Effects of amino acid substitutions outside an antigenic site on protein binding to monoclonal antibodies of predetermined specificity obtained by peptide immunization: Demonstration with region 145–151 (antigenic site 5) of myoglobin

Monoclonal antibodies of predetermined specificity were prepared by immunization with a free (i.e., without coupling to any protein carrier) synthetic peptide representing region 145–151 of sperm whale myoglobin (SpMb) and their cross-reactions with eight Mb variants were determined. Five Mbs—bottle-nose dolphin myoglobin (BdMb), pacific common dolphin myoglobin (PdMb), horse myoglobin (HsMb), dog myoglobin (DgMb), and badger myoglobin (BgMb)—have an identical sequence in that region. Nevertheless, these Mbs exhibited very different cross-reactivities. BdMb and PdMb exhibited cross-activities which were comparable to that of the reference antigen, SpMb; while the reactivity of HsMb was remarkedly decreased, DgMb and BgMb showed almost no cross-reactions with these mAbs. Since the region 145–151 has an identical sequence in all the five Mbs, it is concluded that the differences in their antigenic reactivities with anti-region 145–151 mAbs are due to the effects of amino acid substitutions outside the region 145–151. Another pair of myoglobins, echidna myoglobin (EdMb) and chicken myoglobin (ChMb), have the same sequence in that region, but reacted very differently with anti-region 145–151 mAbs. The reactivity and affinity of EdMb were substantially decreased while those of ChMb were almost completely absent, relative to SpMb. It is concluded, contrary to popular assumptions, that when an amino acid substitution influences the binding of a protein variant to a mAb, it is not necessary for that substitution to be an actual contact residue (i.e., a residue within the antigenic site where the mAb binds). Such effects, which are often very drastic, could be due to indirect influences of the substitution on the chemical and binding properties of the site residues. Furthermore, residues which had been postulated, on the basis of these assumptions, to constitute discontinuous antigenic sites in SpMb, were found [from the present studies and those recently reported with mAbs against the other four antigenic site of Mb (regions 15–22, 56–62, 94–100, and 113–120 of SpMb)] to merely be exerting indirect effects on the known five antigenic sites of Mb. The effects of substitutions, which can happen even in the absence of conformational changes, are determined by many factors, such as the chemical nature of the substitution, its environment, its distance from the site, and the nature of the site residue(s) being affected.     

Effects of amino acid substitutions outside an antigenic site on protein binding to monoclonal antibodies of predetermined specificity obtained by peptide immunization: demonstration with region 15-22 (antigenic site 1) of myoglobin.

Monoclonal antibodies (mAbs) of predetermined specificity were prepared by immunizing with a free (i.e., not conjugated to any carrier) synthetic peptide representing region 15–22 (site 1) of sperm whale myoglobin (SpMb). The cross-reactions of Mb variants with three mAbs were studied in order to determine whether such interactions are influenced by substitutions outsde the site. Finback whale Mb, which has no substitutions within region 15–22, showed lower cross-reactivity and relative binding affinity than the reference antigen, SpMb. Bottle-nose Atlantic dolphin myoglobin (BdMb) and badger myoglobin (BgMb), although they have identical substitutions within region 15–22 (Ala-15 to Gly and Val-21 to Leu), showed very different binding properties. The cross-reaction of BdMb was quite comparable to that of SpMb, while that of BgMb was much lower. Since the two proteins have identical structures in regions 15–22, the differences in their cross-reactivities are readily attributed to the effects of substitutions outside this region. Another pair of myoglobins, horse myoglobins (HsMb) and chicken myoglobin (ChMb), also have two identical substitutions (Ala-15 to Gly and Val-21 to Ile) within region 15–22, but possessed different cross-reactivity. The results indicate that the reaction of mAbs, whose specificity is precisely known and predetermined by the immunizing free peptide, can be markedly affected by substitutions outside the indicated binding region on the protein.     

