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Kinetics of reactions involving C-550 and cytochrome b559 in chloroplasts at low temperature. Evidence for two photoreactions
Vol.
56, No.
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
AND CYTOCHROMB b559 IN CHLOROPLASTS AT LOW TEMPERATURE. EVIDENCE FOR TWO PHOTOREACTIONS.
KINETICS
OP REACTIONS INVOLVING
Paul Service
BIOCHEMICAL
3, 1974
MATHIS,
Michel
de Biophysique, de Saclay,
Received
November
C-550
and Andrd
MICHEL-VILLA2
VERMBGLIO
DLpartement de Biologie. Centre d’Etudes B.P. n* 2 -91190GIF-sur-Wl?TTE.France.
Nuclcaires
28,1973
Summary : The kinetics of reduction of C-550 and of oxidation of cytochrome b55g are studied with spinach chloroplasts, at -170*, under light-limited conditions at different light intensities. The rate of reduction of C-550 of b55g is is proportional to the light intensity I; the rate of oxidation 2-3 times slower and not proportional to I. We propose that two light reactions occur at the reaction center of Photosystem(RC-II) at low temperature. The photoreduction been observed arguments
in photosynthetic
allow
the
of Photosystemdark
of C-550
reaction
(5i.8).
of C-550
and cyt
affected
by the In this
materials
identification (6,7).
of
work,
the
the
the
that
the
oxydation
reactions
reduction
with
under
Several
the
electron
acceptor
results is
(9,lO) of
to be a secondary for
the
presented
are (1 I).
and of oxidation
of
at different
by Butler
to I.
leads us to propose 11 at low temperature.
location
photoreaction
conditions,
proportional
the
by Kok --et al
of C-550
b55g
in Photosystem
assumed
as defined
light-limited
to the
primary
properties
of reduction
b55g have
( 1-5 ).
b55g is
center,
of cyt
temperature
arguments
: several reaction
of C-550
of cytochrome
occur
low
of cyt
different
kinetics
at -170’, cyt b559 are studied Iight intensities. In contrast we find
of C-550
at RC-II
state
photooxidation
at
The oxidation
We provided
b55g
and the
that
--et al (12), The behaviour of at least
two photo-
MATERIAL AND METHODS. Chloroplasts the
grinding
buffer
, prepared ( 0.4
5% dimethylsulfoxide. in liquid
from
spinach
M sucrose;
The suspension
0.02
leaves M Trls,
(9), pH
was distributed
were 7.8;
resuspended 0.01
M NaCl > plus
in 0.5 ml tubes
N 2’ Differential
spectrophotometer Abbreviation
absorption
spectra
were
559 : cytochrome
b 559
(9). : cyt
b
recorded
with
in
a Perkin-Elmer
and kept
Vol. 56, No. 3, 1974
BIOCHEMICAL
AND BIOPHYSICAL
of kinetics
of absorbance
For measurements were
thawed
and transferred
inserted
in a copper
then the transferred
cell
cedure
to a cuvette
frame.
-170’(+
The
actinic
the
plane
the
the
dark.
was dark-adapted
A thermocouple,
The suspension beams,
beam,
cuvette.
windows
( 2 min at
20.);
be referred
in the
euvette,
in a microcrystallized to each
by a 625-w
other,
state.
were
On a parallel
path
filter,
a Schott
of
tungrtene-iodine
the
beam were
a Compur
RG 610-3
at 45’
as I = 100;
smaller
values
of
lamp,
inserted
electronic
mm filter,
of
was focu-
: a 2-cm water
shutter
( opening
time
a MT0 (630 nm ) interference beam at the position of the
The maximum intensity of the actinic -2 ( measured with a calibrated was 25 mW.cm
cuvette
Lucite
inserted
was frozen
perpendicular
provided
(Balzers)
: 8 ms ),
filter.
chloroplasts
cuvette.
a Calflex
1O-90
in
5’).
