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A biomimetic approach to sporidesmins. synthesis of an α,β-epoxytryptophan derivative
Tctr&&oa Vol. 42. No. U, pp. 651I IO6518.1986 Printedin Grnl Britain.
A BILBlIcEIIC
-/sb 55.00+.00 0 WlW~JO~LId.
APPROACH TO SWRIMSMINS. SYNTHESIS OF AN a.8-EPOXYTRYPTOPHANDERIVATIVE
RALF PLATE,
ANNETTE Y.G.
THEWISSE,
RUTGER J.F.
NIVARfl AMI HARRYC.J.
OTTENiELW Department of Organic Toernooiveld,
Chemistry,
University
6525 ED Nijmegen,
(Received in UK 24
Nijmegen,
of
The Netherlands
September 1986)
from 16 Abstract: The reaction of 19 - prepared efficiently with DDQ affords 22. This epoxide may serve as a model compound to investigate the biosynthesis of spridesains, e.g. 1 and 2.
INTRCXIUCTION The sporidesmins turing
a-
causing
make up a group of naturally
0,s ‘-substituted
or
facial
exxema in
which
charterurn liara,s.
occurs A (1)
from the
amino acids
peripheral
changes
that
the N-methyl
delivered
either
the
the
tryptophan must have
groups steps
skeleton
sis
of
place
us with the
introduced
the
tem might
yield
nucleophile This
retention
intriguing
Sammes' , who invoked
2’.
to
would create scheme is
mould qetabolites,
loss
he concluded with
e.g.
of
intermediacy the 5a.b’
groups
1 R’rCI,R2=OMc
series
of the
sulfur
concerning
atoms are
have not been
the
remain obscure.
at C(B) at this
introduction
Kirby’
experiments
pathway
di-epoxide 3;
a-mercapto-B-hydroxy by the following
6511
has
of
tryptophan
considerations.
studied the spo-
involving
C(S)
in the biosythecarbon
atom. This
been
attack
is by
This sys-
by a sulfur
moieties Firstly,
amino acid
group
provided
4 (Scheme I).
subsequent
have an a,B-epoxy
F
of
demonstrated
in the hydroxylation
likely
lx SPORIOESMIN
have
by what mechanism the hydroxyl
R’.OMe SWRIDE!SMIN A
1b.c ,
derivation
an extensive and the
hydroxylation
SCHEMEI
R’.CI,
sporidesmins
to the sporidesmins
details
mono-epoxide
and 6’
Pithomycas and Austra-
a biosynthetic
configuration
question
the
the
fea-
principle
fungus
studies
From labeling that
active
or methionine’.
involved
The most
supported
of
from methionine
two hydroxyl
the
although,
cysteine
metabolites
the
New Zealand
suggests
from tryptophan
hydrogen
fros of
Labeling
In particular,
biosynthetically. react
place.
at the B-position.
derivatives
1 takes
leaves
F (2),
and alaniner, taken
leading
of
areas
structures
are derived
atoms and the
stereochemistry
‘H-labeled
the
and sporidesmin
in any detail.
sulfur
ridesmin
of
pasture
fungsl
They are
and were obtained
certain
by sodium sulfate,
The metabolic investigated of
sheep
in
Consideration
e.g. sporidesmin
ocurring,
dioxopiperaxines.
of
1 or
several
moiety
as a
6512
R. PLME et al,
structural
feature.
well-documented in another oxidative
Secondly,
the conversion
mechanism proposed
synthetic ring
approach
closure
cf.
posed
intermediacy
to
the
4+3 has a close
the biosynthesis sporidesmins,
based on the conversion
Here we wish to report tive,
for
the first
10 (Scheme II). of 3 and
to the Thirdly,
we employed successfully
an
of 4+3i’.
synthesis
of an a,S-epoxy
This
synthesis
4
the biosynthesis
in
resemblance
of gliotoxin’.
provides
further
tryptophan support
to
derivathe pro-
of the sporidesmins’.
4-R koJqpfp 0 l
d
:R= H
b: Rz 044 CYCLOPENOL
STRATEGY
Compound 10 was selected i.e.:
and 4.
3
epoxidation
This
explored
of
the
(Scheme
for
not
the putative
directly
sporidesmin
accessible
o,S-dehydrotryptophan
indole
nucleus.
II).
Initially
C
EPOXY -FUMlTREMOROIN
as a model
compound is
of the corresponding
the presence
Me
Me
CYCLOPENIN
Therefore, we
via
precursors,
straightforward
derivative”,
two alternative the
studied
because approaches
S-oxidation
of
of were an
SCHEME II
N-hydroxytryptophan might
yield
approach
the
failed
derivative sion
(vi&
11 (route
9,
B).
which
Oxidation of
A, 7+8).
should
we first
fnfra),
by the intermediacy
Route
(route
derivative” acylimine
Subsequent
yield
prepared
gave indeed
the
elimination
a,[)-epoxide
the a-functionalized 10; we rationalize
of RX-OH
16.
As this
tryptophan this
conver-
12.
A
S-Oxydation
of an N-hydroxytryptophan
derivative
(cf.
7+8)
was studied
using
SCHEME III
NHR’ 3.-
Lj
,- a: R’.R2=R3=H b: R’.R’=Mc;
R’.H
c: R’=R’=H;
R3.CH2CsH~
d: R’ =R2.Mc the
oxime
as an oxidizing thy1 C=N
derivative bond
attempts a
III)
13 (Scheme
13~ - prepared
of
reagent
and the dioxopiperazine 16 (Scheme IV). Treatment of - with DDQ in aqueous tetrahydrofuran”
from 13a by 0-benxylation agent afforded or
14d had
Treatment introduced
of by
2,3-dihydrotryptophan
derivative
soned
of
that
the R-keto
14d was obtained 14c
failed.
; R3=CH2C6H5
reduction
derivative
analogously to
be
14d with us
reduced
14~
from 13d. selectively.
in 89% yield.
The dime-
Subsequently,
the
Unfortunately,
oxime
all
the trimethylamine borohydride complex the gave related reductions” for
15 in 53% yield.
the oxima had to preceed
Having observed
this
the
Accordingly,
B-oxidation.
we rea-
6513
A biomimctic approach to sporidcsmins the next compound we. studied an untractable
ever,
(Scheme IV).
was 16”
reaction
mixture.
Treatment with DDQ gave,
We ascribe
this
failure
bar-
to the high acid-
!? ity
of the a-proton
of
17 facilitating
the elimination
of benzyl
alcohol.
Route B On the basis
of the above findings
out subsequent
we felt
invariably
lead
to elimination
the proper
oxidation
state.
that
reactions
bef,ore
Accordingly,
the
of 16 with sodium methoxide
of
DDQ in aqueous TRP yielded
20
(30%)
reduce
again and
the a-hydroxy
the B-carbonyl
group
order
the B-carbon
a mixture
19
of
a hydroxy
into
(56%).
steps
18 was pre-
(Scheme V).
of
Oxidation
the desired
Unfortunately, group
would
would have reached
derivative
in methanol
derivative Xl
had to be carried
of reaction
a-•ethoxy
pared by treatment 18 using
S-oxidation
the reverse
to a-functionalization
compound
attempts
failed.
Possibly
to the
SCHEME V 0M.O
16 -
presence
&J?
of an a-NH-proton
Having observed rupted
as
soon
this
as the
B-carbon
alcohol.
We reasoned
12+lD)
might be possible
approach was found When the
precludes
failure, that
in
trapping
to
from an a-hydroxy
has to be inter-
state yield
of
a secondary
an epoxide
derivative,
vfz.
(viz.
11. This
indeed.
by
treated
a molar equivalent
to which we assigned
the oxidation
derivative
(83% yield) with
that the oxidation
atom is
star::ng
treatment
conversion.
intramolecular
to be viable
a-hydroxy
this
we realized
19 - prepared
with
aqueous of
structure
from 18 (95% yield)
sodium
hydroxide,
DDQ in tetrahydrofuran
22 on basis
or
from 16
respectively a product
of the following
-
was
was formed
observations
(Scheme
SCHEME VI
VI).
