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Synthesis of diaza-anthraquinones by hetero diels-alder cycloaddition reactions
Te~raheah Vol 45, No. 14, pp. 4417 to 4484, 1989 Pnnted m Great Bntam.
tlO4&4020/89 $3.00+.00 0 1989 Mamdl PergamonMacmluaoplc
SYNTHESIS OF DIAZA-ANTHRAQUINONES BY HETERO DIELS-ALDER CYCLOADDITION REACTIONS C.
Gesto, E. de la Cuesta and C. AvendaAo*
Departamento de Quimica Organica y Farmaceutica, Facultad de Farmacia, Universidad Complutense 28040-Madrid, Spain. (Received VI UK 19April 1989)
Abstract- Using 3-methyl-1-dimethylamino-1-azabuta-1,3-diene and 3(tert-butyl dimethylsilyl)oxy-l-dimethylamino-l-azabuta-l,3-diene as 1-azadienes and quinoline-5,8-dione and carbostyrilquinone as dienophiles, several diazaanthraquinones have been obtained. Structure assignments were mainly based on IR spectroscopic data. The accessibility of N-oxidation products has been also investigated. Diazaquinomicin A (DQM, fig.1) has been isolated and characterized by l-3 , as a new neutral antifolate antibiotic, active against Gram-
Omura et al.
positive bacteria. The site of action of DQM was studied and compared with other known synthetic antibacterial and antitumor drugs such as trimethoprim, methotrexate and S-fluorouracil. It was described as a thymidilate synthase inhibitor competitively with 5,10-methylene tetrahydrofolate4. Preparation of derivatives with higher solubility was claimed to be of interest in creating new antitumor drugs. This paper deals with a synthetic approach to DQM analogues by hetero Diels-Alder cycloaddition reactions.
Figure 1 Cycloadditions between azanaphthoquinones and appropriate dienes are efficient and regioselective methods of synthesis of aza-anthraquinones 536 . Regioselective (or regiospecific) cycloadditions of an electron-rich diene with an azanaphthoquinone are controlled by the relative electron deficiencies of the carbonyl groups 6 . As carbostyrilquinone is readily available from 8hydroxyquinoline7, we investigated the reactions of such quinone with l-azadienes, compounds extensively studied by Ghosez and coworkers 899 . In this context, only one example of cycloaddition between carbostyrilquinone and 1,2-dimethylenecyclohexane has been previously reported to give anthracyclin 4477
C. GES~Oet al.
4418
analogues
10
.
The reaction with 3-methyl-1-dimethylamino-1-azabuta-1,3-diene was regioselective and yielded 1, which isomeric purity was corroborated by its 200 MHz 'H-NMR spectrum (Tables 1 and 2). The secondary product 2 is formed by addition of dimethylamine to the,starting quinone according to previously proposed reaction mechanisms for such 1-azadiene'. Structure -2 was confirmed by carrying out the direct addition. In both reactions no addition on the 3,4-double bond of carbostyrilquinone was detected.
HN(CH&
The best results (68% of l_) were obtained under N2 atmosphere and equimolecular proportion of reactants. When the reaction was performed in air and/ or 2 equivalents of the starting quinone were used, the yield of 2 was increased while that of 1 decreased. To confirm structure 1, it was transformed into 2 by treatment with phosphorus oxychloride and this derivative was compared with the two cycloaddition products 4 and 5, obtained from quinoline-5,8-dione and 3-methyl-ldimethylamino-1-azabuta-1,3-diene.
2
4
The last mentioned reaction has been studied by Potts to give the diaza6,11 as the only obtained isomer, but by mod anthraquinone 4 ifying the reactiol conditions, the regioselectivity drops to give up to 12% of _5_(see experimentall.
Synthesisofdiaza-anthraquinones
4479
1 H-NMR spectra of isomers 4 and 2 (Tables 1 and 21 are practically identical but while compound 5 only shows a carbonyl stretching IR band, 6,ll show two carbonyl
according to its greater symmetry, compounds 2 and 4
bands in agreement with their assigned structures (Table 3). The electronic effect of the pyridine nitrogen atom increases the frequent) of the neighbour carbonyl group as it is known to occur, for instance, in l-1 5 aza-5,10-anthraquinone in which the CS-carbonyl band appears at 1671 cm -1 while the ClO-carbonyl band occurs at 1686 cm . In compounds 3 and 4 the additional pyridine nitrogen atom augments the difference between the two carbonyl bands. TABLE l.- 'H-NMR data (6 values relative TMS).
