Mutation of a single amino acid converts germ cell alkaline phosphatase to placental alkaline phosphatase

Human placental and germ cell alkaline phosphatases (PLAP and GCAP, respectively), are characterized by their differential sensitivities to inhibition by L-leucine, EDTA, and heat. Yet, they differ by only 7 amino acids at positions 15, 67, 68, 84, 241, 254, and 429 within their respective 484 residues. To determine the structural basis and the amino acid(s) involved in these physicochemical differences, we constructed three GCAP mutants by site-directed mutagenesis and six GCAP/PLAP chimeras and then expressed these alkaline phosphatase mutants in COS-1 cells. We report that the differential reactivity of PLAP and GCAP depends critically on a single amino acid at position 429. GCAP with Gly-429 is strongly inhibited by L-leucine, EDTA, and heat, whereas PLAP with Glu-429 is resistant. By substituting Gly-429 of GCAP with a series of amino acids, we demonstrate that the relative sensitivities of these mutants to L-leucine, EDTA, and heat inhibition are, in general, parallel. Mutants in the order of resistance to these treatments are: Glu (most resistant), Asp/Ile/Leu, Gln/Val/Lys, Ser/His, and Arg/Thr/Met/Cys/Phe/Trp/Tyr/Pro/Asn/Ala/Gly (least resistant). However, the Ser-429 and His-429 mutants were more resistant to EDTA and heat inhibition than the wild-type GCAP, but were equally sensitive to L-leucine inhibition. Structural analysis of mammalian alkaline phosphatase modeled on the refined crystal structure of Escherichia coli alkaline phosphatase indicates that the negative charge of Glu-429 of PLAP, which simultaneously stabilizes the protein as a whole and the metal binding specifically, probably acts through interactions with the metal ligand His-320 (His-331 in E. coli alkaline phosphatase). Replacement of codon 429 with Gly in GCAP leads to destabilization and loosening of the metal binding. The data suggest that the natural binding site for L-leucine may be near position 429, with the amino and carboxyl groups of L-leucine interacting with bound phosphate and His-432 (His-412 in E. coli alkaline phosphatase), respectively.     

Function assignment to conserved residues in mammalian alkaline phosphatases

We have probed the structural/functional relationship of key residues in human placental alkaline phosphatase (PLAP) and compared their properties with those of the corresponding residues in Escherichia coli alkaline phosphatase (ECAP). Mutations were introduced in wild-type PLAP, i.e. [E429]PLAP, and in some instances also in [G429]PLAP, which displays properties characteristic of the human germ cell alkaline phosphatase isozyme. All active site metal ligands, as well as residues in their vicinity, were substituted to alanines or to the homologous residues present in ECAP. We found that mutations at Zn2 or Mg sites had similar effects in PLAP and ECAP but that the environment of the Zn1 ion in PLAP is less affected by substitutions than that in ECAP. Substitutions of the Mg and Zn1 neighboring residues His-317 and His-153 increased k(cat) and increased K(m) when compared with wild-type PLAP, contrary to what was predicted by the reciprocal substitutions in ECAP. All mammalian alkaline phosphatases (APs) have five cysteine residues (Cys-101, Cys-121, Cys-183, Cys-467, and Cys-474) per subunit, not homologous to any of the four cysteines in ECAP. By substituting each PLAP Cys by Ser, we found that disrupting the disulfide bond between Cys-121 and Cys-183 completely prevents the formation of the active enzyme, whereas the carboxyl-terminally located Cys-467-Cys-474 bond plays a lesser structural role. The substitution of the free Cys-101 did not significantly affect the properties of the enzyme. A distinguishing feature found in all mammalian APs, but not in ECAP, is the Tyr-367 residue involved in subunit contact and located close to the active site of the opposite subunit. We studied the A367 and F367 mutants of PLAP, as well as the corresponding double mutants containing G429. The mutations led to a 2-fold decrease in k(cat), a significant decrease in heat stability, and a significant disruption of inhibition by the uncompetitive inhibitors l-Phe and l-Leu. Our mutagenesis data, computer modeling, and docking predictions indicate that this residue contributes to the formation of the hydrophobic pocket that accommodates and stabilizes the side chain of the inhibitor during uncompetitive inhibition of mammalian APs.     

