i i i mul
10 2
a/b RATIO
ons of the emitters in
h chlorophyll a/b ratio.
> (Nipponbare and Norm
s (CMV-15, CMV-16,
88 ) were used. The data
mbols indicate • F680,
! A F745.
TH(nm)
tee spectra of rice wild-
lutant (MGS- 88 ) plant
(diode-laser) light,
-type plant(a) was 632
autant plant (b) 22.9
brane lipids and protein
induce dissociation of
m I (Fig. 2).
»served at 45°C were
I with exhaust gases of
ur oxides and nitrogen
contained in the exhaust
he reaction center of
& Sugahara, 1979),
f emissions from core
:ver, the chemicals seem
of photosystem II based
tion of 0 3 was different
mild fumigation of Oj
eripheral antenna of
3 incorporated into cells
are considered to generate large amounts of superoxide
radicals (Asada et al., 1977; Peiser & Yang, 1977) which
prevent functions of the protective mechanisms,
superoxide dismutase activity (McCord & Fridovich,
1969) and productions of ascorbate and reduced
glutathione (Asada et al., 1977), for naturally generated
superoxide radicals by photosystem I. Therefore, it
primarily acts on photosystem I. Another action of 0 3
on cell organizations is perturbation of membrane
structures through distortion of lipid bilayers.
Superoxide radicals produced from 0 3 cleave double
bonds of fatty acids rich in chloroplasts, resulting in
separation of peripheral antennas from photosystem □, as
well as photosystem I (Fig. 4c).
The assumed emitters in the current investigation do
not correspond to detailed structures of photosystems
and may involve other components than those assigned
above, however, the spectral changes due to high
temperature and air-pollutants, are primarily explained
by changes of emissions from the emitter components
which are sensitive to variable intrinsic and extrinsic
conditions of leaves. Measurements of laser induced
chlorophyll fluorescence and spectral analysis using the
simulated emitter peaks will provide information as to
how far light reactions of photosynthesis are affected
horn various environmental changes, which is useful for
monitoring terrestrial vegetations in remote sensing.
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