OSMOTIC ADJUSTMENT AND DYNAMIC CHANGES IN DISTRIBUTION OF LOW MOLECULAR WEIGHT SOLUTES BETWEEN CELLULAR COMPARTMENTS OF CARROT AND BEET ROOT CELLS EXPOSED TO SALINITY

Carrot cells (Daucus carota L.) in suspension culture exposed to medium containing 150 mM NaCl plasmolyzed immediately and deplasmolyzed within 35 to 40 hr. Three days after exposure to NaCl the cells resumed proliferation. Accommodation to salinity and renewal of growth was accompanied by absorption of Na⁺ from the external medium. On completion of deplasmolysis, K⁺ concentration in the cytosol doubled and Na⁺ concentration approximated that of K⁺. The vacuolar K⁺ concentration was practically unchanged while Na⁺ accumulated to a concentration double that of K⁺. Cl^−- accumulation started later and eventually exceeded that of Na⁺ plus K⁺. Malate was redistributed during accommodation to salinity and eventually returned to its initial level. Amino acid content in the cytosol increased fivefold, while in the vacuole it remained unchanged. These results show that: 1) recovery from osmotic shock requires absorption of easily penetrating solute, mainly Na⁺; 2) distribution of solutes, absorbed or synthesized in cells exposed to salinity, is a dynamic process; 3) cells could grow and proliferate in high NaCl content in the cytosol; 4) red beet root cells grown in the presence of NaCl contain higher cytoplasmic Na⁺ than K⁺; and 5) during adjustment to salinity small spherical carrot cells survive the osmotic shock and do not show any detectable damage.     

Differences in efficient metabolite management and nutrient metabolic regulation between wild and cultivated barley grown at high salinity

Physiological and biochemical responses of Hordeum maritimum and H. vulgare to salt stress were studied over a 60‐h period. Growth at increasing salinity levels (0, 100, 200 and 300 mM NaCl) was assessed in hydroponic culture. H. maritimum was shown to be a true halophyte via its typical behaviour at high salinity. Shoot growth of cultivated barley was gradually reduced with increasing salinity, whereas that of wild barley was enhanced at 100 and 200 mm NaCl then slightly reduced at 300 mM NaCl. The higher salt tolerance of H. maritimum as compared to H. vulgare was due to its higher capacity to maintain cell turgor under severe salinity. Furthermore, H. maritimum exhibited fine regulation of Na⁺ transport from roots to shoots and, unlike H. vulgare, it accumulated less Na⁺ in shoots than in roots. In addition, H. maritimum can accumulate more Na⁺ than K⁺ in both roots and shoots without the appearance of toxicity symptoms, indicating that Na⁺ was well compartmentalized within cells and substituted K⁺ in osmotic adjustment. The higher degree of salt tolerance of H. maritimum is further demonstrated by its economic strategy: at moderate salt treatment (100 mm NaCl), it used inorganic solutes (such as Na⁺) for osmotic adjustment and kept organic solutes and a large part of the K⁺ for metabolic activities. Indeed, K⁺ use efficiency in H. maritimum was about twofold that in H. vulgare; the former started to use organic solutes as osmotica only at high salinity (200 and 300 mm NaCl). These results suggest that the differences in salt tolerance between H. maritimum and H. vulgare are partly due to (i) differences in control of Na⁺ transport from roots to shoots, and (ii) H. maritimum uses Na⁺ as an osmoticum instead of K⁺ and organic solutes. These factors are differently reflected in growth.     

