The electrical impedance spectroscopy of Scots pine (Pinus sylvestris L.) shoots in relation to cold acclimation

Electrical impedance spectroscopy (EIS) was applied to stems of Scots pine (Pinus sylvestris L.) in a provenance field trial during frost hardening to find an EIS parameter for assessing frost hardiness (FH) without a controlled freezing test. The FH of stems and needles assessed by controlled freezing tests was compared with the equivalent circuit EIS parameters of a distributed model of stems (not exposed to controlled freezing treatment) and with dry matter (DM) content of stems. Significant differences in the equivalent circuit parameters, FH and DM content were found between provenances. The relaxation time (tau(1)), describing the peak of the high frequency arc of the impedance spectrum, and the intracellular resistance (r(i)) of stems increased with increasing FH. According to the linear regression, the coefficient of determination (R(2)) between the FH of stems and needles with tau(1) of the stem was 0.87 and 0.89, and with r(i) of the stem 0.74 and 0.85, respectively. The relation between FH and tau(1) changed with the degree of hardiness. The highest coefficient of determination was 0.95 in September when the FH of needles, ranging from -10 degrees C to -25 degrees C, was predicted with an accuracy of +/-2.0 degrees C. The resistance parameter r(2), describing the width of the low frequency arc of the impedance spectrum, decreased prior to and during the initial hardening: significant differences were found between provenances. This indicates that r(2) was not related to frost hardening per se. It is concluded that it is possible to distinguish the hardening patterns of different provenances by tau(1) in the rapid phase of hardening without controlled freezing tests.     

Application of Impedance Spectroscopy for Selecting Frost Hardy Varieties of English Ryegrass

The frost hardening and frost damage of 12 varieties of Englishryegrass (Lolium perenne) was studied by electrical impedancespectroscopy. For the measurement of the impedance spectrum(80 Hz to 1 MHz) a 10 mm length sample was cut from the stemabove the growing point, but the growing point was included.The impedance spectra were analysed by an asymmetric distributedcircuit model. The impedance spectra were measured at two phasesof hardiness and after freezing, i.e. (a) before hardening,(b) after hardening in controlled conditions, and (c) aftercontrolled frost exposure at -16 °C after hardening. Twomodel parameters, i.e. intra- and extracellular resistance,increased with hardening. The intracellular resistance and theskewness factor before hardening, and the ratio between thosetwo parameters before and after hardening, strongly correlatedwith hardening of different varieties of English ryegrass. Theextracellular resistance and the relaxation time decreased asa result of the frost exposure at -16 °C. Cold acclimation; electrical impedance; English ryegrass; frost hardiness; impedance spectroscopy; Lolium perenne     

The relation between growth cessation and frost hardening in Scots pines of different origins

The cessation of shoot elongation, diameter growth and needle elongation were compared with the initiation of frost hardening of the stems and needles in an 8-year-old provenance trial of Scots pine (Pinus sylvestris L.) established in central Finland. The saplings were of six different origins ranging from Estonia to northern Finland, forming a latitudinal gradient of ca. 10°N. The frost hardiness of the stems of current-year shoots was assessed by electrical impedance analysis and that of current-year needles by electrolyte leakage and visual scoring of damage. Artificial freezing tests were used in the assessments. The pattern of growth cessation (shoot and needle elongation, diameter growth) tended to follow the latitude of origin, i.e. growth ceased in the northernmost provenance first and in the southernmost one last. Both stems and needles of the northern provenances hardened earlier than the southern ones, but the differences in hardiness disappeared as hardening progressed. Growth cessation and initial hardening to -15°C were clearly correlated at the provenance level, indicating that growth must cease prior to hardening, and that earlier cessation of growth predicts earlier frost hardening of stems and needles. No differences in frost hardiness of stems were found at the provenance level at the end of the growing period in August. At that time, the frost hardiness of needles of the northernmost provenance was higher than that of other origins. Within the provenance, the stems were less hardy than the needles.     

