Enhanced drought tolerance of transgenic rice plants expressing a pea manganese superoxide dismutase

We investigated the role that manganese superoxide dismutase (MnSOD), an important antioxidant enzyme, may play in the drought tolerance of rice. MnSOD from pea (Pisum sativum) under the control of an oxidative stress-inducible SWPA2 promoter was introduced into chloroplasts of rice (Oryza sativa) by Agrobacterium-mediated transformation to develop drought-tolerant rice plants. Functional expression of the pea MnSOD in transgenic rice plants (T1) was revealed under drought stress induced by polyethylene glycol (PEG) 6000. After PEG treatment the transgenic leaf slices showed reduced electrolyte leakage compared to wild type (WT) leaf slices, whether they were exposed to methyl viologen (MV) or not, suggesting that transgenic plants were more resistant to MV- or PEG-induced oxidative stress. Transgenic plants also exhibited less injury, measured by net photosynthetic rate, when treated with PEG. Our data suggest that SOD is a critical component of the ROS scavenging system in plant chloroplasts and that the expression of MnSOD can improve drought tolerance in rice.     

Crystallization and preliminary X-ray diffraction studies of complexes between an influenza hemagglutinin and fab fragments of two different monoclonal antibodies

Fab fragments from two different monoclonal antibodies (BH151 and HC45) which bind to the same antigenic region of the influenza hemagglutinin were crystallized as complexes with the hemagglutinin. The complexes crystallize in PEG 600, pH 6.0, and PEG 2000, pH 8.5, respectively. Both crystals belong to space group P321, with very similar unit cell dimensions. © 1995 Wiley-Liss, Inc.     

Study of the synthesis, crystallization, and morphology of poly(ethylene glycol)-poly(epsilon-caprolactone) diblock copolymers

Poly(ethylene glycol)-poly(epsilon-caprolactone) diblock copolymers PEG-PCL were synthesized by ring-opening polymerization of epsilon-caprolactone using monomethoxy poly(ethylene glycol) as the macroinitiator and calcium ammoniate as the catalyst. Obvious mutual influence between PEG and PCL crystallization was studied by altering the relative block length. Fixing the length of the PEG block (Mn = 5000) and increasing the length of the PCL block, the crystallization temperature of the PCL block rose gradually from 1 to about 35 degrees C while that of the PEG block dropped from 36 to -6.6 degrees C. Meanwhile, the melting temperature of the PCL block went up from 30 to 60 degrees C, while that of the PEG block declined from 60 to 41 degrees C. If the PCL block was longer than the PEG block, the former would crystallize first when cooling from a molten state and led to obviously imperfect crystallization of PEG and vice versa. And they both crystallized at the same temperature, if their weight fractions were equal. We found that the PEG block could still crystallize at -6.6 degrees C even when its weight fraction is only 14%. A unique morphology of concentric spherulites was observed for PEG5000-PCL5000. According to their morphology and real-time growth rates, it is concluded that the central and outer sections in the concentric spherulites were PCL and PEG, respectively, and during the formation of the concentric spherulite, the PEG crystallized quickly from the free space of the PCL crystal at the earlier stage, followed by outgrowing from the PCL spherulites in the direction of right angles to the circle boundaries until the entire area was occupied.     

Purification and crystallization of coconut globulin cocosin from Cocos nucifera

Cocosin is a legume class reserve protein found in coconut endosperm. Using coconut endosperm, two methods of purification were done. Crystallization was achieved by vapor diffusion (hanging drop) method using MPD, PEG 3350 and PEG 4000 as precipitants. X-ray diffraction data to 3.5-A resolution were collected using Mar345 image plate detector system. Crystals of cocosin grown under 20% MPD, are rhombohedral with space group R3 and cell dimensions a=92.829 A, b=92.829 A, c=215.290 A.     

A poly(ethylene) glycolylated peptide for ocular delivery compacts DNA into nanoparticles for gene delivery to post‐mitotic tissues in vivo

Background

We have previously shown that a novel synthetic peptide for ocular delivery (POD) can efficiently compact DNA and deliver it to cells in vitro. This observation prompted us to develop use of POD as a nonviral vector in vivo.

Methods

POD peptide was modified using poly(ethylene) glycol (PEG‐POD) and used to compact DNA into nanoparticles that were then analysed using electron microscopy, dynamic light scattering, and fluorescent labeling. Transfection efficiency and localization were determined 48 h post‐injection into the subretinal space of the mouse eye using luciferase and LacZ, respectively. Efficiency of ocular transfection was compared to two other PEGylated peptides: PEG‐TAT and PEG‐CK30.

