Effects of group I cations on the gelation of iota carrageenan

N.m.r. and rheological measurements have been used to study the gelation of iota carrageenan. Gelation has been found to occur only at polymer concentrations above the critical entanglement concentration. The high temperature sol state above the gel-sol transition appears to be an entangled polymer network. Although Li⁺ and Na⁺ ions are less effective at gelling the polymer than K⁺, Rb⁺ and Cs⁺ all cationic forms studied gel at sufficiently high polymer concentration and ionic strength. ⁷Li⁺, ²³Na, ³⁹K, ⁸⁷Rb and ¹³³Cs n.m.r. studies have been made as a function of temperature. The lithium salt form (2.2% w/w concentration) formed a viscoelastic solution at room temperature. The other salt forms gelled on cooling. The spectra of Li, Na and Cs carrageenan showed little change on heating whereas K and Rb spectra showed marked changes in apparent intensity. The nature of the cation interaction with the juntion zones is discussed.     

Cat Heart Muscle in Vitro : VII. The temperature dependence of steady state K exchange in presence and absence of NaCl

In quiescent cat papillary muscles J _K, the rate of exchange of cellular K with K⁴² in the steady state, has been measured in the presence and absence of NaCl over a wide range of temperatures. J _K was found to be independent of the presence of external NaCl under the steady state conditions investigated. The Arrhenius plot for K exchange was linear over a range of temperatures from 2.5 to 37.5°C in the absence of NaCl, and from 17.5 to 37.5°C in the presence of NaCl. The corresponding apparent activation energies were, respectively, 10,200 and 8,800 calories/mole. J _K in the absence of NaCl was not affected by 10^-5 M ouabain. These results are consistent with a passive distribution for the K of heart muscle cells. The observations suggest that a carrier-mediated forced exchange of K for Na does not occur during the steady state in mammalian heart muscle.     

Rheological characterization of xanthan fermentation broths and their reconstituted solutions

Two strains of X. campestris from a collection and a wild strain isolated from infected cabbage were cultured in a defined medium in a 25 dm³ fermenter. The rheological characteristics of the broth were measured using a Weissenberg rheogoniometer. The rheological behaviour over a wide range of shear rates could be described with the power law model and a yield stress was obtained using the Herschel-Bulkley equation. As expected, the broth's flow behaviour is highly influenced by gum concentration. In general, the rheological parameters during the fermentations varied within the following ranges: K (2–210 dyn-sⁿ/cm²), n (0.2–0.9), τ _y (0.02–50 dyn/ cm²), with strain 1459 reaching the maximum values as well as the highest gum concentration. Differences in flow behaviour could be associated with different molecular configurations of the polymers produced by the different strains. Heat treatment of the broths change the rheological characteristics, increasing K and decreasing n. Reconstituted solutions of all sterilized gums exhibited similar rheological characteristics and, at low concentrations, also similar to those of a commercial xanthan.     

Sodium ion and solvent nuclear relaxation results in aqueous solutions of DNA

The field-dependent ²³Na nuclear relaxation in aqueous DNA solutions has been obtained for a range of temperatures, including the DNA melting region. At least two correlation times are needed to characterize the spectral density function for the ²³Na relaxation. For the slow process (with the largest correlation time), the temperature dependence of the coupling constant and the correlation time were determined, and important premelting effects were observed. Possible origins of the slow process are discussed. The last process is shown to be correlated with the properties of the hydration water of DNA as reflected by the ¹⁷O relaxation rates in these solutions. The influence of the polyelectrolyte and NaCl concentrations on the ²³Na relaxation rate is compared with previous results from solutions of linear flexible polyelectrolytes.     

Abscisic acid, temperature and salinity interactions on growth and some mineral elements in Carthamus plants

