Abstract
Aim
Magnesium (Mg) deficiency (known as grass tetany) is a serious metabolic disorder that affects grazing ruminants. We tested whether Mg-fertiliser can increase Mg concentration of Italian ryegrasses (Lolium multiflorum L.) including a cultivar (cv. Bb2067; ‘Magnet’), bred to accumulate larger concentrations of Mg.
Methods
Under controlled environment (CE) conditions, three cultivars (cv. Bb2067, cv. Bb2068, cv. RvP) were grown in low-nutrient compost at six fertiliser rates (0–1500 μM MgCl2.6H2O). Under field conditions, the three cultivars in the CE condition and cv. Alamo were grown at two sites, and four rates of MgSO4 fertiliser application rates (0–200 kg ha−1 MgO). Multiple grass cuts were taken over two-years.
Results
Grass Mg concentration increased with increasing Mg-fertiliser application rates in all cultivars and conditions. Under field conditions, cv. Bb2067 had 11–73% greater grass Mg concentration and smaller forage tetany index (FTI) than other cultivars across the Mg-fertiliser application rates, sites and cuts. Grass dry matter (DM) yield of cv. Bb2067 was significantly (p < 0.05) smaller than cv. Alamo. The effect of Mg-fertiliser rate on DM yield was not significant (p ≥ 0.05).
Conclusions
Biofortification of grass with Mg through breeding and agronomy can improve the forage Mg concentration for grazing ruminants, even in high-growth spring grass conditions when hypomagnesaemia is most prevalent. Response to agronomic biofortification varied with cultivar, Mg-fertiliser rate, site and weather. The cost:benefit of these approaches and farmer acceptability, and the impact on cattle and sheep grazing on grasses biofortified with Mg requires further investigation.
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Introduction
Grazing landscapes and ruminant livestock have a dominant role in the environmental, economic and food security of many countries, especially in temperate regions. For example, in 2017/18, 72% of the UK’s land area (17.5 M ha) was utilised for agriculture; of that area the proportion of grazing land was 35% permanent grass, 22% sole rights rough grazing, 6.9% common land rough grazing, and 6.5% temporary grass (DEFRA 2018a). These grazing lands supported a ruminant livestock population of 10 million cattle and 35 million sheep. Among EU states, the UK has the largest sheep population and the third largest cattle population, after France and Germany (DEFRA 2018b). UK agriculture contributed £10.3 billion to the national economy in 2017 with grazing ruminants (i.e., cattle and sheep) representing >50% of this total (DEFRA 2018c).
Maintaining a thriving grazing ruminant sector requires supplying livestock with balanced nutrients through forages (Agricultural Research Council 1980; McDowell and Valle 2000; Voison 1963). Magnesium (Mg) is among the essential mineral nutrients for grazing ruminants, required to ensure a healthy skeleton, metabolism, cardiovascular and neuromuscular transmission (Ebel and Günther 1980; Schonewille 2013; Underwood and Suttle 1999). Livestock dietary Mg requirement vary depending on the species, breed, physiological conditions, age and growth rate of the animal, and the type of feed (Agricultural Research Council 1980). The recommended Mg concentration for grazing ruminants ranges between 1300 and 2200 mg kg−1 DM for cattle, and 900 and 1200 mg kg−1 DM for sheep (CSIRO 2007) with the critical recommended Mg concentration of 2000 mg kg−1 DM (Mayland and Hankins 2001; McDowell and Valle 2000).
In livestock, ~70% of Mg is stored in the skeleton and this pool is not easily mobilised when dietary Mg intake is reduced (Martens and Stumpff 2019; Suttle 2010). Hence, grazing ruminants need to be continuously supplied with forage that meets their Mg requirement. When the quantity of Mg supplied through feed is low, or when absorption in the rumen is impaired, the blood and cerebrospinal fluid Mg level can decline below clinical thresholds causing a physiological disorder known as hypomagnesaemic tetany (also known as grass tetany or grass staggers) (Dua and Care 1995; Henkens et al. 1973; Martens and Stumpff 2019; Suttle 2010). Ruminal absorption of Mg can be impaired by the imbalance of forage Mg2+, calcium (Ca2+) and potassium (K+) ions, which is termed as the forage tetany index (FTI) (Eq. 1) (Kemp and ‘T hart 1957). The risk of hypomagnesaemic tetany is considered to be high in livestock consuming forage with FTI exceeding 2.2 (Crawford et al. 1998; Elliot 2008; Kemp and ‘T hart 1957; Mayland and Hankins 2001; McNaught et al. 1973; Metson et al. 1966). Annually, in the UK hypomagnesaemic tetany is reported to affect 0.5% of dairy herds, and up to 10% on some dairy farms (Foster et al. 2007).
Where, mEq is the milli equivalent of the elements (i.e., the elemental concentration (mg kg−1 DM) is divided by the atomic weight and multiplied by the valence of the respective elements).
In addition to cation imbalances in the forage, lush spring grass tends to be low in fibre and high in dry matter (DM) digestibility which accelerates rumen passage and reducing the ruminal absorption of Mg (Suttle 2010). This is further exacerbated by over application of K to grasslands as fertiliser, including from livestock manures (Agricultural Research Council 1980; Bhanugopan et al. 2015; Lunnan et al. 2018). Excess K+ in the soil solution suppresses the absorption of Mg2+ by plant roots (Elliot 2008).