General structure for compounds
5 (R=H, R'=CH3)
I,?,4 and 6
Compound
Solvent
R
R'
-1 2
Ho(R=H)
HB
DMSOd_6
OHa
C13CD
OHa
Hy
CH3
--
6.98
---
--
6.68
Ha'
Hy'
R'
NH
8.15 7.89'
8.90
8.37
2.59
b
--
--
--
d
J -e 4 3 -
C13CD
Cl
CH3
--
7.77
8.58
8.99
8.41
2.59
-
C13CD
H
CH3
7.79
8.66
9.00
8.44
2.60
-
C13CD
H
CH3
9.18 9.16
7.81
8.75
8.98
8.54
2.61
-
6
DMSOd_6
H
OH
9.08
7.88
8.52
8.62
7.75
11.53
-
a: As carbonyl tautomer.
d: Not observed.
b: Only observed in CDC13 at 9.80 ppm.
e: According with ref. 11.
c:
687=5.71; 6N(CH312=3.33.
Due to the presence of a third carbonyl group, the possibility of hydrogen bonding and the different electronic effects of both nitrogen atoms in l_, the study of the stretching carbonyl IR region is more difficult but structure 1 is confirmed from that of compound 3. Said structure is consistent with an addition reaction controlled by the greater electron-deficience of carbostyrilquinone 8-carbonyl group.
C. G!zsro et al.
4480
J Values
TABLE 2.-
in
Hz.
Compound
a:
a’y’
BY
1
__
9.5
--
2.1
-2 3
__
9.0
--
--
__
8.2
--
2.1
4
4.6
7.9
1.7
2.1
3
4.6
7.9
1.7
2.1
a
4.6
7.9
1.7
2.8
?
__
9.5
--
--
8
4.6
7.9
1 .6
1.0
9
6.6
7.8
1 .l
a
-10 11
4.5
8.0
1.7
a
6.6
7.8
1.2
a
Not
IR carbonvl
TABLE 3.-
o8
determined.
freauencies
of
diaza-anthraouinones
Compound
cm 1650
3
1670
(CS=O)
1695
(ClO=O)
4
1670
(CS=O)
1695
(ClO=O)
1675
1685
6*
1670
(CS=O and
(CS=O)
?
ClO=O) 1680
(ClO=O)
1650-1680
8:s --
1680
10+11 --
1660
* Two maxima
Diels-Alder
cm-‘).
-1
1
5
Hetero
(KBr;
of
1680
one
broad
cycloaddition
band
reaction
between
quinoline
5,8-dione
3(tert-butyldimethylsilyl)oxy-l-dimethylamino-l-azabuta-l,3-diene regioselective Once are
in
those
giving
again
the
agreement compound
to
lower
frequency
the
3-hydroxyl Assignation
in
their
treatment
IR frequency with
of
on literature
5 after the
in
values
proposed
+ we can
compound
data.
of
was also
the
the
see
5 due of
The main
difference
chemical
shift.
to
the
with
the
of
the
electron
between
l-6 --
hot
carbonyl
By comparing shift
compounds The
adduct
quinone
structure.
clearly
group. of ‘H-NMR signals
y’-protons
of
and
bands such
(Tables isomers
(Table
values
ClO-carbonyl
releasing
6 and J values
methanol.
effect
3)
with band of
1 and 2) was based 11 and 5 was found %
of
8 and y-protons in
4481
Synthesisof diaza-anthraquinones compounds
1 and 2 are
The electronic tion
of
the
effect
its
chemical
into
N-oxidation
of
and
the
the
1 with
electron-rich
11
the
for
its
a’
1.
interest
is
the
assigna-
responsible
of
of
possible
and reactivity
we study to
the
their
greater
pyridine-ring,
of
Thus,
N-oxides
oxidation
were
the
accessibility.
mixtures
Similarly,
according
substituted
3 explains
and y’-protons.
derivatives,
MCPBA gave
in
carbostyrilquinone7.
3-hydroxyl-group
biological
(7:3),
methyl
described
2-chloro-substituent of
N-oxide
10 and
those
In 6,
shift
account
diaza-anthraquinone (6:4)
of
to
B and y-protons.
upf ield
Taking
similar
obtained
of
S and 2 the
more
3 and 5
from
respectively.
9Structure troscopic
10 -
assignment data
of
(Tables
2,4
N-oxides and
7-11 was based on ‘H-NMR and IR spec-‘H-NMR spectra of compounds 3 respectively).
7-11 show significative upfield -protons. As both nitrogen atoms effects,
the
carbonyl
band
observed while
chemical in
IR spectrum that
of
11
-10 and
shifts
for
compounds for 11 --
8-11 -8 and 2 (as (as
a mixture)
pyridine have
N-oxidated
opposite
a mixture) has
two
ring
electronic has
only
carbonyl
one bands.
C. GPSTOet al.
4482 The found they
are
groups
low
yields
subject
to
interference
in
Compound
for
Solvent
Ha
-7
DMSOd_6
--
8
C13CD
as
can
be
explained
because
electron-attracting
carbonyl
(6 values
relative
TMS)
HY
Ho’
HY’
CH3
6.72a
7.98a
7.78
8.50
2.38
9.18
7.75
8.58
7.95
8.4Sb
2.49
8.58
7.61
8.11
9.00
8.36
2.58
HB
10
C13CD
9.12
7.81
8.73
8.06b
8.44b
2.49
-Y-l
C13CD Cl ,CD
8.57
7.63
8.22
8.94
8.48
2.60
These
signals
besides ric
appear
the
Not
as
for
in
the
resolved,
The observed
dd.