Results

PEG‐POD can compact DNA and form discrete nanoparticles of approximately 136 nm that can penetrate and transduce the retinal pigment epithelium (RPE) in vivo. PEG‐POD significantly increased expression of plasmid DNA by 215‐fold, PEG‐TAT by 56.52‐fold, and PEG‐CK30 by 24.73‐fold relative to DNA injected alone. In all cases β‐galactosidase was observed primarily in the RPE layer after subretinal injection. Electrophysiological analyses of PEG‐POD transduced retina indicates an absence of PEG‐POD‐mediated toxicity. PEG‐POD can protect plasmid DNA from DNaseI digestion, resulting in significant transfection of the lung after intravenous injection in mice.

Conclusions

PEG‐POD was found to significantly increase gene delivery relative to both DNA alone and other pegylated peptides. These findings highlight the use of pegylated peptides, and specifically PEG‐POD, as novel gene delivery vectors. Copyright © 2009 John Wiley & Sons, Ltd.     

Characterization of PEG-mediated electrofusion of human erythrocytes.

Polyethylene glycol (PEG) and electrofusion were applied together in a simple and highly efficient cell fusion method. PEG (8000 M(r)) was used to bring human erythrocytes into contact, and a single 4.4 kV/cm, 80 microseconds duration pulse was applied to cell suspensions. The fusion yield (FY) is PEG concentration-dependent. A maximum FY (50%) was found at about 10% PEG. Higher PEG concentrations (> 10%) suppressed FY caused by colloid osmotic shrinkage. Morphological changes, such as colloidal osmotic swelling and shrinking, and the expanding and contraction of fusion lumen, when suspension media were changed from PBS to isotonic 15% dextran solutions, was examined by microscopy. FY was found to depend on both simple osmotic and colloidal-osmotic swelling. From the swelling behavior, we propose two types of electropores: the pre-fusion sites between cell pairs, and electropores on each individual cell connecting intracellular and extracellular space. The latter type is responsible for the colloidal osmotic swelling and shrinking of cell which, together with simple osmotic swelling, is responsible for expanding the pre-fusion sites into fusion lumens. Resealing of electropores resulted in reducing FY, but the FY can be restored by simple osmotic shock. Apparently, PEG plays two opposite roles in this fusion method; one is to promote pre-pulse and post-pulse cell-cell contact, protecting pre-fusion sites, and the other suppresses FY by colloid osmotic shrinkage of cells after pulsing, especially when high PEG concentration is used. 10% PEG 8000 represents the optimal combination of these properties.     

Ultrastructural and biochemical studies of the swelling of developing chick telencephalic slices

Summary An ultrastructural and biochemical study of the importance and localization of tissue swelling was performed on telencephalic slices of 1- and 30-day-old chicks incubated in an oxygenated or a non-oxygenated physiological medium. The swelling of slices is greater for 30-day-old chick material than for that from 1-day-old chicks. It also reaches higher values in the non-oxygenated than in the oxygenated medium. When the 30-day-old chick telencephalic slices are incubated in an oxygenated medium, swelling mainly affects astrocytes, and especially the astrocytic endfeet. When they are incubated in a non-oxygenated medium, the astrocytes and astrocytic endfeet are very swollen and in addition the swelling also affects the neurons and their organelles. Extracellular space is increased. When 1-day-old chick telencephalic slices are incubated in a non-oxygenated medium, the tissue structures are well preserved. Swelling predominantly affects astrocytes and astrocytic endfeet. Neurons are not affected and the extracellular space is reduced. However, when they are incubated in an oxygenated medium, tissue structures are greatly affected showing a high degree of disorganization. Extracellular space is greatly increased. This study thus indicates that the best incubation conditions are an oxygenated medium for 30-day-old chick telencephalic slices which are characterized by an aerobic metabolism, and a non-oxygenated medium for 1-day-old chick telencephalic slices which have a predominantly anaerobic metabolism.     

Efficient biodegradation of high-molecular-weight polyethylene glycols by pure cultures of Pseudomonas stutzeri.

