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The oxidation of organic anions by flavins
BIOCHEMICAL AND BIOPHYSICAL RESEARCH COMMUNICATIONS
Vol. 41, No. 5, 1970
THE OXIDATION
OF ORGANIC ANIONS BY FLAVINS
James A. Rynd* and Morton
J.
Gibian
Department of Chemistry University of California Riverside, California 92502 Received September 14, 1970 The reduction of flavins by a-hydroxyketone enolates leads to dihydroflavins and diketones. Isoalloxazines related to flavins (good analogs for their redox chemistry) are reduced by 9,10-dihydroanthracene and succinonitrile carbanions and by propiophenone enolate (in the latter case to give the isoalloxazine Alkali metal alcoholates, with an appropriate radical anion). isoalloxazine, produce 50% yields of isoalloxazine radical ion, presumably via a substitution and electron transfer process. The ease of?&-banion (and complete lack of conjugate acid) oxidation suggests a general mode of flavin redox function. Recent
spectroscopic
the characterization plexes tion
of both states.
of many of the
free
1
However,
free
With
flavin
generally
only
a few notable
with
various
non-reactive
substrates
flavin
might
indications
protein
portions Flavins
ganic
of the
react
flavin
isoalloxazine. redox
seem relevant *National
states
7
oxida-
been direc-
substrates
have not
under
transfer
which
electrons
of the possible
been other-
to or from
functions
of the
enzymes.
either While
with
a wide variety
photoreduction contributing
and structure,
to a chemical
Institutes
and corn-'
in various
the conditions
photochemically
compounds to give
of the of
give
exceptions
would
forms
in
redox chemistry of 2-6 , attempts to react
physiological
wise
have resulted
has attention
organic
Finding
successful.
flavins
recently
the basic
studies
amphoteric
and protein-bound
ted to understanding flavins.
and chemical
of Health
Predoctoral 1097
or photoalkylation to the understanding
these
elucidation
of or-
processes
of the normal Fellow,
do not dark
1968-70.
re-
BIOCHEMICAL
Vol. 41, No. 5,197O
actions
of flavoproteins.
tronically
excited
Photochemical
states.
generated
by complexing
enzymatic
or not,
(dark)
flavin
suggest
redox
such energetic
involve
states
elec-
may be
in any thermal
reaction,
related
state
to be shown. new closely
systems function
involving
organic
of some of the
ground substrates
which
apoenzymes.
and Methods
Reactions
were run anaerobically
gon in Schlenk fit
processes
or association
several
a possible
Materials
That
has yet
We now report
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
tubes
equipped
by first
with
bubbling
1 cm square
Pyrex
with
bottoms
arto
Flavins were 14 or Beckman DU spectrophotometer. 8 All reagents were obby published procedures.
in a Cary
synthesized tained
from Aldrich
Doering.
'
Chemical
Dimethylformamide
and +-BuOK was prepared
(DMF) and dimethylsulfoxide
from CaH2 and stored
were distilled Epr spectra was calibrated
were taken using
the
nitriledithiolene)-nickel tration
Co.,
was determined
over
on a Varian
molecular
after (DMSO)
sieves. The instrument
V-4502.
tetrabutylammonium salt of bis-(maleo10 anion or DPPH in DMF. Spin concen-
from the
integrated
spectra
or estimated
from peak heights.
Results
and Discussion
We have found duce oxidized
that
flavins
in polar
was judged
by the
reoxidized
by molecular
When the mixed tion
a variety
enolate
anaerobically of flavin
ability
of
carbanions
aprotic
solvents.
of the
flavin
True
re-
reduction
to be rapidly
oxygen. of benzoin
with
occurs,
reduced
and enolates
(I,R=C6H5,
3-benzyllumiflavin Quantitative
1098
yields
see Scheme I) in DMF rapid of dihydroflavin
is reducand
BIOCHEMICAL
Vol. 41, No. 5,197O
benzil*
(III)
an a-amino rapidly
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
are obtained. ketone
The reaction
(C,H,COCH(NH2)C6H5)
oxidizes
acetoin
(I,R=CH3)
is equally
and base.
facile
Flavin
with
also
and 2-hydroxycyclohexanone
to
the a-diketones. 0 OH
00 II II RC-CR)
O-OH
Ri-&HR + OH--+
R-&=;R
--
I
IV
RC=CR + HFR* IV
III One-half equivalent produces
an equivalent
of the
semidione half-reduced
(IV)11
(II)
An additional
or full
flavin.
equivalent
Since
upon mixing,
all
these
two one-electron all
these
(Scheme I). of flavin
or one of flavin
A slight
(FR.-),
excess
identified
of by
(470nm, 400nm, sh, 370nm) and epr
half-equivalent
of hydroxyketone
of semidione reactions
experiments steps
(I)
added to one equivalent
flavin
the radical-anion lb visible characteristic
spectra.
