Phosphate transport in potato cuttings: Effect of gibberellic acid and abscisic acid

Apical cuttings of Solanum tuberosum L. cv. Sirtema were used al different stages of development to study long-distance transport of phosphate. The effects of two hormones, gibberellic acid (GA₃) and abscisic acid (ABA), on this process were also investigated. Before tuberization, phosphate (³²P) supplied to a single leaf was transported preferentially in the young and growing parts of the plant: apical bud, young leaves and roots. After tuberization, the tuber became the principal site of phosphate accumulation. GA³ treatment (10⁻⁴ M) of the tuber as well as of the leaves led to reduced transport of ³²P into the tuber. By contrast, treatment of the tuber with ABA (10⁻⁴M) did not change the ³²P distribution within the plant, while foliar spray with ABA greatly increased the transport into the tuber. The opposite effects of the two hormones on phosphate accumulation by tubers are discussed with regard to their opposite effects on the tuberization process.     

Regulatory involvement of abscisic acid in potato tuber wound-healing

Rapid wound-healing is crucial in protecting potato tubers frominfection and dehydration. Wound-induced suberization and theaccumulation of hydrophobic barriers to reduce water vapourconductance/loss are principal protective wound-healing processes.However, little is known about the cognate mechanisms that effector regulate these processes. The objective of this researchwas to determine the involvement of abscisic acid (ABA) in theregulation of wound-induced suberization and tuber water vapourloss (dehydration). Analysis by liquid chromatography–massspectrometry showed that ABA concentrations varied little throughoutthe tuber, but were slightly higher near the periderm and lowestin the pith. ABA concentrations increase then decrease duringtuber storage. Tuber wounding induced changes in ABA content.ABA content in wound-healing tuber discs decreased after wounding,reached a minimum by 24 h, and then increased from the 3rd tothe 7th day after wounding. Wound-induced ABA accumulationswere reduced by fluridone (FLD); an inhibitor of de novo ABAbiosynthesis. Wound-induced phenylalanine ammonia lyase activitywas slightly reduced and the accumulation of suberin poly(phenolics)and poly(aliphatics) noticeably reduced in FLD-treated tissues.Addition of ABA to the FLD treatment restored phenylalanineammonia lyase activity and suberization, unequivocally indicatingthat endogenous ABA is involved in the regulation of these wound-healingprocesses. Similar experiments showed that endogenous ABA isinvolved in the regulation of water vapour loss, a process linkedto wax accumulation in wound-healing tubers. Rapid reductionof water vapour loss across the wound surface is essential inpreventing desiccation and death of cells at the wound site;live cells are required for suberization. These results unequivocallyshow that endogenous ABA is involved in the regulation of wound-inducedsuberization and the processes that protect surface cells fromwater vapour loss and death by dehydration. Key words: Abscisic acid, poly(aliphatic), poly(phenolic), potato, Solanum tuberosum L., suberin     

Physiological determinants of genotypic differences in carbon isotope discrimination in potato grown in well-watered conditions

Carbon isotope discrimination (A), leaf conductance (g_s), photosynthetic capacity, and plant growth were measured in well-watered, glasshouse-grown potato plants of clones from a cross made between diploid Solanum tuberosum and Solanum vernei. Clones showed significant differences (P < 0.001) in g_s, Δ, stomatal density, root growth, and total dry matter production. Carbon isotope discrimination of genotypes was positively correlated (P < 0.001) with g_s. There was no correlation between g_s and stomatal density indicating that differences in g_s reflected differences in stomatal aperture. Differences in rooting characteristics or in root/shoot ratio did not contribute to differences in g_s or A. Genotypic differences in photosynthetic capacity were not statistically significant, and there was no correlation between A and photosynthetic capacity. Total dry matter production and A were positively correlated (P < 0.001) when differences in the time of plant emergence were included in the regression model. It is concluded that differences in A among potato genotypes is largely determined by g_s, but confounding of g_s and photosynthetic capacity reduces genotypic variation in A compared with that in g_s. Total dry matter production is largely determined by processes other than carbon assimilation rate per unit area in individual leaves. Effective use of A as a character for selection in plant breeding depends on elucidating the effects that differences in stomatal characteristics have on crop production both in well-watered and in water-limited crops.     