There is considerable inter and intra-species variation in the concentration of Mg in forages. Mean concentration of Mg (mg kg−1 DM ± SD) reported include: grass hay 1400 ± 520, grass silage 1700 ± 540, clover silage 2300 ± 750, lucerne hay 1700 ± 270, maize silage 2200 ± 690 (Suttle 2010), and ryegrasses ranging between 1300 and 5500 (Crush 1983), 1100–6800 (Crush et al. 2018). Median Mg concentration in ryegrass and clover forages was reported to be 2200 (mg kg−1 DM) in New Zealand (Knowles and Grace 2014).
An Italian ryegrass (Lolium multiflorum L.) synthetic variety called Magnet (S417, Bb2067) with increased grass Mg concentration was bred by the Welsh Plant Breeding Station in the 1970s (Moseley and Baker 1991). This variety was shown to be effective in reducing hypomagnesaemic tetany in grazing sheep (Moseley and Baker 1991). However, the cultivar was never commercialised, due primarily to slightly smaller DM yield performance in National List trials in the late 1980s. The performance of cv. Bb2067 has not previously been assessed under altered Mg-fertiliser inputs. The aims of this research were (1) to test whether it is possible to raise the grass Mg concentration in Italian ryegrass by applying different rates of Mg-fertiliser, under controlled environment and field conditions; and (2) to explore the relative performance of cv. Bb2067 compared to modern Italian ryegrass cultivars under agronomic Mg biofortification.
Materials and methods
Controlled environment (CE) experiment
The CE experiment was conducted at the Sutton Bonington Campus of the University of Nottingham in 2016. Three cultivars, cv. Bb2067, cv. Bb2068 and cv. RvP were sown on 09 August 2016 in 576 cell trays (Plantpak plug tray 576 cell, Dejex Supplies Ltd., Donnington, UK) in compost (Levington F2 + S, Dejex Supplies Ltd) with a topping of fine horticultural grade silver sand (Dejex Supplies Ltd). The trays were transferred to a controlled environment room (20 °C day, 18 °C night, 16 h day length) and watered every other day with HortiMix standard (Dejex Supplies Ltd) at 10 ml L−1. After 21 days, plants were transplanted into 96 well trays (Dejex Supplies Ltd) containing low nutrient media (50% coarse sand, 50% Kettering loam, Dejex Supplies Ltd). Plants were watered every other day with Hortimix standard. In total there were 18 trays, each containing 8 plants of each line, randomly assigned to the central part of the tray. These plants were surrounded by cv. RvP plants to act as guard rows.
Thirty seven days after transplanting, the plants were cut leaving ~1 cm of aerial tissue. The cut plants were then watered every other day with 6 Mg treatments at 0, 75, 188, 375, 750 and 1500 μM MgCl2.6H2O. These were applied as 1 L per tray of a liquid feed based on Hoagland’s media, containing 0.25 mM KH2P04, 0.5 mM KOH, 0.75 mM MgCl2.6H2O, 0.75 mM H2SO4, 0.1 mM FeNaEDTA, 2 mM Ca(NO3)2.4H2O, 2 mM NH4NO3, 30 μM H3BO3, 10 μM MnSO4.4H2O, 1 μM ZnSO4.7H2O, 3 μM CuSO4.5H2O, and 0.5 μM Na2MoO4.2H2O. The pH was maintained at 6.4.
All plants were sampled after 28 days, by cutting plants ~1 cm above the surface. The grass was placed in paper bags and oven dried at 50 °C until dry. The samples were digested in 2 mL 70% Trace Analysis Grade HNO3 and analysed by ICP-MS as described by Thomas et al. (2016).
Field experiments design and treatments
Field experiments were conducted at Aberystwyth, Wales (52°26′00.6”N 4°00′36.7”W; 31 m.a.s.l.) and Edinburgh, Scotland (55°55′40.1”N 3°20′28.0”W; 57 m.a.s.l.) across two years (2017–2018). The soil type at Aberystwyth is well drained loam over gravel in the Eutric Endoskeleti-Eutric Cambisols (IUSS Working Group WRB 2007) Rheidol series (Cranfield University 2019). The site at Edinburgh has a coarse textured soil (sandy-silt-loam or sandy-clay-loam) in the Macmerry series (The James Hutton Institute 2019). A randomised complete block design was adopted with four and three replications at Aberystwyth and Edinburgh, respectively. Two treatment factors (cultivar and fertiliser rate), each with four levels provided 16 treatment combinations. The cultivars were cv. Bb2067, cv. Bb2068, cv. Alamo and cv. RvP. Cultivars Bb2067 and Bb2068 are large and small Mg accumulating cultivars, respectively, which have not been commercially released. Cultivars Bb2067 and Bb2068 were bulked progeny of 2 generations of selection for Mg content. Cultivar RvP was a current variety when these selections were made and individuals with large Mg selected from this cultivar comprised ~25% of cv. Bb2067 along with recurrent selections from the Lolium multiflorum breeding program. Cultivar Alamo is a modern and commonly grown commercial variety in the UK.
Plots of size 3 m * 1.2 m were sown in August 2016 at a seed rate of 35 kg ha−1. Compound NPK fertiliser (N [22%], P2O5 [4%], K2O [14%] SO3 [7.5%]) was added at a rate of 60 kg ha−1 prior to the first cut (March 2017), and then at 100, 100, and 60 kg ha−1 after cuts 1, 2, 3, respectively, and then 35 kg ha−1 after all subsequent cuts. No fertiliser was added after the final cut. The Mg fertiliser was applied in April 2017 and March 2018 as magnesium sulphate (MgSO4) at MgO equivalent rates of 0, 50, 100, and 200 kg ha−1. Reagent grade ≥ 97% anhydrous MgSO4 (Honeywell Specialty Chemicals GmbH, Seelze, Germany) was dissolved in warm water and applied with a calibrated knap sack sprayer after the first sward management cutting. Magnesium fertiliser application rates were scaled in relation to a recommendation of 50–200 kg ha−1 of MgO application every 3–4 years when exchangeable soil Mg is < 26 mg L−1 (AHDB 2017).
