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Article

Responses of Parameters for Electrical Impedance Spectroscopy and Pressure–Volume Curves to Drought Stress in Pinus bungeana Seedlings

1
College of Horticulture, Hebei Agricultural University, 071001 Baoding, China
2
Natural Resources Institute Finland (Luke), Management and Production of Renewable Resources, P.O. Box 68, FI-80101 Joensuu, Finland
3
Ruralia Institute and Helsinki Institute of Sustainability Science, University of Helsinki, Lonnrotinkatu 7, FI-50100 Mikkeli, Finland
*
Author to whom correspondence should be addressed.
Forests 2020, 11(3), 359; https://doi.org/10.3390/f11030359
Submission received: 11 February 2020 / Revised: 15 March 2020 / Accepted: 19 March 2020 / Published: 23 March 2020
(This article belongs to the Special Issue Tree Responses to Drought)

Abstract

:
Background and Objectives: Drought occurs more frequently in Northern China with the advent of climate change, which might increase the mortality of tree seedlings after afforestation due to hydraulic failure. Therefore, investigating water relations helps us understand the drought tolerance of tree seedlings. Electrical impedance spectroscopy (EIS) is widely used to assess the responses of plant tissues to stress factors and may potentially reveal the water relations of cells. The aim of this study is to reveal the relationships between EIS and water related parameters, produced by pressure–volume (PV) curves in lacebark pine (Pinus bungeana Zucc.) seedlings reacting to drought stress. Materials and Methods: Four-year-old pot seedlings were divided into three parts (0, 5, and 10 days of drought) before planting, the treated seedlings were then replanted, and finally exposed to post-planting drought treatments with the following soil relative water contents: (i) adequate irrigation (75%–80%), (ii) light drought (55%–60%), (iii) moderate drought (35%–40%), and (iv), severe drought (15%–20%). During the post-planting growth phase, the EIS parameters of needles and shoots, and the parameters of PV curves, were measured coincidently; thus, the correlations between them could be obtained. Results: The extracellular resistance (re) of needles and shoots were substantially reduced after four weeks of severe post-planting drought stress. Meanwhile, the osmotic potential at the turgor-loss point (ψtlp) and the saturation water osmotic potential (ψsat) of shoots decreased after drought stress, indicating an osmotic adjustment in acclimating to drought. The highest correlations were found between the intracellular resistance (ri) of the shoots and ψtlp and ψsat. Conclusions: EIS parameters can be used as a measure of drought tolerance. The change in intracellular resistance is related to the osmotic potential of the cell and cell wall elasticity. Extracellular resistance is a parameter that shows cell membrane damage in response to drought stress in lacebark pine seedlings.

1. Introduction

Drought conditions in the past two decades occurred more frequently in most regions in Northern China [1]. This situation will continue with the climate change. Drought conditions increase the mortality of trees and may affect the forest carbon fixation and ecosystem services [2]. In addition to mature forests, large-scale afforestation has been done in China in order to promote land greening and to improve the ecological environment. Lacebark pine (Pinus bungeana Zucc.) is one of the main forest and landscape tree species in Northern China and three to four year-old container seedlings are widely used for reforestation purposes. The seedlings may be easily exposed to drought soon after planting and to pre-planting drought during long-distance transportation and by delayed planting in stands, therefore increasing their mortality after afforestation as a result of hydraulic failure [3]. Investigating water status after drought stress may help us to understand the drought tolerance of tree seedlings.
Pressure–volume (PV) curves are one of the basic indices characterizing the plant–water status. It is, therefore, commonly used in plant ecophysiological studies [4,5]. Since the first application of the curves [6], this technique has been widely used to examine the elasticity of cell walls [7,8] and the relationship between plant performance and its internal water status [9,10,11].
During the process of tissues losing water, from being saturated to wilting, the water of cell vacuole is continuously released, and the cells shrink due to water loss. As the shrinkage level of the cell wall and cytoplasm is not the same, plasmolysis occurs when water loses reach a certain degree, and at that moment, the corresponding tissue potential is the initial plasmolysis osmotic potential at the turgor-loss point (ψtlp). The initial osmotic potential at the turgor-loss point (ψtlp) is indicative of the wilting point and the plant cannot absorb sufficient water below this point. Therefore, a lower ψtlp value indicates a stronger capacity to maintain turgor [12,13]. Likewise, a low value for the saturation–water osmotic potential (ψsat) indicates a high concentration of cell sap and a greater ability for plant cells to maintain maximum turgor. It is well known that high turgor is important in maintaining metabolic processes and growth [14]. A high ratio of bound-water content (Va) to free-water content (Vp) suggests a more favorable water uptake and retention by a tree [15]. Cell wall elasticity is also considered to be an important physiological trait to depict the acclimation of plants to water stress [16]. A large value for the cell elastic modulus (ε) is related to rigid cell walls with less elasticity.
Electrical impedance spectroscopy (EIS) is related to the electrolyte balance in cells. In EIS, a plant sample is set in an electrical field with a small amplitude of the alternating current and resistance (real); the reactance (imaginary) part of the impedance is measured at different frequencies [17,18]. The selected equivalent circuit is decided according to the shape of the spectrum and the a priori information concerning the internal composition of the specimen. At low frequencies, the current passes through the apoplast, whereas the high frequency current may pass through the cell membranes. Then, the apoplast and symplast form a parallel circuitry, allowing for the symplastic resistance to be calculated [19]. If the cell membranes are damaged, e.g., by different stressors, then symplastic ions leak into the apoplastic space, leading to decreased extracellular resistance [20,21]. Intracellular resistance relates to the concentration of electrolytes and their mobilities in cells [19].
EIS has been widely used to reveal the responses of plant tissues to environmental stress, such as cold acclimation [22,23,24], freeze-thaw injury [20], heat [21], salt [25], elevated ozone [19], and flooding [26]. It has also been applied to evaluate growth of intact root system of herbaceous plants [27], tree roots [28,29] and the mycorrhiza colonization [30], as well as the frost damages of roots in small tree seedlings [31]. Recently, single-frequency impedance measurement was used to study plant response to alkaline stress [32]. Although the application of EIS in studying drought stress was not addressed before, the following studies showed that water content of organs was associated with the magnitude of EIS parameters. The moisture content had a strong effect on several EIS parameters in both viable and non-viable snap bean seeds—occurring in such a way that the increase in moisture content decreased the resistance parameters [33]. Similarly, the moisture content affected the EIS parameters in wood [34]. In white spruce (Picea glauca), the impedance of the stem was linearly related to the osmotic potential at full turgor during seasonal dormancy induction [35]. Considering the advantages of the EIS method, i.e., being fast and non-destructive, it will prove to be valuable in studies of plant–water relations.
In the present study, PV–curves and the EIS parameters of lacebark pine seedling needles and shoots were measured, coincidentally, after exposing the seedlings to drought stress. We hypothesize that the water-related PV and EIS–parameters are correlated, and therefore, either could be exploited to characterize the degree of drought tolerance in lacebark pine seedlings.

