Effects of lithium and potassium on recovery of solute uptake capacity of Acer pseudoplatanus cells after gas-shock

At concentrations of 10-^?3M, Li⁺ inhibits the recovery of solute uptake capacity of Acer pseudoplatanus L. cell suspension cultures after gas-shock (i.e. after rapid exchange of the atmosphere in the culture flasks for ambient air). It also reduces solute uptake capacity of cells having already attained high rates of uptake during recovery from gas-shock. The effects of Li⁺ are much greater in cells which have been cultivated in 7 mM K⁺ solution than in cells cultivated with higher K⁺ levels (19 mM). Increasing K⁺ concentration during recovery reverses the effect of 10^–3M Li⁺ and, with sufficiently high concentrations of K⁺ (≥ 10-^?2M) during recovery, the solute uptake capacity of the fully recovered cells can even become greater than that of the control, at least for the low values of substrate concentration (here sulphate 10-^?5M). Since Li⁺ does not affect the time course of solute uptake measured over 15–20 min, it is thought that it interacts with the synthesis and turnover of the solute uptake machinery of the Acer pseudoplatanus cells. Thermodynamic analysis of the flux data also supports the hypothesis that Li⁺ inhibits the biosynthesis of specific sites of solute permeation, but it does not rule out the possibility that K⁺ interferes rather on the forces acting on the transport of the considered solutes than on the catalytic structures of permeation.     

Osmotic responses of unicellular blue-green algae (cyanobacteria): changes in cell volume and intracellular solute levels in response to hyperosmotic treatment

Abstract Changes in cell volume and solute content upon hyperosmotic shock have been studied for six unicellular blue-green algae (cyanobacteria): Synechococcus PCC 6301, PCC 6311; Synechocystis PCC 6702, PCC 6714, PCC 6803 and PCC 7008. The extent of change in volume was shown to be dependent upon the solute used to establish the osmotic gradient, with cells in NaCl showing a reduced shrinkage when compared to cells in media containing added sorbitol and sucrose. Uptake of extracellular solutes during hyperosmotic shock was observed in Synechocystis PCC 6714, with maximum accumulation of external solutes in NaCl and minimum solute uptake in sucrose solutions. Conversely, solute loss from the cells (K⁺ and amino acids) was greatest in sucrose-containing media and least in NaCl. The results show that these blue-green algae do not behave as ‘ideal osmometers’ in media of high osmotic strength. It is proposed that short-term changes in plasmalemma permeability in these organisms may be due to transient membrane instability resulting from osmotic imbalance between the cell and its surrounding fluid at the onset of hyperosmotic shock.     

RABBIT SCIATIC NERVE FASCICLE AND''ENDONEURIAL''PREPARATIONS FOR IN VITRO STUDIES OF PERIPHERAL NERVE GLUCOSE METABOLISM

Abstract— Suitable preparations for in vitro studies of the composite glucose and energy metabolism of peripheral nerve axons and Schwann cells have not been available. Methods are described for the preparation and incubation of a defined segment of a rabbit sciatic nerve fascicle, free of epineurial contamination, but with an intact perineurial membrane; removing the perineurium provides in addition an‘endoneurial’preparation. Conditions were selected for incubating each preparation with glucose that maintained stable P-creatine and ATP concentrations and a stable rate of O₂ uptake; under these conditions the preparations retained an unaltered EM appearance during a 2-h incubation. Glucose diffusion into the endoneurial compartment of the fascicle is restricted, possibly by the perineurial membrane, and a higher medium glucose concentration (20 mM) was required to maintain a steady state of energy metabolism in this preparation than in the‘endoneurial’preparation, which was incubated with 5 mwglucose. The‘endoneurial’preparation required 0.50 mm -myoinositol in the medium to prevent a decrease in tissue free myoinositol and a slow decrease in O₂ uptake, which occurred when it was omitted. Under the incubation conditions selected the glucose concentrations in the‘endoneurial’preparation and in the endoneurial compartment of the fascicle were reasonably similar, and the preparations had similar rates of respiration, similar estimated rates of glucose utilization, and similar relative rates of respiration and lactate production. The preparations derive the major fraction of their energy requirements from respiration. Their rates of O₂ uptake are 60% higher than the previous indirect estimate of O₂ uptake in whole rabbit tibial nerve in situ. Constant rates of incorporation of ¹⁴C from [U-¹⁴C]glucose into CO₂ and total lipid were observed in the‘endoneurial’preparation after a 15-min equilibration period. The preparations reported provide suitable tools for in vitro studies of peripheral nerve metabolism not previously available.     