Grass harvesting was conducted using a Haldrup forage harvester at a cutting height of 5 cm above ground. In 2017, six grass cuts were taken at both sites. In 2018, five cuts were taken from Aberystwyth and seven from Edinburgh. Grass harvesting technique followed combined management as per UK National Lists trials protocol (Animal and Plant Health Agency 2019). During each cut, fresh weights were measured and DM yields were calculated after drying a 200–500 g subsample from each plot in a forced draught oven at 80 °C for 48 h. The dried sub-sample was milled, further subsampled, digested in 2 mL 70% Trace Analysis Grade HNO3 and analysed for concentration of Mg and other mineral elements by ICP-MS as described by Thomas et al. (2016), and certified reference materials were used to check analytical quality.
The FTI (Eq. 1) was calculated as the molar ratio of K+ to the sum of Ca2+ and Mg2+ in the grass. Where the FTI is >2.2, the risk of grass tetany in ruminants grazing on such feed is high (Kemp and ‘T hart 1957).
Soil mineral composition analyses
Prior to sowing, composite soil samples (0–15 cm depth) were collected with an auger, using a “W” transect across each site to determine baseline soil physico-chemical properties. Soil samples were also collected from the 16 treatments (samples from the centre of each of four replicate plots were composited) at the beginning of June 2018, after the second Mg-fertiliser application. The baseline soil pH (in water), and exchangeable Mg, Ca and K were analysed at Lancrop Laboratory (Pocklington, UK) while the second-year soil pH, and exchangeable Mg, Ca and K concentrations were analysed at the University of Nottingham. At both laboratories, a similar procedure was followed. Thus, 5 mg of <2 mm sieved soil was dissolved in 25 mL of 1 M NH4NO3. The solution was shaken on an end-over-end shaker for 30 min followed by centrifuging for 15 min at 3000 rpm. The supernatant was then filtered using <0.22 μm syringe filter. The filtered solution was acidified with 0.2 mL of 50% (v/v) HNO3 and analysed using ICP-MS (ICP-MS; iCAP-Q, Thermo-Scientific, Loughborough, UK) at the University of Nottingham (Thomas et al. 2016), and inductively coupled plasma optical emission spectrometry (ICP-OES) at Lancrop.
Data analysis
Data were compiled in MS Excel and Access. For field experiments where repeated observations (i.e., successive cuts) were made, statistical analyses were conducted using R (R Core Team 2018). Exploratory data analysis was undertaken on the residuals of an initial analysis of the data. The histogram of the residuals was inspected to assess the plausibility of an assumption of normality, and a plot of the residuals against the fitted values was inspected to assess the plausibility of an assumption that the variance of the residuals was homogeneous. When required, the data were transformed to natural logarithms to make this assumption plausible. Outliers were identified according to the outer fences of Tukey (1977) procedure whereby a datum is excluded if the residual lies more than three times the interquartile range below or above the first or third quartile, respectively. Accordingly, for grass Mg, FTI and S, the number of outlier data points excluded were two (Aberystwyth 2017), and three (Edinburgh 2018). In addition, for grass S, three more data points were excluded from Edinburgh 2018. A planned orthogonal set of contrasts was identified and mean comparison of grass Mg, FTI and S was conducted between, under field conditions, (i) the large Mg-accumulating cv. Bb2067 and other Italian ryegrass cultivars (ii) cv. Bb2068 and the two conventional varieties and (iii) cv. Alamo and cv. RvP. Under CE condition, comparison was made between i) cv. Bb2067 and the other two Italian ryegrass cultivars, and ii) cv. Bb2068 and cv. RvP.
Analyses of variances of the repeated observation (i.e., successive cuts) was addressed by the use of a linear mixed model. Two models were considered. In the first (sphericity assumption) where the correlation between the residuals for any two measures on the same unit were treated as uniform. In the second an exponential autocorrelation for successive measurements was assumed. The two models were fitted using the nlme package (Pinheiro et al. 2018) for the R platform (R Core Team 2018). The choice between the alternative models was then made based on Akaike’s information criterion (AIC), selecting the model for which this was smallest.
Analysis of variance on the grass dry matter yield and soil properties in the field experiments was conducted by fitting a generalised linear model without any transformation in MINITAB 18. Visualisations were also produced using MINITAB 18 (MINITAB 2017).
Results
Raw mineral element concentration data of Italian ryegrasses of the CE experiment and field experiments, and exchangeable soil cations and dry matter yield of Italian ryegrasses data for the field experiments are given in Online Resources (Sup Table 1–4).
