Epitopic characterization of neuropeptide Y (NPY) by alanine-scanning mutagenesis.

Characterization of the epitopic structures of neuropeptide Y (NPY) has been studied by alanine-scanning mutagenesis, based on our previous investigation of a panel of six murine anti-NPY IgM monoclonal antibodies. To evaluate the structural requirement for these anti-NPY IgM antibodies, recognition variants of the native sequences of the NPY fragment (19-36) were prepared by single alanine substitutions in residues 22 and 25-36. Their binding to these antibodies was examined by competitive inhibition assays. The results demonstrated that the epitopic structures are largely confined to residues 25-36 of NPY and the C-terminal residues of NPY are essential for these anti-NPY IgM antibodies recognition. It emphasizes the notion that even small regions of a protein consisting of as few as 15 residues (22-36) can exhibit multiple epitopic structures. In several anti-NPY IgM antibodies, pairs of residues on opposite faces of the alpha-helix interact with the antibody site, which indicates that the antibody site consists either of a cavity or a deep groove either of which encompasses the alpha-helical segment sufficiently to allow simultaneous contact with most of the residues of this segment.

Primary B-cell response to neuropeptide Y and bovine pancreatic polypeptide.

An analysis of the murine primary response to protein epitopes has been made with two small highly structured proteins, neuropeptide Y (NPY) and bovine pancreatic polypeptide (BPP), both of 36-amino acid residue length and containing helical structures. A group of cell lines producing monoclonal IgM antibody have been prepared consisting of six anti-NPY and two anti-BPP. The VH nucleotide sequences have been determined and characterized as germ-line either by identity to established germ-line sequences or by inference from the germ-line character of the D and JH segments. The intrinsic association constants for the homologous ligands have been estimated to range from 10(4) to 10(7) M-1 based on competitive ELISA. No severe restriction in the utilization of VH families, D segments or JH segments appears to be involved in this response. Among the eight cell lines, three VH families were represented as well as all three families of D segments and all of the JH segments, although some preference for JH3 was indicated. The length of the N(D)N sequences was also not subject to restriction, ranging from 9 to 29. Two unusual features of the CRD3s were noted, one involving the utilization of an uncommon DSP2 segment and the other the apparent occurrence of a D-D fusion.

Probing the transglutaminase-mediated, posttranslational modification of proteins during development.

Sphaerechinus granularis eggs were fertilized in seawater in the presence of 0.2 mM dansylcadaverine, and development was allowed to take place with this compound in the medium. gamma-Glutamyldansylcadaverine, indicative of the utilization of the amine tracer by intrinsic transglutaminase, was isolated from the embryonic proteins, and identity of the product with the chemically synthesized gamma-glutamyl derivative of dansylcadaverine was confirmed. Covalent labeling of proteins occurring during development was examined by means of electrophoresis in NaDodSO4, followed by immunoblotting with an antibody that specifically recognized the dansyl hapten. There was an increase in the total uptake of the tracer at an essentially constant rate with each cell division, from 2- to 8- and 64-cell stages. Moreover, multiple protein labeling was evident in all specimens. The described concept of studying posttranslational modifications in vivo by transglutaminase through detection of the haptenic or specific ligand recognizable group of an incorporated small amine substrate will undoubtedly be of general utility for probing the functions of this family of enzymes in other cell types as well.

Bacterial expression of immunoglobulin VH proteins.

A bacterial expression system in Escherichia coli has been developed that produces as much as 10 mg/l of culture of the VH protein associated with monoclonal antibodies specific for the 5-dimethylaminonaphthalene-2-sulfonyl (Dns) group. This system has been applied to the expression of the VH genes derived from a low-affinity, IgM-producing hybridoma and from a high-affinity, IgG-producing cell line. The plasmid vectors (contributed by Dr William F. Studier) utilize a T7 expression cassette whose activity is initiated by infection with a lambda phage derivative carrying the T7 RNA polymerase gene. The VH proteins were extracted from the bacterial pellet in 8 M urea and purified by chromatography in 8 M urea. Recombinants with the homologous light (L) chains were prepared to yield VHL molecules. These were used to measure intrinsic affinity for Dns-lysine by resonance energy transfer. The association constants were 7 x 10(6) M-1 and 7 x 10(9) M-1 for the low- and high-affinity systems, respectively. These values are not significantly different from those observed with monoclonal antibodies secreted from the corresponding cell lines. This system lends itself to the quantitative evaluation of the binding properties of the VH protein itself as well as the modulation of affinity by site-directed mutagenesis.