Growth and contents of sodium (Na), potassium (K), calcium (Ca), magnesium (Mg), chloride (Cl), phosphorus (P) and sulphur (S) in shoot and root tissues of Carthamus tinctorius plants were measured at combinations of four nutrient solution osmotic potentials (_s=0, -0.3, -0.6 and -0.9 MPa) induced by NaCl and CaCl treatments, three constant temperatures (T) ranging from 15 to 35°C and four abscisic acid (ABA) concentrations (0,10,50 and 100 mg L^–1). Unstressed and stressed plants grown in optimal temperature conditions (25°C) maintained higher growth rates (dry mass production) than plants grown under low and high temperatures (15 and 35°C respectively). Shoot and root growth (dry mass production) were largely inhibited by salinity but the magnitude of growth inhibition was temperature dependent. Safflower plants respond to salinity stress by increases in Ca, Cl and to a lesser extent Na in their shoots and roots and by a decrease in the ratio of fresh to dry weight. The ratio of K/Na was decreased progressively on salinization. With stressed plants, ABA application reduced the toxicity of salt treatment, improved K uptake under salinity, effectively increased K/Na ratio and helped the plants to avoid Na toxicity and sometimes enhanced growth. The effect of ABA on the growth was more pronounced at optimum temperature (25°C). The association between the internal mineral element concentrations was largely affected by ABA application and temperature change but a wide fluctuation in response was noticed. The effects of single factors (_s, T and ABA) on the growth and mineral contents were statistically significant. Also, bifactorial (_s× T, _s × ABA and T × ABA) and three factorial (_s × T × ABA) interactions significantly affected the parameters. Further statistical treatment of the data (coefficient of determination ²) led to four important findings: (1) Salinity (_s) was dominant in affecting Ca and Cl contents in both shoot and root as well as root Na content. (2) Temperature (T) had a dominant effect on growth, shoot K, Mg, P, S and root P, and S contents (3) The share of _s × T × ABA interaction was dominant for root Na and Mg contents. (4) The single factors and their interactions had a dual role in their subsidiary effects.Abbreviations ABA abscisic acid - _s osmotic potential - ² coefficient of determination - F.wt fresh weight - d.m. dry matter - T temperature - MPa mega pascal - SAR sodium adsorption ratio - P phosphorus - S sulphur     

Comparison of salt tolerance and osmotic adjustment of low-sodium and high-sodium subspecies of the C4 halophyte, Atriplex canescens

The relationship between Na⁺ accumulation and salt tolerance was tested by comparing subspecies of the halophyte, Atriplex canescens (fourwing saltbush), that differed markedly in Na⁺ content and Na:K ratios. Above ground tissues of one low-sodium and two high-sodium subspecies were compared with respect to cation accumulation, osmotic adjustment and growth along a salinity gradient in greenhouse trials. Plants of each subspecies were grown for 80 d on 2.2, 180, 540 and 720 mol m^?3 NaCl. At harvest, A. canescens ssp. canescens had significantly lower Na⁺ levels, higher K⁺ levels and lower Na:K ratios in leaf and stem tissues than A. canescens ssp. macropoda and linearis over the salinity range (P < 0.05 or 0.01). Na:K ratios in leaves of the latter two, high-sodium, subspecies were approximately 2 on the lowest salinity treatment and ranged from 5 to 10 on the more saline solutions. By contrast, Na:K ratios in leaves of the low-sodium subspecies canescens, were only 0.4 on the lowest salinity and ranged narrowly from 1.7 to 2.3 at higher salinities. However, despite different patterns of Na⁺ and K⁺ accumulation, all three subspecies exhibited equally high salt tolerance and had similar osmotic pressures in their leaves or stems over the salinity range. Contrary to expectations, high salt tolerance was not necessarily dependent on high levels of Na⁺ accumulation in this species.     

A physico-chemical study of heparin: Evidence for a calcium-induced co-operative conformational transition

The conformations of heparin in aqueous solution in the presence of sodium, potassium, magnesium and calcium cations were studied using circular dichroism, optical rotation, nuclear magnetic resonance and equilibrium dialysis. Potassium and magnesium cations, when added to sodium heparinate solutions, cause small chiroptical changes. Binding of calcium ions gives rise to large changes in both optical rotation and circular dichroism. This is indicative of a major change in chain conformation, which is also manifest in ¹³C and ¹H n.m.r.⁴Equilibrium dialysis suggests one mole of calcium bound per mole of tetrasaccharide, which n.m.r. indicates to be appropriately sulphated iduronateglucosamine-iduronate-glucosamine. The calcium is chelated by two iduronate carboxyl groups. Proton-proton coupling constants, determined by convolution difference spectroscopy and Carr-Purcell sequences, indicate that, over the temperature range 285 to 353 K, the iduronate ring is best described as ¹C₄(l) and the glucosamine residue as ⁴C₁(d) for both sodium and calcium forms.The conformational change induced by calcium is ascribed to rotation around the glycosidic linkages. The binding process is co-operative and the binding constant of 10³ to 10⁴m^?1 is biologically significant. The findings are consistent with intramolecular binding. Hence, this study represents the first report of a polysaccharide undergoing a cation-induced intramolecular disorder-order process. The authors postulate that a function of the post-polymerization epimerization of d-glucuronate to l-iduronate is the attainment of the precise geometry required for co-operative calcium binding with consequent modulation of the flexibility of the tetrasaccharide units.     