Grass Mg concentration and Forage Tetany index (FTI) in the controlled environment (CE) experiment
Grass Mg concentration increased with increasing Mg application rate (p < 0.05, Table 1), with all cultivars responding similarly (Fig. 1). Cultivar Bb2067 consistently had a greater Mg concentration than cv. RvP, which itself had consistently greater Mg than cv. Bb2068 at all Mg application rates (Fig. 1). Both planned contrasts among the cultivar means for Mg concentration were significant (p < 0.01) as shown in the Online Resource (Sup Table 5). At the largest Mg application rate (1500 μM MgCl2.6H2O), the grass Mg concentration (mg kg−1 DM; mean ± SD, n = 24) was 4966 ± 880 (cv. Bb2067), 3115 ± 1018 (cv. Bb2068), and 3889 ± 878 (cv. RvP). At the zero Mg application rate, the grass Mg concentration (mg kg−1 DM, mean ± SD, n = 24) was 2366 ± 381 (cv. Bb2067), 1382 ± 343 (cv. Bb2068), and 1629 ± 320 (cv. RvP). There was no significant interaction effect of cultivar × Mg application rate on grass Mg concentration (p ≥ 0.05) (Table 1).
The FTI did not significantly (p ≥ 0.05) decrease with increasing Mg application rate (Table 1). Cultivar Bb2067 had the smallest FTI at all Mg treatment levels (Fig. 1). At the largest Mg application rate, the FTI (mean ± SD) was 0.55 ± 0.11 (cv. Bb2067), 0.92 ± 0.40 (cv. Bb2068), and 0.74 ± 0.22 (cv. RvP). At the smallest Mg-fertiliser application rate, the FTI (mean ± SD) was 0.91 ± 0.24 (cv. Bb2067), 1.31 ± 0.55 (cv. Bb2068), and 1.05 ± 0.32 (cv. RvP). As with Mg concentration, both orthogonal contrasts among the cultivar means were significant (p < 0.01) as shown in the Online Resource Sup Table 5. There was no significant interaction effect of cultivar × Mg application rate on FTI (p ≥ 0.05, Table 1).
Soil properties at the field experimental sites
The baseline exchangeable soil Mg concentration was 86 mg L−1 at Aberystwyth and 193 mg L−1 at Edinburgh (Table 2). At both sites, exchangeable soil Mg concentration increased significantly (p < 0.05) due to the application of MgSO4 (Table 2). Thus, post-fertiliser application, the mean exchangeable soil Mg concentration (mg L−1) for control plots was 80 at Aberystwyth and 177 at Edinburgh. The increase in the exchangeable soil Mg concentration at Aberystwyth was 20%, 39%, and 74%, and at Edinburgh was 10%, 12% and 32%, at Mg-fertiliser application rates of 50, 100 and 200 kg MgO ha−1, respectively. Baseline exchangeable soil Ca and K concentration, and soil pH were below the recommended optimal for forage cultivation at both sites (Table 2) (AHDB 2017) and were not significantly affected by the application of MgSO4.
Grass Mg and Forage Tetany index (FTI) in the field experiments
Aberystwyth
Grass Mg concentration increased with an increasing Mg-fertiliser application rate for all the cultivars in 2017 and 2018 (Fig. 2). Cultivar Bb2067 had greater grass Mg concentration than all other varieties at all Mg-fertiliser application rates, cuts and in both years (Figs. 2 and 3). Planned contrasts among the cultivar means for Mg concentration were significant (p < 0.01) except the one between cv. Alamo and cv. RvP as shown in the Online Resource (Sup Table 6). In 2017, at the largest Mg-fertiliser application rate (200 kg ha−1), the grass Mg concentrations (mg kg−1 DM; mean ± SD) were 2637 ± 506 (cv. Bb2067, n = 23), 1674 ± 314 (cv. Bb2068, n = 24), 2009 ± 454 (cv. Alamo, n = 23), and 1907 ± 431 (cv. RvP, n = 23). At the zero Mg-fertiliser application rate, the grass Mg concentrations (mg kg−1 DM; mean ± SD) were 2104 ± 495 (cv. Bb2067, n = 23), 1543 ± 423 (cv. Bb2068, n = 24), 1786 ± 457 (cv. Alamo, n = 24), and 1787 ± 490 (cv. RvP, n = 24). In 2018, at the largest Mg-fertiliser application rate, the grass Mg concentrations (mg kg−1 DM; mean ± SD, n = 20) were 2990 ± 628 (cv. Bb2067), 2414 ± 671 (cv. Bb2068), 2691 ± 624 (cv. Alamo), and 2563 ± 643 (cv. RvP). At the zero Mg-fertiliser application rate, the grass Mg concentrations (mg kg−1 DM; mean ± SD) were 2545 ± 589 (cv. Bb2067), 2201 ± 694 (cv. Bb2068), 2101 ± 572 (cv. Alamo) and 2050 ± 553 (cv. RVP) (Fig. 2). In 2018, there was a significant (p < 0.05) cultivar × Mg-fertiliser application rate, cultivar × cutting date, and Mg-fertiliser rate × cutting date interaction effect on grass Mg concentration. In 2017, there was cultivar × cutting date, and Mg-fertiliser rate × cutting date interaction effect on grass Mg concentration. There was no significant (p ≥ 0.05) cultivar × Mg-fertiliser application rate × cutting date interaction effect on the grass Mg concentration in either year (Table 3).
