- Research article
- Open Access
Mechanisms by which the infection of Sclerotinia sclerotiorum (Lib.) de Baryaffects the photosynthetic performance in tobacco leaves
BMC Plant Biology volume 14, Article number: 240 (2014)
Sclerotinia sclerotiorum (Lib.) de Bary is a necrotrophic fungal pathogen which causes disease in a wide range of plants. An observed decrease in photosynthetic performance is the primary reason for the reduction of crop yield induced by S. sclerotiorum. The H2C2O4 is the main pathogenic material secreted by S. sclerotiorum, but the effects of H2C2O4 acidity and the C2O42- ion on photosynthetic performance remain unknown.
S. sclerotiorum infection significantly decreased photosynthetic O2 evolution and the maximum quantum yield of photosystem II (Fv/Fm) in tobacco leaves under high-light. H2C2O4 (the main pathogenic material secreted by S. sclerotiorum) with pH 4.0 also significantly decreased photosynthetic performance. However, treatment with H3PO4 and HCl at the same pH as H2C2O4 caused much less decrease in photosynthetic performance than H2C2O4 did. These results verify that the acidity of the H2C2O4 secreted by S. sclerotiorum was only partially responsible for the observed decreases in photosynthesis. Treatment with 40 mM K2C2O4 decreased Fv/Fm by about 70% of the levels observed under 40 mM H2C2O4, which further demonstrates that C2O42- was the primary factor that impaired photosynthetic performance during S. sclerotiorum infection. K2C2O4 treatment did not further decrease photosynthetic performance when D1 protein synthesis was fully inhibited, indicating that C2O42- inhibited PSII by repressing D1 protein synthesis. It was observed that K2C2O4 treatment inhibited the rate of RuBP regeneration and carboxylation efficiency. In the presence of a carbon assimilation inhibitor, K2C2O42 treatment did not further decrease photosynthetic performance, which infers that C2O42- inhibited PSII activity partly by repressing the carbon assimilation. In addition, it was showed that C2O42- treatment inhibited the PSII activity but not the PSI activity.
This study demonstrated that the damage to the photosynthetic apparatus induced by S. sclerotiorum is not only caused by the acidity of H2C2O4, but also by C2O42- which plays a much more important role in damaging the photosynthetic apparatus. C2O42- inhibits PSII activity, as well as the rate of RuBP regeneration and carboxylation efficiency, leading to the over production of reactive oxygen species (ROS). By inhibiting the synthesis of D1, ROS may further accelerate PSII photoinhibition.
Sclerotinia sclerotiorum (Lib.) de Bary is a necrotrophic fungal pathogen which causes disease in a wide range of plants, leading to enormous crop reduction ,. Previous studies demonstrated that H2C2O4 is an important pathogenic determinant of S. sclerotiorum. S. sclerotiorum mutants deficient in oxalate biosynthesis were shown to be less pathogenic than wild-type fungus, and enhancement of H2C2O4 degradation capacity was shown to enhance plant resistance to S. sclerotiorum-.
A great deal of researches have been conducted on the pathogenic mechanisms of S. sclerotiorum. It was reported that S. sclerotiorum can maintain maximal activity of cell wall-degrading enzymes such as polygalacturonase through the acid environment provided by H2C2O4. The cell wall is a natural barrier shield which protects plant tissues from pathogenic bacteria. S. sclerotiorum can weaken the cell wall through chelation of Ca2+ ions present in the cell wall with oxalic ions, breaking down Ca2+-dependent signal transduction pathways in the host plant . NADPH oxidase, which is involved in reactive oxygen species generation, is required for the pathogenic development and is important for ROS regulation in the successful pathogenesis of S. sclerotiorum. Recently, it was also reported that S. sclerotiorum (via H2C2O4) generates reducing conditions that suppress host defense responses, including the oxidative burst and callose deposition, during the initial stages of infection. However, once infection is established, S. sclerotiorum benefits to its infection by inducing the generation of plant ROS and programmed cell death (PCD) ,.
The leaves of host plant, the primary sites of photosynthesis, are the main targets of many pathogens. The infection of pathogens to the leaves directly reduces photosynthetic performance, leading to drastic losses in crop yield. The repression of photosynthesis in host plants induced by pathogens has been reported in many plant species. For example, photosynthesis was decreased in barley infected by B. graminis. And down-regulation of photosystem II quantum yield in host plants occurred during the infection of Pseudomonas syringae, Albugo candida, Puccinia coronata and Blumeria graminis,, as well as Botrytis cinerea. It was also reported that the expression of sugar-regulated photosynthetic genes, such as the small subunit of ribulose-1,5-bisphosphate carboxylase and chlorophyll a, b binding protein, in most cases, were down-regulated after pathogen infection .
S. sclerotiorum infection could also decrease photosynthetic performance in host plants. During S. sclerotiorum infection, H2C2O4 promotes the accumulation of osmotically active molecules, inducing stomatal opening and inhibiting ABA induced stomatal closure, leading to foliar wilting . In our previous work, S. sclerotiorum infection was shown to induce the over-accumulation of H2O2 in cucumber leaves due to inhibition of the activity of catalase, damaging the functions of photosystem I (PSI) and photosystem II (PSII) . Although H2C2O4 was determined to be the main toxin secreted by S. sclerotiorum, it is still unknown whether the destructive effect of S. sclerotiorum on the host photosynthetic apparatus is due to the acidity of H2C2O4 or the effect of the C2O42- anion, and if either of them has a deleterious effect, what is the mechanism of impairment of photosynthetic performance?
In order to address this question, we compared the effect of H2C2O4 acidity and C2O42- ion on the photosynthetic performance of tobacco leaves, and studied the effects of C2O42- on the photosynthetic electron transport chain, carbon assimilation, the production of ROS and the synthesis of D1 protein in tobacco leaves under high-light treatment. The PSI activity and cyclic electron transport activity were also measured using modulated 820 nm reflection (MR820 nm) techniques -.