2. Materials and Methods

2.1. Plant Materials and Drought Treatments

Four-year-old lacebark pine seedlings (stem diameter 0.48 ± 0.1 cm and height 21.0 ± 3.2 cm) (mean ± SE), originating from Shanxi Province (37°05’ N, 111°45’ E), were cultivated in the Beijing Ming Tombs Nursery (40°13’ N, 116°13’ E, 400 m above sea level). In early spring, a total of 1000 dormant bare-root seedlings were excavated from the nursery bed, dipped in mud, and transported in plastic bags to the Garden of the Hebei Agricultural University (38°50’ N, 115°26’ E, 22 m a. s. l.). The seedlings were immediately planted in mineral soil consisting of a mix of garden soil (top 20 cm) and fine sand (2:1) in soft and black plastic nutrition pots (volume 4.6 L, diameter × height: 18 cm × 18 cm).
The total nitrogen content of the soil was 360 mg kg−1, the rapidly available phosphorus content was 12.1 mg kg−1, the rapidly available potassium content was 128 mg kg−1, and the organic matter content was 15.12 g kg−1. The seedlings were placed in a plastic shed and were watered twice a week. The field moisture capacity of the soil in the pots was 22.6%, and the soil bulk density was 1.24 g cm−3. Soil relative water content (SRWC) was used to indicate water deficiency during drought stress. SRWC was calculated according to the measured volumetric soil water content (TDR100, Spectrum Technologies, Inc., Plainfield, USA) as:
SRWC = [(soil volumetric water content/soil bulk density)/22.6] × 100
The seedlings were watered every day to keep SRWC at the target level.
In the early growth phase, in the beginning of May, the seedlings were divided into three groups for drought stress treatments: (i) adequate irrigation (SRWC 75%–80%) (B1); (ii) light drought (SRWC 55%–60%) (B2), which was reached in 5 days of drought, and iii) moderate drought (SRWC 35%–40%) (B3), which was reached in 10 days of drought. These were called the pre-planting drought treatments and they finished after B3 reached an SRWC level of 35%–40%.
At the end of the pre-planting drought treatments, 720 of the seedlings (240 seedlings of each pre-planting treatment) were transplanted in plastic buckets with a small drainage hole at the bottom (volume 12.3 L, diameter × height: 25 cm × 25 cm)—one plant was transported per bucket. Then, the seedlings of each pre-planting treatment were divided in four post-planting drought treatments in a split-plot design, with 60 seedlings in each treatment with the following SRWC: (i) adequate irrigation (75%–80%) (A1), (ii) light drought (55%–60%) (A2), (iii) moderate drought (35%–40%) (A3), and (iv) severe drought (15%–20%) (A4).
Once in the plastic shed, all the seedlings were divided into four replicate blocks. There were four plots for each post-planting treatment in each block. Each plot, with post-planting treatments (i.e., A1, A2, A3, and A4), was divided into three subplots, where the seedlings with pre-planting treatments (B1, B2, and B3) were placed randomly. Altogether, 12 treatment combinations were formed, i.e., A1B1, A1B2, A1B3, A2B1, A2B2, A2B3, A3B1, A3B2, A3B3, A4B1, A4B2, and A4B3. There were 15 seedlings in each of the four replicates of the treatments, i.e., a total of 60 seedlings in each treatment. The post-planting drought treatments were applied for 5 weeks after transplanting.