Firstly,
idesr’
-
upon spraying
a positive
pounds reported
(red)
pared
to
spectrum
the spectrum
it
decomposes
derivative hydroxide qetboxide products tion
not
22 is slowly
been
for
an unstable to
the ester
can be rationalized
sodium hydroxider’.
to
loss
feature
26b
22
opening
of
of
(Scheme VII).
by the formation
is
ppm) as impact
26a,
of 5a and 5b’.
formed quantitatively silica
gel.
Treatment
of benxoic
acid
of
with
sodium
with sodium
these
This type
So far
amino acid
and reaction
The formation
in Scheme VII.
com-
mass
from the molecular e.g.
using
epoxide.
com-
‘Ii-NMR spectrum
an o,B-difunctionalized the
epox-
(Lk8.56
oxygen it
for other
electron
of epoxides,
gave the acid
as depicted
the
conditions
into
the
C(2)-proton Thirdly,
the
indicative whereas all
Secondly,
compound; whereas
convert ring
test.
indole
under chromarographic
able
- a reagent
was observed,
ppm)“.
is a typical
by nucleophilic
is precedented
the
19 (6~6.87
or sodium methylmercaptide gave
acid
in this
corresponding
fragmentation
The epoxide we have
shift
of
showed an ion
this
ionI’,
picric reaction
here were negative
22 showed a downfield
of
with
colour
degradation of
fragmenm
from 5a upon treatment
with
A biomimctic approach to sporidcsmins
and with brine,
and subsaquently dried (NaeSO.). The residue obtained by evapo-
ration of
the solvent was subjectad
giva
mg
of
W
(N&H)
280
Kw&).
13c
(91%);
to
r..p.
Am,=286,
flash column chromatography (CHsClr) to
120-122
‘C
(CH&lr/n-buana),
255 m.
222 nm; Amin
tic
Rf
0.2
EIMS (70 eV) m/e-S07 ([M]',
25X), 171 (15%). 155 (50%). 130
5%). 216 ([If-CHaC.Hs]*,St), 200 ([M-OCH&.]*,
(IGHeN]+, 55%). exact mass calcd. for C~eHrrNsOs 307.1321, found 307.1325. ~H-NMR (60 MHE, CDCl,), b=8.2 (s(br), lli, indole NH), 7.6-6.9 (m, 5H, indolec(2), C(4)-C(7)H), 7.3 (s. SH, CeHs), 6.5 (s(br), 2H 0X&),
5.15 (s, 2H, CCHs),
4.0 (s, 2H. indole C(3)-WI). 1-[(E)-Benzyloximtno]-2-(HnethylIndol-3-yl)N~thylpropan~lde A solution of benxyl bromide (2.2 -1,
(13d)
380 mg) in dimethoxyethane (10 ml) was
added dropwisc to a stirred solution of 13b"
(2 ssnol, 490 mg) and potassium
terf.-butoxide (2.2 m~ol, 250 mg) in dimethoxyethane (20 ml) at room temperature and in an argon atmosphere. Stirring was continued for 3 hrs.
Then the solvent
was removed in vacua. A solution of the residue in CHrClz was washed with 1N HCl and with brine, and subsequently dried (NasSO.). Evaporation of the solvent and flash column chromatography
(CHrCls) of the residue gave 640 mg of 13d (96%);
m.p. 64-65.5 'C (CHsClr/n-hexane), tic Rf 0.2 (CHsClr).
W
(MeOH) Xmax=286, 228
nm; xmin. 256 nm. EIMS (70 eV) m/e=335 ([Ml', 27X), 228 ([CIIH:.NIO]*, loo%), 47X), 144 171 ([CIIHI~NZ]+, 94%), 170 ([CrrH11Nr]+, 33X), 169 ([C~dWzl+, ([ClrH~rNl*, 80%); exact mass calcd. for C 1,H rrN ,0 r 335.1634, found 335.1628. 'H-NMR (90 MHz, CDCl,), 6=7.71-6.88 (m, SH, indole C(2), C(4)-C(7)H), 7.34 (6, 5H, CIHs). 6.7 (m, lH, CHrNH), 5.21 (6, 2H, OClIr), 4.02 (s, 2H, C(3)-CHs), 3.64 (s, 3H, indole NCHI), 2.76 (d, '5~5 Hz, 3H. CH,NH). l-[(E)-Benzyloximino]-P-(lndol-3-yl)-2-oxo-propanamide TO a solution of 13c (0.2
indole
(14~)
mmol. 63 mg) in THF/HsO (9/l, v/v, 5 ml) was added DDD
(0.4 mmol. 91 mg). After stirring for 2 hrs the solvents were evaporated and CHrCls was added to the residue. The suspension was filtered and the filtrate was washed, dried (NarSO,) and the solvent evaporated.
Flash column chromatog-
raphy (MeOH/CHrClr. 4196, v/v) gave 57 mg of 14~ (89%) as an oil which was homogeneous on tic Rf 0.16 (MeOH/CHrClr, 6/94, 236
(sh).
204
(LC,HrNO]*,
nm;
100X),
lmin.
277
ND.
91 (IC,HTI’,
V/V).
EIMS 100%);
W
(70 eV) exact
(MeOH) Imax=305, 260 (sh), m/e=321
mass
([Ml+, 28%),
calcd.
for
144
ClrHlrNaOr
321.1113, found 321.1110. IH-NMR (60 MHz, CDCl~), 6=9.7 (s(br), lH, indole NH), 8.2-7.9 and 7.3-6.9 (m, SH, indole c(~)H, C(4)-C(7)H), 7.10 (6, SH, CeHr), 6.4 and 6.0 (s(br), 2H, NH,), 4.93 (s, 2H, ~cH,). (14d)
l-(Benzyloximino)-2-(N-methylindol-3-yl)-2-oxo-N-~t~lpro~n~ide To a solution of 13d (1.7 -1,
575 mg) in THF/HrO (9/l, v/v, 10 ml) was added
DDQ (3.5 mmol, 779 mg). After stirring for 3 hrs the solvents were evaporated and CHrClr was added to the residue.
The suspension was filtered and the fil-
trate was washed, dried (NarSO,) and the solvent evaporated. Flash column chromatography gave 451 mg of 14d (76%) as an oil which was homogeneous on tic Rf 0.48 (MeOH/CHrClr, 6/94, v/v). 280, 234 nm. EIMS
([CIHTI+,
45%);
W
(MeOH) Xmax=312, 266 (sh), 246, 208 nm; Xmin.
(70 eV) m/e=349
exact mass
calcd.
([Ml', 22%),
158 ([C~IHINO]*, lOO%), 91
for IZ~~HL.N~O, 349.1426,
found 349.1419.
'H-NMR (60 MHz, CDC~X), 6=8.3-8.1 and 7.4-7.1 (m, SH, indole C(2)H. C(4)-C(7)H), 7.3 (s, SH, C&H,), 6.7 (m, lH, NH-CHr), 5.16 (s, 2H, OCHI), 3.69 (s, 3H, indole N-CH,), 2.84 (d, '515 Hz, 3H, NHCH,). l-(Benzyloxaraino)-2-(N-methylIndolin-3-yl)-N-~thylpropllnami~ To a solution of 14d (0.5 mmol, 175 mg) and HerN*BHr"
(15) (1 mol,
80 qg) in etha-
nol (5 ml) a solution of HCI in ethanol (5 ml of a 7N solution) was added dropwise at room temperature in an argon atmosphere.
After stirring the reaction mixture for 24 hrs another 4 equivalent of MerN*BH, (2 -01, 160 qg) were added.
After 4 days the solvent was
evaporated. Then
the residue was dissolved
in
CHsCls and the resulting solution was washed with O.lN NaOH, dried (NasSO.) and
R. PLATSet al.
6516
filtered. Evaporation of the solvent gave a residue which was subjected to flash column chromatography
(CHrClr) to give 90 mg of 15 (53%) as an oil which was
homogeneous on tic Rf 0.25 (MeOH/CHzClr. 4/96,
W
v/v).
(HeOH) Xm6288.
224 (sh), 204 nm; lmin . 276, 237 nm. EIMS (70 eV) m/e=339 (]CirHirN,Ul+, 25x),
144 ([C,,HION]*.
62X),
132
([C,HIDN]*),
133
for CI.H.SNIO, 91 ([C~HIJ+, 46%); exact mass calcd. 339.1947. 'H-NHR (60 MHZ, CDCl,), 6=7.2 (6. 5H, MIS), 7.2-6.2 6.1
(m,
1H. Nl+CHr), 4.6
3.4-2.5 (m, 5H, indoline c(2)H 2, c(3)H. 3H,
indoline
(26x1,
339.1945,
(41%))
c(4)-c(7)H).
