Effects on substrate profile by mutational substitutions at positions 164 and 179 of the class A TEM(pUC19) beta-lactamase from Escherichia coli.

We investigated the effects of mutations at positions 164 and 179 of the TEM(pUC19) beta-lactamase on turnover of substrates. The direct consequence of some mutations at these sites is that clinically important expanded-spectrum beta-lactams, such as third-generation cephalosporins, which are normally exceedingly poor substrates for class A beta-lactamases, bind the active site of these mutant enzymes more favorably. We employed site-saturation mutagenesis at both positions 164 and 179 to identify mutant variants of the parental enzyme that conferred resistance to expanded-spectrum beta-lactams by their enhanced ability to turn over these antibiotic substrates. Four of these mutant variants, Arg(164) --> Asn, Arg(164) --> Ser, Asp(179) --> Asn, and Asp(179) --> Gly, were purified and the details of their catalytic properties were examined in a series of biochemical and kinetic experiments. The effects on the kinetic parameters were such that either activity with the expanded-spectrum beta-lactams remained unchanged or, in some cases, the activity was enhanced. The affinity of the enzyme for these poorer substrates (as defined by the dissociation constant, K(s)) invariably increased. Computation of the microscopic rate constants (k(2) and k(3)) for turnover of these poorer substrates indicated either that the rate-limiting step in turnover was the deacylation step (governed by k(3)) or that neither the acylation nor deacylation became the sole rate-limiting step. In a few instances, the rate constants for both the acylation (k(2)) and deacylation (k(3)) of the extended-spectrum beta-lactamase were enhanced. These results were investigated further by molecular modeling experiments, using the crystal structure of the TEM(pUC19) beta-lactamase. Our results indicated that severe steric interactions between the large 7beta functionalities of the expanded-spectrum beta-lactams and the Omega-loop secondary structural element near the active site were at the root of the low affinity by the enzyme for these substrates. These conclusions were consistent with the proposal that the aforementioned mutations would enlarge the active site, and hence improve affinity.

Covalent modifications of aminophospholipids by 4-hydroxynonenal.

Lipid oxidation is implicated in a wide range of pathophysiological disorders, which leads to reactive compounds such as aldehydes. Among them 4-hydroxynonenal (4-HNE) reacts strongly with the NH2 groups of amino acids and forms mainly Michael adducts and minor Schiff-base adducts. Such reactions occur also with compounds containing thiol groups. No data are available describing 4-HNE interactions with amino-phospholipids. To investigate such a possibility, 4-HNE was incubated with either phosphatidylethanolamine (PE) or phosphatidylserine (PS) in an aqueous-organic biphasic system and the resulting products were identified by liquid chromatography-mass spectrometry (LC-MS). Our study points out the potential capacity of 4-HNE to react with phospholipids containing amino groups and particularly PE. The main resulting compounds found were a Michael adduct plus a minor Schiff base adduct, which was partly cyclized as a pyrrole derivative via a loss of water. Its stabilization as a pyrrole derivative allows to differentiate 4-HNE from the other aldehydes generated via lipid oxidation (e.g., malondialdehyde, 2-nonenal) that lack the 4-hydroxyl group. Their formation seems not to be affected when the pH varies from 6.5 to 8.5. Surprisingly, PS reacted poorly producing only a small amount of Michael adduct, the Schiff-base adduct being nondetectable. We conclude that such adducts, if they are formed in cell membranes, could alter the phospholipase-dependent cell signaling.