Abstract
Two field trials undertaken in 1999 and 2003 investigated the influence of a range of sugars applied as a root drench at 25, 50, and 70 g/L (3.4, 6.8, and 10.3 oz/gal) of water on root and shoot growth, chlorophyll fluorescence, photosynthetic rates, and leaf carotenoid and chlorophyll concentrations of birch (Betula pendula Roth.). Irrespective of concentration and year, the sugars galactose and rhamnose had no significant effects on tree growth or leaf photosynthetic properties. Application of the sugar maltose increased shoot and root dry weight in the 1999 trial but had no effect in the 2003 trial. Sucrose, fructose, and glucose increased shoot and root dry weight in both 1999 and 2003 trials; however, growth responses were influenced by the concentration of sugar applied. In many cases, sugar application increased the number of new roots formed by week 6 but had no significant effects on the length of existing roots or shoot growth. By week 24, increases in both root and shoot growth were recorded. Sugar feeding at 25 g/L (3.4 oz/gal) of water had no significant effect on leaf chlorophyll fluorescence, photosynthetic rates, or carotenoid and chlorophyll concentrations; however, sugar feeding at 50 and 75 g/L (6.8 and 10.3 oz/gal) of water reduced these values by week 6. At the cessation of the experiment, maximal increase in root and shoot growth was associated with a root drench of sucrose at a concentration of 70 g/L (10.3 oz/gal) of water in both 1999 and 2003 trials. Lower mortality rates recorded in sugar-treated trees indicate applications of sugars would aid in the survival of young birch trees following transplanting.
- Carbohydrates
- resource allocation
- gene expression
- transplant shock
- chlorophyll fluorescence
- photosynthesis
- chlorophyll
- carotenoid
- plant vitality
A major determinant of the performance of a field-grown, transplanted tree is the root:shoot ratio. The transplanting process reduces the root system, which is not paralleled by a reduction in the shoot system. This results in severe water stress because the root system is now of insufficient size to support the tree crown (Haase and Rose 1993). Even when accepted nursery practices are followed, less than 5% of the actual absorbing root system may be moved with the tree (Watson and Himelick 1982). This extreme state of imbalance between the root system and the crown results in an extended period of stress often described as “transplant shock.” Consequently, high mortality rates (30% to 50%) are common the first year after planting, with “transplant shock” identified as a major criterion for failure (Johnston and Rushton 1999). In the United Kingdom, where approximately £300 (US$450) million is spent annually on tree plantings, even a 5% loss rate results in high financial loss.
Although a number of factors have been associated with transplant shock, it is now widely believed that survival of newly planted trees is largely dependent on rapid extension of roots that absorb water to replenish transpirational water loss and thus reduce water stress (Gilbertson and Bradshaw 1990; Watson and Himelick 1997). Ideally a cheap, nontoxic, and environmentally friendly compound that can be applied to badly damaged or severely pruned root systems as a dip, soil amendment, and/or foliar spray that increases root vigor (i.e., new root regeneration and elongation of existing roots to rapidly restore the root:shoot ratio) is required.
Until recently, the control of plant growth and development was believed to be coordinated by a range of plant growth regulators, such as auxins that stimulate root growth and cytokinins that stimulate vegetative growth (Percival and Gerritsen 1998). Recent evidence has, however, shown that in plants, sugars such as sucrose, glucose, and fructose function not only as substrates for growth but affect sugar-sensing systems that initiate changes in gene expression and subsequent plant growth (Koch 1996). Sugar depletion, for example, upregulates genes for photosynthesis, carbon remobilization, and export, resulting in vegetative or shoot growth. In contrast, incubation of root systems in sugar solutions (i.e., sucrose or glucose) leads to the repression of photosynthetic genes, decreased rates of net photosynthesis, and carbon remobilization in favor of enhanced root development (Koch 1996; Martin et al. 1997). Further, supplementing wheat root systems with sugars (i.e., sucrose, glucose, or fructose) significantly increases lateral root branching and root formation compared with controls (Bingham and Stevenson 1993; Bingham et al. 1997, 1998). This raises the possibility that transplant shock may be reduced by treating transplants during or immediately after with sugars.
Objectives of this investigation were to (1) evaluate the influence a factorial combination of six different sugars (galactose, rhamnose, sucrose, glucose, fructose, and maltose) and three concentrations (25, 50, and 70 g/L [3.4, 6.8, and 10.3 oz/gal] of water) on root and shoot growth, chlorophyll fluorescence, photosynthesis, and leaf chlorophyll and carotenoid concentrations of birch (Betula pendula) following transplanting.