Mesophyll conductance decreases in the wild type but not in an ABA‐deficient mutant (aba1) of Nicotiana plumbaginifolia under drought conditions

Under drought conditions, leaf photosynthesis is limited by the supply of CO₂. Drought induces production of abscisic acid (ABA), and ABA decreases stomatal conductance (g_s). Previous papers reported that the drought stress also causes the decrease in mesophyll conductance (g_m). However, the relationships between ABA content and g_m are unclear. We investigated the responses of g_m to the leaf ABA content [(ABA)_L] using an ABA‐deficient mutant, aba1, and the wild type (WT) of Nicotiana plumbaginifolia. We also measured leaf water potential (Ψ_L) because leaf hydraulics may be related to g_m. Under drought conditions, g_m decreased with the increase in (ABA)_L in WT, whereas both (ABA)_L and g_m were unchanged by the drought treatment in aba1. Exogenously applied ABA decreased g_m in both WT and aba1 in a dose‐dependent manner. Ψ_L in WT was decreased by the drought treatment to ?0.7 MPa, whereas Ψ_L in aba1 was around ?0.8 MPa even under the well‐watered conditions and unchanged by the drought treatment. From these results, we conclude that the increase in (ABA)_L is crucial for the decrease in g_m under drought conditions. We discuss possible relationships between the decrease in g_m and changes in the leaf hydraulics.     

Effects of patchy stomatal closure on gas exchange measurements following abscisic acid treatment

Gas exchange data and images of leaf fluorescence were collected concurrently as stomata responded to abscisic acid (ABA) application. When 10^?5kmolm^?3 ABA was applied to the transpiration stream in a short pulse, stomatal conductance (g_s), photosynthesis (A) and intercellular CO2 concentration (C_i) decreased rapidly after a short lag period and became approximately constant after 2h. There was an apparent reduction in the A versus c1 relationship as stomata closed, but the data returned to the A versus C1 curve while stomatal conductance was constant or slowly rising during the second hour after ABA treatment. Larger amounts of ABA administered during the pulse caused larger deviations from the A versus c1 relationship. When 10^?7kmolm^?3 ABA was applied continuously through the transpiration stream, gs, A and Cⁱ decreased, but there was no substantial deviation from the A versus c{ curve. Fluorescence images were patchy as stomata closed for all experiments, but became slowly more uniform during the time that gas exchange was returning to the A versus Cj curve. The distribution of con-ductance among patches was not bimodal, and larger devi-ations from the A versus ct curve had greater ranges of pixel values and more pixel values representing low values of Cj during stomatal closure than did experiments show-ing small or no deviation. Estimates of A and gs from fluo-rescence images compared favourably with measured val-ues in most cases, suggesting that the patchy distributions of fluorescence were caused by patchy distributions of stomatal conductance and that apparent reductions in the A versus ct relationship were the result of these patchy stomatai distributions and not direct effects of ABA on mesophyll functioning. The data show that stomatal patches can be temporary and that patchiness may not be reflected in gas exchange data if the range of stomatal con-ductances is not large. These observations may explain some of the discrepancies among previous studies concerning the effect of ABA on the A versus Cⁱ relationship.     

Growth rate of potato tubers and endogenous contents of indolylacetic acid and abscisic acid

Potato plants ( Solanum tuberosum L. ev. Ostara) were grown in water culture and the growth rate of individual tubers was measured daily or at two day intervals. Tubers of different growth rate and/or different age (days after tuberization) were harvested and analysed for indolylacetic acid (IAA) and abscisic acid (ABA). Within individual tubers the IAA content decreases from the apical to the basal part of the tuber. Tuber age and corresponding fresh weight are negatively correlated with the endogenous IAA content. If, however, individual tubers of comparable age but different growth rates are compared, a significant positive correlation between growth rate and IAA content is revealed, while ABA showed a significant negative correlation with growth rate. Removal of all fast-growing tubers from individual plants causes an increase in the growth rate of the remaining tubers within 3–4 days. This coincides with a particularly steep increase in IAA content. The data support the idea that endogenous IAA content may be one factor responsible for controlling the growth rate ("sink-activity ") of individual tubers.     

Role of abscisic acid in chilling tolerance of rice (Oryza sativa L.) seedlings. I. Endogenous abscisic acid levels

Changes of ABA levels in chilled rice (Oryza sativa L.) seedlings of two varieties were determined. On exposure to chilling, ABA concentration rapidly increased in the chilling-tolerant cultivar (cv. Tainung 67, TNG.67) but not in the chilling-sensitive cultivar (cv. Taichung Native 1, TN.1). Both detached shoots and roots of TNG.67 seedlings showed a significant ABA increase after exposure to chilling. TN.1 seedlings could not accumulate ABA under low temperature but well-watered status. Exogenous application of the ABA biosynthetic inhibitor, fluridone, reduced ABA accumulation, as well as survival ratio of chilled TNG.67 seedlings. Electrolyte leakage and leaf conductance were also increased by the inhibitor and the effects could be reversed by exogenously applied ABA. ABA concentrations in xylem sap of TNG.67 seedlings increased within 4 h after chilling, and this was temporally coincident with the reduction of leaf conductance. The roles of endogenous ABA in the tolerance of rice seedlings to chilling on a whole plant basis are discussed and suggested.     

