Mediation of deep supercooling of peach and dogwood by enzymatic modifications in cell-wall structure

Treatment of stem sections of peach (Prunus persica (L.) Batsch) and flowering dogwood (Cornus florida L.) with macerase, an enzyme mixture rich in pectinase, for 24–48 h resulted in a complete flattening of the low-temperature exotherm (LTE) as determined by differential thermal analysis (DTA). Ultrastructural analysis of macerase-treated tissue demonstrated a nearly complete digestion of the pit membrane (black cap and primary cell-wall) of nearly 100% of the xylem-parenchyma cells examined after 48 h of exposure to the enzyme. Additionally, the underlying amorphous layer was partially degraded in up to 57% of the cells examined. The macerase treatment had no visible effect on secondary cell-walls of xylem tissue. In contrast, treatment of stem tissue with cellulysin (mostly cellulase) resulted in a shift of the LTE to warmer temperatures as determined by DTA, and a digestion of only the outermost layer of the pit membrane in nearly 100% of the cells examined, with little or no effect on the underlying layers. Treatment of tissue with 25 mM sodiumphosphate buffer also resulted in a shift of the LTE to warmer temperatures but the shift was not as great as in cellulysin-treated tissue. The shift was associated with a partial degradation of the outermost layer of the pit membrane in dogwood (33–45% of the cells examined) but not in peach (3–7% of the cells). Collectively, the data indicate that pectins may be an integral structural element of the pit membrane and that this portion of the cell-wall, along with the underlying amorphous layer, play a major role in forming a barrier to water movement and growth of ice crystals. This barrier allows xylem parenchyma of some species of woody plants to undergo deep supercooling.Abbreviations DTA Differential thermal analysis - HTE high-temperature exotherm - LTE low-temperature exotherm     

The use of lanthanum to characterize cell wall permeability in relation to deep supercooling and extracellular freezing in woody plants: II. Intrageneric comparisons betweenBetula lenta andBetula papyrifera

Summary The permeability and porosity of xylem cell walls are believed to play a major role in defining the ability of a cell or tissue to exhibit deep supercooling. Lanthanum nitrate, was utilized to contrast the permeability of stem tissues inB. lenta, which exhibits deep supercooling, withB. papyrifera, which exhibits equilibrium freezing. Although the two species differed greatiy in their response to low temperature, distribution of lanthanum deposits was quite similar. Primary cell walls of all xylem cell types appeared permeable although lanthanum deposition was patchy. Secondary cell walls of fiber cells were also permeable to lanthanum whereas the secondary wall of vessel elements and xylem parenchyma appeared impermeable to the lanthanum. Pit membranes, in all cell types and the protective layer in xylem parenchyma frequently exhibited deposits of lanthanum. Results of this study indicate that the porosity and permeability of the pit membrane, rather than the entire cell wall may determine the rate of water loss from xylem parenchyma to sites of extracellular ice. If differences exist between the species in the physical structure of these sites, they may explain differences observed in their response to freezing.Abbreviations DTA differential thermal analysis - HTE high temperature exotherm - LTE low temperature exoterm - F fiber cell - V vessel element     

Supercooling of xylem ray parenchyma cells in tropical and subtropical hardwood species

 The freezing behavior of xylem ray parenchyma cells in several woody species, Ficus elastica, F. microcarpa, Mangifera indica, Hibiscus Rosa-sinensis, and Schefflera arboricola, that are native to non-frost tropical and subtropical zones, was investigated by differential thermal analysis (DTA), cryo-scanning electron microscopy (cryo-SEM) and freeze-replica electron microscopy. Although profiles after DTA did not exhibit clear evidence of supercooling in the xylem ray parenchyma cells, electron microscopy revealed that the majority of xylem ray parenchyma cells in all of the woody species examined were supercooled to around –10°C upon freezing temperatures and were not frozen extracellularly. It seems likely that DTA failed to reveal the low temperature exotherm (LTE), that is produced by breakdown of supercooling in the xylem ray parenchyma cells as a consequence of the overlap between the high temperature exotherm and the LTE in each case. The xylem ray parenchyma cells in these woody species were very sensitive to dehydration, and supercooling had, to some extent, a protective effect against freezing injury. It is suggested that the capacity for supercooling of xylem ray parenchyma cells of tropical and subtropical woody species might be the result of inherent structural characteristics, such as rigid cell walls and compact xylem tissues, rather than the result of positive adaptation to freezing temperatures. The present and previous results together indicate that the responses of xylem ray parenchyma cells in a wide variety of hardwood species to freezing temperatures can be explained as a continuum, the specifics of which depend upon the temperatures of the growing conditions. Received: 24 January 1997 / Accepted: 13 May 1997     