Effect of S. sclerotiorum infection on O2 evolution and PSII activity of leaves
The O2 evolution rate reflects the capacity of the photosynthetic apparatus, including both the electron transport chain and carbon assimilation. The fluorescence parameter Fv/Fm, providing an estimate of the maximum quantum yield of primary photochemistry, is widely used to reflect the extent of photoinhibition ,. Both the photosynthetic O2 evolution rate and Fv/Fm decreased significantly in leaves infected with S. sclerotiorum when compared with controls, and the decreasing extent increased with the lasting of infection (Figure 1). This result indicates that S. sclerotiorum infection significantly inhibited photosynthesis and aggravated the photoinhibition in tobacco leaves under high-light.
The effect of H2C2O4 and other acids on the activity of PSII
It has been proved that H2C2O4 is the primary pathogenic material secreted by S. sclerotiorum-. Additionally, injection of exogenous H2C2O4 can mimic disease symptoms of an actual fungal infection ,. So H2C2O4 was used in the following experiments to study the effect of S. sclerotiorum on the photosynthetic performance in host plants. Because the pH and concentration of H2C2O4 in the culture solution of S. sclerotiorum were 4.0 and 40 mM respectively after 14 days growing of the S. sclerotiorum, 40 mM H2C2O4 with pH 4.0 (adjusted with KOH) was used to treat leaves in this experiment.
In order to distinguish the effect of H2C2O4-mediated acidity from the effect of C2O42- anion on photosynthetic performance, the effects of acidity (pH 4.0) provided by H2C2O4 (40 mM, pH adjusted to 4.0 with KOH), H3PO4 and HCl, respectively, were compared to 40 mM K2C2O4.
The Fv/Fm decreased significantly in leaves treated with HCl (pH 4.0), H3PO4 (pH 4.0), H2C2O4 (40 mM, pH adjusted to 4.0) and K2C2O4 (40 mM) after high-light treatment (Figure 2A). The decrease of Fv/Fm in HCl and H3PO4 treated leaves was only slightly lower than that in CK leaves after high-light treatment. However, H2C2O4 treatment significantly decreased Fv/Fm in tobacco leaves (Figure 2). When K2C2O4 was used to eliminate H2C2O4 acidity in the experiment, the PSII activity was also severely inhibited under high-light. The extent of K2C2O4 inhibition of Fv/Fm reached 69.7% of the inhibition induced by H2C2O4 (Figure 2A). Meanwhile, the Fm of the normalized fluorescence transient in K2C2O4 treated leaves decreased much more than that in HCl and H3PO4 treated leaves (Figure 2B), and the decreased extent was only a bit smaller than that in H2C2O4 treated leaves. The results indicate that the influence of H2C2O4 on photosynthetic performance was mainly caused by the C2O42- anion.
The effect of different concentrations of K2C2O4 on the activity of PSII
In leaves treated with 20, 40, 60 mm K2C2O4 and 120 mm KCl, Fv/Fm decreased significantly in high light (800 μmol · cm-2 · s-1; Figure 3A). When the treated leaves were placed in low light (50 μmol · cm-2 · s-1) for recovery after photoinhibition treatment, the Fv/Fm in all leaves recovered to a large extent. However, the Fv/Fm in K2C2O4 treated leaves recovered less than that in the control and KCl treated leaves (Figure 3A). Nonetheless, no significant differences were observed in Fv/Fm between different treatment groups in the dark (Figure 3B). There was no significant difference in Fv/Fm between KCl treated leaves and the control leaves either. Because 120 mm KCl has the same concentration of K+ as 60 mm K2C2O4 does, and it has lower osmotic potential than 60 mm K2C2O4, the effect of K+ and osmotic stress on the result was then neglected.
In high light (800 μmol · cm-2 · s-1) for 2 hours, the electron transport rate (ETR) and photochemical quenching (qP) in K2C2O4 treated leaves decreased much more than that in control and KCl treated leaves, meanwhile, NPQ was higher in K2C2O4 treated leaves than that in the leaves with other treatment (Figure 4). This result further indicates that K2C2O4 treatment aggravates PSII photoinhibition in tobacco leaves under high-light.
In the presence of chloramphenicol (CM), an inhibitor of de novo D1 protein synthesis ,, K2C2O4 treatment did not aggravate the decrease of Fv/Fm (Figure 5). And the large difference in P point of the OJIP curves between different treatments was eliminated by CM treatment, which indicates that the inhibition of D1 protein by C2O42- accelerated the photoinhibition of PSII in leaves treated with H2C2O4 under high-light.
The effect of K2C2O4 treatment on the accumulation of hydrogen peroxide (H2O2)
As shown in Figure 6, K2C2O4 treatment obviously enhanced the accumulation of H2O2 in tobacco leaves under high light when compared with control and KCl treated leaves, which indicates that K2C2O4 treated leaves suffered from greater photo-oxidative stress.
The effect of K2C2O4 on carbon assimilation
A photosynthetic model suggests that CO2 assimilation in C3 plants is limited by the rate of RuBP regeneration at high levels of CO2, and is limited by the efficiency of Rubisco at lower levels of CO2. In tobacco leaves treated with K2C2O4, carboxylation efficiency (CE) and net photosynthetic rate (Pn) at saturated CO2 (Am) both decreased severely compared to the control, at magnitudes which increased with K2C2O4 concentration (Figure 7). However, no significant decreases in CE and Am were observed in leaves treated with 120 mm KCl. It suggests that C2O42- inhibited both Rubisco activity and RuBP regeneration. In addition, after exposed to light for 2 h, the contents of both soluble sugar and starch in K2C2O4 treated leaves were significantly lower than those in control and KCl treated leaves (Figure 8), which demonstrates that C2O42- significantly inhibited Calvin cycle.
