Abstract
In this study we have generated transgenic Arabidopsis plants over-expressing the Rieske FeS protein (PetC), a component of the cytochrome b6f (cyt b6f) complex. Increasing the levels of this protein, resulted in the concomitant increase in the levels of cyt f (PetA) and cyt b6 (PetB), core proteins of the cyt b6f complex. Interestingly, an increase in the levels of proteins in both the PSI and PSII complexes was also seen in the Rieske FeS ox plants. Although the mechanisms leading to these changes remain to be identified, the transgenic plants presented here provide novel tools to explore this. Importantly, the overexpression of the Rieske FeS protein resulted in a substantial and significant impact on the quantum efficiency of PSI and PSII, electron transport, biomass and seed yield in Arabidopsis plants. These results demonstrate the potential for manipulating electron transport processes to increase crop productivity.
One-sentence summary Over-expression of the Rieske FeS protein results in significant increases in the quantum efficiencies or PSI and PSII, increases in Amax and has the potential to increase crop productivity
Introduction
Increasing food and fuel demands by the growing world population has led to the need to develop higher yielding crop varieties (Fischer and Edmeades, 2010; Ray et al., 2012). Transgenic studies, modelling approaches and theoretical considerations provide evidence that increasing photosynthetic capacity is a viable route to increase the yield of crop plants (Zhu et al., 2010; Raines, 2011; Long et al., 2015; von Caemmerer and Furbank, 2016). There is now a growing body of experimental evidence showing that increasing the levels of photosynthetic enzymes in carbon metabolism, results in increased photosynthesis and plant biomass (Miyagawa et al., 2001; Raines, 2006, 2011; Lefebvre et al., 2005; Rosenthal et al., 2011; Uematsu et al., 2012; Simkin et al., 2015, 2017; Driever et al., 2017). In addition, manipulation of photosynthetic electron transport by introduction of the algal cytochrome c6 protein has been shown to improve the efficiency of photosynthesis and to stimulate plant growth in low light (Chida et al., 2007). One endogenous target identified for manipulation is the cytochrome b6f (cyt b6f) complex which is located in the thylakoid membrane and functions in both linear and cyclic electron transport, providing ATP and NADPH for photosynthetic carbon fixation. Initially, cyt b6f inhibitors (Kirchhoff et al., 2000) and later transgenic antisense studies suppressing the accumulation of the Rieske FeS protein (PetC), a component of the cyt b6f complex, have demonstrated that the activity of the cyt b6f complex is a key determinant of the rate of electron transport (Price et al., 1995, 1998; Anderson et al., 1997; Ruuska et al., 2000; Yamori et al., 2011a,b).
The finding that the cyt b6f complex is a potential limiting step in the electron transport chain suggests that by increasing the activity of this complex it may be possible to increase the rate of photosynthesis. However, questions have been raised about the feasibility of manipulating this multiprotein, membrane located, complex given that it is composed of eight different subunits, six being encoded in the chloroplast genome (PetA (cyt f), PetB (cyt b6), PetD, PetG, PetL and PetN) and two in the nucleus (PetC, (Rieske FeS) and PetM) (Willey and Grey, 1988; Anderson et al., 1992; Knight et al., 2002; Cramer & Zhang, 2006, Cramer et al., 2006; Baniulis et al., 2009; Schöttler et al., 2015). Furthermore, this protein complex functions as a dimer with the transmembrane domains of both the Rieske FeS and cyt b6 proteins being directly implicated in the monomer–monomer interaction and stability of the complex and the petD gene product functioning as a scaffold (Hager et al., 1999; Schwenkert et al., 2007; Hojka et al., 2014; Cramer et al., 2006). Essential roles in the assembly and stability of the cyt b6f complex have also been shown for the PetG, PetN and PetM subunits and a minor role in stability assigned to the PetL gene product (Schöttler et al., 2007; Bruce and Malkin, 1991; Kuras and Wollman, 1994; Hager et al., 1999; Monde et al., 2000; Schwenkert et al., 2007; Hojka et al., 2014).