Seasonal changes in the freezing behavior of xylem ray parenchyma cells in four boreal hardwood species

The freezing behavior of xylem ray parenchyma cells in several boreal hardwood species, namely, Betula platyphylla, Populus canadensis, P. sieboldii, and Salix sachalinensis, was examined by differential thermal analysis (DTA), cryo-scanning electron microscopy (Cryo-SEM), and freeze-fracture replica electron microscopy. Although DTA profiles of samples harvested in summer and in winter suggested that the xylem ray parenchyma cells in all four species responded to freezing stress by extracellular freezing, Cryo-SEM showed clearly that the xylem ray parenchyma cells in all these species responded to freezing stress by shallow supercooling in summer and by extracellular freezing in winter. It is suggested that DTA failed to reveal the true freezing behavior of xylem ray parenchyma cells because of an overlap of temperature ranges between the high-temperature exotherm and the low-temperature exotherm and/or because of the limited extent of the LTE. The seasonal changes in freezing behavior of xylem ray parenchyma cells in all these boreal species, which are results of seasonal cold acclimation, support the hypothesis that a gradual shift of freezing behavior in xylem ray parenchyma cells from shallow supercooling in hardwood species that grow in tropical zones to extracellular freezing in hardwood species that grow in cold areas might be a result of the evolutionary adaptation of hardwood species to cold climates. Copyright 1999 Academic Press.     

DEVELOPMENT OF THE AMORPHOUS LAYER (PROTECTIVE LAYER) IN XYLEM PARENCHYMA OF CV. GOLDEN DELICIOUS APPLE,CV. LORING PEACH,AND WILLOW

The amorphous layer (AL) in xylem parenchyma may play a prominent role in defining the freezing response of a tissue. A comparative study was undertaken to examine the development of the AL in xylem parenchyma of cv. Golden Delicious apple and cv. Loring peach, which exhibit deep supercooling, and willow, which exhibits only extracellular freezing. AL formation did not begin until secondary wall formation was entirely completed. Deposition of the loose textured AL began at the edges of a pit cavity and spread to the adjacent vessel-parenchyma pit membrane. Upon completion, the AL ensheathed the protoplast of the xylem parenchyma cell and was much thicker in the area of the pit cavity. During AL development, numerous cortical microtubules, RER, and coated vesicles were present in the cytoplasm. Observations indicate that AL development was similar in all 3 species, but differences were found in the time of maturation within an annual ring and AL coloration after staining with toluidine blue O. The latter indicates that compositional differences may exist which may account for the variation in freezing response exhibited by these species.     

High accumulation of soluble sugars in deep supercooling Japanese white birch xylem parenchyma cells

Seasonal changes in the accumulation of soluble sugars in extracellular freezing cortical parenchyma cells and deep supercooling xylem parenchyma cells in Japanese white birch (Betula platyphylla var. japonica) were compared to identify the effects of soluble sugars on the mechanism of deep supercooling, which keeps the liquid state of water in cells under extremely low temperatures for long periods. Soluble sugars in both tissues were analyzed by high-performance liquid chromatography (HPLC), and the concentrations of sugars in cells were estimated by histological observation of occupancy rates of parenchyma cells in each tissue. Relative and equilibrium melting points of parenchyma cells were measured by differential thermal analysis and cryoscanning electron microscopy, respectively. In both xylem and cortical parenchyma cells, amounts of sucrose, raffinose and stachyose increased in winter, but amounts of fructose and glucose exhibited little change throughout the entire year. In addition, no sugars were found to be specific for either tissue. Combined results of HPLC analyses, histological observation and melting point analyses confirmed that the concentration of sugars was much higher in xylem cells than in cortical cells. It is thought that the higher concentration of soluble sugars in xylem cells may contribute to facilitation of deep supercooling in xylem cells by depressing the nucleation temperature.     