Use of exogenous glycine betaine and its precursor choline as osmoprotectants in Antarctic sea‐ice diatoms1

Wide salinity ranges experienced during the seasonal freeze and melt of sea ice likely constrain many biological processes. Microorganisms generally protect against fluctuating salinities through the uptake, production, and release of compatible solutes. Little is known, however, about the use or fate of glycine betaine (GBT hereafter), one of the most common compatible solutes, in sea‐ice diatoms confronted with shifts in salinity. We quantified intracellular concentrations and used [¹⁴C]‐labeled compounds to track the uptake and fate of the nitrogen‐containing osmolyte GBT and its precursor choline in three Antarctic sea‐ice diatoms Nitzschia lecointei, Navicula cf. perminuta, and Fragilariopsis cylindrus at ?1°C. Experiments show that these diatoms have effective transporters for GBT, but take up lesser amounts of choline. Neither compound was respired. Uptake of GBT protected cells against hyperosmotic shock and corresponded with reduced production of extracellular polysaccharides in N. lecointei cells, which released 85% of the retained GBT following hypoosmotic shock. The ability of sea‐ice diatoms to rapidly scavenge and release compatible solutes is likely an important strategy for survival during steep fluctuations in salinity. The release and recycling of compatible solutes may play an important role in algal–bacterial interactions and nitrogen cycling within the semi‐enclosed brines of sea ice.     

Late migration and seawater entry is physiologically disadvantageous for American shad juveniles

Juvenile American shad Alosa sapidissima were subjected to isothermal transfers into sea water (salinity 24)‘early’(1 September; 24° C) and ‘late’(10 November; 10° C) in the autumn migratory season. Early acclimation resulted in a modest osmotic perturbation that recovered rapidly. Haematocrit declined by 14% at 24 h, recovering within 48 h. Plasma osmolality increased by 6% at 4 h, recovering within 8 h. Early acclimation caused a two‐fold increase in gill Na⁺, K⁺‐ATPase activity by 24 h and a four‐fold increase by 4 days. The number of chloride cells on the primary gill filament increased two‐fold by 4 days. Chloride cells on the secondary lamellae rapidly decreased from 22 cells mm^?1 to <2 cells mm^?1 within 4 days. Late acclimation resulted in a severe and protracted osmotic perturbation. Haematocrit levels declined by 23% at 4 days, recovering by 14 days. Plasma osmolality increased by 36% by 48 h, recovering by 4 days. Initial gill Na⁺, K⁺‐ATPase activity was two‐fold greater than in ‘early’ fish and did not change during acclimation. Initial numbers of chloride cells on the primary filament were two‐fold greater than ‘early’ fish and did not increase during acclimation. Initial number of chloride cells on the secondary lamellae was five‐fold greater than ‘early’ fish (116 v. 22 cells mm^?1) and declined to negligible numbers over 14 days. Differences between initial measures for ‘early’ and ‘late’ fish reflect previously described physiological changes associated with migration. These data indicate that late migrants face a greater physiological challenge during seawater acclimation than early migrants. Physiological performance apparently limits the observed duration of autumnal migration.     

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.     