To further investigate the effect of K2C2O4 on carbon assimilation, leaves were pretreated with iodoacetamide (IAM), an inhibitor of the Calvin cycle ,. In the presence of IAM, no significant differences were observed in Fv/Fm between K2C2O4 treated leaves and control leaves after high light treatment (Figure 9). This result implies that when CO2 assimilation was inhibited, K2C2O4 didn't further aggravate the photoinhibition under high light proving that the severe photoinhibition caused by the K2C2O4 may be due in part to inhibition of the Calvin cycle. The inference was also supported by the fact that IAM treatment eliminated the difference in OJIP curves between K2C2O4 treated leaves and CK.
The effect of K2C2O4 on PSI activity and cyclic electron flow
The PSI activities in control leaves, and leaves treated with KCl and K2C2O4 were measured. No significant differences were observed in PSI activity between leaves with different treatments (Figure 10). However, the initial increase rate of MR820nm in K2C2O4 treated leaves after far-red illumination significantly decreased (Figure 11), which indicates a decrease in cyclic electron flow in K2C2O4 treated leaves.
S. sclerotiorum infection significantly inhibited photosynthesis (Figure 1), which suggests that the photosynthetic apparatus is a major pathogenic target. In this study, we demonstrated that H2C2O4, the most important pathogenic determinant of S. sclerotiorum infection, inhibited photosynthetic activity in tobacco leaves more severely than HCl and H3PO4 did at the same pH. The C2O42- anion appeared to play a more important role in damaging the photosynthetic performance than the acidity did, which was supported by the fact that the inhibition of K2C2O4 on PSII activity reached about 70% of the effect observed with H2C2O4 (Figure 2).
Therefore, K2C2O4 was used to study the mechanisms by which S. sclerotiorum affects photosynthetic performance in tobacco leaves. It has been known that the infection of S. sclerotiorum decreases chlorophyll content and causes the appearance of chlorotic symptom in host plants. However, the decrease in chlorophyll content often occurs after infection for several days ,, in our experiment, the treatment period is only about 5 h, so the decrease in chlorophyll content didn't occur in the experiment (Additional file 1: Figure S1). The result indicates that the effect of K2C2O4 on photosynthetic apparatus does not depend on the degradation of chlorophyll.
Fv/Fm, ETR and qP decreased significantly in K2C2O4 treated leaves but the NPQ increased, indicating that the activity of PSII was significantly damaged by C2O42-.We propose that during S. sclerotiorum infection, the decreased PSII activity was probably due to the damage to the reaction centre and acceptor side of PSII by C2O42- secreted by S. sclerotiorum because there was no difference observed in Wk (an indicator of the activity of the donor side of PSII ,) between K2C2O4 treated leaves and control leaves (Additional file 2: Figure S2), and Ψo (an indicator of electron transport at PSII acceptor side ) decreased in K2C2O4 treated leaves (Additional file 3: Figure S3). In the dark, no significant difference was observed in Fv/Fm between K2C2O4 treated leaves and control (Figure 4), demonstrating that C2O42- inhibited the photosynthetic electron transfer chain in an indirect, light-dependent manner.
PSII photoinhibition occurs when the absorbed light is more than it can be used by photochemistry ,. However, photosynthetic organisms are able to overcome PSII photoinhibition by rapidly and efficiently repairing the damage, which requires the synthesis of proteins de novo, such as D1 . Under high-light, the PSII activity depends on the balance between the rates of photodamage and repair; consequently, photoinhibition of PSII becomes apparent when the rate of photodamage exceeds the rate of repair -. As observed in the study, in the presence of CM, the K2C2O4-mediated decrease of Fv/Fm and changes of OJIP curves were eliminated (Figure 5), which indicates that inactivation of PSII by the C2O42- was largely caused by inhibition of D1 protein synthesis. Recently, it was suggested that all environmental stresses enhance photoinhibition through an indirect method - promoting the production of ROS to inhibit the repair of the D1 protein ,. In this study, a marked increase of H2O2 was observed in leaves treated with C2O42- (Figure 6), inferring that the increase of the ROS may inhibit D1 protein synthesis. However, further study is needed to clarify whether D1 protein synthesis was inhibited by accumulation of ROS caused by C2O42-, or via some combination of the accumulation of ROS and C2O42- direct effect.
The chloroplast photosynthetic electron transport chain is one of the major sites of ROS production in leaves of green plants -. The photosynthetic electron transport and carbon assimilation work coordinately under normal physiological conditions. The damage or inhibition of either one of the two components would lead to increased ROS production. The fact that both the CE and Am were significantly inhibited by C2O42- indicates that carbon assimilation processes, including both Rubisco activity and RuBP regeneration (Figure 7 and Additional file 4: Figure S4), were inhibited by C2O42- under high-light, which is further supported by the decrease in the content of soluble sugar and starch in K2C2O4 treated leaves (Figure 8). We suggest that the over accumulation of ROS resulted from the inhibition of CO2 assimilation enhanced C2O42- mediated photoinhibition. This was further supported by the fact that IAM treatment eliminated the decrease in Fv/Fm (Figure 9) and the changes of OJIP curves induced by K2C2O4 under high-light.
It is known that C2O42- can react with many metal ions to form chelate compounds. Rubisco and fructose-1, 6-bisphosphatase are key enzymes in Calvin cycle. It has been reported that Ca2+ and Mg2+ play important roles in the regulation of the activity of chloroplast fructose-1,6-bisphosphatase ,, and Mg2+ has a enhancing effect on the Rubisco activity . We presume the increased C2O42- in plant cells may decrease the activity of Rubisco or fructose-1,6-bisphosphatase through forming chelate compounds with Ca2+ or Mg2+ in chloroplast. Moreover, the signal role of H2C2O4 during the infection of S. sclerotiorum has been demonstrated ,,, the increased C2O42- in plant cells may also interfere with CO2 assimilation through signal transduction. However, to determine the specific mechanism by which C2O42- inhibit the Calvin cycle needs further studies.