CHANGES IN THE ULTRASTRUCTURE OF XYLEM PARENCHYMA CELLS OF PEACH (PRUNUS PERSICA) AND RED OAK (QUERCUS RUBRA) IN RESPONSE TO A FREEZING STRESS

An ultrastructural investigation was conducted of xylem parenchyma cells of peach (Prunus persica [L.] Batsch.) cv. Harbrite and red oak (Quercus rubra L.) in response to a freezing stress. Freezing curves of xylem tissues, as determined by differential thermal analysis, were used to predict temperatures at which both living and dead cells would be observed. Tissues were exposed to low temperatures (-15 to -35 C) and fixed in a frozen state at -10C and at thawing. Current models of the freezing behavior of supercooled plant cells suggest that xylem parenchyma cells behave as individual water droplets. This implies that cells are unresponsive to the presence of low temperature and extracellular ice until internal nucleation triggers lethal, intracellular freezing. For these reasons, deep supercooling has been described as an avoidance mechanism. Results of this study confirmed earlier reports that xylem parenchyma cells freeze as individuals or in small groups. Individual cells, however, did not exhibit a neutral response. Instead, a range of responses was observed that included internal and external vesiculation, deep invaginations of the plasma membrane, and the formation of electron-dense deposits external to the plasmalemma. In general, our observations suggested that the cells responded to a dehydrative stress. Results are discussed in context of the biophysical data associated with deep supercooling phenomena and compared to responses of cells that exhibit extracellular freezing.     

Anti-ice nucleation activity in xylem extracts from trees that contain deep supercooling xylem parenchyma cells

Boreal hardwood species, including Japanese white birch (Betula platyphylla Sukat. var. japonica Hara), Japanese chestnut (Castanea crenata Sieb. et Zucc.), katsura tree (Cercidiphyllum japonicum Sieb. et Zucc.), Siebold’s beech (Fagus crenata Blume), mulberry (Morus bombycis Koidz.), and Japanese rowan (Sorbus commixta Hedl.), had xylem parenchyma cells (XPCs) that adapt to subfreezing temperatures by deep supercooling. Crude extracts from xylem in all these trees were found to have anti-ice nucleation activity that promoted supercooling capability of water as measured by a droplet freezing assay. The magnitude of increase in supercooling capability of water droplets in the presence of ice-nucleation bacteria, Erwinia ananas, was higher in the ranges from 0.1 to 1.7 °C on addition of crude xylem extracts than freezing temperature of water droplets on addition of glucose in the same concentration (100 mosmol/kg). Crude xylem extracts from C. japonicum provided the highest supercooling capability of water droplets. Our additional examination showed that crude xylem extracts from C. japonicum exhibited anti-ice nucleation activity toward water droplets containing a variety of heterogeneous ice nucleators, including ice-nucleation bacteria, not only E. ananas but also Pseudomonas syringae (NBRC3310) or Xanthomonas campestris, silver iodide or airborne impurities. However, crude xylem extracts from C. japonicum did not affect homogeneous ice nucleation temperature as analyzed by emulsified micro-water droplets. The possible role of such anti-ice nucleation activity in crude xylem extracts in deep supercooling of XPCs is discussed.     

Vascular defense responses in rice: peroxidase accumulation in xylem parenchyma cells and xylem wall thickening.