Scheme I
of the a-hydroxyketone
base produces its
III
(IV) take
cannot
produces place
enolate
fully
reduced
instantaneously
be used to differentiate
from one two-electron
step
for
the
over-
reaction. In order
to study
hydroxyketones, void
cf
tain
flavin
it
anions
of compounds less
was desirable
to utilize
acidic
than
isoalloxazines
the de-
the C-8 and C-10 methyl groups that cause the basic side lb reactions of flavins. Thus, lo-phenylisoalloxazines (V) re-
erably
redox
more stable
*Identified by tic dry box under N20
and spectral in basic
using
properties
but
should
be consid-
solution.
three
different
1099
solvent
systems
in a
BIOCHEMICAL
Vol. 41, No. 5, 1970
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
a)R=H b) R = CH2C6H5
Va and Vb behaved scribed tered
below.
The N-3H isoalloxazine
on mixing
with
absorption.
significant
of
immediately
isoalloxazine
amounts was demonstrated (too
almost
100% original
sults
(Va)
reactions
de-
is
al-
&-BuOK,
The presence
slowly
anaerobic
in the
NaH, or even C H ONa to a species 65 a band at 400-410nm (~10,000), but no longer wave-
displaying length
somewhat differently
slowly
for
HCl also
were obtained
the carbanions
of
normal
reduced
isoalloxazine produced
by epr.
the
Shaking
oxidized
9,10-dihydroanthracene,
oxygen
restores
A slight
spectrum.
of a ten-fold
in
with
isoalloxazine)
spectrum.
upon addition
radical
excess Similar
re-
molar
excess
succinonitrile,
or
1.4
I,2
1.0
\
0.0 WAVELENGTH
Figure
1:
(nm)
Va (1x10-'M) plus sodium salt of 9,10-dihydroanthracene5x10-4) and excess 9,10-dihydroanthra-20 minutes: cene (1x10- 4E$ in DMSO, anaerobic. -.-. 6 hours: - - - previous sample after admission of air (1 minute). 1100
of
of
Vol. 4 1, No. 5, 1970
BIOCHEMICAL
propiophenone
(each produced
and slightly
less
than
for
the
shows spectra of oxidized
spectrum
upon oxygen
of unsubstituted
reduced
vb,
the
cut,
an isoalloxazine yield
showed close
to a very
addition
rapid
2:
mission
It philic produce transfers
is
indicative
results
of t-BuOK
spectrum spectrum
500
or C6H50Na
spectral
change to
in approximately is
left.
based on original
400
were obtained
50%
(Figure
2).
Epr
isoalloxazine,
600
Ad-
700
(nm)
--Vb(1.5x10W3M) in DMF; -.-. 1 minute after addition of asaerobic NaOC6H5; - - - previous sample after admission of air (1 minute? same after 6 hours or aerobic photolysis or acidification with HCl).
of air
alloxazine
of N-5 or
return
(seconds)
WAVELENGTH
Figure
rapid
1
Slow return
is typical
Addition
anion
50% spins
300
Figure
system.
surprising,
compound.
radical
to
of NaH in DMF).
while
also
c370) o No oxidized
by
compound
isoalloxazines.
but
3-benzyl
in DMSO or DMF led
from parent
9,10-dihydroanthracene
isoalloxazines,
with
anaerobically
an equivalent
C-4a substituted
More clear
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
led to the
spectrum seems likely
manner to the an alkylated
half that
immediate as intense &-BuO-
to FRox to generate
of oxidized
as in the original
iso-
spectrum,
or C6H50- adds in a nucleo-
isoalloxazine flavin
appearance
(possibly
anion the ‘101
which radical
at N-5 or C-4a)
subsequently anion
electron
(Scheme II).
to
Vol. 41,No.
5, 1970
BIOCHEMICAL
Such a process
12,13
has precedent.
+ C6H50e_,
FROX
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
FROX
C6H5C-F'R
3 C6H5q-fiR + TR*-
\I
dimers?
L
Scheme II On the above,
FROX
other
and also
electron
with
It
It
oxidases,
acyl
inter P
ted)
a,
S to
that
the proteins
a-proton
fer
net
is
alia P,
flavin
4
to protein-bound
these
reactions
with
1,2-dihydro-
flavin
reduction
and succinate
is
oxidized
or
group,
acting
electron
dehydro-
This
resulting
amino
(dehydrogena-
as bases to
the
by either
as the
suggests
remove the
carbanion)
or hydride
(Scheme III).