248,
([Ii]', 17%). 215
(m,
4H,
131
found
i.ndolioo
(8, 2H, OCM,), 3.7-3.5 (m. lH, C(e)M), and c@)H),
2.7
(d,
3H.
NHCH,),
2.6
(s.
(dry,
150
ml)
N-CH,).
l-Methyl-3-methoxy-3-[(N-raethylindol-3-yl)methyl]-6-methylenepiperazine-2.5dione To
(18) a stirred
was added
solution
potassium
of
16l’
tart-butoxyde
(1.14 (320
g,
2.9
sxuol)
qg, 2.9 ml)
in
methanol
at room temperature. After
stirring for 4 days at room temperature the mixture was neutralized by adding ammonium chloride (0.160 g). Stirring was continued for 17 hrs, where after the solvent was evaporated in vacua. Dichloromethane was added to the residue and the suspended salts were filtered off. The filtrate was concentrated to dryness to yield an oil which consisted of 20 and benzyl alcohol. Column chromatography (CHrCl,/MeOH, 98/2, v/v) gave 735 mg of 20 (81%), which was crystallised CHrClr/n-hexane:
m.p.
172-173
'C;
tic
Rf
0.35
(solvent
system
(methanol) Xmax=218, 255 (sh). 284, 296 (sh) nm; lmin=281 nm. m/e=313
from
II).
EIMS
([Ml+, l%), 281 ([CLCHI~N~O~]+, lo%), 144 ([CioHI~N]+, 100%).
UV
(70 eV) exact
mass calcd. for Ci,HirNrO, m/e 313.1426, found 313.1423. 'H-NMR (90 MHz, CDCl,), 67.65-7.0 (m, 4H, indole C(4)-C(7)H), 6.91 (s, lH, indole C(2)H), 6.26 (m, lH, NH), 5.57 (B part of AB spectrum, lH, 'JAB=1.5 Hz, C=CHBHA), 4.59 (A part of AB spectrum, lH, *JAB=1.5 Hz, C=CHAHB), 3.74 (s, 3H, indole N-CHr), (B part of AB spectrum, lH, 'JAB=14.5 Hz, indole C(3)-CHAHB), 3.35 (A part of AB spectrum, lH, 'JAB=14.5 Hz. indole C(3)-CHAHB), 3.27 (s, 3H, C(3)CCHr), 2.98 (s, 3H, piperazinc N-CH,). l~thyl-3-hydroxy-3-[(N-methylindol-3-yl)methyl]-6-rsethylenepiperazlne-2.5-
dlone
(19)
From 16: To a stirred 0.5N
solution
of
16l’
(3.2
rmuol,
1.24
g)
in dimethoxyethane
(60
ml)
NaOH (40 ml) was added at room temperature in an argon atmosphere. After 4
days the reaction mixture was treated with NH.Cl. Then the solvent was evaporated, the residue was partitioned between water and CHrClr. The organic layer was dried and the solvent evaporated. Recrystallization (CHrCl,/n-hexane) gave 0.79 g of 19 (83%), m.p. 163-165 'C. Rf 0.24 (MeOH/CHrClr, 7/93, v/v). UV (MeOH) 1,,=296 3X), 281
(sh), 284, 252 (sh), 221 nm; Xmin
280 nm. EIMS (70 eV) m/e=299 ([Ml+,
(ICIC~ISN~~ZI+, 6%). 144 ([C~DH;,N]+, 100%); exact mass calcd. for
C1~H1,N,OI 299.1270, found 299.1263. iH-NMR (90 MHz, CDClr), 6=7.50-6.90 (m, 4H, indole C(4)-C(7)H), 6.87 (s. lH, indole C(2)H), 6.80 (s(br), lH, piperazine NH), 5.37 (B part of AB spectrum, 'JAB=2 Hz. lH, =CHAHB), 4.44 (A part of AB spectrum, 'JAB=2 Hz, lH, =CHAHB), 4.30 (s(br), lH, OH), 3.71 (s, 3H, indol N-CHI), 3.50 (B part of AB spectrum, 'JAB=14 Hz, lH, CHAHB), 3.30 (A part of AB spectrum, 'JAB=14 Hz, lH, CHAHB, 2.78 (s, 3H, piperazine N-CHI). To a solution of 18 (0.5 mmol, 150
From 18:
qg) in THF/HrO (9/l, v/v, 10 ml) was added
1N NaOH (1 ml) at room temperature in an argon atmosphere. After stirring the reaction mixture for 24 hrs the room temperatrue it was neutralized (NHbCl) and the solvent was evaporated. Usual work-up gave 135 mg (95%) of 19, vhich vas identical with the compound described above. l-Methyl-3-Rethoxy-3-[(Nmethylindol-3-yl)carbonyl]-6-methylenepiperazine-2.5dione
(20)
6511
A biomimetic approach to sporidesmins TO a stirred
solution
was added DDQ (0.5 ture
of 18 (0.25
in an argon atmosphere
the
The
residue.
(NatSO.) 2/98,
v/v)
(HeOH) Lmex=316,
homogeneous on tic,
268
(sh),
159 (29%).
4X),
207
nm; l,,,in.
found
327.1226.
8.30-8.20
and 7.40-7.20
‘JAB=5 Hz, C=CHAtiB) , 5.00
lH, 3.89
(s.
3H, indole
N-CM,),
282,
(s,
was washed,
nm. EIHS (70 mass calcd.
6=8.47
C(4)-C(7)H), of
dried
(MeOWCHaCl1,
(MaOH/CH,Clr, 6/94. 237
100%); exact
(A part
3.55
and CHrClr was added to
filtrate
0.39
‘H-NMR (90 MHz, CDCI,), (m, 4H, indole
10 ml)
19 (58%).
Rf
158 ([C1,H,NO]+,
327.1219,
v/v,
at room tempera-
column chromatography
gave 25 qg of 20 (30%) and 44 mg of oil,
24 hours
and the
Flash
evaporated.
for
were evaporated
was filtered
solvent
Compound 20: (WI+,
stirring
the solvents
suspension
and the
mmol. 78 mg) in THE/H.0 (9/l,
After
114 qg).
maol,
(6,
5.93
AB spectrum,
3H, OCH,), 3.21
for
lH,
lH,
W
ClrHrrNrCb
indole
(B part
(s,
v/v).
eV) m/e=327 C(2)H),
of AB spectrum,
‘JAB=5 Hr., C’CHAHB,
3H, piperazine
N-CH,).
l-Methyl-2,5-dfoxo-6-methylen-plperazine-3-spiro-3’-(N-methylIndol-3-yl)-2’(22)
oxirane
To a stirred argon
solution
atmosphere
residue
of
2/98,
was washed with v/v)
246,
brine.
gave a small
found 297.1115;
ClrHIIN,O,
6=9.30
lH, piperazine
7.70-7.10 5.11
(m, GH, indole
(A part
6=3.5-3.3,
was filtered
was concentrated
column chromatography v/v).
to dryness
281.1164, NH),
found 8.56
C(4)-C(7)H).
281.1163. (s,
5.64
lH,
C(3’)H
probably
266 (sh),
([Ml+,
4%).
281
C1‘HirN,O~ 297.1113,
‘H-NMR (90 MHz, d’-DMSO),
indole
(B part
lH, C=CHAHB, 3.91
N-CHr), proton
for
to give
which was homo-
236 nm. EIMS (70 eV) m/e=297 mass calcd.
an
(M~OH/CHIC~Z,
(MeOH) &x=314,
W
in
and the
C(2)H),
8.30-8.00
of AB spectrum,
(s,
3H, indole
superimposed
and
lH, C’CHAHB),
N-CHr),
by solvent
3.14
picks
(s, (Hz0
d’-DMSO 2.5-2.7).
N-Methyl-indole-3-carboxylic of
A solution
crude
above
was treated
acid
(26a)
22 (0 .OB mmol , 23 mg) in THF (5 ml) prepared with
1N aqueous
After
24 hrs the reaction
vents
were
layer
was washed with water,
evaporated
mixture
and the
NaOH solution
was treated
residue
brine,
and dried
in ethyl (NarSO.).
(lit.”