The rice bacterial blight pathogen Xanthomonas oryzae pv. oryzae is a vascular pathogen that elicits a defensive response through interaction with metabolically active rice cells. In leaves of 12-day-old rice seedlings, the exposed pit membrane separating the xylem lumen from the associated parenchyma cells allows contact with bacterial cells. During resistant responses, the xylem secondary walls thicken within 48 h and the pit diameter decreases, effectively reducing the area of pit membrane exposed for access by bacteria. In susceptible interactions and mock-inoculated controls, the xylem walls do not thicken within 48 h. Xylem secondary wall thickening is developmental and, in untreated 65-day-old rice plants, the size of the pit also is reduced. Activity and accumulation of a secreted cationic peroxidase, PO-C1, were previously shown to increase in xylem vessel walls and lumen. Peptide-specific antibodies and immunogold-labeling were used to demonstrate that PO-C1 is produced in the xylem parenchyma and secreted to the xylem lumen and walls. The timing of the accumulation is consistent with vessel secondary wall thickening. The PO-C1 gene is distinct but shares a high level of similarity with previously cloned pathogen-induced peroxidases in rice. PO-C1 gene expression was induced as early as 12 h during resistant interactions and peaked between 18 and 24 h after inoculation. Expression during susceptible interactions was lower than that observed in resistant interactions and was undetectable after infiltration with water, after mechanical wounding, or in mature leaves. These data are consistent with a role for vessel secondary wall thickening and peroxidase PO-C1 accumulation in the defense response in rice to X. oryzae pv. oryzae.     

Immunogold localization of pectins and glycoproteins in tissues of peach with reference to deep supercooling

Living xylem tissues and floral buds of several species of woody plants survive exposure to freezing temperatures by deep supercooling. A barrier to water loss and the growth of ice crystals into cells is considered necessary for deep supercooling to occur. Pectins, as a constituent of the cell wall, have been implicated in the formation of this barrier. The present study examined the distribution of pectin in xylem and floral bud tissues of peach (Prunus persica). Two monoclonal antibodies (JIM5 and JIM7) that recognize homogalacturonic sequences with varying degrees of esterification were utilized in conjunction with immunogold electron microscopy. Results indicate that highly esterified epitopes of pectin, recognized by JIM7, were the predominant types of pectin in peach and were uniformly distributed throughout the pit membrane and primary cell walls of xylem and floral bud tissues. In contrast, un-esterified epitopes of pectin, recognized by JIM5, were confined to the outer surface of the pit membrane in xylem tissues. In floral buds, these epitopes were localized in middle lamellae, along the outer margin of the cell wall lining empty intercellular spaces, and within filled intercellular spaces. JIM5 labeling was more pronounced in December samples than in July/August samples. Additionally, epitopes of an arabinogalactan protein, recognized by JIM14, were confined to the amorphous layer of the pit membrane. The role of pectins in freezing response is discussed in the context of present theory and it is suggested that pectins may influence both water movement and intrusive growth of ice crystals at freezing temperatures.     

梅花(Prunus mume Sieb et Zucc)远缘杂种及其亲本的差热分析与冻害关系的研究

用差热分析(Differential thermal analysis: DTA)研究了山桃(Prunus davidiana)、杏(P. armeniaca)、青岛“粉红梅”(P.mume cv.'Fenhong Mei,)、“小绿萼”(P.mume cv.'Small Green Calyx')及其种问杂种“小绿萼”梅×山桃、青岛“粉红梅”×杏和杏×青岛“粉红梅”的低温放热(Low temperature exotherm)与冻害关系,以及皮部和木质部的冰冻类型(Freezing pattern)。在差热分析中,观察到亲本和杂种的木质部都有二次放热现象。低温放热后,引起木质部和髓射线薄壁细胞死亡,原生质膜透性急剧增加。在杂种与亲本之间,存在着明显的差异。分离的皮部却只出现一次高温放热(High temperature exotherm)。高温放热是与冻害无关的。文末讨论了梅花及其杂种在北京越冬的主要障碍及有关栽培措施。     

Deep Supercooling in Most Tissues of Wintering Sasa senanensis and Its Mechanism in Leaf Blade Tissues

Cold hardiness of leaf blades, leaf sheaths, culms, rhizomes, and leaf buds in wintering Sasa senanensis (Fr. et Sav.) Rehder, a dwarf bamboo, was studied paying special attention to the types of resistance mechanisms which were determined with differential thermal analysis. Coincidence of LT₂₅ (lethal temperature at which 25% of the tissues are injured) with the initiation temperature of LTE (low temperature exotherm) suggested that all of these tissues described above owe their cold hardiness mechanism mostly to deep supercooling. Deep supercooling in leaf blades was also substantiated with microscopic observations, suggesting that the units of supercooling were minute tissues compartmentalized by longitudinal and cross veins. It was also shown that cooling rates and storage of shoots at −5°C for 1 to 5 days in the ice-inoculated state did not greatly affect the supercooling ability of leaf blades. Sasa senanensis seemed to exhibit a unique strategy against prolonged subzero temperature, and its leaves would be a good system for the study on mechanisms of deep undercooling in plants.     

