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Dipeptide glycols: A new class of renin inhibitors
Vol.
132,
October
No.
1, 1985
15,
BIOCHEMICAL
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS Pages
1985
DIPEPTIDE
GLYCOLS:
155-l
61
A NEW CLASS OF RENIN INHIBITORS
Gunnar J. Hanson: John S. Baran, Thomas Lindberg, Gerald M. Walsh, S.E. Papaioannou, Maribeth Babler, Stephen E. Bittner, Po-Chang Yang and Mary Dal Corobbo G.D. Searle and Co. Parkway, Skokie, Ill.
4901 Searle
60077
Received August 26, 1985 SUMMARY: The discovery of a new class of novel renin inhibitors consisting of protected dipeptide amides derived from aminoglycols (Formula I) prompted a study of structure-activity in vitro and efficacy in vivo. Thus, Boc-&-Phe-N-[(lS,2R)-1-benzyl-(2,3-dihydroxy)propyl]-L-leucinamide (1) and the corresponding histidinamide (2) inhibit human renin in vitro (IC50: 8.7 x 10-6 M and 2.6 x lo-6 Ij, respectively). Compound 1 has a slight inhibitory effect on pepsin and compound 2 does not inhibit pepsin at all (at lo-4q; these compounds are inactive against rat renin. Compound 1 is efficacious in lowering plasma renin activity in the Rhesus monkey (i.v.). Results indicate that this new class of low molecular weight inhibitors is specific for human renin and thus constitutes a new source of drug candidates. 0 1985 Academic Press, Inc.
The search 3.4.99.19)
for
greatly
in
clinical
remains
(EC 3.4.15.1)
catalyzes
N-terminus
inhibitors
(1),
but
are
should
the
hydrolytic
Design candidates
potentially
clinical
of trial,
whom correspondence
the
inhibition
release
of
angiotensin
this
process
is
substance
high
I from
the
rate-limiting II.
Renin
of plasma
pressure.
In seeking
we focused
enzyme
successful.
modulators
Inhibitors.
should
the
and
as an alter-
angiotensin
blood
such
commercial
be equally
important
(EC
interest,
I converting
renin
in principle
and pathologically
for to
in
of pressor
and Selection
tremendous
of angiotensin
interest
that
thus
despite
of human renin has intensified
Nevertheless,
inhibitors
fueled
inhibitor
of hypertension
elusive.
formation
activity
* author
active
of angiotensinogen;
in the
renin
of
has
approach
Renin
treatment years
success
native
an orally
the
recent
an inhibitor
step
for
on compounds
new chemical that
be addressed 0006-291X/85 $1.50
155
Copyright 0 1985 by Academic Press, Inc. All rights of reproduction in any form reserved.
Vol.
132,
No.
1, 1985
satisfied
BIOCHEMICAL
the
exhibit
a high
degree
that
an oral
insuring pepsin,
following
(~600)
2) the to
of
dose
3) it
should
peptide
the
to or greater
lower
plasma
should
we wish
satisfy
the
amides
derived
that
be of
must
of other
low molecular
weight
a primate
a new class
one func-
potency
should
5) the
substance
model.
In this
renin
inhibitors
of
N-terminal
aminoglycols
at most
electrophilic
in vitro
(Formula
acid
absorption;
possessing
of reactive
requirements:
from
inhibition
of pepstatin; in
to report
substance
of gastrointestinal
4) the
activity
above
of
COMMUNICATIONS
--for renin vs pepsin, bound to gastric
become
stable,
be free
than
renin
not
likelihood
as aldehyde;
equal
specificity
probability
and should
such
nication
the
be metabolically
bond
tionality
will
RESEARCH
1) the
in vitro
inhibitor
increase
BIOPHYSICAL
requirements:
and to decrease
proteases;
AND
protected
be must
Commuthat
dipeptide
I).
