Multinuclear NMR study of the structure of the Fv fragment of anti-dansyl mouse IgG2a antibody

A multinuclear NMR study is reported of Fv, which is a minimum antigen-binding unit of immunoglobulin. Fv has been prepared by clostripain digestion of a mouse anti-dansyl IgG2a monoclonal antibody that lacks the entire CH1 domain [Takahashi, H., Igarashi, T., Shimada, I., & Arata, Y. (1991) Biochemistry 30, 2840-2847]. A variety of Fv analogues labeled with 2H in the aromatic rings and with 13C and/or 15N in the peptide bonds have been prepared and used for multinuclear NMR analyses of Fv in the absence and presence of epsilon-dansyl-L-lysine (DNS-Lys). It has been shown that 1H-15N shift correlation spectra of Fv sensitively reflect the antigen binding and can be used along with 1H and 13C spectral data for the structural analyses of antigen-antibody interactions. Hydrogen-deuterium exchange of the amide protons has been followed in the absence and presence of DNS-Lys by using the 1H-15N shift correlation spectra. Use of the beta-shift observed for the carbonyl carbon resonances has also been helpful in following the hydrogen-deuterium exchange. On the basis of the NMR data obtained, the static and dynamic structure of the Fv fragment in the absence and presence of DNS-Lys has been discussed.     

Isotope-edited nuclear magnetic resonance study of Fv fragment of anti-dansyl mouse monoclonal antibody: recognition of the dansyl hapten.

An isotope-edited proton nuclear magnetic resonance study is reported of Fv, which is the smallest antigen recognition unit composed of VH and VL domains. Fv has been obtained by clostripain digestion of a short-chain anti-dansyl mouse IgG2a monoclonal antibody [Igarashi, T., Sato, M., Katsube, Y., Takio, K., Tanaka, T., Nakanishi, M., & Arata, Y. (1990) Biochemistry 29, 5727-5733]. A variety of stable-isotope-labeled anti-dansyl Fv analogues have been prepared. The aromatic proton resonances for all Tyr residues of the Fv fragment have been assigned in the absence and presence of epsilon-dansyl-L-lysine by means of isotope-edited homonuclear and heteronuclear two-dimensional NMR experiments. On the basis of the established assignments, it has been concluded that the dansyl ring is bound through Tyr-96H and Tyr-104H to both ends of H3, the third hypervariable region of the heavy chain. We also suggest that the antigen binding results in the formation of a hydrophobic core comprising the dansyl ring and the aromatic rings of Tyr-96H and Tyr-104H.     

Preparation of the Fv fragment from a short-chain mouse IgG2a anti-dansyl monoclonal antibody and use of selectively deuterated Fv analogues for two-dimensional 1H NMR analyses of the antigen-antibody interactions

The Fv fragment, a univalent antigen-binding unit with a molecular weight of 25,000, has successfully been prepared in high yield by limited proteolysis with clostripain of a short-chain mouse IgG2a anti-dansyl monoclonal antibody in which the entire CH1 domain is deleted [Igarashi, T., Sato, M., Takio, K., Tanaka, T., Nakanishi, M., & Arata, Y. (1990) Biochemistry 29, 5727-5733]. The Fv fragment obtained is stable at room temperature and retains its full antigen-binding capability. It has been shown that selective deuterium labeling of the Fv fragment, which is half the size of the Fab fragment, provides 1H NMR spectral data at a sufficient resolution for a detailed structural analysis of the antigen-combining site. NOESY spectra of an Fv analogue, in which all aromatic protons except for His C2'-H and Tyr C3',5'-H had been deuterated, were measured in the presence of varying amounts of dansyl-L-lysine. On the basis of the NOESY data obtained, it was possible to assign all the ring proton resonances for the dansyl group that is bound to the Fv fragment. It was also possible to obtain information about His and Tyr residues of the Fv fragment in the absence and presence of the antigen. On the basis of the NMR data obtained, we have shown that at least two Tyr residues along with one of the amide groups are directly involved in antigen binding. The mode of interaction of the dansyl ring with these residues in the Fv fragment has briefly been discussed.     

