TY - JOUR
AU - Dodd, Ian C.
AB - Abstract To meet future requirements for food production, sustainable intensive agricultural systems need to optimize nutrient availability to maximize yield, traditionally achieved by maintaining soil pH within an optimal range (6–6.5) by applying lime (calcium carbonate). However, a field trial that applied recommended liming rates to a sandy loam soil (increasing soil pH from 5.5 to 6.2) decreased pod yield of field bean (Vicia faba L. cv. Fuego) by ~30%. Subsequent pot trials, with liming that raised soil pH to 6.3–6.7, reduced stomatal conductance (gs) by 63, 26, and 59% in V. faba, bean (Phaseolus vulgaris), and pea (Pisum sativum), respectively. Furthermore, liming reduced shoot dry biomass by 16–24% in these species. Ionomic analysis of root xylem sap and leaf tissue revealed a decrease in phosphorus concentration that was correlated with decreased gs: both reductions were partially reversed by adding superphosphate fertilizer. Further analysis of pea suggests that leaf gas exchange was reduced by a systemic increase (roots, xylem sap, and leaves) in the phytohormone abscisic acid (ABA) in response to lime-induced suboptimal plant phosphorus concentrations. Supplying synthetic ABA via the transpiration stream to detached pea leaves, at the same xylem sap concentrations induced by liming, decreased transpiration. Furthermore, the gs of the ABA-deficient mutant pea wilty was unresponsive to liming, apparently confirming that ABA mediates some responses to low phosphorus availability caused by liming. This research provides a detailed mechanistic understanding of the physiological processes by which lime application can limit crop yields, and questions the suitability of current liming recommendations. Abscisic acid, ionome, liming, phosphorus, stomatal conductance, wilty. Introduction Modern intensive agricultural practices that rely heavily on applying supplementary mineral fertilizers may accelerate naturally occurring soil acidification processes that can impair crop productivity (Bolan et al., 2003; Matsuyama et al., 2005). The principal factors affecting crop productivity in low pH (<5.5) mineral soils are phytotoxicity associated with increased bioavailability of aluminium (Al) and manganese (Mn) (Brady and Weil, 2008), and decreased availability of certain plant nutrients [typically calcium (Ca), magnesium (Mg), potassium (K), and phosphorus (P)]. In acidic mineral soils with a pH <5.5, raising the soil pH to recommended levels (typically pH 6–6.5) would normally be achieved by adding lime (CaCO3) (Goulding et al., 2008). Managing the deleterious effects of soil acidification by liming has long been shown to improve crop yield (Bolton, 1970; Buerkert et al., 1990; Farhoodi and Coventry, 2008). However, liming responses are not always positive, and yield reductions can occur even at recommended application rates. This has been attributed to changes in tissue Ca:Mg ratios (Carran, 1991), Mg fixation within the soil (Sumner et al., 1978), or reduced P availability (Haynes, 1982; Maxwell et al., 2012). More recent work tested the hypothesis that unregulated Ca uptake by the plant increased root xylem sap calcium ion (Ca2+) concentration or delivery rate, causing a stomatal limitation of photosynthesis that may limit growth of limed legumes. However, the same concentrations of Ca2+ found in vivo failed to elicit stomatal closure when fed to detached leaves via the xylem, and it was concluded that an alternative, as yet unidentified, xylem-borne antitranspirant must be regulating stomatal aperture (Rothwell and Dodd, 2014). Preliminary xylem ionomic analysis of these plants suggested that lime application may reduce P uptake, thereby limiting leaf gas exchange. Phosphorus is an essential plant nutrient that is necessary for many plant processes including synthesis of phospholipids, energy transfer, and enzyme activation (Hawkesford et al., 2012); therefore, inadequate P availability is a major limitation to plant growth and development (Schachtman et al., 1998) and consequently global crop production (Raghothama and Karthikeyan, 2005). It is estimated that 30–40% of global agricultural soils are limited by P availability (Vance et al., 2003) and it is second only to nitrogen (N) in limiting agricultural productivity (Holford, 1997). Although P deficiency might directly limit growth of limed plants, it is not clear how low P availability may limit plant gas exchange. Phosphorus deprivation decreased stomatal conductance (gs) of two cultivars of Capsicum annum (Davies et al., 1999) and in Ricinus communis (Jeschke et al., 1997). However, direct effects of tissue P concentration seem unlikely, as P, N, and S deficiency all elicit stomatal closure, suggesting that these responses are not caused by tissue nutrient levels per se (Clarkson et al., 2000) but by a common or centralized response to those deficiencies (Chapin, 1990; Kudoyarova et al., 2015). It has been suggested that P and other nutrient deficiencies limit both leaf growth and gs via decreased tissue water status (Radin and Eidenbock, 1984; Chapin, 1990) caused by reduced root hydraulic conductance (Clarkson et al., 2000). However, maintaining leaf water status by root pressurization did not maintain gs or leaf elongation in response to soil drying in Triticum aestivum (Gollan et al., 1986), salt stress (100mM NaCl) in T. aestivum and Hordeum vulgare (Termaat et al., 1985), and in N-deprived H. vulgare (Dodd et al., 2002), suggesting that hydraulic signals may not regulate physiological responses. Alternatively, cotton (Gossypium hirsutum) plants with a leaf P concentration of 2.3mg g–1 dry weight (DW) showed a 2-fold increase in leaf abscisic acid (ABA) concentration in response to soil drying compared with plants with a leaf P concentration of 6.8mg g–1 DW (Radin, 1984). Similarly, decreasing the root P concentration from 2.7mg g–1 DW to 0.9mg g–1 DW (and leaf P concentration from 3.7mg g–1 DW to 1.6mg g–1 DW) in well-watered R. communis plants increased root xylem sap ABA concentration and foliar ABA concentration