B-y coupling
structure
observed b:
reactions
as well
N-oxides
9
a:
N-oxidation
hindrance
.
‘H-NMR data
TABLE 4.-
the
steric 12
may be
this
extracoupling
attributed
to
of
a phenolic
The NH$OH proton
compound.
1.3
is
Hz
tautomenot
clearly
spectrum.
wide
singlet. EXPERIMENTAL
Melting melting
points
point
are
uncorrected
apparatus.
spectrophotometer
and
and were
IR spectra
were
‘H-NMR spectra
with
6-Methyl-2-oxo-1,8-diaza-9,10-anthraquinone carbostyrilquinone7 N2 atmosphere
under
6 mmol) for
was
The reaction
The precipitate
and refluxed
in
ethanol (0.9
for g,
0.5
plates
Calc.
Cl 3H8N203 : C 64.98; of
the
of
dimethylamine
in
tetrahydrofuran
formed
was
The residue an excess 58%);
above
68%);
was of
(150
hr.
C 60.52;
H 4.60;
(200
capillary
after 20 mmol)
ml, ml)
extracted
solution
with
Found: N 12.80%.
cooling,
a)
It
under
C 65.07;
was obtained
filtration
of
compound
and carbostyrilquinone for
and the
6.5
hr.
solvent
chloroform Compound
C 60.88;
temperature
ml)
l3
(0.72
in
the
g, dark
N2 atmosphere
compound
Found:
of
(200
1 crystallized H 3.59;
N 11.34.
N 11.66%.
was stirred
ether.
room
577
MHz) spectrometer.
tetrahydrofuran
was filtered
After
(2)
by filtration
petroleum
mp 226-228’C.
a Buchi
To a stirred
at
mp> 3OO’C. H 3.35;
reaction
(2.56
removed
(1) anhydrous
obtained
6-Dimethylamino-carbostyrilquinone liquors
a Brucker
was stirred
thus
as yellow for
in
with
on a Perkin-Elmer
3-methyl-1-dimethylamino-1-azabuta-1,3-diene
added.
4 days.
mmol)
(1 g,5.7
measured
recorded
and
N 13.08.
the b)
(1.05
mother
A solution g,
6 mmol)
precipitate
evaporated
extract
2 precipitated
H 4.86;
1.
The black
was the
from
in vacua.
was poured
as
crystals
Calc.
for
into
(0.76 Cl,H,0N203:
g,
Synthesis ofdiaza-anthraquinones Z-Chloro-6-methyl-‘1,g-diaza-9,1U-anthraquinone mmol) was solved heated
in phosphorus
at 130°C for
neutralized
with
chloroform
hr.
(acetone)
in vacua
was dried
yielding
C 60.50;
. Found:
was poured solution
over
N 11.10.
Calc.
into
g,
ice
3-Methyl-1,5-diaza-9,10-anthraquinone (2 g,
atmosphere,
12 hr.
was solved
diminished
column
(5)
12 mmol) in anhydrous
After
The residue
To a stirred
benzene
at room temperature and refluxed
pressure
chromatography
12%)) mp 289-290°C
mp>300°C
solution (1.34
the
in ethanol
solvent for
using
Found:
(ethanol).
g,
After
12 mmol)
solution
of
anhydrous
H 3.67;
95:s
N 12.60.
trietylamine
(2.2
sulfonate
(5.3
g,
20 mmol) were added and stirred
at room temperature,
cold
solution
was allowed
for
was evaporated
the diene external (lH,
(4.2
g,
to stand under
diminished
91%) as a yellow
reference)
0.02
(6H,
s),
Calc.
for
17.4
mmol) in
atmosphere, anhydrous trifluoromethane-
for
1 hr.
After
evaporation
pressure oil.
0.81
at room temperature
to give
‘H-NMR 6(60 MHz, C13CD; TMS as (9H, s),
2.70
(6H,
s),
4.30
(2H, d),
ws).
5,8-dione
(6)
12 mmol) in anhydrous
(2 g,
atmosphere
To a stirred
methylene
solution
chloride
of
quinoline
(75 ml) under
N2
3(tertbutyldimethylsilyl)oxy-l-dimethylamino-l-azabuta-l,3-diene
13 mmol) recently
room temperature refluxed
g,
(100 ml) was added and the -n-pentane 2 hr. at O’C. After filtration the solu-
3-Hydroxy-l,g-diaza-9,10-anthraquinone
(3 g,
(2 g,
chloride (100 ml) under nitrogen g, 21 mmol) and tertbutyldimethylsilyl
in vacua
by
(0.4
To a cold
2-oxopropyliden-N,N-dimethylhydrazine
methylene
in vacua.
evaporation
from 4 and purified
chloroform/ethanol
C 69.75;
quinoline
nitrogen
was removed
2 hr.
compound 5 was separated
on silicagel
of
(150 ml) under
H 3.59; N 12.49%. C13HgN2C2: C 69.62; 3(Tertbutyldimethylsilyl)oxy-l-dimethylamino-l-azabuta-l,3-dieneg.