Notwithstanding both the genetic and structural complexity of the cyt b6f complex, it has been shown previously that it is possible to manipulate the levels of the cyt b6f complex by down regulation of the expression of the Rieske FeS protein (Price. et al., 1998; Yamori et al., 2011a). It has also been shown that the Rieske FeS protein is one of the subunits required for the successful assembly of the cyt b6f complex (Miles, 1982; Metz et al., 1983; Barkan et al., 1986; Anderson et al., 1997). Based on these results, we reasoned that over-expression of the Rieske FeS protein could be a feasible approach to take in order to increase the electron flow through the cyt b6f. In this paper we report on the production of Arabidopsis with increased levels of the tobacco Rieske FeS protein and we show that this manipulation resulted in an increase in photosynthetic electron transport, CO2 assimilation and yield. This work provides evidence that the process of electron transport is potential route for the improvement of plant productivity.
Material and methods
Rieske iron sulphur protein of the cytochrome b6f (cyt b6f)
The full-length coding sequence of the Rieske iron sulphur protein of the cytochrome b6f (X64353) was amplified by RT-PCR using primers NtRieskeFeSF (5’caccATGGCTTCTTCTACTCTTTCTCCAG’3) and NtRieskeFeSR (5’CTAAGCCCACCATGGATCTTCACC’3). The resulting amplified product was cloned into pENTR/D (Invitrogen, UK) to make pENTR-NtRieskeFeS and the sequence was verified and found to be identical. The full-length cDNA was introduced into the pGWB2 gateway vector (Nakagawa et al., 2007: AB289765) by recombination from the pENTR/D vector to make pGW-NtRieske (B2-NtRi). cDNA are under transcriptional control of the 35s tobacco mosaic virus promoter, which directs constitutive high-level transcription of the transgene, and followed by the nos 3' terminator. Full details of the B2-NtRi construct assembly can be seen in Supplemental Fig. S1.
Generation of transgenic plants
The recombinant plasmid B2-NtRi was introduced into wild type Arabidopsis by floral dipping (Clough and Bent, 1998) using Agrobacterium tumefaciens GV3101. Positive transformants were regenerated on MS medium containing kanamycin (50mg L-1), hygromycin (20mg L-1). Kanamycin/hygromycin resistant primary transformants (T1 generation) with established root systems were transferred to soil and allowed to self-fertilize.
Plant Growth Conditions
Wild type T2 Arabidopsis plants resulting from self-fertilization of transgenic plants were germinated in sterile agar medium containing Murashige and Skoog salts, selected on kanamycin and grown to seed in soil (Levington F2, Fisons, Ipswich, UK) and lines of interest were identified by western blot and qPCR. For experimental study, T3 progeny seeds from selected lines were germinated on soil in controlled environment chambers at an irradiance of 130 μmol m-2 s-1 in an 8 h/16 h square-wave photoperiod, with an air temperature of 22°C and a relative humidity of 60%. Plants position was randomised and the position of the trays rotated daily under the light. Leaf areas were calculated from photographic images using ImageJ software (imagej.nih.gov/ij). Wild type plants used in this study were a combined group of WT and null segregants from the transgenic lines, verified by PCR for non-integration of the transgene, as no significant differences in growth parameters were seen between them (Supplemental Fig. S2).
Protein Extraction and Immunoblotting
Four leaf discs (0.6-cm diameter) from two individual leaves were taken, immediately plunged into liquid N2 and subsequently stored at −80°C. Samples were ground in liquid nitrogen and protein quantification determined (Harrison et al., 1998). Samples were loaded on an equal protein basis, separated using 12% (w/v) SDS-PAGE, transferred to polyvinylidene difluoride membrane, and probed using antibodies raised against the cytochrome b6f complex proteins cyt f (PetA: (AS08306), cyt b6 (PetB: (AS03034), Rieske FeS (PetC: AS08330), the photosystem I Lhca1 (AS01005) and PsaA (AS06172) proteins the Photosystem II PsbA/D1 (AS01016) and PsbD/D2 (AS06146) proteins, ATP synthase delta subunit (AS101591), and against the glycine decarboxylase H-subunit (AS05074), all purchased from Agrisera (via Newmarket Scientific UK). FBPA antibodies were raised against a peptide from a conserved region of the protein [C]-ASIGLENTEANRQAYR-amide, Cambridge Research Biochemicals, Cleveland, UK (Simkin et al., 2015). Proteins were detected using horseradish peroxidase conjugated to the secondary antibody and ECL chemiluminescence detection reagent (Amersham, Buckinghamshire, UK). Proteins were quantified using a Fusion FX Vilber Lourmat imager (Peqlab, Lutterworth, UK) as previously described (Vialet-Chabrand et al., 2017).