The actinic sed on the
the
( e = I mm ) made of
The suspension
and measuring of
filter,
changes
uas dipped into a liquid N2 container for 60 s. The cell was then to a partly unsilvered Dewar flask, containing liquid N2. This pro-
was accomplished
indicated
RESEARCH COMMUNICATIONS
Eppley
I were
thermopile.
obtained
with
It
Schott
will
neutral
filters. The measuring a Bausch
light
was provided
sample
and was received
Schott
BG 18-3 mm and two Wratten
500 lQ;a
variable
required
electrical
V, output, signal
change; signals
with
in order
it
0.5
a Didac
The PM output
(Intertechnique)
had no detectable
to improve
the
( load
amplifier analyser. of the
In most
cuvettes
were
: whose
multichannel
effect.
successive
resistor
The amplified
measurement
the
the minimum
voltage.
photochemical
to several
on
by a
to have
W differential
as comparison
beam was .gpened I min before
corresponding
lamp mounted
The beam crossed
I uF was inserted
a Tektronix
was used
mm ).
(EM1 9558 B ) protected
64 filters. 10 nF to
) fed
at 2 volts,
The measuring the
of
bandwith
fixed
( slits
by a photomultiplier
capacitor
was measured
bance
by a 108-W tungsten
and Lomb 500 mm monochromator
absor-
experiments
stored
and added
S/N ratio.
RESULTS.
Comparison The
of
the
kinetics
effect
of
at
illumination
la,
as
a differential
to
the
oxidation
of
cyt
to
the
reduction
of
C-550.
The
mere
studied
of 542
and
b559
reduction 556
light of
absorption
kinetics at
different
chloroplasts
spectrum. and
the
of
intensities. at The
S-shaped
C-550
nm respectively,
-
negative signal
and
of in
170’
is
peak (+
at
542
oxidation the
range
reported at
of of
in
556 nm,
nm -
cytochrome excitation
at
Fig.
is
due 546
b55S inten-
nm)
BIOCHEMICAL
Vol. 56, No. 3, 1974
AND BIOPHYSICAL
I
AA.O.M)l
al u-1 530
:
t
556
I 1
SLO
550
RESEARCH COMMLJ,\(ICATIONS
560
I
530
I
1
!xo
I
1
550
I
L
560
hnm Figure
1.
sities
from
absorbance presented
Difference spectra recorded after illumination of the sample cuvette at -196’ a - Chloroplest suspension used for the results of Fig. 2-4. Illumination by white light (Is).Chlorophyll concentration : 202 ng.ml-1 bIllumination during 15 min by monochromatic light (611 run) of very low intensity ( top curve ) and then during IS bylwhite light (bottom). Chlorophyll concentration : 250 ug ml .
25 mW.cm -2 (I = 100) changes in Fig.
were 2; they
The reciprocal At 542 nm (reduction seen by a straight not
shown,
were
that
the
reduction
the
of
to 0.098
same at all
mW.cm-*
are practically the
t ,,2
for
at 546 nm).
of C-550
is
Typical
of first reaction
of C-550), the rate (tl,2-I) line with a slope of I in the
obtained
(I = 0.39).
intensities.
This
a primary
is
the
saturation, are
order
at both
wavelengths.
is plotted
versus
I in Fig.3.
is proportional log
plot
in agreement
photoreaction.
684
At
kinetics
to I,
(similar with
as
results, the
assumption
An important
departure
Vol. 56, No. 3, 1974
BIOCHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
I = 55
I = 3.75
5L2 nm AA
I
t
hv
hu
556 nm AA
Figure
from At
2.
Time course intensities. of averaged
linearity, 556
reported
nm,
tendency
the to
Evolution
rate
larger of
once
the is
t
112
the
absorbance
ratio
at
is
the
not
of
progressive as
must
dark
in
lb
is
slower,
in
our
with
a
experiments clear
reaction. the
illumination
achieved,
the
proportion
oxidized
cyt
b559.
difference
spectra after the
also
observed
times
when
minutes
(see
not
a limited
of
when
Fig.
2-3
kinetics,
phototransformation, seen
is
after
C-550
a few
was
intensities.
proportion
observed
(12)
highest
described
the
al
change
the
reduction than
et
the
in
spectrophotometer,
shape,
are
the
2 in
of
recorded
9).
such with
So
has some
a
a Perkin-
: at
spectrum ref.
stopped reduced
However
illumination
difference
Fig.
is
any the
dark
part
of
same reaction
occur. Fig.
the
dark
the
cyt
dark
& represents after
reaction however
A time
gap
due
slow
to
an
attempt
photoreduction
b559.