2.2. Electrical Impedance Spectroscopy

During the post-planting stress period, starting two weeks after transplanting, the EIS of needles and shoots were measured five times at one-week intervals. Eight seedlings per treatment (two seedlings of each replicate block) were randomly sampled at each harvest time and taken to the lab. Two current-year needles were sampled for each seedling, and a 15 mm-long sample was cut from the middle of the needle for EIS measurement at a constant temperature. In addition, two 15 mm-long shoot portions were cut from the middle of the current-year shoot of each sample seedling for EIS. The sample was set between two Ag/AgCl electrodes (RC1; WPI Ltd., Sarasota, FL, USA) connected to an impedance analyzer (HP4284A LCR meter; Agilent, Palo Alto, CA, USA). Electrode gel (Sigma gel, Parker Laboratories, Inc. Fairfield, New Jersey, USA) was set between the cut surface of the sample and the electrode to minimize polarization impedance [20,36]. The real and imaginary part of the impedance was measured at 42 frequencies between 80 Hz and 1 MHz. Needle thicknesses and shoot diameters were measured using a thickness gauge (Mitutoyo NO. 7331, Kawasaki, Kanagawa, Japan).
According to the impedance spectra, an equivalent circuit model was determined for the samples. Model–A (Equation (2)) was used for the needles [24,37]:
Zmodel–A = R + [(R0R) × (1 + β)]/[1 + β × (1 + j × ω × τm)0.5]
where R (Ω) is the resistance at high frequencies, R0 (Ω) is the resistance at low frequencies, the coefficient β is a factor controlling the skewness of the spectrum and the impedance locus center depression, and τm (s) is a time constant for the cell membrane. Here, the extracellular resistance (Re) corresponded to R0, whereas intracellular resistance Ri was calculated as R × R0/(R0R). Specific resistances were calculated as:
rx = Aneedle × Rx/l
where rx refers to r, re, and ri (Ωm). As the needle cross-section is fan-shaped, with a 60 ° central angle, we calculated the needle area as Aneedle = πd2/3, where d is the needle thickness and l is the length.
According to the feature of impedance spectrum, two arcs in shoots, and the centers of the circles of the arcs are below the x-axes, distributed circuit element which is composed with two distributed elements in series with a resistor (double–DCE model) (Equation (4)) was applied for the shoots [20]:
Z = R + R1/[1 + (I × τ1 × ω)ψ1] + R2/[1 + (I × τ2 × ω)ψ2]
The model included three resistances (R, R1, and R2, unit Ω), two relaxation times (τ1 and τ2, unit μs) and two distribution coefficients (ψ1 and ψ2) of the relaxation times. The parameters R, R1, and R2 indicate the intersections of the arcs with the x–axis [17,22]. The relaxation times τ1 and τ2 indicate the apices of the circles, and the parameters ψ1 and ψ2 define the depression of the circle centers below the x–axis. Extracellular and intracellular resistance was calculated as Re = R + R1 + R2 and Ri = R × (1 + R/(R1 + R2), respectively. The corresponding specific resistances (Ωm) were calculated, as in Equation (3), with the cross-sectional area calculated as Ashoot = π × d2/4 where d is the shoot diameter [22,23].
The parameters of the Model-A (Equation (2)) and double –DCE (Equation (4)) were estimated by the complex nonlinear least squares (CNLS) curve fitting of LEVM v 8.06 (obtained from J. R. Macdonald, Department of Physics and Astronomy, University of North Carolina, Chapel Hill, NC, USA).