The electrical impedance spectroscopy of Scots pine needles during cold acclimation

The electrical impedance spectroscopy (EIS) was applied to current-year needles of Scots pine ( Pinus sylvestris L.) in an 8-year provenance field trial in central Finland during frost hardening. The EIS analysis of the needles using a Model-A equivalent circuit indicated a sequence of events in the needles during their cold acclimation. Some of the EIS-parameters referred to maturation phenomena occurring during the pre-hardening phase at the end of the growing season, and some parameters displayed a clear coincidence with the frost hardening itself. Significant differences between provenances were found in several of the Model-A parameters. Extracellular resistance (r_e) and β -coefficient decreased in all provenances in the pre-hardening phase in August and until mid-September. In the same phase, both the intracellular resistance (r_i) and the cell membrane time constant (τ_m) first increased and then decreased. According to τ_m, r_e and β there was a clear gradation between provenances in the pre-hardening phase. From the end of September significant differences were found in the intracellular resistance between provenances, corresponding with the differences in their hardening pattern. The dry weight (DW) content of needles increased during the study period but no clear differences were found between the provenances.     

Assessing frost hardiness of Pinus bungeana shoots and needles by electrical impedance spectroscopy with and without freezing tests

Aims Nursery and forest operations require that frost hardiness results be produced faster than can be provided by controlled freezing tests. There is a great challenge to develop a rapid method for predicting frost hardiness that might not necessitate controlled freezing tests. The aim of this study was to examine the assessment of the frost hardiness of shoots and needles of Pinus bungeana by electrical impedance spectroscopy (EIS) with and without controlled exposure to freezing.Methods The frost hardiness of current-year shoots and needles of P. bungeana in an 8-year-old provenance field trial was measured at Shisanlin Nursery in Beijing, China, from September 2006 to January 2007 by means of EIS and conventional electrolyte leakage (EL). In the same plants, but without controlled freezing test, were monitored the EIS parameters in current-year shoots and needles.Important findings The results showed that (i) after controlled freezing tests, the frost hardiness estimated by EIS parameters (extracellular resistance, r e, and membrane time constant, τ m) was significantly correlated with the frost hardiness assessed by EL method (r = 0.95) and (ii) for the samples not exposed to controlled freezing treatment, the relaxation time τ 1 for shoots and β for needles had greater correlations with the frost hardiness estimated by EL after controlled freezing tests relative to the other parameters (r = ?0.90 for shoots and r = 0.84 for needles, respectively). The parameters r e of shoots and needles and τ m of needles might be applied for measuring frost hardiness of samples after exposed to controlled freezing tests. The frost hardiness results can be obtained within 48 h. The parameters τ 1 of shoots and β of needles could be used for estimating the frost hardiness of samples without using a controlled freezing test. The frost hardiness results can be obtained within 24 h.     

Changing Environmental Effects on Frost Hardiness of Scots Pine During Dehardening

The effects of raised temperature and extended photoperiod onthe dehardening of quiescent and winter-hardy Scots pine saplingswere examined in an open-top-chamber experiment. The saplingswere exposed during winter to natural, square-curve fluctuating(between 1 and 11 °C with a 14 d interval), and constant(6 °C) temperatures with a natural and an extended (17 h)photoperiod. Frost hardiness of needles was determined by controlledfreezing tests and visual damage scoring. The constant 6 °Ctemperature treatment caused a gradual dehardening of needleswhereas under fluctuating temperatures the level of frost hardinessfluctuated. Trees exposed to extended photoperiods were lesshardy than under natural photoperiods after the initiation ofshoot elongation, but before this there were no clear differencesin frost hardiness between different photoperiodic treatments.The results indicate that the frost hardening competence ofScots pine changes during quiescence. Climate change; frost hardiness; hardening competence; photoperiod; Pinus sylvestris, Scots pine; temperature     

Intracellular resistance correlates with initial stage of frost hardening in willow (Salix viminalis)