METHODS AND MATERIALS: In vitro inhibition assays for human renin, rat renin, and porcine pepsin were performed using known methods (2,3,4) as A monkey model for assaying the effect of modified recently (5). test compound on plasma renin activity (PRA) was developed: Rhesus monkeys (6/group) weighing 6.3-9.9 kg were treated with Lasix (furosemide) at 2 mg/kg, both in the a.m. and p.m. on Day 1. intravenousOn Day 2, test compound at 10 mg/kg was administered Plasma samples (K-EDTA) were taken at intervals as indicated ly. in Table 2; PRA was then determined by a known method (6). Details of the dipeptide glycol synthesis will be published elsewhere. Compounds 1 through 9 were prepared by amidation of a protected dipeptide or amino acid with an appropriate aminoglycol (see Table 1 and Figure 1 for structures). All amino acids are of the & configuration.
RESULTS: Table
1 summarizes
dipeptide
glycols
inhibitors
have
the
in vitro
and related the
general
inhibition
data
for
the
The new glycol
compounds. formula:
N-protected-Dipeptide-NHCH(CHZPh)&i([CHz],-0H)OH To demonstrate i.v.
to Rhesus
pepstatin
treated
in vivo
monkeys.
efficacy,
Table
and compound
compound
2 shows the 1 groups. 156
(1) 1 was administered
PRA for For both
both groups,
the PRA is
Vol.
132,
No.
BIOCHEMICAL
1, 1985
Table
AND
BIOPHYSICAL
In Vitro
1.
COMMUNICATIONS
Inhibitiona
Human Renin no.
RESEARCH
Pepsin
Rat Renin
structure
%
IC50
%
IC50
1
Boc-Phe-Leu-V
87
8.7
67
50
0
2
Boc-Phe-His-V
90
2.6
4
>lOOO
0
84
15.4
63
0
59
0
3
Boc-Nal(l)-Leu-V
%
4
tBuAc-Phe-Leu-V
84
14.0
5
Boc-Phe-Lys(Cbz)-V
70
24.0
Boc-Phe-Leu-W
25
>lOO
7
Boc-Phe-Leu-X
70
63
59
8
Boc-Phe-Phe-Y
34
>lOO
4
9
Boc-Phe-Leu-2
8
>lOO
10 Boc-Phe-Phe-Phe-ol
22
>lOO
11 Boc-Phe-Leu-Leu-al
98
2.2
46
100
50
86
13.6
100
0.34
60.3
6
Pepstatin
0 0
apercent (%) figures indicate percent inhibition at low4 M. Is are in micromolar units. Compounds l-9 are the formal 24 It of linking a protected dipeptide acid via an amide bond to an appropriate aminoglycol. V= (lS,2R)-1-benzyl-(2,3-dihydroxypropyl)amino; W= (lS,2S)-1-benzyl-(2,3-dihydroxypropyl)amino; x= (lS,2S)-1-benzyl-(2,4-dihydroxybutyl)amino: Y= (lS,ZS)-2-hydroxy1-hydroxymethyl-(2-phenylethyl)amino; Z= (lS,2R)-l-benzyl-(2,4dihydroxybutyl)amino. Nal(1) denotes 3-(ll-naphthyl)-&-alaninyl.
2. The Effect of Dipeptide Plasma Renin Activity of Lasix
Table
Glycol 1 and Pepstatin on Treated Rhesus Monkeys
Time
Glycol (n=6)
Pre-Lasix -24 hr
12.2 -+ 2.9
13.9 + 2.5b
Post-Lasix 0 hr
47.2 + 7.9
53.1 t 6.1
2 min
13.0 + 0.2
5 min
8.4 + - 2.6 15.1 t 3.5
15 min
23.5 -+ 4.6
44.7 + 5.4
1
b mean + S.E. 157
Pepstatin (n=6)
22.7 + 9.2
Vol.
132,
No.