2.3. Pressure–Volume (PV) Curves and Their Parameters

One seedling from each of the 12 post-planting treatments was sampled for PV–curves (i.e., a total of 12 curves) in the fourth week of the post-planting stress. As PV curves show high repeatability [38], no replicate measurement was made for the same seedling and treatment. The PV–curves were measured at room temperature (22 °C), according to the gradual boosting method [9]. Shoots with a relatively uniform top were cut and inserted into a bottle filled with water for 20 h in darkness. The fresh weights (WTotal) of shoots in full saturation were measured. Then, the shoots were placed in a pressure chamber, with 5 mm of the cut end of the shoot protruding out of the pressure chamber through a rubber seal. For sap collection, a 50 mm–long latex tube, filled with absorbent paper, was weighed (W1) and placed against the cut end of the shoot sample. After the lid was tightly secured, the chamber pressure was increased by 0.2 MPa for 10–15 minutes in order to collect the water exuded from the shoot. Then, the pressure was slightly reduced (0.05–0.1 MPa) and the latex collection tube was removed and weighed (W2). The exuded water was calculated as W2 W1 and was transformed to volume (V), and the corresponding applied pressure (P) was recorded. This procedure was repeated until a total of 10–16 PV–pairs were obtained. After the measurement, the shoot was dried at 85 °C and the dry weight was (WDry) measured. The fresh weight of the shoot at each applied pressure (WFresh) was calculated as WTotal–W2. The relative water content (RWC) of the shoot at each pressure level was calculated as: RWC(%) = (WFresh − WDry)/(WTotal − WDry) × 100. The PV-curve was graphed with the accumulated expressed sap (1–RWC) on the x–axis and the 1/ applied pressure (P) on y–axis (Figure 1).
Depending on the applied pressure, each PV–curve had two distinct ranges: a nonlinear and a linear range [39]. The osmotic potential at the turgor-loss point (ψtlp, MPa) for initial plasmolysis was the turning point where the curve changed to a straight line. The corresponding accumulated expressed sap at the turning point was Vtlp. The relative water content of the initial plasmolysis was (RWCtlp,%) = 1−Vtlp.The intersection point of the extension line of the PV curve straight line and the Y–axis was the saturation water osmotic potential (ψsat, MPa). The symplastic water content at full turgor (Vs,%) was obtained from the intersection of the extrapolated line of the PV curve straight line and the x-axis. The apoplastic water content was (Va,%) = 1 − Vs. The free water was (Vp,%) = Vs − Vtlp [9,40]—the ratio of Va and Vp was calculated accordingly. The cell elastic modulus was (ε, unit MPa) = ΔψP/ΔRWC. When the water was extruded from plant tissue, ε changed continuously. Therefore, the maximum tissue bulk modulus of elasticity (εmax) was usually used to compare the elastic properties, and was calculated as: εmax = (ψsat − ψtlp) × (Vs − Vtlp)/Vs.

2.4. Statistical Analyses

A mixed linear model (procedure MIXED in SPSS 15.0.1, SPSS Inc., Chicago, IL, USA) analyzed the effects of the treatments on the EIS parameters. The model used was y = μ + Ai + Bj + timek + Ai × timek + Bj × timek + Ai × Bj + Ai × Bj × timek + εijk, where μ is a constant. In the model, ‘Ai’ represents the drought treatment effect during the post-planting period; i = 1, 2, 3, 4; ‘Bj’ is the drought treatment effect during the pre-planting period; j = 1, 2, 3; timek is the time effect; and k = 1, 2, 3, 4, 5, and εijk refers to the residual term. The factors ‘A’, ‘B’, and ‘time’ were regarded as a fixed term and ε a random term. The significance of the difference between the treatments at different sampling times was tested by contrasts using Bonferroni-corrected significance levels. The normality and homogeneity of the variance of the residuals were checked. The selection of the covariance structure was based on Akaine’s information criteria. Response variables were log transformed to fulfill the assumption of homogeneity in the analyses. The mean value of the seedlings in one block was used in the statistical analyses of the variables. There were four replicate blocks.
Correlation analyses between the PV curve parameters and EIS parameters were conducted based on Pearson’s correlation coefficients. All the data for correlation analysis were taken in the fourth week of the post-planting period.