Structure-activity relationship study of human interleukin-3. Identification of residues required for biological activity by site-directed mutagenesis

Recombinant human interleukin-3 (rhuIL-3) variants were generated by site-directed mutagenesis and expression in Escherichia coli. Amino acid deletions and substitutions were made in the previously identified epitopes of two huIL-3-specific neutralizing monoclonal antibodies (mAbs). The rhuIL-3 variants were analyzed for their ability to bind to the IL-3 receptor and to induce the proliferation of the human IL-3-dependent cell line M-O7. Several deletion mutants spanning the epitopes of these neutralizing mAbs indicated the importance of residues Pro33 and Leu34 for biological activity. Further, substitution of Pro33 with Asn (Asn33) showed an enhanced proliferative activity (4-fold) and a moderate increase in receptor binding (2-fold) compared to wild-type (wt) rhuIL-3. The most remarkable change, however, was seen with variant Gly33, which showed a 14-fold increase in promoting the growth of M-O7 cells without a significant modification in its receptor binding capacity. In contrast, substitution of Leu34 with Gly (Gly34) yielded an IL-3 variant that had a 25-fold decreased receptor binding capacity and proliferative activity, while Glu34 had properties similar to wild-type rhuIL-3. Analysis of the binding of these variants to different rhuIL-3-specific monoclonal antibodies suggested that no major modification had occurred in their conformations. These results indicate that both residues, Pro33 and Leu34, play a critical role in modulating the activity of rhuIL-3.     

DNA polymorphism of alkaline phosphatase isozyme genes: linkage disequilibria between placental and germ-cell alkaline phosphatase alleles.

The use of human placental alkaline phosphatase (PLAP) cDNA as a probe allows the detection and identification of restriction DNA fragments derived from three homologous genes, i.e., intestinal alkaline phosphatase (AP), germ-cell AP (GCAP), and PLAP. In previous RFLP studies we have reported linkage disequilibria between an RsaI and two PstI (a and b) polymorphic restriction sites and electrophoretic types of PLAP. In this report we present evidence that, in spite of the strong correlation with PLAP types, PstI(b) is an RFLP of GCAP. The data indicate close linkage between the PLAP and GCAP loci.     

Time-dependent irreversible inhibition of bovine kidney alkaline phosphatase by oxidized adenosine. Use of this compound as a site-directed inhibitor for studying uncompetitive inhibition

The L/B/K type of mammalian alkaline phosphatase (ALP) is inhibited uncompetitively by nucleotides. A combination of adenosine and nicotinamide is more effective than either adenosine or nicotinamide alone, probably because a dinucleotide structure is necessary to trigger a conformational change accompanying binding of structures such as NADH. It has been suggested that a loop region containing residue 429 in the ALP polypeptide is important in the interaction of uncompetitive inhibitors with the enzyme. In the L/B/K isoenzyme, residue 429 is a histidine and is a potential target for modification. In an attempt to learn more about the molecular events accompanying inhibition of ALP by uncompetitive inhibitors, bovine kidney ALP was reacted with oxidized adenosine in the presence of nicotinamide to see if site-directed modification occurs. Kidney ALP was irreversibly inactivated by oxidized adenosine but the reaction was slow. The site modified is likely to be close to the region of binding. Sequence data for the kidney enzyme shows that in the region of residue 429 there are no residues except His⁴²⁹ itself that is likely to react with oxidized adenosine.     

Isolation and affinity maturation of hapten-specific antibodies

More and more recombinant antibodies specific for haptens such as drugs of abuse, dyes and pesticides are being isolated from antibody libraries. Thereby isolated antibodies tend to possess lower affinity than their parental, full-size counterparts, and therefore the isolation techniques must be optimized or the antibody genes must be affinity-matured in order to reach high affinities and specificities required for practical applications. Several strategies have been explored to obtain high-affinity recombinant antibodies from antibody libraries: At the selection level, biopanning optimization can be performed through elution with free hapten, analogue pre-incubation and subtractive panning. At the mutagenesis level, techniques such as random mutagenesis, bacterial mutator strains passaging, site-directed mutagenesis, mutational hotspots targeting, parsimonious mutagenesis, antibody shuffling (chain, DNA and staggered extension process) have been used with various degrees of success to affinity mature or modify hapten-specific antibodies. These techniques are reviewed, illustrated and compared.     