Expression,purification, and isotope labeling of the Fv of the human HIV-1 neutralizing antibody 447-52D for NMR studies

The Fv is the smallest antigen binding fragment of the antibody and is made of the variable domains of the light and heavy chains, V(L) and V(H), respectively. The 26-kDa Fv is amenable for structure determination in solution using multi-dimensional hetero-nuclear NMR spectroscopy. The human monoclonal antibody 447-52D neutralizes a broad spectrum of HIV-1 isolates. This anti-HIV-1 antibody elicited in an infected patient is directed against the third variable loop (V3) of the envelope glycoprotein (gp120) of the virus. The V3 loop is an immunodominant neutralizing epitope of HIV-1. To obtain the 447-52D Fv for NMR studies, an Escherichia coli bicistronic expression vector for the heterodimeric 447-52D Fv and vectors for single chain Fv and individually expressed V(H) and V(L) were constructed. A pelB signal peptide was linked to the antibody genes to enable secretion of the expressed polypeptides into the periplasm. For easy cloning of any antibody gene without potential modification of the antibody sequence, restriction sites were introduced in the pelB sequence and following the termination codon. A set of oligonucleotides that prime the leader peptide genes of all potential antibody human antibodies were designed as backward primers. The forward primers for the V(L) and V(H) were based on constant region sequences. The 447-52D Fv could not be expressed either by a bicistronic vector or as single chain Fv, probably due to its toxicity to Escherichia coli. High level of expression was obtained by individual expression of the V(H) and the V(L) chains, which were then purified and recombined to generate a soluble and active 447-52D Fv fragment. The V(L) of mAb 447-52D was uniformly labeled with 13C and 15N nuclei (U-13C/15N). Preliminary NMR spectra demonstrate that structure determination of the recombinant 447-52D Fv and its complex with V3 peptides is feasible.     

Use of 2D NMR, protein engineering, and molecular modeling to study the hapten-binding site of an antibody Fv fragment against 2-phenyloxazolone

Two-dimensional (2D) 1H NMR spectroscopy was used to study the hapten-binding site of a recombinant antibody Fv fragment expressed in Escherichia coli. Point mutations of residues in the CDR loops of the Fv fragment were designed in order to investigate their influence on hapten binding and to make site-specific assignments of aromatic NMR proton signals. Two tyrosines giving NOEs to the ligand 2-phenyloxazolone were identified, residue 33 in CDR1 of the heavy chain and residue 32 in CDR1 of the light chain. The benzyl portion of 2-phenyloxazolone is located between these two residues. The binding site is close to the surface of the Fv fragment. Comparison with a different anti-2-phenyloxazolone antibody, the crystal structure of which has recently been solved, shows that the general location of the hapten-binding site in both antibodies is similar. However, in the crystallographically solved antibody, the hapten is bound farther from the surface in a pocket created by a short CDR3 loop of the heavy chain. In the binding site identified in the Fv fragment studied in this report, this space is probably filled by the extra seven residues of the CDR3.     

Changes in structure and dynamics of the Fv fragment of a catalytic antibody upon binding of inhibitor

Binding of the product inhibitor p-nitrophenol to the monoclonal esterolytic antibody NPN43C9 has been investigated by performing NMR spectroscopy of the heterodimeric variable-domain fragment (Fv) of the antibody in the presence and absence of inhibitor. Structural information from changes in chemical shift upon binding has been related to the changes in local dynamics in the active site of the catalytic antibody using NMR relaxation measurements. Significant changes in the chemical shifts of the backbone resonances upon binding extend beyond the immediate vicinity of the antigen binding site into the interface between the two associated polypeptides that form the Fv heterodimer, a possible indication that the binding of ligand causes a change in the relative orientations of the component light (V(L)) and heavy (V(H)) chain polypeptides. Significant differences in backbone dynamics were observed between the free Fv and the complex with p-nitrophenol. A number of resonances, including almost all of the third hypervariable loop of the light chain (L3), were greatly broadened in the free form of the protein. Other residues in the antigen-binding site showed less broadening of resonances, but still required exchange terms (R(ex)) in the model-free dynamics analysis, consistent with motion on a slow timescale in the active site region of the free Fv. Binding of p-nitrophenol caused these resonances to sharpen, but some R(ex) terms are still required in the analysis of the backbone dynamics. We conclude that the slow timescale motions in the antigen-binding site are very different in the bound and free forms of the Fv, presumably due to the damping of large-amplitude motions by the bound inhibitor.     