We see
(about
of
Butler
of
to
greater
difference Elmer
by
absorbance
According
C-550
of absorbance changes at 542 and 556 nm, at two light The arrows indicate the opening of the shutter. Number experiments : 6 for I = 55, 3 for I I 3.76 .
No
evolution
is
a reverse that
evolution
between
evolutions
of due
to
60%
the the several
follow of
the
observed,
oxidation
any
remains
1 minute,
of is
to
so of
has abilities baseline) manual
the C-550 that
C-550 to
evolution and we
or
slow
of
the
kinetic
and
of
685
the
of
decide
a dark
very
absorbance
oxidation
cannot
be
operations
of
oxidation (t ,,2
greater
apparatus
Perkin-Elmer following
in
25-30% whether of
of the
cyt than
b559V 5s).
(about spectrophotometer
the
illumination).
10
s,
Vol.
56,
No.
BIOCHEMICAL
3, 1974
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
/
I
,' I'
ix_ 01
/' ,I
D , ,,.' ,' I ,. ,' I 1
IO
III
L I(
Figure
3.
A logarithmic plot the reciprocal of the half-time of absorbance changes at 542 nm (reduction of C-550) and at 556 nm (oxidation Line has a slope of cyt b559) versus light intensity I. The dashed of 1. The continuons line is a best fit for cyt b559. In that plot the straight line with a slope different of 1 has no well-defined signification.
Figure
4.
Time course of absorbance changes at 542 and 556 nm, with and a shutter opening of l/8 s (negative square signal). the vertical step corresponds 8 experiments were averaged; AA = 1.1 x 10-3. At 542 nm, 6 experiments were averaged; vertical step corresponds to AA = 1.8 x 10m3.
I At
= 16.25 556 nm, to
the
DISCUSSION. Our at
-17d
accounted
results its for
confirm rate
of
by
the
that
C-550
reduction
is
currently
used
behaves
as
proportional model
686
a primary to
for
the
I.
electron However
low-temperature
acceptor they
cannot reactions
: be
Vol. 56, No. 3, 1974
BIOCHEMICAL
of Photosystem-
(8,Y) hv -
c550
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
: C - - Chl+ 550
- b55y -
kb
C
- Chl 550
+ - b55y
r where
is
%
a ratio
a dark
reaction.
of 2-3 between in our
b559 reaction,
a : c550
range
Indeed
the
of
rates
according
- Chl
- b55y
We are
to one of a1
r
no value
of reduction
intensities.
e.g.
for
the
of kb this
of C-550
led
to
the
- b55y
Predict
--!% c
of cyt
of a second
models
kr
can
and of oxidation
proposal
two following
C 550 - Chl+
model
light
:
C - - Chl 550
- b;5y
kb
a1 - (Chl
c550
- D)
7
C - - (Chl 550
b:
- D)+
b,
kr
!sE -
(A - Chl)
donor
- A : electron
(A - Chl) - bssy (D:
electron
Model
a/ can readily
with
I and the
time
after
identical
a partial
xidation
of cyt
model
correctly
a definite
predict
the
assumptiorsare
dation
of cyt
b55y
products Model
of b/
donor-acceptor
in the
photoreactions
presents
at RC-II
of
variation
C-550
of the
and of oxidized
However
it
predicts,
we were
not
able
the
reaction
absorbance
cyt for
b55y the
to detect. changes;
kinetics
The second however
is
the
addiof oxibetween
and b2. with
the
on the possible
photooxidation
S2 and S3 states
some
photoo-
proposal
by Joliot
and Joliot
of
electron
temperature. of cyt donor
occurence of these The second reaction b55y : very
and fluorescence low temperatures
two reactions could explain induction (12,14),
-55'
(10,15).
Knaff, D.B. and Arnon D.I.(1969)Proc. Nat. Acad. Sci. Knaff D.B. and Arnon D.I. (1969)Proc. Nat. Acad. Sci. Boardman,N.K., Anderson, J.M. and Hiller, R.G. (1971) Acta 234, 126-136
687
U.S. 63, U.S. 63, Biochim.
in the
in ca-
REFERENCES.