Affinity maturation to improve human monoclonal antibody neutralization potency and breadth against hepatitis C virus

A potent neutralizing antibody to a conserved hepatitis C virus (HCV) epitope might overcome its extreme variability, allowing immunotherapy. The human monoclonal antibody HC-1 recognizes a conformational epitope on the HCV E2 glycoprotein. Previous studies showed that HC-1 neutralizes most HCV genotypes but has modest potency. To improve neutralization, we affinity-matured HC-1 by constructing a library of yeast-displayed HC-1 single chain Fv (scFv) mutants, using for selection an E2 antigen from one of the poorly neutralized HCVpp. We developed an approach by parallel mutagenesis of the heavy chain variable (VH) and κ-chain variable (Vk) genes separately, then combining the optimized VH and Vk mutants. This resulted in the generation of HC-1-related scFv variants exhibiting improved affinities. The best scFv variant had a 92-fold improved affinity. After conversion to IgG1, some of the antibodies exhibited a 30-fold improvement in neutralization activity. Both surface plasmon resonance and solution kinetic exclusion analysis showed that the increase in affinity was largely due to a lowering of the dissociation rate constant, Koff. Neutralization against a panel of HCV pseudoparticles and infectious 2a HCV virus improved with the affinity-matured IgG1 antibodies. Interestingly, some of these antibodies neutralized a viral isolate that was not neutralized by wild-type HC-1. Moreover, propagating 2a HCVcc under the selective pressure of WT HC-1 or affinity-matured HC-1 antibodies yielded no viral escape mutants and, with the affinity-matured IgG1, needed 100-fold less antibody to achieve complete virus elimination. Taken together, these findings suggest that affinity-matured HC-1 antibodies are excellent candidates for therapeutic development.     

Structural evidence of functional divergence in human alkaline phosphatases

The evolution of the alkaline phosphatase (AP) gene family has lead to the existence in humans of one tissue-nonspecific (TNAP) and three tissue-specific isozymes, i.e. intestinal (IAP), germ cell (GCAP), and placental AP (PLAP). To define the structural differences between these isozymes, we have built models of the TNAP, IAP, and GCAP molecules based on the 1.8-structure of PLAP(1) and have performed a comparative structural analysis. We have examined the monomer-monomer interface as this area is crucial for protein stability and enzymatic activity. We found that the interface allows the formation of heterodimers among IAP, GCAP, and PLAP but not between TNAP with any of the three tissue-specific isozymes. Secondly, the active site cleft was mapped into three regions, i.e. the active site itself, the roof of the cleft, and the floor of the cleft. This analysis led to a structural fingerprint of the active site of each AP isozyme that suggests a diversification in substrate specificity for this isozyme family.     

Mutational analysis of Thermus caldophilus GK24 beta-glycosidase: role of His119 in substrate binding and enzyme activity

Three amino acid residues (His119, Glu164, and Glu338) in the active site of Thermus caldophilus GK24 beta- glycosidase (Tca beta-glycosidase), a family 1 glycosyl hydrolase, were mutated by site-directed mutagenesis. To verify the key catalytic residues, Glu164 and Glu338 were changed to Gly and Gln, respectively. The E164G mutation resulted in drastic reductions of both beta-galactosidase and beta-glucosidase activities, and the E338Q mutation caused complete loss of activity, confirming that the two residues are essential for the reaction process of glycosidic linkage hydrolysis. To investigate the role of His119 in substrate binding and enzyme activity, the residue was substituted with Gly. The H119G mutant showed 53-fold reduced activity on 5 mM p-nitrophenyl beta-Dgalactopyranoside, when compared with the wild type; however, both the wild-type and mutant enzymes showed similar activity on 5 mM p-nitrophenyl beta-D-glucopyranoside at 75degreeC. Kinetic analysis with p-nitrophenyl beta-D-galactopyranoside revealed that the kcat value of the H119G mutant was 76.3-fold lower than that of the wild type, but the Km of the mutant was 15.3-fold higher than that of the wild type owing to the much lower affinity of the mutant. Thus, the catalytic efficiency (kcat/Km) of the mutant decreased to 0.08% to that of the wild type. The kcat value of the H119G mutant for p-nitrophenyl beta- D-glucopyranoside was 5.1-fold higher than that of the wild type, but the catalytic efficiency of the mutant was 2.5% of that of the wild type. The H119G mutation gave rise to changes in optima pH (from 5.5-6.5 to 5.5) and temperature (from 90 degrees C to 80-85 degrees C). This difference of temperature optima originated in the decrease of H119G's thermostability. These results indicate that His119 is a crucial residue in beta- galactosidase and beta-glucosidase activities and also influences the enzyme's substrate binding affinity and thermostability.     

