penta- and hexavalent capsomeres therefore must spontaneously switch their bonding specificity during assembly.

Arrangement of subunits in peanut lectin. Rotation function and chemical cross-linking studies

X-ray intensity data from the native orthorhombic crystals of peanut lectin have been collected using oscillation photography. Rotation function studies using data up to a resolution of 4.5 A indicate that the four subunits in the molecule, which constitute the asymmetric unit in the crystals, are related to one another by three mutually perpendicular noncrystallographic 2-fold axes. Chemical cross-linking experiments in solution followed by sodium dodecyl sulfate gel electrophoresis, carried out in parallel, suggest that there is more than one type of intersubunit approach in the molecule. Rotation function and cross-linking studies thus show that the tetrameric molecule of peanut lectin is a dimer of a dimer. The two monomers in a dimer are related by a 2-fold axis. The two dimers are in turn related by another 2-fold axis perpendicular to the one that relates the two monomers in the dimer, endowing the molecule with 222 (D2) symmetry.

X-ray characterisation of an additional binding site in lysozyme

Bromophenol red (BPR) binds to lysozyme and inhibits its activity against bacterial cell walls, but not against the polysaccharide component of peptidoglycan. The binding site of BPR in the enzyme has been characterised by X-ray analysis of the complex at 5.5A resolution. The new binding site, which is outside the cleft close to subsite F, is presumably involved in interactions with the peptide component of peptidoglycan, in the action of lysozyme against bacterial cell walls.

X-ray studies on crystalline complexes involving amino acids and peptides. IX. Crystal structure of L-ornithine L-aspartate hemihydrate

L-Ornithine L-aspartate hemihydrate crystallizes in the space group C2 with a = 21.858(2), b = 4.718(1), c = 18.046(2) A and beta = 137.4(1) degrees. The crystal structure, solved by direct methods, has been refined to an R value of 0.041 for 1270 observed reflections. The conformation of the two amino acid molecules in the structure are somewhat different from those observed in other crystal structures which contain them. The crystal structure is stabilized by ionic interactions accompanied by hydrogen bonds. The unlike molecules aggregate into separate two-fold helices; each helix of one type is surrounded by, and is in hydrogen bonded contact with, four helices of the other type. The arrangement of the molecules in the structure is such that it can be described as consisting of alternating hydrophilic and hydrophobic regions. The hydrophilic regions contain hydrogen bonded loops, each made up of two amino groups and two carboxylate groups. The structure also provides the first example of a head-to-tail sequence involving two types of amino acids.