Under high-light treatment, though PSI activity was not damaged by C2O42- (Figure 10), cyclic electron flow around PSI was decreased by K2C2O4 treatment (Figure 11). The over-reducing of PSI acceptors, always leading to the increase of the generation of superoxide, would be prevented by an increase of cyclic electron flow around PSI . Moreover, the cyclic electron flow can also decrease the probability that singlet oxygen generates within PSII through charge recombination ,. Further studies are needed to clarify whether the decrease in cyclic electron flow induced by C2O42- is correlated to the increase in ROS generation and the enhancement of PSII photoinhibition in K2C2O4 treated leaves.
Our experiment demonstrated that it is the C2O42- ion secreted by S. sclerotiorum rather than the decrease in pH caused by the H2C2O4 that mainly induces the damage to photosynthetic apparatus. However, we did not exclude that necrosis may also cause inhibition of Calvin cycle and PSII activity. Since the C2O42- ion plays a more important role in impairing photosynthetic apparatus than acidity does, it reasonable to infer that the inhibition of Calvin cycle and PSII activity by necrosis in S. sclerotiorum infected leaves is mainly induced by the C2O42- ion secreted by S. sclerotiorum. Fo is the fluorescence emitted by antenna pigment of PSII with open reaction center. Chlorophyll content and Fo all showed no significant difference among the leaves treated with K2C2O4, CK and KCl, which indicates that the antenna of PSII might not affected by C2O42- in our experiment (Additional file 1: Figure S1 and Additional file 5: Figure S5).
This study demonstrated that H2C2O4 secreted by S. sclerotiorum enhanced photoinhibition, mainly by the effect of the C2O42- ion. C2O42- led to the decrease of both the activity of Rubisco and RuBP regeneration, leading to the accumulation of H2O2 in the chloroplast. The over accumulation of H2O2 inhibited the turnover of the D1 protein. This is likely the primary mechanism by which S. Sclerotiorum infection affects the photosynthetic performance of tobacco leaves. Further studies are needed to explore whether C2O42- has a direct effect on D1 protein synthesis, and to elucidate the detailed mechanisms by which C2O42- inhibits the activity of Rubisco and RuBP regeneration in tobacco leaves. And if the inhibition of Rubisco activity and RuBP regeneration is mediated by the signal effect of C2O42- and if the decrease in PSII activity caused by C2O42- is involved in the PCD induced by S.Sclerotiorum remain to be elucidated in future work.
Tobacco seeds (Nicotiana tabacum L. cv. NC89) were germinated on vermiculite. Thirty days after germination, the seedlings were transplanted to pots containing a compost soil substrate to grow in a greenhouse under a natural photoperiod (day: 25-30°C, night: 20-25°C). Commercial humus, vermiculite and field soil (1:1:1, v:v:v) were mixed as a compost soil substrate. The pots were periodically irrigated with tap water and fertilized twice a month. Just before flowering, the new fully expanded leaves were used in this experiment.
Fungal growth and plant inoculations
S. sclerotiorum was grown on PDA culture at 25°C in the dark for 3-5 days. After this period, mycelial agar plugs of 10 mm diameter were excised and transferred to Maxwell & Lumsden liquid cultures at 25°C in the dark for 14 days. The resultant mycelium was taken for use in leaf inoculation, which was performed according to Walz (2008) and Bu (2009) ,. Leaf segments 2°Cm away from the center of the necrotic spot were cut for measurement of O2 evolution rate and Fv/Fm.
Photosynthetic O2 evolution rate measurement
A Chlorolab-2 liquid-phase oxygen electrode system (Hansatech Instruments, Norfolk, UK) was used to measure the photosynthetic O2 evolution rates of infected leaf discs in 1 mm NaHCO3 solution under saturation light (800 μmol m-2 s-1) at room temperature.
Treatment of plant materials
Leaf disks (10 mm diameter) obtained from new fully expanded leaves were immersed in H3PO4 (pH 4.0), HCL (pH 4.0), H2C2O4 (40 mm, pH adjusted to 4.0 with KOH), 40 mm K2C2O4, or different concentrations (20, 40, 60 mm) of K2C2O4 solution for 3 hours in the dark for sufficient permeation, and then floated on the solution for photoinhibition or recovery treatment. S. sclerotiorum culture medium showed pH ~4.0 and [H2C2O4] ~40 mm; H3PO4, HCL were tested at the same pH. The photoinhibition and recovery of the leaf disks were taken under 800 μmol · m-2 · s-1 light and 50 μmol · m-2 · s-1 light, respectively.
The first new fully expanded leaves from the top of the tobacco plants were excised from the plants at the end of the petiole. The petioles of the excised leaves were quickly dipped into treatment solutions with a second excision in the solution. Treated leaves were then transferred into a growth chamber at 25°C in the dark. Gas exchange parameters were measured after four hours.
Measurement of chlorophyll fluorescence
Chlorophyll a fluorescence transients were measured at room temperature with a Handy Plant Efficiency Analyzer (Hansatech, UK). Illumination was provided by an array of six high intensity LEDs (with a peak of 650 nm) which were focused on the sample surface to provide homogeneous illumination over the exposed area of a sample with 4 mm diameter. Measurements were carried out on leaves dark adapted for 30 min to ensure an initial photochemical activity of zero. During light illumination, chlorophyll a fluorescence intensity in dark-adapted leaves rose rapidly from an initial minimal level, Fo (the O step), to the maximal level, Fm (P step). Two intermediate steps designated J and I appeared at 2 and 30 ms, respectively; hence, a fast rise of the chlorophyll a fluorescence, transient with the notation O-J-I-P, was obtained.