Importance of Glu(282) in transmembrane segment M3 of the Na(+),K(+)-ATPase for control of cation interaction and conformational changes

Glu(282) located in the NH(2)-terminal part of transmembrane helix M3 of the Na(+),K(+)-ATPase was replaced by alanine, glycine, leucine, lysine, aspartate, or glutamine, and the effects of the mutations on the overall and partial reactions of the enzyme were analyzed. The mutations affected at least 3 important functions of the Na(+),K(+)-ATPase: (i) the conformational transitions between E(1) and E(2) forms of dephospho- and phosphoenzyme, (ii) Na(+) binding at the cytoplasmically facing sites of E(1), and (iii) long-range interaction controlling dephosphorylation. In mutants Glu(282) --> Lys and Glu(282) --> Asp, the E(1) form was favored during ATP hydrolysis, whereas the E(2) form was favored in Glu(282) --> Ala and Glu(282) --> Gly. Regardless of the change of conformational equilibrium, all the mutants displayed a reduced apparent affinity for Na(+), at least 3-fold for Glu(282) --> Lys and Glu(282) --> Asp, suggesting a direct effect on the Na(+) binding properties of E(1). Glu(282) --> Ala and Glu(282) --> Gly exhibited an extraordinary high rate of ATP hydrolysis in the mere presence of Na(+) without K(+) ("Na(+)-ATPase activity"), because of an increased rate of dephosphorylation of E(2)P. These results are in accordance with the hypothesis that Glu(282) is involved in the communication between the cation binding pocket and the catalytic site and in control of the cytoplasmic entry pathway for Na(+).     

Site-directed antibodies for probing the structure and biogenesis of phosphatidylinositol glycan-linked membrane proteins: application to placental alkaline phosphatase

An immunological approach to the study of the structure and biogenesis of the phosphatidylinositol glycan (PI-G) membrane anchor at the carboxyl terminus of human placental alkaline phosphatase (PLAP) is described. Based on the protein sequence predicted from full length PLAP cDNA, two epitopes were chosen in the region of the carboxyl terminus for the production of site-directed antibodies. The exo site represents the last nine residues of preproPLAP, (res. 505-513), which is part of the sequence that is expected to be cleaved from the nascent protein during processing and addition of the PI-G tail. A second site, the endo sequence, was selected close to the expected carboxyl terminus in mature PI-G-tailed PLAP (res. 474-484 of proPLAP). The two peptides were synthesized, polyclonal antibodies to the conjugated peptides were prepared, and the antisera were characterized. Analytical methods for both synthetic peptides and proteins are presented. Preliminary applications to the isolation and characterization of the PI-G-linked carboxyl terminus of mature PLAP and to the characterization of nascent PLAP are described. The application of both carboxyl terminal-directed antibodies, and a third antibody directed to the amino terminus of mature PLAP, in studies employing mutant forms of PLAP and to the PI-G tailing process itself are discussed. The immunological approach used here for PLAP should be applicable generally to the study of other PI-G-tailed proteins.     

Structural insights into steroid hormone binding: the crystal structure of a recombinant anti-testosterone Fab fragment in free and testosterone-bound forms.

The monoclonal anti-testosterone antibody (3-C(4)F(5)) has a relatively high affinity (3 x 10(8) m(-1)) with an overall good specificity profile. However, the earlier characterized binding properties have shown that both the affinity and specificity of this antibody must be improved if it is intended for use in clinical immunoassays. In this paper, the crystal structures of the recombinant anti-testosterone (3-C(4)F(5)) Fab fragment have been determined in the testosterone-bound and free form at resolutions of 2.60 and 2.72 A, respectively. The high affinity binding of the (3-C(4)F(5)) Fab is mainly determined by shape complementarity between the protein and testosterone. Only one direct hydrogen bond is formed between the hydroxyl group of the testosterone D-ring and the main-chain oxygen of Gly100(J)H. The testosterone is deeply bound in a hydrophobic pocket, and the close shape complementarity is mainly formed by the third complementarity-determining regions (CDR) of the heavy and light chain. Comparison of the bound structure with the free structure indicates conformational changes in the protein upon testosterone binding. The conformational changes of the side chains of two residues Glu95H and Tyr99H in the CDR-H3 are particularly essential for the binding. Interesting similarities in the binding of different steroids were also observed upon comparison of the available structures of anti-steroid antibodies.     