6.58
with sulfate
C13H7C1N202: C 60.33;
3-methyl-1-dimethylamino-I-azabuta-1,3-diene
was added.
tion
and
sodium
75%),
for
1.9
was
was extracted
anhydrous
compound 2 (0.37
H 3.00;
g,
solution
N 10.82%.
5,8-dione14
under
mixture
The resulting
solution
Compound 1 (0.46
(10 ml) and the
The reaction
ammonia.
and the organic
and concentrated H 2.72;
0.5
aqueous
(3)
oxychloride
4483
in methanol
recrystallized
(1.2
2.88;
Calc.
N 12.27.
prepared
overnight. for g,
0.5
43%);
for
was added.
The reaction
The precipitate hr.
After
cooling
thus
at
was filtered
compound 5 was filtered
mp>300°C(methanol-water).
C12H6N203: C 63.70;
was stirred
obtained
H 2.77;
Found:
C 63.39;
and and H
N 12.38%.
N-oxidation reactions. General procedure: An excess of m-chloroperbenzoic acid (MCPBA) was added to a solution of anthraquinones in chloroform. The reaction was stirred at room temperature and was followed by thin-layer chromatography. During this time additional MCPBA was added twice. The resulting reaction mixture was washed with 10% aqueous potassium carbonate
4484
C. GESTCI et al.
and extracted with chloroform. The organic solution was dried under anhydrous sodium sulfate and evaporated. The residue was purified by column chromatography (silicagel, chloroform: ethanol, 95:s). 3-Methyl-7-oxo-l,8-diaza-EH-9,lO-anthraquinone-l-oxide
(1) Reaction time:
30 days, 10% yield; mp>300°C. Found: C 60.75; H 3.08; N 10.78. Calc. for C,3H8N204: C 60.93; H 3.14; N 10.93%. 3-Methyl-1,8-diaza-9,10-anthraquinone-l-oxide
and 6-methyl-1,8-diaza-9,10-
anthraquinone-l-oxide
(8 - and -9) Reaction time: 10 days, 6% yield. Found: C 65.09; H 3.48; N 11.89. Calc. for C13H8N203: C 64.98; H 3.35; N 11.66%. 3-Methyl-1,5-diaza-9,10-anthraquinone-l-oxide
and 7-methyl-1,5-diaza-9,10-
(10 - and -111 Reaction time: 10 days, 5% yield. Found: C 65.64; H 3.18; N 11.42. Calc. for C13H8N203: C 64.98; H 3.35; N 11.66%.
anthraquinone-l-oxide
Acknowledgements. This work was supported by the Spanish CICYT (PA86-0317). REFERENCES 1. 2. 3. 4. 2: 7. 8. 9.
10. 11. 12.
13. 14.
Omura,S.; Iwai,Y.; Hinotozawa,K.; Tanaka,H.; Takahashi,Y.; Nakagawa,A. J. Antibiotics 1982, 35, 1425. Omura,S.; Nakagawa,A. FAoyama,H.; Hinotozawa,K.; Sano,H. Tetrahedron Lett. 1983, 24, 3643. Omura,x; Murata,M.; Kimura,K.; Matsukura,S.; Nishihara,T.; Tanaka,H. J. Antibiotics 1985, 38, 1016. masaka,T.; Tanaka,H.; Omura,S. J. Antibiotics 1985, 38, 1025. Birch,A.J.; Butler,D.N.; Sidda1,J.B. J. Chem. Sot. 1964 2941; Potts,K.T.; Bhattarcharjee,D.; Walsh,E.B. J. Ch em. Soc.'Chem. Commun. 1984, 114. Pettit,G.R.; Fleming,W.C.; Paul1,K.D. J. Or Serckx-Poncin,B.; Hesbain-Frisque,A.M.;--iX&$?Te:zt!GdgA I!.:!::1982, 23, 3261. Gliosez,L.; Serckx-Poncin,B.; Rivera,M.; Bayard,P.; Sainte,F.; Demoulin,A.; Frisque-Hesbain,A.M.; Mockel,A.; MuAoz,K.; Bernard-Henriet,C. Lect. Heterocycl. Chem. 1985, 8, 169. Oda,N.; Kobayashi,K.; Ueda,T.; Potts, K.T.; Walsh,E.B.; a) Katritzky,A.R.; Lagowsky,J.M. In "Chemistry o des"; Academic Press. New York, 1971. b) Remy,D.C. U.S. Patent, 41639, 457. 1987. Ioffe,B.V.; Zelenin,K.N. Dokl. Akad. Nauk. SSSR 1961, 141, 1369; Chem. 14038b. Abstr. 1962, Pratt,Y.T.; Drake,N.L. 56, J. Am. Chem. Sot. 1960, 82, 1155.
tlO4&4020/89 $3.00+.00 0 1989 Mamdl PergamonMacmluaoplc
SYNTHESIS OF DIAZA-ANTHRAQUINONES BY HETERO DIELS-ALDER CYCLOADDITION REACTIONS C.