Acknowledqments
(Grant
GM 15100)
support
of this
to
and the
the National Research
work. 1102
Institutes
Corporation
of Health for
and
trans-
Scheme III
We are grateful
by
in the work of Russell. 11,15
stabilizing
flavin
of Vb spec-
has occurred
That
stabilizing
may be in part
followed
of
in such flavoenzymes
each substrate
also
and base,complete
such case with
was suggested that
mentioned
are in progress.
reduction
recently.
a somewhat anion
then
studies
CoA dehydrogenases,
(possibly
this
14
products)
Another
be noted
genase,
that
that
is possible should
carbanions
and 100% return
Detailed
has been reported
carbanions
place
the oxidation
clear
three
7-cyanocycloheptatriene
and carbanions.
phthalate
the
upon aeration.
is
enolates
with
to Vb takes
(and especially
acid
hand,
transfer
trum occurs
O2
financial
Vol. 41,No.
5, 1970
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
References 1.
a) A. Ehrenberg and P. Hemmerich, in "Biological Oxidations," T. P. Singer, Ed., Interscience Publishers, New York, N. y., 1968. p. 239; b) A. Ehrenberg and P. Hemmerich, Europ. J_. Biochem., 2, 286 (1967): c) F. Muller, P. Hemmerich, A. Ehrenberg, G. Palmer, and V. Massey, i&i&., 14, 185 (1970).
2.
J.
3.
a) I. M. Gascoigne and G. K. Radda, Biochem. Biophys. 131, 448 (1967); b) M. J. Gibian and D. V. Winkelman, Letters, m. 44, 3901 (1969).
4.
G. 0. Weatherby
5.
M. J. Gibian and J. A. Rynd, 34, 544 (1969).
6.
A. H. Gibson and J. W. Hastings, Biochem. J_., 83, 368 (1962): b) D. Ballou, G. Palmer, and V. Massey, Bio3em. Biophys. Res Commun., 36, 898 (1969). --
7.
P. Hemmerich, Biochem. Sot.
8.
a) P. Hemmerich, S. Fallab, and H. Erlenmeyer, Helv. Chim. -Acta, 39, 1242 (1956); b) R. Kuhn and F. Weygand, Chem. Ber., E, 1282 (1935).
9.
A. H. Doering,
L. FOX and G. Tollin,
Biochem.,
and D. 0. Carr,
I,
3865 (1966).
Biochem.,
Biochem.
Aa,
2, 351 (1970).
Biophys.
Res. Commun., --
a)
G. Nagel Letters,
Schneider, and C. Veeger, 8_, 69 (1970).
2. Am. Chem. s., --
10.
A. Davison, N. Edelstein, 82, 2029 (1963).
11.
G. A. Rl1ssel1, 1807 (1964).
12.
F. Miiller
13.
P. Bemporad, G. Illuminati, 91, 6742 (1969). -
14.
Observations
15.
G. A. Russell, R. Konaka, K-Y. Chang, and G. Kaupp,
and V. Massey,
J.
of D. L. Elliott
Europ.
76, 6162 (1954).
R. H.
E. G. Janzen,
Fed.
and A. H. Maki,
Helm,
and E. Biol.
T.
ibid.,
Strom,
Chem., 2,
and F. inthis
Stegel,
86,
4007 (1969). J. ---
Am.
G-em.
laboratory.
E. T. Strom, W. C. Danen, ibid., 90, 4646 (1968).
1103
ibid.,
s.,
Vol. 41, No. 5, 1970
THE OXIDATION
OF ORGANIC ANIONS BY FLAVINS
James A. Rynd* and Morton
J.
Gibian
Department of Chemistry University of California Riverside, California 92502 Received September 14, 1970 The reduction of flavins by a-hydroxyketone enolates leads to dihydroflavins and diketones. Isoalloxazines related to flavins (good analogs for their redox chemistry) are reduced by 9,10-dihydroanthracene and succinonitrile carbanions and by propiophenone enolate (in the latter case to give the isoalloxazine Alkali metal alcoholates, with an appropriate radical anion). isoalloxazine, produce 50% yields of isoalloxazine radical ion, presumably via a substitution and electron transfer process. The ease of?&-banion (and complete lack of conjugate acid) oxidation suggests a general mode of flavin redox function. Recent
spectroscopic
the characterization plexes tion
of both states.