MATERIALS AND METHODS
Plant Material and Experimental Design
Four-year-old, bare-root birch (Betula pendula Roth.), a transplant-sensitive species (Watson and Himelick 1997), were obtained from a commercial supplier in early January and stored at 6°C (42.8°F) in a refrigerated cold store prior to planting. The physical characteristics of 20 trees selected at random from the 1999 and 2003 trials were destructively analyzed to provide an estimation of stock uniformity for each trial were as follows:
1999 Trial
height—91.3 ± 3.7 cm (36.5 ± 1.5 in.)
girth—2.9 ± 0.11 cm (1.2 ± 0.04 in.)
height:girth ratio—31.5 ± 1.01
shoot dry weigh—19.9 ± 0.99 g (0.7 ± 0.04 oz)
root dry weight—29.3 ± 1.32 g (1.05 ± 0.05 oz)
shoot:root ratio—0.68 ± 0.02
root area—629 ± 40.93 cm2 (100.6 ± 2.6 in2)
2003 Trial
height—17.5 ± 4.76 cm (47 ± 1.9 in)
girth—3.7 ± 0.15 cm (1.48 ± 0.06 in)
height:girth ratio—31.8 ± 1.94
shoot dry weight—26.3 ± 1.28 g (0.94 ± 0.05 oz)
root dry weight—38.9 ± 1.70 g (1.39 ± 0.06 oz)
shoot:root ratio—0.67 ± 0.02
root area—786 ± 55.7 cm2 (125.8 ± 8.9 in2).
Stem diameter was quantified using Mantax blue precision calipers (Haglöf Sweden AB, Langsele, Sweden) at one-third of the height of the stem and girth calculated using the equation C = ρD, where C = circumference (girth), ρ = 3.14, and D = diameter. Root areas were quantified using a Delta-T area meter. Leaf, shoot, and root dry weight were recorded after oven drying at 85°C (185°F) for 48 h.
In both 1999 and 2003, the trials were laid out in a randomized complete block design. The block was planned in a square formation to minimize effects of any gradients in soil conditions. Seven treatments (six sugars plus a water-only control), three concentrations, five individual replications per treatment, and two sampling dates (6 × 3 × 5 × 2 = 180 plus 10 controls = 190 trees per trial) were randomized within the block. The same plot was used for both the 1999 and 2003 trials. Trees were planted by hand at the University of Reading, Shinfield Experimental Station, Reading, UK, at 2 m (6.6 ft) square spacing on 9 February 1999 and 13 February 2003. Root barriers (RootControl, Green-Tech, Nun Monkton, York) to a depth of 60 cm (24 in.) were installed around each tree in a square pattern at a distance of 1 m (3.3 ft) from the tree to eliminate cross contamination of treatments.
The soil was a sandy clay loam containing 4% to 6% organic matter with a pH of 6.2. Weeds were controlled chemically using glyphosate (Roundup) prior to planting, and by hand during the trial. Just prior to planting, all trees had 90% of their root area removed to achieve a root surface area of approximately 60 to 62 cm2 (9.6 to 9.9 in2) to simulate field harvesting practices.
Two weeks after budbreak (a stage when 80% to 100% of foliage has emerged), which, in this investigation occurred on 3 May 1999 and 28 April 2003, a factorial combination of root drenches of six sugars (galactose, rhamnose, sucrose, glucose, fructose, and maltose) at three concentrations (25, 50, and 70 g/L [3.4, 6.8, and 10.3 oz/gal] of water) were applied.
Each tree received weekly for 4 weeks 1.5 L (0.4 gal) of sugar solution applied using a watering can. The spout was lightly rested against the main stem at a height of 30 cm (12 in.), and the sugar solution was allowed to trickle slowly down the main stem. Watering with equal volumes and frequency with water served as the control. Plants received no irrigation or fertilization during the growing season.
Chlorophyll Fluorescence
Chlorophyll fluorescence was measured at weeks 6 (14 June 1999, 9 June 2003) and 24 (18 October 1999, 13 October 2003) after budbreak. Leaves were adapted to darkness for 30 min by attaching light-exclusion clips to the leaf surface. Chlorophyll fluorescence was measured using a portable fluorescence spectrometer (Hansatech Instruments Ltd., King’s Lynn, UK). Six leaves per tree were selected for measurements (two from the top of the crown, two in the center, and two at the base), and each leaf was tagged to ensure that assessments were taken from the same leaf throughout the entire experiment. Measurements were recorded up to 1 s. The fluorescence responses were induced by a red (peak at 650 nm) light of 600 W/m2 intensity provided by an array of six light-emitting diodes (Shuang and Xu 1999).
