Altered methamphetamine place conditioning in mice vaccinated with a succinyl-methamphetamine-tetanus-toxoid vaccine.

BACKGROUND AND OBJECTIVES: We previously reported that an anti-methamphetamine (MA) vaccine attenuated drug-conditioned effects in mice, but it used a carrier protein and adjuvant not available for clinical use. Here we produced a vaccine with the same hapten (succinyl-methamphetamine, SMA) but attached to tetanus toxoid (SMA-TT) and adsorbed to aluminum hydroxide, components approved for use in humans. We then assessed the vaccine's ability to generate anti-MA antibodies, alter acquisition and reinstatement of MA place conditioning, and prevent MA brain penetration. METHODS: Mice were administered SMA-TT at weeks 0 and 3 and non-vaccinated mice received saline. Anti-MA antibody concentrations were determined at 8 and 12 weeks. Place conditioning began during week 9 in which vaccinated and non-vaccinated mice were divided into groups and conditioned with .5, or 2.0 mg/kg MA. Following acquisition training, mice were extinguished and then a reinstatement test was performed in which mice were administered their original training dose of MA. Separate groups of non-vaccinated and vaccinated mice were administered .5 and 2.0 mg/kg MA and brain MA levels determined. RESULTS AND CONCLUSIONS: Anti-MA antibody levels were elevated at week 8 and remained so through week 12. The SMA-TT vaccine attenuated acquisition and reinstatement of MA place conditioning. Significantly greater proportions of vaccinated mice during acquisition and reinstatement tests showed conditioned place aversion. Moreover, MA brain levels were decreased in vaccinated mice following administration of both doses of MA. SCIENTIFIC SIGNIFICANCE: Results support further development of anti-MA vaccines using components approved for use in humans.

Mutagenesis of zinc ligand residue Cys221 reveals plasticity in the IMP-1 metallo-ß-lactamase active site.

Metallo-ß-lactamases catalyze the hydrolysis of a broad range of ß-lactam antibiotics and are a concern for the spread of drug resistance. To analyze the determinants of enzyme structure and function, the sequence requirements for the subclass B1 IMP-1 ß-lactamase zinc binding residue Cys221 were tested by saturation mutagenesis and evaluated for protein expression, as well as hydrolysis of ß-lactam substrates. The results indicated that most substitutions at position 221 destabilized the enzyme. Only the enzymes containing C221D and C221G substitutions were expressed well in Escherichia coli and exhibited catalytic activity toward ß-lactam antibiotics. Despite the lack of a metal-chelating group at position 221, the C221G enzyme exhibited high levels of catalytic activity in the presence of exogenous zinc. Molecular modeling suggests the glycine substitution is unique among substitutions in that the complete removal of the cysteine side chain allows space for a water molecule to replace the thiol and coordinate zinc at the Zn2 zinc binding site to restore function. Multiple methods were used to estimate the C221G Zn2 binding constant to be 17 to 43 µM. Studies of enzyme function in vivo in E. coli grown on minimal medium showed that both IMP-1 and the C221G mutant exhibited compromised activity when zinc availability was low. Finally, substitutions at residue 121, which is the IMP-1 equivalent of the subclass B3 zinc-chelating position, failed to rescue C221G function, suggesting the coordination schemes of subclasses B1 and B3 are not interchangeable.

A morphine conjugate vaccine attenuates the behavioral effects of morphine in rats.

Vaccines for opioid dependence may provide a treatment that would reduce or slow the distribution of the drug to brain, thus reducing the drug's reinforcing effects. We tested whether a conjugate vaccine against morphine (keyhole limpet hemocyanin-6-succinylmorphine; KLH-6-SM) administered to rats would produce antibodies and show specificity for morphine or other heroin metabolites. The functional effects of the vaccine were tested with antinociceptive and conditioned place preference (CPP) tests. Rats were either vaccinated with KLH-6-SM and received two boosts 3 and 16 weeks later or served as controls and received KLH alone. Anti-morphine antibodies were produced in vaccinated rats; levels increased and were sustained at moderate levels through 24 weeks. Antibody binding was inhibited by free morphine and other heroin metabolites as demonstrated by competitive inhibition ELISA. Vaccinated rats showed reduced morphine CPP, tested during weeks 4 to 6, and decreased antinociceptive responses to morphine, tested at week 7. Brain morphine levels, assessed using gas-chromatography coupled to mass spectrometry (GC-MS) on samples obtained at 26 weeks, were significantly lower in vaccinated rats. This suggests that morphine entry into the brain was reduced or slowed. These results provide support for KLH-6-SM as a candidate vaccine for opioid dependence.