Chlorophyll fluorescence monitoring of freezing point exotherms in leaves.

Following supercooling prompt chlorophyll fluorescence and delayed fluorescence from leaves undergo transients simultaneous with the freezing point exotherm. The degree of supercooling and, hence, the temperature at which the exotherm occurs is dependent upon the leaf water content.Winter wheat leaves (Triticum aestivum L.) that had the lowest water content (hardened “Kharkov”) supercooled to a greater degree than those leaves with a higher water content (hardened “Rescue” and unhardened “Kharkov” or “Rescue”).Seeding the leaves with ice increased the temperature at which the exotherm occurred and decreased the difference between varities but not between hardened and unhardened material. Our results suggest that freeze-avoidance via supercooling may be one mechanism in winter wheat for withstanding subfreezing temperatures.     

Gene expression associated with increased supercooling capability in xylem parenchyma cells of larch (Larix kaempferi)

Xylem parenchyma cells (XPCs) in larch adapt to subfreezing temperatures by deep supercooling, while cortical parenchyma cells (CPCs) undergo extracellular freezing. The temperature limits of supercooling in XPCs changed seasonally from -30 degrees C during summer to -60 degrees C during winter as measured by freezing resistance. Artificial deacclimation of larch twigs collected in winter reduced the supercooling capability from -60 degrees C to -30 degrees C. As an approach to clarify the mechanisms underlying the change in supercooling capability of larch XPCs, genes expressed in association with increased supercooling capability were examined. By differential screening and differential display analysis, 30 genes were found to be expressed in association with increased supercooling capability in XPCs. These 30 genes were categorized into several groups according to their functions: signal transduction factors, metabolic enzymes, late embryogenesis abundant proteins, heat shock proteins, protein synthesis and chromatin constructed proteins, defence response proteins, membrane transporters, metal-binding proteins, and functionally unknown proteins. All of these genes were expressed most abundantly during winter, and their expression was reduced or disappeared during summer. The expression of all of the genes was significantly reduced or disappeared with deacclimation of winter twigs. Interestingly, all but one of the genes were expressed more abundantly in the xylem than in the cortex. Eleven of the 30 genes were thought to be novel cold-induced genes. The results suggest that change in the supercooling capability of XPCs is associated with expression of genes, including genes whose functions have not been identified, and also indicate that gene products that have been thought to play a role in dehydration tolerance by extracellular freezing also have a function by deep supercooling.     

A xylem sap retrieval pathway in rice leaf blades: evidence of a role for endocytosis?

The structure and transport properties of pit membranes at the interface between the metaxylem and xylem parenchyma cells and the possible role of these pit membranes in solute transfer to the phloem were investigated. Electron microscopy revealed a fibrillar, almost tubular matrix within the pit membrane structure between the xylem vessels and xylem parenchyma of leaf blade bundles in rice (Oryza sativa). These pits are involved primarily with regulating water flux to the surrounding xylem parenchyma cells. Vascular parenchyma cells contain large mitochondrial populations, numerous dictyosomes, endomembrane complexes, and vesicles in close proximity to the pit membrane. Taken collectively, this suggests that endocytosis may occur at this interface. A weak solution of 5,6-carboxyfluorescein diacetate (5,6-CFDA) was applied to cut ends of leaves and, after a minimum of 30 min, the distribution of the fluorescent cleavage product, 5,6-carboxyfluorescein (5,6-CF), was observed using confocal microscopy. Cleavage of 5,6-CFDA occurred within the xylem parenchyma cells, and the non-polar 5,6-CF was then symplasmically transported to other parenchyma elements and ultimately, via numerous pore plasmodesmata, to adjacent thick-walled sieve tubes. Application of Lucifer Yellow, and, separately, Texas Red-labelled dextran (10 kDa) to the transpiration stream, confirmed that these membrane-impermeant probes could only have been offloaded from the xylem via the xylem vessel-xylem parenchyma pit membranes, suggesting endocytotic transmembrane transfer of these membrane-impermeant fluorophores. Accumulation within the thick-walled sieve tubes, but not in thin-walled sieve tubes, confirms the presence of a symplasmic phloem loading pathway, via pore plasmodesmata between xylem parenchyma and thick-walled sieve tubes, but not thin-walled sieve tubes.     