Chlorophyll a fluorescence transients were analyzed by utilizing the original data from polyphasic fluorescence transients according to the JIP test ,,. The following fluorescence parameters were calculated using the JIP test:
The maximum quantum yield of photosystem II (Fv/Fm), Fv/Fm = (Fm-Fo)/Fm; the probability that a trapped exciton moves an electron into the electron transport chain beyond QA- (Ψo), Ψo =1-Vj = 1-(F2ms-Fo)/(Fm-Fo); the normalized relative variable fluorescence at the K band (Wk, K indicates fluorescence extensity at 0.3 ms), Wk = (F0.3 ms - Fo)/(F2 ms - Fo).
Measurements of chlorophyll fluorescence
Modulated chlorophyll fluorescence was measured with an FMS-2 pulse-modulated fluorometer (Hansatech, UK). The light-fluorescence measurement protocol was as follows: the light-adapted leaves were continuously illuminated by actinic light at 800 μmol m-2 s-1 from the FMS-2 light source, steady-state fluorescence (Fs) was recorded after a 2 min illumination, and 0.8 s of saturating light of 8000 μmol m-2 s-1 was imposed to obtain maximum fluorescence in the light-adapted state (Fm'). The actinic light was then turned off, and the minimum fluorescence in the light-adapted state (Fo') was determined by a 3 s illumination with far-red light.
The following parameters were then calculated :
Histochemical detection of H2O2
In situ hydrogen peroxide (H2O2) was detected by DAB staining as previously described . H2O2 reacts with DAB to form a reddish-brown stain. Treated leaf disks were incubated in DAB solution, pH 5.5, at 1 mg/ml. After incubation in the dark at room temperature for 20 h, samples were boiled in alcohol (96%) for 10 min. After cooling, the leaf discs were extracted at room temperature with fresh ethanol and photographed.
Measurements of gas exchange
Net photosynthetic rate (Pn), substomatal CO2 concentration (Ci) was measured at room temperature (25°C) and 60% relative humidity with a portable system (CIRAS-2, PP Systems, UK). The light intensity was set to 800 μmol m-2 s-1. CO2 concentration were changed every 3 min in a sequence of 2 000, 1 600, 1 200, 800, 600, 400, 300, 200, 150, 100, and 0 μmol mol-1. Irradiance and CO2 concentration were controlled by the automatic control function of the CIRAS-2 photosynthetic system. Carboxylation efficiency was calculated according the initial slop of Pn-Ci response curve.
Measurements of soluble sugar and starch in tobacco leaves
The samples (25 leave discs) were grounded in double-distilled water and filtered. The residue was again grounded and filtered. Filtrates were pooled and centrifuged at 10,000 × g for 15 min. The sample solution (0.1 mL) was taken in a test tube and made to 1 mL with double-distilled water. Four millilitre of 0.2% anthrone reagent (0.2 g dissolved in 100 mL conc. H2SO4) was added, and the contents were heated in a boiling water bath and subsequently cooled. The absorbance was read at 620 nm . A mixture of 1 mL distilled water and 4 mL of 0.2% anthrone served as blank. The final residue of the leaves after filtered was resuspended in 1.6 M perchloric acid and incubated in a water bath at 70°C for 2 h. Then samples were centrifuged at 10000 g for 10 min and the carbohydrated concentration in the supernatant was determined via the anthrone method as described above.
Measurements of PSI activity and cylic electron flow around PSI
The modulated reflection signal measured at 820 nm (MR820nm) provides information about oxidation of PSI (concluding PC and P700). MR820nm were recorded using a Multifunctional Plant Efficiency Analyzer, M-PEA (Hansatech Instrument Ltd., UK).The induction curve of MR820nm of the leaves obtained by saturating red light shows a fast oxidation phase and a following reduction phase. The initial slope of oxidation phase of MR820nm at the beginning of the saturated red light indicates the capability of P700 to get oxidized, which is used to reflect the activity of PSI ,,.
Cylic electron flow around PSI of leaves were measured after leaves were dark adapted for 15 min. After illuminated by far-red light for 20 s, the far-red light was turned off and the MR820nm of the leaves was recorded. The initial increase rate of the MR820nm indicates the intensity of cyclic electron flow around PSI . Statistical analysis.
LSD (least significant difference) was used to analyse differences between different treatments by using SPSS 16.
Net photosynthesis rate in saturated CO2
Maximal quantum yield of PSII
Net photosynthesis rate
Density of QA-reducing PSII reaction centres
Reactive oxygen species
- S. sclerotiorum:
Sclerotinia sclerotiorum (Lib.) de Bary
Normalized relative variable fluorescence at the K step
Exciton efficiency of electron transport beyond QA
Boland GJ, Hall R: Index of plant hosts of sclerotinia sclerotiorum. Can J Plant Pathol. 1994, 16 (2): 93-108. 10.1080/07060669409500766.
Bolton MD, Thomma BP, Nelson BD: Sclerotinia sclerotiorum (Lib.) de bary: biology and molecular traits of a cosmopolitan pathogen. Mol Plant Pathol. 2006, 7 (1): 1-16. 10.1111/j.1364-3703.2005.00316.x.
Godoy G, Steadman JR, Dickman MB, Dam R: Use of mutants to demonstrate the role of oxalic acid in pathogenicity of sclerotinia sclerotiorum on phaseolus vulgaris. Physiol Mol Plant P. 1990, 37 (3): 179-191. 10.1016/0885-5765(90)90010-U.
Donaldson PA, Anderson T, Lane BG, Davidson AL, Simmonds DH: Soybean plants expressing an active oligomeric oxalate oxidase from the wheat gf-2.8 (germin) gene are resistant to the oxalate-secreting pathogen sclerotina sclerotiorum. Physiol Mol Plant P. 2001, 59 (6): 297-307. 10.1006/pmpp.2001.0369.