(MeOH/CH,Clr,
243
(sh),
Rf 0.28
215 run; Amin=
run.
ml)
at
as described
room temperature.
with NH&Cl. Subsequently,
which was crystallized
205-206’C);
(2
dissolved
vent gave 13 mg of 26a (93X), 286,
room temperature
DDQHr. Flash
100%); exact
of AB spectrum),
3H, piperaxine
at
mixture
The filtrate
281,
158 ([Ci,H,NO];,
(s(br),
72 hrs
(MeOH/CH,Clr, 7/93,
203 NO; Xmin
4X),
([n-01+,
with
for
The reaction
amount of pure 22 as an amorphous solid
Rf 0.20
208 (sh),
nrmol, 185 mg) in dry THF (10 ml) was added
stirring
NarCO, was added.
22 which was contaminated geneous on tic;
19 (0.6
After
mmol, 110 qg).
DDQ (0.5
Evaporation
v/v).
the sol-
The organic of
from MeOH, m.p.
6/94,
EIMS (70
acetate.
the sol-
199-203
oc
(MeOH) Xmax298 (sh),
W
eV) m/e=175
([Ml’,
loo%),
158
mass calcd. for CIDHINO~ 175.0633, found 175.0635. 79%), exact ‘H-NMR (60 MHz, CDCl,), 6=8.3-0.1 and 7.5-7.2 (m, 4H, indole C(4)-C(7)H), 7.84
([CI,HINC]+, (s,
lH, indole
Methyl
c(~)H),
(s,
3H, indole
(N-methylindole)-3-carboxylate
A solution
of
crude
above was treated ture.
3.86
After
the solvents matography
22 (0.11
with
24 hrs the (CH,Cl,)
(26b)
mmol, 33 mg)
a 1N solution reaction
were evaporated
N-CHr).
of
in THF (5 ml) prepared
mixture
was treated
and the residue
with
was subjected
NHbCl. Subsequently, to flash
26b (91%) as a foam which was homogeneous on tic;
189.0790,
found
189.0790.
C(4)-C(7)H),
N-CH, and CQCCH,).
column chro-
gave 20 qg of Rf 0.71
(MeOH/CHrClr, 6/94.
W (MeOH) Xmax287 (sh), 226 (sh), 214 nm; Xmin=258 nm. v/v). m/e=189 ([Ml’, 90%), 158 ([CI,H,NO]*. 100%). exact mass calcd.
4H, indole
as described
NaOMe in MeOH (1 ml) at room tempera-
‘H-NMR (90 MHx, CDClr), 7.69
(s,
lH, indole
c(z)H),
6r8.10-7.90 3.78
EIMS (70 eV) for CllHr~0rN
and 7.40-7.00
and 3.76
(2s,
(m,
6H, indol
R. PLAIT et al.
6518
REFERENCES 1. For recent
reviews
on Sporidesmfns: see: a. Mortimer, P.H.,
Ronalson.
in Plant and Fuagal Toxins, Randbook of Natural Toxins 1, Keeler, A.T;
U. Dekker,
Eds.,
New York,
Hetabolftes, Cole,
R.J.:
569;
R.;
c.
Naragajan,
Purification; Betina,
Cox,
1983, p.
R.H.;
Eds.,
in lycotoxins V.;
Ed.;
361.
b.
J.W.
R.F.;
Tu,
Bavdbook of Toxic Fuogal
Academic
Press,
London,
1981.
p.
Production, Isolation, Separation and
Elsevier
Siences
Pub.,
Amsterdam,
1904, p.
351. 2. Total
syntheses
a. Kishi,
of Sporidesein A and B have been described:
Nakatsuka,
S.; Fukujama, T.;
Havel,
M. J. Am. Chem. Sot.
Nakatsuka,
S.;
Kishi,
Y. Tetrahedron Lett.
syntheses
of
Fukujama, T.; other
members of
the
73, 95,
1974, 1549.
group have
Sporidesmin
Y.;
6493.
not
b.
Total
yet
been
reported. 3. Kirby,
Robins,
G.H.;
in The Biosynthesis of Hycotoxins, A Study in Sec-
D.J.
ondary Ratabolisa; Steyn, P.S.; and references 4. Kirby,
cited
G.W.; Varley,
5. Sammes, P.G. tar,
L.;
Ed.,
Academic
Press,
London,
1980,
320
1974, 633.
M.J. J. Chea. Sot. Cbem. Coamun.
in The Cheafstry of Organic Natural Products Vol.
Herz,
p.
therein.
W.;
Grisabach,
H.;
Kirby,
G.W.;
Eds..
32, Zechmeis-
Springer
Verlag,
Wien,
1975, p. 51. 6. Another
possible
involve
mechanism explaining
hydroxylation
hydroxylation
of
B-hydroxylation
of
type,
see ref.
7. Randbook of Toxic Fungal Uetabolites, Cole,
R.J.;
Cox,
London,
8. Yamasaki, Press, heijm,
M. in:
R.;
10. Plate,
a direct
R.H; Eds.,
Academic
The Biosynthesis of Rycotoxins, Steyn, P.S.;
Ed.,
Academic
1980, p. 206.
J.D.M.;
H.C.J.
or
3.
1981, p. 849.
London,
9. Herscheid.
1 and 2 might
derivative
of the mono-oxygenase
Press,
reaction
the
an o,B-dehydrotryptophan
Nivard,
R.J.F.;
Tijhuis,
M.U.;
Scholten,
1980, 45, 1885 and references
J. Org. Chem.
Akkerman, M.A.J.,
Smits,
J.M.H.;
H.P.H.; cited
Ottenheijm.
Otten-
therein.
H.J.C.
manuscript
submitted. 11. The
synthesis
sluggish
hedron 1963, 26,
terreus,
natural
N-hydroxytryptophan Shimizu,
S.;
Moreover,
J.D.;
may play
tryptophan;
a
Haeflinger,
an important
product K.; Yammoto,
the
relevant
acid,
a very
H.J.
Tetra-
Dimsdale.
has
been
(e.g. 9.;
1981, p.
proposed
Conn,
K.; Oikewa,
Mohri,
isolated
as
Y.;
E.E.;
1981, 29,
an intermediate
Knowles, 0.
contains
K.; Sate.
Arai.
G.J.;
197 and references Yonemitsu,
pathways Aspergillus
which
structure:
Clucobrassicfns), M6ller,
ide in Bfology; Vennesland, London,
in the biosynthetic
Y. Chen. Pherm. Bull.
Eds.,
Academic Press,
role
a dipeptide
of glucosinolates
T.;
W.E.;
been
has
of
N-hydroxytryptophan
13. Yoshioka,
of
perbenzoic
Astechrome, a metabolite from
with
as part
Nitta,
biosynthesis
treatment
with metachloro
233.
12. N-Hydroxytryptophan with
involves
derivative
see White,
reaction,
starting
5a
for
reported
a,B-dehydro-phenylalanine
cited
B.L.
S.; 1510.
in
the
in Cyen-
Westley,
J.;
therein.
J. Chea. Res.
1981,
194. 14. Tijhuis,
M.W.; Herscheid,
J.D.M.;
15. Fioriti,
J.A.;
J. Chromatopr.
Sims, R.J.
16. Unfortunatly,
the epoxide
Ottenheijm,
B-proton
H.C.J.
Synthesis 1980, 890.
1968. 32, 761.
of 22 is hidden behind
the signals
due to
solvents. 17.
[M-16]+.
15X, exact
18. Mohammed, Y.S.; 19. Arx,
E. von;
Faupel,
20. “Anfaerbereagantien Merck, 21. Plate,
R.;
22. Ottenheijm, Chem. 23. Millich,
Bruggen,
F.R.G.,
Hermkens, 51,
[CisHisN~Os]*
die
281.1164;
1963,
M. J. Chromatogr.
Papier-
found 281,1163.
1953. 1976, 120. 224.
und Duennschichtchromatographie”,
Fa.
1970.
P.H.H.;
Smits,
J.M.M.;
Ottenheijm,
H.C.J.
1. Org.
J.D.M.
J. Org.
301.
H.C.J.;
1982, 47, F.;
H.;
for
M..Tetrahedron Lett.
fuer
Darmstadt,
Chem, 1986,
mass calcd.
Luckner,
Plate,
R.;
Noordik,
J.H.;
J. Org. Cher.
19%.