1, 1985
increased after
BIOCHEMICAL
by Lasix
and is
treatment.
diminished of the
AND
returned
The PRA for
to
50% of the
pepstatin
group
BIOPHYSICAL
to pre-Lasix
the
initial
RESEARCH
group
had returned
values
treated
value
after
COMMUNICATIONS
at 2 min
with
1 was still
15 min,
to post-Lasix
while
the
PRA
levels
within
15
(8)
postulated
min.
DISCUSSION: Recent that
work
a C-terminal
be the
on aldehydic
geminal
pharmacophore,
Because
the
inhibitory
glycols:
1,2
respectively,
aldehyde
in
Formula
As can be seen
Compounds respectively pepstatin;
I;
from
renin
compounds
to explore more
would
our
1, this
approach
inhibitor
leads,
IC50,s
inhibitors
I
R= i-h
2
R=CH2
Most
vitro
and
n= 1,2 hypothesis
that
formyl. was successful especially
of 8.7 than
Potent
158
and 2.6
the
when n=l: micromolar
standard,
respectively,
The one-carbon
Dipeptide
in
naphthylalaninyl,
substitutions
to pepstatin.
1.
in
under
homologous
this
test
might
mimic.
the
stable
3, 4, and 5 possessing
in potency
hydrate)
to be unstable
where
and Cbz-lysinyl
Figure
likely
substances
1) with
more potent
aldehyde
i.e.
Table
1 and 2 (Figure are
is
of the
with
new primate
tert-butylacetyl, comparable
moiety
diols,
the
as a transition-state
properties and 1,3
inhibitors
(i.e.
we decided
may be bioisosteric
generating
glycol
conditions,
in vivo
renin
functioning
parent
physiological
diol
(7)
Glycols.
homologue
are 7
Vol.
132,
No.
(n=2)
BIOCHEMICAL
1, 1985
was also
than
active
pepstatin.
important weakly clear
(IC50
activity
active.
That
because
the
the
diol
example,
and the
configuration
epimer
of I (n=l),
of 7 (n=2),
i.e.
at this
compounds
derived
(S,S)-statine
center
from
(9),
possibly,
1 and 2 occupy
inhibitor
pepstatin
potency there
is a closer
enzymatic
reaction
active-site.
It
with
transition
state
A remarkable
illustrates
the
specificity
of 1 and 2 for
385:l
glycol these
substances inhibit
also rat
homologue
dipeptides render over
for
such them
pepsin
containing
during
renin,
whereas
Table
versus
has not
over
Compounds
human renin; even
(11). I59
pepsin:
specificity: the
I)
been obtained
pepsin
Interestingly,
11,
such for
specificity a large
3
a greater
1 and 2
postulated
It is remarkable -is active. as 1 and 2 contain sufficient information for
their
preference.
aldehyde
as
(10). is
2 exhibits
at the acting
or pepsin. renin
that
the
10,Valll,,,
human renin
6:l
fact
2 and the
diols
renin
Compound
show species
(n=O in
specific statine
rat
inhibiting
1 shows a corresponding
do not lower
inhibitors.
preference
the
inhibitor
inhibitory
versus
than
to
inhibitors
human renin
other
competitive
and collected-substrate
for
with
Quite
1 and 2 are
of these
those
at C-3 in
glycols
feature
The
The superior
---His'-Leu
specificity
compared
inactive.
as the
is positioned
that
is
the
(i.e.
be linked
between
sequence
is possible
series
space
2 could
the
is also
of renin.
angiotensinogen
substrate:
9,
of pepstatin.
same
analogy
activity
bearing
same as that
active-site
sequence
only
inactive.
active
principle
of histidine-containing
natural
both
in the
for
carbon
compound
much the
8 is
for activity: -is critical i.e. compound 6, is inactive,
in the
active
is probably
necessary
10 is
V and X) is the
the
potent
derivative
is
I)
less
hydroxyls
asymmetric
(C* in Formula
the
epimer
the
COMMUNICATIONS
although
phenylserinol
alcohol
at
RESEARCH
x 10m5 M),
moiety
monohydric
hydroxyl
BIOPHYSICAL
of the
because
The stereochemistry
for
6.3
The orientation
for
secondary
AND
(7)
that
mere
to for
heptapeptide
renin
Vol.