Mechanism of water stress-induced xylem embolism

We investigated the hypothesis that water stress-induced xylem embolism is caused by air aspirated into functional vessels from neighboring embolized ones (e.g. embolized by physical damage) via pores in intervessel pit membranes. The following experiments with sugar maple (Acer saccharum Marsh.) support the hypothesis. (a) Most vessels in dehydrating stem segments embolized at xylem pressures < −3 megapascals; at this point the pressure difference across intervessel pits between air-filled vessels at the segment's ends and internal water-filled vessels was >3 megapascals. This same pressure difference was found to be sufficient to force air across intervessel pits from air injection experiments of hydrated stem segments. This suggests air entry at pits is causing embolism in dehydrating stems. (b) Treatments that increased the permeability of intervessel pits to air injection also caused xylem to embolize at less negative xylem pressures. Permeability was increased either by perfusing stems with solutions of surface tension below that of water or by perfusion with a solution of oxalic acid and calcium. The mechanism of oxalic-calcium action on permeability is unknown, but may relate to the ability of oxalate to chelate calcium from the pectate fraction of the pit membrane. (c) Diameter of pores in pit membranes measured with the scanning electron microscope were within the range predicted by hypothesis (≤0.4 micrometer).     

The mechanism of freezing injury in xylem of winter apple twigs

In acclimated winter twigs of Haralson apple (Pyrus Malus L.), a lag in temperature during cooling at a constant rate was observed at about −41 C by differential thermal analysis. The temperature at which this low temperature exotherm occurred was essentially unaffected by the cooling rate. During thawing there was no lag in temperature (endotherm) near the temperature at which the low temperature exotherm occurred, but upon subsequent refreezing the exotherm reappeared at a somewhat higher temperature when twigs were rewarmed to at least −5 C before refreezing. These observations indicate that a small fraction of water may remain unfrozen to as low as −42 C after freezing of the bulk water in stems. The low temperature exotherm was not present in twigs freeze-dried to a water content below 8.5% (per unit fresh weight), but it reappeared when twigs were rehydrated to 20% water. When freeze-dried twigs were ground to a fine powder prior to rehydration, no exotherm was observed. Previous work has shown that the low temperature exotherm arises from xylem and pith tissues, and that injury to living cells in these tissues invariably occurs only when twigs are cooled below, but not above the temperature of the low temperature exotherm. This study revealed that the low temperature exotherm resulted from the freezing of a water fraction, that the freezing of this water was independent of the freezing of the bulk water, that the exotherm was associated with some gross structural feature but not the viability of the tissue, and that injury to living cells in the xylem and pith was closely and perhaps causally related to the initial freezing of this water.     

Anti-ice nucleation activity in xylem extracts from trees that contain deep supercooling xylem parenchyma cells

Boreal hardwood species, including Japanese white birch (Betula platyphylla Sukat. var. japonica Hara), Japanese chestnut (Castanea crenata Sieb. et Zucc.), katsura tree (Cercidiphyllum japonicum Sieb. et Zucc.), Siebold’s beech (Fagus crenata Blume), mulberry (Morus bombycis Koidz.), and Japanese rowan (Sorbus commixta Hedl.), had xylem parenchyma cells (XPCs) that adapt to subfreezing temperatures by deep supercooling. Crude extracts from xylem in all these trees were found to have anti-ice nucleation activity that promoted supercooling capability of water as measured by a droplet freezing assay. The magnitude of increase in supercooling capability of water droplets in the presence of ice-nucleation bacteria, Erwinia ananas, was higher in the ranges from 0.1 to 1.7 °C on addition of crude xylem extracts than freezing temperature of water droplets on addition of glucose in the same concentration (100 mosmol/kg). Crude xylem extracts from C. japonicum provided the highest supercooling capability of water droplets. Our additional examination showed that crude xylem extracts from C. japonicum exhibited anti-ice nucleation activity toward water droplets containing a variety of heterogeneous ice nucleators, including ice-nucleation bacteria, not only E. ananas but also Pseudomonas syringae (NBRC3310) or Xanthomonas campestris, silver iodide or airborne impurities. However, crude xylem extracts from C. japonicum did not affect homogeneous ice nucleation temperature as analyzed by emulsified micro-water droplets. The possible role of such anti-ice nucleation activity in crude xylem extracts in deep supercooling of XPCs is discussed.     