Burke JM, Rieseberg LH: Fitness effects of transgenic disease resistance in sunflowers. Science. 2003, 300 (5623): 1250-10.1126/science.1084960.
Bateman DF, Beer SV: Simultaneous production and synergistic action of oxalic acid and polygalacturonase during pathogenesis by sclerotium rolfsii. Phytopathology. 1965, 55: 204-211.
Kim H, Chen C, Kabbage M, Dickman MB: Identification and characterization of sclerotinia sclerotiorum NADPH oxidases. Appl Environ Microb. 2011, 77 (21): 7721-7729. 10.1128/AEM.05472-11.
Williams B, Kabbage M, Kim H, Britt R, Dickman MB: Tipping the balance: sclerotinia sclerotiorum secreted oxalic acid suppresses host defenses by manipulating the host redox environment. PLoS Pathog. 2011, 7 (6): e1002107-10.1371/journal.ppat.1002107.
Schulze Lefert P, Swarbrick PJ, Scholes JD: Metabolic consequences of susceptibility and resistance (race-specific and broad-spectrum) in barley leaves challenged with powdery mildew. Plant Cell Environ. 2006, 29 (6): 1061-1076. 10.1111/j.1365-3040.2005.01472.x.
Bonfig KB, Schreiber U, Gabler A, Roitsch T, Berger S: Infection with virulent and avirulent P. syringae strains differentially affects photosynthesis and sink metabolism in Arabidopsis leaves. Planta. 2006, 225 (1): 1-12. 10.1007/s00425-006-0303-3.
Chou HM, Bundock N, Rolfe SA, Scholes JD: Infection of arabidopsis thaliana leaves with albugo candida (white blister rust) causes a reprogramming of host metabolism. Mol Plant Pathol. 2000, 1 (2): 99-113. 10.1046/j.1364-3703.2000.00013.x.
Scholes JD, Rolfe SA: Photosynthesis in localised regions of oat leaves infected with crown rust (puccinia coronata): quantitative imaging of chlorophyll fluorescence. Planta. 1996, 199 (4): 573-582. 10.1007/BF00195189.
Berger S, Papadopoulos M, Schreiber U, Kaiser W, Roitsch T: Complex regulation of gene expression, photosynthesis and sugar levels by pathogen infection in tomato. Physiol Plantarum. 2004, 122 (4): 419-428. 10.1111/j.1399-3054.2004.00433.x.
Berger S, Sinha AK, Roitsch T: Plant physiology meets phytopathology: plant primary metabolism and plant-pathogen interactions. J Exp Bot. 2007, 58 (15-16): 4019-4026. 10.1093/jxb/erm298.
Guimarães RL, Stotz HU: Oxalate production by sclerotinia sclerotiorum deregulates guard cells during infection. Plant Physiol. 2004, 136 (3): 3703-3711. 10.1104/pp.104.049650.
Bu JW, Yao G, Gao HY, Jia YJ, Zhang LT, Cheng DD, Wang X: Inhibition mechanism of photosynthesis in cucumber leaves infected by sclerotinia sclerotiorum (Lib.) de bary. Acta Phytopathologica Sinica. 2009, 39 (6): 613-621.
Gao J, Li P, Ma F, Goltsev V: Photosynthetic performance during leaf expansion in malus micromalus probed by chlorophyll a fluorescence and modulated 820 nm reflection. J Photochem Photobiol B. 2014, 137 (8): 144-150. 10.1016/j.jphotobiol.2013.12.005.
Oukarroum A, Goltsev V, Strasser RJ: Temperature effects on pea plants probed by simultaneous measurements of the kinetics of prompt fluorescence, delayed fluorescence and modulated 820 nm reflection. PLoS One. 2013, 8 (3): e59433-10.1371/journal.pone.0059433.
Zhang Z, Jia Y, Gao H, Zhang L, Li H, Meng Q: Characterization of PSI recovery after chilling-induced photoinhibition in cucumber (cucumis sativus L.) leaves. Planta. 2011, 234 (5): 883-889. 10.1007/s00425-011-1447-3.
Björkman O, Demmig B: Photon yield of O2 evolution and chlorophyll fluorescence characteristics at 77 K among vascular plants of diverse origins. Planta. 1987, 170 (4): 489-504. 10.1007/BF00402983.
Vonshak A, Torzillo G, Tomaseli L: Use of chlorophyll fluorescence to estimate the effect of photoinhibition in outdoor cultures of spirulina platensis. J Appl Phycol. 1994, 6 (1): 31-34. 10.1007/BF02185901.
Maxwell DP, Lumsden RD: Oxalic acid production by sclerotinia sclerotiorum in infected bean and in culture. Phytopathology. 1970, 60 (9): 1395-1398. 10.1094/Phyto-60-1395.
Zhou T, Boland GJ: Mycelial growth and production of oxalic acid by virulent and hypovirulent isolates of sclerotinia sclerotiorum. Can J Plant Pathol. 1999, 21 (1): 93-99. 10.1080/07060661.1999.10600090.
Cessna SG, Sears VE, Dickman MB, Low PS: Oxalic acid, a pathogenicity factor for sclerotinia sclerotiorum, suppresses the oxidative burst of the host plant. Sci Signal. 2000, 12 (11): 2191-
Noyes RD, Hancock JG: Role of oxalic acid in the sclerotinia wilt of sunflower. Physiol Plant Pathol. 1981, 18 (2): 123-132. 10.1016/S0048-4059(81)80033-1.
Nishiyama Y, Allakhverdiev SI, Murata N: Protein synthesis is the primary target of reactive oxygen species in the photoinhibition of photosystem II. Physiol Plant. 2011, 142 (1): 35-46. 10.1111/j.1399-3054.2011.01457.x.