Gesto, E. de la Cuesta and C. AvendaAo*
Departamento de Quimica Organica y Farmaceutica, Facultad de Farmacia, Universidad Complutense 28040-Madrid, Spain. (Received VI UK 19April 1989)
Abstract- Using 3-methyl-1-dimethylamino-1-azabuta-1,3-diene and 3(tert-butyl dimethylsilyl)oxy-l-dimethylamino-l-azabuta-l,3-diene as 1-azadienes and quinoline-5,8-dione and carbostyrilquinone as dienophiles, several diazaanthraquinones have been obtained. Structure assignments were mainly based on IR spectroscopic data. The accessibility of N-oxidation products has been also investigated. Diazaquinomicin A (DQM, fig.1) has been isolated and characterized by l-3 , as a new neutral antifolate antibiotic, active against Gram-
Omura et al.
positive bacteria. The site of action of DQM was studied and compared with other known synthetic antibacterial and antitumor drugs such as trimethoprim, methotrexate and S-fluorouracil. It was described as a thymidilate synthase inhibitor competitively with 5,10-methylene tetrahydrofolate4. Preparation of derivatives with higher solubility was claimed to be of interest in creating new antitumor drugs. This paper deals with a synthetic approach to DQM analogues by hetero Diels-Alder cycloaddition reactions.
Figure 1 Cycloadditions between azanaphthoquinones and appropriate dienes are efficient and regioselective methods of synthesis of aza-anthraquinones 536 . Regioselective (or regiospecific) cycloadditions of an electron-rich diene with an azanaphthoquinone are controlled by the relative electron deficiencies of the carbonyl groups 6 . As carbostyrilquinone is readily available from 8hydroxyquinoline7, we investigated the reactions of such quinone with l-azadienes, compounds extensively studied by Ghosez and coworkers 899 . In this context, only one example of cycloaddition between carbostyrilquinone and 1,2-dimethylenecyclohexane has been previously reported to give anthracyclin 4477
C. GES~Oet al.
4418
analogues
10
.
The reaction with 3-methyl-1-dimethylamino-1-azabuta-1,3-diene was regioselective and yielded 1, which isomeric purity was corroborated by its 200 MHz 'H-NMR spectrum (Tables 1 and 2). The secondary product 2 is formed by addition of dimethylamine to the,starting quinone according to previously proposed reaction mechanisms for such 1-azadiene'. Structure -2 was confirmed by carrying out the direct addition. In both reactions no addition on the 3,4-double bond of carbostyrilquinone was detected.
HN(CH&
The best results (68% of l_) were obtained under N2 atmosphere and equimolecular proportion of reactants. When the reaction was performed in air and/ or 2 equivalents of the starting quinone were used, the yield of 2 was increased while that of 1 decreased. To confirm structure 1, it was transformed into 2 by treatment with phosphorus oxychloride and this derivative was compared with the two cycloaddition products 4 and 5, obtained from quinoline-5,8-dione and 3-methyl-ldimethylamino-1-azabuta-1,3-diene.
2
4
The last mentioned reaction has been studied by Potts to give the diaza6,11 as the only obtained isomer, but by mod anthraquinone 4 ifying the reactiol conditions, the regioselectivity drops to give up to 12% of _5_(see experimentall.
Synthesisofdiaza-anthraquinones
4479
1 H-NMR spectra of isomers 4 and 2 (Tables 1 and 21 are practically identical but while compound 5 only shows a carbonyl stretching IR band, 6,ll show two carbonyl
according to its greater symmetry, compounds 2 and 4
bands in agreement with their assigned structures (Table 3). The electronic effect of the pyridine nitrogen atom increases the frequent) of the neighbour carbonyl group as it is known to occur, for instance, in l-1 5 aza-5,10-anthraquinone in which the CS-carbonyl band appears at 1671 cm -1 while the ClO-carbonyl band occurs at 1686 cm . In compounds 3 and 4 the additional pyridine nitrogen atom augments the difference between the two carbonyl bands. TABLE l.- 'H-NMR data (6 values relative TMS).
General structure for compounds
5 (R=H, R'=CH3)
I,?,4 and 6
Compound
Solvent
R
R'
-1 2
Ho(R=H)
HB
DMSOd_6
OHa
C13CD
OHa
Hy
CH3
--
6.98
---
--
6.68
Ha'
Hy'
R'
NH
8.15 7.89'
8.90
8.37
2.59
b
--
--
--
d
J -e 4 3 -
C13CD
Cl
CH3
--
7.77
8.58
8.99
8.41
2.59
-
C13CD
H
CH3
7.79
8.66
9.00
8.44
2.60
-
C13CD
H
CH3
9.18 9.16
7.81
8.75
8.98
8.54
2.61
-
6
DMSOd_6
H
OH
9.08
7.88
8.52
8.62
7.75
11.53
-
a: As carbonyl tautomer.
d: Not observed.
b: Only observed in CDC13 at 9.80 ppm.
e: According with ref. 11.
c:
687=5.71; 6N(CH312=3.33.