Domain interactions in antibody Fv and scFv fragments: effects on unfolding kinetics and equilibria

The equilibrium denaturation and unfolding kinetics of the domains V(L) and V(H) have been compared with those of the Fv and single-chain Fv (scFv) fragment of an engineered variant of the antibody McPC603 in the presence and absence of the antigen phosphorylcholine. The scFv fragment is significantly more stable than the isolated constituting domains. Antigen binding stabilizes the heterodimeric assembly even further. Domain dissociation and domain unfolding are coupled processes, giving rise to a highly cooperative unfolding transition. For the Fv fragment, cooperative unfolding is only observed in the presence of antigen. At low protein concentrations and in the absence of antigen, the Fv fragment is significantly destabilized, leading to quantitative domain dissociation before significant domain unfolding takes place. The kinetic unfolding of V(H), V(L) and the scFv fragment is monophasic. Unfolding of the scFv fragment is much slower, when extrapolated to zero denaturant, than either of the isolated domains, suggesting that the higher thermodynamic stability of the scFv fragment is at least partially due to a high-energy transition state for unfolding. These studies emphasize the enormous importance of mutual domain stabilization in engineering stable antibodies.     

Conformational dynamics of complementarity-determining region H3 of an anti-dansyl Fv fragment in the presence of its hapten

Antigen-induced structural changes in the Fv fragment of an anti-dansyl immunoglobulin G were studied by X-ray crystallography and stopped-flow fluorescence measurement. The crystal structure of the Fv fragment complexed with dansyl-lysine was determined at a resolution of 1.85 A. The dansyl-lysine molecule bound to a narrow cavity formed by the complementarity-determining regions H3 and H1, the N-terminal region of the VH domain and L2 of the VL domain. The structure of the binding site in the crystal structure explained well the results of the previous nuclear magnetic resonance measurements. The hapten binding caused remarkable conformational changes in H3 and its environmental structures, including the hydration structure from those observed in the unliganded state. The tip of H3 moved about 12 A from its position in the unliganded state. In addition, because of the contacts of H3 with the VL domain at the domain interface, the conformational changes of H3 resulted in the relative rotation of the variable domains by 5 degrees from their association observed in the unliganded state. The hydrophobic interactions at the domain interface seemed to be particularly important for the mutual rotation of the domains. The stopped-flow fluorescence measurement monitoring the interaction of the dansyl group and the binding pocket revealed that H3 was in a conformational equilibrium of three consecutive conformational states in the presence of dansyl-lysine in solution; an unliganded state preventing the access of the hapten, another unliganded state able to bind the hapten and the complex. The conformational dynamics of H3 in recognizing and binding the hapten molecule are discussed on the basis of the structural information from the present and previous studies.     

Helix-stabilized Fv (hsFv) antibody fragments: substituting the constant domains of a Fab fragment for a heterodimeric coiled-coil domain.

Antibody Fv fragments would in principle be useful for a variety of biotechnological applications because of their small size and the possibility to produce them in relatively large amounts in recombinant form; however, their limited stability is a drawback. To solve this problem, both domains are usually fused via a peptide linker to form a single-chain Fv (scFv) fragment, but in some cases this leads to a dimerization. We present an alternative format for stabilizing antibody Fv fragments. The C(H)1 and C(L) domain of the Fab fragment were replaced with a heterodimeric coiled coil (WinZip-A2B1), which had previously been selected using a protein-fragment complementation assay in Escherichia coli. This new antibody format was termed helix-stabilized Fv fragment (hsFv), and was compared to the corresponding Fv, Fab and single-chain Fv format. Bacterial growth and expression of the hsFv was significantly improved compared to the Fab fragment. The hsFv fragment formed a heterodimer of heavy and light chain with the expected molecular mass, also under conditions where the scFv fragment was predominantly dimeric. The hsFv fragment was significantly more stable than the Fv fragment, and nearly as stable as the scFv fragment under the conditions used (80 nM protein concentration). Thus, the format of a helix-stabilized Fv (hsFv) fragment can be a useful alternative to existing recombinant antibody formats, especially in cases where poor expression of Fab fragments or multimerization of scFv fragments is a problem.     

