- Email: [email protected]
Structure-activity relationships involving the catechol subunit of rolipram
Liioorganic & kfedicinal Chemistly Letters, Vol. 4, NO. 15. pp. 1855-1860, 1994 Copyright0 1994 E1swie.r Science L.td Printed in Great Britain. All rights ~su~ed~ G940-894X/94 $7.00+0.00
0960-894X(94)00247-9
Structure-Activity
Relationships Involving the Catechol Subunit of Rolipram
Jeffrey A. Stafford,**= Paul L. Feldman,= Brian E. Marron,= Frank J. Schoenen,a Nicole L. Valvano,a Rayomand J. UnwaBa,b Paul L. Domanico,e E. Sloan Brawley , CMichael A. Leesnitzer,e Dudley A. Rose,e and Robert W. Doughertyd Glaxo Research Institute 5 Moore Drive Research Triangle Park, NC 27709 a Department of Medicinal Chemistry b Department of Molecular Sciences c Department of Biochemistry d Department of Cellular Biochemistry
Abstract: Structure-activity rolipram (l), arediscussed. Rolipram CAMP-specific for chronic
involving the aromatic ring of the selective PDE IV inhibitor,
(1) is a selective inhibitor of
[(R, S)-4-(3-cyclopentoxy-4-methoxyphenyl)-2-pyrrolidinone] phosphodiesterase
inflammatory
diseases
medicinal
chemistry
synthesis
of PDE IV inhibitors
pyrrolidinone
relationships
type IV (PDE IV).l Due to the wide interest in developing through
selective
effort aimed at improving
ring.2 Less attention,
Letter we report structure-activity
derived
inhibition
however,
agents
of PDE IV, there has been a considerable
the potency of rolipram. A number of groups have reported the
from rolipram,
relationships
therapeutic
in which
the modifications
has been directed to modifications of rolipram derivatives
were
made to the
of the catechol ring.3 In this
in which the aromatic ring has been
modified.
Rolipram (1)
2 (n=l) 3 (n=2)
4
The exact nature in which rolipram binds to PDE IV is unclear due to a lack of structural data on the enzyme. Our primary goal therefore was to prepare derivatives
of the catechol that would help us ascertain the
nature in which the catechol ethers interact with the enzyme. The methylenedioxyderivatives,
24 and 3,s respectively,
were prepared and found to be considerably
IV than rolipram itself (see Table). A similar loss in potency was observed acetal4.6 1855
and ethylenedioxyphenyl
less potent inhibitors
of PDE
with the derived cyclohexylidene
1856
J. A. STAFFORDef al.
We reasoned that the loss in activity observed with compounds 2-4 perhaps stemmed from an improper orientation of the electron lone pairs associated with the oxygen atoms of the catechol. If one or both of these oxygens are involved in hydrogen bonding to an amino acid residue on the enzyme surface, clearly then the spatial geometry of these electron lone pairs is critical.7 The cyclic framework holding the catechol subunit of 2-4 forces the general dipoles created by the lone pairs to be directed away from each other (Figure la). However, it is possible that the optimum binding mode for rolipram and related derivatives is such that these dipoles are generally oriented in the same direction (Fig lb). Indeed, the minimum energy conformation of rolipram (Fig lc) has the two alkyl groups of the catechol ethers oriented similarly to the depiction in Figure
Figure lb
Figure la
Figure lc
In order to test this hypothesis we required aromatic derivatives of rolipram wherein the oxygen lone pairs are constrained to meet the geometric arrangement shown in Figure lb. If, in fact, the orientation in Fig. lb is required one might expect that compounds possessing this arrangement would exhibit equal or improved potency versus rolipram for inhibiting PDE IV. By simply anchoring the methoxy group at the 4-position to the ring we designed the benzofuran 5, dihydrobenzofuran 6, and dihydrobenxopyran 7, Each of these compounds meets the generalized criterion set forth by Fig. lb. At the outset of this work, however, we were not certain of the enzyme’s tolerance for the added substituent on the aromatic group in 5-7. Additionally,
the effect of
lowering the basicity of one of the catechol oxygens when going to a benzofuran (i.e., sp3-hybridization in 1; sp2-hybridization in 5) was unknown.