Zhang LT, Zhang ZS, Gao HY, Xue ZC, Yang C, Meng XL, Meng QW: Mitochondrial alternative oxidase pathway protects plants against photoinhibition by alleviating inhibition of the repair of photodamaged PSII through preventing formation of reactive oxygen species in rumex K-1 leaves. Physiol Plant. 2011, 143 (4): 396-407. 10.1111/j.1399-3054.2011.01514.x.
Farquhar GD, von von Caemmerer S, Berry JA: A biochemical model of photosynthetic CO2 assimilation in leaves of C3 species. Planta. 1980, 149 (1): 78-90. 10.1007/BF00386231.
Yamanaka R, Nakamura K, Murakami A: Reduction of exogenous ketones depends upon NADPH generated photosynthetically in cells of the cyanobacterium synechococcus PCC 7942. AMB Express. 2011, 1 (1): 1-8. 10.1186/2191-0855-1-24.
Xu Z, Luo G, Ke D, Chen J, Chen Y, Wang A: Chlorophyll fluorescence quenching induced by superoxide anion. Prog Biochem Biophys. 2002, 29 (1): 139-143.
Pedras MSC, Ahiahonu PW: Phytotoxin production and phytoalexin elicitation by the phytopathogenic fungus sclerotinia sclerotiorum. J Chem Ecol. 2004, 30 (11): 2163-2179. 10.1023/B:JOEC.0000048781.72203.6c.
Hollowell JE, Shew BB: Yellow nutsedge (cyperus esculentus L.) as a host of sclerotinia minor. Plant Dis. 2001, 85 (5): 562-10.1094/PDIS.2001.85.5.562C.
Strasser BJ: Donor side capacity of photosystem II probed by chlorophyll a fluorescence transients. Photosynth Res. 1997, 52 (2): 147-155. 10.1023/A:1005896029778.
Zhang Z, Li G, Gao H, Zhang L, Yang C, Liu P, Meng Q: Characterization of photosynthetic performance during senescence in stay-green and quick-leaf-senescence Zea Mays L. Inbred lines. Plos One. 2012, 7 (8): e42936-10.1371/journal.pone.0042936.
Strasser RJ, Tsimilli-Michael M, Srivastava A: Analysis of the chlorophyll a fluorescence transient. Chlorophyll a Fluorescence: A Signature of Photosynthesis. Edited by: Papageogiou GC, Govindjee. Springer, Dordrecht; 2004:321-362. 10.1007/978-1-4020-3218-9_12.
Anderson JM, Chow WS: Structural and functional dynamics of plant photosystem II. Philos Trans R Soc Lond B Biol Sci. 2002, 357 (1426): 1421-1430. 10.1098/rstb.2002.1138.
Tyystjärvi E, Aro E: The rate constant of photoinhibition, measured in lincomycin-treated leaves, is directly proportional to light intensity. Proc Natl Acad Sci U S A. 1996, 93 (5): 2213-2218. 10.1073/pnas.93.5.2213.
Aro E, Virgin I, Andersson B: Photoinhibition of photosystem II. Inactivation, protein damage and turnover. Biochim Biophys Acta. 1993, 1143 (2): 113-134. 10.1016/0005-2728(93)90134-2.
Nishiyama Y, Allakhverdiev SI, Murata N: A new paradigm for the action of reactive oxygen species in the photoinhibition of photosystem II. Biochim Biophys Acta. 2006, 1757 (7): 742-749. 10.1016/j.bbabio.2006.05.013.
Takahashi S, Murata N: How do environmental stresses accelerate photoinhibition?. Trends Plant Sci. 2008, 13 (4): 178-182. 10.1016/j.tplants.2008.01.005.
Murata N, Takahashi S, Nishiyama Y, Allakhverdiev SI: Photoinhibition of photosystem II under environmental stress. Biochim Biophys Acta. 2007, 1767 (6): 414-421. 10.1016/j.bbabio.2006.11.019.
Apel K, Hirt H: Reactive oxygen species: metabolism, oxidative stress, and signal transduction. Annu Rev Plant Biol. 2004, 55: 373-399. 10.1146/annurev.arplant.55.031903.141701.
Shen BO, Jensen RG, Bohnert HJ: Increased resistance to oxidative stress in transgenic plants by targeting mannitol biosynthesis to chloroplasts. Plant Physiol. 1997, 113 (4): 1177-1183. 10.1104/pp.113.4.1177.
Edreva A: Generation and scavenging of reactive oxygen species in chloroplasts: a submolecular approach. Agr Ecosyst Environ. 2005, 106 (2): 119-133. 10.1016/j.agee.2004.10.022.
Rosa L, Whatley FR: Conditions required for the rapid activation in vitro of the chloroplast fructose-1, 6-bisphosphatase. Plant Physiol. 1984, 75 (1): 131-137. 10.1104/pp.75.1.131.
Hertig C, Ricardo A, Wolosiuk RA: A dual effect of Ca2+ on chloroplast fructose-1, 6-bisphosphatase. Biochem Biophys Res Commun. 1980, 97 (1): 325-333. 10.1016/S0006-291X(80)80171-9.
Liang C, Xiao W, Hao H, Xiaoqing L, Chao L, Lei Z, Fashui H: Effect of Mg2+ on the structure and function of ribulose-1, 5-bisphosphate carboxylase/oxygenase. Biol Trace Elem Res. 2008, 121 (3): 249-257. 10.1007/s12011-007-8050-2.
Kim KS, Min J, Dickman MB: Oxalic acid is an elicitor of plant programmed cell death during sclerotinia sclerotiorum disease development. Mol Plant Microbe In. 2008, 21 (5): 605-612. 10.1094/MPMI-21-5-0605.
Scandalios JG: Oxygen stress and superoxide dismutases. Plant Physiol. 1993, 101 (1): 7-
Macpherson AN, Telfer A, Barber J, Truscott TG: Direct detection of singlet oxygen from isolated photosystem II reaction centres. Biochim Biophys Acta. 1993, 1143 (3): 301-309. 10.1016/0005-2728(93)90201-P.