Organization of the middle RNA segment of snowshoe hare Bunyavirus.

The genetic organization of the M RNA segment of snowshoe hare (SSH) virus, a member of the Bunyavirus genus of the family Bunyaviridae, has been determined. The middle (M) RNA segment has a single open reading frame (ORF) of 1441 amino acids. We have used amino- and carboxy-terminus sequencing and synthetic peptides to map proteins within the ORF. The order of the proteins translated from the single large open reading frame is G2, NSm, G1. The G2 protein extends from amino acids 14 to 299. The molecule is 286 residues long, with a computed nonglycosylated molecular weight of 31,973 Da. It is preceded by a cleaved 13 amino acid signal sequence. G2 includes a long highly hydrophobic sequence and contains three potential N-linked glycosylation sites. The G1 protein occupies the C-terminal end of the open reading frame from amino acids 474 to 1441 (968 amino acid residues) and has a computed nonglycosylated, molecular weight of 108,981 kDa. It has two potential N-linked glycosylation sites, and a potential transmembrane region followed by a potential cytoplasmic domain at the C-terminal end. If membrane associated it has an orientation of N-terminus outer, C-terminus inner. Limited trypsin digestion removes a 33-kDa fragment from the N-terminal end, leaving a virion-associated truncated G1 molecule (amino acids 762 to 1441) with a single N-linked glycosylation site. Between the G2 and G1 molecules there are 174 amino acids, sufficient to code for 19 kDa of protein. Some antibodies raised against peptides within this region react with proteins of 11 kDa (NSm) and 10 kDa present in infected cell lysates, but the exact relationship of these proteins to the open reading frame remains to be determined.

Transamidating activities of factor XIIIa and of transglutaminases, measured by an ELISA procedure.

The dansyl hapten in dansylcadaverine offers unique possibilities for measuring the incorporation of the monoamine into proteins (e.g. N,N'-dimethylcasein) by transamidating enzymes such as factor XIIIa and the transglutaminases. The protein-bound dansylcadaverine was assayed by an ELISA procedure based on a monoclonal antibody to the dansyl moiety.

Induction of polyclonal and monoclonal antibody responses to cholera toxin by the synthetic peptide approach.

The induction of an antibody response to cholera toxin (CT) was studied by using the synthetic peptide approach. Two peptides, corresponding to the amino acid sequences from residues 57 to 69 (CTBP1) and 47 to 60 (CTBP2) of the cholera toxin B subunit, were synthesized by the solid-phase method. These peptides were primarily chosen on the basis of their hydrophilicity and sequence identity with the B subunit of E. coli toxin (LTh). Synthesized peptides were coupled to carrier proteins through additional cysteine residues at the carboxyl (CTBP1) or amino terminal ends (CTBP2). Rabbit antisera to the peptide-carrier conjugates were found to react with the free peptides as well as intact CT, its B subunit and LTh as determined by the conventional enzyme-linked immunosorbent assay (ELISA). On the other hand, anti-peptide sera failed to react with CT and LTh in GM1 (ganglioside)--ELISA, thereby suggesting the possible involvement of CTBP1 and CTBP2 peptide regions of the toxin molecule in GM1 receptor binding. Both anti-peptide sera possessed rather weak toxin neutralizing activity in the rabbit ileal loop assay. However, such activity was statistically significant (0.02 less than P less than 0.05) only in the case of anti-CTBP2 serum. Similar results were also obtained with mouse polyclonal anti-peptide sera. Ten mouse monoclonal antibodies were obtained against the CTBP1 peptide, five of which reacted to CT, the B subunit and LTh in ELISA. Interestingly, one monoclonal showed strong reactivity against CT and LTh although it reacted very weakly against the immunizing peptide CTBP1. It appears that the immunizing peptide probably exists in multiple conformers in the conjugated form, some of which may mimic more closely its structural features in the intact protein than in the free state. Results obtained in this study suggest that synthetic peptides can serve as useful probes for the structural analysis of CT or related toxins and may be useful in vaccine development.

Affinity of anti-peptide antibodies measured by resonance energy transfer.