:: 3.
two
(13).
between b55y
that
course
similarities
no information
cyt
lag
b,
at room
ses where
of reduced
time
photosynthesis,
parallelism
observed
)
needed to account for the non-linearity in the rate ( versus I ) and some interaction has to be postulated
pairs
We have normal
the
amount
b2
acceptor
phototransformation.
b55y,
tional the
explain
+ - b559
963-969 956-962 Biophys.
Vol.
56,
No.
3, 1974
BIOCHEMICAL
AND
BIOPHYSICAL
RESEARCH
4. 5.
Bendall, D. S. and Sofrova, D. (1971) Biochim. Floyd,R.A., Chance, B. and Devault, D. (1971)
6.
Erixon, K.and Butler, W.L. (1971) Biochim. Biophys. Acta 234, 381-389 Vermeglio,A. and Mathis, P. (1973) Bioelectrochemistry and Bioenergetics I, in the press. Butler, W.L. (1973) Act. Chem. Res. 6, 177-184 Vermeglio, A. and Mathis P. (1973) Biochim. Biophys. Acta 292, 763-771 Vermeglio, A. and Mathis, P. (1973) Biochim. Biophys. Acta 314, 57-65 Kok, B.,Forbusch, B. and MC Gloin, M. (1970) Photochem. Photobiol. II,
103-I 7.
8. 9. 10. II.
Biophys. Biochim.
COMMUNICATIONS
Acta 234, 371-380 Biophys. Acta 226
12
457-475
12. 13.
14. 15.
Butler, W.L., Visser, J.W.M. and Simons, H.L. (1973) Biochim. Biophys.Acta 292, 140-151 Joliot, P. and Joliot,A. (1972) in Proc. 2nd Int. Congr. Photosynth. (Forti G ., Avron, M. and Melandri, A., eds) Vol. I, pp.26-38, Dr. Junk N.V. Publishers, The Hague. Okayama, S. and Butler, W.L. (1972) Biochim. Biophys. Acta, 267, 523-529 Joliot, P. and Joliot, A. (1973) Biochim. Biophys. Acta 305, 302-316
688
56, No.
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
AND CYTOCHROMB b559 IN CHLOROPLASTS AT LOW TEMPERATURE. EVIDENCE FOR TWO PHOTOREACTIONS.
KINETICS
OP REACTIONS INVOLVING
Paul Service
BIOCHEMICAL
3, 1974
MATHIS,
Michel
de Biophysique, de Saclay,
Received
November
C-550
and Andrd
MICHEL-VILLA2
VERMBGLIO
DLpartement de Biologie. Centre d’Etudes B.P. n* 2 -91190GIF-sur-Wl?TTE.France.
Nuclcaires
28,1973
Summary : The kinetics of reduction of C-550 and of oxidation of cytochrome b55g are studied with spinach chloroplasts, at -170*, under light-limited conditions at different light intensities. The rate of reduction of C-550 of b55g is is proportional to the light intensity I; the rate of oxidation 2-3 times slower and not proportional to I. We propose that two light reactions occur at the reaction center of Photosystem(RC-II) at low temperature. The photoreduction been observed arguments
in photosynthetic
allow
the
of Photosystemdark
of C-550
reaction
(5i.8).
of C-550
and cyt
affected
by the In this
materials
identification (6,7).
of
work,
the
the
the
that
the
oxydation
reactions
reduction
with
under
Several
the
electron
acceptor
results is
(9,lO) of
to be a secondary for
the
presented
are (1 I).
and of oxidation
of
at different
by Butler
to I.
leads us to propose 11 at low temperature.
location
photoreaction
conditions,
proportional
the
by Kok --et al
of C-550
b55g
in Photosystem
assumed
as defined
light-limited
to the
primary
properties
of reduction
b55g have
( 1-5 ).