Transient,specific and extremely rapid release of osmolytes from growing cells of Escherichia coli K-12 exposed to hypoosmotic shock

The influence of hypoosmotic shock on the solute content of growing Escherichia coli K-12 cells was investigated at 37°C. Within 20 s after the shock the cells had released most of their osmolytes K⁺, glutamate and trehalose. This release was specific and not due to rupture of the cell membrane, since under these conditions i) the cells neither lost protein nor ATP, ii)[¹⁴C]-labeled sucrose did not enter the cytoplasm from the periplasm, and iii) except for their glutamate and aspartate level, which decreased, the amino acid pool of alanine, lysine and arginine of the cells remained approximately constant. Within a minute after the shock the cells started to reaccumulate parts of their previously released glutamate, aspartate and K⁺, but not trehalose and resumed growth within 10 min after the shock. Experiments with K⁺-transport mutants showed that none of the genetically-identified K⁺ transport systems is involved in the K⁺-release process. Reaccumulation of K⁺ took place via the uptake systems TrkG and TrkH. The possibility is discussed that the exit of solutes after hypoosmotic shock occurs via several stretch-activated channels, which each allow the release of a specific osmolyte.Abbreviations OD₅₇₈ optical density at 578 nm - TEA triethylammonium - TMG 1,-S-methyl--thiogalactopyranoside     

Dependence of the kinetics of secondary active transports in yeast on H+-ATPase acidification

Acidification of the external medium of the yeast Saccharomyces cerevisiae, mainly caused by proton extrusion by plasma membrane H⁺-ATPase, was inhibited to different degrees by D₂O, diethylstilbestrol, suloctidil, vanadate, erythrosin B, cupric sulfate and dicyclohexylcarbodiimide. The same pattern of inhibition was found with the uptake of amino acids, adenine, uracil, and phosphate and sulfate anions. An increase of the acidification rate by dioctanoylglycerol also increased the rates of uptake of adenine and of glutamic acid. In contrast, a decrease of the membrane potential at pH 4.5 from a mean of -40 to -20 mV caused by 20 mm KC1 had no effect on the transport rates. The ATPase-deficient mutant S. cerevisiae pmal-105 showed a markedly lower uptake of all the above solutes as compared with the wild type, while its membrane potential and pH were unchanged.Other types of acidification (spontaneous upon suspension; K⁺ stimulated) did not affect the secondary uptake systems.     

Heat shock response ofChlorella protothecoides during greening

Heterotrophically grown cells ofChlorella protothecoides were transferred to autotrophic medium and allowed to green at 25°C. The protein synthetic activity of the greening cells measured in terms of incorporation of [³5S]-methionine showed a maximum around 20 h of greening and thereafter started declining. Similarly, an analysis of densitometric tracings of the fluorographic profile of the polypeptides associated with both total cellular fraction and membrane fractions during different hours of greening revealed that maximum number of polypeptides were getting labelled around 20 h of greening. At 20 h of greening, the cells were shifted to 40°C and the effect of heat shock on protein synthesis was studied. The heat shock treatment caused a definite decrease in the incorporation of [³⁵S]-methionine into proteins. Due to heat shock, the synthesis of total soluble proteins was affected much more than that of the thylakoid membrane bound proteins. When the cells were transferred back to 25°C after a brief period of heat shock at 40°C, there was a considerable recovery in the protein synthesis and this recovery was found to be significant in the case of soluble proteins, while there was no such definite recovery in the synthesis of thylakoid membrane bound proteins.     

Erythrocyte membrane sulfhydryl groups and cation permeability

Reaction of the slowly penetrating organic mercurial compound parachloromercuribenzene sulfonate (PCMBS) with intact erythrocytes has been characterized. Addition of concentrations of PCMBS which result in binding within the interior of the membrane of more than 1.9 × 10^?18 moles/cell produces alterations in Na⁺ and K⁺ permeability, but does not affect choline permeability. However, the increased cation permeability is observed only after a lag period of over two hours. After ten hours, a spontaneous slow “recovery” to normal rates of K⁺ leakage occurs at 25°C but not at 2°C. Subsequent to the effects on cation balance, increasing degrees of hemolysis occur, interpreted as colloid osmotic lysis. The relationships between the binding of the agent and its effects are as follows: a small, rapid initial uptake does not affect cation permeability; the subsequent slower uptake is associated with increased leakage of K⁺ and Na⁺; and the recovery at 25°C is associated with desorption of about half of the PCMBS due to competition by soluble thiol substances released into the medium from the cells. Desorption and “recovery” can be mimicked at any time by addition of small amounts of protein in the medium. The half of the PCMBS that cannot be desorbed is assumed to be bound by the hemoglobin inside the cell. The sulfhydryl groups involved in control of cation permeability constitute only a fraction of the total within the membrane (4–18%). They are located within the interior of the membrane separated from the medium and from the interior of the cell by diffusion barriers to PCMBS.     