The pH-dependent structural variation of complementarity-determining region H3 in the crystal structures of the Fv fragment from an anti-dansyl monoclonal antibody.

The Fv fragment from an anti-dansyl antibody was optimally crystallized into two crystal forms having slightly different lattice dimensions at pH 5.25 and 6.75. The two crystal structures were determined and refined at high resolution at 112 K (at 1.45 A for the crystal at pH 5.25 and at 1.55 A for that at pH 6.75). In the two crystal structures, marked differences were identified in the first half of CDRH3 s having an amino acid sequence of Ile95H-Tyr96H-Tyr97H-His98H-Tyr99H-Pro1 00H-Trp100aH-Phe100bH-Ala101H- Tyr102H. NMR pH titration experiments revealed the p Kavalues of four histidine residues (His27dL, His93L, His55H and His98H) exposed to solvent. Only His98H (p Ka=6.3) completely changed its protonation state between the two crystallization conditions. In addition, the environmental structures including hydration water molecules around the four histidine residues were carefully compared. While the hydration structures around His27dL, His93L and His55H were almost invariant between the two crystal structures, those around His98Hs showed great difference in spite of the small conformational difference of His98H between the two crystal structures. These spectroscopic and crystallographic findings suggested that the change in the protonation state in His98H was responsible for the structural differences between pH 5.25 and 6.75. In addition, the most plausible binding site of the dansyl group was mapped into the present structural models with our previous NMR experimental results. The complementarity-determining regions H1, H3 and the N-terminal region in the VH domain formed the site. The side-chain of Tyr96H occupied the site and interacted with Phe27H of H1, giving a clue for the binding mode of the dansyl group in the site.     

Backbone assignment,secondary structure and Protein A binding of an isolated,human antibody VH domain

Summary Antibody heavy chain variable domains (VH) lacking their light chain domain (VL) partner are prime candidates for the design of minimum-size immunoreagents. To obtain structural information about isolated VH domains, a human VH was labelled with ¹⁵N or doubly labelled with both ¹⁵N and ¹³C and was studied by heteronuclear nuclear magnetic resonance spectroscopy. Most (90%) of the ¹H and ¹⁵N main-chain signals were assigned through two-dimensional TOCSY and NOESY experiments on the unlabelled VH and three-dimensional heteronuclear multiple quantum correlation TOCSY and NOESY experiments on the ¹⁵N-labelled VH. Four short stretches of the polypeptide chain could only be assigned on the basis of three-dimensional HNCA and HN(CO)CA experiments on the ¹³C-/¹⁵N-labelled protein. Long-range interstrand backbone NOEs suggest the presence of two adjacent -sheets formed by altogether nine antiparallel -strands. ³J_H ^NHC coupling constants and the location of slowly exchanging backbone amides support this interpretation. The secondary structure of the isolated VH is identical to that of heavy chain variable domains in intact antibodies, where VH domains are packed against a VL domain. The backbone assignments of the VH made it possible to locate its Protein A binding site. Chemical shift movements after complexing with the IgG binding fragment of Protein A indicate binding through one of the two -sheets of the VH. This -sheet is solvent exposed in intact antibodies. The Protein A binding site obviously differs from that on the Fc portion of immunoglobulins and is unique to members of the human VH_III gene subgroup.Abbreviations CDR complementarity determining region - CHAPS [(cholamidopropyl)-dimethylammonio]-1-propanesulfonate - DQF-COSY double-quantum-filtered correlated spectroscopy - Fab antigen binding antibody fragment - Fc crystallisable antibody fragment - Fv heterodimer of VH and VL - H1 (2, 3) hypervariable loop 1 (2, 3) - IgG immunoglobulin G - NOE nuclear Overhauser effect - NOESY nuclear Overhauser enhancement spectroscopy - HMQC heteronuclear multiple quantum correlation spectroscopy - HSQC heteronuclear single quantum correlation spectroscopy - scFv single chain Fv - TOCSY total correlation spectroscopy - TPPI time-proportional phase incrementation - VH antibody heavy chain variable region - VL antibody light chain variable region. Mutants are denoted by the wild-type amino acid (one-letter code), follwed by the residue number and the new amino acid     