3. Results

3.1. Electrical Impedance Spectroscopy (EIS) Parameters

Post-planting drought treatments (A1, A2, A3, and A4), pre-planting drought treatments (B1, B2, and B3), and their interactions (A × B), had significant effects on the specific extracellular resistance (re) of stems during the post-planting growing period (Table 1). Pre-planting drought treatments (A1B2, A1B3) caused the reduction in the re of stems, as compared to the A1B1 treatment (p < 0.05 for each) after four weeks of post-planting growth. The re of the stems was significantly lower in the post-planting drought treatments (A2B1, A3B1, and A4B1), as compared to A1B1 seedlings four weeks after the post-planting growth (p < 0.05, p < 0.001, and p < 0.001, respectively). In the seedlings that went through pre-planting drought stress (B2), the re of the stems was almost significantly lower in A4B2 at week four (p = 0.057); however, A2B2 and A3B2 was not lower than A1B2. Additionally, in seedlings that went through pre-planting drought stress (B3), the re of the stems was higher in A2B3 and A4B3 than in A1B3, and was higher than in A2B1, A4B1 seedlings, but was still lower than in A1B1 (Figure 2a).
Post-planting drought treatments (A1, A2, A3, and A4) had significant effects on the re of needles, whereas pre-planting drought (B1, B2, and B3) had no effect—with no differences between A1B1, A1B2, and A1B3 being shown (Figure 2b). The interaction effects between post and pre-planting stress were significant (Table 1). The re of the needles was significantly lower in A3B1 and A4B1 than in A1B1 (p < 0.05, p < 0.001, respectively), in A2B2, A3B2, and A4B2 than in A1B2 (p < 0.01, p < 0.001, p < 0.001, respectively), and in A4B3 than in A1B3 at week four (p < 0.001) (Figure 2b).
Overall, either post-planting drought treatments (A1, A2, A3, and A4) or pre-planting drought treatments (B1, B2, and B3) had no significant effect on the ri of the stems; however, the interaction effects between post and pre-planting stress were significant (Table 1). When comparing the pre-planting drought effects at week four, the ri of the stems was higher in A3B2 than in A3B1 (p < 0.05), and higher in A4B2 and A4B3 than in A4B1 (p < 0.05, p = 0.001). When comparing post-planting drought effects, the ri of the stems was higher in A4B3 than in A1B3, A2B3, and A3B3 (p = 0.001, p < 0.05, p < 0.05, respectively), and was slightly, but not significantly, higher in A3B2 and A4B2 than in A1B2 (Figure 3a).
Post-planting drought treatments (A) had significant effects on the ri of the needles, whereas pre-planting drought (B) only had a slight effect on it. The interaction effects between post and pre-planting treatments were significant (Table 1). When comparing the pre-planting drought impact, the ri of the needles was lower in A3B1 than in A3B3 (p < 0.05), and lower in A4B1 than in A4B3 (p < 0.01). When comparing the post-planting drought impact, the ri of the needles was lower in A3B1 and A4B1 than in A1B1, and the statistically significant differences were found between the A4B1 and A1B1 treatments at week four (p < 0.01). In regard to the seedlings that went through pre-planting drought stress (B2), the ri of the needles was lower in A2B2, A3B2, and A4B2 at week 4 (p < 0.05, p = 0.08, p < 0.01, respectively) than in the A1B2 treatment. There were no significant differences between post-planting drought treatments for the seedlings that went through pre-planting drought stress (B3) (Figure 3b).

3.2. Hydraulic Parameters of Shoots by PV Curves After Four Weeks Post-Planting Growth

Most of the shoots already underwent plasmolysis at a relative water content higher than 90%. The RWCtlp of the shoots was the highest in A1B1 seedlings that were adequately irrigated throughout the experiment. Slight pre-planting drought (A1B2) decreased the value to 88% after four weeks of post-planting growth with adequate irrigation. Slight and moderate post-planting drought stresses (A2B1 and A3B1) decreased the RWCtlp of the shoots. The RWCtlp of the shoots was also lower in the seedlings that went through pre-planting drought and the further slight and moderate post-planting drought (A2B2, A3B2, A2B3, A3B3) than in A1B1 seedlings (Figure 4a).
Compared to A1B1 seedlings that were adequately irrigated throughout the experiment, the ψtlp of the shoots decreased, whether pre-planting drought stress (A1B2, A1B3) or the post-planting drought stress was applied (A2B1, A3B1, and A4B1). The ψtlp of the shoots also decreased in the seedlings that went through pre-planting drought (B2 and B3), and the further post-planting drought (A2B2, A3B2, A4B2, A2B3, A3B3, and A4B3) compared to A1B1. Notably, the seedlings without pre-planting drought stress (B1) had the lowest ψtlp of the shoots after four weeks of slight drought treatment (A2); however, the seedlings with pre-planting drought stress (B2 and B3) had the lowest value after four weeks of severe drought treatment (A4) (Figure 4b).
Similar to the ψtlp of the shoots, the ψsat of the shoots decreased in pre-planting drought treatment (A1B2 and A1B3) and the post-planting drought treatments alone (A2B1, A3B1, and A4B1), as well as in the treatments with seedlings suffering from pre-planting drought treatments (B2, B3) and further post-planting drought treatments (A2B2, A3B2, A4B2, A2B3, A3B3, and A4B3)—as compared to the adequately irrigated seedling treatment (A1B1). The seedlings without pre-planting drought stress (B1) had the lowest ψtlp of the shoots after four weeks of slight drought stress (A2); however, the seedlings with pre-planting drought stress (B2 and B3) had the lowest value after four weeks of severe drought stress (A4) (Figure 4c).
The ratio of bound-water content to free-water content (Va/Vp) of the shoots was lower in the seedlings that suffered from slight pre-planting drought (A1B2), whereas it was higher in the seedlings that suffered from moderate pre-planting drought (A1B3) than in the A1B1 seedlings. The Va/Vp of the shoots was higher in the seedlings that suffered from moderate post-planting drought (A3B1) and severe post-planting drought (A4B3) than in the A1B1 seedlings (Figure 4d).
The modulus of cell elasticity (εmax) markedly increased in the seedlings that went through slight pre-planting drought (A1B2), as compared to A1B1 seedlings. The post-planting drought (A2B1, A3B1, and A4B1) induced an increased εmax, with A2B1 increasing the most, and A4B1 increasing the least. The εmax was also higher in the seedlings that went through pre-planting drought treatment and further post-planting drought (A2B2, A3B2, A4B2, A2B3, A3B3, and A4B3) than in A1B1 seedlings. It is noted that εmax was lower in A2B2, A3B2, and A4B2 than in A1B2 seedlings (Figure 4e).