Effects of amino acid substitutions outside an antigenic site on protein binding to monoclonal antibodies of predetermined specificity obtained by peptide immunization: Demonstration with region 15–22 (antigenic site 1) of myoglobin

Monoclonal antibodies (mAbs) of predetermined specificity were prepared by immunizing with a free (i.e., not conjugated to any carrier) synthetic peptide representing region 15–22 (site 1) of sperm whale myoglobin (SpMb). The cross-reactions of Mb variants with three mAbs were studied in order to determine whether such interactions are influenced by substitutions outsde the site. Finback whale Mb, which has no substitutions within region 15–22, showed lower cross-reactivity and relative binding affinity than the reference antigen, SpMb. Bottle-nose Atlantic dolphin myoglobin (BdMb) and badger myoglobin (BgMb), although they have identical substitutions within region 15–22 (Ala-15 to Gly and Val-21 to Leu), showed very different binding properties. The cross-reaction of BdMb was quite comparable to that of SpMb, while that of BgMb was much lower. Since the two proteins have identical structures in regions 15–22, the differences in their cross-reactivities are readily attributed to the effects of substitutions outside this region. Another pair of myoglobins, horse myoglobins (HsMb) and chicken myoglobin (ChMb), also have two identical substitutions (Ala-15 to Gly and Val-21 to Ile) within region 15–22, but possessed different cross-reactivity. The results indicate that the reaction of mAbs, whose specificity is precisely known and predetermined by the immunizing free peptide, can be markedly affected by substitutions outside the indicated binding region on the protein.     

Effects of amino acid substitutions outside an antigenic site on protein binding to monoclonal antibodies of predetermined specificity obtained by peptide immunization: demonstration with region 56-62 (antigenic site 2) of myoglobin.

This work was carried out in order to study the effects of substitutions outside antigenic site 2 of sperm whale myoglobin (SpMb) on the reactivity of protein variants with antisite 2 monoclonal antibodies (mAbs). A synthetic peptide corresponding to region 56–62 (site 2) of SpMb was used as an immunogen in mice in its free form (i.e., without coupling to any carrier) to prepare a panel of mAbs whose predetermined specificity is directed, by design, against this region. The binding of three of these mAbs to eight Mbs from different species was studied. Myoglobins of Pacific common dolphin, finback whale, and horse, which have no substitutions within region 56–62 relative to SpMb, showed remarkable differences in their cross-reactivities and relative affinities with each of the mAbs. Myoglobins of badger, chicken, and dog, although they have an identical substitution within the site (Ala-57 to Gly), exhibited cross-reactivities with a given mAb that were affected differently. Echidna Mb, which has one replacement (Glu-59 to Ala) within region 56–62, displayed greatly reduced cross-reactivities and relative binding affinities. The results, especially those from Mbs that have no substitutions within the boundaries of site 2, clearly indicate that substitutions outside site 2 of Mb can exert drastic effects on the binding of the Mb variants with mAbs whose specificity was predesigned to be against the site. These indirect effects and their impact on site reactivity will completely explain previous findings on cross-reactivities of Mb variants with mAbs of unknown specificity and will rule out the postulations of discontinuous sites in Mb, which were based on the assumption that every substitution affecting reactivity is directly involved in binding to antibody.     

Effects of amino acid substitutions outside an antigenic site on protein binding to monoclonal antibodies of predetermined specificity obtained by peptide immunization: Demonstration with region 56–62 (antigenic site 2) of myoglobin