by 6-fold and 2-fold, respectively (Jeschke et al., 1997). Elevated endogenous levels of ABA, if delivered to the apoplast in the vicinity of the stomatal guard cells, can cause stomatal closure (Hartung et al., 2002), but this hypothesis has never been explicitly tested in P-deprived plants. Further evidence for the action of phytohormones on a physiological response can be established by seeking to manipulate their endogenous concentrations by using mutants that either are impaired in their ability to synthesize the hormone of interest or are insensitive to its action (Jones et al., 1987; Nagel et al., 1994; Dodd, 2003; Chen et al., 2013). Stomatal conductance of both wild-type and ABA-deficient wilty pea was similarly decreased (by 40%) in plants grown at low (0.5mM NO3–) compared with those grown at high (5mM NO3–) nitrogen status (Dodd, 2005). Similarly, N-deprived ABA-deficient flacca and wild-type tomato had comparably decreased gs when compared with N-sufficient plants (Coleman and Schneider, 1996). To the authors’ knowledge, there has been no mutational analysis of the causes of stomatal closure in P-deficient (or limed) plants. Since previous short-term (4 week) pot trials established that liming an acidic soil to a recommended soil pH decreased shoot biomass (Rothwell and Dodd, 2014), an initial experiment aimed to establish the agronomic implications of this response over the entire crop life cycle. In attempting to understand why crop yield and photosynthesis were decreased in plants grown in limed soil, the tissue and xylem ionic status was investigated. The role of P status in regulating biomass accumulation and leaf gas exchange was investigated by applying factorial combinations of lime and superphosphate. Based on this analysis, it was hypothesized that a liming-induced reduction in P availability decreased gas exchange by increasing root to shoot signalling of the plant hormone ABA. This hypothesis was further tested by measuring transpiration of detached pea leaves that were supplied with the ABA concentrations found endogenously in limed plants, and by measuring gs of wild-type (WT) and the ABA-deficient pea (Pisum sativum) mutant wilty (De Bruijn et al., 1993) grown in limed and unlimed soil. Materials and methods Vicia faba field trial A field experiment was carried out at Lee Farm, Myerscough College, Lancashire, UK on a site previously established as pasture. The site was chosen as a low pH sandy loam soil (pH 5.5, 46% sand, 32% silt, 9% clay, 13% organic matter) that allowed the application of agronomically significant levels of lime. Treatments were an unlimed control and calcium carbonate- (CaCO3) based agricultural lime (J. Arthur Bowers Ltd Coarse Screened Limestone, William Sinclair Horticulture Ltd, Lincoln, UK) that had a neutralizing value (CaO equivalent) of 57%, added at 7 t ha–1. The lime application rate was calculated to meet the DEFRA- (2010) recommended target soil pH of 6.5 using the Rothlime online liming calculator (McGrath, 2002). Four plots of each treatment were arranged in a complete randomized design; plot size was 5×3 m with a 2 m buffer zone between plots. Lime was applied by hand on 7 February 2013 to previously ploughed plots and incorporated into the top 10–15cm of the soil profile using a tractor-mounted rotavator. A crop of Vicia faba L. cv. Fuego was drilled 2 months later at a rate of 25–30 seeds m–2. Soil samples were taken for pH analysis immediately prior to the lime application and again on 30 May, 13 August, and 21 September 2013. The crop was managed using standard agronomic protection practice which included an application of Bentazon selective herbicide (at recommended rates supplied by the manufacturer) 1 month after drilling to control weeds. At the end of the experiment, pods were collected from two randomly selected 1 m–2 quadrats per plot and weighed on a digital hand-held balance to record pod yield. Legume pot trials Soil preparation and analysis All pot trials used the same 2:1 (v:v) mixture of the low pH sandy loam field soil described above and horticultural grit sand (DA30, Boughton, Kettering, UK), which was used to improve drainage. Field soil–grit sand combinations were homogenized in a cement mixer for 5min, passed through a 10mm sieve, and sterilized (Camplex 68 l, Thermoforce Ltd, Cockermouth, UK) at a minimum temperature of 82 °C to prevent infection from soil-borne pests and diseases. The previously described agricultural lime was applied at a rate of 3g l–1 to target a final soil pH of 6.5 as recommended by DEFRA (2010) and converted from t ha–1 to g l–1 by assuming that soil pH is measured in the top 20cm of the soil profile and 1 ha contains 2 000 000 litres of soil at 20cm depth. Field soil–grit sand and lime combinations were thoroughly homogenized in 15 litre batches for 5min in a cement mixer before incubation in black plastic bags for a minimum of 4 weeks prior to planting to allow the lime reaction to occur. To prepare soil from both field and pot trials for analysis, samples were homogenized, air-dried, and passed through a 4mm sieve. Soil pH was determined in triplicate using the DEFRA-recommended (MAFF, 1986) method where 20g soil samples were mixed in small plastic containers with 50ml of distilled water, thoroughly stirred, and left for 1h. Soil pH was determined by re-mixing and immediately measuring the suspension with a pH electrode (Orion Sure Flow, Fisher Scientific, Loughborough, UK) and meter (Denver instruments, Bohemia, New York, USA). Plant culture In separate experiments, seeds of V. faba L. cv. Longpod, Phaseolus vulgaris L. cv. Nassau, or P. sativum L. cv. Alderman were sown into 1.5 litre (V. faba) or 0.8 litre (P. vulgaris and P. sativum) pots using the control and limed soil described above. In another experiment with P. sativum cv. Alderman, one group of control and limed plants received an additional treatment of superphosphate fertilizer (J. Arthur Bowers Ltd) at a rate of 0.59g l–1 (equivalent to a 200kg ha–1 application rate). In a separate experiment, near-isogenic seeds of the ABA-deficient pea