Fluorescence values recorded include Fv/Fm as a measure of the photochemical efficiency of photosystem II that is widely used in field studies as an early diagnostic measure of plant stress caused by adverse environmental conditions (Meinander et al. 1996).
Photosynthetic CO2 Fixation
The light-induced CO2 fixation (Pn) was measured in pre-darkened (20 min), fully expanded leaves near the top of the canopy (generally about the fourth leaf from the apex) using an infrared gas analyzer (LCA-2 ADC). The irradiance on the leaves was 700 to 800 μmol/m2 photosynthetically active radiation saturating with respect to Pn; the velocity of the airflow was 1 mL/s/cm2 leaf area. Calculation of the photosynthetic rates was carried out according to von Caemmerer and Farquhar (1981). Readings were taken at weeks 6 and 24. Two leaves per tree were selected for measurements. Leaves were tagged to ensure that assessments were taken from the same leaf throughout the experiment.
Leaf Chlorophyll and Carotenoid Analysis
Chlorophyll and carotenoids were extracted from three leaf samples per tree at weeks 6 and 24 after transplanting by suspending 1 g (0.04 oz) of fresh tissue in 5 mL (0.2 oz) of 80% v/v aqueous acetone. After centrifugation in closed vials, an aliquot of the supernatant was transferred to a 1 cm (0.4 in.) path glass cuvette. Chlorophylls a and b and total carotenoid concentration were calculated according to the equations of Lichtenthaler (1987) following measurement of absorbance at 663, 645, and 480 nm in a spectrophotometer (PU8800 Pye Unicam, Portsmouth, UK).
Plant Dry Weights and Leaf Area
At weeks 6 and 24 after budbreak, five trees per treatment were destructively harvested and leaf, shoot, and root dry weight recorded after oven drying at 85°C (185°F) for 48 h. Girth increments were quantified using Mantax blue precision calipers (Haglöf Sweden AB, Langsele, Sweden) from measurements taken 7.5 cm (3 in.) above the substrate surface. In all cases, root systems were excavated gently by hand and using a spade. Soil was removed by washing with water through a 4 mm (0.16 in.) screen. Root growth potential (number of new white roots formed >1 cm [0.4 in]) and root length (the straight-line distance from the trunk to the furthest root tip) were measured.
Statistical Analysis
Effects of sugars on growth, chlorophyll fluorescence, photosynthetic rates, chlorophyll and carotenoid concentrations, and significant interactions between sugar and concentration were determined by two- and one-way analyses of variance (ANOVA) following checks for normality and equal variance distributions. Differences between treatment means were separated by the least significance difference (LSD) at the 95% confidence level (P > 0.05) using the Genstat V program.
RESULTS
There was no significant interaction between sugar type and concentration for any parameter in either the 1999 or 2003 trials (Table 1*). Sugar concentration affected only leaf dry weight in 2003. Sugar type affected chlorophyll and carotenoid content and Fv/Fm ratio in 1999 and root dry weight and Fv/Fm ratio in 2003.
Pooled P values from weeks 6 and 24 for growth, leaf chlorophyll and carotenoid concentration, chlorophyll fluorescence (Fv/Fm), and photosynthetic rates (Pn) following sugar treatments. P < 0.05 are considered significant.
No significant effects on growth or leaf photosynthetic properties were recorded following application of galactose, rhamnose, and maltose (2003 trial only), irrespective of concentration applied. For reasons of clarity, nonsignificant data are not shown.
Chlorophyll Fluorescence, Photosynthesis, and Chlorophyll and Carotenoid Concentrations and Mortality
No significant effects on Fv/Fm, Pn, or leaf chlorophyll and carotenoid concentrations were recorded following application of any of the sugars tested at a concentration of 25 g/L (3.4 oz/gal), with one exception: significantly reduced leaf carotenoid concentrations were found in trees supplemented with fructose at week 6 in the 2003 trial. At week 6 in both the 1999 and 2003 trials, leaf chlorophyll and carotenoid concentrations and Pn and Fv/Fm were significantly lower (P < 0.05) in trees supplemented with sucrose, glucose, fructose, and maltose (1999 trial) at concentrations of 50 and 70 g/L (6.8 and 10.3 oz/gal) compared with control values (Tables 2 and 3). Exceptions to this include, in the 1999 trial, fructose (leaf chlorophyll, carotenoid concentrations and Fv/Fm values) and maltose (Pn) applied at 50 g/L (6.8 oz/gal), where no significant effects were recorded.
Trial 1, 1999. The influence of different sugars and concentrations applied as a root drench on leaf chlorophyll and carotenoid concentrations, photosynthetic rates, and chlorophyll fluorescence of transplanted birch (Betula pendula Roth.).