Distributed model parameters of shoots of five clones of willow ( Salix viminalis ) were examined with electrical impedance analysis at the end of the growing season and with cold acclimation. The parameters were compared with regard to frost hardiness, linoleic (18:2) and linolenic (18:3) fatty acids, unsaturation/saturation ratio of fatty acids and dry weight content. The intracellular resistance (r_i) correlated best with changes in frost hardiness. The value of r_i rose from 1–2 Ω m in non-hardened to about 12 Ω m in hardened samples. In the initial stages of frost hardening, a linear relationship was found between r_i and frost hardiness and levels of 18:2 fatty acid, and an inverse relationship between r_i and levels of 18:3 fatty acid. The unsaturation/saturation ratio of fatty acids rose fairly rapidly in the initial stage of hardening. The dry weight content increased stepwise during the experimental period, and less steadily than r_i. In addition, equivalent circuit parameters changed in the prehardening phase, and were probably connected with cell differentiation and lignification. Frost hardiness by the visual method and by extracellular resistance, determined after controlled freezing tests, correlated well in the initial stages of hardening until about − 10°C but deviated upon further hardening.     

Electrical Impedance Analysis in Plant Tissues8

Electrical impedance spectra (100 Hz–800 kHz) were measuredin leaves of Peperomia obtusifolia L. (a succulent) and Brassicaoleracea L. (cabbage). By measuring impedances at three or moreinter-electrode distances in a single leaf, electrode impedanceand specific tissue impedance were separated. Analysis of impedance data from B. oleracea leaves in relationto an equivalent circuit model showed that leaf developmentwas accompanied by increases in extracellular resistance, cytoplasmicresistance and vacuole interior resistance, together with decreasesin plasma membrane capacitance and tonoplast capacitance. AfterB. oleracea leaves were subjected to a –6 °C freeze-thawstress, extracellular resistance, cytoplasmic resistance andvacuole interior resistance decreased, but plasma membrane capacitanceand tonoplast capacitance did not change. These results indicatethat useful measurements of leaf parameters can be obtainedby this technique. Examination of the electrode impedance spectrum showed thatelectrode insertion produced a damaged collar, 0·4–0·5mm wide, around the electrode. This was confirmed by visualobservation of the damage in P. obtusifolia leaf. Key words: Peperomia obtusifolia L., Brassica oleracea L. (cabbage), electrical impedance, equivalent circuit, electrode polarization     

Does availability of potassium affect cold hardening of Scots pine through polyamine metabolism?

The effect of different potassium availability on the polyamines and frost resistance of Scots pine seedlings ( Pinus sylvestris L.) during cold hardening was studied. Scots pine seedlings were grown applying different rates of potassium by using the relative addition rate technique followed by a 2- or 9-week hardening period with decreased light intensity, day length and temperature. After 2 weeks of treatment the seedlings were not hardened (LT₅₀, =−11°C) and showed no differences in frost resistance, although differences in the polyamine levels between the K levels were observed. After 9 weeks of hardening the seedlings at the low, medium and high K levels showed a mean frost resistance (LTs.₅₀) of −81, −63, and −47°C, respectively. A negative effect of K on the frost resistance of the needles was also found in adult trees in September. The results indicate that at the early stage of cold hardening, potassium or free polyamine levels do not affect the frost resistance of Scots pine needles. However, in hardened seedlings and adult trees potassium displays a negative and putrescine a positive correlation with frost resistance, whereas spermidine and spermine show no correlation.     

CaCl2对金叶女贞茎抗寒性和电阻抗图谱参数的影响

为探明CaCl₂处理对金叶女贞(Ligustrum vicaryi)茎抗寒性和电阻抗图谱参数的影响,找出抗寒性和电阻抗图谱参数的关系,2006年9月15日开始对金叶女贞当年生扦插苗进行CaCl₂处理,对照为清水;分别用电阻抗图谱法和电导法估测其抗寒性,并进行比较分析。结果表明：CaCl₂处理能在抗寒锻炼初期使金叶女贞茎的抗寒性提高3.5℃,金叶女贞茎的抗寒性与未冷冻处理茎的弛豫时间τ、冷冻处理后茎的胞外电阻率r_e、含水量之间均存在较高的相关性。     