Investigations on the growth and metabolism of cultured explants of Daucus carota

Summary The responses of carrot explants to various growth-promoting agents and to certain trace elements with which they interact have been investigated. A great range in the metabolic behavior of the tissue may be brought about in this way. The responses to the exogenously applied substances are described in terms of the growth of the carrot explants in fresh weight and number of cells and also in terms of their metabolism, as shown by the final content and composition of the non-protein N compounds, by the relations between protein and non-protein (alcohol-soluble) N and by the content of nucleic acid in the cultured tissue.The growth-promoting agents employed consisted of (1) the balanced complex of factors found in coconut milk, (2) an active isolate from Aesculus (AF_aesc), which is one of a class of growth factors (AF₁) that interact with inositol (AF₁+inositol) and which in this sense comprise growth-promoting System I, (3) the substance zeatin (Zeat) which is typical of a class of active factors (AF₂) that interact with indoleacetic acid (AF₂+IAA) and which, therefore, function as a growth promoting complex termed System II in the culture of carrot tissue.The carrot explants stimulated by coconut milk grew better than those stimulated by the other combinations of growth factors and they converted their soluble N more effectively to protein. The growth, whether it was induced by coconut milk or by System I or II, and other specific effects attributable to the growth factors employed were markedly affected also by the elements iron and molybdenum.The carrot explants that had responded to coconut milk emphasized alanine in their soluble, non-protein, nitrogenous pool, whereas those subjected to the active components of System I or of System II as clearly emphasized glutamine as the prominent non-protein, nitrogen-rich compound.The partial effects due to the component parts of System I (AF_aesc or inositol) and to the component parts of System II (Zeat. or IAA), as these interacted also with iron and molybdenum in an otherwise trace element free basal medium (B ^**), revealed a pattern of interlocking effects, due to trace elements and to growth factors, upon the metabolism (especially the nitrogen metabolism) of the aseptically cultured carrot explants. These effects show that the individual growth factors do not act alone and that their implications are far reaching. The interactions between growth promoting Systems I and II and their component parts, with each other, with various environmental factors, and especially with trace elements constitute a network, or a matrix, of parameters that will merit further investigation to reveal all that is required to control the growth and metabolism of carrot cells.This investigation was supported by PHS Research Grant No. GM 09609 to one of us (F.C.S.) from the National Institutes of Health.The collaboration with Dr. K. V. N. Rao, later made possible by this grant, was first arranged under the terms of a Fulbright travel grant and the award of a Smith-Mundt stipend.     

The Potassium Requirement for Growth and Embryogenesis in Wild Carrot Suspension Cultures

A requirement for potassium for growth and forembryogenesis in suspension cultures of wild carrot (Daucus carota L.) was demonstrated. The concentration of K⁺ required for maximal growth (1 mM) was less than that required for maximal embryogenesis (20 mM). Neither Na⁺ nor NH₄⁺ could replace K⁺. Ammonium ion enhanced embryogenesis when K⁺ was present at suboptimal levels greater than 1 mM. Nitrogen sources strongly influenced growth and embryogenesis, but the effects of nitrogen were separable from those of K⁺. Subline differences were noted. Subline CSC-29 produced nearly half the maximum embryo number in 1 mM K⁺ while CSC-31 produced no embryos at that K⁺ concentration. Growth of CSC-29 was slightly repressed by Na⁺, but no more than by similarconcentrations of K⁺. Growth of CSC-31 in 1 mM K⁺ was strongly repressed by Na⁺. Embryogenesis in CSC-29 was unaffected by Na⁺. In CSC-31, Na⁺ repressed embryogenesis at lower concentrations of K⁺.     

Solute Accumulation in Tobacco Cells Adapted to NaCl

Cells of Nicotiana tabacum L. var Wisconsin 38 adapted to NaCl (up to 428 millimolar) which have undergone extensive osmotic adjustment accumulated Na⁺ and Cl⁻ as principal solutes for this adjustment. Although the intracellular concentrations of Na⁺ and Cl⁻ correlated well with the level of adaptation, these ions apparently did not contribute to the osmotic adjustment which occurred during a culture growth cycle, because the concentrations of Na⁺ and Cl⁻ did not increase during the period of most active osmotic adjustment. The average intracellular concentrations of soluble sugars and total free amino acids increased as a function of the level of adaptation; however, the levels of these solutes did not approach those observed for Na⁺ and Cl⁻. The concentration of proline was positively correlated with cell osmotic potential, accumulating to an average concentration of 129 millimolar in cells adapted to 428 millimolar NaCl and representing about 80% of the total free amino acid pool as compared to an average of 0.29 millimolar and about 4% of the pool in unadapted cells. These results indicate that although Na⁺ and Cl⁻ are principal components of osmotic adjustment, organic solutes also may make significant contributions.     

