Calcium deficiency in potato (Solanum tuberosum ssp. tuberosum) leaves and its effects on the pectic composition of the apoplastic fluid

Potato plants (Solanum tuberosum ssp. tuberosum cv. Adelheid), multiplied in vitro, were cultivated in growth chambers on nutrient solution at calcium regimes of 1000, 90, 60 or 30 μM Ca. An absolute Ca deficiency, particularly at the low Ca‐supply levels of 30 and 60 μM Ca, manifested itself initially in the form of marginal necrosis in younger, but not in the youngest, leaves of the potato plants. Further symptoms were rolling of the leaf lamina, browning of veins and roots, and finally necrosis also of the youngest leaves. Only in an advanced stage of Ca deficiency, the meristem of the shoots died. Ca‐deficiency symptoms could be expected at a Ca content in the leaves of less than 5 mg Ca (g dry weight)^?1. However, there was no close negative correlation between the extent of leaf damage and the total Ca content of the leaves. In order to obtain information about the Ca concentration in the apoplast fluid of the leaves, apoplastic washing fluid was extracted by an infiltration‐centrifugation technique. A low Ca supply reduced the Ca concentration both in the apoplast fluid of the leaves and in the cell walls. Up to 60% more diffusible pectin fragments were then found in the apoplast of younger leaves, as compared to the control supplied with an optimum Ca level of 1000 μM. The amount of diffusible pectins accounted for 1–2% of the total pectin content of younger potato leaves. The size of the existing pectin fragments varied depending on the Ca supply. Compared with an optimum Ca supply of 1000 μM, fewer monomers and up to 7 times more diffusible pectin fragments with a degree of polymerization 9–20 were present at the low Ca‐supply level (30 μM). In addition, polygalacturonase activity in tissue homogenates increased remarkably with Ca deficiency. Thus it appears that one major effect of Ca deficiency was a stimulation of the activity of polygalacturonase, which could control the breakdown of pectic polysaccharides in the cell wall. Whether the release of potentially biologically active pectic fragments in cell walls might be involved in the occurrence of Ca‐deficiency symptoms is discussed.     

The influence of calcium deficiency on the translocation of photosynthetically fixed 14C in soybeans

Summary Soybean (Glycine max (L.) Merr.) plants were grown at two levels of Ca (0.05 and 2.5 mM Ca) with and without an inorganic source of N in a growth chamber and in the greenhouse. The fourth leaf from the top of the plant was labeled with ¹⁴C, and the distribution of ¹⁴C was measured 24 hours after labeling. The translocation of ¹⁴C out of the labeled leaf was decreased at the low Ca level in both experiments. This decrease occurred before there were any visual Ca deficiency symptoms and before the low Ca level had any effect on dry weight accumulation. The effect of the low Ca level on translocation was the same for plants exposed to an inorganic N source and those that were nodulated. The reduced rate of translocation from the labeled leaf had no measurable effect on the nodule activity as measured by the acetylene reduction method. The data demonstrate the importance of an adequate supply of Ca to the soybean plant for maximum translocation of carbohydrates from the leaves.This paper (76-3-110) is published with the approval of the Director of the Kentucky Agric. Exp. Stn.This paper (76-3-110) is published with the approval of the Director of the Kentucky Agric. Exp. Stn.     

