3. Results3.1. Chlorophyll a fluore

3. Results
3.1. Chlorophyll a fluorescence rise
Prompt chlorophyll fluorescence rise measured from all leaves
displayed the typical OJIP transients when plotted on a logarithmic
time scale (Fig. 1AB). To visualise the comparative effect of nutrient
deficiency on the transient dynamics, the curves are plotted as
relative variable fluorescence, Vt ¼ (Ft  Fo)/(FM  Fo) (Strasser et al.,
2004). This experimental expression is taken as a measure of the
fraction of the primary quinone electron acceptor of PSII being in its
reduced state [Q
A ]/[QA.(total)]. The fluorescence transients showed
two steps between O and P: J at about 2 ms and I at about 30 ms.
The OJ phase is strongly light dependent (Neubauer and Schreiber,
1987; Schansker et al., 2006) and contains information on antenna
size and connectivity between PSII reaction centres. The J to P rise is
called the thermal phase (Delosme, 1967) and reflects a reduction
of the rest of the electron transport chain (Schansker et al., 2005).
The shape of the OJIP fluorescence transients recorded in nutrient
deficient (ND) plants of both species differed from those recorded
in control plants (Fig. 1AB). However, nutrient deficiency in maize
plants had stress response markedly different from that of tomato
plants. The major changes in prompt fluorescence of stressed plants
were observed in the J (VJ) and I (VI) levels, except for P-deficiency
in maize plants, and these changes were less prominent in tomato
plants.
Changes in OJIP fluorescence rise kinetics were revealed by
calculating the difference in variable fluorescence curves (DVt). DVt
curves were constructed by subtracting the normalized fluorescence
values (between O and P) recorded in ND plants from those
recorded in control plants (Fig. 2AB). Analysis of the fluorescence
transients revealed that although the major effects of nutrient
deficiency for maize and tomato plants occurred in the O-J phase,
changes were also evident in multiple turnover events of PSII (i.e.
the JeP transition) (Fig. 2AB). The appearance of three bands in
fluorescence intensity in ND plants can be seen, namely a DK (at
w300 ms), DJ peak (at w2 ms) and DI (at 10e30 ms), which
depended on nutrient deficiency and plant species. A clearly
defined DK-band was induced by nutrient deficiency in both maize
and tomato plants (Fig. 2AB), except in P-deficient tomato plants.
However, this change was more important in maize leaves than in
tomato leaves. We noted here that DK-bands are associated with
uncoupling of the oxygen evolving complex (Guisse et al.,1995), and
DJ-bands are associated with accumulation of Q
A , i.e. inhibition of
the Q
A reoxidation. Inactivation of ferredoxin-NADPþ oxidoreductase
(FNR) has also been suggested as a factor that could contribute
towards the appearance of an I-peak (Schansker et al., 2003).
The appearance of DK-band in the fluorescence transients of
stressed plants furthermore pointed at foliar nutrient limitation.
The DJ-bands were much prominent in stressed maize plants
(except in P-deficient plants) than in tomato plants. The appearance of DI-bands in ND maize plants could be a result of an
inhibition of FNR activity. However, the quantitative effect of each
nutrient deficiency was different in maize and tomato plants. For
example, the effect of Ca-deficiency was more prominent in maize
plants than in tomato plants, as observed by the higher amplitude
of DK-band, DJ-band and DI-band. On the other hand, in tomato
plants the K-deficiency had greater effect on these three
parameters.