Solutes Involved in Osmotic Adjustment to Increasing Salinity in Suspension Cells of Alternanthera philoxeroides Griseb

Cell recovery from osmotic stress was studied in suspension cell cultures from Alternanthera philoxeroides [Mart.] Griseb. Changes in different classes of cellular solutes were measured after cells were transferred from 0 to 200 mM NaCl (high salt) to obtain an integrated picture of the solute pools involved in osmotic adjustment. By 2 h, cellular [Na⁺] and [Cl⁻] had increased several-fold, potentially accounting for the osmotic adjustment that produced a rapid recovery of cell turgor. There was a four-fold increase in the concentration of quaternary ammonium compounds (QAC) by 12 h and a slower increase for several days afterward. Betaine aldehyde dehydrogenase (BADH) is required for synthesis of glycine betaine, a QAC produced by a range of organisms in response to osmotic stress. Western-blot analysis for BADH suggested that glycine betaine was a significant component of the QAC solutes. The amount of BADH was generally similar at different sampling times for control and high salt cells, unlike previous reports of stimulation by osmotic stress in intact plants of some species. Between 3 and 7 days after cell transfer to high salt, other organic solutes increased in concentration and [Na⁺] and [Cl⁻] decreased. In A. philoxeroides, high [Na⁺] and [Cl⁻] produce rapid osmotic adjustment but organic solutes apparently replace these potentially harmful inorganic ions after the recovery of turgor.     

Evidence for a sodium-dependent proline and glycine-betaine uptake in the cyanobacterium <Emphasis Type="Italic">Nostoc muscorum</Emphasis>

The cyanobacterium Nostoc muscorum is able to utilized proline and glycine-betaine as a nitrogen source under unstressed growth conditions. This cyanobacterium when grow in modified Chu No. 10 medium (without Na⁺) unable to utilized proline and glycine-betaine as a nitrogen source. Spontaneously occurring mutant clones defective in Na⁺ transport (Na⁺-R) was isolated and analyzed for proline and glycine-betaine utilization. The mutant phenotype showed normal heterocyst frequency and nitrogenase activity even in the medium containing 1 mM proline or 1 mM glycine-betaine, indicates the role of Na⁺ for proline/glycine-betaine uptake. The Na⁺-R mutant showed 100% survival at pH 11 and was simultaneously able to uptake and utilize proline/glycine-betaine at higher alkaline pH. This indicates that proline and glycinebetaine uptake systems are more efficient at higher alkaline pH. Since, the hypersaline environments are rich in Na⁺ contents and have alkaline pH, therefore it is suggested that the origin and evolution of specific compatible solutes may not depend only on the osmoregulatory role they play, but also on the other ecological factors operating simultaneously in the organism’s niche.     

Investigations on the growth and metabolism of cultured explants of Daucus carota

Summary The induction and maintenance of growth in small, standard explants of carrot root exposed to a trace-element-free basal nutrient medium (B ^**) have been investigated. The organic growth factors that induce the growth are complex as represented by a trace-element-limited coconut-milk preparation (CM^**) or the component parts of distinct growth promoting systems mediated by inositol or by 3-indoleacetic acid (IAA). In System I inositol interacts with growth factors from Aesculus, of which a known example is an IAA-rhamnoseglucose compound; in System II IAA interacts with adenyl compounds, of which zeatin is a known example. But the organic growth-promoting substances also interact with trace elements; therefore, the effects of the component parts of the growth promoting systems, separately and in combination, have been investigated with respect to their interactions with Mo, with Fe and also with these trace elements in combination. The growth so induced has been measured in terms of the fresh weight of the explants, the number and average size of their cells, as well as their total content of protein and nucleic acids. The metabolic responses of the cultured explants to the combined effects of growth factors and of trace elements are also described in terms of the principal soluble nitrogenous compounds. Each basis is informative, and suitable graphical devices are adopted so that the interactions of the multivariate factors that affect the behavior of the cultured tissue may be seen with respect to the various parameters selected. The study shows the range of complexity to be understood before the exogenous factors that determine cell growth and metabolism are both known and controllable; it also shows the limitations when attention is directed, simplistically, to one parameter or to the controlling influence of any single factor, or class, of growth factors.This investigation was supported by PHS Research Grant No. GM 09 609 to one of us (F. C. S.) from the National Institutes of Health, Bethesda, Maryland. The collaboration with Dr. K. V. N. Rao, later made possible by this grant, was first arranged under the terms of a Fulbright travel grant and the award of a Smith-Mundt stipend. Other assistance and facilities employed in the investigation depended upon research support made available through the Director of Research, New York State College of Agriculture.     