Importance of stalk segment S5 for intramolecular communication in the sarcoplasmic reticulum Ca2+-ATPase

Sixteen residues in stalk segment S5 of the Ca(2+)-ATPase of sarcoplasmic reticulum were studied by site-directed mutagenesis. The rate of the Ca(2+) binding transition, determined at 0 degrees C, was enhanced relative to wild type in mutants Ile(743) --> Ala, Val(747) --> Ala, Glu(748) --> Ala, Glu(749) --> Ala, Met(757) --> Gly, and Gln(759) --> Ala and reduced in mutants Asp(737) --> Ala, Asp(738) --> Ala, Ala(752) --> Leu, and Tyr(754) --> Ala. In mutant Arg(762) --> Ile, the rate of the Ca(2+) binding transition was wild type like at 0 degrees C, whereas it was 3.5-fold reduced relative to wild type at 25 degrees C. The rate of dephosphorylation of the ADP-insensitive phosphoenzyme was increased conspicuously in mutants Ile(743) --> Ala and Tyr(754) --> Ala (close to 20-fold in the absence of K(+)) and increased to a lesser extent in Asn(739) --> Ala, Glu(749) --> Ala, Gly(750) --> Ala, Ala(752) --> Gly, Met(757) --> Gly, and Arg(762) --> Ile, whereas it was reduced in mutants Asp(737) --> Ala, Val(744) --> Gly, Val(744) --> Ala, Val(747) --> Ala, and Ala(752) --> Leu. In mutants Ile(743) --> Ala, Tyr(754) --> Ala, and Arg(762) --> Ile, the apparent affinities for vanadate were enhanced 23-, 30-, and 18-fold, respectively, relative to wild type. The rate of Ca(2+) dissociation was 11-fold increased in Gly(750) --> Ala and 2-fold reduced in Val(747) --> Ala. Mutants with alterations to Arg(751) either were not expressed at a significant level or were completely nonfunctional. The findings show that S5 plays a crucial role in mediating communication between the Ca(2+) binding pocket and the catalytic domain and that Arg(751) is important for both structural and functional integrity of the enzyme.     

Functional consequences of alterations to Gly310, Gly770, and Gly801 located in the transmembrane domain of the Ca(2+)-ATPase of sarcoplasmic reticulum.

Site-specific mutagenesis was used to replace Gly310, Gly770, and Gly801, located in the transmembrane domain of the sarcoplasmic reticulum Ca(2+)-ATPase, with either alanine or valine. In addition, Gly310 was substituted with proline. In the Gly310----Ala mutant, the Vmax for Ca2+ transport and ATPase activity was reduced to about 40% of the wild type activity, but the apparent Ca2+ affinity was close to normal. The Gly310----Val and Gly310----Pro mutants were devoid of Ca2+ transport or ATPase activity and displayed more than a 20-fold reduction in the apparent Ca2+ affinities measured in the phosphorylation assays with either ATP or Pi. In these mutants, the rate of phosphoenzyme hydrolysis was reduced, and the ADP-insensitive phosphoenzyme intermediate accumulated. The apparent affinity for Pi was increased in the absence, but not in the presence, of dimethyl sulfoxide. The properties of this new class of Ca(2+)-ATPase mutants ("E2/E2P" type) are consistent with a conformational state in which the protein-phosphate interaction is stabilized and the Ca(2+)-protein interaction is destabilized. The Gly770----Ala mutant transported Ca2+ with a Vmax close to that of the wild type, but displayed more than a 20-fold reduction of apparent Ca2+ affinity. The Gly770----Val mutant was not phosphorylated from either ATP or Pi. The Gly801----Ala mutant transported Ca2+ with a Vmax of 126% that of the wild type, hydrolyzed ATP at the same Vmax as the wild type in the presence of calcium ionophore, and displayed a 3-fold reduction in apparent Ca2+ affinity. The Gly801----Val mutant was unable to transport Ca2+ and to be phosphorylated from ATP, even at a Ca2+ concentration of 1 mM, but Ca2+ in the micromolar range inhibited phosphorylation from Pi. The ability to bind ATP with normal affinity was retained. The properties of this mutant are consistent with a disruption of one of the two Ca2+ binding sites required for phosphorylation with ATP.     