5
6 (n=l) I (n=2)
The synthesis of benzofuran 5 is shown in Scheme 1. Knoevenagel condensation between 3-furaldehyde (8) and diethyl malonate provided the unsaturated diester 9. DIBAL reduction of 9 (toluene, -78 “C), followed by acetylation of the derived diol afforded 10. Direct formation of the benzofuran ring from 10 was then accomplished
using a palladium-catalyzed
cyclocarbonylation
reaction recently reported by Hidai and
The catechot subunit of rolipram
1857
coworkers.g Thus, treatment of 10 with Pd(PPh3)2ClZ (5 mol %) and triethylamine
in toluene under an
atmosphere of CO (IOOQpsi, 175 “C, 11 hr) provided, after silica gel chromatography, benzofuran IX in 45% yield. Saponification
of the acetate esters (LiUH, H2Um)
selectively ~y~lo~nty~at~
(~y~lu~ntyl
bromide, K$O3,
provided an intermediate
DMF) KUgive the ben~fu~~
dial, which was alcohol 12 in 74%
yield from fl. Oxidation of the benzylie alcohol with MnU2 then delivered aldehyde 13 in 39% yield. With W in hand we followed a previously established three-step sequence to append the pyrrolidinone ring.sa Thus, Homer-Emmons homologation of 13 provided an unsaturated ester, which upon treatment with CH3N@ and tetramethylguanidine (TlMG), afforded an internxxliate nitroester resulting from conjugate addition of CH3NO2. Catalytic reduction of the nitro group afforded an intermediate amino ester, which undergoes spontaneous cyclization to provide the rolipram derivative 5 in an overall yield of 53% from 13.10
Scheme 1
EtO&XH $02Et piperidine, PhCHs
1. Dll3At 2. AC20 -
t , (MeO)~POCH&O&le MnO2 CHC13
LiHMDS, THF 2. CH3N02, TMG, $5 “C 3. Ha, Raney-Ni, CHsUH
cc%I’
The syntheses of mlipram derivatives 6 and 7 began from dihydrobenzofuran 14 and dihydrobenzopyran 15, respectively, and is shuwn beIow in Scheme 2.11 Thus, O-alkylation (cyclopentyl bromide, QCO3, DMF) provided the aldehydes 16 and 17, which were then converted to 6 and 7 by the same three-step sequence described above in the synthesis uf $12
1858
J. A. STAFFORD et al.
Scheme
2
CHO 14 (ml) 15 (n=2)
Test compounds
7 (n=2)
were measured
both for their ability to inhibit the catalytic activity of PDE IV (Ki)‘3 binding site (Q). t4,15 The data are shown in the Table.
and for their ability to bind to the rolipram high-affinity As mentioned Consistent
above, compounds with
our
dihydrobenzopyran
2-4 were considerably activity
hypothesis,
derivative
is restored
less potent inhibitors in the
of PDE IV than (+)-rolipram.
dihydrobenzofuran
derivative
6 and
7, which are similar in their ability to inhibit PDE IV, Ki = 3.69 and 1.17 pM,
respectively. Perhaps most noteworthy
is the benzofuran
analog 5, whose PDE IV inhibitory
activity (Ki = 0.26 pM)
is nearly equal to rolipram. It appears that lowering the basicity of the ether oxygen does not necessarily deleterious
effect on enzyme inhibition.
reasonable
to suggest that the in-plane sp2-hybridized
accept a hydrogen
Within the framework
bond than its counterpart,
6.l6 This being the case, the enhanced due to the greater flexibility
of our hydrogen-bonding
lone pair of the benzofuran
out-of-plane
sp3-hybridized
activity of the dihydrobenzopyran
of a six-membered
hypothesis,
have a
it is then
oxygen is better oriented to
lone pair in the dihydrobenzofuran 7, relative to 6, is easily understood
ring versus a five-membered
ring. This added flexibility
in 7
allows the oxygen to position itself more. favorably for hydrogen bonding. Finally, the rolipram binding data for this set of compounds
parallel the enzyme inhibition
approximately
lower than its Ki, compounds
lo-fold
data. Indeed, like rolipram itself, which has a Q that is 5 and 7 display significantly
greater binding affinity than
PDE IV inhibition. Table PDE IV Inhibition (K;. UM)
(f)-Rolipram
Rolipram Binding (Kd. p.h4)
0.19
0.01
2
> loo
> loo
3
> loo
> loo
4
63.9
16.5
5
0.26
0.03
6
3.69
4.00
7
1.17
0.21
1859
The catcchol subunit of rohpram
In summary, we have presented the PDE IV inhibitory activity of a number of rolipram derivatives, which were designed to explore the nature in which the catechol ether moiety interacts with the enzyme. Our goal was to understand the optimum spatial arrangement of the catechol ethers, not simply to assess the steric tolerance at each oxygen. We have provided evidence that the spatial ~angem~nt
of the oxygen lone pairs of
the catechol ethers am critically important with respect to the PDE IV inhibitory properties of rolipram and its derivatives. The ability to design potent inhibitors of PDE IV, which are based on rolipram, should be facilitated by the present study. Acknowledgement The authors thank the ICOS Corporation (Bothell, WA) for supplying the PDE IV that was used in the enzyme experiments. References and Notes 1. Schwabe, U.; Miyake, M.; Ohga, Y.; Daly, 3. Mol. Patrol.
1976,900.
