Conformational changes affect binding and catalysis by ester-hydrolysing antibodies.

D2.3, D2.4 and D2.5 are ester-hydrolysing antibodies raised against a phosphonate transition state analogue (TSA). All three antibody-TSA binding kinetics, as monitored by fluorescence quenching, indicate an "induced-fit" mechanism: fast bimolecular association followed by a unimolecular isomerisation (k=1-7 s-1). Isomerisation leads to a 30-170-fold increase in affinity towards the TSA and, consequently, to higher catalytic rates. Antibody D2.3 exhibits a complex three-step binding mechanism, in which the last step is a "very slow" isomerisation (k<0.02 s-1). This very slow isomerisation is limiting the rate of catalysis by D2.3, as indicated by the kinetics of product release which show characteristics of enzyme "conformational memory" or "hysteresis". The results support a mechanism consisting of pre-equilibrium between "nether-active" (low affinity) and "active" (high affinity) antibody conformers (prior to ligand addition) as well as induced-fit, i.e. isomerisation of the nether-active ligand-antibody complex to give the active complex. Crystal structures of these antibodies, free and complexed, have previously indicated that their conformation does not change upon binding. Here, we show that the buffer used to crystallise the antibodies, and in particular its polyethylene glycol component, alters the pre-equilibrium in favour of the active conformer, leading to its crystallisation both in the presence and in the absence of the TSA.

Expression and characterization of recombinant single-chain Fv and Fv fragments derived from a set of catalytic antibodies.

The generation of catalytic antibodies should enable the catalysis of reactions for which no enzymatic or chemical catalyst is currently available. In previous studies, we established a series of catalytic antibodies capable of hydrolysing p-nitrobenzyl (pNB) and p-nitrophenyl (pNP) esters. A group of these catalytic antibodies exhibited high reactivity and substrate specificity, yet each individual antibody demonstrated different kinetic parameters. In order to study the molecular basis for these differences, we have cloned, sequenced and expressed the variable regions of this group of antibodies as functional scFv and Fv in bacteria. The variable region of the heavy chain is derived from a novel germline gene of the J558 family whereas the light chain comes from a germline gene previously found in our catalytic antibodies catalysing the hydrolysis of only nitrophenyl esters, demonstrating that the heavy chain determines the specificity for the nitrobenzyl esters. Several different expression systems were examined for their ability to produce catalytically active antibodies. When expressed as an scFv, both refolded and secreted scFvs exhibited catalytic activity although yields of expressed protein were low. The secreted scFvs had higher specific activity. On the other hand, Fv fragments were expressed in sufficient quantities to allow kinetic analysis. Levels of expression were dependent on the sequence of VL used. Using this expression system, the relative contributions of the individual light and heavy chains to catalysis and binding could be evaluated. Both original VH and VL regions are required for hapten binding, although the VH is more crucial for catalysis. By replacing the CDR3 of the heavy chain with a random sequence, it was shown to be essential for both binding and catalysis. This expression system together with site-directed mutagenesis should enable a more detailed study of the catalytic mechanism of this set of antibodies.

Efficient and selective p-nitrophenyl-ester-hydrolyzing antibodies elicited by a p-nitrobenzyl phosphonate hapten.

A number of monoclonal antibodies elicited against a nitrobenzyl (Nbzl)-phosphonate transition-state analogue (TSA), and which were selected for the hydrolysis of the corresponding Nbzl-ester, were also found to catalyze the hydrolysis of the analogous p-nitrophenyl(Np) ester with notable efficiency and specificity. The activity towards the Np-ester is higher in terms of rates (k(cat); as expected from the higher intrinsic reactivity of Np-esters); however, the rate acceleration (k(cat)/k(uncat)) is close to or lower than that observed with the Nbzl-ester. Unexpectedly, the affinity to the Np-ester substrate (1/K(M)) and therefore k(cat)/K(M) are significantly higher. The best example is antibody D2.4 having a k(cat)/K(M) value of 64 s(-1) x M(-1) with the Nbzl-ester and 9400 s(-1) x M(-1) with the Np-ester. Moreover, due to a lower product inhibition by p-nitrophenol relative to p-nitrobenzyl alcohol, these antibodies exhibit more than 1000 turnovers with the Np-ester. The differential affinity of these antibodies to the Nbzl-phosphonate TSA versus the Nbzl-ester substrate (K(S)/K(TSA) or K(M)/K(i)) correlates well with the observed rate enhancement (k(cat)/k(uncat)). For the Np-ester, however, stabilisation of the transition state (as reflected by K(S)/K(TSA) and by the catalytic proficiencies, k(cat)/K(M)/k(uncat)) does not fully account for the catalytic power (k(cat)/k(uncat)), indicating a more complex catalytic mechanism than simply transition-state stabilization. A comparison of the kinetic parameters of D2.4 with other Np-ester-hydrolyzing antibodies raised against Np-phosphonate haptens emphasizes the marked advantage of this antibody which was elicited against an Nbzl-phosphonate hapten. These results appear to be general: anti-(Nbzl-phosphonate TSA) antibodies obtained from other mouse strains and using different immunization protocols are also efficient Np-esterases. They demonstrate the use of an expanded TSA-hapten, where a spacer (a methylene group) mimics bonds that are partially cleaved in the transition state of the catalyzed reaction.