The dissociative-hypnotic
compound ketamine is being used in an
increasingly wide range of therapeutic contexts, including anesthesia,
adjunctive analgesia, treatment-resistant depression, but it also
continues to be a notable substance of abuse. No specific antidotes
exist for ketamine intoxication or overdose. Immunopharmacotherapy
has demonstrated the ability to offer overdose protection through
production of highly specific antibodies that prevent psychoactive
drug penetration across the blood–brain barrier, although antiketamine
antibodies have not yet been assessed or optimized for use in this
approach. Moreover, generation of specific antibodies also provides
an opportunity to address the role of 6-hydroxynorketamine metabolites
in ketamine’s rapid-acting antidepressant effect through selective
restriction of metabolite access to the central nervous system. Hapten
design is a critical element for tuning immune recognition of small
molecules, as it affects the presentation of the target antigen and
thus the quality and selectivity of the response. Here, we report
the synthesis and optimization of carrier protein and conjugation
conditions for an initial hapten, norketamine-N-COOH (NK-N-COOH),
to optimize vaccination conditions and assess the functional consequences
of such vaccination on ketamine-induced behavioral alterations occurring
at dissociative-like (50 mg/kg) doses. Iterating from this initial
approach, two additional haptens, ketamine-N-COOH (KET-N-COOH) and
6-hydroxynorketamine-N-COOH (HNK-N-COOH), were synthesized to target
either ketamine or 6-hydroxynorketamine with greater selectivity.
The ability of these haptens to generate antiketamine, antinorketamine,
and anti-6-hydroxynorketamine immune responses in mice was then assessed
using enzyme-linked immunosorbent assay (ELISA) and competitive surface
plasmon resonance (SPR) methods. All three haptens provoked immune
responses in vivo, although the KET-N-COOH and 6-HNK-N-COOH
haptens yielded antibodies with 5- to 10-fold improvements in affinity
for ketamine and/or 6-hydroxynorketamine, as compared to NK-N-COOH.
Regarding selectivity, vaccines bearing a KET-N-COOH hapten yielded
an antibody response with approximately equivalent K
d values against ketamine (86.4 ± 3.2 nM) and 6-hydroxynorketamine
(74.1 ± 7.8 nM) and a 90-fold weaker K
d against norketamine. Contrastingly, 6-HNK-N-COOH generated the highest
affinity and most selective antibody profile, with a 38.3 ± 4.7
nM IC50 against 6-hydroxynorketamine; K
d values for ketamine and norketamine were 33- to 105-fold
weaker, at 1290 ± 281.5 and 3971 ± 2175 nM, respectively.
Overall, these findings support the use of rational hapten design
to generate antibodies capable of distinguishing between structurally
related, yet mechanistically distinct, compounds arising from the
same precursor molecule. As applied to the production of the first-reported
anti-6-hydroxynorketamine antibodies to date, this approach demonstrates
a promising path forward for identifying the individual and combinatorial
roles...