This work was carried out in order to study the effects of substitutions outside antigenic site 2 of sperm whale myoglobin (SpMb) on the reactivity of protein variants with antisite 2 monoclonal antibodies (mAbs). A synthetic peptide corresponding to region 56–62 (site 2) of SpMb was used as an immunogen in mice in its free form (i.e., without coupling to any carrier) to prepare a panel of mAbs whose predetermined specificity is directed, by design, against this region. The binding of three of these mAbs to eight Mbs from different species was studied. Myoglobins of Pacific common dolphin, finback whale, and horse, which have no substitutions within region 56–62 relative to SpMb, showed remarkable differences in their cross-reactivities and relative affinities with each of the mAbs. Myoglobins of badger, chicken, and dog, although they have an identical substitution within the site (Ala-57 to Gly), exhibited cross-reactivities with a given mAb that were affected differently. Echidna Mb, which has one replacement (Glu-59 to Ala) within region 56–62, displayed greatly reduced cross-reactivities and relative binding affinities. The results, especially those from Mbs that have no substitutions within the boundaries of site 2, clearly indicate that substitutions outside site 2 of Mb can exert drastic effects on the binding of the Mb variants with mAbs whose specificity was predesigned to be against the site. These indirect effects and their impact on site reactivity will completely explain previous findings on cross-reactivities of Mb variants with mAbs of unknown specificity and will rule out the postulations of discontinuous sites in Mb, which were based on the assumption that every substitution affecting reactivity is directly involved in binding to antibody.     

Effects of amino acid substitutions outside an antigenic site on protein binding to monoclonal antibodies of predetermined specificity obtained by peptide immunization: Demonstration with region 113–120 (antigenic site 4) of myoglobin

Immunochemical cross-reactivity of protein variants has been very frequently used to map protein antigenic sites. The approach is based on the assumption that amino acid substitutions affecting the binding of a protein to its antibody, particularly when monoclonal antibodies (mAbs) are used, must be part of the antigenic site and not far from it. The assumption was investigated in this study by determining the effects of amino acid substitutions outside the antigenic site on the reactivity of six myglobin (Mb) variants with three mAbs of predetermined specificity prepared by immunization with a free synthetic peptide representing region 113–120 (antigenic site 4) of Mb. Two of the Mb variants used had no substitutions within residues 113–120 (the region to which the specificity of the mAbs is directed) and yet exhibited markedly decreased cross-reactions and binding affinities, relative to the reference antigen, sperm-whale Mb. The other three Mb variants possessed substitutions within, as well as outside, region 113–120 and showed very little cross-reactivities. The results of this study, particularly with the Mbs that have no substitutions within the indicated antigenic site, clearly show that substitutions outside the site, and which by design are not part of the site, can influence very markedly the reactivity of the protein variant with the anti-site mAbs. The approach can, therefore, lead to serious errors if used to identify residues of protein antigenic sites.     

Effects of amino acid substitutions outside an antigenic site on protein binding to monoclonal antibodies of predetermined specificity obtained by peptide immunization: demonstration with region 94-100 (antigenic site 3) of myoglobin.

Amino acid substitutions outside protein antigenic sites are very frequently assumed to exert no effect on binding to antiprotein antibodies, especially if these are monoclonal antibodies (mAbs). In fact, a very popular method for localization of residues in protein antigenic sites is based on the interpretation that whenever a replacement causes a change in binding to antibody, then that residue will be located in the antigenic site. To test this assumption, mAbs of predetermined specificity were prepared by immunization with a free (i.e., without coupling to any carrier) synthetic peptide representing region 94–100 of sperm whale myoglobin (Mb). The cross-reactivities and relative affinities of three mAbs with eight Mb variants were studied. Five Mb variants which had no substitutions within the boundaries of the designed antigenic site exhibited remarkable, and in two cases almost complete, loss in cross-reactivity relative to the reference antigen, sperm whale Mb. Two myoglobins, each of which had one substitution within region 94–100, showed little or no reactivity with the three mAbs. It is concluded that substitutions outside an antigenic site can exert drastic effects on the reactivity of a protein with mAbs against the site and that caution should be exercised in interpreting cross-reactivity data of proteins to implicate residues directly in an antigenic site.     