b55g is
center,
of cyt
temperature
arguments
: several reaction
of C-550
of cytochrome
occur
low
of cyt
different
kinetics
at -170’, cyt b559 are studied Iight intensities. In contrast we find
of C-550
at RC-II
state
photooxidation
at
The oxidation
We provided
b55g
and the
that
--et al (12), The behaviour of at least
two photo-
MATERIAL AND METHODS. Chloroplasts the
grinding
buffer
, prepared ( 0.4
5% dimethylsulfoxide. in liquid
from
spinach
M sucrose;
The suspension
0.02
leaves M Trls,
(9), pH
was distributed
were 7.8;
resuspended 0.01
M NaCl > plus
in 0.5 ml tubes
N 2’ Differential
spectrophotometer Abbreviation
absorption
spectra
were
559 : cytochrome
b 559
(9). : cyt
b
recorded
with
in
a Perkin-Elmer
and kept
Vol. 56, No. 3, 1974
BIOCHEMICAL
AND BIOPHYSICAL
of kinetics
of absorbance
For measurements were
thawed
and transferred
inserted
in a copper
then the transferred
cell
cedure
to a cuvette
frame.
-170’(+
The
actinic
the
plane
the
the
dark.
was dark-adapted
A thermocouple,
The suspension beams,
beam,
cuvette.
windows
( 2 min at
20.);
be referred
in the
euvette,
in a microcrystallized to each
by a 625-w
other,
state.
were
On a parallel
path
filter,
a Schott
of
tungrtene-iodine
the
beam were
a Compur
RG 610-3
at 45’
as I = 100;
smaller
values
of
lamp,
inserted
electronic
mm filter,
of
was focu-
: a 2-cm water
shutter
( opening
time
a MT0 (630 nm ) interference beam at the position of the
The maximum intensity of the actinic -2 ( measured with a calibrated was 25 mW.cm
cuvette
Lucite
inserted
was frozen
perpendicular
provided
(Balzers)
: 8 ms ),
filter.
chloroplasts
cuvette.
a Calflex
1O-90
in
5’).
The actinic sed on the
the
( e = I mm ) made of
The suspension
and measuring of
filter,
changes
uas dipped into a liquid N2 container for 60 s. The cell was then to a partly unsilvered Dewar flask, containing liquid N2. This pro-
was accomplished
indicated
RESEARCH COMMUNICATIONS
Eppley
I were
thermopile.
obtained
with
It
Schott
will
neutral
filters. The measuring a Bausch
light
was provided
sample
and was received
Schott
BG 18-3 mm and two Wratten
500 lQ;a
variable
required
electrical
V, output, signal
change; signals
with
in order
it
0.5
a Didac
The PM output
(Intertechnique)
had no detectable
to improve
the
( load
amplifier analyser. of the
In most
cuvettes
were
: whose
multichannel
effect.
successive
resistor
The amplified
measurement
the
the minimum
voltage.
photochemical
to several
on
by a
to have
W differential
as comparison
beam was .gpened I min before
corresponding
lamp mounted
The beam crossed
I uF was inserted
a Tektronix
was used
mm ).
(EM1 9558 B ) protected
64 filters. 10 nF to
) fed
at 2 volts,
The measuring the
of
bandwith
fixed
( slits
by a photomultiplier
capacitor
was measured
bance
by a 108-W tungsten
and Lomb 500 mm monochromator
absor-
experiments
stored
and added
S/N ratio.
RESULTS.
Comparison The
of
the
kinetics
effect
of
at
illumination
la,
as
a differential
to
the
oxidation
of
cyt
to
the
reduction
of
C-550.
The
mere
studied
of 542
and
b559
reduction 556
light of
absorption
kinetics at
different
chloroplasts
spectrum. and
the
of
intensities. at The
S-shaped
C-550
nm respectively,
-
negative signal
and
of in
170’
is
peak (+
at
542
oxidation the
range
reported at
of of
in
556 nm,
nm -
cytochrome excitation
at
Fig.
is
due 546
b55S inten-
nm)
BIOCHEMICAL
Vol. 56, No. 3, 1974
AND BIOPHYSICAL
I
AA.O.M)l
al u-1 530
:
t
556
I 1
SLO
550
RESEARCH COMMLJ,\(ICATIONS
560
I
530
I
1
!xo
I
1
550
I
L
560
hnm Figure
1.
sities
from
absorbance presented
Difference spectra recorded after illumination of the sample cuvette at -196’ a - Chloroplest suspension used for the results of Fig. 2-4. Illumination by white light (Is).Chlorophyll concentration : 202 ng.ml-1 bIllumination during 15 min by monochromatic light (611 run) of very low intensity ( top curve ) and then during IS bylwhite light (bottom). Chlorophyll concentration : 250 ug ml .