Changes in abscisic and gibberellic acids contents during the release of potato seed dormancy

Gas chromatographic measurements demonstrated that the content of endogenous gibberellic acid increased and that of abscisic acid decreased during storage of potato seeds, suggesting that the dormancy of the seeds is controlled by the balance between these two hormones. This revised version was published online in July 2006 with corrections to the Cover Date.     

The effects of abscisic acid on growth and respiratory characteristics of potato tuber tissue discs

Incubation of potato tuber tissue discs on B5 medium supplemented with 1-naphtyl-acetic acid (NAA) led to callus formation, irrespective of the presence of kinetin; without NAA no callus formation occurred. Incubation in the presence of abscisic acid (ABA) reduced the increases in fresh weight and dry weight both in callus-forming and in non-callus-forming tissue. Mitochondrial respiration was lowered by ABA as well. The induction of the alternative, CN-resistant pathway was inhibited by the presence of ABA, especially in mitochondria from non-callus-forming tissue.The in vivo respiration of the callus-forming tissue was higher than that of the non-callus-forming tissue. Total respiration, cytochrome pathway activity and the capacity of the alternative pathway were all lowered in callus-forming tissue by treatment with ABA. The in vivo activity of the alternative pathway was low in all tissue types, especially after ABA-treatment. The slight stimulation by hydroxamates of the oxygen uptake of callus-forming tissue incubated on medium with NAA and ABA indicates the involvement of a hydroxamate-activated peroxidase in the oxygen uptake of this tissue; this peroxidase seemed not to participate in the oxygen uptake of the other tissues types.In non-callus-forming tissue the oxygen uptake of ABA-treated tissue was very low and almost completely resistant to the combined addition of inhibitors of both the cytochrome and the alternative pathway, indicating that the in vivo activity of the mitochondria in the oxygen uptake of the tissue was very low. The possible causes for this ABA-effect are discussed. In non-callus-forming tissue the treatment with ABA creates a situation which is comparable with that observed in intact potato tubers. This situation is characterized by a tissue respiration lower than that of the isolated mitochondria and an alternative pathway capacity that is low or absent.     

Potato cold hardiness development and abscisic acid. I. Conjugated abscisic acid is not the source of the increase in free abscisic acid during potato (Solanum commersonii) cold acclimation

Free and conjugated abscisic acid (ABA) levels in stem-cultured plantlets of potato ( Solanum commersonii Dun, PI 458317) during cold acclimation were measured. The levels of free and conjugated ABA were measured by an enzyme immunoassay (EIA) with rabbit anti-ABA-serum. The use of immunoglobulin G fraction purified from rabbit antiserum and the methylated form of ABA resulted in an improved measuring range (0.01 to 10 pmol ABA) and precision (slope of logit-log plot, −1.35) of EIA, compared to the use of antiserum and free ABA. Estimates of the EIA were consistent with those resulting from a commercial EIA. Under a 4/2°C (day/night) temperature regime, the potato plantlets increased cold hardiness from −5°C (warm-grown control) to −10°C by the 7th day. During the same period, there were two transitory increases in free ABA, the first one three-fold from 1.5 to 5.3 nmol (g dry weight)⁻¹ on the 2nd day and the second one five-fold from 1.5 to 7.6 nmol (g dry weight)⁻¹ on the 6th day. Each increase in ABA concentration was followed by an increase in cold hardiness. There was no significant change in conjugated ABA content (4.2±0.6 nmol [g dry weight]⁻¹) throughout the cold acclimation period. The lack of an interrelationship between levels of free and conjugated ABA suggested that the transitory increase in free ABA during cold acclimation was not a result of the conversion of conjugated ABA. The increase in free ABA due to biosynthesis of ABA during potato cold acclimation is discussed.     