wilty mutant (De Bruijn et al., 1993) which show 60-90% lower foliar ABA concentrations than its WT (Dodd et al 2003, Wang et al 1984), its WT, and cv. Alderman were germinated and established as described above. Plants were initially watered to run-off and weighed after 24h to establish weight at drained capacity, and maintained well-watered by replacing full evapotranspiration (determined gravimetrically) daily and kept in a semi-controlled naturally lit greenhouse with supplementary lighting (supplied by Osram 600W daylight bulbs) for 12h and 22 °C/16 °C minimum day/night temperature at the Lancaster Environment Centre. Physiological measurements Stomatal conductance was recorded 24h prior to harvest on the third or fourth leaf pair numbered from the base (V. faba and P. sativum), or the first tri-foliate leaf (P. vulgaris) using an AP4 diffusive porometer (Delta-T Devices, Cambridge, UK). Two readings were taken per plant and averaged. Measurements were made between 11:00h and 13:00h on the abaxial leaf surface. In the superphosphate addition experiment, gas exchange [gs and photosynthesis (Pn)] was recorded using infra-red gas analysis (6400Xt Li-Cor Portable Photosynthesis System, Lincoln, NE, USA) on one leaflet of leaf pair four. Instrument settings were ambient CO2 levels (390 μl l–1), 600 μmol m–2 s–1 phosynthetic photon flux density (PPFD), a cuvette temperature of 22 °C, and ambient humidity. In the P. sativum superphosphate experiment, leaf water potential (Ѱleaf) of one leaf of leaflet pair four was measured by thermocouple psychrometry. Leaf discs of 8mm diameter were punched from the mid-lamina, placed immediately on clean sample holders, and then wrapped in aluminium foil to minimize water loss. When all samples had been collected, they were unwrapped and loaded into C52 sample chambers (Wescor Inc., Logan, UT, USA), incubated for ~3h, then voltages were read with a microvolt meter (model HR-33T; Wescor Inc.). Voltages were converted into water potentials based on calibration with salt solutions of known osmotic potential. Root (P. vulgaris) or root and leaf (P. sativum) xylem sap samples were collected for ionomic and/or hormonal analysis at flow rates closely matching in vivo transpiration rates, determined gravimetrically 1–2h prior to sampling, using techniques described in more detail previously (Rothwell and Dodd, 2014). Briefly, de-topped 3-week-old P. vulgaris plants were placed in a Scholander pressure chamber and sap collected using an appropriate over-pressure (0.2–0.5MPa). For P. sativum, leaf xylem sap was collected from a small V-shaped section cut from the mid-rib of one leaflet of leaflet pair four, using plants grown in a whole-plant pressure chamber. Root xylem sap was collected after subsequent excision of the shoot 3cm above the soil surface, at sequentially increasing 0.1MPa pressures until the appropriate sap flow rate was achieved. Sap samples were immediately frozen in liquid nitrogen and stored at –80 °C prior to analysis. Plants in all experiments were harvested at 3–4 weeks old. Roots were collected, washed clear of soil, and checked for nodulation, though this was not observed. Both shoot and root material was then dried at 80 °C for 1 week to record dry weight and stored in air-tight containers to provide samples for nutrient and hormone analysis. Plant analyses For tissue nutrient analysis, all leaves or roots present at the time of harvest were collected to provide enough sample material, oven dried at 80 °C for 7 d, and ground to a fine powder using a ball mill (Retsch MM400, Retsch UK Limited, Castleford, West Yorkshire, UK). Samples were then subjected to microwave-assisted acid digestion (Mars-5 Xpress microwave-accelerated reaction system, CEM Corporation, Matthews, NC, USA) in trace metal grade HNO3 (Sigma-Aldrich, Dorset, UK) for 30min at a maximum temperature of 200 °C. To prepare samples for analysis, the digestate was diluted to a final 2% (v/v) HNO3 concentration with Millipore water and filtered through a 0.45 μm syringe filter. Xylem sap samples were diluted directly in a 2% (v/v) HNO3 solution, and filtered prior to analysis. Macronutrients (Ca, K, Mg, P, and S) were analysed using inductively coupled plasma-optical emission spectrometry (ICP-OES; iCAP 6300, Thermo Scientific, MA, USA) and compared against standards of a known range of concentrations, and corrected, if required, using determinations from blank samples run in the microwave digestion. Leaf and root xylem sap and tissue ABA concentrations were determined by competitive radioimmunoassay (RIA) as previously described by Quarrie et al. (1988) using radiolabelled ABA (dl-cis/trans [3H]ABA) and the antibody MAC 252 (Dr Geoff Butcher, Babraham Institute) that has high specificity for the free acid of (+)-2-cis-ABA (Barrieu and Simonneau, 2000). To prepare plant tissue for analysis, samples were freeze-dried and ground to a fine powder using dissecting scissors. Both leaf and root tissue samples were extracted at a ratio of 1:25 in distilled water by shaking overnight at 4 °C on a mechanical shaker. Leaf and root xylem sap samples were analysed as collected. A spike dilution test of both xylem sap and aqueous extracts of P. sativum tissue (Bacon, 2001) indicated the absence of immunoreactive contamination. Detached leaf transpiration bioassays Eight uniformly germinated seeds of P. sativum L. cv. Alderman were established in 5 litre pots using the unlimed control 2:1 field soil:grit sand combination described above. When established (2–3 weeks), fully expanded leaflet pairs including petioles were detached 4–5h into the photoperiod using a razor blade and immediately re-cut under distilled water to prevent embolism. Maintaining a meniscus of water on the cut petiole surface, the leaflets were then placed in a 1.5ml Eppendorf tube containing an artificial xylem sap solution containing: 3mM KNO3, 1mM KH2PO4, 1mM K2HPO4, 1mM CaCl2, 0.1mM MnSO4, and 0.1mM MgSO4 (as in Dodd et al., 2003). A transpiration dose response to ABA was established by adding ABA at concentrations of 0, 10, 50, and 100nM to