Due to the presence of a third carbonyl group, the possibility of hydrogen bonding and the different electronic effects of both nitrogen atoms in l_, the study of the stretching carbonyl IR region is more difficult but structure 1 is confirmed from that of compound 3. Said structure is consistent with an addition reaction controlled by the greater electron-deficience of carbostyrilquinone 8-carbonyl group.
C. G!zsro et al.
4480
J Values
TABLE 2.-
in
Hz.
Compound
a:
a’y’
BY
1
__
9.5
--
2.1
-2 3
__
9.0
--
--
__
8.2
--
2.1
4
4.6
7.9
1.7
2.1
3
4.6
7.9
1.7
2.1
a
4.6
7.9
1.7
2.8
?
__
9.5
--
--
8
4.6
7.9
1 .6
1.0
9
6.6
7.8
1 .l
a
-10 11
4.5
8.0
1.7
a
6.6
7.8
1.2
a
Not
IR carbonvl
TABLE 3.-
o8
determined.
freauencies
of
diaza-anthraouinones
Compound
cm 1650
3
1670
(CS=O)
1695
(ClO=O)
4
1670
(CS=O)
1695
(ClO=O)
1675
1685
6*
1670
(CS=O and
(CS=O)
?
ClO=O) 1680
(ClO=O)
1650-1680
8:s --
1680
10+11 --
1660
* Two maxima
Diels-Alder
cm-‘).
-1
1
5
Hetero
(KBr;
of
1680
one
broad
cycloaddition
band
reaction
between
quinoline
5,8-dione
3(tert-butyldimethylsilyl)oxy-l-dimethylamino-l-azabuta-l,3-diene regioselective Once are
in
those
giving
again
the
agreement compound
to
lower
frequency
the
3-hydroxyl Assignation
in
their
treatment
IR frequency with
of
on literature
5 after the
in
values
proposed
+ we can
compound
data.
of
was also
the
the
see
5 due of
The main
difference
chemical
shift.
to
the
with
the
of
the
electron
between
l-6 --
hot
carbonyl
By comparing shift
compounds The
adduct
quinone
structure.
clearly
group. of ‘H-NMR signals
y’-protons
of
and
bands such
(Tables isomers
(Table
values
ClO-carbonyl
releasing
6 and J values
methanol.
effect
3)
with band of
1 and 2) was based 11 and 5 was found %
of
8 and y-protons in
4481
Synthesisof diaza-anthraquinones compounds
1 and 2 are
The electronic tion
of
the
effect
its
chemical
into
N-oxidation
of
and
the
the
1 with
electron-rich
11
the
for
its
a’
1.
interest
is
the
assigna-
responsible
of
of
possible
and reactivity
we study to
the
their
greater
pyridine-ring,
of
Thus,
N-oxides
oxidation
were
the
accessibility.
mixtures
Similarly,
according
substituted
3 explains
and y’-protons.
derivatives,
MCPBA gave
in
carbostyrilquinone7.
3-hydroxyl-group
biological
(7:3),
methyl
described
2-chloro-substituent of
N-oxide
10 and
those
In 6,
shift
account
diaza-anthraquinone (6:4)
of
to
B and y-protons.
upf ield
Taking
similar
obtained
of
S and 2 the
more
3 and 5
from
respectively.
9Structure troscopic
10 -
assignment data
of
(Tables
2,4
N-oxides and
7-11 was based on ‘H-NMR and IR spec-‘H-NMR spectra of compounds 3 respectively).
7-11 show significative upfield -protons. As both nitrogen atoms effects,
the
carbonyl
band
observed while
chemical in
IR spectrum that
of
11
-10 and
shifts
for
compounds for 11 --
8-11 -8 and 2 (as (as
a mixture)
pyridine have
N-oxidated
opposite
a mixture) has
two
ring
electronic has
only
carbonyl
one bands.
C. GPSTOet al.
4482 The found they
are
groups
low
yields
subject
to
interference
in
Compound
for
Solvent
Ha
-7
DMSOd_6
--
8
C13CD
as
can
be
explained
because
electron-attracting
carbonyl
(6 values
relative
TMS)
HY
Ho’
HY’
CH3
6.72a
7.98a
7.78
8.50
2.38
9.18
7.75
8.58
7.95
8.4Sb
2.49
8.58
7.61
8.11
9.00
8.36
2.58
HB
10
C13CD
9.12
7.81
8.73
8.06b
8.44b
2.49
-Y-l
C13CD Cl ,CD
8.57
7.63
8.22
8.94
8.48
2.60
These
signals
besides ric
appear
the
Not
as
for
in
the
resolved,
The observed
dd.