The effects of long-term elevation of air temperature and CO on the frost hardiness of Scots pine

The frost hardiness of 20 to 25-year-old Scots pine (Pinus sylvestris L.) saplings was followed for 2 years in an experiment that attempted to simulate the predicted climatic conditions of the future, i.e. increased atmospheric CO₂ concentration and/or elevated air temperature. Frost hardiness was determined by an electrolyte leakage method and visual damage scoring on needles. Elevated temperatures caused needles to harden later and deharden earlier than the controls. In the first year, elevated CO₂ enhanced hardening at elevated temperatures, but this effect disappeared the next year. Dehardening was hastened by elevating CO₂ in both springs. The frost hardiness was high (相似文献   

Plant resistance to cold stress: Mechanisms and environmental signals triggering frost hardening and dehardening

This introductory overview shows that cold, in particular frost, stresses a plant in manifold ways and that the plant’s response, being injurious or adaptive, must be considered a syndrome rather than a single reaction. In the course of the year perennial plants of the temperate climate zones undergo frost hardening in autumn and dehardening in spring. Using Scots pine (Pinus sylvestris L.) as a model plant the environmental signals inducing frost hardening and dehardening, respectively, were investigated. Over 2 years the changes in frost resistance of Scots pine needles were recorded together with the annual courses of day-length and ambient temperature. Both act as environmental signals for frost hardening and dehardening. Climate chamber experiments showed that short day-length as a signal triggering frost hardening could be replaced by irradiation with far red light, while red light inhibited hardening. The involvement of phytochrome as a signal receptor could be corroborated by respective night-break experiments. More rapid frost hardening than by short day or far red treatment was achieved by applying a short period (6 h) of mild frost which did not exceed the plant’s cold resistance. Both types of signals were independently effective but the rates of frost hardening were not additive. The maximal rate of hardening was − 0.93°C per day and frost tolerance of < − 72°C was achieved. For dehardening, temperature was an even more effective signal than day-length.     

测定植物抗寒性的电阻抗图谱法

电阻抗图谱(electrical impedance spectroscopy,EIS)分析作为测定植物抗寒性的一种方法,在农业、林业和园艺领域的应用正在不断扩大。该文从EIS的原理入手,讨论了影响电阻抗特性的生理和物理因子;介绍了测定EIS适用的模型;阐述了用EIS测定抗寒性的方法。在EIS分析中,胞外电阻率(re)是确定抗寒性最适用的一个参数,弛豫时间(τ1)是精确度最高的参数。     

Cold acclimation was partially impaired in boron deficient Norway spruce seedlings

Susceptibility of trees to freezing injury has been suggested to increase in boron (B) deficiency but there is no experimental evidence to support this proposition. In this study, Norway spruce (Picea abies L. Karst.) seedlings were cultivated for two growing seasons in deficient, intermediate and ‘optimal’ B levels. Cold hardening of the seedlings was measured after the second growing season. Freezing tolerance in tips of shoots, needles, stems and roots was determined by controlled freezing tests and electrolyte leakage method, and that of buds, in addition, by differential thermal analysis (DTA). Electrical impedance was used to monitor changes in the apoplastic space during cold acclimation. Root dry weight and shoot height growth were lower in B deficiency. Cold acclimation of buds and stems was reduced by B deficiency. When hardened seedlings were subjected to subzero temperatures for 3 weeks, extracellular electrical resistance of stems became the highest at the lowest B supply which was probably due to decreased desiccation tolerance. As a conclusion, susceptibility to freezing damage may be increased by B deficiency in Norway spruce trees.     