Increased Ca++ uptake by erythrocytes infected with malaria parasites: Evidence for exported proteins and novel inhibitors

Malaria parasites export many proteins into their host erythrocytes and increase membrane permeability to diverse solutes. Although most solutes use a broad‐selectivity channel known as the plasmodial surface anion channel, increased Ca⁺⁺ uptake is mediated by a distinct, poorly characterised mechanism that appears to be essential for the intracellular parasite. Here, we examined infected cell Ca⁺⁺ uptake with a kinetic fluorescence assay and the virulent human pathogen, Plasmodium falciparum. Cell surface labelling with N‐hydroxysulfosuccinimide esters revealed differing effects on transport into infected and uninfected cells, indicating that Ca⁺⁺ uptake at the infected cell surface is mediated by new or altered proteins at the host membrane. Conditional knockdown of PTEX, a translocon for export of parasite proteins into the host cell, significantly reduced infected cell Ca⁺⁺ permeability, suggesting involvement of parasite‐encoded proteins trafficked to the host membrane. A high‐throughput chemical screen identified the first Ca⁺⁺ transport inhibitors active against Plasmodium‐infected cells. These novel chemical scaffolds inhibit both uptake and parasite growth; improved in vitro potency at reduced free [Ca⁺⁺] is consistent with parasite killing specifically via action on one or more Ca⁺⁺ transporters. These inhibitors should provide mechanistic insights into malaria parasite Ca⁺⁺ transport and may be starting points for new antimalarial drugs.     

Ultrarapid endocytotic uptake of large molecules inDunaliella species

Summary This paper describes the uptake of Lucifer Yellow carbohydrazide and fluorescent dextrans labeled with fluorescein isothiocyanate or Sodium Green (molecular masses ranging from 522 to 2 × 10⁶ Da) byDunaliella spp. halotolerant unicellular green algae isolated from salt pools in the Sinai peninsula. The fluorescent dyes were taken up into a set of vesicles around the nucleus and just above the chloroplast. It proved impossible to inhibit uptake of the fluorescent compounds in cells treated with a large variety of metabolic and other inhibitors. Cell labeling was complete within half a minute of addition of fluorescent compounds to the outside medium; efflux was equally rapid. The results are interpreted in terms of an endocytotic process whereby the outside medium, together with any substance dissolved in it, remains within vesicles enclosed within the cell body but cycles rapidly between the plasma membrane and the interior of the cell. The outside medium does not pass across the vesicular membrane, nor enters the cytosol.Abbreviations LYCH Lucifer Yellow carbohydrazide - FITC fluorescein-5-isothiocyanate - TCA trichloroacetic acid - DMSO dimethylsulfoxide - NEM N-ethyl maleimide - DNP dinitrophenol - CCCP m-chlorocarbonyl-cyanide phenylhydrazone - APM amiprophos-methyl     

Factors inducing regeneration response in oat (Avena sativa L.) anther culture

The efficiency of embryogenesis of anther culture was compared using four cultivars of oat (Avena sativa L.): ‘Akt’, ‘Bingo’, ‘Bajka’, and ‘Chwat’. Despite the high resistance of oat to the process of androgenesis, all tested cultivars produced embryo-like structures and only two of them, ‘Akt’ and ‘Chwat’, produced fertile doubled haploid plants. A strong cultivar dependency was observed during induction of androgenesis. Further, cold pretreatment together with high temperature shock enhanced the efficiency of this technique. The highest number of embryo-like structures and haploid plants was obtained from cv. ‘Chwat’ (3.6% and 0.8%, respectively). Embryo-like structure formation also depended on the distance from the base of the flag leaf to the penultimate leaf of the panicle. Most of them were observed on anthers harvested from panicles of which the distance from the base of the flag leaf to the penultimate leaf was less than 4 cm. The presence of the induction medium supplemented with different plant growth regulators was essential for the induction of embryo-like structures but did not increase the production of haploid plants and doubled haploid lines. The highest number of embryo-like structures and plants was obtained on W14 medium with the addition of 2.0 mg/dm³ 2,4-dichlorophenoxyacetic acid and 0.5 mg/dm³ kinetin (2.7%). The low haploid plant regeneration rate (from 0.03 to 0.05%) still limits the practical application of anther culture for the production of doubled haploid lines in oat.