3.3. Correlation Analysis

Correlations among the EIS parameters and the PV–parameters are shown in Table 2. The ri of the stems correlated negatively and significantly with ψtlp and ψsat in the shoots; however, the re of the stems showed slightly positive relationships with ψtlp and ψsat in the shoots. Moreover, the ri of the stems showed a slightly positive relationship with εmax. The ri and β of the needles correlated negatively with RWCtlp in the shoots. The relaxation time (τ1) of the stems had slightly positive correlations with the Va/Vp of the shoots.

4. Discussion

Moderate and severe post-planting drought stresses (A3 and A4) for four weeks reduced the re of the shoots and needles, especially in the seedlings without pre-planting drought stress (B1). The decrease of re may be attributed to cellular membrane injuries, as previously observed in frost [20] and heat stress [21]. Cell dehydration by drought conditions caused the cytoplast to shrink and break the molecular arrangement of the lipid layers on the membrane; thus, symplastic ions leach into the apoplastic space, and re decreases. The injury of the cellular membrane was proven by the increased electrolyte leakage of the needles and stems from drought stress, as reported earlier [41,42]. Membrane stability index (MSI) of roots reflecting the electrolyte leakage also supported EIS results [32]. Due to its close relationship with the membrane injury by frost stress, re was often used to estimate semi-lethal temperatures after freezing treatments, i.e., cold hardiness of conifer trees [43,44]. It seems that re is also a good parameter to estimate cell damage after drought stress.
The intracellular resistance of stems was increased in the A3 and A4 treatments in the seedlings that experienced pre-planting drought stress (B2 and B3). In the previous study on cold hardiness, the intracellular resistance of the stems of Scots pine increased during cold acclimation, which was suggested to be due to the restriction on the mobility of the ions [22]. Severe post-planting drought stress decreased the water content and increased the soluble sugar content of the stems in lacebark pine seedlings [42], which might increase the cell sap concentration, and restrict the mobility of ions—thus increasing intracellular resistance [22,45]. Severe post-planting drought reduced the ri in the needles of seedlings without pre-planting drought (B1). Similarly, increasing the NaCl concentration in the growth media reduced the ri of leaves in olive trees (Olea europaea L.), which was suggested to be due to the alteration of membrane properties [25].
According to the correlation analysis, the re of the stems had slight positive correlations with the ψtlp and ψsat of the shoots. On the contrary, there were higher negative correlations between the ri of the stems and the ψtlp and ψsat of the shoots. Previous studies showed that electrical resistance was related to the moisture content of the organ [33,34], and ψsat was linearly correlated with the impedance of the stem in white spruce, which accorded with our results [35]. Under moderate and severe post-planting drought conditions (A3 and A4), both ψtlp and ψsat were reduced, which accorded with the effects of drought on hemlock (Tsuga heterophylla) seedlings [46] and the Eucalyptus globulus clones [47]. This suggests that the stressed seedlings could enhance turgor maintenance by osmotic adjustment. Changes in minimum and maximum turgor pressure, and improved osmotic adjustment, are possibly associated with cell membrane properties and fluctuations in intracellular fluid compositions [25].
The intracellular resistance ri of the stems also showed negative correlations with cell wall elasticity. εmax was markedly higher in pre-planting drought treatment (A1B2) when compared to the pre-planting drought effect, and overall, was higher in the slight and moderate post-planting drought treatments (A2, A3) than in A4 and A1. The increase of εmax (less cell wall elasticity) was consistent with previous studies on cell wall elasticity in drought stress [14]. On the contrary, the increment in cell wall elasticity (decrease of εmax) was found in grapevine [48,49], olive tree [50], and common beans [16] in response to water stress. Both responses can be interpreted as evidence of the acclimation to drought conditions [51,52,53]. In this study, in the mild drought condition, cell wall elasticity was decreased more than what can contribute to turgor maintenance, allowing for the water potential of the cell to decrease faster when the water loss is the same, and therefore facilitating the water uptake from the soil [53]. The values of RWCtlp decreased slightly after mild and moderate drought stress. A similar reduction of RWCtlp was found in tomato leaves under infiltration irrigation (stimulus of drought), in which a higher resistance to water stress was suggested [54]. Va/Vp rose under drought stress, indicating that the apoplastic water content increased. The correlation between the relaxation time τ1 and Va/Vp was obtained. This result accorded with the study on Scots pine shoots, where τ1 had a high correlation with the dry matter content of the shoots during cold acclimation [22].