Chlorophyll Fluorescence Imaging
Chlorophyll fluorescence measurements were performed on 10-day-old Arabidopsis seedlings that had been grown in a controlled environment chamber at a photosynthetic photon flux density (PPFD) of 130 μmol m-2s-1 ambient CO2 at 22°C. Images of the operating efficiency of photosystem two (PSII) photochemistry, (Fq’/Fm’) were taken at PPFDs of 310 and 600 μmol m-2 s-1 using a chlorophyll fluorescence imaging system, (Technologica, Colchester, UK; Barbagallo et al., 2003; Baker and Rosenqvist, 2004). Fq’/Fm’, was calculated from measurements of steady state fluorescence in the light (F’) and maximum fluorescence in the light (Fm’) was obtained after a saturating 800 ms pulse of 6200 μmol m-2 s-1 PPFD using the following equation Fq’/Fm’ = (Fm’-F’)/Fm’. (Baker et al., 2001; Oxborough and Baker 1997a).
A/Ci response curves
The response of net photosynthesis (A) to intracellular CO2 (Ci) was measured using a portable gas exchange system (CIRAS-1, PP Systems Ltd, Ayrshire, UK). Leaves were illuminated using a red-blue light source attached to the gas-exchange system, and light levels were maintained at saturating photosynthetic photon flux density (PPFD) of 1000 μmol m-2 s- 1 with an integral LED light source (PP Systems Ltd, Ayrshire, UK) for the duration of the A/Ci response curve. Measurements of A were made at ambient CO2 concentration (Ca) of 400 μmol mol-1, before Ca was decreased in a stepwise manner to 300, 200, 150, 100, 50 μmol mol-1 before returning to the initial value and increased to 500, 600, 700, 800, 900, 1000, 1100, 1200 μmol mol-1. Leaf temperature and vapour pressure deficit (VPD) were maintained at 22°C and 1 ± 0.2 kPa respectively. The maximum rates of Rubisco-(Vcmax) and the maximum rate of electron transport for RuBP regeneration (Jmax) were determined and standardized to a leaf temperature of 25°C based on equations from Bernacchi et al. (2001), and McMurtrie and Wang (1993) respectively.
Photosynthetic capacity
Photosynthesis as a function of PPFD (A/Q response curves) was measured using a Li-Cor 6400XT portable gas exchange system (Li-Cor, Lincoln, Nebraska, USA). Cuvette conditions were maintained at a leaf temperature of 22°C, relative humidity of 50-60%, and ambient growth CO2 concentration 400 μmol mol-1 for plants grown in ambient conditions). Leaves were initially stabilized at saturating irradiance 1000 μmol m-2 s-1, after which A and gs was measured at the following PPFD levels; 0, 50, 100, 150, 200, 250, 300, 350, 400, 500, 600, 800, 1000 μmol m-2 s-1. Measurements were recorded after A reached a new steady state (1-3 min) and before stomatal conductance (gs) changed to the new light levels. A/Q analyses were performed at 21% and 2% [O2].
PSI and PSII quantum efficiency
The photochemical quantum efficiency of PSII and PSI in transgenic and WT plants was measured following a dark-light induction transition using a Dual-PAM-100 instrument (Walz, Effeltrich, Germany) with a DUAL-DR measuring head. Plants were dark adapted for 20 min before placing in the instrument. Following a dark adapted measurement plants were illuminated with 220 μmol m-2 s-1 PPFD. The maximum quantum yield of PSII was measured following a saturating pulse of light for 600 ms saturating pulse of light at an intensity of 6200 μmol m-2 s-1. The PSII operating efficiency was determined as described by the routines above. PSI quantum efficiency was measured as an absorption change of P700 before and after a saturating pulse of 6200 μmol m-2 s-1 for 300 ms (which fully oxidizes P700) in the presence of far-red light with a FR pre-illumination of 10s. Both measurements were recorded every minute for 5 min). qp or (Fv’/Fm’), was calculated from measurements of steady state fluorescence in the light (F’) and maximum fluorescence in the light (Fm’) whilst minimal fluorescence in the light (Fo’) was calculated following the equation of Oxborough and Baker (1997b). The fraction of open PSII centres (qL) was calculated from qp x Fo’/F (Baker, 2008).
