912
decrease in the proportion of the fast component at 460 nm. It should also be noted that the very fast component
(or scattering, see above) disappears almost completely in chloroplasts (not shown), which is in accordance with
the less scattering properties of organelles in solution compared to leaves. Finally, the largest contribution of the
very slow component is seen in the mesophyll (17 %). For the results of Table 2, the analysis was performed
individually on each decay, allowing the program to fit freely both the lifetime and pre-exponential factors from
which fractional contributions were computed. When the global fit was applied to the data, common lifetimes
were fitted to all decays. This accentuated even further the described changes in fractional contributions of the four
components to fluorescence in different types of sample (data not shown).
We further analyzed the kinetic components of the mesophyll by comparing the wavelength combination
which favoured either nicotinamide (340/430) or flavin (375/525) nucleotide fluorescence (cf. Table 1.). From
Table 3 it can be seen that the fast and medium components were almost un-affected. The fractional contribution
of the slow component was increased under conditions favoring flavin fluorescence (excitation 375 nm, emission
525 nm) and that of the very slow component doubled under conditions favouring nicotinamide fluorescence
(excitation 340 nm, emission 430 nm). Excitation at 420 nm, where nicotinamide nucleotides do not absorb at
all, favoured substantially the emission of the medium and slow components (Table 3). The fast and very slow
components were not only decreased accordingly, but also the lifetime of the fast component was decreased and
the lifetime of the very slow component increased, suggesting that the major fluorophores contributing to these
two components are different under this type of excitation.
The confirmation for the involvement of flavin nucleotides in the slow component and nicotinamide
nucleotides in the very slow component came from the investigation of the effect of the gas phase (nitrogen or
air) on mesophyll fluorescence. The fast and medium component did not show any significant change in their
fractional contribution when the gas phase was changed and therefore are not shown in Fig. 2. By contrast,
changes in the slow and very slow components could clearly be seen. Under the reducing atmosphere of nitrogen
most of the nucleotides would be reduced. Pyridine nucleotides (NADH and NADPH) fluoresce when they are
reduced, while flavin nucleotides (FMN and FAD) fluoresce when they are oxidized [21]. The nitrogen atmosphere
brings a decrease in the fractional contribution of the slow component especially pronounced in the green (520
nm) at the fluorescence maximum of flavins. By contrast, the very slow component has an increased contribution
under nitrogen compared to air both at 460 nm, where pyridine nucleotides have a fluorescence maximum, and at
520 nm, where their fluorescence is still 50 % of the maximum [19].
4-DISCUSSION
In the present work four kinetic components of blue-green fluorescence could be resolved and defined in
leaves, mesophyll and chloroplasts of sugar beet. The medium (1 ns) and slow (4 ns) components were already
well resolved in intact spinach leaves (adaxial side) and could be discussed [2]. The lifetimes and contributions of
the fast (0.3-0.4 ns) and very slow (8-11 ns) components differ from those found in the work of Goulas et al.
(1990) due to several important changes in the measurements and analysis of fluorescence decays. In the present
work the temperature and gas phase of the sample were rigorously controlled. The accumulation of counted
photons was doubled (30.000 counts at maximum) permitting better statistics, which is especially important for
the slow components. The excitation was made at longer wavelengths that favoured nucleotide excitation and was
less absorbed by flavonoids [22]. Several convolution models were compared which involved scattered light and
background. A global fit could be performed on several decays. All these changes permitted to define well the fast
and very slow kinetic components and to analyze the spectral characteristics and relative contribution of all four
components at different levels of leaf organization.
The fast and medium components dominate the fluorescence of the intact leaf (on both sides). They have
a blue maximum, and are probably composed of fluorescent flavonoids of the vacuole [23, 24] or phenolic acids
of the cell wall [25, 2]. Total fluorescence of intact leaves is strongly influenced by these fluorophores of the
epidermal layer (including cuticle) [8, 4] precluding the investigation on changes of mesophyllic fluorophores
especially in the blue part of the spectrum. This is why actinic light-induced changes of blue-green fluorescence
could not be seen in intact mature leaves [5, 6] although there were claims that most of the blue florescence in
leaves comes from pyridine nucleotides [3]. Still, results of DAS show that the contribution of mesophyll
fluorescence is more pronounced in the green part of the spectrum, confirming the conclusion of Lang et al.
(1992) [4] and suggesting that light-induced changes should be searched for in this spectral region. The presence
of "screening" compounds (plant phenolics and alkaloids) is not restricted to the epidermal layer and cuticle and
some of them can be found in the mesophyll too, the amount depending on plant species [26, 24]. This seems to
be the case with sugar beet, judging from the important contribution of the fast and medium kinetic components
of mesophyll fluorescence. Unfortunately the data on fluorescence lifetimes on most plant phenolics are missing
and, although the presence of quercetin, p-coumaric acid, kaempferol and especially ferulic acid is well
documented in sugar beet [26], the exact assignment of the fast and medium component should await time-
resolved studies of these compounds. All we can conclude at this point is that these short-lived component are far
more abundant in the epidermis than in the mesophyll, and more on the adaxial than abaxial side [23,24] and that
they are responsible for the blurred picture of total blue-green fluorescence of leaves.