the artificial xylem sap. The P. sativum leaflets (placed in small glass vials to allow them to sit upright) were randomly placed in a controlled environment growth chamber with fan-assisted air flow at a temperature of 24 °C with a relative humidity of ~60%. Vials were weighed on a four-point analytical balance every 50min over a 5h period to determine transpiration rates gravimetrically. At the end of the assay, leaflet area was recorded using a leaf area meter (Li-3050A, Li-Cor, Lincoln, NE, USA) to normalize transpiration rates. Statistical analysis A Student t-test was used to determine significant effects of lime on soil pH and pod yield; soil pH, biomass accumulation, and gs; and ionomic composition of leaf tissue and xylem sap. Two-way analysis of variance (ANOVA) determined significant treatment effects of lime and superphosphate fertilizer and effects of lime and genotype. Regression analysis determined correlations, and linear, second-order polynomial or hyperbolic decay regression lines were fitted as appropriate where significant. All analyses used Minitab v16 software. Results Vicia faba field trial Soil samples taken 16 weeks after agricultural lime application showed that soil pH increased from ~5.5 to 6.2 (Fig. 1A), slightly less than the pH 6.5 target. Later in the growing season (26 and 32 weeks after application), the pH had dropped slightly in the limed treatment to values between 5.8 and 6. Throughout crop growth, soil pH was significantly higher in the limed treatment. At harvest, liming had reduced fresh pod yield of V. faba by 28% (Fig. 1B) from 1.44kg m–2 to 1.03kg m–2 (21 weeks after drilling) when compared with unlimed controls. Although liming increased soil pH to levels that were considered optimal for growth throughout the entire growing season, pod yield was significantly decreased. Fig. 1. Open in new tabDownload slide Soil pH of limed (open circles) and unlimed controls (filled circles) during the Vicia faba cropping cycle (A). Total fresh pod yield of limed and unlimed (control) V. faba recorded 21 weeks after drilling in the field trial (B). Data are means ±SE of four treatment plots. Asterisks (A) and different letters above bars (B) indicate a significant difference (P<0.05) as determined by a Student t-test. Fig. 1. Open in new tabDownload slide Soil pH of limed (open circles) and unlimed controls (filled circles) during the Vicia faba cropping cycle (A). Total fresh pod yield of limed and unlimed (control) V. faba recorded 21 weeks after drilling in the field trial (B). Data are means ±SE of four treatment plots. Asterisks (A) and different letters above bars (B) indicate a significant difference (P<0.05) as determined by a Student t-test. Pot trials Liming significantly reduced shoot biomass of V. faba, P. vulgaris, and P. sativum in pot trials by 24, 22, and 16%, respectively, and reduced gs by 63, 26, and 59%, respectively (Table 1). Ionomic analysis of leaf tissue (V. faba) or root xylem sap (P. vulgaris and P. sativum) revealed a consistent halving of P concentrations in limed plants (Table 2). Liming significantly increased Ca concentration only in P. vulgaris root xylem sap, though none of the other macronutrients measured (K, Mg and S) changed in response to liming. Thus liming consistently decreased biomass accumulation and gs of several legume species, but, of the macronutrients analysed, only P status was consistently decreased. Table 1. Soil pH, shoot dry biomass, and stomatal conductance of limed and unlimed (control) Vicia faba, Phaseolus vulgaris, and Pisum sativum in pot trials Data are means ±SE of three replicates for soil pH and 11–12 (V. faba and P. vulgaris) or 5–6 (P. sativum) replicates for biomass and stomatal conductance. Species . Soil pH . Shoot dry biomass (g) . Stomatal conductance (mmol m–2 s–1) . Control . Lime . Control . Lime . % change . Control . Lime . % change . V. faba 5.75±0.03 a 6.29±0.01 b 1.98±0.10 a 1.50±0.16 b –24 287±35 a 106±18 b –63 P. vulgaris 5.78±0.01 a 6.37±0.02 b 1.96±0.14 a 1.53±0.11 b –22 626±29 a 462±22 b –26 P. sativum 6.00±0.04 a 6.67±0.02 b 0.89±0.04 a 0.75±0.01 b –16 303±34 a 125±10 b –59 Species . Soil pH . Shoot dry biomass (g) . Stomatal conductance (mmol m–2 s–1) . Control . Lime . Control . Lime . % change . Control . Lime . % change . V. faba 5.75±0.03 a 6.29±0.01 b 1.98±0.10 a 1.50±0.16 b –24 287±35 a 106±18 b –63 P. vulgaris 5.78±0.01 a 6.37±0.02 b 1.96±0.14 a 1.53±0.11 b –22 626±29 a 462±22 b –26 P. sativum 6.00±0.04 a 6.67±0.02 b 0.89±0.04 a 0.75±0.01 b –16 303±34 a 125±10 b –59 Different letters indicate significant differences (P<0.05) within each species between treatments as determined by a Student t-test. Open in new tab Table 1. Soil pH, shoot dry biomass, and stomatal conductance of limed and unlimed (control) Vicia faba, Phaseolus vulgaris, and Pisum sativum in pot trials Data are means ±SE of three replicates for soil pH and 11–12 (V. faba and P. vulgaris) or 5–6 (P. sativum) replicates for biomass and stomatal conductance. Species . Soil pH . Shoot dry biomass (g) . Stomatal conductance (mmol m–2 s–1) . Control . Lime . Control . Lime . % change . Control . Lime . % change . V. faba 5.75±0.03 a 6.29±0.01 b 1.98±0.10 a 1.50±0.16 b –24 287±35 a 106±18 b –63 P. vulgaris 5.78±0.01 a 6.37±0.02 b 1.96±0.14 a 1.53±0.11 b –22 626±29 a 462±22 b –26 P. sativum 6.00±0.04 a 6.67±0.02 b 0.89±0.04 a 0.75±0.01 b –16 303±34 a 125±10 b –59 Species . Soil pH . Shoot dry biomass (g) . Stomatal conductance (mmol m–2 s–1) . Control . Lime . Control . Lime . % change . Control . Lime . % change . V. faba 5.75±0.03 a 6.29±0.01 b 1.98±0.10 a 1.50±0.16 b –24 287±35 a 106±18 b –63 P. vulgaris 5.78±0.01 a 6.37±0.02 b 1.96±0.14 a 1.53±0.11 b –22 626±29 a 462±22 b –26 P. sativum 6.00±0.04 a 6.67±0.02 b 0.89±0.04 a 0.75±0.01 b –16 303±34 a 125±10 b –59 Different letters indicate significant differences (P<0.05) within each species between treatments as determined by a Student t-test. Open in new tab Table 2. Ionomic analysis of limed and unlimed (control) leaf tissue (mg g–1DW; Vicia faba) or root xylem sap (mM; Phaseolus vulgaris