     

Uptake and retention of external solutes from the digest medium during preparation of protoplasts

The extent to which solutes present in the digest medium enter cells and are retained during preparation of protoplasts was investigated. When barley (Hordeum vulgare, L. cv. Clipper) leaf slices were incubated in sorbitol there was considerable uptake of sorbitol into the tissue, which continued for up to 6 h and was dependent on the sorbitol concentration in the external medium. Protoplasts prepared by digesting leaf slices in a medium containing [¹⁴C]sorbitol but isolated and purified in media with unlabelled sorbitol contained significant amounts of [¹⁴C]sorbitol. From measurements of the protoplast volume, the internal sorbitol concentration was calculated to be 100 mM, assuming uniform distribution of the sorbitol throughout the protoplasm. The uptake of sorbitol during digestion and its retention by protoplasts was confirmed by measuring sugars in protoplast extracts by gas sucrose or inositol. Vacuoles prepared from the protoplasts contained 83% of the sorbitol present in protoplasts. It is concluded that considerable uptake of solutes from the external medium occurs during digestion of leaf tissue and that these solutes are retained within the protoplasts during isolation and purification. The solutes appear to be uniformly distributed throughout the subcellular compartments of the protoplast.     

PHYSIOLOGICAL AND OPTICAL PROPERTIES OF RHIZOSOLENIA FORMOSA (BACILLARIOPHYCEAE) IN THE CONTEXT OF OPEN-OCEAN VERTICAL MIGRATION1

Cultures of Rhizosolenia formosa H. Peragallo were studied to assess whether or not physiological and optical characteristics of this large diatom were consistent with the ability to migrate vertically in the open ocean. Time-course experiments examined changes in chemical composition and buoyancy of R. formosa during nitrate (N)–replete growth, N starvation, and recovery. Cells could maintain unbalanced growth for at least 53 h after depletion of ambient nitrate. Increases in C:N and carbohydrate: protein ratios observed during N starvation reversed within 24 h of reintroduction of nitrate to culture medium. Buoyancy was related to nutrition: Upon N depletion, the percentage of positively buoyant cells decreased to 4% from 11% but reverted to 9% within 12 h of nitrate readdition. Cells took up nitrate in the dark. Nitrogen-specific uptake rates averaged 0.48 d^?1; these rates were higher than N-specific growth rates (0. 15 d^?1), indicating the potential for luxury consumption of nitrate, which can be stored for later use. Measurements of photosynthesis vs. irradiance, chlorophyll-specific absorption (a_ph*(λ)), and pigment composition showed that cells may be adapted for growth under a wide range of irradiances. Values of a_ph*(λ) were lower for N-depleted cells than for N-replete cells, and N-depleted cells had higher ratios of total carotenoids to chlorophyll a. Aggregation of chloroplasts was more pronounced in N-depleted cells. These are possibly photoprotective mechanisms that would be an advantage to N-depleted cells in surface waters. Compounds that absorb in the ultraviolet region were detected in N-replete cells but were absent in N-depleted cultures. Overall, these results have important implications for migrations of Rhizosolenia in nature. Cells may survive fairly long periods in N-depleted surface waters and will continue to take up carbon; then they can resume nitrate uptake and revert to positive buoyancy upon returning to deep, N-rich water. Uncoupled uptake of carbon and nitrogen during migrations of Rhizosolenia is a form of new production that may result in the net removal of carbon from oceanic surface waters.     