5. Conclusions

The seedlings were injured in cells by four weeks of severe drought stress; however, they also showed some potential acclimation by adjusting the osmotic potential of the cell and cell wall elasticity. Intracellular resistance could be thought of as an important parameter indicating the cell osmotic adjustment functioning; however, extracellular resistance is a parameter to show the cell membrane damage in response to drought stress in lacebark pineseedlings.

Author Contributions

Designing the experiment, A.-F.W., G.Z.; Implementation of the experiment and data collection, A.-F.W., B.D.; Data analysis and interpretation, A.-F.W., G.Z.; Manuscript writing, A.-F.W., B.D., T.R., M.R., G.Z. All authors have read and agreed to the published version of the manuscript.

Funding

This work was funded by the Start-up Fund for Introduced Talents of Hebei Agricultural University (YJ201813) and the Fund for Introduced Returned Overseas Scholars of Hebei Province (C20190339).

Acknowledgments

We thank Jaakko Heinonen for his advice on the statistical analyses.

Conflicts of Interest

The authors declare no conflict of interest.

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Figure 1. An example pressure–volume (P–V) curve of shoots in lacebark pine seedlings.
Figure 1. An example pressure–volume (P–V) curve of shoots in lacebark pine seedlings.
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Figure 2. Extracellular resistance (re) of stems (a) and needles (b) in lacebark pine seedlings by four weeks of post-planting drought treatments (A1, A2, A3, and A4). A1, 75%–80% soil relative water content (SRWC); A2, 55%–60% SRWC; A3, 35%–40% SRWC; and A4, 15%–20% SRWC. B1, adequate irrigation before planting; B2, 5 days of drought before planting; and B3, 10 days of drought before planting.
Figure 2. Extracellular resistance (re) of stems (a) and needles (b) in lacebark pine seedlings by four weeks of post-planting drought treatments (A1, A2, A3, and A4). A1, 75%–80% soil relative water content (SRWC); A2, 55%–60% SRWC; A3, 35%–40% SRWC; and A4, 15%–20% SRWC. B1, adequate irrigation before planting; B2, 5 days of drought before planting; and B3, 10 days of drought before planting.
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Figure 3. Intracellular resistance (ri) of stems (a) and needles (b) in lacebark pine seedlings by four weeks of post-planting drought treatments (A1, A2, A3, and A4). A1, 75%–80% soil relative water content (SRWC); A2, 55%–60% SRWC; A3, 35%–40% SRWC; and A4, 15%–20% SRWC. B1, adequate irrigation before planting; B2, 5 days of drought before planting; and B3, 10 days of drought before planting.
Figure 3. Intracellular resistance (ri) of stems (a) and needles (b) in lacebark pine seedlings by four weeks of post-planting drought treatments (A1, A2, A3, and A4). A1, 75%–80% soil relative water content (SRWC); A2, 55%–60% SRWC; A3, 35%–40% SRWC; and A4, 15%–20% SRWC. B1, adequate irrigation before planting; B2, 5 days of drought before planting; and B3, 10 days of drought before planting.
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Figure 4. Relative water content at the turgor-loss point (RWCtlp) (a), initial osmotic potential at the turgor-loss point (ψtlp) (b), saturation water osmotic potential (ψsat) (c), ratio of bound-water content to free-water content (Va/Vp) (d), and the cell maximum bulk modulus of elasticity (εmax) (e) of shoots in lacebark pine seedlings by four weeks of post-planting drought treatments (A1, A2, A3, and A4). A1, 75%–80% soil relative water content (SRWC); A2, 55%–60% SRWC; A3, 35%–40% SRWC; and A4, 15%–20% SRWC. B1, adequate irrigation before planting; B2, 5 days of drought before planting; and B3, 10 days of drought before planting.
Figure 4. Relative water content at the turgor-loss point (RWCtlp) (a), initial osmotic potential at the turgor-loss point (ψtlp) (b), saturation water osmotic potential (ψsat) (c), ratio of bound-water content to free-water content (Va/Vp) (d), and the cell maximum bulk modulus of elasticity (εmax) (e) of shoots in lacebark pine seedlings by four weeks of post-planting drought treatments (A1, A2, A3, and A4). A1, 75%–80% soil relative water content (SRWC); A2, 55%–60% SRWC; A3, 35%–40% SRWC; and A4, 15%–20% SRWC. B1, adequate irrigation before planting; B2, 5 days of drought before planting; and B3, 10 days of drought before planting.