Because of the increasing use of monoclonal anti-peptide antibodies we have undertaken to formulate a general method for the measurement of intrinsic association constants characterizing complex formation between peptide and antibody. The method is based on the phenomenon of resonance energy transfer between tryptophan-excited antibody and an appropriate fluorophor conjugated to the amino terminus of the peptide. The fluorophor we have employed is 8-(2-N-succinylaminoethylamino)-1-naphthalene-sulfonic acid with an absorption maximum at 344 nm and an emission maximum at 500 nm. The model peptide used was the sequence corresponding to residues 48-60 of the regulatory subunit of aspartyltranscarbamoylase. Three IgG and two IgM affinity-purified monoclonal anti-peptide antibodies were used in the fluorescence titration experiments. A maximum value of 2.1 X 10(6) M-1 was found for the IgG antibodies and a maximum of 2.7 X 10(4) M-1 for the IgM antibodies. These limited results suggest similar behavior for the anti-peptide B cell response with respect to affinity maturation as observed for other specificities. In particular it is likely that the IgM affinities are restricted to the potential available in the germline repertoire of variable region genes and, therefore, express only germline affinities.

Germ-line affinity and germ-line variable-region genes in the B cell response.

The predominance of germ-line genes in IgM expression was evaluated from the nucleotide sequences of mRNA, derived from 10 hybridoma cell lines, coding for the VH and VL regions of anti-5-dimethylaminonaphthalene-1-sulfonyl (anti-Dns) IgM antibody. At least six germ-line VH gene segments distributed among four families are used in this response. Seven of the 10 independently rear-ranged VH genes were identified as germ line, with the other three possibly germ line. In all of them the D and JH portions retained the germ-line sequences of the D and JH segments from which they were derived. Maximum diversity was found in the D segments and the use of noncoded nucleotides at the VH-D and D-JH junctions. Of the eight cell lines expressing the lambda light chains, all were germ line and involved the three subtypes. Maximum affinity for the homologous ligand was found among the seven cell lines identified as expressing germ-line gene segments. Thus any somatic mutation among the remaining 3 cell lines did not provide enhanced affinity and the observed affinity of each cell line can be described as germ-line affinity. It is further suggested that the anti-Dns selectivity of the IgM antibodies is associated primarily with the CDR3 regions.

Identification of transglutaminase substrates in inside-out vesicles from human erythrocytes: immunoblotting with anti-dansyl antibody.

An immunoblotting procedure, using anti-dansyl antibody, was employed to demonstrate that band 3 protein was the predominant substrate in inside-out vesicles from human erythrocytes reacting with transglutaminase.

Antibodies to the first constant-region domain of the murine mu-chain induced by a synthetic peptide.

A peptide corresponding to the N-terminal 13 amino acid residues of the murine C mu 1 domain was synthesized by the solid-phase method and was coupled to carrier proteins through an additional cysteine residue. Rabbit antisera to these peptide-carrier conjugates were found to react with intact mouse IgM as well as its Fab mu fragment. These antisera also reacted with the isolated mu-chain and the V mu fragment of the heavy chain. This fragment consists of the VH-domain and the N-terminal residues of the C mu 1 domain preceding the interchain half-cystine. No significant reactivity of these antisera was found with the IgM of human and equine species or with murine IgG isotypes. Apart from their utility in the purification of the V mu fragment, these and similar antisera can be used to probe structure and function relationships of immunoglobulin domains. Furthermore, such antisera may be used in the study of expression vectors with heavy-chain genes to detect the expression of truncated forms of heavy chain in E. coli and other hosts.

Interaction of monoclonal anti-peptide antibodies with lysozyme.

The interaction of monoclonal anti-peptide antibodies with the free peptide and its protein counterpart has been evaluated for hen egg white lysozyme and the peptide constituting residues 38 to 45. Fluorescence methodology has been developed for the measurement of association constants based on resonance energy transfer between the excited tryptophan of antibody and bound peptide ligand conjugated to a fluorescent probe. Five antibodies, four IgM and one IgG, have been assayed by ELISA, and have demonstrated binding to the adsorbed peptide alone, to the adsorbed lysozyme alone, or to both. Multivalent interaction with the adsorbed ligand is a key factor in the efficacy of binding. Measurement of binding constants in homogeneous solution, by equilibrium dialysis and energy transfer, demonstrated that lysozyme was bound to an IgG antipeptide antibody with an association constant (4 X 10(2) M-1) 200-fold less than that for the free peptide (8 X 10(4) M-1). It was also inferred for IgM that an association constant of the order of 10(2) M-1 was sufficient to effect selective interaction in a system providing multivalent interaction. The shared conformations between protein and peptide, implied by the specific reactivity of the anti-peptide antibody with the protein, points to structural fluctuations of the surface regions and residues of globular proteins.