132,
No.
BIOCHEMICAL
1, 1985
Table
3.
AND
BIOPHYSICAL
Specificity
RESEARCH
of Renin
COMMUNICATIONS
Inhibitors
SPECIFICITY (IC50 for pepsin) Renin
Inhibitor
(IC50 for 0.025 23 6
Pepstatin Iva-His-Pro-Phe-His-Sta-Ile-Phe-NH2 1 Boc-Phe-Leu-V 2 Boc-Phe-His-V
As part
of
trial,
we tested
(Table
2).
the
Compound
pepstatin,
exhibiting
consistent
with
prospective
for
1 for 1 proved
an agent activity
duration that
than
of action. a minimum
is desirable
for
for in
more efficacious
hypothesis
inhibitors
selecting
PRA lowering
greater
our
11
>385
protocol
diol
Reference
renin)
the the
This
of peptide
in vivo
clinical monkey standard is bonds
in
utility.
CONCLUSION: The novel 2,
represent
compounds
are
attractively
Because
subsites for
1,2-diol
lowest possess
stable
function
theme
the
known,
cophore.
glycols
an important
inhibitors
could
dipeptide
new class molecular only
of their
as probes their
the
design
constituting
Formula
I,
of renin weight
non-aldehydic
one peptide
demonstated for
in vivo
SAR studies activity
bond, 1,2
an addition
the
These renin
and contain diol
an
pharma-
activity, they 12 of S ,S , and S3 renin
makes them
to be bioisosteric to
by 1 and
in vitro
of new therapeutics.
was shown
typified inhibitors.
and convenient-to-handle
(7);
unit
of
armamentarium
an attractive
In addition,
the
with
thus
formyl, of the
medicinal
chemist. REFERENCES: 1.
2. 3.
Haber, E. (1983) Clin. and Exper. Hyper. A5(7&8), 1193. Burton, J., Poulsen, K., and Haber, E. (1975) Biochemistry 14, 3892. Haber, E., Koerner, T., Page, L.B., Kliman, B., and Purnode, A. (1969) J. Clin. Endocr., 29, 1349. 160
Vol.
4.
5. 6. 7. 8. 9. 10. 11.
132,
No.
1, 1985
BIOCHEMICAL
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
Anson, M.L. (1938) J. Gen. Physiol. 22, 79. Papaioannou, S., Hansen, D., Babler, M. P.-C. Yang, Bittner, S ., Miller, A., and Clare, M. (1985) Clin. and Exper. Hyper., in press. Sealey, J.E. and Laragh J.H. (1977) Cardiovascular Medicine 2,
1079.
Fehrentz, J.-A., Heitz, A., Castro, B., Cazaubon, C., and Nisato, D. (1984) FEBS Letters 167, 273. Kokubu,T., Hiwada, K., Sato, Y., Iwata, T., Imamura! Y., Matsueda, R., Yabe, Y., Kogen, H., Yamazaki, M., Ii]ima, Y and Baba, Y. (1984) BBRC 118, 929. Um&zawa, H., Aoyagi, T., Morishima, H., Matsuzaki, M., Hamada, M., and Takeuchi, T. (1970) J. Antibiot. Tokyo 23, 259. Rich, D.H. (1985) J. Med. Chem. 28, 263. Boger, J., Lohr, N-S., Ulm, E.H, Poe, M., Blaine, E.H., Fanelli, G.M., Lin, T.-Y., Payne, L.S., Schorn, T.W., LaMont, B.I., Vassil, T.C., Stabilito, I.I., and Veber, D.F. (1983) Nature 303, 81.