Biodegradation of polyethylene glycols (PEGs) of up to 13,000 to 14,000 molecular weight has been shown to be performed by a river water bacterial isolate (strain JA1001) identified as Pseudomonas stutzeri. A pure culture of strain JA1001 grew on PEG 1000 or PEG 10000 at 0.2% (wt/vol) as a sole source of carbon and energy with a doubling time of 135 or 150 min, respectively. Cultures metabolized 2 g of polymer per liter in less than 24 h and 10 g/liter in less than 72 h. The limit of 13,500 molecular weight in the size of the PEG sustaining growth and the presence of a PEG-oxidative activity in the periplasmic space indicated that PEGs cross the outer membrane and are subsequently metabolized in the periplasm. PEG oxidation was found to be catalyzed by PEG dehydrogenase, an enzyme that has been shown to be a single polypeptide. Characterization of PEG dehydrogenase revealed glyoxylic acid as the product of the PEG-oxidative cleavage. Glyoxylate supported growth by entering the cell and introducing its carbons in the general metabolism via the dicarboxylic acid cycle, as indicated by the ability of strain JA1001 to grow on this compound and the presence of malate synthase, the first enzyme in the pathway, in extracts of PEG-grown cells.     

Efficient biodegradation of high-molecular-weight polyethylene glycols by pure cultures of Pseudomonas stutzeri.

Biodegradation of polyethylene glycols (PEGs) of up to 13,000 to 14,000 molecular weight has been shown to be performed by a river water bacterial isolate (strain JA1001) identified as Pseudomonas stutzeri. A pure culture of strain JA1001 grew on PEG 1000 or PEG 10000 at 0.2% (wt/vol) as a sole source of carbon and energy with a doubling time of 135 or 150 min, respectively. Cultures metabolized 2 g of polymer per liter in less than 24 h and 10 g/liter in less than 72 h. The limit of 13,500 molecular weight in the size of the PEG sustaining growth and the presence of a PEG-oxidative activity in the periplasmic space indicated that PEGs cross the outer membrane and are subsequently metabolized in the periplasm. PEG oxidation was found to be catalyzed by PEG dehydrogenase, an enzyme that has been shown to be a single polypeptide. Characterization of PEG dehydrogenase revealed glyoxylic acid as the product of the PEG-oxidative cleavage. Glyoxylate supported growth by entering the cell and introducing its carbons in the general metabolism via the dicarboxylic acid cycle, as indicated by the ability of strain JA1001 to grow on this compound and the presence of malate synthase, the first enzyme in the pathway, in extracts of PEG-grown cells.     

Interaction forces and morphology of a protein-resistant poly(ethylene glycol) layer

The molecular interactions on a protein-resistant surface coated with low-molecular-weight poly(ethylene glycol) (PEG) copolymer brushes are investigated using the extended surface forces apparatus. The observed interaction force is predominantly repulsive and nearly elastic. The chains are extended with respect to the Flory radius, which is in agreement with qualitative predictions of scaling theory. Comparison with theory allows the determination of relevant quantities such as brush length and adsorbed mass. Based on these results, we propose a molecular model for the adsorbed copolymer morphology. Surface-force isotherms measured at high resolution allow distinctive structural forces to be detected, suggesting the existence of a weak equilibrium network between poly(ethylene glycol) and water--a finding in accordance with the remarkable solution properties of PEG. The occurrence of a fine structure is interpreted as a water-induced restriction of the polymer's conformational space. This restriction is highly relevant for the phenomenon of PEG protein resistance. Protein adsorption requires conformational transitions, both in the protein as well as in the PEG layer, which are energetically and kinetically unfavorable.     

THE DISTRIBUTION OF AMINO ACIDS, Na+ AND K+ FROM SURFACE TO CENTRE IN INCUBATED SLICES OF MOUSE BRAIN

—The effect of tissue damage on the uptake of amino acids by brain slices was investigated by measuring uptake in slices of different thickness and measuring the distribution of [¹⁴C]-labelled amino acid on the surface and in the centre of incubated slices. The uptake of glutamate, aspartate, and GABA was greater in 0.1 mm-thick slices than in 0.42 mm-thick slices in short and in long (up to 120 min) incubations; the uptake of other amino acids was equal or greater in the 0.42 mm-thick slices. The water content of incubated slices did not change greatly from surface to centre; inulin space was greater at the surface, and in slices from cortex, especially higher at the cut surface. Na⁺ and K⁺ concentrations were also higher at the surface. In the rest of the slice space, inulin, Na⁺ and K⁺ distribution was quite uniform. The distribution of ATP was inhomogeneous: in thinner slices the centre concentration was higher; in thicker slices the centre concentration was lower. Amino acid uptake initially (at 5 min) was higher at the surface, especially in the thicker slices; after longer time (30 min) incubation, the distribution of lysine and leucine was uniform, and glutamate uptake was greater at the surface. The inhomogeneity of distribution increased with increasing thickness of the slices. We concluded that the uptake of some amino acids (perhaps those for which, beside a low affinity transport, also a higher affinity transport system exists) is greater in thinner slices and greater on the surface of slices, and there is an initially inhomogeneous distribution during amino acid uptake. The uptake on the surface constitutes only a small portion of the total uptake, and tissue damage does not explain the greater uptake of amino acids by slices in comparison to the brain in vivo. This shows the higher transport capacity of cells in the brain and emphasizes the importance of mechanisms controlling the metabolite composition of the extracellular fluid in finally influencing the metabolite composition of the brain itself.     