Herscheid,
2147.
Becker,
E.I.
23,
1096.
A BILBlIcEIIC
-/sb 55.00+.00 0 WlW~JO~LId.
APPROACH TO SWRIMSMINS. SYNTHESIS OF AN a.8-EPOXYTRYPTOPHANDERIVATIVE
RALF PLATE,
ANNETTE Y.G.
THEWISSE,
RUTGER J.F.
NIVARfl AMI HARRYC.J.
OTTENiELW Department of Organic Toernooiveld,
Chemistry,
University
6525 ED Nijmegen,
(Received in UK 24
Nijmegen,
of
The Netherlands
September 1986)
from 16 Abstract: The reaction of 19 - prepared efficiently with DDQ affords 22. This epoxide may serve as a model compound to investigate the biosynthesis of spridesains, e.g. 1 and 2.
INTRCXIUCTION The sporidesmins turing
a-
causing
make up a group of naturally
0,s ‘-substituted
or
facial
exxema in
which
charterurn liara,s.
occurs A (1)
from the
amino acids
peripheral
changes
that
the N-methyl
delivered
either
the
the
tryptophan must have
groups steps
skeleton
sis
of
place
us with the
introduced
the
tem might
yield
nucleophile This
retention
intriguing
Sammes' , who invoked
2’.
to
would create scheme is
mould qetabolites,
loss
he concluded with
e.g.
of
intermediacy the 5a.b’
groups
1 R’rCI,R2=OMc
series
of the
sulfur
concerning
atoms are
have not been
the
remain obscure.
at C(B) at this
introduction
Kirby’
experiments
pathway
di-epoxide 3;
a-mercapto-B-hydroxy by the following
6511
has
of
tryptophan
considerations.
studied the spo-
involving
C(S)
in the biosythecarbon
atom. This
been
attack
is by
This sys-
by a sulfur
moieties Firstly,
amino acid
group
provided
4 (Scheme I).
subsequent
have an a,B-epoxy
F
of
demonstrated
in the hydroxylation
likely
lx SPORIOESMIN
have
by what mechanism the hydroxyl
R’.OMe SWRIDE!SMIN A
1b.c ,
derivation
an extensive and the
hydroxylation
SCHEMEI
R’.CI,
sporidesmins
to the sporidesmins
details
mono-epoxide
and 6’
Pithomycas and Austra-
a biosynthetic
configuration
question
the
the
fea-
principle
fungus
studies
From labeling that
active
or methionine’.
involved
The most
supported
of
from methionine
two hydroxyl
the
although,
cysteine
metabolites
the
New Zealand
suggests
from tryptophan
hydrogen
fros of
Labeling
In particular,
biosynthetically. react
place.
at the B-position.
derivatives
1 takes
leaves
F (2),
and alaniner, taken
leading
of
areas
structures
are derived
atoms and the
stereochemistry
‘H-labeled
the
and sporidesmin
in any detail.
sulfur
ridesmin
of
pasture
fungsl
They are
and were obtained
certain
by sodium sulfate,
The metabolic investigated of
sheep
in
Consideration
e.g. sporidesmin
ocurring,
dioxopiperaxines.
of
1 or
several
moiety
as a
6512
R. PLME et al,
structural
feature.
well-documented in another oxidative
Secondly,
the conversion
mechanism proposed
synthetic ring
approach
closure
cf.
posed
intermediacy
to
the
4+3 has a close
the biosynthesis sporidesmins,
based on the conversion
Here we wish to report tive,
for
the first
10 (Scheme II). of 3 and
to the Thirdly,
we employed successfully
an
of 4+3i’.
synthesis
of an a,S-epoxy
This
synthesis
4
the biosynthesis
in
resemblance
of gliotoxin’.
provides
further
tryptophan support
to
derivathe pro-
of the sporidesmins’.
4-R koJqpfp 0 l
d
:R= H
b: Rz 044 CYCLOPENOL
STRATEGY
Compound 10 was selected i.e.:
and 4.
3
epoxidation
This
explored
of
the
(Scheme
for
not
the putative
directly
sporidesmin
accessible
o,S-dehydrotryptophan
indole
nucleus.
II).
Initially
C
EPOXY -FUMlTREMOROIN
as a model
compound is
of the corresponding
the presence
Me
Me
CYCLOPENIN
Therefore, we
via
precursors,
straightforward
derivative”,
two alternative the
studied
because approaches
S-oxidation
of
of were an
SCHEME II
N-hydroxytryptophan might
yield
approach
the
failed
derivative sion
(vi&
11 (route
9,
B).
which
Oxidation of
A, 7+8).
should
we first
fnfra),
by the intermediacy
Route
(route
derivative” acylimine
Subsequent
yield
prepared
gave indeed
the
elimination
a,[)-epoxide
the a-functionalized 10; we rationalize
of RX-OH
16.
As this
tryptophan this
conver-
12.
A
S-Oxydation
of an N-hydroxytryptophan
derivative
(cf.
7+8)
was studied
using
SCHEME III
NHR’ 3.-
Lj
,- a: R’.R2=R3=H b: R’.R’=Mc;
R’.H
c: R’=R’=H;
R3.CH2CsH~
d: R’ =R2.Mc the
oxime
as an oxidizing thy1 C=N
derivative bond
attempts a
III)
13 (Scheme
13~ - prepared
of
reagent
and the dioxopiperazine 16 (Scheme IV). Treatment of - with DDQ in aqueous tetrahydrofuran”
from 13a by 0-benxylation agent afforded or
14d had
Treatment introduced
of by
2,3-dihydrotryptophan
derivative
soned
of
that
the R-keto
14d was obtained 14c
failed.
; R3=CH2C6H5
reduction
derivative
analogously to
be
14d with us
reduced
14~
from 13d. selectively.
in 89% yield.
The dime-
Subsequently,
the
Unfortunately,
oxime
all
the trimethylamine borohydride complex the gave related reductions” for
15 in 53% yield.
the oxima had to preceed
Having observed
this
the
Accordingly,
B-oxidation.
we rea-
6513
A biomimctic approach to sporidcsmins the next compound we. studied an untractable
ever,
(Scheme IV).
was 16”
reaction
mixture.
Treatment with DDQ gave,
We ascribe
this
failure
bar-
to the high acid-
!? ity
of the a-proton
of
17 facilitating
the elimination
of benzyl
alcohol.
Route B On the basis
of the above findings
out subsequent
we felt
invariably
lead
to elimination
the proper
oxidation
state.
that
reactions
bef,ore
Accordingly,
the
of 16 with sodium methoxide
of
DDQ in aqueous TRP yielded
20
(30%)
reduce
again and
the a-hydroxy
the B-carbonyl
group
order
the B-carbon
a mixture
19
of
a hydroxy
into
(56%).
steps
18 was pre-
(Scheme V).
of
Oxidation
the desired
Unfortunately, group
would
would have reached
derivative
in methanol
derivative Xl
had to be carried
of reaction
a-•ethoxy
pared by treatment 18 using
S-oxidation
the reverse
to a-functionalization
compound
attempts
failed.
Possibly
to the
SCHEME V 0M.O
16 -
presence
&J?
of an a-NH-proton
Having observed rupted
as
soon
this
as the
B-carbon
alcohol.
We reasoned
12+lD)
might be possible
approach was found When the
precludes
failure, that
in
trapping
to
from an a-hydroxy
has to be inter-
state yield
of
a secondary
an epoxide
derivative,
vfz.
(viz.
11. This
indeed.
by
treated
a molar equivalent
to which we assigned
the oxidation
derivative
(83% yield) with
that the oxidation
atom is
star::ng
treatment
conversion.
intramolecular
to be viable
a-hydroxy
this
we realized
19 - prepared
with
aqueous of
structure
from 18 (95% yield)
sodium
hydroxide,
DDQ in tetrahydrofuran
22 on basis
or
from 16
respectively a product
of the following
-
was
was formed
observations
(Scheme
SCHEME VI
VI).
Firstly,
idesr’
-
upon spraying
a positive
pounds reported
(red)
pared
to
spectrum
the spectrum
it
decomposes
derivative hydroxide qetboxide products tion
not
22 is slowly
been
for
an unstable to
the ester
can be rationalized
sodium hydroxider’.
to
loss
feature
26b
22
opening
of
of
(Scheme VII).
by the formation
is
ppm) as impact
26a,
of 5a and 5b’.
formed quantitatively silica
gel.