161
132,
October
No.
1, 1985
15,
BIOCHEMICAL
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS Pages
1985
DIPEPTIDE
GLYCOLS:
155-l
61
A NEW CLASS OF RENIN INHIBITORS
Gunnar J. Hanson: John S. Baran, Thomas Lindberg, Gerald M. Walsh, S.E. Papaioannou, Maribeth Babler, Stephen E. Bittner, Po-Chang Yang and Mary Dal Corobbo G.D. Searle and Co. Parkway, Skokie, Ill.
4901 Searle
60077
Received August 26, 1985 SUMMARY: The discovery of a new class of novel renin inhibitors consisting of protected dipeptide amides derived from aminoglycols (Formula I) prompted a study of structure-activity in vitro and efficacy in vivo. Thus, Boc-&-Phe-N-[(lS,2R)-1-benzyl-(2,3-dihydroxy)propyl]-L-leucinamide (1) and the corresponding histidinamide (2) inhibit human renin in vitro (IC50: 8.7 x 10-6 M and 2.6 x lo-6 Ij, respectively). Compound 1 has a slight inhibitory effect on pepsin and compound 2 does not inhibit pepsin at all (at lo-4q; these compounds are inactive against rat renin. Compound 1 is efficacious in lowering plasma renin activity in the Rhesus monkey (i.v.). Results indicate that this new class of low molecular weight inhibitors is specific for human renin and thus constitutes a new source of drug candidates. 0 1985 Academic Press, Inc.
The search 3.4.99.19)
for
greatly
in
clinical
remains
(EC 3.4.15.1)
catalyzes
N-terminus
inhibitors
(1),
but
are
should
the
hydrolytic
Design candidates
potentially
clinical
of trial,
whom correspondence
the
inhibition
release
of
angiotensin
this
process
is
substance
high
I from
the
rate-limiting II.
Renin
of plasma
pressure.
In seeking
we focused
enzyme
successful.
modulators
Inhibitors.
should
the
and
as an alter-
angiotensin
blood
such
commercial
be equally
important
(EC
interest,
I converting
renin
in principle
and pathologically
for to
in
of pressor
and Selection
tremendous
of angiotensin
interest
that
thus
despite
of human renin has intensified
Nevertheless,
inhibitors
fueled
inhibitor
of hypertension
elusive.
formation
activity
* author
active
of angiotensinogen;
in the
renin
of
has
approach
Renin
treatment years
success
native
an orally
the
recent
an inhibitor
step
for
on compounds
new chemical that
be addressed 0006-291X/85 $1.50
155
Copyright 0 1985 by Academic Press, Inc. All rights of reproduction in any form reserved.
Vol.
132,
No.
1, 1985
satisfied
BIOCHEMICAL
the
exhibit
a high
degree
that
an oral
insuring pepsin,
following
(~600)
2) the to
of
dose
3) it
should
peptide
the
to or greater
lower
plasma
should
we wish
satisfy
the
amides
derived
that
be of
must
of other
low molecular
weight
a primate
a new class
one func-
potency
should
5) the
substance
model.
In this
renin
inhibitors
of
N-terminal
aminoglycols
at most
electrophilic
in vitro
(Formula
acid
absorption;
possessing
of reactive
requirements:
from
inhibition
of pepstatin; in
to report
substance
of gastrointestinal
4) the
activity
above
of
COMMUNICATIONS
--for renin vs pepsin, bound to gastric
become
stable,
be free
than
renin
not
likelihood
as aldehyde;
equal
specificity
probability
and should
such
nication
the
be metabolically
bond
tionality
will
RESEARCH
1) the
in vitro
inhibitor
increase
BIOPHYSICAL
requirements:
and to decrease
proteases;
AND
protected
be must
Commuthat
dipeptide
I).