and Pisum sativum) in pot trials Data are means ±SE of five (V. faba), 10 (P. vulgaris), or three (P. sativum) replicates Species . K . Ca . Mg . S . P . . Control . Lime . Control . Lime . Control . Lime . Control . Lime . Control . Lime . V. faba 24.9±1.86 25.5±2.02 8.64±0.95 10.3±0.77 2.45±0.23 2.66±0.14 NA NA 3.24±0.18 1.63±0.08* P. vulgaris 5.46±0.32 6.06±0.38 1.19±0.06 1.91±0.09* 0.59±0.02 0.52±0.03 0.19±0.02 0.15±0.01 0.54±0.04 0.23±0.01* P. sativum 8.71±1.33 9.76±0.94 1.00±0.06 0.92±0.01 0.40±0.04 0.29±0.02 0.40±0.02 0.35±0.03 0.28±0.03 0.16±0.01* Species . K . Ca . Mg . S . P . . Control . Lime . Control . Lime . Control . Lime . Control . Lime . Control . Lime . V. faba 24.9±1.86 25.5±2.02 8.64±0.95 10.3±0.77 2.45±0.23 2.66±0.14 NA NA 3.24±0.18 1.63±0.08* P. vulgaris 5.46±0.32 6.06±0.38 1.19±0.06 1.91±0.09* 0.59±0.02 0.52±0.03 0.19±0.02 0.15±0.01 0.54±0.04 0.23±0.01* P. sativum 8.71±1.33 9.76±0.94 1.00±0.06 0.92±0.01 0.40±0.04 0.29±0.02 0.40±0.02 0.35±0.03 0.28±0.03 0.16±0.01* NA denotes that the sample was not analysed and * indicates where lime had a significant (P<0.05) effect on nutrient concentration. Open in new tab Table 2. Ionomic analysis of limed and unlimed (control) leaf tissue (mg g–1DW; Vicia faba) or root xylem sap (mM; Phaseolus vulgaris and Pisum sativum) in pot trials Data are means ±SE of five (V. faba), 10 (P. vulgaris), or three (P. sativum) replicates Species . K . Ca . Mg . S . P . . Control . Lime . Control . Lime . Control . Lime . Control . Lime . Control . Lime . V. faba 24.9±1.86 25.5±2.02 8.64±0.95 10.3±0.77 2.45±0.23 2.66±0.14 NA NA 3.24±0.18 1.63±0.08* P. vulgaris 5.46±0.32 6.06±0.38 1.19±0.06 1.91±0.09* 0.59±0.02 0.52±0.03 0.19±0.02 0.15±0.01 0.54±0.04 0.23±0.01* P. sativum 8.71±1.33 9.76±0.94 1.00±0.06 0.92±0.01 0.40±0.04 0.29±0.02 0.40±0.02 0.35±0.03 0.28±0.03 0.16±0.01* Species . K . Ca . Mg . S . P . . Control . Lime . Control . Lime . Control . Lime . Control . Lime . Control . Lime . V. faba 24.9±1.86 25.5±2.02 8.64±0.95 10.3±0.77 2.45±0.23 2.66±0.14 NA NA 3.24±0.18 1.63±0.08* P. vulgaris 5.46±0.32 6.06±0.38 1.19±0.06 1.91±0.09* 0.59±0.02 0.52±0.03 0.19±0.02 0.15±0.01 0.54±0.04 0.23±0.01* P. sativum 8.71±1.33 9.76±0.94 1.00±0.06 0.92±0.01 0.40±0.04 0.29±0.02 0.40±0.02 0.35±0.03 0.28±0.03 0.16±0.01* NA denotes that the sample was not analysed and * indicates where lime had a significant (P<0.05) effect on nutrient concentration. Open in new tab Lime and superphosphate fertilizer both had significant, independent effects on both shoot biomass and tissue P concentration. Again, liming significantly reduced shoot dry biomass of P. sativum (Fig. 2A) by 38%, but applying superphosphate fertilizer increased shoot dry biomass (by 15–23%). Similarly, liming approximately halved leaf tissue P concentration when compared with unlimed controls (Fig. 2B), but applying superphosphate fertilizer increased leaf P concentration (by ~25% in both control and limed soil). Thus shoot dry biomass significantly increased with leaf tissue P concentration (Fig. 2C). Fig. 2. Open in new tabDownload slide Shoot dry biomass (A) and leaf tissue phosphorus concentration (B) of control ●, control+P fertilizer ○-, lime ▼-, or lime+P fertilizer △-treated Pisum sativum, and relationship between shoot dry biomass and leaf tissue phosphorus concentration (C). Data are means ±SE of 8–10 (A) or six (B) replicates. Two-way ANOVA results (P-values reported) are indicated in (A) and (B), with different letters above bars indicating significant differences as determined by Tukey pair-wise analysis. Data points in (C) represent individual plants with a second-order polynomial regression line fitted, with P-values and r2 shown. Fig. 2. Open in new tabDownload slide Shoot dry biomass (A) and leaf tissue phosphorus concentration (B) of control ●, control+P fertilizer ○-, lime ▼-, or lime+P fertilizer △-treated Pisum sativum, and relationship between shoot dry biomass and leaf tissue phosphorus concentration (C). Data are means ±SE of 8–10 (A) or six (B) replicates. Two-way ANOVA results (P-values reported) are indicated in (A) and (B), with different letters above bars indicating significant differences as determined by Tukey pair-wise analysis. Data points in (C) represent individual plants with a second-order polynomial regression line fitted, with P-values and r2 shown. In P. sativum, the liming treatment approximately halved gs when compared with the unlimed controls (Fig. 3A). Applying superphosphate fertilizer partially restored gs in limed plants, but had no significant effect on controls, as signified by the lime×P fertilizer interaction (P=0.02). Similarly, liming inhibited net photosynthesis by 32% compared with unlimed controls, but superphosphate fertilizer restored Pn in the limed plants to near control levels (Fig. 3B). Again, a significant lime×P fertilizer interaction (P=0.046) indicated that superphosphate fertilizer only enhanced Pn in the limed plants and not in the control group. Limed plants also had a 12% lower leaf intercellular CO2 concentration (Fig. 3C) when compared with controls, which was restored to control levels by applying superphosphate fertilizer. Thus liming limited photosynthesis by decreasing gs and leaf intercellular CO2 concentration, but this could be reversed by superphosphate fertilizer application. Fig. 3. Open in new tabDownload slide Stomatal conductance (A), net photosynthesis (B), and intercellular CO2 concentration (C) of control, control+P fertilizer-, lime-, or lime+P fertilizer-treated Pisum sativum. Data are means ±SE of 8–10 replicates with two-way ANOVA results (P-values reported) shown. Different letters above each bar indicate significant differences (P<0.05) as determined by Tukey pair-wise analysis. Fig. 3. Open in new tabDownload slide Stomatal conductance (A), net photosynthesis (B), and intercellular CO2 concentration (C) of control, control+P fertilizer-, lime-, or lime+P fertilizer-treated Pisum sativum. Data are means ±SE of 8–10 replicates with two-way ANOVA results (P-values reported) shown. Different letters above each bar indicate significant