Treatment
of benxoic
acid
of
with
sodium
with sodium
these
This type
So far
amino acid
and reaction
The formation
in Scheme VII.
com-
mass
from the molecular e.g.
using
epoxide.
com-
‘Ii-NMR spectrum
an o,B-difunctionalized the
epox-
(Lk8.56
oxygen it
for other
electron
of epoxides,
gave the acid
as depicted
the
conditions
into
the
C(2)-proton Thirdly,
the
indicative whereas all
Secondly,
compound; whereas
convert ring
test.
indole
under chromarographic
able
- a reagent
was observed,
ppm)“.
is a typical
by nucleophilic
is precedented
the
19 (6~6.87
or sodium methylmercaptide gave
acid
in this
corresponding
fragmentation
The epoxide we have
shift
of
showed an ion
this
ionI’,
picric reaction
here were negative
22 showed a downfield
of
with
colour
degradation of
fragmenm
from 5a upon treatment
with
A biomimctic approach to sporidcsmins
and with brine,
and subsaquently dried (NaeSO.). The residue obtained by evapo-
ration of
the solvent was subjectad
giva
mg
of
W
(N&H)
280
Kw&).
13c
(91%);
to
r..p.
Am,=286,
flash column chromatography (CHsClr) to
120-122
‘C
(CH&lr/n-buana),
255 m.
222 nm; Amin
tic
Rf
0.2
EIMS (70 eV) m/e-S07 ([M]',
25X), 171 (15%). 155 (50%). 130
5%). 216 ([If-CHaC.Hs]*,St), 200 ([M-OCH&.]*,
(IGHeN]+, 55%). exact mass calcd. for C~eHrrNsOs 307.1321, found 307.1325. ~H-NMR (60 MHE, CDCl,), b=8.2 (s(br), lli, indole NH), 7.6-6.9 (m, 5H, indolec(2), C(4)-C(7)H), 7.3 (s. SH, CeHs), 6.5 (s(br), 2H 0X&),
5.15 (s, 2H, CCHs),
4.0 (s, 2H. indole C(3)-WI). 1-[(E)-Benzyloximtno]-2-(HnethylIndol-3-yl)N~thylpropan~lde A solution of benxyl bromide (2.2 -1,
(13d)
380 mg) in dimethoxyethane (10 ml) was
added dropwisc to a stirred solution of 13b"
(2 ssnol, 490 mg) and potassium
terf.-butoxide (2.2 m~ol, 250 mg) in dimethoxyethane (20 ml) at room temperature and in an argon atmosphere. Stirring was continued for 3 hrs.
Then the solvent
was removed in vacua. A solution of the residue in CHrClz was washed with 1N HCl and with brine, and subsequently dried (NasSO.). Evaporation of the solvent and flash column chromatography
(CHrCls) of the residue gave 640 mg of 13d (96%);
m.p. 64-65.5 'C (CHsClr/n-hexane), tic Rf 0.2 (CHsClr).
W
(MeOH) Xmax=286, 228
nm; xmin. 256 nm. EIMS (70 eV) m/e=335 ([Ml', 27X), 228 ([CIIH:.NIO]*, loo%), 47X), 144 171 ([CIIHI~NZ]+, 94%), 170 ([CrrH11Nr]+, 33X), 169 ([C~dWzl+, ([ClrH~rNl*, 80%); exact mass calcd. for C 1,H rrN ,0 r 335.1634, found 335.1628. 'H-NMR (90 MHz, CDCl,), 6=7.71-6.88 (m, SH, indole C(2), C(4)-C(7)H), 7.34 (6, 5H, CIHs). 6.7 (m, lH, CHrNH), 5.21 (6, 2H, OClIr), 4.02 (s, 2H, C(3)-CHs), 3.64 (s, 3H, indole NCHI), 2.76 (d, '5~5 Hz, 3H. CH,NH). l-[(E)-Benzyloximino]-P-(lndol-3-yl)-2-oxo-propanamide TO a solution of 13c (0.2
indole
(14~)
mmol. 63 mg) in THF/HsO (9/l, v/v, 5 ml) was added DDD
(0.4 mmol. 91 mg). After stirring for 2 hrs the solvents were evaporated and CHrCls was added to the residue. The suspension was filtered and the filtrate was washed, dried (NarSO,) and the solvent evaporated.
Flash column chromatog-
raphy (MeOH/CHrClr. 4196, v/v) gave 57 mg of 14~ (89%) as an oil which was homogeneous on tic Rf 0.16 (MeOH/CHrClr, 6/94, 236
(sh).
204
(LC,HrNO]*,
nm;
100X),
lmin.
277
ND.
91 (IC,HTI’,
V/V).
EIMS 100%);
W
(70 eV) exact
(MeOH) Imax=305, 260 (sh), m/e=321
mass
([Ml+, 28%),
calcd.
for
144
ClrHlrNaOr
321.1113, found 321.1110. IH-NMR (60 MHz, CDCl~), 6=9.7 (s(br), lH, indole NH), 8.2-7.9 and 7.3-6.9 (m, SH, indole c(~)H, C(4)-C(7)H), 7.10 (6, SH, CeHr), 6.4 and 6.0 (s(br), 2H, NH,), 4.93 (s, 2H, ~cH,). (14d)
l-(Benzyloximino)-2-(N-methylindol-3-yl)-2-oxo-N-~t~lpro~n~ide To a solution of 13d (1.7 -1,
575 mg) in THF/HrO (9/l, v/v, 10 ml) was added
DDQ (3.5 mmol, 779 mg). After stirring for 3 hrs the solvents were evaporated and CHrClr was added to the residue.
The suspension was filtered and the fil-
trate was washed, dried (NarSO,) and the solvent evaporated. Flash column chromatography gave 451 mg of 14d (76%) as an oil which was homogeneous on tic Rf 0.48 (MeOH/CHrClr, 6/94, v/v). 280, 234 nm. EIMS
([CIHTI+,
45%);
W
(MeOH) Xmax=312, 266 (sh), 246, 208 nm; Xmin.
(70 eV) m/e=349
exact mass
calcd.
([Ml', 22%),
158 ([C~IHINO]*, lOO%), 91
for IZ~~HL.N~O, 349.1426,
found 349.1419.
'H-NMR (60 MHz, CDC~X), 6=8.3-8.1 and 7.4-7.1 (m, SH, indole C(2)H. C(4)-C(7)H), 7.3 (s, SH, C&H,), 6.7 (m, lH, NH-CHr), 5.16 (s, 2H, OCHI), 3.69 (s, 3H, indole N-CH,), 2.84 (d, '515 Hz, 3H, NHCH,). l-(Benzyloxaraino)-2-(N-methylIndolin-3-yl)-N-~thylpropllnami~ To a solution of 14d (0.5 mmol, 175 mg) and HerN*BHr"
(15) (1 mol,
80 qg) in etha-
nol (5 ml) a solution of HCI in ethanol (5 ml of a 7N solution) was added dropwise at room temperature in an argon atmosphere.
After stirring the reaction mixture for 24 hrs another 4 equivalent of MerN*BH, (2 -01, 160 qg) were added.
After 4 days the solvent was
evaporated. Then
the residue was dissolved
in
CHsCls and the resulting solution was washed with O.lN NaOH, dried (NasSO.) and
R. PLATSet al.
6516
filtered. Evaporation of the solvent gave a residue which was subjected to flash column chromatography
(CHrClr) to give 90 mg of 15 (53%) as an oil which was
homogeneous on tic Rf 0.25 (MeOH/CHzClr. 4/96,
W
v/v).
(HeOH) Xm6288.
224 (sh), 204 nm; lmin . 276, 237 nm. EIMS (70 eV) m/e=339 (]CirHirN,Ul+, 25x),
144 ([C,,HION]*.
62X),
132
([C,HIDN]*),
133
for CI.H.SNIO, 91 ([C~HIJ+, 46%); exact mass calcd. 339.1947. 'H-NHR (60 MHZ, CDCl,), 6=7.2 (6. 5H, MIS), 7.2-6.2 6.1
(m,
1H. Nl+CHr), 4.6
3.4-2.5 (m, 5H, indoline c(2)H 2, c(3)H. 3H,
indoline
(26x1,
339.1945,
(41%))
c(4)-c(7)H).