Controls over leaf and litter calcium concentrations among temperate trees

Four-fold variation in leaf-litter Ca concentration among 14 tree species growing in a common garden in central Poland was linked to variation in soil pH, exchangeable Ca, soil base saturation, forest floor turnover rates, and earthworm abundance. Given the potential importance of tissue Ca to biogeochemical processes, in this study we investigated potential controls on leaf Ca concentrations using studies of both laboratory seedlings and 30-year-old trees in the field. We first assessed whether species differences in Ca concentration of green leaves and leaf litter were due to differences in Ca uptake, plant growth, or Ca translocation to different organs, by measuring seedlings of 6 of the 14 species grown under controlled conditions of varying Ca supply. We also investigated whether trees species with high Ca concentrations in green leaves and leaf litter access soil Ca to a greater extent than low-Ca species by growing more fine roots in high-Ca soil horizons. Root distribution in the field was determined in all 14 tree species by profile wall mapping and soil sampling of excavated pits. There was no correlation between horizon root count density (number of roots m⁻²) and exchangeable soil Ca, nor was there a correlation of stand-level leaf litter Ca with density of roots 45–100 cm deep in the soil, suggesting that a deeper root distribution does not result in greater Ca acquisition among these species. Variation among species in leaf Ca concentration of greenhouse seedlings was positively correlated with leaf Ca concentrations of mature trees, indicating that the same ranking in leaf Ca among species existed under controlled Ca supply. Species also differed in seedling growth response to Ca supply. Tilia, the species with the highest leaf Ca in the field, generated only 10% as much biomass and height at low relative to high Ca supply, whereas the other species exhibited no significant differences. Species exhibited differences in (i) partitioning of whole plant Ca and biomass to leaf, stem and root organs and (ii) the pattern of such partitioning between high and low Ca treatments. Our data support the hypothesis that although soil Ca supply can contribute to variation among trees in leaf and litter Ca concentration, innate physiological differences among species also can be a major cause for species variation.     

Distribution of calcium in tomato plants in response to heat stress and plant growth regulators

Two cultivars of tomato with contrasting response to elevated temperature were compared: sensitive-Roma and tolerant-Robin. Experiments were done on fruit explants and on rooted cuttings with small fruits. In both cases⁴⁵Ca was poorly transported to the fruits. Nevertheless in fruit explants elevated temperature (40°C) increased⁴⁵Ca import into the fruits in both cultivars. In the compared cuttings, treated or not treated with growth regulators and at various temperatures, the greatest differences were observed in the amount of⁴⁵Ca transported to the fruits. Sensitive Roma cuttings scantily supplied their fruits with⁴⁵Ca both under optimal temperature and heat stress. In plants previously treated with NOA+GA₃ high temperature increased⁴⁵Ca transport to the fruits. Robin cuttings inversely responded to heat stress by transporting a much higher portion of⁴⁵Ca to the fruits, both in control and NOA+GA₃ cuttings.The diversity of⁴⁵Ca distribution during elevated temperature in cuttings, but not in fruit explants of both cultivars seems to be connected with an ability to control calcium supply to fruit or at least to prevent its decrease; this mechanism is perhaps located outside the cluster.     

Subsynaptosomal distribution of45Ca taken up by synaptosomes in high-potassium medium

The⁴⁵Ca uptake of synaptosomes was stimulated by high K⁺, and the K-stimulated uptake was temperature dependent and reached a plateau level within 20 sec at 30°C. The synaptosomes which took up⁴⁵Ca in high-K⁺ medium for 20 sec was disrupted, and subsynaptosomal distribution of⁴⁵Ca was examined. The percentage increases of⁴⁵Ca labeling of fractions D (vesicles), C (myelin), B (synaptic plasma membrane), and A (mitochondria) induced by high potassium were 27.7±10.3%, 28.7±10.4%, 31.0±4.0%, and 48.1±5.5%, respectively. However, total counts of K-stimulated⁴⁵Ca labeling in fraction B was equal to that in fraction A, and those in fractions C and D were less. These observations indicate that Ca binding on the synaptic plasma membrane may be as important as a Ca reservoir of regulator of Ca²⁺ in nerve terminals as the mitochondria.     

An Exogenous Source of Nitric Oxide Modulates Iron Nutritional Status in Peanut Seedlings (<Emphasis Type="Italic">Arachis hypogaea</Emphasis> L.)