Salt tolerance in rice in vitro: Implication of accumulation of Na+, K+ and proline

The implication of accumulation of both inorganic (Na⁺, K⁺) and organic (proline) solutes were evaluated in unadapted and NaCl-adapted callus of a salt-sensitive (Basmati 370) and a salt-tolerant (SR-26B) cultivar of rice (Oryza sativa L.) after a NaCl shock. Accumulation of Na⁺,K⁺ and/or proline in callus was co relatable and the relative presence of these components in tissues after shock treatment was found to be important factors to support differential regrowth capacities of the shock treated calluses. Presence or retention of K⁺ in rice callus was a key factor for salt tolerance as it was observed to be positively correlated with growth in both the varieties. The results indicated that K⁺ was the first candidate to counteract the negative water potential of outside milieu, while proline was probably the last metabolic device that rice calluses opted for when exposed to salt stress.     

A laser ablation technique maps differences in elemental composition in roots of two barley cultivars subjected to salinity stress

In saline soils, high levels of sodium (Na⁺) and chloride (Cl^?) ions reduce root growth by inhibiting cell division and elongation, thereby impacting on crop yield. Soil salinity can lead to Na⁺ toxicity of plant cells, influencing the uptake and retention of other important ions [i.e. potassium (K⁺)] required for growth. However, measuring and quantifying soluble ions in their native, cellular environment is inherently difficult. Technologies that allow in situ profiling of plant tissues are fundamental for our understanding of abiotic stress responses and the development of tolerant crops. Here, we employ laser ablation‐inductively coupled plasma‐mass spectrometry (LA‐ICP‐MS) to quantify Na, K and other elements [calcium (Ca), magnesium (Mg), sulphur (S), phosphorus (P), iron (Fe)] at high spatial resolution in the root growth zone of two genotypes of barley (Hordeum vulgare) that differ in salt‐tolerance, cv. Clipper (tolerant) and Sahara (sensitive). The data show that Na⁺ was excluded from the meristem and cell division zone, indicating that Na⁺ toxicity is not directly reducing cell division in the salt‐sensitive genotype, Sahara. Interestingly, in both genotypes, K⁺ was strongly correlated with Na⁺ concentration, in response to salt stress. In addition, we also show important genetic differences and salt‐specific changes in elemental composition in the root growth zone. These results show that LA‐ICP‐MS can be used for fine mapping of soluble ions (i.e. Na⁺ and K⁺) in plant tissues, providing insight into the link between Na⁺ toxicity and root growth responses to salt stress.     

Extracts from Yeast and Carrot Roots Enhance Maize Performance under Seawater-Induced Salt Stress by Altering Physio-Biochemical Characteristics of Stressed Plants