The FTI decreased with an increasing Mg-fertiliser application rate for all cultivars with cultivar Bb2067 having the smallest FTI. Planned contrasts among the cultivar means for FTI were significant (p < 0.01) except the one between cv. Alamo and cv. RvP as shown in the Online Resource (Sup Table 6). In 2017, at the largest Mg-fertiliser application rate the FTI (mean ± SD) was 1.42 ± 0.22 (cv. Bb2067), 1.88 ± 0.34 (cv. Bb2068), 1.66 ± 0.23 (cv. Alamo) and 1.68 ± 0.29 (cv. RvP). The FTI (mean ± SD) at the zero Mg-fertiliser rate was 1.60 ± 0.28 (cv. Bb2067), 1.88 ± 0.34 (cv. Bb2068) 1.78 ± 0.28 (cv. Alamo), and 1.60 ± 0.30 (cv. RvP) (Fig. 2). In 2018, at the largest Mg-fertiliser application rate, the FTI (mean ± SD) was 1.25 ± 0.28 (cv. Bb2067), 1.39 ± 0.40 (cv. Bb2068), 1.30 ± 0.35 (cv. Alamo) and 1.30 ± 0.33 (cv. RvP). At the zero Mg-fertiliser rate, the FTI (mean ± SD) was 1.28 ± 0.31 (cv. Bb2067), 1.40 ± 0.38 (cv. Bb2068), 1.45 ± 0.0.35 (cv. Alamo), and 1.36 ± 0.37 (cv. RvP) (Fig. 2). The FTI was significantly (p < 0.05) affected by cultivar, cutting date, and cultivar × cutting date interaction in 2017 and 2018, but the effect of Mg-fertiliser rate on FTI was only significant in 2018. There was no statistically significant (p ≥ 0.05) cultivar × Mg-fertiliser rate, Mg-fertiliser rate × cutting date, or cultivar × Mg-fertiliser rate × cutting date, interaction effect on the FTI (Table 3).
Edinburgh
Grass Mg concentration increased with an increasing Mg-fertiliser application rate for all cultivars in 2017 and 2018 (Fig. 4). Cultivar Bb2067 accumulated greater grass Mg concentration than cv. Bb2068, cv. Alamo and cv. RvP at all Mg-fertiliser application rates, cutting dates and in both years (Figs. 4 and 5). Planned contrasts among the cultivar means for Mg concentration were significant (p < 0.01) except the one between cv. Alamo and cv. RvP as shown in the Online Resource (Sup Table 6). In 2017, at the largest Mg-fertiliser application rate (200 kg ha−1), the grass Mg concentrations (mg kg−1 DM; mean ± SD) were 2801 ± 521 (cv. Bb2067, n = 17), 1698 ± 410 (cv. Bb2068, n = 17), 2122 ± 514 (cv. Alamo, n = 18) and 1945 ± 433 (cv. RvP, n = 18). At the zero Mg-fertiliser application rate the grass Mg concentrations (mg kg−1 DM; mean ± SD) were 2337 ± 478 (cv. Bb2067, n = 17), 1354 ± 304 (cv. Bb2068), 1732 ± 438 (cv. Alamo, n = 18) and 1632 ± 386 (cv. RVP, n = 17). In 2018, at the largest Mg-fertiliser application rate, the grass Mg concentrations (mg kg−1 DM; mean ± SD, n = 21) were 4205 ± 746 (cv. Bb2067), 2578 ± 503 (cv. Bb2068), 3094 ± 726 (cv. Alamo) and 2965 ± 707 (cv. RvP). At the zero Mg-fertiliser application rate, the grass Mg concentrations (mg kg−1 DM; mean ± SD, n = 21) were 3239 ± 531 (cv. Bb2067, n = 20), 2103 ± 395 (cv. Bb2068), 2526 ± 498 (cv. Alamo) and 2437 ± 480 (cv. RVP) (Fig. 4). In 2017 and 2018, the grass Mg concentration was significantly (p < 0.05) affected by cultivar, Mg-fertiliser application rate and cutting date. The cultivar × cutting date, and Mg-fertiliser application rate × cutting date interaction effect on grass Mg concentration was significant (p < 0.05) in both years. There was significant (p < 0.05) cultivar × Mg-fertiliser rate × cutting date interaction effect on grass Mg concentration in 2018 but not in 2017 (Table 4).
The FTI decreased with an increasing Mg-fertiliser application rate, for all cultivars, with cv. Bb2067 having the smallest FTI (Fig. 4). Planned contrasts among the cultivar means for FTI were significant (p < 0.01) except the one between cv. Alamo and cv. RvP in 2017 as shown in the Online Resource (Sup Table 6). In 2017, at the largest Mg-fertiliser application rate, the FTI (mean ± SD) was 1.53 ± 0.23 (cv. Bb2067), 2.02 ± 0.41 (cv. Bb2068), 1.82 ± 0.29 (cv. Alamo) and 1.81 ± 0.30 (cv. RvP). At the zero Mg-fertiliser application rate, the FTI (mean ± SD) was 1.57 ± 0.21 (cv. Bb2067), 2.15 ± 0.34 (cv. Bb2068), 1.88 ± 0.26 (cv. Alamo) and 1.89 ± 0.20 (cv. RvP). In 2018, at the largest Mg-fertiliser application rate, the FTI (mean ± SD) was 0.96 ± 0.26 (cv. Bb2067), 1.32 ± 0.38 (cv. Bb2068), 1.20 ± 0.31 (cv. Alamo) and 1.16 ± 0.30 (cv. RvP). At the zero Mg-fertiliser application rate, the FTI (mean ± SD) was 1.03 ± 0.28 (cv. Bb2067), 1.39 ± 0.38 (cv. Bb2068), 1.28 ± 0.34 (cv. Alamo) and 1.18 ± 0.29 (cv. RvP). In 2017 and 2018, the FTI was significantly (p < 0.05) affected by cultivar, Mg-fertiliser application rate and cutting date. Cultivar × cutting date, and Mg-fertiliser rate × cutting date interaction effect was significant (p < 0.05) on FTI in 2017 and 2018. There was no significant (p ≥ 0.05) cultivar × Mg-fertiliser, and cultivar × Mg-fertiliser rate × cutting date interaction effect on FTI in both years (Table 4).