Iron (Fe) deficiency chlorosis is a common and severe nutritional deficiency in plants, and nitric oxide (NO) is an important signaling molecule in regulating Fe homeostasis in plants. We studied the effect of sodium nitroprusside (SNP, an NO donor) on Fe uptake, translocation, storage, and activation in a greenhouse. The concentrations of active Fe, total Fe, and the ratio of active Fe to total Fe, the activities of key enzymes, and chlorophyll concentration were determined, and resistance to oxidative stress and mineral element distribution in peanut plants grown in Fe sufficiency and Fe deficiency (an absence of Fe and low level of Fe concentration) conditions were also investigated. The results showed that NO significantly increased the concentration of active Fe and the ratio of active Fe to total Fe in Fe-deficient plants, and increased active Fe concentration in leaves and stems of Fe-sufficient plants. NO application also increased Fe translocation from roots to the shoots and the accumulation of Fe in cell organelles and the soluble fraction in leaves, especially in the low-level Fe concentration condition, thus increased available Fe and chlorophyll concentration in leaves of Fe-deficient plants. The activities of key enzymes were regulated by NO, which effectively mitigated oxidative damages by enhancing the activities of antioxidant enzymes (SOD, POD, CAT), increasing H⁺-ATPase and Ca²⁺-ATPase activities to balance the ion (Fe, Ca, Mg and Zn) uptake and distribution in Fe-deficient plants. However, NO application had no obvious effect on these variables in Fe-sufficient plants. These results indicated that NO application can improve Fe uptake, translocation, and activation of related enzymes in Fe-deficient plants, thus mitigating the adverse effect of Fe deficiency.     

On the movement and distribution of calcium in white cabbage in dependence of the water status

Summary The uptake and distribution of Ca in white cabbage have been measured under controlled climatic conditions. The uptake of Ca has been determined by continuous -intensity measurements of⁴⁵Ca simultaneously at an outer transpiring leaf and at an inner head leaf. In the outer leaves the Ca content increased during the day in dependence of the transpiration amplitude. With-in the inner head leaves Ca was transported mainly during the night when the head mass additionally measured by -absorption increased due to the increasing plant water potential. At the end of the experiment the stable and active Ca concentration has been measured. re]19760823     

A study of calcium compartments in rat brain cortex thin slices: Effects of veratridine,lithium and of a mitochondrial uncoupler

The efflux kinetics of⁴⁵Ca from rat brain cortex thin slices previously equilibrated with it, was studied in a superfusion system. Two first order kinetic components of efflux from the tissue were found: k₂=0.0667 min^–1, that was unchanged by lowering the temperature from 37°C to 15°, and k₃=0.0167 min^–1 at 37°C, that was reduced to 0.0897 min^–1 at 15°C. This suggests that k₂ represents efflux from the extracellular space, and k₃ that from the cellular compartment. Addition of the mitochondrial uncoupler carbonyl cyanide,m-chlorophenylhydrazone (CCCP) (10^–5 M) increased the efflux fractional rate constant of⁴⁵Ca by 35%, while no change in efflux was induced by 10 mM caffeine. Veratridine (10^–5M) drastically reduced⁴⁵Ca efflux if superfusion was with physiological salt solution (150 mM sodium present), but not if 50 mM lithium replaced an equivalent amount of sodium in the superfusion fluid. This lithium-containing solution did not affect⁴⁵Ca efflux in the absence of veratridine. These results indicate that mitochondria accumulate only a minor fraction of intracellular⁴⁵Ca; that⁴⁵Ca possibly turns over very rapidly in the endoplasmic reticulum, and that most of⁴⁵Ca is present in a different, non-mitochondrial, non endoplasmic reticular compartment, the nature of which can be only conjectured.     

油菜幼苗对硼的吸收与运转及钙的影响

硼促进油菜幼苗生长和对N、P、K、Ca 营养元素的吸收.当油菜生长介质中钙浓度增大时,植株吸硼量和硼在新叶中的积累减少,老叶中积累增加。硼在油菜体内的运转系数在低硼条件下较大,并随钙处理水平的增加而下降.结果表明,在硼素供应有限的条件下,油菜体内硼仍具一定的移动性,钙则使硼的吸收和移动性下降.     

Calcium transport in apple trees

⁴⁵Ca, applied to roots of apple seedlings, moved readily to the developing leaves. Kinetin, benzyladenine, and B sprays increased movement. NO₃⁻ as the source of N increased movement and accumulation of Ca into mature leaves; NH₄⁺ increased movement into new leaves. Translocation in the stem is effected by a nonspecific ion exchange. Any divalent cation can free Ca for ascent. The exchange may be a property of lignin. Genetic differences in the uptake and translocation of Ca exist among apple seedlings. Those which show juvenile leaf characteristics translocate Ca into mature leaves more readily. Translocation of Ca in woody species appears to be similar to that reported for herbaceous plants.     