METHODS AND MATERIALS: In vitro inhibition assays for human renin, rat renin, and porcine pepsin were performed using known methods (2,3,4) as A monkey model for assaying the effect of modified recently (5). test compound on plasma renin activity (PRA) was developed: Rhesus monkeys (6/group) weighing 6.3-9.9 kg were treated with Lasix (furosemide) at 2 mg/kg, both in the a.m. and p.m. on Day 1. intravenousOn Day 2, test compound at 10 mg/kg was administered Plasma samples (K-EDTA) were taken at intervals as indicated ly. in Table 2; PRA was then determined by a known method (6). Details of the dipeptide glycol synthesis will be published elsewhere. Compounds 1 through 9 were prepared by amidation of a protected dipeptide or amino acid with an appropriate aminoglycol (see Table 1 and Figure 1 for structures). All amino acids are of the & configuration.
RESULTS: Table
1 summarizes
dipeptide
glycols
inhibitors
have
the
in vitro
and related the
general
inhibition
data
for
the
The new glycol
compounds. formula:
N-protected-Dipeptide-NHCH(CHZPh)&i([CHz],-0H)OH To demonstrate i.v.
to Rhesus
pepstatin
treated
in vivo
monkeys.
efficacy,
Table
and compound
compound
2 shows the 1 groups. 156
(1) 1 was administered
PRA for For both
both groups,
the PRA is
Vol.
132,
No.
BIOCHEMICAL
1, 1985
Table
AND
BIOPHYSICAL
In Vitro
1.
COMMUNICATIONS
Inhibitiona
Human Renin no.
RESEARCH
Pepsin
Rat Renin
structure
%
IC50
%
IC50
1
Boc-Phe-Leu-V
87
8.7
67
50
0
2
Boc-Phe-His-V
90
2.6
4
>lOOO
0
84
15.4
63
0
59
0
3
Boc-Nal(l)-Leu-V
%
4
tBuAc-Phe-Leu-V
84
14.0
5
Boc-Phe-Lys(Cbz)-V
70
24.0
Boc-Phe-Leu-W
25
>lOO
7
Boc-Phe-Leu-X
70
63
59
8
Boc-Phe-Phe-Y
34
>lOO
4
9
Boc-Phe-Leu-2
8
>lOO
10 Boc-Phe-Phe-Phe-ol
22
>lOO
11 Boc-Phe-Leu-Leu-al
98
2.2
46
100
50
86
13.6
100
0.34
60.3
6
Pepstatin
0 0
apercent (%) figures indicate percent inhibition at low4 M. Is are in micromolar units. Compounds l-9 are the formal 24 It of linking a protected dipeptide acid via an amide bond to an appropriate aminoglycol. V= (lS,2R)-1-benzyl-(2,3-dihydroxypropyl)amino; W= (lS,2S)-1-benzyl-(2,3-dihydroxypropyl)amino; x= (lS,2S)-1-benzyl-(2,4-dihydroxybutyl)amino: Y= (lS,ZS)-2-hydroxy1-hydroxymethyl-(2-phenylethyl)amino; Z= (lS,2R)-l-benzyl-(2,4dihydroxybutyl)amino. Nal(1) denotes 3-(ll-naphthyl)-&-alaninyl.
2. The Effect of Dipeptide Plasma Renin Activity of Lasix
Table
Glycol 1 and Pepstatin on Treated Rhesus Monkeys
Time
Glycol (n=6)
Pre-Lasix -24 hr
12.2 -+ 2.9
13.9 + 2.5b
Post-Lasix 0 hr
47.2 + 7.9
53.1 t 6.1
2 min
13.0 + 0.2
5 min
8.4 + - 2.6 15.1 t 3.5
15 min
23.5 -+ 4.6
44.7 + 5.4
1
b mean + S.E. 157
Pepstatin (n=6)
22.7 + 9.2
Vol.
132,
No.