Microbial degradation of polyethers

This paper summarizes studies on microbial degradation of polyethers. Polyethers are aerobically metabolized through common mechanisms (oxidation of terminal alcohol groups followed by terminal ether cleavage), well-characterized examples being found with polyethylene glycol (PEG). First the polymer is oxidized to carboxylated PEG by alcohol and aldehyde dehydrogenases and then the terminal ether bond is cleaved to yield the depolymerized PEG by one glycol unit. Most probably PEG is anaerobically metabolized through one step which is catalyzed by PEG acetaldehyde lyase, analogous to diol dehydratase. Whether aerobically or anaerobically, the free OH group is necessary for metabolization of PEG. PEG with a molecular weight of up to 20,000 was metabolized either in the periplasmic space (Pseudomonas stutzeri and sphingomonads) or in the cytoplasm (anaerobic bacteria), which suggests the transport of large PEG through the outer and inner membranes of Gram-negative bacterial cells. Membrane-bound PEG dehydrogenase (PEG-DH) with high activity towards PEG 6,000 and 20,000 was purified from PEG-utilizing sphingomonads. Sequencing of PEG-DH revealed that the enzyme belongs to the group of GMC flavoproteins, FAD being the cofactor for the enzyme. On the other hand, alcohol dehydrogenases purified from other bacteria that cannot grow on PEG oxidized PEG. Cytoplasmic NAD-dependent alcohol dehydrogenases with high specificity towards ether-alcohol compound, either crude or purified, showed appreciable activity towards PEG 400 or 600. Liver alcohol dehydrogenase (equine) also oxidized PEG homologs, which might cause fatal toxic syndrome in vivo by carboxylating PEG together with aldehyde dehydrogenase when PEG was absorbed. An ether bond-cleaving enzyme was detected in PEG-utilizing bacteria and purified as diglycolic acid (DGA) dehydrogenase from a PEG-utilizing consortium. The enzyme oxidized glycolic acid, glyoxylic acid, as well as PEG-carboxylic acid and DGA. Similarly, dehydrogenation on polypropylene glycol (PPG) and polytetramethylene glycol (PTMG) was suggested with cell-free extracts of PPG and PTMG-utilizing bacteria, respectively. PPG commercially available is atactic and includes many structural (primary and secondary alcohol groups) and optical (derived from pendant methyl groups on the carbon backbone) isomers. Whether PPG dehydrogenase (PPG-DH) has wide stereo- and enantioselective substrate specificity towards PPG isomers or not must await further purification. Preliminary research on PPG-DH revealed that the enzyme was inducibly formed by PPG in the periplasmic, membrane and cytoplasm fractions of a PPG-utilizing bacterium Stenotrophomonas maltophilia. This finding indicated the intracellular metabolism of PPG is the same as that of PEG. Besides metabolization of polyethers, a biological Fenton mechanism was proposed for degradation of PEG, which was caused by extracellular oxidants produced by a brown-rot fungus in the presence of a reductant and Fe3+, although the metabolism of fragmented PEG has not yet been well elucidated.     

Enzymes Involved in Anaerobic Polyethylene Glycol Degradation by Pelobacter venetianus and Bacteroides Strain PG1

In extracts of polyethylene glycol (PEG)-grown cells of the strictly anaerobically fermenting bacterium Pelobacter venetianus, two different enzyme activities were detected, a diol dehydratase and a PEG-degrading enzyme which was characterized as a PEG acetaldehyde lyase. Both enzymes were oxygen sensitive and depended on a reductant, such as titanium citrate or sulfhydryl compounds, for optimal activity. The diol dehydratase was inhibited by various corrinoids (adenosylcobalamin, cyanocobalamin, hydroxocobalamin, and methylcobalamin) by up to 37% at a concentration of 100 μM. Changes in ionic strength and the K⁺ ion concentration had only limited effects on this enzyme activity; glycerol inhibited the enzyme by 95%. The PEG-degrading enzyme activity was stimulated by the same corrinoids by up to 80%, exhibited optimal activity in 0.75 M potassium phosphate buffer or in the presence of 4 M KCI, and was only slightly affected by glycerol. Both enzymes were located in the cytoplasmic space. Also, another PEG-degrading bacterium, Bacteroides strain PG1, contained a PEG acetaldehyde lyase activity analogous to the corresponding enzyme of P. venetianus but no diol dehydratase. Our results confirm that corrinoid-influenced PEG degradation analogous to a diol dehydratase reaction is a common strategy among several different strictly anaerobic PEG-degrading bacteria.     