Damage to plant productivity due to soil salinity is a major agricultural problem, necessitating the development of effective salinity management measures. Here, we sought the potential effects of yeast and carrot extracts, and their associated mechanisms in the alleviation of seawater-induced salt stress in maize. Pretreatment of maize seeds with yeast or carrot extract provided maize plants with enormous abilities in reducing growth inhibition and biomass loss when exposed to seawater. The better growth performance of yeast extract- and carrot extract-primed plants under saline conditions coincided with improved protection of the photosynthetic pigments, chlorophylls and carotenoids. The primed plants also restricted Na⁺ accumulation in both roots and shoots while maintaining a higher K⁺ content and lower Na⁺/K⁺ ratio when compared with that of non-primed plants. Yeast extract and carrot extract also potentiated salt tolerance mechanisms by accelerating the production of osmolytes, as evidenced by accumulating levels of total free amino acids and soluble sugars, especially in the roots of primed plants during salinity. The enhanced levels of ascorbic acid and phenolic compounds, and the heightened activities of reactive oxygen species-detoxifying enzymes superoxide dismutase, catalase, and ascorbate peroxidase with concurrent reduction of lipid peroxidation in the leaves of primed plants clearly indicated a positive impact of yeast extract- and carrot extract-priming on the antioxidant system of maize under salt stress. Our results together suggest decisive roles of yeast extract and carrot extract in the management of salt-induced adverse effects in economically important maize, and perhaps other crops.

     

Differential effects of sodium ions on motility in the homoacetogenic bacteriaAcetobacterium woodii andSporomusa sphaeroides

The strictly anaerobic homoacetogenic bacteria Acetobacterium woodii and Sporomusa sphaeroides differ with respect to their energy metabolism. Since growth as well as acetate and ATP formation of A. woodii is strictly dependent on Na⁺, but that of S. sphaeroides is not, the question arose whether these organisms also use different coupling ions for mechanical work, i.e. flagellar rotation. During growth on fructose in the presence of Na⁺ (50 mM), cells of A. woodii were vigorously motile, as judged by light microscopy. At low Na⁺ concentrations (0.3 mM), the growth rate decreased by only 15%, but the cells were completely non-motile. Addition of Na⁺ to such cultures restored motility instantaneously. Motility, as determined in swarm agar tubes, was strictly dependent on Na⁺; Li⁺, but not K⁺ partly substituted for Na⁺. Of the amilorides tested, phenamil proved to be a specific inhibitor of the flagellar motor of A. woodii. Growth and motility of S. sphaeroides was neither dependent on Na⁺ nor inhibited by amiloride derivatives. These results indicate that flagellar rotation is driven by Δμ_Na ⁺ in A. woodii, but by Δμ_H ⁺ in S. sphaeroides. Received: 30 May 1995 / Accepted: 31 August 1995     

Interactions between growth, Cl− and Na+ uptake, and water relations of plants in saline environments. I. Slightly vacuolated cells

Abstract. Slightly vacuolated cells, i.e. microalgae and meristematic cells of vascular plants, maintain low Cl^? and Na⁺ concentrations even when exposed to a highly saline environment. The factors regulating the internal ion concentration are the relative rate of volume expansion, the membrane permeability to ions, the electrical potential, and the active ion fluxes. For ion species which are not actively transported, a formula is developed which relates the internal concentration to the rate of expansion of cell volume, the permeability of membranes to that ion, and the electrical potential. For example, when the external concentration of Cl^? is high, and Cl^? influx is probably mainly passive, the formula predicts that rapid growth keeps the internal Cl^? concentration lower than that in a non-growing cell with the same electrical potential; this effect is substantial if the plasmalemma has a low permeability to Cl^?. For ion species which are actively transported, the rate of pumping must be considered. For instance Na⁺ concentrations are kept low mainly by an efficient Na⁺ extrusion pump which works against the electric field across the membrane. The requirement for Na⁺ extrusion is related to the external Na⁺ concentration, the rate of expansion of cell volume, the membrane permeability, and the electrical potential. It is possible that microalgae have a more positive electrical potential than many other plant cells; if so, requirements for high rates of active Na⁺ extrusion will be lower. The required rates of Na⁺ extrusion are lower during rapid growth, provided that the permeability of the plasmalemma to Na⁺ is low. The energy required for the regulation of Cl^? and Na⁺ concentrations is low, especially in rapidly expanding cells where Na⁺ extrusion requires only 1–2% of the energy normally produced in respiration. The exclusion of these ions, however, must be accompanied by the synthesis of enough organic compounds to provide adequate osmotic solutes for the increases in volume accompanying growth. This process reduces the substrates available for respiration and synthesis of cell constituents, but the reduction is not prohibitively large—even for cells growing in 750 mol m^?3 NaCl, the carbohydrate accumulated as osmotic solute is only 10% of that consumed in respiration.     