Pigment extraction and HPLC analysis
Chlorophylls and carotenoids were extracted using n,n-dimethylformamide (DMF) as previously described (Inskeep and Bloom, 1985), which was subsequently shown to suppressed chlorophyllide formation in Arabidopsis leaves (Hu et al., 2013). Briefly, two leaf discs collected from two different leaves were immersed in DMF at 4°C for 48 hours and separated by UPLC as described by Zapata et al. (2000).
Leaf Thickness
Leaves of equivalent developmental stage were collected from plants after 28 days of growth. Strips were cut from the centre of the leaf, avoiding the mid-vein, preserved in 5% glutaraldehyde, stored at 4°C for 24 h followed by dehydration in sequential ethanol solutions of 20, 40, 80 and 100%. The samples were placed in LR white acrylic resin (Sigma-Aldrich, Gillingham, UK), refrigerated for 24 h, embedded in capsules and placed at 60°C for 24 h. Sections (0.5μm) were cut using a Reichert-Jung Ultracut microtome (Ametek Gmbh, Munich, Germany), fixed, stained and viewed under a light microscope (Lopez-Juez et al., 1998). Leaf thickness was determined by measuring leaves from two to three plants from line 9 and 11 compared to leaves from four wild type plants.
Statistical Analysis
All statistical analyses were done by comparing ANOVA, using Sys-stat, University of Essex, UK. The differences between means were tested using the Post hoc Tukey test (SPSS, Chicago).
Results
Production and selection of Rieske FeS ox transformants
The full-length tobacco Rieske FeS coding sequence from the cyt b6f complex was used to generate an over-expression construct B2-NtRi (Supplemental Fig. S1). Following floral dipping, transgenic Arabidopsis plants were selected on both kanamycin/hygromycin containing medium (Nakagawa et al., 2007) and plants expressing the integrated transgenes identified using RT-PCR (data not shown). Proteins were extracted from leaves of the T1 progeny allowing the identification of three lines with increased levels of the Rieske FeS protein (PetC) (Supplemental Fig. S3A). Immunoblot analysis of T3 progeny of lines 9, 10 and 11 were shown to have higher levels of the Rieske FeS protein when compared to wild type (WT) (Fig. 1 and Supplemental Fig. S3B). The over-expression of the Rieske FeS protein (hereafter referred to as Rieske FeS ox) resulted in a concomitant increase in both cyt f (PetA) and cyt b6 (PetB) (Fig. 1A). An increase in the level of the PSI type I chlorophyll a/b-binding protein (LhcaI) and an increase in the core protein of PSI (PsaA) was also observed. Furthermore, the D1 (PsbA) and D2 (PsbD) proteins which form the reaction centre of PSII were also shown to be elevated in Rieske FeS ox lines. Finally, an increase in the ATP synthase delta subunit (AtpD) was also observed in Rieske FeS ox lines (Fig. 1A). In contrast, no notable differences in protein levels for either the chloroplastic FBP aldolase (FBPA), the mitochondrial glycine decarboxylase-H protein (GDC-H) or the Rubisco large subunit were observed (Fig. 1A). A quantitative estimate of the changes in protein levels was determined from the immunoblots of leaf extracts isolated from two to three independent plants per lines. An example is shown in Fig. 1B. These results showed a 2-2.5 fold increase in the Rieske Fe S protein relative to WT plants and a similar increase was also observed for cyt f, cyt b6, Lhca1, D2 and PsaA (Fig 1C). No increase in the stromal FBPA protein was evident.
Chlorophyll fluorescence imaging reveals increased photosynthetic efficiency in young Rieske FeS ox seedlings
In order to explore the impact of increased levels of the Rieske FeS protein on photosynthesis the quantum efficiency of PSII (Fq’/Fm’) was analysed using chlorophyll a fluorescence imaging (Baker, 2008; Murchie and Lawson, 2013). A small increase in Fq’/Fm’ was found in the Rieske FeS ox plants at irradiances of 310 μmol m-2 s-1 and 600 μmol m-2s-1 (Fig. 2). Leaf area, generated from these images, was significantly larger in all Rieske FeS ox lines compared to WT (Fig. 2C), but no significant difference in leaf thickness was observed between the leaves of Rieske FeS lines 9 and 11 and that of the WT plants (Supplemental Table S1).