Characterization of an antibody Fv fragment that binds to the human, but not to the rat neurotensin receptor NTS-1

The cDNAs coding for the heavy and light chain variable domains of an antibody, recognizing the human G-protein-coupled receptor for neurotensin, NTS-1, were obtained from a hybridoma cell line, B-N6. The Fv B-N6 fragment was expressed in Escherichia coli and purified. To characterize the properties of the antibody fragment, human and rat high-affinity neurotensin receptors were expressed in E. coli in functional form, linked at their N-termini to the maltose-binding protein. Fv B-N6 was found to compete for [3H]neurotensin binding to the human neurotensin receptor, but not to the rat neurotensin receptor, with IC50 values of 1.6 microM (membrane-bound receptor) and 1.9 microM (detergent-solubilized, purified receptor). The formation of a relatively stable complex of Fv B-N6 with purified human neurotensin receptor fusion protein was also demonstrated by gel filtration experiments. The Fv B-N6 fragment will be used to isolate a high-affinity binder to the human neurotensin receptor as a valuable tool for cocrystallization and receptor structure determination.     

Functional Fv fragment of an antibody specific for CD28: Fv-mediated co-stimulation of T cells

The most predominant co-stimulation pathway, which is critical for T cell activation and proliferation, is the CD28-B7 pathway. The anti-CD28 monoclonal antibody (mAb) also provides a co-stimulatory signal to T cells. In order to construct a functional Fv fragment (complex of VH and VL domains) of anti-CD28 antibody using a bacterial expression system, cDNA encoding the variable regions of immunoglobulin from 15E8 hybridoma cells was cloned and expressed in Escherichia coli. The Fv fragment was obtained as a soluble protein from the periplasmic fraction and showed a binding pattern similar to parental IgG. The Fv fragment induced proliferation of peripheral blood mononuclear cells in the presence of anti-CD3 or anti-CD2 mAb and enhanced anti-tumor activity of anti-MUC1x(anti)-CD3 bispecific antibody when tested with lymphokine-activated killer cells with T cell phenotype. Thus, the anti-CD28 Fv fragment will be promising not only for the study of co-stimulation, but also for cancer immunotherapy.     

Structure-based affinity maturation of a chimeric anti-ricin antibody C4C13

Ricin is a highly lethal toxin. Anti-ricin chimeric monoclonal antibody (mAb) C4C13 was prepared in our lab; however, its binding affinity was much weaker than that of the parent antibody 4C13. In this study, based on the computer-guided homology modeling and conformational optimization methods, the 3-D structure of C4C13 variable regions Fv was constructed and optimized. Using molecular docking and dynamics simulation methods, the 3-D complex structure of ricin and C4C13 Fv was obtained. Considering the orientation property, surface electrostatic distribution, residues chemical andphysical character and intermolecular hydrogen bond, the binding mode and key residues were predicted. According to C4C13 Fv fragment and ricin complementary binding surface, electrostatic attraction periphery and van der Waals interaction interface, three mutants (i.e., M1 (N^H102F, W^H103Y); M2 (W^H103Y) and M3 (R^L90G)) were designed, in which M1 and M2 were predicted to possess higher antigen-binding activity than C4C13, while M3 was weaker. The relative affinity assays by ELISA showed that M1 and M2 mutations had higher affinity (9.6 and 18.3?nmol/L) than C4C13 (130?nmol/L) and M3 had weaker affinity (234.5?nmol/L) than C4C13. The results showed that the modeling complex structure of the antigen (ricin) and antibody (C4C13) is reasonable. Our work offered affinity maturated antibodies by site mutations, which were beneficial for valuable anti-ricin antibody design and preparation in future.     