Exogenously applied jasmonic acid induces changes in apical meristem morphology of potato stolons

Hooked apex stolons and initial swelling stolons of potato plants were treated with 3 x 10-8 mol l-1 jasmonic acid (JA) to study the effect of this compound on histology, cell expansion and tissue differentiation. In hooked apex stolons, JA application increased the meristem thickness and reduced the length of the leaf primordia, whereas in initial swelling stolons narrowing of the apical region, absence of leaf primordia and swelling of the subapical meristem were evident. Early vascular tissue differentiation was observed in response to JA treatment, especially of xylem elements from regions proximal to the tunic. Protoxylem elements, such as tracheal elements, were present with thin primary cell walls. The cell area was measured in two zones: zone I, central mother cells situated immediately under the tunic; and zone II, rib meristem cells. JA caused a four- and six-fold increase in cell area in both zones in hooked apex stolons and initial swelling stolons, respectively. Thus, tuber formation is concluded to occur as a consequence of increased cell expansion, a reduction in the length of leaf primordia, enlargement of meristems, and early vascular tissue differentiation.     

Stomatal conductance in relation to xylem sap abscisic acid concentrations in two tropical trees, Acacia confusa and Litsea glutinosa

Two tropical trees, Acacia confusa and Litsea glutinosa, were grown under controlled conditions with their roots subjected to soil drying and soil compaction treatments. In both species, a decline in stomatal conductance resulting from soil drying took place much earlier than the decline of leaf water potential. Soil compaction treatment also resulted in a substantial decrease in stomatal conductance but had little effect on leaf water potential. A rapid and substantial increase in xylem abscisic acid (ABA) concenation ([ABA]), rather than hulk leaf ABA, was closely related to soil drying and soil compaction. A significant relationship between stomatal conductance (g_s) and xylem [ABA] was observed in both species. Artificially feeding ABA solutions to excised leaves of both species showed that the relationship bet ween g_s and [ABA] was very similar to that obtained from the whole plant, i.e. the relationship between g_s and xylem [ABA]. These results suggest that xylem ABA may act as a stress signal in the control of stomatal conductance.     

The metabolism of abscisic acid in flacca,a wilty mutant of tomato

The wilty tomato mutant flacca and the normal variety Rheinlands Ruhm were used in this research. The mutant phenotype was explained mainly by hormonal changes. One of these, the decrease in abscisic acid level, was suggested as the hormonal change closest to the mutated gene. The cause of the lower abscisic acid level in the mutant, which may be enhanced breakdown or inactivation, or inhibited biosynthesis, was investigated. The first possibility was studied by comparing mutant and normal plants treated with t-abscisic acid-2-C¹⁴ for (1) rate of production of labeled methanol-extractable metabolites and (2) radioactivity remaining in the methanol-unextractable fraction. The level of trans, trans-abscisic acid relative to that of cis,trans-abscisic acid was studied in untreated plants. Only two radioactive regions containing metabolites of abscisic acid were detected from either of the plant types, and their rates of production relative to total radioactivity was equal. The radioactivity in the methanolunextractable fraction and the level of trans,trans-abscisic acid were very low in both mutant and normal plants. The second possibility was studied partly by comparing the levels of various xanthophylls in mutant and normal plants and their effect after illumination on cress seed germination. Xanthophylls of both plant types were identical in their absorption spectra, but their levels were higher in the mutant. Of these xanthophylls, illuminated neoxanthin inhibited seed germination in both plant types, but more effectively in the mutant. The most probable explanation for the low level of cis,trans-abscisic acid in flacca is that the conversion of farnesyl PiP to abscisic acid is inhibited in this plant.     

Lactate metabolism in potato tubers deficient in lactate dehydrogenase activity

The aim of this work was to investigate the effect of decreased activity of lactate dehydrogenase (EC 1.1.1.27; LDH) on lactate metabolism in potato tubers. By expressing a cDNA‐encoding potato tuber LDH in the antisense orientation, we generated transgenic potato plants with a preferential decrease in two of the five isozymes of LDH. Surprisingly, transgenic tubers grown under normoxic conditions did not contain less lactate, but rather instead contained approximately two‐fold more lactate than control tubers. This result is explicable if the decreased isozymes of LDH are responsible for the oxidation of lactate to pyruvate in vivo. This was confirmed by measurements of the rate of metabolism of lactate supplied to tuber discs: the rate in transgenic tubers was approximately half that of control tubers. The decrease in LDH activity had no measurable effect on the accumulation of lactate in cold‐stored tubers under anoxia, nor during the subsequent utilization of this lactate upon return to normoxia. In both control and transgenic tubers, the accumulation of lactate during anoxia was not accompanied by an induction of LDH activity or a change in isozyme distribution. In contrast, the metabolism of lactate after a period of anoxia was accompanied by a two‐fold increase in LDH activity and the induction of two isozymes that were distinct from those which had been decreased in the transgenic plants.     