differences (P<0.05) as determined by Tukey pair-wise analysis. In P. sativum, liming increased leaf and root tissue ABA concentration by 31% and 62%, respectively (Fig. 4A, B). Applying superphosphate fertilizer restored leaf tissue ABA levels to control values in the limed treatment, but had no significant effect on plants grown in unlimed soil, as indicated by a significant lime×P fertilizer interaction (P=0.025). Applying superphosphate fertilizer had no effect on root ABA concentration in the control treatment although it did partially reduce ABA concentrations of limed plants by ~12%. Liming also reduced Ѱleaf by 0.25MPa (Fig. 4C) and superphosphate fertilizer partially restored Ѱleaf to control levels by 0.12MPa, but had no effect on plants grown in unlimed soil (Fig. 4C). Thus liming increased tissue ABA concentration and lowered Ѱleaf, but these effects could be fully or partially reversed by superphosphate fertilizer application. Fig. 4. Open in new tabDownload slide Leaf (A) and root (B) tissue ABA concentrations and leaf water potential (C) of control, control+P fertilizer-, lime-, or lime+P fertilizer-treated Pisum sativum. Data are means ±SE of 8–10 replicates with two-way ANOVA results (P-values reported) shown. Different letters above each bar indicate significant differences (P<0.05) as determined by Tukey pair-wise analysis. Fig. 4. Open in new tabDownload slide Leaf (A) and root (B) tissue ABA concentrations and leaf water potential (C) of control, control+P fertilizer-, lime-, or lime+P fertilizer-treated Pisum sativum. Data are means ±SE of 8–10 replicates with two-way ANOVA results (P-values reported) shown. Different letters above each bar indicate significant differences (P<0.05) as determined by Tukey pair-wise analysis. Leaf tissue ABA was correlated (P=0.003; r2=0.51) with foliar P concentration (Fig. 5A), and root tissue ABA (P=0.007; r2=0.47) with root tissue P concentration (Fig 5B). Ѱleaf was also correlated (P=0.009; r2=0.51) with leaf tissue P concentration (Fig. 5C) and, although data were more scattered, Ѱleaf was negatively correlated (P=0.004; r2=0.28) with foliar ABA concentrations (Fig. 5D). Across all treatments, stomatal closure was highly correlated with both decreased foliar P (P<0.001; r2=0.78) and increased ABA (P<0.001; r2=0.58) concentrations (Fig. 6A, B), and Ѱleaf was weakly correlated (P=0.004; r2=0.22) with gs (Fig. 6C). Given the multiplicity of significant correlations, resolving the physiological significance of increased ABA status required additional experiments focusing on the relationship between gs and ABA. Fig. 5. Open in new tabDownload slide Relationship between leaf (A) and root (B) tissue ABA concentration and phosphorus concentration, leaf water potential and leaf tissue phosphorus concentration (C), and leaf water potential and leaf ABA concentration (D) in limed (filled triangles), limed + P fertilizer (open triangles), unlimed (filled circles), and unlimed + P fertilizer (open circles) Pisum sativum. Data points represent individual plants, with second-order polynomial (A, B, C) and linear (D) regression lines fitted, with P-values and r2 reported. Fig. 5. Open in new tabDownload slide Relationship between leaf (A) and root (B) tissue ABA concentration and phosphorus concentration, leaf water potential and leaf tissue phosphorus concentration (C), and leaf water potential and leaf ABA concentration (D) in limed (filled triangles), limed + P fertilizer (open triangles), unlimed (filled circles), and unlimed + P fertilizer (open circles) Pisum sativum. Data points represent individual plants, with second-order polynomial (A, B, C) and linear (D) regression lines fitted, with P-values and r2 reported. Fig. 6. Open in new tabDownload slide Relationship between stomatal conductance and leaf tissue phosphorus concentration (A), leaf water potential (B), and leaf tissue ABA concentration (C) of lime- (filled triangle), lime+P fertilizer- (open triangle), control (filled circle), and control+P fertilizer- (open circle) treated Pisum sativum. Data points represent individual plants with hyperbolic decay (A) or linear (B, C) regression lines fitted, and P values and r2 reported. Fig. 6. Open in new tabDownload slide Relationship between stomatal conductance and leaf tissue phosphorus concentration (A), leaf water potential (B), and leaf tissue ABA concentration (C) of lime- (filled triangle), lime+P fertilizer- (open triangle), control (filled circle), and control+P fertilizer- (open circle) treated Pisum sativum. Data points represent individual plants with hyperbolic decay (A) or linear (B, C) regression lines fitted, and P values and r2 reported. To determine whether root to shoot ABA signalling was also affected by liming, xylem sap was collected from the roots and leaves of P. sativum plants grown in specialized pressure pots. Both leaf and root xylem sap ABA concentrations were approximately doubled from ~ 4–5nM to ~10nM (Fig. 7A). Supplying 10nM ABA to detached P. sativum leaves via the transpiration stream decreased the leaf transpiration rate by 17% compared with that of leaves supplied with artificial xylem sap alone (Fig. 7B), indicating that this ABA concentration is physiologically active. Fig. 7. Open in new tabDownload slide Root and leaf xylem sap ABA concentration (A) of limed (open bars) or unlimed (filled bars) Pisum sativum grown in a whole-plant pressure chamber. (B) The relationship between artificial xylem sap ABA concentration and transpiration rate in detached leaflets of P. sativum. Data are means ±SE of 5–6 (A) and 6–8 (B) replicates; different letters in (A) indicate significant differences (P<0.05) as determined by a Student t-test. A hyperbolic decay regression line is fitted in (B), with P-values and r2 reported in the top right of the panel. Fig. 7. Open in new tabDownload slide Root and leaf xylem sap ABA concentration (A) of limed (open bars) or unlimed (filled bars) Pisum sativum grown in a whole-plant pressure chamber. (B) The relationship between artificial xylem sap ABA concentration and transpiration rate in detached