posted on 1996-11-08, 00:00authored byAnthony P. Guzikowski, Sui Xiong Cai, Stephen A. Espitia, Jon E. Hawkinson, James E. Huettner, Daniel F. Nogales, Minhtam Tran, Richard M. Woodward, Eckard Weber, John F. W. Keana
A series of aromatic and azepine ring-modified analogs of
3-hydroxy-1H-1-benzazepine-2,5-dione (HBAD) were synthesized and evaluated as antagonists at NMDA
receptor glycine sites.
Aromatic ring-modified HBADs were generally prepared via a Schmidt
reaction with substituted
2-methoxynaphthalene-1,4-diones followed by demethylation.
Electrophilic aromatic substitution of benzazepine 3-methyl ethers gave 7-substituted analogs. The
preparation of multiply
substituted 2-methoxynaphthalene-1,4-diones was effected via
Diels−Alder methodology
utilizing substituted butadienes with 2-methoxybenzoquinones followed
by aromatization.
Structural modifications, such as elimination of the aromatic
ring, removal of the 3-hydroxyl
group, and transfer of the hydroxyl group from C-3 to C-4, were also
studied. An initial
evaluation of NMDA antagonism was performed using a
[3H]MK801 binding assay. HBADs
demonstrating NMDA antagonist activity as indicated by inhibition of
[3H]MK801 binding were
further evaluated employing a [3H]-5,7-dichlorokynurenic
acid (DCKA) glycine site binding
assay. Selected HBADs were characterized for functional antagonism
of NMDA and AMPA
receptors using electrophysiological assays in Xenopus
oocytes and cultured rat cortical neurons.
Antagonist potency of HBADs showed good correlation between the
different assay systems.
HBADs substituted at the 8-position possessed the highest potency
with the 8-methyl (5),
8-chloro (6), and 8-bromo (7) analogs being the
most active. For HBAD 6, the IC50 in
[3H]DCKA binding assays was 0.013 μM and the Kb
values for antagonism of NMDA receptors in
oocytes (NR1a/2C) and cortical neurons were 0.026 and 0.048 μM,
respectively. HBADs also
antagonized AMPA-preferring non-NMDA receptors expressed in oocytes but
at a lower potency
than corresponding inhibition of NMDA receptors. HBADs
demonstrating a high potency for
NMDA glycine sites showed the highest steady-state selectivity index
relative to AMPA
receptors. Substitution at the 6-, 7-, and 9-positions generally
reduced or eliminated glycine
site affinity. Moving the hydroxyl group from C-3 to C-4 reduced
receptor affinity, and potency
was eliminated by the removal of the aromatic ring or the hydroxyl
group. These data indicate
that the HBAD series has specific structural requirements for high
receptor affinity. With
the exception of substitution at C-8, modified HBADs generally have a
lower affinity at NMDA
receptor glycine sites than the parent compound 3.
Mouse maximum electroshock-induced
seizure studies show that the three HBADs selected for testing have
in vivo potency with the
6,8-dimethyl analog (52) being the most potent
(ED50 = 3.9 mg/kg, iv).