2. (a) Koc, B. K.; Lebel, L. A.; Nielsen, J. A.; Russo, L. L.; Saccamano, N. A.; Vinick, F. J.; Williams, I. H. Drug Dev. Res. 1990,21,
135. (b) Pinto, I. L.; Buckle, D. R.; Readshaw, S. A.; Smith, D. G. Bioorg. Med.
Chem. Lett. 1993,3, 1743. (c) Backstrom, R.; Honkanen, E.; Raasmaja, A.; Linden, I.-B. Int. Pat. Appl. (PCT)
WG 91/16303 (26 Apr 1991). (d) Bagli, J. F.; Lomb&o,
L. J.; Skotnicki, J. S. gut. Par. Appl. 0 511 865 Al (30
Apr 1992). (e) Bender, P. E.; Christensen, S. B. Znt. Pat. Appl. (PCT) WO 93/07141(2 Ott 1992). 3. (a) Marivet, M. C.; Bourguignon, J. J.; Lugnier, C.; Mann, A.; Stoclet, J.-C.; Wermuth, C.-G. J. Med. Chem. 1989,32,1450.
(b) Huth, A.; Beetz, I.; Schumann, I. Tefra~dr~~ 1989,45,6679.
4. This com~und
was prepared adding from piperonal using an es~b~sh~ synthetic route.3aTh~ data for 2 are as follows: m.p. 153-55 OC. 1H NMR (CDCl3,300 MHz): 6 2.44 (dd, 1, J = 8.8, 16.8). 2.70 (dd, 1, J = 8.8, 16.8), 3.36 (dd, 1, J = 2.0,7.3), 3.62 (m. l), 3.72 (m, 1). 5.94 (d, 2,J = 2.7), 6.41 (bs, I), 6.75 (m, 3). Anal calcd
for CtlHllN03:
C, 64.38; H, 5.40, N, 6.83. Found: C, 64.23; H, 5.39; N, 6.74.
5. This compound was prepared beginning from 1,4-benzodioxan-6-carboxaldehyde using an established synthetic route.3a The data for 3 are as follows: m.p. 98-99 OC. 1H NMR (CDCl3, 300 MHz): 6 2.43 (dd, 1, J = 9.0, 16.8). 2.67 (dd, 1, J = 8.8, 16.8), 3.35 (dd, 1, J= 7.8,9.3), 3.58 (m, l), 3.72 (dd, 1, J = 8.3,9.3), 4.24 (s, 4), 6.71 (m, 2), 6.75 (d, 1, J = l-7), 6.82 (d, 1, J = 8.3). Anal calcd for CrzHl3N03: C, 65.74; H, 5.98; N, 6.39. Found: C!,65.75; H, 6.02; N, 6.40. 6. 4: m.p. 164-65 “C. ‘II NMR (CDCl3, 300 MHz): 8 1.49-1.85 (m, IO), 2.43 (dd, 1, J = 8.9, 17.1), 2.67 (dd, 1, J = 8.9, 16.9), 3.35 (t, 1, J = 8.4). 3.59 (m, 1), 3.72 (t, 1, J = 8.4). 6.65 (m, 3), 6.47 (bs, 1). Anal calcd for C&llgNO3:
C, 70.31; H, 7.01; N, 5.12. Found: C, 70.28; H, 7.06; N, 5.07.
7. We have examined the effect of removing either the methoxy or the cyclopentoxy group, respectively, These two rolipram analogs inhibit PDE IV with a Kt = 26 @I and >lOO PM, respectively, demonstrating the requirement that both ether groups be present for significant PDE IV inhibition. 8. This minimum-energy
rolipram conformation was calculated by semi-empirical (PM3) calculations within
SPARTAN ~avefunction
Inc) and is in good agreement with the recently pubfished crystal structure of (+)-l-
(4-bromobenzyl)-4-(3-(cyclopentoxy)-4-~~ox~henyl)p~oli~n-2-one:
Baures, P. W.; Eggleston, D. S.;
Erhard, K. F.; Cieslinski, L. B.; Torphy, T. J.; Christensen, S. B. J. Med. Cfzem. 1993,36,3274.
J. A. STAPFORD et al.
1860
9. Iwasaki, M.; Kobayashi,
K.; Li, J.-P.; Matsuzaka, H.; Ishii, Y.; Hidai, M. J. Org. Chem. 19% 5X1922.
10.5: mp. 169-70 ‘C. 1H NMR (CDCl3,300
MHz): 6 1.64-1.97 (m, 8), 2.54 (dd, 1, J = 8.5, 16.9), 2.78 (dd, 1,
J= 8.7, 17.0), 3.45 (m, 1), 3.73-3.84 (m, 2), 5.02 (m, l), 5.95 (bs, 1), 6.67 (s, l), 6.71 (d, 1, J= 2.2), 7.05 (d, 1, J = 1.2), 7.61 (d, 1, J = 2.0). Anal calcd for C17H19N03: C, 71.56; H, 6.71; N, 4.91. Found: C, 71.43; H, 6.73; N, 4.93. Stafford, J. A.; Valvano, N. L. J. Org. Chem., in PUSS.