PROTEIN BIOSYNTHESIS IN SALT-SHOCKED CELLS OF STICHOCOCCUS BACILLARIS (CHLOROPHYCEAE)1

We have developed an in vivo¹⁴C-amino acid labelling procedure for monitoring protein synthesis in salt-shocked cells of Stichococcus bacillaris Naeg. This alga possesses an efficient transport system for the uptake of leucine, methionine, and phenylalanine and rapidly incorporates these amino acids into proteins. Of the three amino acids tested, ¹⁴C-phenylalanine is ideally suited for labelling proteins in S. bacillaris, as it establishes an early equilibrium between uptake and incorporation of the amino acid into proteins. The uptake of phenylalanine shows little inhibition following transfer of cells to higher salinities and is also not affected in short-term experiments by the presence of the protein inhibitors cycloheximide and chloramphenicol. While Stichococcus bacillaris grows slowly at salinities equal to, or higher than, 150% artificial seawater (ASW), it shows surprising rates of recovery of major physiological functions following considerable salt shocks. Cells transferred from 33 to 150% ASW show complete recovery of photosynthetic activity and protein synthesis within 10–15 min, and cell transferred from 33 to 300% ASW recover 50% of their capacity to synthesize proteins within. 1 h. Cytoplasmic and organellar protein synthesis appears to be equally sensitive to the effects of salt shocks according to studies with protein synthesis inhibitors.     

Isolation and maintenance of differentiated exocrine gland acinar cells in vitro

Summary Methods have been developed for isolating and maintaining differentiated rat exorbital lacrimal, parotid, and pancreatic acinar cells for up to 1 month in culture. The dissociated cells retained their differentiated morphology when cultured as suspension cultures at 35°C with the appropriate secretagogue (exorbital lacrimal, 10⁻⁶ M carbamyl choline; pancreas 10⁻⁵ M carbamyl choline; parotid, 10⁻⁶ M isoproterenol). Under these conditions the cells remained viable and differentiated for up to 4 weeks in culture and continued to incorporate³H-leucine at rates similar to those of freshly isolated cells. If secretagogue was omitted from the medium, the cells rapidly degenerated. These results indicate that differentiated from the medium, the cells rapidly degenerated. These results indicate that differentiated exocrine gland acinar cells may be maintained in vitro and utilized as a model system for the study of secretory processes.     

Regulation of H Excretion : EFFECTS OF OSMOTIC SHOCK

Osmotic shock, a 15-minute plasmolysis followed by a 15-minute rehydration in the cold, is a nondestructive technique which inhibits fusicoccin-stimulated H⁺ excretion from oat mesophyll cells (Avena sativa L.). Osmotic shock also causes a loss of intracellular solutes and stimulates H⁺ uptake, but osmoregulation can still occur, and enhanced H⁺ uptake is observed only at low external pH. It is concluded that osmotic shock interferes directly with the excretion of H⁺ rather than affecting only H⁺ or counter ion uptake.     

PINOCYTOSIS IN ACANTHAMOEBA CASTELLANII : Kinetics and Morphology

The uptake of radioactively labeled albumin, inulin, leucine, and glucose by Acanthamoeba castellanii (Neff strain) was measured. The uptake is linear with time and appears to be continuous under the conditions of these experiments. Uptake is abolished at 0°C. No evidence for saturation of the uptake mechanism was obtained with either albumin or leucine. Each of the four tracer molecules enters the ameba at a similar rate when the uptake is calculated as volume of fluid ingested per unit time. The data suggest that each of these molecules enters the cell by pinocytosis. The highest rate of uptake was obtained with cells in their usual culture medium containing proteose peptone, glucose, and salts but pinocytosis also continued at a reduced rate in a simple salt solution. The calculated volume of fluid taken in during pinocytosis in culture medium was about 2 µl/hr per 10⁶ cells. The route of uptake was examined in the electron microscope using horseradish peroxidase (HRP) as a tracer. HRP activity was found exclusively within membrane profiles within the cytoplasm, confirming the pinocytotic mode of uptake. An estimate of the rate of surface membrane turnover due to pinocytosis was made using the biochemical and morphological data obtained. This estimate suggests that the plasma membrane turnover of one cell is on the order of several times an hour.