of many of the
free
1
However,
free
With
flavin
generally
only
a few notable
with
various
non-reactive
substrates
flavin
might
indications
protein
portions Flavins
ganic
of the
react
flavin
isoalloxazine. redox
seem relevant *National
states
7
oxida-
been direc-
substrates
have not
under
transfer
which
electrons
of the possible
been other-
to or from
functions
of the
enzymes.
either While
with
a wide variety
photoreduction contributing
and structure,
to a chemical
Institutes
and corn-'
in various
the conditions
photochemically
compounds to give
of the of
give
exceptions
would
forms
in
redox chemistry of 2-6 , attempts to react
physiological
wise
have resulted
has attention
organic
Finding
successful.
flavins
recently
the basic
studies
amphoteric
and protein-bound
ted to understanding flavins.
and chemical
of Health
Predoctoral 1097
or photoalkylation to the understanding
these
elucidation
of or-
processes
of the normal Fellow,
do not dark
1968-70.
re-
BIOCHEMICAL
Vol. 41, No. 5,197O
actions
of flavoproteins.
tronically
excited
Photochemical
states.
generated
by complexing
enzymatic
or not,
(dark)
flavin
suggest
redox
such energetic
involve
states
elec-
may be
in any thermal
reaction,
related
state
to be shown. new closely
systems function
involving
organic
of some of the
ground substrates
which
apoenzymes.
and Methods
Reactions
were run anaerobically
gon in Schlenk fit
processes
or association
several
a possible
Materials
That
has yet
We now report
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
tubes
equipped
by first
with
bubbling
1 cm square
Pyrex
with
bottoms
arto
Flavins were 14 or Beckman DU spectrophotometer. 8 All reagents were obby published procedures.
in a Cary
synthesized tained
from Aldrich
Doering.
'
Chemical
Dimethylformamide
and +-BuOK was prepared
(DMF) and dimethylsulfoxide
from CaH2 and stored
were distilled Epr spectra was calibrated
were taken using
the
nitriledithiolene)-nickel tration
Co.,
was determined
over
on a Varian
molecular
after (DMSO)
sieves. The instrument
V-4502.
tetrabutylammonium salt of bis-(maleo10 anion or DPPH in DMF. Spin concen-
from the
integrated
spectra
or estimated
from peak heights.
Results
and Discussion
We have found duce oxidized
that
flavins
in polar
was judged
by the
reoxidized
by molecular
When the mixed tion
a variety
enolate
anaerobically of flavin
ability
of
carbanions
aprotic
solvents.
of the
flavin
True
re-
reduction
to be rapidly
oxygen. of benzoin
with
occurs,
reduced
and enolates
(I,R=C6H5,
3-benzyllumiflavin Quantitative
1098
yields
see Scheme I) in DMF rapid of dihydroflavin
is reducand
BIOCHEMICAL
Vol. 41, No. 5,197O
benzil*
(III)
an a-amino rapidly
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
are obtained. ketone
The reaction
(C,H,COCH(NH2)C6H5)
oxidizes
acetoin
(I,R=CH3)
is equally
and base.
facile
Flavin
with
also
and 2-hydroxycyclohexanone
to
the a-diketones. 0 OH
00 II II RC-CR)
O-OH
Ri-&HR + OH--+
R-&=;R
--
I
IV
RC=CR + HFR* IV
III One-half equivalent produces
an equivalent
of the
semidione half-reduced
(IV)11
(II)
An additional
or full
flavin.
equivalent
Since
upon mixing,
all
these
two one-electron all
these
(Scheme I). of flavin
or one of flavin
A slight
(FR.-),
excess
identified
of by
(470nm, 400nm, sh, 370nm) and epr
half-equivalent
of hydroxyketone
of semidione reactions
experiments steps
(I)
added to one equivalent
flavin
the radical-anion lb visible characteristic
spectra.
Scheme I
of the a-hydroxyketone
base produces its
III
(IV) take
cannot
produces place
enolate
fully
reduced
instantaneously
be used to differentiate
from one two-electron
step
for
the
over-
reaction. In order
to study
hydroxyketones, void
cf
tain
flavin
it
anions
of compounds less
was desirable
to utilize
acidic
than
isoalloxazines
the de-
the C-8 and C-10 methyl groups that cause the basic side lb reactions of flavins. Thus, lo-phenylisoalloxazines (V) re-
erably
redox
more stable
*Identified by tic dry box under N20
and spectral in basic
using
properties
but
should
be consid-
solution.
three
different
1099
solvent
systems
in a
BIOCHEMICAL
Vol. 41, No. 5, 1970
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
a)R=H b) R = CH2C6H5
Va and Vb behaved scribed tered
below.