Grass dry matter yield from field experiments
The rate of Mg-fertiliser application did not significantly affect the annual total dry matter yield at either of the sites or in either year. At Aberystwyth, at the zero Mg-fertiliser application rate, total dry matter yields (t ha−1 p.a.; mean ± SD) were 21.0 ± 0.7 (cv. Bb2067), 21.0 ± 0.7 (cv. Bb2068), 24.5 ± 2 (cv. Alamo), and 22.9 ± 1.0 (cv. RvP) in 2017. At the largest Mg-fertiliser application rate (200 kg ha−1), total dry matter yields (t ha−1 p.a.; mean ± SD) were 21.0 ± 0.9 (cv. Bb2067), 21.2 ± 0.9 (cv. Bb2068), 24.1 ± 0.5 (cv. Alamo), and 23.3 ± 0.9 (cv. RvP). In 2018, at the zero Mg-fertiliser application rate, total dry matter yields (t ha−1 p.a.; mean ± SD) were 6.6 ± 0.6 (cv. Bb2067), 6.4 ± 0.5 (cv. Bb2068), 8.7 ± 0.7 (cv. Alamo), and 8.2 ± 0.8 (cv. RvP). At the largest Mg-fertiliser application rate, total dry matter yields (t ha−1; mean ± SD) were 6.9 ± 0.3 (cv. Bb2067), 6.7 ± 0.5 (cv. Bb2068), 9 ± 0.6 (cv. Alamo), and 9.1 ± 0.3 (cv. RvP) (Fig. 6).
At Edinburgh, in 2017, at the zero Mg-fertiliser application rate, the total dry matter yields (t ha−1 p.a.; mean ± SD) were 19.8 ± 0.5 (cv. Bb2067), 19.6 ± 0.9 (cv. Bb2068), 21.8 ± 1.6 (cv. Alamo), and 19.9 ± 1.5 (cv. RvP). At the largest Mg-fertiliser application rate, total dry matter yields (t ha−1 p.a.; mean ± SD) were 19.6 ± 1.4 (cv. Bb2067), 19.7 ± 0.7 (cv. Bb2068), 20.4 ± 0.6 (cv. Alamo), and 20.2 ± 1.6 (cv. RvP). In 2018, at the zero Mg-fertiliser application rate, total dry matter yields (t ha−1 p.a.; mean ± SD) were 7.8 ± 0.2 (cv. Bb2067), 8 ± 0.1 (cv. Bb2068), 9.4 ± 0.8 (cv. Alamo), and 9.3 ± 0.3 (cv. RvP). At the largest Mg-fertiliser application rate, dry matter yields (t ha−1; mean ± SD) were 7.5 ± 1 (cv. Bb2067), 8.3 ± 0.2 (cv. Bb2068), 9.1 ± 0.1 (cv. Alamo), and 8.4 ± 0.4 (cv. RvP) (Fig. 7).
The total annual grass dry matter yield was affected by cultivar in both 2017 and 2018, with cv. Bb2067 and cv. Bb2068 having smaller yields than the commercial cultivars, cv. Alamo and cv. RvP. At both trial sites, the grass biomass yield in 2018 was 55–67% less than the yield in 2017 (Figs. 6 and 7) due to drought.
There were no significant (p ≥ 0.05) interaction effects of cultivar × Mg-fertiliser application rate, cultivar × cutting date, cultivar × Mg-fertiliser or cultivar × Mg-fertiliser rate × cutting date on the grass biomass yield at both sites in both years. There was a highly significant (p < 0.01) negative correlation between grass biomass yield and Mg concentration. The correlation between grass DM yield and Mg concentration at Aberystwyth was (in 2017, −0.308; in 2018, −0.495), and at Edinburgh was (in 2017, −0.194; in 2018, −0.447).
Grass Sulphur (S) concentration from field experiments
At both field experimental sites, grass S concentration increased with an increasing Mg-fertiliser (MgSO4) application rate for all the cultivars in 2017 and 2018 (Figs. 6 and 7). Cultivar Bb2067 accumulated significantly (p < 0.05) more S in its biomass than the other three Italian ryegrass cultivars. Planned contrasts among the cultivars mean S concentration were significant (p < 0.01) except the one between cv. Alamo and cv. RvP as shown in the Online Resource (Sup Table 6). At Aberystwyth, grass S concentration was significantly (p < 0.05) affected by cultivar, Mg-fertiliser application rate, cutting date, and by the interaction effect of cultivar × cutting date and Mg-fertiliser rate × cutting date, in 2017 and 2018 (Table 5). There were no significant interaction effects of cultivar × Mg-fertiliser application rate × cutting date on grass S concentration (Table 5). At Edinburgh, in 2017 and 2018, the grass S concentration was significantly (p < 0.05) affected by cultivar, Mg-fertiliser application rate and cutting date. The cultivar × Mg-fertiliser application rate, and cultivar × cutting date interaction effect on grass S concentration was significant (p < 0.05) in 2018 but not in 2017 (Table 5). On the other hand, Mg-fertiliser rate × cutting date interaction effect on grass S was significant (p < 0.05) in both years. There was no significant (p ≥ 0.05) cultivar × Mg-fertiliser application rate × cutting date interaction effect on grass S concentration (Table 5).