11. The syntheses of 14 and 15 are reported elsewhere:
12. 6: m.p. 121-23 OC. 1H NMR (CDC13, 300 MHz): 6 1.54-1.92 (m, 8), 2.45 (dd, 1, J = 8.9, 16.8), 2.70 (dd, 1, J= 8.5, 16.8),3.20(t,2,J=8.8),
3.37 (dd, l,J=7.1,8.8),
3.62(m,
l), 5.75 (bs, I), 6.60 (s, I), 6.72 (s, 1). Anal calcd for Cl7H2lN03:
1),3.75 (m, 1),4.61 (t. 2,J=8.8),4.84(m, C, 71.06; H, 7.37; N, 4.87. Found: C, 71.14;
H, 7.35; N, 4.84. 7: m.p. 142-45 “C. 1H NMR (CDC13, 300 MHz): 6 1.53-2.03 (m, lo), 2.46 (dd, 1, J = 9.0, 17.1), 2.69 (dd, 1, J = 8.7, 16.8), 2.74 (m, 2), 3.37 (dd, 1, J = 7.3,9.0),
3.58 (m, I), 3.74 (m, l), 4.23 (m, 2), 4.73
(m, 1), 5.59 (bs, l), 6.53 (s, l), 6.58 (s, 1). Anal calcd for C17H2lN03*0.13
H20: C, 71.18; H, 7.72; N, 4.61.
Found: C, 71.16; H, 7.67; N, 4.35. 13. The Ki for a test compound compound
is dissolved
is evaluated against recombinant
human PDE IV enzyme as follows: The test
and serially diluted in 100% DMSO, and then diluted
stepwise
with Hz0 to 10%
DMSO. A 100 ltL reaction is prepared by mixing 10 p.L of a buffer solution, which contains 20 mM TRIS, 10 mM MgC12, 2 mM EDTA, 2 mM DlT, 0.5% n-octyl glycoside, 5 mg/mL metal-free BSA , pHf = 7.5; 10 @L of the test compound
(10-e to lo-1uM final, 1% final DMSO); 10 ltL of the substrate solution containing
CAMP (300 nC final) and 5.3 l..tM 14C-adenosine
addition of 20 ltL of an enzyme solution containing diluted appropriately reaction
is stopped
batchwise
into reaction
50 l@nL
of 5’-nucleotidase
buffer to give 50% turnover of substrate
by the addition
1 PM 3H-
(3 nC final), and 50 l.tL H20. The reaction is initiated by the and hrPDE IV that has been
in 20 min at 23 ‘C. The PDE
of pH 10.0 buffer. The cyclic nucleotide
and the nucleoside
are then
separated by QAE Sephadex A25 anion exchange resin. The filtrate (100 FL) is mixed with 150 l.tL
of scintillation
cocktail and counted in dual channel mode. The Ki is determined
data to the following equation: I = [(Ymax * [II)& three independent
by fitting the dose-response
+ [I])] + Yniin. Values in the Table represent the mean from
determinations.
14. Torphy, T. J.; Stadel, J. M.; Burman, M.; Cieslinski, L. B.; McLaughlin,
M. M.; White, J. R.; Livi, G. P. J.
Biol. Chem. 1992,267,1798. 15. The ability of test compounds
to compete with [3H]rolipram for binding to recombinant
assessed as follows: hrPDE IV is incubated with [3H]rolipram (IO-9 M final concentration) (1O-11 through 10e4 M) in a total volume of 1.0 mL containing mixing
to adsorb
the ligand/receptor
quantified
concentration/response 16. Computer systems
respectively,
liquid
complex.
The mixture
scintillation
is filtered
counting.
ICsn
is ad&d to 2.5% were
within SPARTAN
(Wavefunction
to mimic 5 and 7, 7-methoxybenzofuran
confirmed
(Received in USA 6 June 1994; accepted 22 June 1994)
determined
and the from
correction.