leaflets of P. sativum. Data are means ±SE of 5–6 (A) and 6–8 (B) replicates; different letters in (A) indicate significant differences (P<0.05) as determined by a Student t-test. A hyperbolic decay regression line is fitted in (B), with P-values and r2 reported in the top right of the panel. Further evidence that ABA was involved in decreasing gs of limed plants was sought by comparing stomatal responses of wild-type and ABA-deficient wilty peas. Liming decreased gs of both a commercial cultivar (Alderman) and the WT by ~25%, but had no significant effect on gs of the wilty pea, as confirmed by a significant genotype×lime interaction (P=0.02; Fig. 8.). Thus ABA deficiency prevented the normal stomatal responses of limed plants. Fig. 8. Open in new tabDownload slide Stomatal conductance of limed (open bars) or unlimed (filled bars) Pisum sativum cv. Alderman (Ald), ‘wild-type’ (WT) or wilty. Data are means ±SE of 7–8 replicates, and two-way ANOVA results (P-values reported) are shown. Different letters above each bar indicate significant differences (P<0.05) as determined by Tukey pair-wise analysis. Fig. 8. Open in new tabDownload slide Stomatal conductance of limed (open bars) or unlimed (filled bars) Pisum sativum cv. Alderman (Ald), ‘wild-type’ (WT) or wilty. Data are means ±SE of 7–8 replicates, and two-way ANOVA results (P-values reported) are shown. Different letters above each bar indicate significant differences (P<0.05) as determined by Tukey pair-wise analysis. Discussion Conventional wisdom suggests that soil pH for arable crops should be maintained between 6 and 6.5 to maximize nutrient availability (Brady and Weil, 2008; Goulding et al., 2008; DEFRA, 2010) and crop yields, and that lime should be applied to correct for excessive soil acidity (pH <5.5). Accordingly, lime was applied in the field trial, which maintained a mean soil pH value of ~6.2 throughout the cropping cycle (Fig. 1A). This pH would be expected to improve crop yield (Bolan et al., 2003) and should have avoided the yield penalties characteristic of overliming (usually generating soil pH values >8) typically caused by unavailability of iron (Mengel, 1994), P and Mn (Kerley, 2000), and boron (Bartlett and Picarell, 1973). Paradoxically, lime application decreased V. faba fresh pod yield (Fig. 1B). This was unlikely to be a unique response of this species, since pot trials in the same soil with several legume species (V. faba, P. vulgaris, and P. sativum; Table 1) all showed decreased shoot biomass in response to lime application. While further studies are needed to determine how common this response may be in a range of soil types, this investigation focused on determining the physiological reasons for this lime-induced yield suppression. Decreased yield following liming has been attributed to fixation of available Mg (Sumner et al., 1978,Myers et al., 1988) or tissue Ca:Mg ratios (Carran, 1991), yet plant uptake of these elements (as assayed by tissue and xylem ionomic analysis) was similar in limed and control plants (Table 2). Previous studies with this soil excluded a role for excessive Ca uptake [Ca is a potent antitranspirant (De Silva et al., 1985)] in limiting leaf gas exchange and biomass accumulation of legume crops (Rothwell and Dodd, 2014). However, tissue or xylem sap P concentrations of limed plants were consistently decreased (Table 2), as in previous observations where liming decreased yield (Haynes, 1982; Maxwell et al., 2012). While further investigations of soil P dynamics seem advisable, adding CaCO3 could precipitate large quantities of CaHPO4, thereby making P unavailable to the plant (Delgado and Torrent, 2000). The importance of P in regulating plant responses to liming was established by supplying excessive quantities (200kg ha–1 P) of P fertilizer to limed plants, which partially reversed the negative effects of lime on gs (Fig. 3A), if not biomass (Fig. 2A). Thus it seemed essential to establish the physiological mechanisms by which lime-induced suboptimal P concentrations may decrease biomass accumulation (Fig. 2C) and gas exchange (Table 1; Fig. 3). While decreased P status may directly regulate biomass accumulation, since considerable quantities of P are needed for nucleic acid formation and phospholipid synthesis (Veneklaas et al., 2012), it seems less likely that P per se directly regulates gs. Certainly, P-deprived plants showed reduced gs and transpiration (Jeschke et al., 1997; Davies et al., 1999), and gs declined with leaf tissue P concentration (Fig. 6A), suggesting that P concentration per se may directly cause or act as a signal for stomatal closure. Although changes in xylem ionomic composition might act as root to shoot signals that influence stomatal aperture (Bahrun et al., 2002), responses of xylem phosphate concentration to soil drying seem rather variable, with increased and decreased concentrations reported (Perez-Alfocea et al., 2011). Similarly, xylem concentrations of a range of measured cations and anions (including phosphate) were not correlated with gs at the onset of soil drying (Gollan et al., 1992), suggesting that changes in xylem sap ion concentration are unlikely to regulate stomatal responses directly (Schurr et al., 1992). Alternatively, foliar P concentration might affect stomata by decreasing the CO2 fixation rate by impairing photochemical efficiency. However, when P is withheld from the plant, Ci values typically increase (e.g. Jacob and Lawlor, 1991, 1993). In the current experiment, Ci values of limed plants actually decreased (Fig. 3C), suggesting that decreased net photosynthesis results from a reduced CO2 flux into the substomatal cavity caused by stomatal closure (Chaves et al., 2002). Common stomatal responses to multiple individual nutrient deficiencies (N, P, and K) in well-watered plants (Clarkson et al., 2000) make it more plausible that any signal affecting stomatal behaviour acts as part of a centralized response (Chapin, 1990). Hence, the significant negative correlation between tissue P concentrations and gs (Fig. 6A) may simply reflect plant P status and