Modelling Woody Plant Tissues5

An electrical impedance spectrum (20 Hz to 1 MHz) was measuredin both the bark and wood of current-year and one-year-old Scotspine (Pinus sylvestris L.) shoots. The measured impedance spectrawere analysed in reference to two lumped circuits and a distributedcircuit. It was found that neither of the two lumped circuitsfit the data from bark or wood as well as the distributed model.The lumped (double-shell) model fit fairly well for bark, butpoorly for wood. It is proposed that the good fit of the distributedmodel and the poorer fit of the lumped models are due to a widerange of cell sizes in the bark and wood. The distributed circuitused in the present study may be useful for describing differentiatedplant tissues for physiological studies. Key words: Bark, electrical impedance, equivalent circuit, Pinus sylvestris L., wood     

高温胁迫对菊花电阻抗图谱参数的影响

以菊花(Chrysanthemum morifolium)‘神马’扦插苗茎段和叶片为材料,测定其高温胁迫(25~50℃)下电阻抗图谱参数的变化,通过膜透性(相对电导率)与电阻抗图谱参数间的相关性,来证明电阻抗图谱法研究菊花耐热性的有效性。结果表明:随着温度升高,茎叶的胞外电阻、胞内电阻、弛豫时间呈现先增加,后急剧下降的趋势,而弛豫时间分布系数变化趋势为不规则下降。茎叶相对电导率是随着温度的升高先增加后降低再急剧增加。经过菊花茎叶电阻抗图谱参数拟合菊花的耐热性与相对电导率表示的耐热性温度极为接近。相关分析表明,高温胁迫下菊花茎叶相对电导率与胞外电阻(茎p<0.01,叶p<0.05)、弛豫时间(p<0.05)之间有显著的相关。由此可见,胞外电阻和弛豫时间是测定菊花耐热性的适合参数。     

水杨酸对大叶黄杨茎抗寒性和电阻抗图谱参数的影响

在抗寒锻炼前,对当年生大叶黄杨(Euonymus japonicus)扦插苗喷施不同浓度水杨酸,用电阻抗图谱(EIS)法和电导(EL)法估测茎的抗寒性,以探明抗寒锻炼期间水杨酸对大叶黄杨抗寒性和电阻抗图谱参数的影响,找到适合不经冷冻处理估测大叶黄杨茎抗寒性和经冷冻处理后测定其抗寒性的EIS参数。结果表明,水杨酸处理能够提高大叶黄杨茎的抗寒性,最适浓度为5.0mmol.L-1;不经冷冻处理茎的EIS参数电阻率r和r1、胞外电阻率re、胞内电阻率ri、弛豫时间τ、弛豫时间分布系数ψ与EL法测定的抗寒性有较高的相关性(r=0.70~0.87),说明不经冷冻处理样本用以上参数估测大叶黄杨茎抗寒性是可行的,r1为最佳参数;冷冻处理后茎的re、τ、ri求得的抗寒性与EL法测定的抗寒性有较高的相关性(r=0.85~0.94),说明冷冻处理后re、τ、ri可以作为测定大叶黄杨茎抗寒性的参数,re为最佳参数。     

Accumulation of Phenolic Compounds in the Necrotic Areas of Austrian and Red Pine Needles Due to Salt Spray

Austrian pine (Pinus nigra) and red pine (P resinosa) were testedfor needle damage caused by salt spray. Morphology and histologyof newly grown needles were compared in 3- and 6-year-old plantsgrowing in the greenhouse under controlled conditions. Pottedplants covered with plastic bags were sprayed daily either withdistilled H₂O or saturated salt solution. Needle tips, mid-partsand bases were fixed after 1, 3 and 24 h, and 3, 7 and 30 din glutaraldehyde+0·1 % caffeine for precipitation ofphenolics. Histochemical reactions and electron microscope observationsshowed that the morphological damage is linked to increasedphenolic compound deposition in mesophyll cells, beginning directlyunder the stomata. Disorganization of membranes leads to deathof the mesophyll cells, even before morphological damage isrecognizable as brown spots on the needle surface. Thus thehistochemical reactions and observations of cell structure revealeddamage earlier than macroscopic observations. Salt injury, phenolic compounds, histological damage, ultrastructural damage, salt spray, Pinus nigra, Austrian pine, Pinus resinosa, red pine     

