Structural diversity in a conserved cholera toxin epitope involved in ganglioside binding

Detection of intermolecular NOE interactions in large protein complexes

Intermolecular NOE interactions are invaluable for structure determination of biomolecular complexes by NMR and they represent the "gold-standard" amongst NMR measurements for characterizing interfaces. These NOEs constitute only a small fraction of the observed NOEs in a complex and are usually weaker than many of the intramolecular NOEs. A number of methods have been developed to remove the intramolecular NOEs that interfere with the identification of intermolecular NOEs. NMR experiments used to observe intermolecular NOE interactions in large protein complexes must cope with the short T2 relaxation time of the protons and heteronuclei in these complexes because they result in severe losses in sensitivity. The isotope-edited/isotope-filtered experiment is a powerful method for extraction of intermolecular NOEs in biomolecular complexes. Its application to large protein complexes is limited because of severe losses in signal-to-noise ratio caused by delays in the pulse sequence necessary for the multiple magnetization transfer steps between protons and heteronuclei. Isotope-edited/isotope-edited experiments, in which one protein is usually labeled with ¹³C and the other is labeled with ¹⁵N, reduce possible artifacts in the filtering experiments and improve somewhat the sensitivity of these experiments. Sensitivity can also be improved by deuteration of the components of the complex in order to replace either or both of the filtering or editing steps. Asymmetric deuteration, where aromatic residues in one protein and non-aromatic amino acids in the other are reverse protonated, can eliminate the editing and the filtering steps altogether, thus maintaining high sensitivity even for large proteins complexes. Difference spectroscopy and the use of 2D NOESY experiments without using editing or filtering steps can significantly increase the signal-to-noise ratio in experiments aimed at observing intermolecular NOEs. The measurement of NOESY spectra of three different preparations of a heterodimeric complex under investigation in which one or neither of the components is uniformly deuterated, and calculation of a double difference spectrum provides information on all intermolecular NOEs of non-exchangeable protons. Recent studies indicate that many protein-protein interactions are actually between a protein and a linear peptide recognition motif of the second protein, and determinants represented by linear peptides contribute significantly to the binding energy. NMR is a very versatile method to study peptide-protein interactions over a wide range of binding affinities and binding kinetics. Protein-peptide interactions in complexes exhibiting tight binding can be studied using single and/or multiple deuteration of the peptide residues and measuring a difference NOESY spectrum. This difference spectrum will show exclusively intra- and intermolecular interactions of the peptide protons that were deuterated. Transferred nuclear Overhauser spectroscopy (TRNOE) extends NMR to determine interactions within and between a weakly-bound rapidly-exchanging peptide and its protein target. TRNOE, together with asymmetric deuteration, is applicable to complexes up to ∼100KDa and is highly sensitive, taking advantage of the long average T2 of the peptide protons. Among the methods described in this review, TRNOE has the best potential to determine intermolecular NOEs for the upper molecular weight limit of proteins that can be studied in detail by NMR.

Mutational analysis of ganglioside GM(1)-binding ability, pentamer formation, and epitopes of cholera toxin B (CTB) subunits and CTB/heat-labile enterotoxin B subunit chimeras

Variants of cholera toxin B subunit (CTB) were made by bisulfite- and oligonucleotide-directed mutagenesis of the ctxB gene. Variants were screened by a radial passive immune hemolysis assay (RPIHA) for loss of binding to sheep erythrocytes (SRBC). Variant CTBs were characterized for the formation of immunoreactive pentamers, the ability to bind ganglioside GM(1) in vitro, and reactivity with a panel of monoclonal anti-CTB antibodies. Substitutions at eight positions (i.e., positions 22, 29, 36, 45, 64, 86, 93, and 100) greatly reduced the yield of immunoreactive CTB. RPIHA-negative substitution variants that formed immunoreactive pentamers were obtained for residues 12, 33, 36, 51, 52 + 54, 91, and 95. Tyrosine-12 was identified as a novel residue important for GM(1) binding since, among all of the novel variants isolated with altered RPIHA phenotypes, only CTB with aspartate substituted for tyrosine at position 12 failed to bind significantly to ganglioside GM(1) in vitro. In contrast, CTB variants with single substitutions for several other residues (Glu-51, Lys-91, and Ala-95) that participate in GM(1) binding, based on the crystal structure of CTB and the oligosaccharide of GM(1), were not appreciably altered in their ability to bind GM(1) in vitro, even though they showed altered RPIHA phenotypes and did not bind to SRBC. Hybrid B genes made by fusing ctxB and the related Escherichia coli heat-labile enterotoxin eltB genes at codon 56 produced CTB variants that had 7 or 12 heat-labile enterotoxin B residue substitutions in the amino or carboxyl halves of the monomer, respectively, each of which which also bound GM(1) as well as wild-type CTB. This collection of variant CTBs in which 47 of the 103 residues were substituted was used to map the epitopes of nine anti-CTB monoclonal antibodies (MAbs). Each MAb had a unique pattern of reactivity with the panel of CTB variants. Although no two of the epitopes recognized by different MAbs were identical, most of the single amino acid substitutions that altered the immunoreactivity of CTB affected more that one epitope. The tertiary structures of the epitopes of these anti-CTB MAbs are highly conformational and may involve structural elements both within and between CTB monomers. Substitution of valine for alanine at positions 10 and 46 had dramatic effects on the immunoreactivity of CTB, affecting epitopes recognized by eight or six MAbs, respectively.