Trial 2, 2003. The influence of different sugars and concentrations applied as a root drench on leaf chlorophyll and carotenoid concentrations, photosynthetic rates, and chlorophyll fluorescence of transplanted birch (Betula pendula Roth.).
In the 2003 trial, no significant effects on Fv/Fm were found following application of 50 g/L (6.8 oz/gal) of sucrose, fructose, and glucose; on Fv/Fm following application of 70 g/L (10.3 oz/gal) of glucose; on leaf chlorophyll concentration following application of 50 g/L (6.8 oz/gal) of fructose; or on Pn following application of 70 g/L (10.3 oz/gal) of glucose.
In both 1999 and 2003 trials, no significant effects on Fv/Fm or Pn, or on leaf chlorophyll and carotenoid concentrations were recorded at week 24. Results indicate a reduction in leaf photosynthetic properties by week 6 following application of sucrose, glucose, and fructose at 50 and 70 g/L (6.8 and 10.3 oz/gal). By week 24, a rising chlorophyll and carotenoid content and subsequent increase in Fv/Fm were mirrored by increased leaf photosynthetic rates (Pn). No significant effects on the ratio of chlorophyll a:b (65:35) compared to controls were recorded (data not shown).
Plant Growth
Applications of sucrose, glucose, and fructose induced similar alterations in growth of birch in both 1999 and 2003 experiments (Tables 4 and 5). Irrespective of sugar type and concentration, no significant effects on root length, girth, or leaf and shoot dry weight were recorded at week 6. However, a significant increase (P < 0.05) in root growth potential and root dry weight was recorded following applications of sucrose, glucose, fructose, and maltose (1999 trial) at all three concentrations, with the following exceptions. In the 1999 trial, sucrose and glucose at 25 g/L (3.4 oz/gal) (root dry weight); glucose at 50 g/L (6.8 oz/gal) (root growth potential); and maltose at 25 g/L (3.4 oz/gal) (root growth potential, root dry weight) and at 70 g/L (10.3 oz/gal) (root dry weight), where no significant effects occurred. In the 2003 trial, sucrose and fructose at 25 g/L (3.4 oz/gal) (root growth potential); fructose at 70 g/L (10.3 oz/gal) (root growth potential); sucrose at 25 g/L (3.4 oz/gal); and glucose at 70 g/L (10.3 oz/gal) (root dry weight), where no significant effects were recorded.
Trial 1, 1999. The influence of different sugars and concentrations applied as a root drench on growth and mortality of transplanted birch (Betula pendula Roth.).
Trial 2 2003. The influence of different sugars and concentrations applied as a root drench on growth and mortality of transplanted birch (Betulapendula Roth.).
By week 24 (1999 trial), a significant increase (P < 0.05) in growth was recorded, with the exceptions of glucose and fructose at 25 g/L (3.4 oz/gal) (root dry weight); glucose at 50 g/L (6.8 oz/gal) (root length); sucrose, fructose, glucose, and maltose at 25 g/L (3.4 oz/gal) (root growth potential); sucrose, fructose, and glucose at 25 g/L (3.4 oz/gal); maltose at 25, 50, and 70 g/L (3.4, 6.8, and 10.3 oz/gal) (girth, shoot dry weight); and fructose and glucose at 25 g/L (3.4 oz/gal) (leaf dry weight), where values were not significantly higher than controls.
At week 24 in the 2003 trial, a significant increase (P < 0.05) in growth was recorded, with the exceptions of sucrose and fructose at 25 and 70 g/L (3.4 and 10.3 oz/gal) (root dry weight); sucrose, fructose, and glucose at 50 g/L (6.8 oz/gal), glucose at 25 g/L (3.4 oz/gal), and fructose at 70 g/L (10.3 oz) (root length); sucrose and fructose at 25 and 70 g/L (3.4 and 10.3 oz/gal), and glucose at 70 g/L (10.3 oz/gal) (root growth potential); sucrose and glucose at 25 g/L (3.4 oz/gal), and fructose and glucose at 50 and 70 g/L (6.8 and 10.3 oz/gal) (girth); sucrose, fructose, and glucose at 25 g/L (3.4 oz/gal), glucose at 50 and 70 g/L (6.8 and 10.3 oz/gal) (shoot dry weight); and sucrose, fructose, and glucose at 25 g/L (3.4 oz/gal) (leaf dry weight), where values were higher, but not significantly more so than controls.
In both 1999 and 2003 trials, the highest increases in girth and in root, shoot, and leaf dry weight at the cessation of the experiment were recorded following applications of sucrose as a root drench at a concentration of 70 g/L (10.3 oz/gal). Application of the sugars tested in this investigation to root systems of birch following severe root pruning reduced mortality from 15% (controls) to zero in the 1999 trial and 5% to zero in the 2003 trial.