Inc) at a basis set level (6-31G*) performed (5’) and 7-methoxy-2,3-dihydrobenzofuran
that the dipole vectors are oriented differently.
y=O.O, z=O.43 @t=1.06 D); For 7’ the vector coordinates
with
(W/V)
onto glass fiber filters values
curves (n=2) and converted to Ki values using the Cheng-Prusoff
calculations
modelled
by
and test compounds
(mM): NaCl (lOO), Tris-HCI (25), MgCl2 (lo),
CaCl2 (11, and BSA (0.25%, w/v) pH 7.4. After 60 min on ice, hydroxyapatite radioactivity
human PDE IV was
For 5’ the vector coordinates
are x=0.14, y=-0.79, z~l.18 (~~1.49 D).
on (7’),
are x=0.93,
0960-894X(94)00247-9
Structure-Activity
Relationships Involving the Catechol Subunit of Rolipram
Jeffrey A. Stafford,**= Paul L. Feldman,= Brian E. Marron,= Frank J. Schoenen,a Nicole L. Valvano,a Rayomand J. UnwaBa,b Paul L. Domanico,e E. Sloan Brawley , CMichael A. Leesnitzer,e Dudley A. Rose,e and Robert W. Doughertyd Glaxo Research Institute 5 Moore Drive Research Triangle Park, NC 27709 a Department of Medicinal Chemistry b Department of Molecular Sciences c Department of Biochemistry d Department of Cellular Biochemistry
Abstract: Structure-activity rolipram (l), arediscussed. Rolipram CAMP-specific for chronic
involving the aromatic ring of the selective PDE IV inhibitor,
(1) is a selective inhibitor of
[(R, S)-4-(3-cyclopentoxy-4-methoxyphenyl)-2-pyrrolidinone] phosphodiesterase
inflammatory
diseases
medicinal
chemistry
synthesis
of PDE IV inhibitors
pyrrolidinone
relationships
type IV (PDE IV).l Due to the wide interest in developing through
selective
effort aimed at improving
ring.2 Less attention,
Letter we report structure-activity
derived
inhibition
however,
agents
of PDE IV, there has been a considerable
the potency of rolipram. A number of groups have reported the
from rolipram,
relationships
therapeutic
in which
the modifications
has been directed to modifications of rolipram derivatives
were
made to the
of the catechol ring.3 In this
in which the aromatic ring has been
modified.
Rolipram (1)
2 (n=l) 3 (n=2)
4
The exact nature in which rolipram binds to PDE IV is unclear due to a lack of structural data on the enzyme. Our primary goal therefore was to prepare derivatives
of the catechol that would help us ascertain the
nature in which the catechol ethers interact with the enzyme. The methylenedioxyderivatives,
24 and 3,s respectively,
were prepared and found to be considerably
IV than rolipram itself (see Table). A similar loss in potency was observed acetal4.6 1855
and ethylenedioxyphenyl
less potent inhibitors
of PDE
with the derived cyclohexylidene
1856
J. A. STAFFORDef al.
We reasoned that the loss in activity observed with compounds 2-4 perhaps stemmed from an improper orientation of the electron lone pairs associated with the oxygen atoms of the catechol. If one or both of these oxygens are involved in hydrogen bonding to an amino acid residue on the enzyme surface, clearly then the spatial geometry of these electron lone pairs is critical.7 The cyclic framework holding the catechol subunit of 2-4 forces the general dipoles created by the lone pairs to be directed away from each other (Figure la). However, it is possible that the optimum binding mode for rolipram and related derivatives is such that these dipoles are generally oriented in the same direction (Fig lb). Indeed, the minimum energy conformation of rolipram (Fig lc) has the two alkyl groups of the catechol ethers oriented similarly to the depiction in Figure
Figure lb
Figure la
Figure lc
In order to test this hypothesis we required aromatic derivatives of rolipram wherein the oxygen lone pairs are constrained to meet the geometric arrangement shown in Figure lb. If, in fact, the orientation in Fig. lb is required one might expect that compounds possessing this arrangement would exhibit equal or improved potency versus rolipram for inhibiting PDE IV. By simply anchoring the methoxy group at the 4-position to the ring we designed the benzofuran 5, dihydrobenzofuran 6, and dihydrobenxopyran 7, Each of these compounds meets the generalized criterion set forth by Fig. lb. At the outset of this work, however, we were not certain of the enzyme’s tolerance for the added substituent on the aromatic group in 5-7. Additionally,
the effect of
lowering the basicity of one of the catechol oxygens when going to a benzofuran (i.e., sp3-hybridization in 1; sp2-hybridization in 5) was unknown.