Multinuclear n.m.r. studies of group I cations in furcellaran gels

Multinuclear n.m.r. experiments were carried out in order to study the possible selective interaction between group I cations and furcellaran. It has been shown that the intensity of the 39K, 87Rb and 133Cs spectra show a change in the vicinity of the sol-gel transition. However, the intensity of the 23Na spectrum showed no singularity at the sol-gel transition. These studies suggest that the selective interactions of the group I cations upon gelation of furcellaran resemble those observed for the structurally related kappa-carrageenan.     

Membrane differentiation and de Nova synthesis of the (Na+ + k+)-activated adenosine triphosphatase during development of Artemia salina nauplii.

The developing brine shrimp, Artemia salina, nauplius is explored as a new model for the study of the biogenesis of the cation transport enzyme, (Na⁺ + K⁺)-activated adenosine triphosphatase [(Na, K)-ATPase]. (Na, K)-ATPase activity develops from undetectable levels in preemergent cysts (embryos prior to 12 hr of development) to very high levels in the nauplius after 40 hr of incubation in sea water [Conte, F. P., Droukas, P. C., and Ewing, R. D. 1977). J. Exp. Zool.202, 339], then declines between 44 and 72 hr. Similar ontogenic patterns of enzyme activity development are observed for Mg-ATPase, 5′-nucleotidase, glucose-6-phosphatase, NADH oxidase (rotenone insensitive), and cytochrome oxidase. However, these enzymes show measurable activity in the early cyst stage, and the points at which the activity increases and then reaches a maximum are usually different from those of the (Na, K)-ATPase. These enzyme ontogeny studies demonstrate that membrane differentiation is extensive during the period in naupliar development when (Na, K)-ATPase activity appears, and that the appearance of specific enzymes is asynchronous during embryogenesis. Pulse-chase experiments with NaH¹⁴CO₃ show an increase in the specific radioactivity of the partially purified (Na, K)-ATPase which is maximum when the label is administered at 12–18 hr after the initiation of development. At this time the specific radioactivity increases with purity of the enzyme, whereas in earlier pulse periods the specific radioactivity is higher in the more crude enzyme fractions, suggesting that preferential synthesis of the (Na, K)-ATPase occurs between 12 and 18 hr. Radioactivity is found in the subunits of the partially purified (Na, K)-ATPase isolated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, and is maximum for the 12- to 18-hr pulse experiment. These pulse-chase experiments demonstrate that the large increase in (Na, K)-ATPase activity is due to de novo synthesis and establish that the brine shrimp is a workable new model for the study of the biogenesis of the (Na, K)-ATPase.     

Power law dispersion in animal horn

The dielectric response of sheep horn has been measured in the frequency range from 10^–3–10⁵ Hz and over temperatures in the range 304–500 K. The dynamic behaviour of the conductance and capacitance in sheep horn has been observed to follow fractional power law dependences on frequency. It is shown that the over all dielectric response of these dead cells correspond to a dispersive imperfect bulk in series with a dispersive barrier region. It is further shown that the increase in temperature influences the reponse by eliminating the room temperature dc conductance and affecting the magnitude of the dispersion in capacitance. The magnitudes of activation energies are found as 0.33±0.02 eV for conductance, 0.40±0.02 eV for relaxation and 0.33±0.02 eV for the frequency shift.     

A pulsed N.M.R study of D2O bound to 1,2 dipalmitoyl phosphatidylcholine

Spin lattice relaxation times in both the lab and rotating frame, have been measured for deuterons (²H) in a number of unsonicated dispersions of 1,2 dipalmitoyl phosphatidylcholine in D₂O over a range of resonant frequencies from 13 MHz to 1 MHz for temperatures from ?20°C to 65°C.The proton (¹H) spin lattice relaxation time for the lecithin was measured for resonant frequencies of 8.5 MHz, and 40 MHz over a similar range of temperatures.The results agree with broadline measurements by Salsbury et al. [1], and for the liquid crystal phase are consistent with an anisotropic tumbling model of the water molecules bound to the lecithin headgroup. This tumbling occurs with correlation times of ≤10^?10 sec and ≈ 10^?6 sec about axes parallel to and perpendicular to the bisector of the D-O-D angle within a D₂O molecule, hydrogen bonded to the negatively charged phosphate headgroup.     

Studies on the heat-precipitated phosphoenzyme complex of eel electric organ (Na + K).ATPase.