Effects of amino acid substitutions outside an antigenic site on protein binding to monoclonal antibodies of predetermined specificity obtained by peptide immunization: Demonstration with region 94–100 (antigenic site 3) of myoglobin

Amino acid substitutions outside protein antigenic sites are very frequently assumed to exert no effect on binding to antiprotein antibodies, especially if these are monoclonal antibodies (mAbs). In fact, a very popular method for localization of residues in protein antigenic sites is based on the interpretation that whenever a replacement causes a change in binding to antibody, then that residue will be located in the antigenic site. To test this assumption, mAbs of predetermined specificity were prepared by immunization with a free (i.e., without coupling to any carrier) synthetic peptide representing region 94–100 of sperm whale myoglobin (Mb). The cross-reactivities and relative affinities of three mAbs with eight Mb variants were studied. Five Mb variants which had no substitutions within the boundaries of the designed antigenic site exhibited remarkable, and in two cases almost complete, loss in cross-reactivity relative to the reference antigen, sperm whale Mb. Two myoglobins, each of which had one substitution within region 94–100, showed little or no reactivity with the three mAbs. It is concluded that substitutions outside an antigenic site can exert drastic effects on the reactivity of a protein with mAbs against the site and that caution should be exercised in interpreting cross-reactivity data of proteins to implicate residues directly in an antigenic site.     

Functional evaluation of heme vinyl groups in myoglobin with symmetric protoheme isomers

We replaced protoheme-IX in native myoglobin with the symmetric protohemes-III and -XIII, in order to investigate the role of heme vinyl-globin contacts on Mb function. The UV-visible spectra and the resonance Raman spectra in the high-frequency region (containing oxidation, spin, and coordination state marker lines) of the two reconstituted Mbs were very similar. However, the signal intensity of the Soret band in the CD spectra and the resonance Raman lines for vinyl bending modes in the low-frequency region notably differed, thereby reflecting altered heme peripheral contacts. The redox potentials, formal heterogeneous electron-transfer rates, and thermal denaturation temperatures of the two reconstituted Mbs were also indistinguishable. In addition, the oxygen binding properties of the ferrous deoxy Mbs were comparable. These results demonstrate that altered heme vinyl-globin interactions only slightly affect the physical properties of Mb. It is therefore likely that the orientation of protoheme-IX about the alpha,gamma-axis in the heme pocket is not necessarily a crucial factor for oxygen binding to native Mb.     

Structure and ligand binding properties of leucine 29(B10) mutants of human myoglobin.

Site-specific mutants of human myoglobin (Mb) have been prepared, in which Leu29 (B10) is replaced by Ala(L29A) or Ile(L29I), in order to examine the influence of this highly conserved residue in the hydrophobic clusters of the heme distal site on the heme environmental structure and ligand binding properties of Mb. Structural characterizations of these recombinant Mbs are studied by electronic absorption, infrared (IR), one- and two-dimensional proton nuclear magnetic resonance spectroscopies, and ligand-binding kinetics by laser photolysis measurements under ambient and high pressures (up to 2000 bar). Multiple split carbon monoxide (CO) stretch bands in the IR spectra of mutant Mbs exhibit a relative decrease of the 1945 cm-1 band (approximately 50%) which is associated with an upright binding geometry of CO, accompanied by an increase of the tilted CO conformer at 1932 cm-1. On the basis of these results, replacement of Leu29(B10) by Ala or Ile appears to allow bound CO to rotate from a conformation pointing toward the beta meso carbon of the heme group to the one pointing toward the alpha meso carbon atom, presumably filling the space left by removal of the delta 2 carbon atom of Leu29(B10). These substitutions cause the rate constants for CO and O2 association to decrease almost 3-5-fold. Present results show that CO and O2 bindings to the heme iron of Mb are controlled by Leu29(B10) by influencing the structure of close vicinity of the heme and the geometry of iron-bound ligand. Further, mutant Mbs (Leu72(E15)----Ala and Leu104 (G5)----Ala) which have altered residues in another hydrophobic clusters around proximal and distal site are also examined.