Boron Deficiency Induced Changes in Translocation of 14CO2-Photosynthate Into Primary Metabolites in Relation to Essential Oil and Curcumin Accumulation in Turmeric (Curcuma longa L.)

Changes in leaf growth, net photosynthetic rate (P _N), incorporation pattern of photosynthetically fixed ¹⁴CO₂ in leaves 1–4 from top, roots, and rhizome, and in essential oil and curcumin contents were studied in turmeric plants grown in nutrient solution at boron (B) concentrations of 0 and 0.5 g m^-3. B deficiency resulted in decrease in leaf area, fresh and dry mass, chlorophyll (Chl) content, and P _N and total ¹⁴CO₂ incorporated at all leaf positions, the maximum effect being in young growing leaves. The incorporation of ¹⁴CO₂ declined with leaf position being maximal in the youngest leaf. B deficiency resulted in reduced accumulation of sugars, amino acids, and organic acids at all leaf positions. Translocation of the metabolites towards rhizome and roots decreased. In rhizome, the amount of amino acids increased but content of organic acids did not show any change, whereas in roots there was decrease in contents of these metabolites as a result of B deficiency. Photoassimilate partitioning to essential oil in leaf and to curcumin in rhizome decreased. Although the curcumin content of rhizome increased due to B deficiency, the overall rhizome yield and curcumin yield decreased. The influence of B deficiency on leaf area, fresh and dry masses, CO₂ exchange rate, oil content, and rhizome and curcumin yields can be ascribed to reduced photosynthate formation and translocation.     

Influence of Nitrogen Supply on Uptake and Translocation of Strontium and Calcium in Wheat Seedlings

Supplying nitrate to N-depleted wheat seedlings (Triticum vulgare cv. Knox) stimulated the uptake and translocation of both ⁸³Sr and ⁴⁵Ca. Since the increase in ⁴⁵Ca accumulation was greater, the ⁸⁵Sr/⁴⁵Ca ratio in the plant tissue was decreased. Nitrate had relatively little influence on the amount of the divalent cations and ⁸⁵Sr/⁴⁵Ca ratio in the exchangeable fraction on the root surfaces, whereas it greatly increased the uptake into root tissue and translocation to shoots. The increase in percent transported to shoots occurred largely in the period of most rapid nitrate uptake. A split root study indicated that nitrate was ineffective when it was supplied to a different portion of the root system than that exposed to ⁸⁵Sr and ⁴⁵Ca. Nevertheless, ammonium and urea also increased the translocation of the two cations, indicating that the effects of nitrate could not entirely be ascribed to a direct effect of the nitrate anion.     

Diurnal changes in the flux of calcium toward meristems and transpiring leaves in tomato and maize plants

Tomato (Lycopersicon esculentum Mill. cv. Moneymaker) and maize (Zea mays L. cv. spec.) plants were supplied with ⁴⁵Ca-labeled nutrient solutions for a period of 8 or 16 h in the dark, in the light, or in a light-dark régime. Plant parts were analyzed for ⁴⁵Ca content. The partitioning of ⁴⁵Ca between mature leaves and meristems was shown to be affected by the presence of light. The transport of ⁴⁵Ca to meristems was higher in a dark period than in a comparable light period. Experiments with excised tomato shoots yielded similar distribution patterns of ⁴⁵Ca over leaves and meristems, thus excluding root pressure as the main driving force for the enhanced import of ⁴⁵Ca into the meristems in the dark. Results are discussed in terms of cation-exchange transport and competition between the various calcium sinks.Abbreviations DM dry material - IAA indole-3-acetic acid - TIBA 2,3,5-trijodbenzoic acid - CEC cation exchange capacity Contribution No. 1693 of the Radiation Protection Programme of the Commission of the European Communities     

油菜幼苗对硼的吸收与运转及钙的影响

硼促进油莱幼苗生长和对N、P、K、Ca营养元素的吸收。当油莱生长介质中钙浓度增大时,植株吸硼量和硼在新叶中的积累减少,老叶中积累增加。硼在油莱体内的运转系数在低硼条件下较大,并随钙处理水平的增加而下降。结果表明,在硼素供应有限的条件下,油菜体内硼仍具-定的移动性,钙则使硼的吸收和移动性下降。     