1, 1985
increased after
BIOCHEMICAL
by Lasix
and is
treatment.
diminished of the
AND
returned
The PRA for
to
50% of the
pepstatin
group
BIOPHYSICAL
to pre-Lasix
the
initial
RESEARCH
group
had returned
values
treated
value
after
COMMUNICATIONS
at 2 min
with
1 was still
15 min,
to post-Lasix
while
the
PRA
levels
within
15
(8)
postulated
min.
DISCUSSION: Recent that
work
a C-terminal
be the
on aldehydic
geminal
pharmacophore,
Because
the
inhibitory
glycols:
1,2
respectively,
aldehyde
in
Formula
As can be seen
Compounds respectively pepstatin;
I;
from
renin
compounds
to explore more
would
our
1, this
approach
inhibitor
leads,
IC50,s
inhibitors
I
R= i-h
2
R=CH2
Most
vitro
and
n= 1,2 hypothesis
that
formyl. was successful especially
of 8.7 than
Potent
158
and 2.6
the
when n=l: micromolar
standard,
respectively,
The one-carbon
Dipeptide
in
naphthylalaninyl,
substitutions
to pepstatin.
1.
in
under
homologous
this
test
might
mimic.
the
stable
3, 4, and 5 possessing
in potency
hydrate)
to be unstable
where
and Cbz-lysinyl
Figure
likely
substances
1) with
more potent
aldehyde
i.e.
Table
1 and 2 (Figure are
is
of the
with
new primate
tert-butylacetyl, comparable
moiety
diols,
the
as a transition-state
properties and 1,3
inhibitors
(i.e.
we decided
may be bioisosteric
generating
glycol
conditions,
in vivo
renin
functioning
parent
physiological
diol
(7)
Glycols.
homologue
are 7
Vol.
132,
No.
(n=2)
BIOCHEMICAL
1, 1985
was also
than
active
pepstatin.
important weakly clear
(IC50
activity
active.
That
because
the
the
diol
example,
and the
configuration
epimer
of I (n=l),
of 7 (n=2),
i.e.
at this
compounds
derived
(S,S)-statine
center
from
(9),
possibly,
1 and 2 occupy
inhibitor
pepstatin
potency there
is a closer
enzymatic
reaction
active-site.
It
with
transition
state
A remarkable
illustrates
the
specificity
of 1 and 2 for
385:l
glycol these
substances inhibit
also rat
homologue
dipeptides render over
for
such them
pepsin
containing
during
renin,
whereas
Table
versus
has not
over
Compounds
human renin; even
(11). I59
pepsin:
specificity: the
I)
been obtained
pepsin
Interestingly,
11,
such for
specificity a large
3
a greater
1 and 2
postulated
It is remarkable -is active. as 1 and 2 contain sufficient information for
their
preference.
aldehyde
as
(10). is
2 exhibits
at the acting
or pepsin. renin
that
the
10,Valll,,,
human renin
6:l
fact
2 and the
diols
renin
Compound
show species
(n=O in
specific statine
rat
inhibiting
1 shows a corresponding
do not lower
inhibitors.
preference
the
inhibitor
inhibitory
versus
than
to
inhibitors
human renin
other
competitive
and collected-substrate
for
with
Quite
1 and 2 are
of these
those
at C-3 in
glycols
feature
The
The superior
---His'-Leu
specificity
compared
inactive.
as the
is positioned
that
is
the
(i.e.
be linked
between
sequence
is possible
series
space
2 could
the
is also
of renin.
angiotensinogen
substrate:
9,
of pepstatin.
same
analogy
activity
bearing
same as that
active-site
sequence
only
inactive.
active
principle
of histidine-containing
natural
both
in the
for
carbon
compound
much the
8 is
for activity: -is critical i.e. compound 6, is inactive,
in the
active
is probably
necessary
10 is
V and X) is the
the
potent
derivative
is
I)
less
hydroxyls
asymmetric
(C* in Formula
the
epimer
the
COMMUNICATIONS
although
phenylserinol
alcohol
at
RESEARCH
x 10m5 M),
moiety
monohydric
hydroxyl
BIOPHYSICAL
of the
because
The stereochemistry
for
6.3
The orientation
for
secondary
AND
(7)
that
mere
to for
heptapeptide
renin
Vol.