25 mW.cm -2 (I = 100) changes in Fig.
were 2; they
The reciprocal At 542 nm (reduction seen by a straight not
shown,
were
that
the
reduction
the
of
to 0.098
same at all
mW.cm-*
are practically the
t ,,2
for
at 546 nm).
of C-550
is
Typical
of first reaction
of C-550), the rate (tl,2-I) line with a slope of I in the
obtained
(I = 0.39).
intensities.
This
a primary
is
the
saturation, are
order
at both
wavelengths.
is plotted
versus
I in Fig.3.
is proportional log
plot
in agreement
photoreaction.
684
At
kinetics
to I,
(similar with
as
results, the
assumption
An important
departure
Vol. 56, No. 3, 1974
BIOCHEMICAL
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
I = 55
I = 3.75
5L2 nm AA
I
t
hv
hu
556 nm AA
Figure
from At
2.
Time course intensities. of averaged
linearity, 556
reported
nm,
tendency
the to
Evolution
rate
larger of
once
the is
t
112
the
absorbance
ratio
at
is
the
not
of
progressive as
must
dark
in
lb
is
slower,
in
our
with
a
experiments clear
reaction. the
illumination
achieved,
the
proportion
oxidized
cyt
b559.
difference
spectra after the
also
observed
times
when
minutes
(see
not
a limited
of
when
Fig.
2-3
kinetics,
phototransformation, seen
is
after
C-550
a few
was
intensities.
proportion
observed
(12)
highest
described
the
al
change
the
reduction than
et
the
in
spectrophotometer,
shape,
are
the
2 in
of
recorded
9).
such with
So
has some
a
a Perkin-
: at
spectrum ref.
stopped reduced
However
illumination
difference
Fig.
is
any the
dark
part
of
same reaction
occur. Fig.
the
dark
the
cyt
dark
& represents after
reaction however
A time
gap
due
slow
to
an
attempt
photoreduction
b559.
We see
(about
of
Butler
of
to
greater
difference Elmer
by
absorbance
According
C-550
of absorbance changes at 542 and 556 nm, at two light The arrows indicate the opening of the shutter. Number experiments : 6 for I = 55, 3 for I I 3.76 .
No
evolution
is
a reverse that
evolution
between
evolutions
of due
to
60%
the the several
follow of
the
observed,
oxidation
any
remains
1 minute,
of is
to
so of
has abilities baseline) manual
the C-550 that
C-550 to
evolution and we
or
slow
of
the
kinetic
and
of
685
the
of
decide
a dark
very
absorbance
oxidation
cannot
be
operations
of
oxidation (t ,,2
greater
apparatus
Perkin-Elmer following
in
25-30% whether of
of the
cyt than
b559V 5s).
(about spectrophotometer
the
illumination).
10
s,
Vol.
56,
No.
BIOCHEMICAL
3, 1974
AND
BIOPHYSICAL
RESEARCH
COMMUNICATIONS
/
I
,' I'
ix_ 01
/' ,I
D , ,,.' ,' I ,. ,' I 1
IO
III
L I(
Figure
3.
A logarithmic plot the reciprocal of the half-time of absorbance changes at 542 nm (reduction of C-550) and at 556 nm (oxidation Line has a slope of cyt b559) versus light intensity I. The dashed of 1. The continuons line is a best fit for cyt b559. In that plot the straight line with a slope different of 1 has no well-defined signification.
Figure
4.
Time course of absorbance changes at 542 and 556 nm, with and a shutter opening of l/8 s (negative square signal). the vertical step corresponds 8 experiments were averaged; AA = 1.1 x 10-3. At 542 nm, 6 experiments were averaged; vertical step corresponds to AA = 1.8 x 10m3.