The binding of 2,4,6-trinitrophenyl derivatives to the mouse myeloma immunoglobulin A protein MOPC 315

The binding of Tnp (2,4,6-trinitrophenyl) derivatives to the Fv fragment (variable region of heavy and light chains) of the mouse myeloma IgA protein MOPC 315 was investigated by 270MHz proton nuclear magnetic resonance. Two of the haptens, Tnp-glycine and Tnp-l-aspartate, are in fast exchange with the Fv fragment, and the changes in chemical shifts for both protein and hapten resonances were determined by titrations. For the tightly binding hapten epsilon-N-Tnp-alpha-N-acetyl-l-lysine, which is in slow exchange with the Fv fragment, the changes in chemical shifts for the hapten H(3)+H(5) resonances were determined by cross-saturation. By using these data and the known structure of the combining site of protein MOPC 315 [Dwek, Wain-Hobson, Dower, Gettins, Sutton, Perkins & Givol (1977), Nature (London) 266, 31-37] the mode of binding of Tnp derivatives is deduced by ring-current calculations. The trinitrophenyl ring stacks with tryptophan-93(L) (light chain) in the ;aromatic box' formed by tryptophan-93(L), tyrosine-34(L) and phenyl-alanine-34(H) (heavy chain). Further evidence for the stacking interaction with a tryptophan residue is provided by the similarity of the optical-difference spectra observed with Tnp-aminomethylphosphonate in the presence of either the Fab fragment (light chain and N-terminal half of heavy chain) of protein MOPC 315 or tryptophan. These data show that the modes of binding of all the Tnp derivatives are very similar, despite a 100-fold range in their affinities. It is also concluded that the modes of binding of Dnp (2,4-dinitrophenyl) and Tnp derivatives to protein MOPC 315 are very similar, and that the structural basis for this is that the aromatic box is large enought to allow the trinitrophenyl ring to stack with tryptophan-93(L) while still forming hydrogen bonds to asparagine-36(L) and tyrosine-34(L).     

Construction and high-level expression of a single-chain Fv antibody fragment specific for acidic isoferritin in Escherichia coli

A functional single-chain Fv antibody fragment (scFv) specific for acidic isoferritin (AIF) was produced at high level in Escherichia coli. The variable regions of heavy chain (V(H)) and light chain (V(L)) from the hybridoma 4c9 were connected with a flexible linker using an assembly polymerase chain reaction. The construct of V(H)-linker-V(L) was inserted into a phagemid pCANTAB 5 E followed by selection with the Recombinant Phage Antibody System (RPAS). Anti-AIF scFv gene from the recombinant phagemid pCAN4c9 was subcloned into pET28a fused to N-terminal His-tag sequence in frame and overexpressed in E. coli BL21(DE3). With an on-column refolding procedure based on Ni-chelating chromatography, the active anti-AIF scFv was recovered efficiently from inclusion bodies with a refolding yield of approximate 75% confirmed by spectrophotometer. The activity of refolded scFv was determined through sodium dodecyl sulfate-polyacrylamide gel electrophoresis, Western blotting and enzyme-linked immunosorbent assay. The results showed anti-AIF scFv retains the specific binding activity to AIF with an affinity constant of 7.29 x 10(-8) mol l(-1). The overall yield of anti-AIF scFv with bioactivity in E. coli flask culture was more than 60 mg l(-1).     

Crystal structure of a phage library-derived single-chain Fv fragment complexed with turkey egg-white lysozyme at 2.0 A resolution

The three-dimensional structure of the single-chain Fv fragment 1F9 in complex with turkey egg-white lysozyme (TEL) has been determined to a nominal resolution of 2.0 A by X-ray diffraction. The scFv fragment 1F9 was derived from phage-display libraries in two steps and binds both hen and turkey egg-white lysozyme, although the level of binding affinity is two orders of magnitude greater for the turkey lysozyme. The comparison of the crystal structure with a model of the single-chain Fv fragment 1F9 in complex with hen egg-white lysozyme (HEL) reveals that in the latter a clash between Asp101 in lysozyme and Trp98 of the complementarity determining region H3 of the heavy chain variable domain occurs. This is the only explanation apparent from the crystal structure for the better binding of TEL compared to HEL.The binding site topology on the paratope is not simply a planar surface as is usually found in antibody-protein interfaces, but includes a cleft between the light chain variable domain and heavy chain variable domain large enough to accommodate a loop from the lysozyme. The scFv fragment 1F9 recognizes an epitope on TEL that differs from the three antigenic determinants recognized in other known crystal structures of monoclonal antibodies in complex with lysozyme.     