Restriction in IgM expression--VI. Affinity analysis of monoclonal anti-dansyl antibodies.

Affinity restriction in the IgM response to the 5-dimethylaminonaphthalene-1-sulfonyl (dansyl) group was studied with 56 monoclonal IgG and IgM affinity-purified antibodies. These were generated by immunization with dansyl-Ficoll or dansyl-B gamma G. Association constants for N epsilon-dansyl-lysine were determined by fluorescence titration based on resonance energy transfer. The antibodies were also characterized with respect to the emission maximum of the antibody-ligand complex. The distribution of binding constants covered a 100,000-fold range, demonstrating thereby a restriction in IgM affinity relative to IgG affinity. In the secondary response the IgG affinity exhibited a ceiling of about 1 X 10(10) M-1, a value in accord with the size and hydrophobic nature of the dansyl group. In the case of IgM, with one exception, the value of 1 X 10(7) M-1 was not exceeded with IgM antibodies isolated from 28 hybridomas. This system, therefore, provides further evidence for the restriction in expression of IgM as a general feature of the immune response.

Restriction in IgM expression--V. Fine structure analysis in the anti-lactose system.

A methodology for the analysis of the fine specificity of monoclonal anti-lactose IgM and IgG antibodies is described using structural variants of the homologous lactoside epitope. These variants are used as inhibitors of the binding of a reference ligand N-(5-dimethylaminonaphthalene-1-sulfonyl)-p-aminophenyl-beta-lactoside. Excitation of the antibody with bound ligand at 295 nm leads to resonance energy transfer to and fluorescence emission by the ligand. Titration of the antibody-ligand mixture with the inhibitor and measurement of the emission at 550 nm provide the data for the calculation of the binding constants of the inhibitors. A comparison of two IgM and two IgG antibodies showed that the higher affinity of the IgG antibodies arises from their specific interaction with both hexosides of the lactoside in contrast to IgM antibodies which do not engage the non-terminal hexoside as effectively. The quantitative significance of this difference is a differential free energy contribution of about -3 kcal/mole to the binding of lactoside by IgG. A finer discrimination between homologous and several cross-reactive molecules is evident with IgG antibody compared to IgM. The former exhibits about 100-fold greater difference in their binding constants than does IgM. These differences applied to biologically relevant multivalent interactions, where functional affinity governs complex formation, suggest a possible explanation for the IgM to IgG conversion characteristic of the humoral immune response.

Attachment of immunoglobulin to liposomal membrane via protein carbohydrate.

A general method has been developed for the covalent attachment of immunoglobulin molecules to the outer layer of liposomal membranes. Aldehyde groups are generated by the mild oxidation with periodate or galactose oxidase of the carbohydrate groups on the constant region of the heavy chain. The oxidized protein is then reacted with a hydrazide group linked to a membrane component. Detailed studies were carried out with monomers of a monoclonal human IgM and two monoclonal murine IgM antibodies specific for the 1-dimethylaminonaphthalene-5-sulfonyl (Dns) group. Two hydrazide-containing hydrophobic reagents were used: N alpha-lauroyl, N epsilon-Dns-lysine hydrazide and lauric acid hydrazide. The number of protein aldehyde groups formed was assayed by reaction with N-(2,4-dinitrophenyl)-beta-alanylglycylglycine hydrazide. Measurement of the intrinsic affinity for Dns-lysine of the processed anti-Dns IgMs demonstrated no substantial impairment of the specific reactivity of the antibody either from the oxidation step or the subsequent attachment to small unilamellar vesicles. The extent of attachment of antibody to small unilamellar vesicles was evaluated with respect to the mol% of hydrazide in the membrane, the duration of the incubation period for the aldehyde-hydrazide reaction and the ratio of protein to hydrazide. The yield of attached protein was significantly dependent on each of these experimental parameters over the ranges tested. Under the most favorable conditions the extent of covalent attachment of IgMs to small unilamellar vesicles was 535 micrograms of protein per mumol of phospholipid, corresponding to 0.3 mol% of protein. Under these conditions, 61% of the total protein was associated with the small unilamellar vesicle fraction after fractionation by gel filtration. The attachment of the antibody to small unilamellar vesicles did not destroy the integrity of the vesicles, as demonstrated by the retention of carboxyfluorescein following initial encapsulation during the formation of small unilamellar vesicles.