Use of secondary ion mass spectrometry to image44calcium uptake in the cell walls of apple fruit

Summary Calcium, an important agent in regulating cell wall autolysis during fruit ripening, interacts with pectic acid polymers to form cross-bridges that influence cell separation. In the present study, secondary ion mass spectrometry (SIMS) was used to determine whether the cell walls of apple fruit were able to take up exogenously applied⁴⁴Ca, which was infiltrated into mature fruit. SIMS, which has the ability to discriminate between isotopes, allowed localization of the exogenously applied⁴⁴Ca and the native⁴⁰Ca. The results indicated that the total amount of calcium present in the cell walls was enriched with⁴⁴Ca and that heterogeneity of⁴⁴Ca distribution occurred in the pericarp. Isotope ratio images showed microdomains in the cell wall, particularly in the middle lamella intersects that oppose the intercellular spaces. These domains may be the key areas that control cell separation. These data suggest that exogenously applied calcium may influence cell wall autolysis.Abbreviations SIMS secondary ion mass spectrometry     

Investigating the in vivo calcium transport path to developing potato tuber using 45Ca: a new concept in potato tuber calcium nutrition

Calcium is believed to be transported with water in the xylem. Consistent with this proposal, low‐transpiring organs such as potato Solanum tuberosum tubers are known to suffer from calcium deficiency. Although roots on tubers and stolons have been shown to supply water to tubers, there is no direct evidence for the calcium transport pathway to tubers. Both a xylem and a phloem transport pathway have been suggested. We investigated in vivo calcium transport to developing potato, cv. Dark Red Norland and cv. Russet Burbank, tubers using ⁴⁵Ca in a controlled environment facility. Whole plant split pot experiments allowed the placement of ⁴⁵Ca either in the main (basal) root or the tuber and stolon areas of the pot. The results showed that ⁴⁵Ca was transported to the shoot with the transpiration stream from both areas but was not re‐translocated to tubers or the main (basal) root system even 57 days after ⁴⁵Ca application. Radioactivity could only be detected in the tuber when ⁴⁵Ca was fed to the stolon and tuber area. When ⁴⁵Ca was fed to specific tubers, radioactivity was detected in the aerial shoot; however, no activity was detected in other tubers or the main (basal) roots. In another set of experiments, roots on a stolon near a tuber were precisely fed ⁴⁵Ca and Safranin O. The radioactive signal exactly overlapped the water transport pathway in the tuber marked with Safranin O dye, suggesting that water and calcium can be simultaneously transported from stolon roots to the tuber. No transport of ⁴⁵Ca across the tuber periderm was detected 8 days after ⁴⁵Ca was applied to the tuber periderm. This indicated that no significant transport of calcium occurs from the soil across the periderm. Our results provide evidence that: (1) calcium is not re‐translocated via the phloem from the aerial shoot tubers and main (basal) roots; (2) the main root system does not supply calcium to the tuber; (3) calcium is not transported across the periderm to the interior tuber tissue; (4) calcium is transported to the tuber via the xylem along with water, and the roots on the stolon associated with the tuber supply water and calcium to the developing tuber; and (5) transpirational demand is a significant determinant of calcium distribution within the plant.     

Effects of calcium ionophores on the transport and distribution of calcium in isolated cells and in liver and kidney slices

Summary The effects of calcium ionophores on cellular calcium metabolism were studied in cultured kidney cells, in cells freshly isolated from rat kidney, and in liver and kidney slices. In isolated cells, these ionophores decreased the total cellular Ca content and the mitochondrial Ca.⁴⁵Ca efflux from prelabelled cells was also stimulated even in the absence of extracellular Ca. In slices, the ionophore A23187 increased the total slice Ca and the uptake of⁴⁵Ca. However, the mitochondria isolated from these slices treated with the ionophore had a lower total Ca and a depressed relative radioactivity. These results suggest that the increased cytosolic Ca produced by Ca ionophores may be due to mobilization of intracellular Ca stores rather than to a net shift of Ca from the extracellular fluids to the cell.     