Characterization of the binding interface between the E-domain of Staphylococcal protein A and an antibody Fv-fragment

Staphylococcal protein A (SpA) is a cell-surface component of Staphylococcus aureus. In addition to the well-characterized interaction between SpA and the Fc-region of human IgG, an alternative binding interaction between SpA and the Fab-region of immunoglobulin domains encoded by the V(H)3 gene family has been described. To characterize structurally the interface formed by SpA repeats and type-3 V(H)-domains, we have studied the 32-kDa complex formed between an E-domain mutant (EZ4) and the Fv-fragment of the humanized anti-HER2 antibody (Hu4D5-8) using heteronuclear NMR spectroscopy. Protocols were established for efficient incorporation of (15)N, (13)C, and (2)H into EZ4 and the V(H)- and V(L)-domains of the Fv, allowing backbone resonances to be assigned sequentially for EZ4 and the V(H)-domain in both free and complexed states. Broadening of certain V(H)-resonances in the free and bound Fv-fragment suggests microsecond to millisecond time-scale motion in CDR3. Residues experiencing significant chemical shift changes of backbone (1)H(N), (15)N, and (13)CO resonances upon complex formation delineate contiguous surfaces on EZ4 and the V(H)-domain that define the binding interfaces of the two proteins. The interaction surfaces identified by chemical shift mapping are comprised of predominantly hydrophilic residues. This is in contrast to the SpA-Fc interface which is predominantly hydrophobic in nature. Further analysis of the surface properties suggests a probable binding orientation for SpA- and V(H)3-domains.     

Conformational multiplicity of the antibody combining site of a monoclonal antibody specific for a (6-4) photoproduct.

The antigen binding site of monoclonal antibody 64M5, which possesses a high degree of affinity for DNA containing pyrimidine (6-4) pyrimidone photoproducts, were investigated by use of stable-isotope-assisted NMR spectroscopy. A variety of 64M5 Fab fragments specifically labeled with 13C and 15N at backbone amide groups were prepared. Extensive assignments of amide resonances originating from the variable region of 64M5 were made by using 2D-HN(CO) measurements along with recombination of the heavy and light chains of 64M5. On the basis of chemical shift changes of the amide resonances caused upon addition of d(T[6-4]T) and d(GTAT[6-4]TATG), the binding sites of 64M5 Fab for the (6-4) photodimer and for the oligodeoxynucleotides flanking it were identified. It was revealed that the L1 and L3 segments, which are responsible for the binding to (6-4) photodimer, exhibit conformational multiplicities in the absence of antigens, and take different conformations between the d(T[6-4]T) and d(GTAT[6-4]TATG)-bound forms. On the basis of spectral comparison with another Fab fragment with a similarity in the amino acid sequence of the VL domain of 64M5, we suggest that the conformational multiplicities observed in the present study is caused by a substitution of an amino acid residue at the position of a key residue in L3 canonical structure, which leads to a preferable effect on the antigen binding, and by a specific combination of L1 and L3 canonical structures.     

Single chain Fab (scFab) fragment

Background  

The connection of the variable part of the heavy chain (VH) and and the variable part of the light chain (VL) by a peptide linker to form a consecutive polypeptide chain (single chain antibody, scFv) was a breakthrough for the functional production of antibody fragments in Escherichia coli. Being double the size of fragment variable (Fv) fragments and requiring assembly of two independent polypeptide chains, functional Fab fragments are usually produced with significantly lower yields in E. coli. An antibody design combining stability and assay compatibility of the fragment antigen binding (Fab) with high level bacterial expression of single chain Fv fragments would be desirable. The desired antibody fragment should be both suitable for expression as soluble antibody in E. coli and antibody phage display.