I At
= 16.25 556 nm, to
the
DISCUSSION. Our at
-17d
accounted
results its for
confirm rate
of
by
the
that
C-550
reduction
is
currently
used
behaves
as
proportional model
686
a primary to
for
the
I.
electron However
low-temperature
acceptor they
cannot reactions
: be
Vol. 56, No. 3, 1974
BIOCHEMICAL
of Photosystem-
(8,Y) hv -
c550
AND BIOPHYSICAL
RESEARCH COMMUNICATIONS
: C - - Chl+ 550
- b55y -
kb
C
- Chl 550
+ - b55y
r where
is
%
a ratio
a dark
reaction.
of 2-3 between in our
b559 reaction,
a : c550
range
Indeed
the
of
rates
according
- Chl
- b55y
We are
to one of a1
r
no value
of reduction
intensities.
e.g.
for
the
of kb this
of C-550
led
to
the
- b55y
Predict
--!% c
of cyt
of a second
models
kr
can
and of oxidation
proposal
two following
C 550 - Chl+
model
light
:
C - - Chl 550
- b;5y
kb
a1 - (Chl
c550
- D)
7
C - - (Chl 550
b:
- D)+
b,
kr
!sE -
(A - Chl)
donor
- A : electron
(A - Chl) - bssy (D:
electron
Model
a/ can readily
with
I and the
time
after
identical
a partial
xidation
of cyt
model
correctly
a definite
predict
the
assumptiorsare
dation
of cyt
b55y
products Model
of b/
donor-acceptor
in the
photoreactions
presents
at RC-II
of
variation
C-550
of the
and of oxidized
However
it
predicts,
we were
not
able
the
reaction
absorbance
cyt for
b55y the
to detect. changes;
kinetics
The second however
is
the
addiof oxibetween
and b2. with
the
on the possible
photooxidation
S2 and S3 states
some
photoo-
proposal
by Joliot
and Joliot
of
electron
temperature. of cyt donor
occurence of these The second reaction b55y : very
and fluorescence low temperatures
two reactions could explain induction (12,14),
-55'
(10,15).
Knaff, D.B. and Arnon D.I.(1969)Proc. Nat. Acad. Sci. Knaff D.B. and Arnon D.I. (1969)Proc. Nat. Acad. Sci. Boardman,N.K., Anderson, J.M. and Hiller, R.G. (1971) Acta 234, 126-136
687
U.S. 63, U.S. 63, Biochim.
in the
in ca-
REFERENCES.
:: 3.
two
(13).
between b55y
that
course
similarities
no information
cyt
lag
b,
at room
ses where
of reduced
time
photosynthesis,
parallelism
observed
)
needed to account for the non-linearity in the rate ( versus I ) and some interaction has to be postulated
pairs
We have normal
the
amount
b2
acceptor
phototransformation.
b55y,
tional the
explain
+ - b559
963-969 956-962 Biophys.
Vol.
56,
No.
3, 1974
BIOCHEMICAL
AND
BIOPHYSICAL
RESEARCH
4. 5.
Bendall, D. S. and Sofrova, D. (1971) Biochim. Floyd,R.A., Chance, B. and Devault, D. (1971)
6.
Erixon, K.and Butler, W.L. (1971) Biochim. Biophys. Acta 234, 381-389 Vermeglio,A. and Mathis, P. (1973) Bioelectrochemistry and Bioenergetics I, in the press. Butler, W.L. (1973) Act. Chem. Res. 6, 177-184 Vermeglio, A. and Mathis P. (1973) Biochim. Biophys. Acta 292, 763-771 Vermeglio, A. and Mathis, P. (1973) Biochim. Biophys. Acta 314, 57-65 Kok, B.,Forbusch, B. and MC Gloin, M. (1970) Photochem. Photobiol. II,
103-I 7.
8. 9. 10. II.
Biophys. Biochim.
COMMUNICATIONS
Acta 234, 371-380 Biophys. Acta 226
12
457-475
12. 13.
14. 15.
Butler, W.L., Visser, J.W.M. and Simons, H.L. (1973) Biochim. Biophys.Acta 292, 140-151 Joliot, P. and Joliot,A. (1972) in Proc. 2nd Int. Congr. Photosynth. (Forti G ., Avron, M. and Melandri, A., eds) Vol. I, pp.26-38, Dr. Junk N.V. Publishers, The Hague. Okayama, S. and Butler, W.L. (1972) Biochim. Biophys. Acta, 267, 523-529 Joliot, P. and Joliot, A. (1973) Biochim. Biophys. Acta 305, 302-316
688