5
6 (n=l) I (n=2)
The synthesis of benzofuran 5 is shown in Scheme 1. Knoevenagel condensation between 3-furaldehyde (8) and diethyl malonate provided the unsaturated diester 9. DIBAL reduction of 9 (toluene, -78 “C), followed by acetylation of the derived diol afforded 10. Direct formation of the benzofuran ring from 10 was then accomplished
using a palladium-catalyzed
cyclocarbonylation
reaction recently reported by Hidai and
The catechot subunit of rolipram
1857
coworkers.g Thus, treatment of 10 with Pd(PPh3)2ClZ (5 mol %) and triethylamine
in toluene under an
atmosphere of CO (IOOQpsi, 175 “C, 11 hr) provided, after silica gel chromatography, benzofuran IX in 45% yield. Saponification
of the acetate esters (LiUH, H2Um)
selectively ~y~lo~nty~at~
(~y~lu~ntyl
bromide, K$O3,
provided an intermediate
DMF) KUgive the ben~fu~~
dial, which was alcohol 12 in 74%
yield from fl. Oxidation of the benzylie alcohol with MnU2 then delivered aldehyde 13 in 39% yield. With W in hand we followed a previously established three-step sequence to append the pyrrolidinone ring.sa Thus, Homer-Emmons homologation of 13 provided an unsaturated ester, which upon treatment with CH3N@ and tetramethylguanidine (TlMG), afforded an internxxliate nitroester resulting from conjugate addition of CH3NO2. Catalytic reduction of the nitro group afforded an intermediate amino ester, which undergoes spontaneous cyclization to provide the rolipram derivative 5 in an overall yield of 53% from 13.10
Scheme 1
EtO&XH $02Et piperidine, PhCHs
1. Dll3At 2. AC20 -
t , (MeO)~POCH&O&le MnO2 CHC13
LiHMDS, THF 2. CH3N02, TMG, $5 “C 3. Ha, Raney-Ni, CHsUH
cc%I’
The syntheses of mlipram derivatives 6 and 7 began from dihydrobenzofuran 14 and dihydrobenzopyran 15, respectively, and is shuwn beIow in Scheme 2.11 Thus, O-alkylation (cyclopentyl bromide, QCO3, DMF) provided the aldehydes 16 and 17, which were then converted to 6 and 7 by the same three-step sequence described above in the synthesis uf $12
1858
J. A. STAFFORD et al.
Scheme
2
CHO 14 (ml) 15 (n=2)
Test compounds
7 (n=2)
were measured
both for their ability to inhibit the catalytic activity of PDE IV (Ki)‘3 binding site (Q). t4,15 The data are shown in the Table.
and for their ability to bind to the rolipram high-affinity As mentioned Consistent
above, compounds with
our
dihydrobenzopyran
2-4 were considerably activity
hypothesis,
derivative
is restored
less potent inhibitors in the
of PDE IV than (+)-rolipram.
dihydrobenzofuran
derivative
6 and
7, which are similar in their ability to inhibit PDE IV, Ki = 3.69 and 1.17 pM,
respectively. Perhaps most noteworthy
is the benzofuran
analog 5, whose PDE IV inhibitory
activity (Ki = 0.26 pM)
is nearly equal to rolipram. It appears that lowering the basicity of the ether oxygen does not necessarily deleterious
effect on enzyme inhibition.
reasonable
to suggest that the in-plane sp2-hybridized
accept a hydrogen
Within the framework
bond than its counterpart,
6.l6 This being the case, the enhanced due to the greater flexibility
of our hydrogen-bonding
lone pair of the benzofuran
out-of-plane
sp3-hybridized
activity of the dihydrobenzopyran
of a six-membered
hypothesis,
have a
it is then
oxygen is better oriented to
lone pair in the dihydrobenzofuran 7, relative to 6, is easily understood
ring versus a five-membered
ring. This added flexibility
in 7
allows the oxygen to position itself more. favorably for hydrogen bonding. Finally, the rolipram binding data for this set of compounds
parallel the enzyme inhibition
approximately
lower than its Ki, compounds
lo-fold
data. Indeed, like rolipram itself, which has a Q that is 5 and 7 display significantly
greater binding affinity than
PDE IV inhibition. Table PDE IV Inhibition (K;. UM)
(f)-Rolipram
Rolipram Binding (Kd. p.h4)
0.19
0.01
2
> loo
> loo
3
> loo
> loo
4
63.9
16.5
5
0.26
0.03
6
3.69
4.00
7
1.17
0.21
1859
The catcchol subunit of rohpram
In summary, we have presented the PDE IV inhibitory activity of a number of rolipram derivatives, which were designed to explore the nature in which the catechol ether moiety interacts with the enzyme. Our goal was to understand the optimum spatial arrangement of the catechol ethers, not simply to assess the steric tolerance at each oxygen. We have provided evidence that the spatial ~angem~nt
of the oxygen lone pairs of
the catechol ethers am critically important with respect to the PDE IV inhibitory properties of rolipram and its derivatives. The ability to design potent inhibitors of PDE IV, which are based on rolipram, should be facilitated by the present study. Acknowledgement The authors thank the ICOS Corporation (Bothell, WA) for supplying the PDE IV that was used in the enzyme experiments. References and Notes 1. Schwabe, U.; Miyake, M.; Ohga, Y.; Daly, 3. Mol. Patrol.
1976,900.
2. (a) Koc, B. K.; Lebel, L. A.; Nielsen, J. A.; Russo, L. L.; Saccamano, N. A.; Vinick, F. J.; Williams, I. H. Drug Dev. Res. 1990,21,
135. (b) Pinto, I. L.; Buckle, D. R.; Readshaw, S. A.; Smith, D. G. Bioorg. Med.