DISCUSSION
Results of this investigation show that application of the sugars sucrose, fructose, and glucose as a root drench improved root growth of young, newly transplanted birch following severe root pruning. Likewise, reduced mortality and increased shoot and leaf dry weight and girth in treated trees recorded at the cessation of both the 1999 and 2003 field trials indicate applications of sugars would aid in the survival of young birch trees following transplanting. Further research is required to determine whether applying sugars to root systems of other tree species would induce similar beneficial responses.
Improved root vigor, as assessed by higher root growth potential values at week 6, in trees supplemented with sucrose, fructose, and glucose in both trials and maltose in the 1999 trial and reduced photosynthetic rates recorded at the same time indicate that these sugars were used as direct substrates for root growth (Lindqvist and Asp 2002). Sucrose is the major photoassimilate transported from source to sink tissues in birch that is hydrolyzed into glucose and fructose to provide energy via respiration, while maltose is the predominant sugar in barley (Salisbury and Ross; 1985; Lindqvist and Asp 2002). Rapid uptake, transfer, and breakdown mechanisms that naturally exist within plants for utilizing these four sugars may account for the stimulatory root growth responses recorded by week 6. Sugars such as galactose and rhamnose are not directly used as substrates for growth but have been shown to play important roles in plant defense systems (Percival et al. 1998). This may account for their failure to induce any alterations in growth and leaf photosynthetic properties recorded in this investigation.
No significant effects on growth of birch were recorded following application of the sugar maltose in the 2003 trial. Contrary to this finding, significant increases in growth were recorded in the 1999 trial. Such a response is disadvantageous to professionals involved in urban tree care where products with repeatability and reliability are required.
Although not explored, alterations in gene expression may explain the growth and leaf photosynthetic responses recorded at the whole plant level. Reduced photosynthetic rates, chlorophyll fluorescence, and leaf chlorophyll and carotenoid concentrations, coupled with increased root growth potential and root dry weight recorded at week 6, would indicate repression of photosynthetic genes and upregulation of genes involved in root vigor in the short term (Koch 1996; Martin et al. 1997). By week 24, the genetic balance is restored as reflected by no significant difference in leaf chlorophyll fluorescence, photosynthetic rates, and leaf chlorophyll and carotenoid content between treated and control trees. Alternately, biologically active organic molecules such as sugars, sea weed extracts, and betaines, when applied to soils, have been shown to induce changes in the naturally occurring soil rhizosphere populations—resulting in alterations to plant nutrient uptake patterns (Pattison 1994; Walsh 1997). Such changes may also have contributed to improved growth and reduced mortality recorded in this investigation (Blunden and Woods 1969; Finnie and van Staden 1985).
Rapid root regeneration is associated with successful transplant establishment. Significant increases in the root growth potential recorded by week 6 indicate short-term stimulatory effects of sugars on root regeneration. Consequently, the higher root growth potential values associated with sugar applied to birch may reduce drought-related transplant shock symptoms permitting increased shoot and leaf growth recorded at 24. Work elsewhere has shown that exogenously applied auxins (a plant hormone involved in root metabolism) promote root initiation and increase numbers and length of existing roots of a range of plants by 6- to 18-fold in some instances (Looney and McIntosh 1968; Struve and Moser 1984; Struve 1990); however, a delay exists between each process, with each requiring a different optimum auxin concentration. The concentration for growth tends to be lower than that for initiation (Kelly and Moser 1983). Results of this investigation indicated a sugar concentration of at least 25 g/L (3.4 oz/gal) is required before significant effects on root formation occur. By week 24, significant effects on root length were recorded. Consequently, a sugar concentration of at least 25 g/L (3.4 oz/gal) is initially optimal for root formation such that, with time, dilution by watering or degradation in the soil possibly resulted in a concentration inducing elongation of existing roots.
In conclusion, applications of sugars improved root and shoot growth and reduced transplant losses in birch; however, further studies are required to understand the mechanistic basis by which this occurred and to determine whether sugars can provide useful soil amendments for landscape- sized trees greater than 50 mm (2 in.) diameter. Likewise, the practicality of applying sugars at weekly intervals for the first month commencing budbreak needs to be addressed. This is an area worthy of further research given the fact that sugars are water soluble, nontoxic, environmentally safe, and inexpensive to purchase.
Acknowledgments
The author is grateful for funding from the TREE Fund (Hyland Johns grant program).
Footnotes
↵* Tables for this article appear on pp. 73–77.
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