Effect of sugars and amino acids on membrane potential in two clones of sugarcane

Sugarcane (Saccharum officinarum L.) leaf parenchyma cells bathed in 1X solution maintained an average membrane potential of −135 millivolts in the dark. No difference in membrane potential was found between clones 51 NG 97 and H50 7209. An electrogenic pump appears to contribute to membrane potential in these cells. Sugars (25 millimolar) added externally caused the following membrane potential depolarizations (in millivolts) in clone 51 NG 97: glucose, 18 ± 4; galactose, 24 ± 7; 3-O-methylglucose, 10 ± 4; sucrose, 22 ± 3; fructose, 21 ± 7; raffinose, 9 ± 3; mannitol, 0; lactose, 0; melibiose, 0; and 1-O-methyl-α-galactose, 0. Glycine (25 millimolar) and serine (10 millimolar) caused depolarizations of 47 ± 7 and 23 ± 2 millivolts, respectively. Depolarization shows saturation kinetics with respect to glucose concentration, with a K_m of 3 to 6 millimolar. The metabolic inhibitors KCN and salicyl hydroxamic acid together caused depolarization of the membrane potential and greatly inhibited depolarization by 25 millimolar glucose and 25 millimolar raffinose. In a series of substitution experiments, glucose (25 millimolar) caused almost total inhibition of depolarization by raffinose, sucrose, and 3-O-methylglucose (all 25 millimolar), but only partial inhibition of depolarization to 25 millimolar glycine. Glycine (25 millimolar), also, only partially inhibited depolarization by 25 millimolar glucose. Total depolarization to 25 millimolar glycine and 25 millimolar glucose was comparable to the amount of depolarization of membrane potential caused by 1 millimolar KCN plus 1 millimolar salicyl hydroxamic acid. The results are consistent with a co-transport mechanism of membrane transport, with sugars and amino acids being transported by separate carrier systems.     

Cold Acclimation in Genetically Related (Sibling) Deciduous and Evergreen Peach (Prunus persica [L.] Batsch): I. Seasonal Changes in Cold Hardiness and Polypeptides of Bark and Xylem Tissues

Seasonal patterns of proteins and of cold hardiness were characterized in bark and xylem tissues of genetically related (sibling) deciduous and evergreen peach (Prunus persica [L.] Batsch). In contrast with deciduous trees, which entered endodormancy and abscised leaves in the fall, evergreen trees retained their leaves and exhibited shoot elongation under favorable environmental conditions. A successive increase in the cold hardiness of bark and xylem was observed during the fall in both genotypes. This was followed by a subsequent decrease from midwinter to spring. Xylem tissue in both genotypes exhibited deep supercooling and a significant correlation (r = 0.99) between the midpoint of the low-temperature exotherm and the subzero temperature at which 50% injury occurred (assessed by electrolyte leakage) was noted. The maximum hardiness level attained in deciduous trees was more than twofold that of evergreens. Seasonal pattern of proteins from bark and xylem of the sibling genotypes was characterized by one-dimensional sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Among other qualitative and quantitative changes, accumulation of a 19-kilodalton polypeptide in the bark of both genotypes was observed during fall followed by a decrease in spring. This polypeptide accumulated to higher levels in the deciduous peach compared with the evergreen. Additionally, a 16-kilodalton protein exhibited the same pattern in deciduous trees but not in the evergreen trees. Both the 19- and a 16-kilodalton bark proteins conform to the criteria of a bark storage protein. The relationship of seasonal changes in protein to cold hardiness and dormancy in these genetically related peach genotypes is discussed.