When the hydrolytic reaction between eel electric organ (Na + K) · ATPase and [γ-³²P]ATP is terminated at neutral pH by heat precipitation, a phosphoenzyme complex is formed which reaches maximal levels in the simultaneous presence of Mg, Na, and K. After formation of a steady-state level of phosphoenzyme in the presence of Mg and Na, a pulse of K increases the level of the heat-precipitated phosphoenzyme (while decreasing the level of the acid-precipitated phosphoenzyme). The formation of the heat-precipitated phosphoenzyme is clearly inhibited by ouabain only when the phosphoenzyme is formed in the presence of Mg, Na, and K. Inorganic phosphate decreases the level of the heat-precipitated phosphoenzyme, but not that of the acid-precipitated phosphoenzyme (in the presence of Mg and Na or in the presence of Mg, Na, and K). Moreover, a heat-precipitated, ouabain-sensitive phosphoenzyme forms in the reaction between the eel (Na + K) · ATPase and ³²P_i with or without ATP. The pH stability of the heat-precipitated phosphoenzyme complex is maximal at pH 6 to 8, and this complex shows little or no reactivity with neutral hydroxylamine, suggesting that the phosphate is not bound to an acyl residue of the protein. These experiments indicate that both heat-resistant and acid-resistant phosphoenzymes are formed during the (Na + K) · ATPase reaction at pH 7.4.     

Codon-anticodon interaction in tRNAPhe: II. A nuclear magnetic resonance study of the binding of the codon UUC

The effect of binding of the codon UUC to yeast tRNA^Phe was investigated by means of n.m.r.² spectroscopy and analytical ultracentrifugation. Binding of UUC to the transfer RNA anticodon tends to promote the aggregation of tRNA molecules; this is manifest from a line broadening in the n.m.r. experiments as well as from an increase in s_20,w the ultracentrifuge experiments. Such an aggregation of tRNA molecules was not observed upon addition of different oligonucleotides, as described in the accompanying paper. In addition to the general broadening observed in the n.m.r. spectra, specific resonances in the methyl proton spectrum as well as in the hydrogen-bonded proton spectrum are broadened or shifted upon binding of UUC.These results are explained on the basis of the premise that two different tRNA-UUC complexes can exist in solution. It is suggested that the binding of UUC tends to promote a disruption of the m⁷G₄₆ · m²₂G₂₂ base-pair and its neighbouring base-pairs.In studying the binding of U-U-U-U to yeast tRNA^Phe no resonances of protons hydrogen-bonded between the oligonucleotide and the tRNA could be detected at low temperatures. This indicates, that at these temperatures the lifetime of the tRNA-U-U-U-U complex is substantially shorter than the lifetime of the other tRNA-oligonucleotide complexes studied in this and the accompanying paper under these conditions.     

Reassignment of the methine resonances of D-fructose based on the carbon-13 n.m.r. spectrum of 3-O-methyl-D-fructose

Several disagreements in the ¹³C n.m.r. assignments of the methine carbons of D-fructose exist in the literature. In order to settle these inconsistencies, we examined the ¹³C n.m.r. spectrum of 3-O-methyl-D-fructose. By following the methyl induced shift in this spectrum, as compared to the parent sugar, we identified the alkylated C-3 resonance of all four tautomeric forms of D-fructose. This information, together with our previous identification of the C-5 resonances of the α- and β-forms of D-fructofuranose 6-phosphate, allow the unambiguous identification of all methine carbons of D-fructose in its ¹³C n.m.r. spectrum. The tautomeric composition of 3-O-methyl-D-fructose at 16.5°, in aqueous solution, was found to be as follows: α-pyranose 18%, β-pyranose 37%, α-furanose 11% and β-furanose 34%.     

Potassium-39 and sodium-23 NMR studies of cation binding to phosvitin

The binding of Na+ and K+ to hen egg-yolk phosvitin has been studied by 23Na and 39K NMR. A transition in the binding behaviour of these cations is shown to accompany deprotonation of the phosphate groups on this highly charged protein. At lower pH the data are well described by a purely mass-action binding model, whereas at higher pH significant polyelectrolyte effects are apparent. From single ion as well as competition experiments K+ is shown to bind more strongly to phosvitin than does Na+. The temperature and magnetic field strength dependences of the 23Na and 39K relaxation rates provide a picture of phosvitin as a highly flexible macromolecule. This work demonstrates the potential of 39K NMR as a useful tool in the study of protein-cation interactions.     

Growth of Crithidia at High Temperature: Crithidia hutneri sp. n. and Crithidia luciliae thermophila s. sp. n.*

SYNOPSIS. Crithidia hutneri sp. n. and Crithidia luciliae thermophila s. sp. n. are described. Both flagellates can be grown in a defined medium over a temperature range of 15–37°C. The requirements for amino acids, vitamins, purine and hemin, and pH range were similar to those established for Crithidia fasciculata, although threonine was required as a growth factor for C. luciliae thermophila at high temperatures. Adenosine could be used by the 2 Crithidia as a purine source at 28 but not at 37 C.     