Novel Zn(2+)-chelating peptides selected from a fimbria-displayed random peptide library

The display of peptide sequences on the surface of bacteria is a technology that offers exciting applications in biotechnology and medical research. Type 1 fimbriae are surface organelles of Escherichia coli which mediate D-mannose-sensitive binding to different host surfaces by virtue of the FimH adhesin. FimH is a component of the fimbrial organelle that can accommodate and display a diverse range of peptide sequences on the E. coli cell surface. In this study we have constructed a random peptide library in FimH. The library, consisting of approximately 40 million individual clones, was screened for peptide sequences that conferred on recombinant cells the ability to bind Zn(2+). By serial selection, sequences that exhibited various degrees of binding affinity and specificity toward Zn(2+) were enriched. None of the isolated sequences showed similarity to known Zn(2+)-binding proteins, indicating that completely novel Zn(2+)-binding peptide sequences had been isolated. By changing the protein scaffold system, we demonstrated that the Zn(2+)-binding seems to be uniquely mediated by the peptide insert and to be independent of the sequence of the carrier protein. These findings might be applied in the design of biomatrices for bioremediation purposes or in the development of sensors for detection of heavy metals.

Fimbriae-assisted bacterial surface display of heterologous peptides

The display of peptide segments on the surface of bacteria offers many new and exciting applications in biotechnology and medical research. Fimbria-assisted display of heterologous sequences is a paradigm for chimeric organelle display on bacteria. Fimbriae are particularly attractive candidates for epitope display for several reasons: (1) they are present in extremely high numbers at the cell surface, (2) they are strong immunogens, (3) they possess inherent adhesive properties, and (4) they can be easily purified. The majority of work dealing with fimbria-assisted peptide display has been focused on the development of recombinant vaccines. A number of different fimbrial types have been used to display immune-relevant sectors of various foreign proteins. Chimeric fimbrial vaccines can be used in the context of purified proteins, however the potential also exists to exploit this technology for the development of live recombinant vaccines. Work has also been performed demonstrating the amenability of fimbriae towards the powerful technology of random peptide display. This review summarises the current state of research in this field.

A model of a gp120 V3 peptide in complex with an HIV-neutralizing antibody based on NMR and mutant cycle-derived constraints

The 0.5beta monoclonal antibody is a very potent strain-specific HIV-neutralizing antibody raised against gp120, the envelope glycoprotein of HIV-1. This antibody recognizes the V3 loop of gp120, which is a major neutralizing determinant of the virus. The antibody-peptide interactions, involving aromatic and negatively charged residues of the antibody 0.5beta, were studied by NMR and double-mutant cycles. A deuterated V3 peptide and a Fab containing deuterated aromatic amino acids were used to assign these interactions to specific V3 residues and to the amino acid type and specific chain of the antibody by NOE difference spectroscopy. Electrostatic interactions between negatively charged residues of the antibody Fv and peptide residues were studied by mutagenesis of both antibody and peptide residues and double-mutant cycles. Several interactions could be assigned unambiguously: F96(L) of the antibody interacts with Pro13 of the peptide, H52(H) interacts with Ile7, Ile9 and Gln10 and D56(H) interacts with Arg11. The interactions of the light-chain tyrosines with Pro13 and Gly14 could be assigned to either Y30a(L) and Y32(L), respectively, or Y32(L) and Y49(L), respectively. Three heavy-chain tyrosines interact with Ile7, Ile20 and Phe17. Several combinations of assignments involving Y32(H), Y53(H), Y96(H) and Y100a(H) may satisfy the NMR and mutagenesis constraints, and therefore at this stage the interactions of the heavy-chain tyrosines were not taken into account. The unambiguous assignments [F96(L), H52(H) and D56(H)] and the two possible assignments of the light-chain tyrosines were used to dock the peptide into the antibody-combining site. The peptide converges to a unique position within the binding site, with the RGPG loop pointing into the center of the groove formed by the antibody complementary determining regions while retaining the beta-hairpin conformation and the type-VI RGPG turn [Tugarinov, V., Zvi, A., Levy, R. & Anglister, J. (1999) Nat. Struct. Biol. 6, 331-335].

Authentic display of a cholera toxin epitope by chimeric type 1 fimbriae: effects of insert position and host background

The potential of the major structural protein of type 1 fimbriae as a display system for heterologous sequences was tested. As a reporter-epitope, a heterologous sequence mimicking a neutralizing epitope of the cholera toxin B chain was inserted, in one or two copies, into four different positions in the fimA gene. This was carried out by introduction of new restriction sites by PCR-mediated site-directed mutagenesis of fimA in positions predicted to correspond to optimally surface-located regions of the subunit protein. Subsequently, the synthetic cholera-toxin-encoding DNA segment was inserted. Several of the chosen positions seemed amenable even for large foreign inserts; the chimeric proteins were exposed on the bacterial surface and the cholera toxin epitope was authentically displayed, i.e. it was recognized on bacteria by specific antiserum. Display of chimeric fimbriae was tested with respect to host background in three different Escherichia coli strains, i.e. an isogenic set of K-12 strains, differing in the presence of an indigenous fim gene cluster, as well as a wild-type isolate. Immunization of rabbits with purified chimeric fimbriae resulted in serum which specifically recognized cholera toxin B chain, confirming the utility of the employed strategy.