At Aberystwyth, in 2017, at the largest Mg-fertiliser application rate (200 kg ha−1), the grass S concentrations (mg kg−1 DM; mean ± SD, n = 23) were 3257 ± 703 (cv. Bb2067), 2738 ± 476 (cv. Bb2068, n = 24), 2790 ± 697 (cv. Alamo) and 2838 ± 595 (cv. RvP). At the zero Mg-fertiliser application rate the grass S concentrations (mg kg−1 DM; mean ± SD, n = 24) were 2814 ± 588 (cv. Bb2067, n = 23), 2540 ± 512 (cv. Bb2068), 2599 ± 561 (cv. Alamo) and 2662 ± 573 (cv. RvP). In 2018, at the largest Mg-fertiliser application rate, the grass S concentrations (mg kg−1 DM; mean ± SD, n = 20) were 3970 ± 845 (cv. Bb2067), 3266 ± 592 (cv. Bb2068), 3345 ± 429 (cv. Alamo) and 3382 ± 604 (cv. RvP). At the zero Mg-fertiliser application rate, the grass S concentrations (mg kg−1 DM; mean ± SD, n = 20) were 3309 ± 601 (cv. Bb2067, n = 20), 3155 ± 575 (cv. Bb2068), 2861 ± 637 (cv. Alamo) and 2830 ± 639 (cv. RVP) (Fig. 6).
At Edinburgh, in 2017, at the largest Mg-fertiliser application rate (200 kg ha−1), the grass S concentrations (mg kg−1 DM; mean ± SD) were 4063 ± 844 (cv. Bb2067, n = 18), 3153 ± 600 (cv. Bb2068, n = 17), 3510 ± 860 (cv. Alamo, n = 18) and 3372 ± 782 (cv. RvP, n = 18). At the zero Mg-fertiliser application rate the grass S concentrations (mg kg−1 DM; mean ± SD, n = 17) were 3393 ± 1033 (cv. Bb2067, n = 18), 2638 ± 819 (cv. Bb2068), 2973 ± 898 (cv. Alamo, n = 18) and 2931 ± 904 (cv. RVP). In 2018, at the largest Mg-fertiliser application rate, the grass S concentrations (mg kg−1 DM; mean ± SD, n = 21) were 4303 ± 908 (cv. Bb2067), 3292 ± 813 (cv. Bb2068), 3526 ± 909 (cv. Alamo) and 3502 ± 820 (cv. RVP). At the zero Mg-fertiliser application rate, the grass S concentrations (mg kg−1 DM; mean ± SD, n = 21) were 3154 ± 747 (cv. Bb2067, n = 20), 2885 ± 645 (cv. Bb2068), 2835 ± 627 (cv. Alamo) and 2742 ± 614 (cv. RVP) (Fig. 7).
Discussion
Raising grass Mg concentration to control hypomagnesaemic tetany in grazing ruminants is possible via agronomic and genetic biofortification of Italian ryegrass. Response to agronomic biofortification varied with cultivar, Mg-fertiliser rate, site and weather. Average grass Mg concentration in the large Mg-accumulator cv. Bb2067 was consistently above 2000 mg kg−1 DM forage Mg concentration threshold (Mayland and Hankins 2001) across sites and years when there was no Mg-fertiliser applied. Despite the contrasting extractable soil Mg at Aberystwyth and Edinburgh experimental sites, grass Mg concentration in the other Italian ryegrass cultivars was below 2000 mg kg−1 DM with or without Mg-fertiliser application in 2017. In 2018, the grass Mg concentration in all Italian ryegrass cultivars was well above the 2000 mg kg−1 DM threshold at both sites regardless of Mg fertiliser application. The contrast in grass Mg concentration between the two years is assumed to be due to the dilution effect of normal biomass production in 2017 compared with the smaller biomass yield in 2018 because of drought. The negative correlation between grass DM yield and Mg concentration also shows the biomass yield dilution effect on Mg concentration. Forage Ca, Mg and K imbalance was not observed in this study, as the average FTI of all Italian ryegrasses tested was <2.2 (Mayland and Hankins 2001) at all Mg-fertiliser levels under CE and field conditions. Nonetheless, cv. Bb2067 had significantly smaller FTI than the other cultivars.
Agronomic biofortification of Italian ryegrasses with Mg fertilisers
Grass Mg concentration in Italian ryegrass can be increased by applying Mg-fertiliser. The current study used MgCl2 in the CE experiment, which is widely used source of Mg in liquid fertilisers (Mikkelsen 2010), and anhydrous magnesium sulphate (MgSO4) for the field experiment. There are a range of potential Mg resources including dolomitic limestone (for example, Bolan et al. 2005; McNaught et al. 1973; Mikkelsen 2010; Yermiyahu et al. 2017; Parnes 2013).
Under CE conditions, we observed 85–140% increases in grass Mg concentration across three Italian ryegrass cultivars at an application rate of 1500 μM MgCl2. In the field, there were 7–25% increases across the four Italian ryegrass cultivars at the application rate of 200 kg ha−1 MgO equivalent of MgSO4. In agreement with studies elsewhere (e.g., McNaught et al. (1973) the grass Mg concentration varied across the two experimental sites which had contrasting extractable soil Mg. Mg-fertiliser did not affect the dry matter yield of Italian ryegrass cultivars in either year, under adequate rain (2017) or drought (2018) conditions. Further steps should include cost-benefit analyses of using MgSO4 as a source of Mg-fertiliser to improve grass Mg concentration and its impact on the Mg status of ruminants grazing on the forages. Optimum frequency of Mg-fertiliser application and the responses of Italian ryegrass to different Mg-fertiliser types may also be worth exploring.