132,
No.
BIOCHEMICAL
1, 1985
Table
3.
AND
BIOPHYSICAL
Specificity
RESEARCH
of Renin
COMMUNICATIONS
Inhibitors
SPECIFICITY (IC50 for pepsin) Renin
Inhibitor
(IC50 for 0.025 23 6
Pepstatin Iva-His-Pro-Phe-His-Sta-Ile-Phe-NH2 1 Boc-Phe-Leu-V 2 Boc-Phe-His-V
As part
of
trial,
we tested
(Table
2).
the
Compound
pepstatin,
exhibiting
consistent
with
prospective
for
1 for 1 proved
an agent activity
duration that
than
of action. a minimum
is desirable
for
for in
more efficacious
hypothesis
inhibitors
selecting
PRA lowering
greater
our
11
>385
protocol
diol
Reference
renin)
the the
This
of peptide
in vivo
clinical monkey standard is bonds
in
utility.
CONCLUSION: The novel 2,
represent
compounds
are
attractively
Because
subsites for
1,2-diol
lowest possess
stable
function
theme
the
known,
cophore.
glycols
an important
inhibitors
could
dipeptide
new class molecular only
of their
as probes their
the
design
constituting
Formula
I,
of renin weight
non-aldehydic
one peptide
demonstated for
in vivo
SAR studies activity
bond, 1,2
an addition
the
These renin
and contain diol
an
pharma-
activity, they 12 of S ,S , and S3 renin
makes them
to be bioisosteric to
by 1 and
in vitro
of new therapeutics.
was shown
typified inhibitors.
and convenient-to-handle
(7);
unit
of
armamentarium
an attractive
In addition,
the
with
thus
formyl, of the
medicinal
chemist. REFERENCES: 1.
2. 3.
Haber, E. (1983) Clin. and Exper. Hyper. A5(7&8), 1193. Burton, J., Poulsen, K., and Haber, E. (1975) Biochemistry 14, 3892. Haber, E., Koerner, T., Page, L.B., Kliman, B., and Purnode, A. (1969) J. Clin. Endocr., 29, 1349. 160
Vol.
4.
5. 6. 7. 8. 9. 10. 11.
132,
No.
1, 1985
BIOCHEMICAL
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
Anson, M.L. (1938) J. Gen. Physiol. 22, 79. Papaioannou, S., Hansen, D., Babler, M. P.-C. Yang, Bittner, S ., Miller, A., and Clare, M. (1985) Clin. and Exper. Hyper., in press. Sealey, J.E. and Laragh J.H. (1977) Cardiovascular Medicine 2,
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Fehrentz, J.-A., Heitz, A., Castro, B., Cazaubon, C., and Nisato, D. (1984) FEBS Letters 167, 273. Kokubu,T., Hiwada, K., Sato, Y., Iwata, T., Imamura! Y., Matsueda, R., Yabe, Y., Kogen, H., Yamazaki, M., Ii]ima, Y and Baba, Y. (1984) BBRC 118, 929. Um&zawa, H., Aoyagi, T., Morishima, H., Matsuzaki, M., Hamada, M., and Takeuchi, T. (1970) J. Antibiot. Tokyo 23, 259. Rich, D.H. (1985) J. Med. Chem. 28, 263. Boger, J., Lohr, N-S., Ulm, E.H, Poe, M., Blaine, E.H., Fanelli, G.M., Lin, T.-Y., Payne, L.S., Schorn, T.W., LaMont, B.I., Vassil, T.C., Stabilito, I.I., and Veber, D.F. (1983) Nature 303, 81.
161