Impedance Spectroscopy in Frost Hardiness Evaluation of Rhododendron Leaves

Impedance spectroscopy was used in studying frost hardinessof leaves of two diploid rhododendron cultivars, RhododendronL. ‘PJM’ and R. ‘Cunningham's White’,and their tetraploid derivatives, R. ‘Northern Starburst’(NSB) and CW4. After the growing season and initial hardeningin a greenhouse, plants were subjected to an acclimation regimein a phytotron: 3 consecutive weeks at +5, +1 and -2°C each.Hardiness was studied with controlled freezing tests beforeeach decrease in temperature and at the end of the experiment,based on data of extracellular resistance r_eand relaxation time of the frost-exposed leaves. The correlation of the two estimateswas 0.92. Generally, the diploid clones had better frost hardinessthan the tetraploid clones. At the end of the experiment, frosthardiness of the diploid ‘PJM’ was -28.7°C andthat of the tetraploid NSB -20.6°C. Leaves of the diploid‘Cunningham's White’ and of the tetraploid CW4 hardenedto -32.0°C and -20.9°C, respectively. Frost hardinessestimated by impedance spectroscopy correlated well with earlierresults based on visual scoring (r = 0.81–0.86) and electrolyteleakage tests (r = 0.84–0.90), but results from impedancespectroscopy indicated weaker hardiness than the other tests.The difference between the results from impedance spectroscopyand the other tests was smaller and more coherent within the‘Cunningham's White’ clones than within ‘PJM’and NSB. Changes in extracellular and intracellular resistanceof non-frozen leaves during the acclimation correlated withthe changes in frost hardiness of ‘Cunningham's White’clones, but not with those of ‘PJM’ and NSB, whichbelong to another subspecies.Copyright 2000 Annals of BotanyCompany Cold resistance, evergreen, frost hardiness, impedance spectroscopy, polyploid, Rhododendron, tetraploid     

On the mechanisms of frost injury and frost hardening of spruce chloroplasts

Hill reaction and noncyclic photophosphorylation of isolated class C chloroplasts of spruce (Picea abies (L.) Karst.), as well as ¹⁴CO₂ fixation by whole needles at constant laboratory conditions proceeded at high rates during spring and early summer, declined during late summer and autumn by about 60%, remained at this level during winter, and recovered quickly in early spring. During summer, the whole needles proved to be frost labile, since after exposure to-20°C and careful thawing, fast chlorophyll degradation occurred. In addition, only photosynthetically inactive chloroplasts could be isolated from those precooled needles. On the contrary, during winter the photochemical activities of plastids from freshly harvested needles did not differ from those of artificially frozen-thawed needles. When isolated spruce chloroplasts were exposed to the same subfreezing temperatures as the whole needles, no influence of freezing on the photochemical activities was observed, irrespective of whether the plastids were isolated from frost sensitive or frost hardened needles. It is concluded that frost damage to spruce chloroplasts is due to an attack of membrane toxic compounds or lytic enzymes which were liberated upon freezing from more labile compartments. Frost hardening of the chloroplasts, as determined by the stability of chlorophyll after exposure of the needles to low temperatures, as well as by the isolation of photosynthetically active chloroplasts from such precooled needles, appeared to depend at least on 2 processes: (i) an alteration of the composition of the photosynthetically active membranes and (ii) and additional stabilization of these membranes by protecting substances. The first process was indicated by a large increase (decrease) of the capability of isolated chloroplasts for PMS-mediated photophosphorylation which accompanied natural or artificial frost hardening (dehardening). Production of cryoprotecting compounds was suggested by a significant higher stability against NaCl observed with class C chloroplasts isolated from frost hardened needles as compared to that of plastids from frost labile material. The decrease of the capability for both, the ferricyanide dependent photoreactions of the plastids and the CO₂ fixation by whole needles, which was observed during the frost hardening phase, cannot be due to freezing injuries; it rather appears to be a consequence of the frost hardening process.