Evidence that root pressure flow is required for calcium transport to head leaves of cabbage

Young cabbage plants (Brassica oleracea L. var. capitata) that were exposed to an atmosphere at 50% relative humidity transpired freely and accumulated significant quantities of ⁴⁵Ca in the leaves. Plants that were enclosed by plastic bags to stop transpiration from all leaves exhibited guttation with the development of root pressure and also accumulated significant quantities of ⁴⁵Ca in the leaves. ⁴⁵Ca accumulation increased in the leaves and tended to decrease in roots and stems with increasing quantities of water transpired or guttated by the plant. When plants were only partially enclosed so that some leaves were covered and the remainder exposed, only the exposed leaves that were transpiring accumulated significant quantities of ⁴⁵Ca. The covered leaves of partially enclosed plants exhibited no guttation and accumulated little ⁴⁵Ca with no measurable ⁴⁵Ca at the margins of the leaves. The results demonstrate that root pressure flow is required to transport adequate amounts of Ca to those tissues in plants that are not undergoing transpirational water loss.     

Relationship between boron and calcium in the N2-fixing legume–rhizobia symbiosis

Because boron (B) and calcium (Ca²⁺) seem to have a strong effect on legume nodulation and nitrogen fixation, rhizobial symbiosis with leguminous plants, grown under varying concentrations of both nutrients, was investigated. The study of early pre‐infection events included the capacity of root exudates to induce nod genes, and the degree of adsorption of bacteria to the root surface. Both phenomena were inhibited by B deficiency, and increased by addition of Ca²⁺, resulting in an increase of the number of nodules. The infection and invasion steps were investigated by fluorescence microscopy in pea nodules harbouring a Rhizobium leguminosarum strain that constitutively expresses green fluorescent protein. High Ca²⁺ enhanced cell and tissue invasion by Rhizobium, which was highly inhibited after B deficiency. This was combined with an increased B concentration in nodules of plants grown on B‐free medium and supplemented with high Ca²⁺ concentrations, and that can be attributed to an increased B import to the nodules. Histological examination of indeterminate (pea) and determinate (bean) nodules showed an altered nodule anatomy at low B content of the tissue. The moderate increase in nodular B due to additional Ca²⁺ was not sufficient to prevent the abnormal cell wall structure and the aberrant distribution of pectin polysaccharides in B‐deficient treatments. Overall results indicate that the development of the symbiosis depends of the concentration of B and Ca²⁺, and that both nutrients are essential for nodule structure and function.     

Boron distribution and mobility in navel orange grafted on citrange and trifoliate orange

Background and Aims

In China, boron (B) deficiency is frequently observed in citrus orchards, and is responsible for considerable loss of productivity and quality. A better understanding of B distribution and remobilization within orange plants is important for developing programs in rational fertilization and effective mitigation of B-deficiency. In the present study (i) the distribution of newly absorbed B and (ii) the translocation of foliar-applied B in ‘Newhall’ navel orange grafted on citrange and trifoliate orange was investigated.

Methods

¹⁰B was applied in the nutrient solution or sprayed on the lower-old leaves of both grafted plants for 35?days.

Results

In the ¹⁰B uptake experiment, citrange-grafted plants showed higher newly acquired total B content and B concentration in both lower-old and upper-old leaves than those in trifoliate-orange-grafted plants. The newly absorbed B in the new leaves was much higher than that in the lower-old leaves and the upper-old leaves in both grafted plants. Foliar application of ¹⁰B to the lower-old leaves resulted in B translocation to the upper-old leaves and the new leaves with preference mainly to the new leaves in both citrange and trifoliate orange when root B supply was relatively low. However, ¹⁰B sprayed to the lower-old leaves not only did not increase the abundance percentage of ¹⁰B in the root, but also reduced B concentration and the total B content in the root.

Conclusions

The results suggest that foliar-applied B can be translocated within both grafted plants, which might also depress B uptake from root medium with low B supply. Rootstock can affect the B distribution in old leaves in navel orange, and newly absorbed B was preferentially transported to the new leaves.