Chem. Lett. 1993,3, 1743. (c) Backstrom, R.; Honkanen, E.; Raasmaja, A.; Linden, I.-B. Int. Pat. Appl. (PCT)
WG 91/16303 (26 Apr 1991). (d) Bagli, J. F.; Lomb&o,
L. J.; Skotnicki, J. S. gut. Par. Appl. 0 511 865 Al (30
Apr 1992). (e) Bender, P. E.; Christensen, S. B. Znt. Pat. Appl. (PCT) WO 93/07141(2 Ott 1992). 3. (a) Marivet, M. C.; Bourguignon, J. J.; Lugnier, C.; Mann, A.; Stoclet, J.-C.; Wermuth, C.-G. J. Med. Chem. 1989,32,1450.
(b) Huth, A.; Beetz, I.; Schumann, I. Tefra~dr~~ 1989,45,6679.
4. This com~und
was prepared adding from piperonal using an es~b~sh~ synthetic route.3aTh~ data for 2 are as follows: m.p. 153-55 OC. 1H NMR (CDCl3,300 MHz): 6 2.44 (dd, 1, J = 8.8, 16.8). 2.70 (dd, 1, J = 8.8, 16.8), 3.36 (dd, 1, J = 2.0,7.3), 3.62 (m. l), 3.72 (m, 1). 5.94 (d, 2,J = 2.7), 6.41 (bs, I), 6.75 (m, 3). Anal calcd
for CtlHllN03:
C, 64.38; H, 5.40, N, 6.83. Found: C, 64.23; H, 5.39; N, 6.74.
5. This compound was prepared beginning from 1,4-benzodioxan-6-carboxaldehyde using an established synthetic route.3a The data for 3 are as follows: m.p. 98-99 OC. 1H NMR (CDCl3, 300 MHz): 6 2.43 (dd, 1, J = 9.0, 16.8). 2.67 (dd, 1, J = 8.8, 16.8), 3.35 (dd, 1, J= 7.8,9.3), 3.58 (m, l), 3.72 (dd, 1, J = 8.3,9.3), 4.24 (s, 4), 6.71 (m, 2), 6.75 (d, 1, J = l-7), 6.82 (d, 1, J = 8.3). Anal calcd for CrzHl3N03: C, 65.74; H, 5.98; N, 6.39. Found: C!,65.75; H, 6.02; N, 6.40. 6. 4: m.p. 164-65 “C. ‘II NMR (CDCl3, 300 MHz): 8 1.49-1.85 (m, IO), 2.43 (dd, 1, J = 8.9, 17.1), 2.67 (dd, 1, J = 8.9, 16.9), 3.35 (t, 1, J = 8.4). 3.59 (m, 1), 3.72 (t, 1, J = 8.4). 6.65 (m, 3), 6.47 (bs, 1). Anal calcd for C&llgNO3:
C, 70.31; H, 7.01; N, 5.12. Found: C, 70.28; H, 7.06; N, 5.07.
7. We have examined the effect of removing either the methoxy or the cyclopentoxy group, respectively, These two rolipram analogs inhibit PDE IV with a Kt = 26 @I and >lOO PM, respectively, demonstrating the requirement that both ether groups be present for significant PDE IV inhibition. 8. This minimum-energy
rolipram conformation was calculated by semi-empirical (PM3) calculations within
SPARTAN ~avefunction
Inc) and is in good agreement with the recently pubfished crystal structure of (+)-l-
(4-bromobenzyl)-4-(3-(cyclopentoxy)-4-~~ox~henyl)p~oli~n-2-one:
Baures, P. W.; Eggleston, D. S.;
Erhard, K. F.; Cieslinski, L. B.; Torphy, T. J.; Christensen, S. B. J. Med. Cfzem. 1993,36,3274.
J. A. STAPFORD et al.
1860
9. Iwasaki, M.; Kobayashi,
K.; Li, J.-P.; Matsuzaka, H.; Ishii, Y.; Hidai, M. J. Org. Chem. 19% 5X1922.
10.5: mp. 169-70 ‘C. 1H NMR (CDCl3,300
MHz): 6 1.64-1.97 (m, 8), 2.54 (dd, 1, J = 8.5, 16.9), 2.78 (dd, 1,
J= 8.7, 17.0), 3.45 (m, 1), 3.73-3.84 (m, 2), 5.02 (m, l), 5.95 (bs, 1), 6.67 (s, l), 6.71 (d, 1, J= 2.2), 7.05 (d, 1, J = 1.2), 7.61 (d, 1, J = 2.0). Anal calcd for C17H19N03: C, 71.56; H, 6.71; N, 4.91. Found: C, 71.43; H, 6.73; N, 4.93. Stafford, J. A.; Valvano, N. L. J. Org. Chem., in PUSS.