B-y coupling
structure
observed b:
reactions
as well
N-oxides
9
a:
N-oxidation
hindrance
.
‘H-NMR data
TABLE 4.-
the
steric 12
may be
this
extracoupling
attributed
to
of
a phenolic
The NH$OH proton
compound.
1.3
is
Hz
tautomenot
clearly
spectrum.
wide
singlet. EXPERIMENTAL
Melting melting
points
point
are
uncorrected
apparatus.
spectrophotometer
and
and were
IR spectra
were
‘H-NMR spectra
with
6-Methyl-2-oxo-1,8-diaza-9,10-anthraquinone carbostyrilquinone7 N2 atmosphere
under
6 mmol) for
was
The reaction
The precipitate
and refluxed
in
ethanol (0.9
for g,
0.5
plates
Calc.
Cl 3H8N203 : C 64.98; of
the
of
dimethylamine
in
tetrahydrofuran
formed
was
The residue an excess 58%);
above
68%);
was of
(150
hr.
C 60.52;
H 4.60;
(200
capillary
after 20 mmol)
ml, ml)
extracted
solution
with
Found: N 12.80%.
cooling,
a)
It
under
C 65.07;
was obtained
filtration
of
compound
and carbostyrilquinone for
and the
6.5
hr.
solvent
chloroform Compound
C 60.88;
temperature
ml)
l3
(0.72
in
the
g, dark
N2 atmosphere
compound
Found:
of
(200
1 crystallized H 3.59;
N 11.34.
N 11.66%.
was stirred
ether.
room
577
MHz) spectrometer.
tetrahydrofuran
was filtered
After
(2)
by filtration
petroleum
mp 226-228’C.
a Buchi
To a stirred
at
mp> 3OO’C. H 3.35;
reaction
(2.56
removed
(1) anhydrous
obtained
6-Dimethylamino-carbostyrilquinone liquors
a Brucker
was stirred
thus
as yellow for
in
with
on a Perkin-Elmer
3-methyl-1-dimethylamino-1-azabuta-1,3-diene
added.
4 days.
mmol)
(1 g,5.7
measured
recorded
and
N 13.08.
the b)
(1.05
mother
A solution g,
6 mmol)
precipitate
evaporated
extract
2 precipitated
H 4.86;
1.
The black
was the
from
in vacua.
was poured
as
crystals
Calc.
for
into
(0.76 Cl,H,0N203:
g,
Synthesis ofdiaza-anthraquinones Z-Chloro-6-methyl-‘1,g-diaza-9,1U-anthraquinone mmol) was solved heated
in phosphorus
at 130°C for
neutralized
with
chloroform
hr.
(acetone)
in vacua
was dried
yielding
C 60.50;
. Found:
was poured solution
over
N 11.10.
Calc.
into
g,
ice
3-Methyl-1,5-diaza-9,10-anthraquinone (2 g,
atmosphere,
12 hr.
was solved
diminished
column
(5)
12 mmol) in anhydrous
After
The residue
To a stirred
benzene
at room temperature and refluxed
pressure
chromatography
12%)) mp 289-290°C
mp>300°C
solution (1.34
the
in ethanol
solvent for
using
Found:
(ethanol).
g,
After
12 mmol)
solution
of
anhydrous
H 3.67;
95:s
N 12.60.
trietylamine
(2.2
sulfonate
(5.3
g,
20 mmol) were added and stirred
at room temperature,
cold
solution
was allowed
for
was evaporated
the diene external (lH,
(4.2
g,
to stand under
diminished
91%) as a yellow
reference)
0.02
(6H,
s),
Calc.
for
17.4
mmol) in
atmosphere, anhydrous trifluoromethane-
for
1 hr.
After
evaporation
pressure oil.
0.81
at room temperature
to give
‘H-NMR 6(60 MHz, C13CD; TMS as (9H, s),
2.70
(6H,
s),
4.30
(2H, d),
ws).
5,8-dione
(6)
12 mmol) in anhydrous
(2 g,
atmosphere
To a stirred
methylene
solution
chloride
of
quinoline
(75 ml) under
N2
3(tertbutyldimethylsilyl)oxy-l-dimethylamino-l-azabuta-l,3-diene
13 mmol) recently
room temperature refluxed
g,
(100 ml) was added and the -n-pentane 2 hr. at O’C. After filtration the solu-
3-Hydroxy-l,g-diaza-9,10-anthraquinone
(3 g,
(2 g,
chloride (100 ml) under nitrogen g, 21 mmol) and tertbutyldimethylsilyl
in vacua
by
(0.4
To a cold
2-oxopropyliden-N,N-dimethylhydrazine
methylene
in vacua.
evaporation
from 4 and purified
chloroform/ethanol
C 69.75;
quinoline
nitrogen
was removed
2 hr.
compound 5 was separated
on silicagel
of
(150 ml) under
H 3.59; N 12.49%. C13HgN2C2: C 69.62; 3(Tertbutyldimethylsilyl)oxy-l-dimethylamino-l-azabuta-l,3-dieneg.