Photosynthetic CO2 assimilation and electron transport rates are increased in the Rieske FeS ox plants
The impact of overexpression of the Rieske FeS protein on the rate of photosynthesis in mature plants was investigated using combined gas exchange and chlorophyll fluorescence analyses. Both the light saturated rate of CO2 fixation (Asat) and the relative light saturated rate of electron transport (rETR), were increased in the Rieske FeS ox lines compared to WT when measured at 2% [O2] (Fig. 3A & B; Table 1). Additionally the light saturated rate of CO2 assimilation at ambient [CO2] was also increased when measured at 21% [O2] (Supplemental Fig. S4). No significant difference in leaf absorbance (Abs) between the Rieske FeS ox and WT plants was found (Table S1).
In plants grown at a light level of 130 μmol m-2 s-1 no difference in the light- or CO2 - saturated rate of CO2 assimilation (Amax) was found. In contrast, in a second group of plants grown at 280 μmol m-2s-1, Amax was greater in the Rieske FeS ox lines 9 and 11 relative to WT (Fig. 3C; Table 1). Further analysis of the A/Ci curves revealed that Jmax was significantly greater in the Rieske FeS ox plants when compared to WT (Table 1), but no significant difference in Vcmax (data not shown) was observed.
The quantum efficiency of PSI and PSII was increased in the Rieske FeS ox plants
To further explore the influence of increases in the Rieske FeS protein on PSII and PSI photochemistry, dark-light induction responses were determined in WT and Rieske FeS ox (lines 11 & 10) using simultaneous measurements of P700 oxidation state and PSII efficiency. These results showed that the quantum yields of both PSI and PSII were increased in the Rieske FeS ox plants compared to WT and that the fraction of PSII centres that were open (qL) was also increased, whilst the level of Qa reduction (1-qp) was lower in leaves of 27 day old plants from line 11. (Fig. 4). NPQ levels were also shown to be lower in the Rieske FeS ox plants together with a reduction in stress induced limitation of NPQ (qN) when compared to WT plants (Fig. 4). Similar results were obtained for both lines 10 and 11 when plants were analysed later in development (34 DAP) (Supplemental Fig. S5). The increases in the quantum yields of PSI and PSII observed here were accompanied by corresponding increase in electron transport rates (ETRI and ETRII; Supplemental Fig. S6).
Growth, vegetative biomass and seed yield is increased in the Rieske FeS ox plants
The leaf area of the Rieske FeS ox lines was significantly greater than WT as early as 10 days after planting in soil and by 18 days were 40-114% larger (Fig. 5). Destructive harvest at day 25 showed that this increase in leaf area translated to an increase in shoot biomass of between 29% - 72% determined as dry weight (Fig. 5C). To determine the impact of increased Rieske FeS protein on seed yield and final shoot biomass a second group of plants was grown in the same conditions as described in Fig 6. Interestingly, 38 days after planting (DAP) 40% of the Rieske FeS ox plants had flowered in contrast to 22% in the WT plants (Fig. 6A). Following seed set (52 DAP) both vegetative biomass (Fig. 6B) and seed yield (Fig. 6C) were determined and although a significant increase in biomass was observed in all of the Rieske FeS ox plants a statically significant increase in seed yield was only evident in line 11.
The pigment content was altered in the Rieske FeS ox plants
The pigment composition of the leaves of the Rieske FeS ox and WT plants was determined. An increase in the levels of chlorophyll a and b (14-29%) was observed in the Rieske FeS ox compared to WT plants (Fig. 7). These increases were accompanied by an increase in the carotenoids, neoxanthin (+38%), violaxanthin (+59%), lutein (+75%) and β-carotene (+169%). No detectable change in the level of zeaxanthin was evident in the Rieske FeS ox plants.