Rheological behaviour of high density continuous cultures of Saccharomyces cerevisiae

By culture of Saccharomyces cerevisiae with cell recycle using tangential microfiltration, high cell concentrations are obtained (in the range of 0 to 345 gl⁻¹ dry-weight). The rheological properties of the cell suspension during the cell growth were studied. Over a wide range of biomass concentration (X<275 gl⁻¹D.W.) the power-law model was found adequate to describe the rheological behaviour of the broth. Pronounced non-Newtonian (pseudoplastic) behaviour occurred for X > 75 gl⁻¹. Experimental correlations for apparent viscosity (n_a, mPa.s) and power-law index vs. biomass concentration (X, gl⁻¹) were established: n_a = (1+0.012X)² suitable over the whole range of concentration up to 275 gl⁻¹ D.W. n_a = 1+0.04X in the low concentration range; X<100 gl⁻¹D.W. Beyond the cell concentration of 275 gl⁻¹ D.W. the viscosity increases suddenly.     

Ionic dependence of bumetanide binding to the rabbit parotid Na/K/Cl cotransporter

Summary The Na/K/Cl-dependent component of the binding of the loop diuretic bumetanide to basolateral membrane vesicles from the rabbit parotid is studied. A Scatchard analysis indicates that this binding is due to a single high-affinity site withK _D =3.2±0.3 m (n=9) at 100mm sodium, 100mm potassium and 5mm chloride. When KCl-dependent²²Na transport and tracer [³H]-bumetanide binding are monitored simultaneously as a function of (unlabeled) bumetanide concentration it is found that theK _0.5 for bumetanide inhibition of both processes are identical indicating that the high-affinity bumetanide binding site studied here is identical with a bumetanide-inhibitory site on the Na/K/Cl cotransport system previously identified in this preparation (R.J. Turner, J.N. George and B.J. Baum,J. Membrane Biol. 94:143–152, 1986). High-affinity bumetanide binding exhibits a hyperbolic dependence on both [Na] and [K] consistent with Na/bumetanide and K/bumetanide binding stoichiometries of 11 andK _0.5 values of approximately 33mm for sodium and 23mm for potassium. In contrast, the dependence on [Cl] is biphasic, with bumetanide binding increasing from 0 to 5mm chloride and decreasing toward baseline levels thereafter. Scatchard analysis of this latter inhibitory effect of chloride indicates a competitive interaction with bumetanide in agreement with earlier indications that bumetanide inhibits Na/K/Cl cotransport at a chloride site. However, studies of the effects of various anions on bumetanide binding and²²Na transport show a poor correlation between the specificities of these two processes, suggesting that the inhibitory chloride site is not a chloride transport site.     

Nuclear Magnetic Resonance of Sodium-23 Linoleate-Water: Basis for an Alternative Interpretation of Sodium-23 Spectra within Cells

The ²³Na spectrum from liquid crystals of sodium linoleate in water has been studied by nuclear magnetic resonance (NMR) techniques. The integrated intensity of the visible central spectral line was 34-39% of the intensity of a reference sample containing an equal quantity and concentration of ²³Na nuclei. Since satellite signals were clearly demonstrable, the effect reflected a nuclear quadrupolar interaction rather than a splitting of the ²³Na into two populations of bound and free nuclei. It is proposed that a similar quadrupolar effect may be the basis for the apparent binding of the ²³Na observed in biological systems.     

Effects of temperature and field strength on the NMR relaxation times of 23Na in frog striated muscle

Pulsed NMR techniques have been applied to the study of the relaxation parameters characterizing ²³Na within frog striated muscle. Experiments were performed at 3°C, 22–24°C and 39°C at a Larmor frequency of 15.7 MHz; at 22–24°C, measurements were obtained both at 15.7 MHz and at 7.85 MHz.As previously reported, only a single spine-lattice relaxation time (T₁) was observed, but both slow (T₂)_I and fast (T₂)_II components of the spin-spin relaxation time were measured. The effect of temperature (θ) upon (1/T₁) was qualitatively similar to that reported for ²³Na in free solution; (θ) did not significantly affect (1/T₂) over the range of temperatures studied. (1/T₂)_I, and to a lesser degreee, (1/T₁) exhibited a modest inverse dependence of doubtful significance on the Larmor frequency.The data are examined within the framework of a simple specific model; a conservative values in assumed for the quadrupolar coupling constant characterizing immobilized intracellular Na⁺. Within this framework, the results suggest that the fraction of bound ions whose molecular tumbling is severely restricted does not exceed some few percent of the total sodium population.