Structural studies of human placental alkaline phosphatase in complex with functional ligands

The activity of human placental alkaline phosphatase (PLAP) is downregulated by a number of effectors such as l-phenylalanine, an uncompetitive inhibitor, 5'-AMP, an antagonist of the effects of PLAP on fibroblast proliferation and by p-nitrophenyl-phosphonate (PNPPate), a non-hydrolysable substrate analogue. For the first two, such regulation may be linked to its biological function that requires a reduced and better-regulated hydrolytic rate. To understand how such disparate ligands are able to inhibit the enzyme, we solved the structure of the complexes at 1.6A, 1.9A and 1.9A resolution, respectively. These crystal structures are the first of an alkaline phosphatase in complex with organic inhibitors. Of the three inhibitors, only l-Phe and PNPPate bind at the active site hydrophobic pocket, providing structural data on the uncompetitive inhibition process. In contrast, all three ligands interact at a remote peripheral site located 28A from the active site. In order to extend these observations to the other members of the human alkaline phosphatase family, we have modelled the structures of the other human isozymes and compared them to PLAP. This comparison highlights the crucial role played by position 429 at the active site in the modulation of the catalytic process, and suggests that the peripheral binding site may be involved in the functional specialization of the PLAP isozyme.     

The intrinsic contributions of tyrosine, serine, glycine and arginine to the affinity and specificity of antibodies

Synthetic antibody libraries with restricted chemical diversity were used to explore the intrinsic contributions of four amino acids (Tyr, Ser, Gly and Arg) to the affinity and specificity of antigen recognition. There was no correlation between nonspecific binding and the content of Tyr, Ser or Gly in the antigen-binding site, and in fact, the most specific antibodies were those with the highest Tyr content. In contrast, Arg content was clearly correlated with increased nonspecific binding. We combined Tyr, Ser and Gly to generate highly specific synthetic antibodies with affinities in the subnanomolar range, showing that the high abundance of Tyr, Ser and Gly in natural antibody germ line sequences reflects the intrinsic capacity of these residues to work together to mediate antigen recognition. Despite being a major functional contributor to co-evolved protein-protein interfaces, we find that Arg does not contribute generally to the affinity of naïve antigen-binding sites and is detrimental to specificity. Again, this is consistent with studies of natural antibodies, which have shown that nonspecific, self-reactive antibodies are rich in Arg and other positively charged residues. Our findings suggest that the principles governing naïve molecular recognition differ from those governing co-evolved interactions. Analogous studies can be designed to explore the roles of the other amino acids in molecular recognition. Results of such studies should illuminate the basic principles underlying natural protein-protein interactions and should aid the design of synthetic binding proteins with functions beyond the scope of natural proteins.     

Identification of a determinant of epidermal growth factor receptor ligand-binding specificity using a truncated, high-affinity form of the ectodomain

Murine and human epidermal growth factor receptors (EGFRs) bind human EGF (hEGF), mouse EGF (mEGF), and human transforming growth factor alpha (hTGF-alpha) with high affinity despite the significant differences in the amino acid sequences of the ligands and the receptors. In contrast, the chicken EGFR can discriminate between mEGF (and hEGF) and hTGF-alpha and binds the EGFs with approximately 100-fold lower affinity. The regions responsible for this poor binding are known to be Arg(45) in hEGF and the L2 domain in the chicken EGFR. In this study we have produced a truncated form of the hEGFR ectodomain comprising residues 1-501 (sEGFR501), which, unlike the full-length hEGFR ectodomain (residues 1-621, sEGFR621), binds hEGF and hTGF-alpha with high affinity (K(D) = 13-21 and 35-40 nM, respectively). sEGFR501 was a competitive inhibitor of EGF-stimulated mitogenesis, being almost 10-fold more effective than the full-length EGFR ectodomain and three times more potent than the neutralizing anti-EGFR monoclonal antibody Mab528. Analytical ultracentrifugation showed that the primary EGF binding sites on sEGFR501 were saturated at an equimolar ratio of ligand and receptor, leading to the formation of a 2:2 EGF:sEGFR501 dimer complex. We have used sEGFR501 to generate three mutants with single position substitutions at Glu(367), Gly(441), or Glu(472) to Lys, the residue found in the corresponding positions in the chicken EGFR. All three mutants bound hTGF-alpha and were recognized by Mab528. However, mutant Gly(441)Lys showed markedly reduced binding to hEGF, implicating Gly(441), in the L2 domain, as part of the binding site that recognizes Arg(45) of hEGF.     

