22
: very fast component
is in accordance with
;st contribution of the
alysis was performed
xmential factors from
ta, common lifetimes
ntributions of the four
velength combination
: (cf. Table 1.). From
ractional contribution
ion 375 nm, emission
inamide fluorescence
ides do not absorb at
he fast and very slow
nt was decreased and
contributing to these
ent and nicotinamide
as phase (nitrogen or
Scant change in their
Fig. 2. By contrast,
mosphere of nitrogen
oresce when they are
; nitrogen atmosphere
:ed in the green (520
ncreased contribution
nee maximum, and at
solved and defined in
ponents were already
; and contributions of
vork of Goulas et al.
lecays. In the present
mulation of counted
lecially important for
ie excitation and was
ed scattered light and
to define well the fast
attribution of all four
oth sides). They have
24] or phenolic acids
î fluorophores of the
iphyllic fluorophores
e-green fluorescence
e blue florescence in
bution of mesophyll
usion of Lang et al.
region. The presence
layer and cuticle and
6, 24]. This seems to
t kinetic components
thenolics are missing
ferulic acid is well
t should await time-
ed component are far
side [23, 24] and that
21
20
19
18
17
16
15
14
ent
Fig. 2. Effect of gas phase on the slow and very slow component of mesophyll fluorescence.
Fluorescence was excited with 360 nm light and decays recorded at the emission wavelength indicated on
graph. The decays were convoluted using the "4-component with scattered light" model, and the
fractional intensity calculated as described in Table 1. Humidified pure nitrogen (N 2 ) or air (AIR) were
flown over the sample at a rate of 45 1/h. The temperature was 20°C.
Because of the blue fluorescence of the epidermis, the blue/green ratio proposed as a stress signature [1,
9] would reflect mainly changes in epidermal phenolics. For the same reasons, the well-established practice in
biomedical studies to estimate the redox state of tissue by measuring the blue/green ratio of nucleotide
fluorescence [14, 27] is precluded in leaves. For the study of nucleotides involved in bioenergetics of leaves, it is
therefore preferable to use the green emission, even though nicotinamide nucleotides have a maximum emission
in the blue. At 520 nm, the emission of NAD(P)H is still 50 %.
Several lines of evidence indicate the presence of flavin nucleotides in the slow kinetic component at any
given level of organization of the leaf: matched lifetime, emission maximum in the green, preferential excitation
at 420 nm and increased fractional contribution under air. On the other hand, the very slow component shows all
the characteristics reflecting the presence of nicotinamide nucleotides: maximal contribution to fluorescence in
mesophyll, minimal in darkened chloroplasts (oxidized), preferential excitation at 340 nm and an increase of
fractional contribution upon reduction under nitrogen. The apparent discrepancy concerning the lifetime is
elevated when taking into account that in the cell the pools of nucleotides are almost totally bound to enzymes
[13]. When bound to proteins, the lifetime of nicotinamide nucleotide increases by one order of magnitude [19,
28] and can attain 9.5 ns for ternary complexes with substrates [29].
An advantage could be gained from this presence of nicotinamide and flavin nucleotides in two different
kinetic components of fluorescence. The ratio of the fractional contribution of the slow and very slow component
could be used as a measure of cellular redox sate. Under reducing conditions in the cell, nicotinamide nucleotides
are reduced, the fractional contribution of the very slow component is increased, as opposed to a reduction of
flavin nucleotides which brings a decrease in contribution of the slow component (recall that flavins are
fluorescent when in an oxidized state). This ratio of the slow and very slow fluorescence component can be
measured at a single wavelength, which eliminates the problem of screening and reabsorption, especially the
reabsorption in the blue by the omnipresent chlorophyll. The most promising way to extract information on the
redox state of nucleotides in intact leaves would be to combine the approach of actinic light induced variable
fluorescence [6] and time-resolved measurements.
Acknowledgements
Part of the work described here was supported by the EUREKA project No. 380 (LASFLEUR). The visit of
Z.G.C. and F.M. to LURE was financed by CNRS (Program Interdisciplinaire pour la Recherche sur
lEnvironement) and the French Ministry of Foreign Affairs, respectively.