248,
([Ii]', 17%). 215
(m,
4H,
131
found
i.ndolioo
(8, 2H, OCM,), 3.7-3.5 (m. lH, C(e)M), and c@)H),
2.7
(d,
3H.
NHCH,),
2.6
(s.
(dry,
150
ml)
N-CH,).
l-Methyl-3-methoxy-3-[(N-raethylindol-3-yl)methyl]-6-methylenepiperazine-2.5dione To
(18) a stirred
was added
solution
potassium
of
16l’
tart-butoxyde
(1.14 (320
g,
2.9
sxuol)
qg, 2.9 ml)
in
methanol
at room temperature. After
stirring for 4 days at room temperature the mixture was neutralized by adding ammonium chloride (0.160 g). Stirring was continued for 17 hrs, where after the solvent was evaporated in vacua. Dichloromethane was added to the residue and the suspended salts were filtered off. The filtrate was concentrated to dryness to yield an oil which consisted of 20 and benzyl alcohol. Column chromatography (CHrCl,/MeOH, 98/2, v/v) gave 735 mg of 20 (81%), which was crystallised CHrClr/n-hexane:
m.p.
172-173
'C;
tic
Rf
0.35
(solvent
system
(methanol) Xmax=218, 255 (sh). 284, 296 (sh) nm; lmin=281 nm. m/e=313
from
II).
EIMS
([Ml+, l%), 281 ([CLCHI~N~O~]+, lo%), 144 ([CioHI~N]+, 100%).
UV
(70 eV) exact
mass calcd. for Ci,HirNrO, m/e 313.1426, found 313.1423. 'H-NMR (90 MHz, CDCl,), 67.65-7.0 (m, 4H, indole C(4)-C(7)H), 6.91 (s, lH, indole C(2)H), 6.26 (m, lH, NH), 5.57 (B part of AB spectrum, lH, 'JAB=1.5 Hz, C=CHBHA), 4.59 (A part of AB spectrum, lH, *JAB=1.5 Hz, C=CHAHB), 3.74 (s, 3H, indole N-CHr), (B part of AB spectrum, lH, 'JAB=14.5 Hz, indole C(3)-CHAHB), 3.35 (A part of AB spectrum, lH, 'JAB=14.5 Hz. indole C(3)-CHAHB), 3.27 (s, 3H, C(3)CCHr), 2.98 (s, 3H, piperazinc N-CH,). l~thyl-3-hydroxy-3-[(N-methylindol-3-yl)methyl]-6-rsethylenepiperazlne-2.5-
dlone
(19)
From 16: To a stirred 0.5N
solution
of
16l’
(3.2
rmuol,
1.24
g)
in dimethoxyethane
(60
ml)
NaOH (40 ml) was added at room temperature in an argon atmosphere. After 4
days the reaction mixture was treated with NH.Cl. Then the solvent was evaporated, the residue was partitioned between water and CHrClr. The organic layer was dried and the solvent evaporated. Recrystallization (CHrCl,/n-hexane) gave 0.79 g of 19 (83%), m.p. 163-165 'C. Rf 0.24 (MeOH/CHrClr, 7/93, v/v). UV (MeOH) 1,,=296 3X), 281
(sh), 284, 252 (sh), 221 nm; Xmin
280 nm. EIMS (70 eV) m/e=299 ([Ml+,
(ICIC~ISN~~ZI+, 6%). 144 ([C~DH;,N]+, 100%); exact mass calcd. for
C1~H1,N,OI 299.1270, found 299.1263. iH-NMR (90 MHz, CDClr), 6=7.50-6.90 (m, 4H, indole C(4)-C(7)H), 6.87 (s. lH, indole C(2)H), 6.80 (s(br), lH, piperazine NH), 5.37 (B part of AB spectrum, 'JAB=2 Hz. lH, =CHAHB), 4.44 (A part of AB spectrum, 'JAB=2 Hz, lH, =CHAHB), 4.30 (s(br), lH, OH), 3.71 (s, 3H, indol N-CHI), 3.50 (B part of AB spectrum, 'JAB=14 Hz, lH, CHAHB), 3.30 (A part of AB spectrum, 'JAB=14 Hz, lH, CHAHB, 2.78 (s, 3H, piperazine N-CHI). To a solution of 18 (0.5 mmol, 150
From 18:
qg) in THF/HrO (9/l, v/v, 10 ml) was added
1N NaOH (1 ml) at room temperature in an argon atmosphere. After stirring the reaction mixture for 24 hrs the room temperatrue it was neutralized (NHbCl) and the solvent was evaporated. Usual work-up gave 135 mg (95%) of 19, vhich vas identical with the compound described above. l-Methyl-3-Rethoxy-3-[(Nmethylindol-3-yl)carbonyl]-6-methylenepiperazine-2.5dione
(20)
6511
A biomimetic approach to sporidesmins TO a stirred
solution
was added DDQ (0.5 ture
of 18 (0.25
in an argon atmosphere
the
The
residue.
(NatSO.) 2/98,
v/v)
(HeOH) Lmex=316,
homogeneous on tic,
268
(sh),
159 (29%).
4X),
207
nm; l,,,in.
found
327.1226.
8.30-8.20
and 7.40-7.20
‘JAB=5 Hz, C=CHAtiB) , 5.00
lH, 3.89
(s.
3H, indole
N-CM,),
282,
(s,
was washed,
nm. EIHS (70 mass calcd.
6=8.47
C(4)-C(7)H), of
dried
(MeOWCHaCl1,
(MaOH/CH,Clr, 6/94. 237
100%); exact
(A part
3.55
and CHrClr was added to
filtrate
0.39
‘H-NMR (90 MHz, CDCI,), (m, 4H, indole
10 ml)
19 (58%).
Rf
158 ([C1,H,NO]+,
327.1219,
v/v,
at room tempera-
column chromatography
gave 25 qg of 20 (30%) and 44 mg of oil,
24 hours
and the
Flash
evaporated.
for
were evaporated
was filtered
solvent
Compound 20: (WI+,
stirring
the solvents
suspension
and the
mmol. 78 mg) in THE/H.0 (9/l,
After
114 qg).
maol,
(6,
5.93
AB spectrum,
3H, OCH,), 3.21
for
lH,
lH,
W
ClrHrrNrCb
indole
(B part
(s,
v/v).
eV) m/e=327 C(2)H),
of AB spectrum,
‘JAB=5 Hr., C’CHAHB,
3H, piperazine
N-CH,).
l-Methyl-2,5-dfoxo-6-methylen-plperazine-3-spiro-3’-(N-methylIndol-3-yl)-2’(22)
oxirane
To a stirred argon
solution
atmosphere
residue
of
2/98,
was washed with v/v)
246,
brine.
gave a small
found 297.1115;
ClrHIIN,O,
6=9.30
lH, piperazine
7.70-7.10 5.11
(m, GH, indole
(A part
6=3.5-3.3,
was filtered
was concentrated
column chromatography v/v).
to dryness
281.1164, NH),
found 8.56
C(4)-C(7)H).
281.1163. (s,
5.64
lH,
C(3’)H
probably
266 (sh),
([Ml+,
4%).
281
C1‘HirN,O~ 297.1113,
‘H-NMR (90 MHz, d’-DMSO),
indole
(B part
lH, C=CHAHB, 3.91
N-CHr), proton
for
to give
which was homo-
236 nm. EIMS (70 eV) m/e=297 mass calcd.
an
(M~OH/CHIC~Z,
(MeOH) &x=314,
W
in
and the
C(2)H),
8.30-8.00
of AB spectrum,
(s,
3H, indole
superimposed
and
lH, C’CHAHB),
N-CHr),
by solvent
3.14
picks
(s, (Hz0
d’-DMSO 2.5-2.7).
N-Methyl-indole-3-carboxylic of
A solution
crude
above
was treated
acid
(26a)
22 (0 .OB mmol , 23 mg) in THF (5 ml) prepared with
1N aqueous
After
24 hrs the reaction
vents
were
layer
was washed with water,
evaporated
mixture
and the
NaOH solution
was treated
residue
brine,
and dried
in ethyl (NarSO.).
(lit.”