Discussion
In recent years increasing the rate of photosynthetic carbon assimilation has been identified as a target for improvement to increase yield. Evidence to support this has come from the theory and modelling of the photosynthetic process, growth of plants in elevated CO2 and also from transgenic manipulation (Zhu et al., 2010). It was shown previously in antisense studies that reducing the levels of the Rieske FeS protein resulted in a reduction in levels of the cyt b6f complex, a decrease in photosynthetic electron transport and in rice a decrease in both biomass and seed yield was observed (Price et al., 1998; Yamori et al., 2016). These findings identified the cyt b6f complex as a limiting step in electron transport and would suggest that over expression of the Rieske FeS protein may be a feasible route to increase photosynthesis and yield. In this study we show that overexpression of the Rieske FeS protein in Arabidopsis results in an increase in photosynthesis, vegetative biomass and seed yield.
Increased levels of the Rieske FeS protein increased photosynthetic electron transport, CO2 assimilation and biomass
Using chlorophyll fluorescence imaging we have shown that that overexpression of the Rieske FeS protein resulted in an increase in photosynthesis and growth which is evident from the early stages of seedling development. These observed increases in Fq’/Fm’ represent an early indication that the potential quantum yield of PSII photochemistry had been elevated in Rieske ox lines (Genty et al., 1989; Genty et al., 1992; Baker et al., 2007). This early stimulation is maintained into maturity and an increase in the light saturated rate of CO2 assimilation and electron transport rates was evident in the Rieske FeS ox plants. Our data also showed that quantum yields of both PSII and PSI were increased and that the fraction of PSII centres available for photochemistry was increased indicated by an increase in (qL) and a lower 1-qp (Baker et al., 2007; Baker and Oxborough, 2004; Kramer et al., 2004). These results are consistent with what would be predicted from results obtained from the Rieske FeS antisense studies where ETR was reduced (Price. et al., 1998; Ruuska et al., 2000; Yamori et al,. 2011a). However, the impact of overexpression of the Rieske FeS protein was clearly not restricted to increasing the activity of the cyt b6/f complex but resulted in an increase in electron flow through the entire electron transport chain.
Substantial and significant increases in the growth of the rosette area were observed in the Rieske FeS ox plants in the early vegetative phase which resulted in an approximately 30-70% increase in biomass yield in the different lines. Importantly seed yields in line 11, which showed the biggest increases in shoot biomass were also shown to be increased relative to WT.
The Rieske FeS ox plants have increased levels of proteins in the cyt b6f, PSI and PSII complexes
In keeping with our analysis of the electron transport processes in the Rieske FeS ox plants, an increase in the levels of the cyt b6 and cyt f, core proteins of the cyt b6f complex was evident. Furthermore an increase in the levels of proteins in both PSII and PS1 and the δ subunit of the ATPase complex was also observed. This result was unexpected given that no changes in components of PSII or PSI were observed in the Rieske FeS antisense plants. Interestingly, a recent study reported increases in cyt b6f proteins levels in Arabidopsis plants grown under square wave light, compared to plants grown under fluctuating light, and these were matched by increased levels of PSII, PSI and the δ subunit of the ATPase proteins, which agrees with our study (Vialet-Chabrand et al., 2017). Furthermore, the hcf mutant, in which the biogenesis of the cyt b6f was inhibited, had a reduced accumulation of components of both PSI and PSII, although these complexes remained fully functional, as inferred from spectroscopic analyses, and no mechanism controlling these changes has been identified (Lennartz et al., 2001). Despite considerable efforts to gain insight into the mechanisms underlying the regulation of synthesis and assembly of components of the thylakoid membrane, the factors determining accumulation of these complexes are still poorly understood but our results provide evidence that the Rieske FeS protein levels may play a role in this regulation (Schöttler, 2015).