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Table 1. The statistical significance of the effects of A, B, sampling time, and their interactions on electrical impedance spectroscopy (EIS) parameters during the post-planting growth period, where A is the effect of post-planting drought treatments, B is the effect of pre-planting drought treatments, and t is sampling time effect. p values ≤ 0.05 are in boldface. re: specific extracellular resistance; ri: specific intracellular resistance; τ1 and τ2: relaxation times; ψ1 and ψ2: two distribution coefficients of the relaxation times; τm: a time constant for the cell membrane; β: a factor controlling the skewness of the spectrum and the impedance locus center depression.
Table 1. The statistical significance of the effects of A, B, sampling time, and their interactions on electrical impedance spectroscopy (EIS) parameters during the post-planting growth period, where A is the effect of post-planting drought treatments, B is the effect of pre-planting drought treatments, and t is sampling time effect. p values ≤ 0.05 are in boldface. re: specific extracellular resistance; ri: specific intracellular resistance; τ1 and τ2: relaxation times; ψ1 and ψ2: two distribution coefficients of the relaxation times; τm: a time constant for the cell membrane; β: a factor controlling the skewness of the spectrum and the impedance locus center depression.
ResponseDatap Values
tABA × Bt × A t × Bt × A × B
reStem0.0000.0000.0000.0090.0000.0000.000
riStem0.0000.6610.4360.0020.0000.0000.000
τ1Stem0.3100.6400.6600.0120.0000.0200.000
τ2Stem0.0000.3400.0080.8350.0000.0110.000
ψ1Stem0.4940.1100.9460.1090.2640.4000.059
ψ2Stem0.0000.1100.1110.0030.0040.0040.000
reNeedle0.0000.0000.2270.0010.0000.1360.000
riNeedle0.0000.0000.0800.0100.0000.0000.000
τmNeedle0.0000.0000.0030.0580.0000.0050.000
βNeedle0.0000.0000.0050.2510.0000.0250.000
Table 2. Pearson correlation coefficients between the electrical impedance spectroscopy parameters and pressure–volume curves parameters at week 4 after the post-planting growing period. Asterisks indicate a significant correlation coefficient p < 0.05. Boldface indicates a significant correlation coefficient 0.05 < p < 0.1. RWCtlp: relative water content of the initial plasmolysis; ψtlp: osmotic potential at the turgor-loss point; ψsat: saturation water osmotic potential; Va/Vp: ratio of bound-water content to free-water content; εmax: the maximum tissue bulk modulus of elasticity. re: specific extracellular resistance; ri: specific intracellular resistance; τ1 and τ2: relaxation times; ψ1 and ψ2: two distribution coefficients of the relaxation times; τm: a time constant for the cell membrane; β: coefficient β controlling the skewness of the spectrum and the impedance locus center depression.
Table 2. Pearson correlation coefficients between the electrical impedance spectroscopy parameters and pressure–volume curves parameters at week 4 after the post-planting growing period. Asterisks indicate a significant correlation coefficient p < 0.05. Boldface indicates a significant correlation coefficient 0.05 < p < 0.1. RWCtlp: relative water content of the initial plasmolysis; ψtlp: osmotic potential at the turgor-loss point; ψsat: saturation water osmotic potential; Va/Vp: ratio of bound-water content to free-water content; εmax: the maximum tissue bulk modulus of elasticity. re: specific extracellular resistance; ri: specific intracellular resistance; τ1 and τ2: relaxation times; ψ1 and ψ2: two distribution coefficients of the relaxation times; τm: a time constant for the cell membrane; β: coefficient β controlling the skewness of the spectrum and the impedance locus center depression.
StemNeedle
reriτ1τ2ψ1ψ2reriτmβ
RWCtlp0.24−0.03−0.030.180.09−0.180.24−0.43−0.18−0.51 *
ψtlp0.46−0.56 *−0.24−0.300.12−0.140.29−0.320.24−0.02
ψsat0.43−0.58 * −0.09−0.170.07−0.110.36−0.190.280.18
Va/Vp0.050.080.410.12−0.07−0.03−0.16−0.07−0.09−0.38
εmax−0.370.400.320.34−0.10.10−0.180.35−0.170.19

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Wang, A.-F.; Di, B.; Repo, T.; Roitto, M.; Zhang, G. Responses of Parameters for Electrical Impedance Spectroscopy and Pressure–Volume Curves to Drought Stress in Pinus bungeana Seedlings. Forests 2020, 11, 359. https://doi.org/10.3390/f11030359

AMA Style

Wang A-F, Di B, Repo T, Roitto M, Zhang G. Responses of Parameters for Electrical Impedance Spectroscopy and Pressure–Volume Curves to Drought Stress in Pinus bungeana Seedlings. Forests. 2020; 11(3):359. https://doi.org/10.3390/f11030359

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Wang, Ai-Fang, Bao Di, Tapani Repo, Marja Roitto, and Gang Zhang. 2020. "Responses of Parameters for Electrical Impedance Spectroscopy and Pressure–Volume Curves to Drought Stress in Pinus bungeana Seedlings" Forests 11, no. 3: 359. https://doi.org/10.3390/f11030359

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