may not be causative. Previous work that detected lime-induced stomatal closure argued that an unidentified xylem-borne signal was responsible (Rothwell and Dodd, 2014). Decreased leaf water status under suboptimal P levels mediated by reduced root hydraulic conductance (Radin and Eidenbock, 1984) may limit gs (Clarkson et al., 2000). Although liming decreased both Ѱleaf and gs (Fig. 6C), the gs of P. sativum is not always closely linked to leaf water status. Flooding decreased gs without changing leaf water status (Zhang and Zhang, 1994), and soil drying increased Ѱleaf by ~0.2MPa, which was thought to be caused by stomatal closure (Belimov et al., 2009). Furthermore, gs of low-N- (1mM) supplied tomato (Solanum lycopersicum) was 27% lower than that of N-sufficient (10mM) plants without any change in Ѱleaf (Guidi et al., 1998). Thus it seems unlikely that reduced Ѱleaf of P. sativum caused stomatal closure of limed plants, and instead enhanced concentrations of the phytohormone ABA, a signal common to many nutrient stresses (Vysotskaya et al., 2008), may be important. Liming increased ABA concentrations in both root and leaf tissues (Fig. 4) and root- and leaf-derived xylem sap (Fig. 7) of P. sativum, apparently in response to decreased P availability (Fig. 5A, B). Furthermore, additional P fertilizer prevented foliar ABA accumulation in limed plants (Fig. 4A). In P. sativum, foliar ABA concentrations increased below a threshold leaf tissue P concentration of ~2.5mg g–1 DW (Fig. 5A). This value appears to vary with species, since P-deprived R. communis (P concentration of 1.6mg g–1 DW) had a 2-fold increase in leaf ABA concentration (Jeschke et al., 1997), while P-deprived G. hirsutum (P concentration of 2.3mg g–1 DW) did not show elevated ABA concentrations compared with control plants containing 6.8mg g–1 DW (Radin, 1984). This suggests that it is not tissue P concentration per se, but a secondary signal that triggers foliar ABA accumulation. Reduced Ѱleaf under suboptimal P conditions may trigger leaf ABA synthesis (Zeevaart and Creelman, 1988). Although leaf tissue ABA and Ѱleaf were weakly correlated (Fig. 5D), significant leaf synthesis of ABA is not thought to occur until leaf water status reaches zero turgor (Pierce and Raschke, 1981); therefore, foliar water deficit is unlikely to be the principal signal triggering foliar ABA accumulation. An alternative argument is that increased root ABA accumulation in response to liming (Figs 4B, 5B) and its export in xylem sap (Fig. 7A) probably influences stomatal behaviour (Hartung et al., 2002). Unequivocally determining the site of increased ABA production in the current experiments is difficult. Reciprocal grafting experiments of WT plants with ABA-deficient mutants (Albacete et al., 2015) including those with the ABA-deficient wilty pea (Wang et al., 1984) have generally established that an ABA-deficient root system has little impact on xylem ABA concentration or stomatal closure in response to soil drying. However, hormone flow modelling techniques (sensuJeschke and Pate, 1991) indicate that in well-watered P-deprived plants, root biosynthesis contributes 82% of xylem exported ABA as opposed to being a moderate sink for ABA metabolism under P-sufficient conditions (Jeschke et al., 1997). Since liming increased both root and leaf xylem sap ABA concentrations equally over unlimed controls (Fig. 7A), and because significant quantities of leaf-synthesized ABA are unlikely to be recycled via the phloem under P deficiency (Jeschke et al., 1997), it is most likely that increased ABA under lime-induced suboptimal P is root synthesized. Irrespective of the source of this additional ABA in the transpiration stream, the concentrations detected (10nM) in both root and leaf xylem sap of limed P.sativum plants (Fig. 7A) were sufficient to decrease the transpiration rate of detached leaves (Fig. 7B), consistent with previous detached leaf experiments in pea (Dodd et al., 2008). Further evidence that the decrease in gs of limed plants was ABA mediated was provided by observations that gs of the ABA-deficient wilty was not affected by liming, whereas its WT and a commercial cultivar showed partial stomatal closure following liming (Fig. 8), apparently confirming that ABA induces stomatal closure. Substantial evidence is required to establish convincingly the physiological significance of any plant hormone in a given response, according to Jackson (1993). In fulfilling these criteria, this study correlates stomatal closure and foliar ABA concentration in vivo (Fig. 6B) and duplicates this response in an isolated system (Fig. 7B). Moreover, partially excluding ABA from limed P. sativum plants via the ABA-deficient wilty pea prevented the typical stomatal response to limed soil (Fig. 8). Taken together, this provides strong evidence that reduced gas exchange in legumes in response to lime-induced suboptimal P concentrations is mediated by the plant hormone ABA, and that this response limits photosynthesis, biomass accumulation, and crop yields (Fig. 9). Re-evaluating liming recommendations, and/or a better understanding of soil P dynamics following liming, seems necessary to avoid this ABA-mediated response. Fig. 9. Open in new tabDownload slide Conceptual model detailing the mechanistic understanding of the physiological processes by which lime can limit gas exchange and shoot growth. Solid lines represent processes established in this study and dashed lines indicate probable mechanisms. Fig. 9. Open in new tabDownload slide Conceptual model detailing the mechanistic understanding of the physiological processes by which lime can limit gas exchange and shoot growth. 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TI - Liming can decrease legume crop yield and leaf gas exchange by enhancing root to shoot ABA signalling
JF - Journal of Experimental Botany
DO - 10.1093/jxb/erv042
DA - 2015-04-01
UR - https://www.deepdyve.com/lp/oxford-university-press/liming-can-decrease-legume-crop-yield-and-leaf-gas-exchange-by-8ZuAACLe08
SP - 2335
EP - 2345
VL - 66
IS - 8
DP - DeepDyve
ER -