11. The syntheses of 14 and 15 are reported elsewhere:
12. 6: m.p. 121-23 OC. 1H NMR (CDC13, 300 MHz): 6 1.54-1.92 (m, 8), 2.45 (dd, 1, J = 8.9, 16.8), 2.70 (dd, 1, J= 8.5, 16.8),3.20(t,2,J=8.8),
3.37 (dd, l,J=7.1,8.8),
3.62(m,
l), 5.75 (bs, I), 6.60 (s, I), 6.72 (s, 1). Anal calcd for Cl7H2lN03:
1),3.75 (m, 1),4.61 (t. 2,J=8.8),4.84(m, C, 71.06; H, 7.37; N, 4.87. Found: C, 71.14;
H, 7.35; N, 4.84. 7: m.p. 142-45 “C. 1H NMR (CDC13, 300 MHz): 6 1.53-2.03 (m, lo), 2.46 (dd, 1, J = 9.0, 17.1), 2.69 (dd, 1, J = 8.7, 16.8), 2.74 (m, 2), 3.37 (dd, 1, J = 7.3,9.0),
3.58 (m, I), 3.74 (m, l), 4.23 (m, 2), 4.73
(m, 1), 5.59 (bs, l), 6.53 (s, l), 6.58 (s, 1). Anal calcd for C17H2lN03*0.13
H20: C, 71.18; H, 7.72; N, 4.61.
Found: C, 71.16; H, 7.67; N, 4.35. 13. The Ki for a test compound compound
is dissolved
is evaluated against recombinant
human PDE IV enzyme as follows: The test
and serially diluted in 100% DMSO, and then diluted
stepwise
with Hz0 to 10%
DMSO. A 100 ltL reaction is prepared by mixing 10 p.L of a buffer solution, which contains 20 mM TRIS, 10 mM MgC12, 2 mM EDTA, 2 mM DlT, 0.5% n-octyl glycoside, 5 mg/mL metal-free BSA , pHf = 7.5; 10 @L of the test compound
(10-e to lo-1uM final, 1% final DMSO); 10 ltL of the substrate solution containing
CAMP (300 nC final) and 5.3 l..tM 14C-adenosine
addition of 20 ltL of an enzyme solution containing diluted appropriately reaction
is stopped
batchwise
into reaction
50 l@nL
of 5’-nucleotidase
buffer to give 50% turnover of substrate
by the addition
1 PM 3H-
(3 nC final), and 50 l.tL H20. The reaction is initiated by the and hrPDE IV that has been
in 20 min at 23 ‘C. The PDE
of pH 10.0 buffer. The cyclic nucleotide
and the nucleoside
are then
separated by QAE Sephadex A25 anion exchange resin. The filtrate (100 FL) is mixed with 150 l.tL
of scintillation
cocktail and counted in dual channel mode. The Ki is determined
data to the following equation: I = [(Ymax * [II)& three independent
by fitting the dose-response
+ [I])] + Yniin. Values in the Table represent the mean from
determinations.
14. Torphy, T. J.; Stadel, J. M.; Burman, M.; Cieslinski, L. B.; McLaughlin,
M. M.; White, J. R.; Livi, G. P. J.
Biol. Chem. 1992,267,1798. 15. The ability of test compounds
to compete with [3H]rolipram for binding to recombinant
assessed as follows: hrPDE IV is incubated with [3H]rolipram (IO-9 M final concentration) (1O-11 through 10e4 M) in a total volume of 1.0 mL containing mixing
to adsorb
the ligand/receptor
quantified
concentration/response 16. Computer systems
respectively,
liquid
complex.
The mixture
scintillation
is filtered
counting.
ICsn
is ad&d to 2.5% were
within SPARTAN
(Wavefunction
to mimic 5 and 7, 7-methoxybenzofuran
confirmed
(Received in USA 6 June 1994; accepted 22 June 1994)
determined
and the from
correction.
Inc) at a basis set level (6-31G*) performed (5’) and 7-methoxy-2,3-dihydrobenzofuran
that the dipole vectors are oriented differently.
y=O.O, z=O.43 @t=1.06 D); For 7’ the vector coordinates
with
(W/V)
onto glass fiber filters values
curves (n=2) and converted to Ki values using the Cheng-Prusoff
calculations
modelled
by
and test compounds
(mM): NaCl (lOO), Tris-HCI (25), MgCl2 (lo),
CaCl2 (11, and BSA (0.25%, w/v) pH 7.4. After 60 min on ice, hydroxyapatite radioactivity
human PDE IV was
For 5’ the vector coordinates
are x=0.14, y=-0.79, z~l.18 (~~1.49 D).
on (7’),
are x=0.93,