Antibody interaction with a membrane-bound fluorescent ligand on synthetic lipid vesicles.

The interaction of membrane-bound ligand with bivalent and monovalent fragments of monoclonal antibody was studied by fluorescence and precipitation analysis using synthetic lipid vesicles. The ligand N epsilon-[5-(dimethylamino)-naphthyl-1-sulfonyl]lysine was linked to the hydrophobic anchor dipalmitoylphosphatidylethanolamine and ranged between 0.01 and 1 mol% of the membrane components. The effects of cholesterol on the specific interaction were observed over the range of 0-50 mol%. A precipitation assay was developed to evaluate various factors related to the cross-linking of small unilamellar vesicles by bivalent antibody. The cholesterol content was critical for this process as demonstrated by the increased efficiency of precipitation over the range of 0-40 mol% of this component. Fluorescence analysis yielded the parallel finding of increased accessibility of the ligand to the antibody with greater cholesterol content. Increased surface density of the ligand also was found to enhance the intervesicle interaction. Finally, a comparison of the kinetics by fluorescence analysis of the binding of monovalent and bivalent fragments indicated that the bivalent interaction involved primarily the cross-linking of vesicles in accord with published findings of the interaction of monoclonal antibody with cell membrane antigens.

Specific reactivity of lipid vesicles conjugated with oriented anti-lactose antibody fragments.

The method previously described (Sinha, D. and Karush, F. (1979) Biochem. Biophys. Res. Commun. 90, 554--560) for the oriented attachment of immunoglobulins to lipid vesicles has been used to confer specific reactivity on liposomes by their conjugation with anti-lactose Fab' fragments derived from rabbit IgG antibody. It is estimated that one-third of the Fab' fragments was irreversibly attached to liposomal membrane, resulting in a membrane concentration of 2 mmol of Fab' per mol of total lipid. The specific reactivity of the modified liposomes was demonstrated by agglutination with a multivalent, lactose-containing diheteroglycan. The availability of virtually all of the binding sites of the attached antibody for reaction with ligand was established by a fluorescence quenching titration with N-(N epsilon-Dnp-L-lysyl)-p-aminophenyl-beta-lactoside. An intrinsic association constant of 8.9 x 10(6) M-1 was found for the attached Fab' compared to a value of 2.8 x 10(6) M-1 for free anti-lactose Fab'. In addition the maximum values for the quenching by bound ligand of the fluorescence of free and attached antibody were the same. It can be concluded that the chemical procedures used to effect attachment of the antibody to the lipid vesicles allow retention of the original structure of the antibody site and its accessibility to external components.

Restriction in IgM expression. III. Affinity analysis of monoclonal anti-lactose antibodies.

A clonal analysis has been made of the murine BALB/C response to lactose-containing immunogens with respect to the affinity restriction in IgM expression. Monoclonal IgM and IgG antibodies were prepared from antilactosyl hybridomas generated from mice immunized with p-aminophenyl-beta-lactoside (PAPL) coupled to BGG or with a vaccine of Streptococcus faecalis (Strain N). Association constants for the binding of monovalent derivatives of PAPL were measured by quenching fluorescence. These derivatives carried a probe (2,4-dinitrophenyl or 1-dimethylaminonaphthalene-5-sulfonyl) that served to quench the protein fluorescence when the ligand was complexed with the protein. The central finding was that with both immunogens a restriction in the affinity of IgM was demonstrated since the highest values exhibited by IgG antibody exceeded by at least a factor of 50 the highest comparable values of the association constants for IgM antibody. It is suggested that the hypothesis of germ-line restriction, previously proposed as the basis for the affinity restriction of IgM, may also be applicable to the T cell receptor since its distinctive properties parallel those of IgM antibody.