Genetic biofortification of Italian ryegrasses with Mg is feasible
Cultivar Bb2067/Magnet was previously shown to reduce hypomagnesaemic tetany in grazing sheep (Moseley and Baker 1991). Here, Bb2067 had greater (5–73%) grass Mg concentration at all Mg-fertiliser application rates, cutting dates, and sites even when dry matter yields were affected by drought in 2018. Cultivar Bb2068 had the smallest concentration of grass Mg under corresponding scenarios. These two varieties were selected as large (cv. Bb2067) and small (cv. Bb2068) Mg-accumulators originating from the same group of commercial varieties through recurrent selection. Cultivar Bb2067 clearly shows the potential for genetic biofortification. However, it had not been commercialised due to its slightly smaller dry matter yield than Italian ryegrass cultivars of its time. The herbage dry matter yield of cv. Bb2067 compared with the largest yielding cv. Alamo over two years was 86% (2017) and 76% (2018) at Aberystwyth, and 93% (2017), 85% (2018) at Edinburgh. The average annual dry matter yield cv. Alamo was reported to be 18.06 t ha−1 DM (AHDB 2018). The average dry matter yield (> 20 t ha−1 DM) of cv. Bb2067 in these trials in 2017 was well above that perennial ryegrass under conservation sward management and comparable to cv. Alamo under farmer management. There is a need to transfer cv. Bb2067 Mg-accumulating trait into the cultivars that yield larger biomass (Capstaff and Miller 2018). To facilitate this process, it might be possible to identify genetic markers that are responsible for the accumulation of Mg in cv. Bb2067.
Other potential nutritional consequences of Mg biofortification
There may be additional nutrient benefits for grazing ruminants given that MgSO4 application also increased grass S. Sulphur is an essential element for crops and livestock, and it is estimated that S deficiency is widespread in UK arable and pasturelands (Donald et al. 1999; Zhao and McGrath 1994) which could be mitigated by applying S-containing fertilisers. Here, there was no increase in DM yield due to MgSO4. Given the application of 7.5% SO3with NPK fertiliser and grass S concentration at the zero MgSO4 application rate was >2200 mg kg−1 DM (Suttle 2010), it seems unlikely that plants were affected by S deficiency. The application of MgSO4 to pastures can help to raise the sulphur:nitrogen (N) ratio in lush grasses with large N in spring during lambing season when animal requirement for S increases (Suttle 2010). Similarly, agronomic biofortification of forage with Mg-fertiliser can help the plants to readily take up Mg by raising the concentration of Mg2+ in the soil solution, curbing competition from other antagonistic ions such as K+ and NH4−, and dampening soil acidification effect on Mg2+ availability due to frequent application of inorganic or organic N-fertiliser to pastures (Bolan et al. 2005; Mulder 1956; Voison 1963). It will be important to quantify the wider effects of using fertilisers to improve grass nutritional quality in ruminant grazing systems. For example, it would be interesting to explore if dolomitic lime (with large concentrations of Mg) were to be utilised can increase grass Ca and Mg, and reduce the FTI and help to manage pasture soil pH in those areas where this is sub-optimal.
Conclusions
This study has shown that biofortification of grass with Mg through breeding and agronomy can improve the forage Mg concentration in Italian ryegrasses for grazing ruminants, even in rapid-growth spring grass conditions when hypomagnesaemia is most prevalent. Response to agronomic biofortification varied with cultivar, Mg-fertiliser rate, site and weather. The Mg concentration in the grass biomass of the large Mg-accumulating cv. Bb2067 was greater while the FTI was smaller than the other three cultivars, at both field experimental sites. Cultivar Bb2067 consistently contained an average of >2000 mg kg−1 DM Mg at all Mg-fertiliser rates indicating its potential to reduce incidence of hypomagnesaemic tetany in grazing ruminants. Given, the slight DM yield penalty for growing cv. Bb2067 compared to cv. Alamo, transfer of the Mg-accumulating traits to the high DM yielder can be considered. The cost:benefit of these approaches, farmers’ adoption, and the impact of Mg-fortified Italian ryegrasses on cattle and sheep grazing on such grasses requires further investigation.
Abbreviations
- AHDB:
-
Agriculture and Horticulture Development Board
- CE:
-
Controlled Environment
- DEFRA:
-
Department for Environment Food & Rural Affairs
- DM:
-
Dry Matter
- FTI:
-
Forage Tetany Index
- ICP-MS:
-
Inductively Coupled Plasma Mass Spectrometry
- MS:
-
Microsoft
- p.a.:
-
Per annum
- rpm:
-
Revolutions per minute
- SD:
-
Standard Deviation
- SE:
-
Standard Error of the mean
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Acknowledgements
This work was supported by the Biotechnology and Biological Sciences Research Council [grant numbers BB/N004280/1 (ELA), BB/N004302/1 (MRB), BB/N004272/1 (AL)]; and the Natural Environment Research Council, through the jointly funded initiative Sustainable Agriculture Research and Innovation Club (SARIC). The project is entitled Magnesium Network (MAG-NET): Integrating Soil-Crop-Animal Pathways to Improve Ruminant Health.
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Kumssa, D.B., Lovatt, J.A., Graham, N.S. et al. Magnesium biofortification of Italian ryegrass (Lolium multiflorum L.) via agronomy and breeding as a potential way to reduce grass tetany in grazing ruminants. Plant Soil 457, 25–41 (2020). https://doi.org/10.1007/s11104-019-04337-x
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DOI: https://doi.org/10.1007/s11104-019-04337-x