Temporal dynamics of tuber formation and related processes in a crossing population of potato (Solanum tuberosum)

The chronological relationships between stolon formation, stolon tip swelling, tuber initiation, flowering, senescence, growth and resorption of tubers were studied under field conditions in a diploid population of potato with 238 genotypes, the parental clones and seven tetraploid cultivars. Timing of tuber initiation was not closely related to the timing of stolon formation, flowering and duration of the plant cycle. Tuber initiation very often preceded stolon branching. The number and size distribution of tubers were largely influenced by the degree of stolon branching, the length of the stolon swelling period and tuber resorption. The peak production of stolons and swollen stolon tips largely took place within the flowering period, although in most genotypes, some stolon tip swelling took place until the end of the plant cycle. More information on the general temporal relationships between events related to tuber formation and plant development will contribute to a better understanding of the physiological and genetic basis of the processes leading to the production of harvestable tubers.     

Abscisic acid and mefluidide in the regulation of cold hardiness development in Solanum tuberosum L. potato

Plants of Solanum tuberosum L. potato do not cold acclimate when exposed to low temperature such as 5°C, day/night. When ABA (45 M) was added to the culture medium, stem-cultured plantlets of S. tuberosum, cv. Red Pontiac, either grown at 20°C/15°C, day/night, or at 5°C, increased in cold hardiness from –2°C (killing temperature) to –4.5°C. The increase in cold hardiness could be inhibited in both temperature regimes if cycloheximide (70 M) was added to the culture medium at the inception of ABA treatment. Cycloheximide did not inhibit cold hardiness development, however, when it was added to the culture medium 3 days after ABA treatment.When pot-grown plants were foliar sprayed with mefluidide (50 M), ABA content increased from 10 nmol to 30 nmol g^–1 dry weight and plants increased in cold hardiness from –2°C to about –3.5°C. The increases in free ABA and cold hardiness occurred only in plants grown at 20°C/15°C; neither ABA nor cold hardiness increased in plants grown at 5°C.The results suggest that an increase in ABA and a subsequent de novo synthesis of proteins are required for the development of cold hardiness in S. tuberosum regardless of temperature regime, and that the inability to synthesize ABA at low temperature, rather than protein synthesis, appears to be the reason why S. tuberosum does not cold acclimate.     

Memristors: Memory elements in potato tubers

A memristor is a nonlinear element because its current-voltage characteristic is similar to that of a Lissajous pattern for nonlinear systems. This element was postulated recently and researchers are looking for it in different biosystems. We investigated electrical circuitry of red Irish potato tubers (Solanum tuberosum L.). The goal was to discover if potato tubers might have a new electrical component - a resistor with memory. The analysis was based on a cyclic current-voltage characteristic where the resistor with memory should manifest itself. We found that the electrostimulation by bipolar sinusoidal or triangle periodic waves induces electrical responses in the potato tubers with fingerprints of memristors. Tetraethylammonium chloride, an inhibitor of voltage gated K⁺ channels, transforms a memristor to a resistor in potato tubers. Our results demonstrate that a voltage gated K⁺ channel in the excitable tissue of potato tubers has properties of a memristor. Uncoupler carbonylcyanide-4-trifluoromethoxy-phenyl hydrazone decreases the amplitude of electrical responses at low and high frequencies of bipolar periodic sinusoidal or triangle electrostimulating waves. The discovery of memristors in plants creates a new direction in the understanding of electrical phenomena in plants.     

Expression of a bacterial sucrose phosphorylase in potato tubers results in a glucose-independent induction of glycolysis

Sugars are not only metabolic substrates: they also act as signals that regulate the metabolism of plants. Previously, we found that glycolysis is induced in transgenic tubers expressing a yeast invertase in the cytosol but not in those expressing invertase in the apoplast. This suggests that either the low level of sucrose, the increased formation of cytosolic glucose or the increased levels of metabolites downstream of the sucrose cleavage is responsible for the induction of glycolysis in storage organs. In order to discriminate between these possibilities, we cloned and expressed a bacterial sucrose phosphorylase gene from Pseudomonas saccharophila in potato tubers. Due to the phosphorolytic cleavage of sucrose, formation of glucose was circumvented, thus allowing assessment of the importance of cytosolic glucose – and, by implication, flux through hexokinase – in glycolytic induction. Expression of sucrose phosphorylase led to: (i) a decrease in sucrose content, but no decrease in glucose or fructose; (ii) a decrease in both starch accumulation and tuber yield; (iii) increased levels of glycolytic metabolites; (iv) an induction of the activities of key enzymes of glycolysis; and (v) increased respiratory activity. We conclude that the induction of glycolysis in heterotrophic tissues such as potato tubers occurs via a glucose‐independent mechanism.