Over-expression of Rieske FeS significantly modifies pigment content of leaves
In parallel with the increase in components of the thylakoid membranes, plants with increased Rieske FeS protein were found to have an increase in levels of both chlorophyll a and b and a small increase in the chlorophyll a to b ratio from 2.96 to 3.12. The increase in chlorophyll a and b suggest a greater investment in both light capture and PSII reactions centres and would fit with the increase in photosynthetic electron transport capacity in the Rieske FeS ox plants. In previous work, plants with reduced levels of the Rieske FeS protein had a lower chlorophyll a/b ratio (Hurry et al., 1996; Price et al., 1998) which is the opposite to what was observed in the Rieske FeS ox plants. In addition to increases in chlorophyll, significant increases in the carotenoid pigments were also seen with β-carotene, violaxanthin (+59%), lutein (+75%) and neoxanthin (+37%). β-carotene is a component of both the RC and light harvesting complex (Kamiya and Shen, 2003; Ferreira et al., 2004; Loll et al., 2005; Litvin et al., 2008; Janik et al., 2016) and the increase in these pigments observed in the Rieske FeS ox plants is in agreement with investment in both light harvesting and increasing RC efficiency.
Lutein, neoxanthin and violaxanthin are the main xanthophyll pigment constituents of the largest light-harvesting pigment-protein complex of photosystem II (LHCII) (Thayer and Björkman, 1992; Ruban et al., 1994; Ruban et al., 1999; Ruban et al., 2012; Janik et al., 2016). Acidification of the thylakoid lumen as a result of electron transport (and driven in particular by the activities of the cytochrome b6f complex) is accompanied by the de-epoxidation of violaxanthin and an accumulation of zeaxanthin (Björkman and Demmig-Adams, 1994; Müller et al., 2001; Ruban et al., 2012), as well as protonation of carboxylic acid residues of the PsbS protein associated with PSII antennae (Li et al., 2000, 2004). Protonation of PsbS and binding of zeaxanthin increase NPQ and the thermal dissipation of excitation energy (Baker, 2008; Jahns and Holzwarth, 2012). Increases in electron transport observed in Rieske FeS ox lines might be expected to result in the acidification of the thylakoid lumen and an increase in NPQ. However, we found that the increase in the level of the Rieske FeS protein led to a small but significantly lower steady state levels of NPQ and an increase in the rate of relaxation of NPQ following illumination. The absence of an increase in NPQ in the presence of significant increases in electron transport rates suggest that the Rieske FeS ox plants also have increased rates of ATP synthesis. Although we provide no direct support for this we did observe and increase in the level of the ATP synthase delta subunit protein in the Rieske FeS ox plants. Support for this comes from the earlier work on the Rieske FeS antisense plants showing that the levels of ATP synthase were reduced and that a low transthylakoid pH gradient was evident (Price et al., 1995, 1998 Ruuska et al., 2000).
Conclusion
A number of studies have shown that increasing photosynthesis through the manipulation of CO2 assimilation can improve growth (Miyagawa et al., 2001; Lefebvre et al., 2005; Rosenthal et al., 2011; Uematsu et al., 2012; Simkin et al., 2015, 2017), this work together with a study in which cytochrome C6 from the red alga Porphyra, was expressed in Arabidopsis (Chida et al., 2007) provide direct evidence that there is also an opportunity to improve the efficiency of the electron transfer chain. Our results demonstrate that overexpression of the Rieske FeS protein can increase electron transport, photosynthesis and yield and provides another potential avenue to improve crop productivity and meet the food requirements for future population growth. Furthermore, overexpression of the Rieske FeS protein may offer tool to investigate fundamental questions on factors controlling the biogenesis of the photosynthetic complexes in the electron transport chain.
ACKNOWLEDGMENTS
We thank James E. Fox and Philip A. Davey for help with pigment analysis and Elena A. Pelech for help with Dual-PAM measurements. A.J.S was supported by BBSRC (Grant: BB/J004138/1 awarded to C.A.R and T.L): A.J.S generated transgenic plants and performed molecular and biochemical experiments and carried out plant phenotypic and growth analysis. A.J.S and L.M performed gas exchange measurement on Arabidopsis. A.J.S and L.M carried out data analysis on their respective contributions. C.R and T.L designed and supervised the research. C.R, A.J.S wrote the manuscript with input from TL.
Footnotes
This work was supported by the Biotechnology and Biological Sciences Research Council (Grant: BB/J004138/1 awarded to C.A.R and T.L)
A.J.S generated transgenic plants and performed molecular and biochemical experiments and carried out plant phenotypic and growth analysis. A.J.S and L.M performed gas exchange measurement on Arabidopsis. A.J.S and L.M carried out data analysis on their respective contributions. C.R and T.L designed and supervised the research. C.R, A.J.S wrote the manuscript with input from TL.