The N-3H isoalloxazine
on mixing
with
absorption.
significant
of
immediately
isoalloxazine
amounts was demonstrated (too
almost
100% original
sults
(Va)
reactions
de-
is
al-
&-BuOK,
The presence
slowly
anaerobic
in the
NaH, or even C H ONa to a species 65 a band at 400-410nm (~10,000), but no longer wave-
displaying length
somewhat differently
slowly
for
HCl also
were obtained
the carbanions
of
normal
reduced
isoalloxazine produced
by epr.
the
Shaking
oxidized
9,10-dihydroanthracene,
oxygen
restores
A slight
spectrum.
of a ten-fold
in
with
isoalloxazine)
spectrum.
upon addition
radical
excess Similar
re-
molar
excess
succinonitrile,
or
1.4
I,2
1.0
\
0.0 WAVELENGTH
Figure
1:
(nm)
Va (1x10-'M) plus sodium salt of 9,10-dihydroanthracene5x10-4) and excess 9,10-dihydroanthra-20 minutes: cene (1x10- 4E$ in DMSO, anaerobic. -.-. 6 hours: - - - previous sample after admission of air (1 minute). 1100
of
of
Vol. 4 1, No. 5, 1970
BIOCHEMICAL
propiophenone
(each produced
and slightly
less
than
for
the
shows spectra of oxidized
spectrum
upon oxygen
of unsubstituted
reduced
vb,
the
cut,
an isoalloxazine yield
showed close
to a very
addition
rapid
2:
mission
It philic produce transfers
is
indicative
results
of t-BuOK
spectrum spectrum
500
or C6H50Na
spectral
change to
in approximately is
left.
based on original
400
were obtained
50%
(Figure
2).
Epr
isoalloxazine,
600
Ad-
700
(nm)
--Vb(1.5x10W3M) in DMF; -.-. 1 minute after addition of asaerobic NaOC6H5; - - - previous sample after admission of air (1 minute? same after 6 hours or aerobic photolysis or acidification with HCl).
of air
alloxazine
of N-5 or
return
(seconds)
WAVELENGTH
Figure
rapid
1
Slow return
is typical
Addition
anion
50% spins
300
Figure
system.
surprising,
compound.
radical
to
of NaH in DMF).
while
also
c370) o No oxidized
by
compound
isoalloxazines.
but
3-benzyl
in DMSO or DMF led
from parent
9,10-dihydroanthracene
isoalloxazines,
with
anaerobically
an equivalent
C-4a substituted
More clear
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
led to the
spectrum seems likely
manner to the an alkylated
half that
immediate as intense &-BuO-
to FRox to generate
of oxidized
as in the original
iso-
spectrum,
or C6H50- adds in a nucleo-
isoalloxazine flavin
appearance
(possibly
anion the ‘101
which radical
at N-5 or C-4a)
subsequently anion
electron
(Scheme II).
to
Vol. 41,No.
5, 1970
BIOCHEMICAL
Such a process
12,13
has precedent.
+ C6H50e_,
FROX
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
FROX
C6H5C-F'R
3 C6H5q-fiR + TR*-
\I
dimers?
L
Scheme II On the above,
FROX
other
and also
electron
with
It
It
oxidases,
acyl
inter P
ted)
a,
S to
that
the proteins
a-proton
fer
net
is
alia P,
flavin
4
to protein-bound
these
reactions
with
1,2-dihydro-
flavin
reduction
and succinate
is
oxidized
or
group,
acting
electron
dehydro-
This
resulting
amino
(dehydrogena-
as bases to
the
by either
as the
suggests
remove the
carbanion)
or hydride
(Scheme III).
Acknowledqments
(Grant
GM 15100)
support
of this
to
and the
the National Research
work. 1102
Institutes
Corporation
of Health for
and
trans-
Scheme III
We are grateful
by
in the work of Russell. 11,15
stabilizing
flavin
of Vb spec-
has occurred
That
stabilizing
may be in part
followed
of
in such flavoenzymes
each substrate
also
and base,complete
such case with
was suggested that
mentioned
are in progress.
reduction
recently.
a somewhat anion
then
studies
CoA dehydrogenases,
(possibly
this
14
products)
Another
be noted
genase,
that
that
is possible should
carbanions
and 100% return
Detailed
has been reported
carbanions
place
the oxidation
clear
three
7-cyanocycloheptatriene
and carbanions.
phthalate
the
upon aeration.
is
enolates
with
to Vb takes
(and especially
acid
hand,
transfer
trum occurs
O2
financial
Vol. 41,No.
5, 1970
BIOCHEMICAL
AND BIOPHYSICAL RESEARCH COMMUNICATIONS
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