Reversed transport of amino acids in Ehrlich cells

Gramicidin induces a marked Na⁺-dependent efflux of amino acids from Ehrlich cells. In absence of Na⁺, gramicidin does not alter the efflux. In presence of gramicidin, glycine efflux is inhibited by methionine and less so by leucine. Glycine efflux caused by HgCl₂ is neither Na⁺ dependent nor inhibitable by amino acids. Neither efflux of inositol which is transported by an Na⁺-dependent route, nor efflux of several other solutes which are transported by Na⁺-independent routes, is affected by gramicidin. The antibiotic appears to permit a reversal in the direction of the operation of the Na⁺-dependent amino acid transport system. The increased efflux is partly, but not entirely, due to an increase in the cellular Na⁺ concentration and a reduction of the electrochemical potential difference for Na⁺.     

Bioenergetics of alkalophilic bacteria

Summary The central problem for organisms which grow optimally, and in some cases obligately, at pH values of 10 to 11, is the maintenance of a relatively acidified cytoplasm. A key component of the pH homeostatic mechanism is an electrogenic Na⁺/H⁺ antiporter which—by virtue of kinetic properties and/or its concentration in the membrane—catalyzes net proton uptake while the organisms extrude protons during respiration. The antiporter is also capable of maintaining a constant pH_in during profound elevations in pH_out as long as Na⁺ entry is facilitated by the presence of solutes which are taken up with Na⁺. Secondary to the problem of acidifying the interior is the adverse effect of the large pH gradient, acid in, on the total pmf of alkalophile cells. For the purposes of solute uptake and motility, the organisms appear to largely bypass the problem of a low pmf by utilizing a sodium motive force for energization. However, ATP synthesis appears not to resolve the energetics problem by using Na⁺ or by incorporating the proton-translocating ATPase into intracellular organelles. The current data suggest that effective proton pumping carried out by the alkalophile respiratory chain at high pH may deliver at least some portion of the protons to the proton-utilizing catalysts, i. e., theF ₁ F ₀-ATPase and the Na⁺/H⁺ antiporter, by some localized pathway.     

Na<Superscript>+</Superscript> Modulates Anion Permeation and Block of P2X<Subscript>7</Subscript> Receptors from Mouse Parotid Glands

Experiments were conducted to test the hypothesis that aliphatic hydrocarbons bind to pockets/crevices of sodium (Na⁺) channels to cause action potential (AP) block. Aliphatic solutes exhibiting successively greater octanol/water partitition coefficients (K _ow) were studied. Each solute blocked Na⁺ channels. The 50% effective concentration (EC₅₀) to block APs could be mathematically predicted as a function of the solute’s properties. The solutes studied were methyl ethyl ketone (MEK), cyclohexanone, dichloromethane, chloroform and triethylamine (TriEA); the K _ow increased from MEK to TriEA. APs were recorded from frog nerves, and test solutes were added to Ringer’s solution bathing the nerve. When combined with EC₅₀s for solutes with log K _ows < 0.29 obtained previously, the solute EC₅₀s could be predicted as a function of the fractional molar volume (dV/dm = [dV/dn]/100), polarity (P) and the hydrogen bond acceptor basicity (β) by the following equation: Fluidity changes cannot explain the EC₅₀s. Each of the solutes blocks Na⁺ channels with little or no change in kinetics. Na⁺ channel block explains much of the EC₅₀ data. EC₅₀s are produced by a combination of effects including ion channel block, fluidity changes and osmotically induced structural changes. As the solute log K _ow increases to values near 1 or greater, Na⁺ channel block dominates in determining the EC₅₀. The results are consistent with the hypothesis that the solutes bind to channel crevices to cause Na⁺ channel and AP block.     