EFFECTS OF POTASSIUM ON INDICATOR SPACES AND FLUXES IN SLICES OF BRAIN CORTEX FROM ADULT AND NEW-BORN RATS

—Inulin, sucrose and chloride spaces were measured in slices of brain cortex from adult and from new-born rats incubated in‘balanced', potassium-rich and sodium-rich media. The efflux of the radioactive markers was followed in the two first media and the following results were obtained: (1) In brain slices from new-born rats inulin and sucrose spaces were of identical magnitude (35 per cent). The space magnitude was essentially unaffected by excess potassium. The chloride space was somewhat larger than the inulin (sucrose) space, and the difference increased continuously but relatively slightly with the external potassium concentration. By far the largest amount (i.e. about 90 per cent) of the efflux of radioactive inulin, sucrose and chloride occurred from a rapidly exchanging compartment during incubation in both ‘balanced’ and potassium-rich media. (2) In brain slices from adult rats the inulin space (35 per cent) was significantly smaller than that of sucrose (50 per cent) and of chloride (65 per cent); it seemed to represent the extracellular space relatively well although 10 per cent of the efflux occurred from a slowly exchanging (probably intracellular) compartment. High concentrations of potassium led to a reduction of the inulin space which was probably a result of the concomitant intracellular swelling. The hyperosmolarity per se did not affect the space magnitude, but an increase of the sodium concentration exerted a competitive inhibition of potassium effects on the inulin space. Of the sucrose efflux, 20 per cent occurred from a slowly exchanging compartment in both ‘balanced’ and potassium-rich media, and 30 per cent of the chloride exchanged with this compartment when the tissue was incubated in a ‘balanced’ medium. An increase of the external potassium concentration caused a drastic increase of the chloride space and a reduction of the slowly exhanging fraction of chloride efflux to less than 10 per cent.     

Effect of alloxan on islet tissue permeability: protection and reversal by NADPH.

Previous work has shown that incubation of slices of the toadfish islet of Langerhans in a diabetogenic concentration of alloxan increases the permeability of their cell membranes to D-[1-¹⁴C]-mannitol, which normally remains in the extracellular space. We have now found that prior incubation of the slices in as little as 10^?5M NADPH, which markedly stimulates insulin release, protects the slices against this action of alloxan. Similarly, incubation of islet slices in NADPH after incubation in alloxan reverses the action of the latter. NADP, which produces little or no stimulation of insulin release, does not protect against or reverse the action of alloxan. These results suggest that alloxan may damage the β-cell membrane by acting at or near a site involved in insulin release.     

Application of surface response analysis to the optimization of penicillin acylase purification in aqueous two-phase systems

Penicillin acylase purification from an Escherichia coli crude extract using PEG 3350–sodium citrate aqueous two-phase systems (ATPS) was optimized. An experimental design was used to evaluate the influence of PEG, sodium citrate and sodium chloride on the purification parameters. A central composite design was defined centred on the previously found conditions for highest purification from an osmotic shock extract. Mathematical models for the partition coefficient of protein and enzyme, balance of protein and enzyme, yield and purification were calculated and statistically validated. Analysis of the contours of constant response as a function of PEG and sodium citrate concentrations for three different concentrations of NaCl revealed different effects of the three factors on the studied parameters. A maximum purification factor of 6.5 was predicted for PEG 3350, sodium citrate and NaCl concentrations of 15.1, 11.0 and 8.52% respectively. However, under these conditions the predicted yield was 61%. A better compromise between these two parameters can be found by superimposing the contour plots of the purification factor and yield for 10.3% NaCl. A region in the experimental space can be defined where the purification factor is always higher than 5.5 with yields exceeding 80%.     