Using homology modeling to interrogate binding affinity in neutralization of ricin toxin by a family of single domain antibodies

In this report we investigated, within a group of closely related single domain camelid antibodies (V_HHs), the relationship between binding affinity and neutralizing activity as it pertains to ricin, a fast‐acting toxin and biothreat agent. The V1C7‐like V_HHs (V1C7, V2B9, V2E8, and V5C1) are similar in amino acid sequence, but differ in their binding affinities and toxin‐neutralizing activities. Using the X‐ray crystal structure of V1C7 in complex with ricin's enzymatic subunit (RTA) as a template, Rosetta‐based homology modeling coupled with energetic decomposition led us to predict that a single pairwise interaction between Arg29 on V5C1 and Glu67 on RTA was responsible for the difference in ricin toxin binding affinity between V1C7, a weak neutralizer, and V5C1, a moderate neutralizer. This prediction was borne out experimentally: substitution of Arg for Gly at position 29 enhanced V1C7's binding affinity for ricin, whereas the reverse (ie, Gly for Arg at position 29) diminished V5C1's binding affinity by >10 fold. As expected, the V5C1_R29G mutant was largely devoid of toxin‐neutralizing activity (TNA). However, the TNA of the V1C7_G29R mutant was not correspondingly improved, indicating that in the V1C7 family binding affinity alone does not account for differences in antibody function. V1C7 and V5C1, as well as their respective point mutants, recognized indistinguishable epitopes on RTA, at least at the level of sensitivity afforded by hydrogen‐deuterium mass spectrometry. The results of this study have implications for engineering therapeutic antibodies because they demonstrate that even subtle differences in epitope specificity can account for important differences in antibody function.     

A panel of monoclonal antibodies for the type I insulin-like growth factor receptor. Epitope mapping, effects on ligand binding, and biological activity.

We obtained 20 mouse monoclonal antibodies specific for human type I insulin-like growth factor (IGF) receptors, using transfected cells expressing high levels of receptors (IGF-1R/3T3 cells) as immunogen. The antibodies immunoprecipitated receptor.125I-IGF-I complexes and biosynthetically labeled receptors from IGF-1R/3T3 cells but did not react with human insulin receptors or rat type I IGF receptors. Several antibodies stimulated DNA synthesis in IGF-1R/3T3 cells, but the maximum stimulation was only 25% of that produced by IGF-I. The antibodies fell into seven groups recognizing distinct epitopes and with different effects on receptor function. All the antibodies reacted with the extracellular portion of the receptor, and epitopes were localized to specific domains by investigating their reaction with a series of chimeric IGF/insulin receptor constructs. Binding of IGF-I was inhibited up to 90% by antibody 24-60 reacting in the region 184-283, and by antibody 24-57 reacting in the region 440-586. IGF-I binding was stimulated up to 2.5-fold by antibodies 4-52 and 16-13 reacting in the region 62-184, and by antibody 26-3 reacting downstream of 283. The latter two groups of antibodies also dramatically stimulated insulin binding to intact IGF-1R/3T3 cells (by up to 50-fold), and potentiated insulin stimulation of DNA synthesis. Scatchard analysis indicated that in the presence of these antibodies, the affinity of the type I IGF receptor for insulin was comparable with that of the insulin receptor. These data indicate that regions both within and outside the cysteine-rich domain of the receptor alpha-subunit are important in determining the affinity and specificity of ligand binding. These antibodies promise to be valuable tools in resolving issues of IGF-I receptor heterogeneity and in studying the structure and function of classical type I receptors and insulin/IGF receptor hybrids.