(MeOH/CH,Clr,
243
(sh),
Rf 0.28
215 run; Amin=
run.
ml)
at
as described
room temperature.
with NH&Cl. Subsequently,
which was crystallized
205-206’C);
(2
dissolved
vent gave 13 mg of 26a (93X), 286,
room temperature
DDQHr. Flash
100%); exact
of AB spectrum),
3H, piperaxine
at
mixture
The filtrate
281,
158 ([Ci,H,NO];,
(s(br),
72 hrs
(MeOH/CH,Clr, 7/93,
203 NO; Xmin
4X),
([n-01+,
with
for
The reaction
amount of pure 22 as an amorphous solid
Rf 0.20
208 (sh),
nrmol, 185 mg) in dry THF (10 ml) was added
stirring
NarCO, was added.
22 which was contaminated geneous on tic;
19 (0.6
After
mmol, 110 qg).
DDQ (0.5
Evaporation
v/v).
the sol-
The organic of
from MeOH, m.p.
6/94,
EIMS (70
acetate.
the sol-
199-203
oc
(MeOH) Xmax298 (sh),
W
eV) m/e=175
([Ml’,
loo%),
158
mass calcd. for CIDHINO~ 175.0633, found 175.0635. 79%), exact ‘H-NMR (60 MHz, CDCl,), 6=8.3-0.1 and 7.5-7.2 (m, 4H, indole C(4)-C(7)H), 7.84
([CI,HINC]+, (s,
lH, indole
Methyl
c(~)H),
(s,
3H, indole
(N-methylindole)-3-carboxylate
A solution
of
crude
above was treated ture.
3.86
After
the solvents matography
22 (0.11
with
24 hrs the (CH,Cl,)
(26b)
mmol, 33 mg)
a 1N solution reaction
were evaporated
N-CHr).
of
in THF (5 ml) prepared
mixture
was treated
and the residue
with
was subjected
NHbCl. Subsequently, to flash
26b (91%) as a foam which was homogeneous on tic;
189.0790,
found
189.0790.
C(4)-C(7)H),
N-CH, and CQCCH,).
column chro-
gave 20 qg of Rf 0.71
(MeOH/CHrClr, 6/94.
W (MeOH) Xmax287 (sh), 226 (sh), 214 nm; Xmin=258 nm. v/v). m/e=189 ([Ml’, 90%), 158 ([CI,H,NO]*. 100%). exact mass calcd.
4H, indole
as described
NaOMe in MeOH (1 ml) at room tempera-
‘H-NMR (90 MHx, CDClr), 7.69
(s,
lH, indole
c(z)H),
6r8.10-7.90 3.78
EIMS (70 eV) for CllHr~0rN
and 7.40-7.00
and 3.76
(2s,
(m,
6H, indol
R. PLAIT et al.
6518
REFERENCES 1. For recent
reviews
on Sporidesmfns: see: a. Mortimer, P.H.,
Ronalson.
in Plant and Fuagal Toxins, Randbook of Natural Toxins 1, Keeler, A.T;
U. Dekker,
Eds.,
New York,
Hetabolftes, Cole,
R.J.:
569;
R.;
c.
Naragajan,
Purification; Betina,
Cox,
1983, p.
R.H.;
Eds.,
in lycotoxins V.;
Ed.;
361.
b.
J.W.
R.F.;
Tu,
Bavdbook of Toxic Fuogal
Academic
Press,
London,
1981.
p.
Production, Isolation, Separation and
Elsevier
Siences
Pub.,
Amsterdam,
1904, p.
351. 2. Total
syntheses
a. Kishi,
of Sporidesein A and B have been described:
Nakatsuka,
S.; Fukujama, T.;
Havel,
M. J. Am. Chem. Sot.
Nakatsuka,
S.;
Kishi,
Y. Tetrahedron Lett.
syntheses
of
Fukujama, T.; other
members of
the
73, 95,
1974, 1549.
group have
Sporidesmin
Y.;
6493.
not
b.
Total
yet
been
reported. 3. Kirby,
Robins,
G.H.;
in The Biosynthesis of Hycotoxins, A Study in Sec-
D.J.
ondary Ratabolisa; Steyn, P.S.; and references 4. Kirby,
cited
G.W.; Varley,
5. Sammes, P.G. tar,
L.;
Ed.,
Academic
Press,
London,
1980,
320
1974, 633.
M.J. J. Chea. Sot. Cbem. Coamun.
in The Cheafstry of Organic Natural Products Vol.
Herz,
p.
therein.
W.;
Grisabach,
H.;
Kirby,
G.W.;
Eds..
32, Zechmeis-
Springer
Verlag,
Wien,
1975, p. 51. 6. Another
possible
involve
mechanism explaining
hydroxylation
hydroxylation
of
B-hydroxylation
of
type,
see ref.
7. Randbook of Toxic Fungal Uetabolites, Cole,
R.J.;
Cox,
London,
8. Yamasaki, Press, heijm,
M. in:
R.;
10. Plate,
a direct
R.H; Eds.,
Academic
The Biosynthesis of Rycotoxins, Steyn, P.S.;
Ed.,
Academic
1980, p. 206.
J.D.M.;
H.C.J.
or
3.
1981, p. 849.
London,
9. Herscheid.
1 and 2 might
derivative
of the mono-oxygenase
Press,
reaction
the
an o,B-dehydrotryptophan
Nivard,
R.J.F.;
Tijhuis,
M.U.;
Scholten,
1980, 45, 1885 and references
J. Org. Chem.
Akkerman, M.A.J.,
Smits,
J.M.H.;
H.P.H.; cited
Ottenheijm.
Otten-
therein.
H.J.C.
manuscript
submitted. 11. The
synthesis
sluggish
hedron 1963, 26,
terreus,
natural
N-hydroxytryptophan Shimizu,
S.;
Moreover,
J.D.;
may play
tryptophan;
a
Haeflinger,
an important
product K.; Yammoto,
the
relevant
acid,
a very
H.J.
Tetra-
Dimsdale.
has
been
(e.g. 9.;
1981, p.
proposed
Conn,
K.; Oikewa,
Mohri,
isolated
as
Y.;
E.E.;
1981, 29,
an intermediate
Knowles, 0.
contains
K.; Sate.
Arai.
G.J.;
197 and references Yonemitsu,
pathways Aspergillus
which
structure:
Clucobrassicfns), M6ller,
ide in Bfology; Vennesland, London,
in the biosynthetic
Y. Chen. Pherm. Bull.
Eds.,
Academic Press,
role
a dipeptide
of glucosinolates
T.;
W.E.;
been
has
of
N-hydroxytryptophan
13. Yoshioka,
of
perbenzoic
Astechrome, a metabolite from
with
as part
Nitta,
biosynthesis
treatment
with metachloro
233.
12. N-Hydroxytryptophan with
involves
derivative
see White,
reaction,
starting
5a
for
reported
a,B-dehydro-phenylalanine
cited
B.L.
S.; 1510.
in
the
in Cyen-
Westley,
J.;
therein.
J. Chea. Res.
1981,
194. 14. Tijhuis,
M.W.; Herscheid,
J.D.M.;
15. Fioriti,
J.A.;
J. Chromatopr.
Sims, R.J.
16. Unfortunatly,
the epoxide
Ottenheijm,
B-proton
H.C.J.
Synthesis 1980, 890.
1968. 32, 761.
of 22 is hidden behind
the signals
due to
solvents. 17.
[M-16]+.
15X, exact
18. Mohammed, Y.S.; 19. Arx,
E. von;
Faupel,
20. “Anfaerbereagantien Merck, 21. Plate,
R.;
22. Ottenheijm, Chem. 23. Millich,
Bruggen,
F.R.G.,
Hermkens, 51,
[CisHisN~Os]*
die
281.1164;
1963,
M. J. Chromatogr.
Papier-
found 281,1163.
1953. 1976, 120. 224.
und Duennschichtchromatographie”,
Fa.
1970.
P.H.H.;
Smits,
J.M.M.;
Ottenheijm,
H.C.J.
1. Org.
J.D.M.
J. Org.
301.
H.C.J.;
1982, 47, F.;
H.;
for
M..Tetrahedron Lett.
fuer
Darmstadt,
Chem, 1986,
mass calcd.
Luckner,
Plate,
R.;
Noordik,
J.H.;
J. Org. Cher.
19%.
Herscheid,
2147.
Becker,
E.I.
23,
1096.