6.58
with sulfate
C13H7C1N202: C 60.33;
3-methyl-1-dimethylamino-I-azabuta-1,3-diene
was added.
tion
and
sodium
75%),
for
1.9
was
was extracted
anhydrous
compound 2 (0.37
H 3.00;
g,
solution
N 10.82%.
5,8-dione14
under
mixture
The resulting
solution
Compound 1 (0.46
(10 ml) and the
The reaction
ammonia.
and the organic
and concentrated H 2.72;
0.5
aqueous
(3)
oxychloride
4483
in methanol
recrystallized
(1.2
2.88;
Calc.
N 12.27.
prepared
overnight. for g,
0.5
43%);
for
was added.
The reaction
The precipitate hr.
After
cooling
thus
at
was filtered
compound 5 was filtered
mp>300°C(methanol-water).
C12H6N203: C 63.70;
was stirred
obtained
H 2.77;
Found:
C 63.39;
and and H
N 12.38%.
N-oxidation reactions. General procedure: An excess of m-chloroperbenzoic acid (MCPBA) was added to a solution of anthraquinones in chloroform. The reaction was stirred at room temperature and was followed by thin-layer chromatography. During this time additional MCPBA was added twice. The resulting reaction mixture was washed with 10% aqueous potassium carbonate
4484
C. GESTCI et al.
and extracted with chloroform. The organic solution was dried under anhydrous sodium sulfate and evaporated. The residue was purified by column chromatography (silicagel, chloroform: ethanol, 95:s). 3-Methyl-7-oxo-l,8-diaza-EH-9,lO-anthraquinone-l-oxide
(1) Reaction time:
30 days, 10% yield; mp>300°C. Found: C 60.75; H 3.08; N 10.78. Calc. for C,3H8N204: C 60.93; H 3.14; N 10.93%. 3-Methyl-1,8-diaza-9,10-anthraquinone-l-oxide
and 6-methyl-1,8-diaza-9,10-
anthraquinone-l-oxide
(8 - and -9) Reaction time: 10 days, 6% yield. Found: C 65.09; H 3.48; N 11.89. Calc. for C13H8N203: C 64.98; H 3.35; N 11.66%. 3-Methyl-1,5-diaza-9,10-anthraquinone-l-oxide
and 7-methyl-1,5-diaza-9,10-
(10 - and -111 Reaction time: 10 days, 5% yield. Found: C 65.64; H 3.18; N 11.42. Calc. for C13H8N203: C 64.98; H 3.35; N 11.66%.
anthraquinone-l-oxide
Acknowledgements. This work was supported by the Spanish CICYT (PA86-0317). REFERENCES 1. 2. 3. 4. 2: 7. 8. 9.
10. 11. 12.
13. 14.
Omura,S.; Iwai,Y.; Hinotozawa,K.; Tanaka,H.; Takahashi,Y.; Nakagawa,A. J. Antibiotics 1982, 35, 1425. Omura,S.; Nakagawa,A. FAoyama,H.; Hinotozawa,K.; Sano,H. Tetrahedron Lett. 1983, 24, 3643. Omura,x; Murata,M.; Kimura,K.; Matsukura,S.; Nishihara,T.; Tanaka,H. J. Antibiotics 1985, 38, 1016. masaka,T.; Tanaka,H.; Omura,S. J. Antibiotics 1985, 38, 1025. Birch,A.J.; Butler,D.N.; Sidda1,J.B. J. Chem. Sot. 1964 2941; Potts,K.T.; Bhattarcharjee,D.; Walsh,E.B. J. Ch em. Soc.'Chem. Commun. 1984, 114. Pettit,G.R.; Fleming,W.C.; Paul1,K.D. J. Or Serckx-Poncin,B.; Hesbain-Frisque,A.M.;--iX&$?Te:zt!GdgA I!.:!::1982, 23, 3261. Gliosez,L.; Serckx-Poncin,B.; Rivera,M.; Bayard,P.; Sainte,F.; Demoulin,A.; Frisque-Hesbain,A.M.; Mockel,A.; MuAoz,K.; Bernard-Henriet,C. Lect. Heterocycl. Chem. 1985, 8, 169. Oda,N.; Kobayashi,K.; Ueda,T.; Potts, K.T.; Walsh,E.B.; a) Katritzky,A.R.; Lagowsky,J.M. In "Chemistry o des"; Academic Press. New York, 1971. b) Remy,D.C. U.S. Patent, 41639, 457. 1987. Ioffe,B.V.; Zelenin,K.N. Dokl. Akad. Nauk. SSSR 1961, 141, 1369; Chem. 14038b. Abstr. 1962, Pratt,Y.T.; Drake,N.L. 56, J. Am. Chem. Sot. 1960, 82, 1155.