Hideg É, Spetea C, Vass I: Singlet oxygen production in thylakoid membranes during photoinhibition as detected by EPR spectroscopy. Photosynth Res. 1994, 39 (2): 191-199. 10.1007/BF00029386.
Walz A, Zingen-Sell I, Theisen S, Kortekamp A: Reactive oxygen intermediates and oxalic acid in the pathogenesis of the necrotrophic fungus sclerotinia sclerotiorum. J Plant Pathol. 2008, 120 (4): 317-330. 10.1007/s10658-007-9218-5.
Haldimann P, Strasser RJ: Effects of anaerobiosis as probed by the polyphasic chlorophyll a fluorescence rise kinetic in pea (pisum sativum L.). Photosynth Res. 1999, 62 (1): 67-83. 10.1023/A:1006321126009.
Srivastava A, Jüttner F, Strasser RJ: Action of the allelochemical, fischerellin A, on photosystem II. Biochim Biophys Acta. 1998, 1364 (3): 326-336. 10.1016/S0005-2728(98)00014-0.
Maxwell K, Johnson GN: Chlorophyll fluorescence—a practical guide. J Exp Bot. 2000, 51: 659-668. 10.1093/jexbot/51.345.659.
Thordal Christensen H, Zhang Z, Wei Y, Collinge DB: Subcellular localization of H2O2 in plants. H2O2 accumulation in papillae and hypersensitive response during the barley—powdery mildew interaction. Plant J. 1997, 11 (6): 1187-1194. 10.1046/j.1365-313X.1997.11061187.x.
Dubois M, Gilles KA, Hamilton JK, Rebers PT, Smith F: Colorimetric method for determination of sugars and related substances. Anal Chem. 1956, 28 (3): 350-356. 10.1021/ac60111a017.
Strasser RJ, Tsimilli-Michael M, Qiang S, Goltsev V: Simultaneous in vivo recording of prompt and delayed fluorescence and 820-nm reflection changes during drying and after rehydration of the resurrection plant haberlea rhodopensis. Biochim Biophys Acta. 2010, 1797 (6): 1313-1326. 10.1016/j.bbabio.2010.03.008.
This work was supported by the Specialized research fund for the doctoral program of higher education (20113702110008) and National natural science foundation of China (31370276).
The authors declare that they have no competing interests.
CY performed most of the experiments and wrote the manuscript. HG and CY designed the study. HG directed the study and revised the manuscript. ZZ performed the measurement of cyclic electron transport, PSI activity, NPQ, qP and ETR, and helped to revised the manuscript. ML and XF helped in measuring OJIP transients. All authors read and approved the final manuscript.
Electronic supplementary material
Additional file 1: Figure S1.: The effect of K2C2O4 and KCl treatment on the content of pigment in tobacco leaves at the end of treatment. The "Dark" were dark adapted leaves without any reagent treatment. Different letters indicate significant differences between leaves with different treatments (P < 0.05). Values shown are means ± SE (n = 5). (PDF 17 KB)
Additional file 2: Figure S2.: Effect of HCl (pH 4.0), H3PO4 (pH 4.0), H2C2O4 (40 mm, pH adjusted to 4.0), K2C2O4 (40 mm) and KCl (80 mm) treatment on Wk (A) and K band (O-J normalized, B) in tobacco leaves. Leaf discs (10 mm diameter) were infiltrated with HCL (pH 4.0), H3PO4 (pH 4.0), H2C2O4 (40 mm, pH adjusted to 4.0), K2C2O4 (40 mm) and KCl (80 mm) under darkness for 3 h, followed by exposure to intense light (800 μmol m-2 s-1) for 2 hours. CK were leaves without any reagent treatment. Different letters indicate significant differences between leaves with different treatments (P < 0.05). Values were means ± SE (n = 8). (PDF 16 KB)
Additional file 3: Figure S3.: Effect of HCl (pH 4.0), H3PO4 (pH 4.0), H2C2O4 (40 mm, pH adjusted to 4.0), K2C2O4 (40 mm) and KCl (80 mm) treatment on Ψo(A) and OJIP curves (O-P normalized, B) in tobacco leaves. Leaf discs (10 mm diameter) were infiltrated with HCL (pH 4.0), H3PO4 (pH 4.0), H2C2O4 (40 mm, pH adjusted to 4.0), K2C2O4 (40 mm) and KCl (80 mm) under darkness for 3 h, followed by exposure to intense light (800 μmol m-2 s-1) for 2 hours. CK were leaves without any reagent treatment. Different letters indicate significant differences between leaves with different treatments (P < 0.05). Values were means ± SE (n = 8). (PDF 18 KB)
Additional file 4: Figure S4.: The Pn-CO2 curves of tobacco leaves treated with different concentrations (0, 20, 40, 60 mm) of K2C2O4 and 120 mm KCl. The petioles of detached leaves were dipped into treatment solutions before measurement in the dark for 3 hours. CK were leaves without K2C2O4 and KCl treatment. (PDF 14 KB)
Additional file 5: Figure S5.: The effect of 40 mm K2C2O4 and 80 mm KCl treatment on the Fo in tobacco leaves treated with high-light for 2 hours. CK were leaves without K2C2O4 and KCl treatment. Different letters indicate significant differences between leaves with different treatments (P < 0.05). Values were means ± SE (n = 8). (PDF 15 KB)
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Yang, C., Zhang, Z., Gao, H. et al. Mechanisms by which the infection of Sclerotinia sclerotiorum (Lib.) de Baryaffects the photosynthetic performance in tobacco leaves. BMC Plant Biol 14, 240 (2014). https://0-doi-org.brum.beds.ac.uk/10.1186/s12870-014-0240-4
- Photosynthetic Apparatus
- Tobacco Leave
- Calvin Cycle
- Photosynthetic Performance
- Treated Leaf