Growth and osmotic adjustment of two tomato cultivars during and after saline stress

The effect of a short period of saline stress was studied in two phenotypically different cultivars, one of normal fruit-size (L. esculentum cv. New Yorker) and one of cherry fruit-size (L. esculentum var.cerasiforme cv. PE-62). In both cultivars the relative growth rate (RGR) and the leaf area ratio (LAR) decreased following salinisation. The leaf turgor potential (_p) and the osmotic potential at full turgor (_os) decreased to the same extent in both cultivars. However, the contributions of organic and inorganic solutes to the osmotic adjustment was different between cultivars. New Yorker achieved the osmotic adjustment by means of the Cl^– and Na⁺ uptake from the substrate, and by synthesis of organic solutes. In the cherry cultivar organic solutes did not contribute to the osmotic adjustment, instead, their contribution decreased after salinisation. After the salt stress was removed, the water stress disappeared, the content of organic solutes decreased in plants of both cultivars and, therefore, their growth was not retarded by the diversion of resources for the synthesis of organic solutes. However, the toxic effects of the Cl^– and Na⁺ did not disappear after removal of the salt stress, and the net assimilation rate (NAR) and the rate of growth (RGR) did not recover.     

Investigations on the growth and metabolism of cultured explants of Daucus carota

Summary Knowing that the element Fe essentially triggers the action of the coconut milk stimulus for the growth of carrot explants and thereafter interacts with added Mo and Mn, the effects of these trace elements on growth (fresh and dry weight) and metabolism of both nitrogenous and nitrogen-free metabolites have been determined. An outstanding effect of Fe is to determine the level of protein synthesized, and the combination of Mo with Fe increases both protein and the content of non-protein nitrogen compounds. The role of Mn seems to reside in the mobilization of the soluble (non-protein) nitrogen compounds but its effects, which tend to compete with Fe in combination with Mo, tend to divert these compounds from protein synthesis. The element Fe appears again as a key element which determines the linkage between the use of carbon from carbohydrate and its entry into nitrogen metabolism: this has been shown by the use of ¹⁴C-fructose as the source. Whereas Fe promotes the use of ¹⁴C from fructose and directs it into protein, neither Mo nor Mn could achieve this either separately or in combination. The paper presents both the individual effects due to the trace elements and their interactions when supplied in combination. Stress is laid upon the need to consider the effects which are due to the inorganic elements in combination with the componenents of such growth-promoting systems as those present in coconut milk. These interactions are illustrated by polygonal diagrams (Figs. 3, 4 and 5). The point is made that any of several single entities of such an interacting complex may be in a given case rendered limiting, and the consequences of this fact for the concept of kinins or cell division factors are outlined. Any concept that requires cell division to be mediated solely by a given kind of chemical substance, or cell-division factor, would on the evidence here given present problems.The collaboration with K. H. Neumann was made possible by a German-Cornell Exchange Scholarship tenable at Cornell University and awarded by the Deutsche Akademische Austauschdienst, Bad Godesberg. The collaboration with K. V. N. Rao was made possible by the award of a Fulbright Travel grant and a Smith-Mundt stipend. In both cases (K. H. N. and K. V. N. R.) work continued after their scholarships expired under arrangements made possible by a grant to one of us (F. C. S.) from the National Institutes of Health, Bethesda, Md. K. H. Neumann was associated with the work throughout both at Cornell University and subsequently at the Justus Liebig Universität at Giessen (Institute für Pflanzenernährung); K. V. N. Rao was concerned with the work in its later stages at Cornell.     

Rapid effects of nerve growth factor on the Na,K-pump in rat pheochromocytoma cells

Nerve growth factor (NGF) induces neuronal differentiation of rat pheochromocytoma cells (PC12). Here we show that NGF causes a stimulation of Na⁺,K⁺-pump mediated K⁺ influx, with a maximum at 30 min after addition of NGF. The stimulation of the Na⁺,K⁺-pump is completely blocked by the Na⁺-flux inhibitor amiloride (0.2 mM) and can be mimicked by the Na⁺ ionophore monensin. These results suggest that NGF causes a rapid enhancement of Na⁺ influx leading to an activation of the Na⁺,K⁺-pump, a mechanism similar to the action of other growth factors.