An iterative procedure to estimate muscle lines of action in vivo

A method is described to estimate the line of action of muscles in the three-dimensional space from serial images of parallel muscle sections obtained in vivo by means of CT or MRI scanning. The external shape of a muscle, reconstructed from the series of parallel sections, is mathematically divided into a series of imaginary slices directed arbitrarily in the three-dimensional space. The line of action is estimated initially as a regression line through the centroids of these mathematical slices. A new series of mathematical slices is constructed perpendicular to the regression line and a new estimate of the line of action is obtained from their centroids. This procedure is repeated until the estimated line of action is perpendicular to the mathematical slices; it can then be considered as a reliable estimate of the line of action. The accuracy of the method has been tested for various reconstruction parameters and muscle shapes. The results of these tests show that the accuracy is relatively independent of the direction in which the sectional images have been made and that, except for relatively short and thick muscles, the estimated lines of action deviated less than about 2 degrees from the theoretical one. The presented method is a relatively simple mathematical technique which can be used easily for muscles reconstructed in vivo from routinely obtained sectional MRI or CT images.     

Effect of acute cyanide intoxication on the active transport of amino acids in brain slices

(1) Acute hypoxia was produced in adult rats by cyanide inhalation and the effect on the active transport of amino acids was studied in brain slices. (2) Initial and steady-state accumulation of amino acids and rates of amino acid exit were identical in brain slices from control and treated animals when a glucose-containing incubation medium was used. (3) When the incubation was carried out in a glucose-free incubation medium, the inhibition of initial and steady-state accumulation and the stimulation of amino acid exit observed in control slices were significantly reduced or abolished in slices from treated animals. (4) Tissue swelling, size of ‘inulin space’ and glucose consumption did not differ in the two groups of animals. (5) Also the respiration rate was identical in slices from control and treated animals incubated in the presence of glucose. In the absence of added substrate, brain slices from treated animals consumed 15-20 per cent more oxygen than control slices. (6) A possible correlation between the effects observed on amino acid transport and on respiration is suggested. The reasons why cyanide given in vivo or added in vitro have different effects on amino acid transport in brain slices are discussed.     

THE EFFECT OF PHOSPHOLIPASES ON THE UPTAKE OF ATROPINE AND ACETYLCHOLINE BY SLICES OF MOUSE BRAIN CORTEX

The uptake of [³H]atropine, [³H]acetylcholine and [¹⁴C]inulin in mouse brain cortex slices was studied in slices treated with phospholipases A or C. In control experiments the slices took up atropine and acetylcholine against a concentration gradient, indicating active uptake. This uptake was decreased by ouabain, by anaerobic conditions and by an increase in the potassium ion concentration. The phospholipases were found to decrease the uptake of atropine and particularly that of acetylcholine in the slices. The uptake of labelled inulin in enzyme-treated slices, as compared to untreated slices, was not decreased, indicating no change in the inulin space. The effect of the phospholipases was time dependent and, up to a certainlimit, concentration dependent. The effect of ouabain in decreasing the uptake of atropine was not eliminated by the enzyme treatment. The effect of anaerobic conditions in decreasing the uptake was weak after treatment with phospholipases. The effect of higher concentrations of potassium ions was abolished by treatment with phospholipase A. The results emphasize the importance of phospholipids as substances controlling structural order in membranes and suggest their participation in active transport.     

Movements of radioactive sodium in cerebral-cortex slices in response to electrical stimulation

1. Sodium exchange was measured with ²⁴Na in incubated guinea-pig cerebral-cortex slices maintained under adequate metabolic conditions with a steady content of fluid and ions resembling that of brain in vivo. 2. Evidence was obtained indicating that Na⁺ ions behaved in the inulin space as if they were extracellular, and that their entry into the non-inulin space of unstimulated tissue was about 10 times slower and could be separated, on the basis of complete exchangeability, into two components, a `fast' one, which reacted to electrical stimulation, and a `slow' one, exchanging at a rate of about 8μequiv./g./hr., which was not affected by stimulation. 3. The average rate of sodium turnover in unstimulated slices was 175–275μequiv./g./hr., whereas that for stimulated slices was approx. 4–6 times this, or 1050–1180μequiv./g./hr. The stimulated rate was equivalent to a turnover of 32% of the sodium in the non-inulin space/min., or 3mμequiv./g./impulse. 4. Response to the onset of stimulation appeared to be immediate, but after cessation of stimulation increased sodium movements persisted for several minutes before return to unstimulated values. 5. Calculations based on electrochemical gradients suggested that about one-quarter of the energy available from respiration was required for sodium and potassium transport at maximal rates in both unstimulated and stimulated cerebral-cortex slices.