Statoliths and microfilaments in plant cells

Microfilaments have been demonstrated in rhizoids of Chara fragilis Desvaux by labelling of actin with rhodamine-conjugated phalloidin. Each rhizoid contains thick microfilament-bundles arranged longitudinally in the basal region. In the subapical and apical regions, much thinner bundles exist which contact the statoliths and encircle them in the form of a dense envelope. In root statocytes from Lepidium sativum L. the presence of an actin network is indicated by the fact that application of cytochalasin B (25 g·ml^-1 for 4 h) results in an approximately threefold increase in the rate of statolith (amyloplast) sedimentation relative to controls. It is concluded that in gravity-perceiving plant cells statoliths may trigger the transduction mechanism via actin filaments.Abbreviation CB cytochalasin B - ER endoplasmic reticulum - MF microfilament     

Actin polymerization induced by chemotactic peptide and concanavalin A in rat neutrophils

Changes in the state of actin in rat neutrophils were studied after chemotactic peptide and concanavalin A stimulation by using the DNase I inhibition assay. Actin polymerization occurred within seconds after stimulation with F-Met-Leu-Phe and concanavalin A. Pretreatment of cells with cytochalasin D prevented chemotactic peptide-induced actin polymerization. The addition of F-Met-Leu-Phe to lysed cells did not produce any change in actin state. These data offer strong evidence for receptor-induced actin polymerization and support the models implicating actin microfilament formation as a crucial event in cell activation. The observations on platelets, lymphocytes, neutrophils, and islets of Langerhans from different species suggest that actin polymerization might be a universal intracellular event accompanying cell surface receptor perturbation in eukaryotic cells.     

Dynamic reorganization of microfilaments and microtubules is necessary for the expression of non-host resistance in barley coleoptile cells

To show the involvement of microfilaments and microtubules in non-host resistance of barley, partially dissected coleoptiles which had been inoculated with a non-pathogen, Erysiphe pisi, were treated with several actin and tubulin inhibitors. If the coleoptiles were not treated with any of the inhibitors, the non-pathogen always failed to penetrate the coleoptile cells. However, when coleoptiles were treated with actin or tubulin polymerization or depolymerization inhibitors, the non-pathogen was able to penetrate successfully and to form haustoria in coleoptile cells of a non-host plant, barley. Actin polymerization inhibitors, cytochalasins, were more effective in causing an increase in penetration efficiency of E. pisi than tubulin inhibitors. The effects of cytochalasins depended on the kind of cytochalasin; the strength of the actin depolymerizing activity correlated significantly with the efficiency of increasing the penetration of the non-pathogen. When both actin and tubulin inhibitors were added simultaneously, the polarization of defense-related responses, such as massive cytoplasmic aggregation, deposition of papillae and accumulation of autofluorescent compounds, at fungal penetration sites was suppressed. Actin inhibitors did not affect arrangement and stability of microtubules and vice versa, and a double treatment of coleoptile cells with both microfilament and microtubule inhibitors showed an additive effect in increasing the penetration efficiency of E. pisi. Furthermore, cytochalasin A treatment allowed other non-pathogens, Colletotrichum lagenarium and Alternaria alternata, to penetrate successfully into the non-host barley cells. These results strongly suggest that microfilaments and microtubules might play important roles in the expression of non-host resistance of barley.     

Cross-talk between EGFR and T-cadherin: EGFR activation promotes T-cadherin localization to intercellular contacts

Reciprocal cross-talk between receptor tyrosine kinases (RTKs) and classical cadherins (e.g. EGFR/E-cadherin, VEGFR/VE-cadherin) has gained appreciation as a combinatorial molecular mechanism enabling diversification of the signalling environment and according differential cellular responses. Atypical glycosylphosphatidylinositol (GPI)-anchored T-cadherin (T-cad) was recently demonstrated to function as a negative auxiliary regulator of EGFR pathway activation in A431 squamous cell carcinoma (SCC) cells. Here we investigate the reciprocal impact of EGFR activation on T-cad. In resting A431 T-cad was distributed globally over the cell body. Following EGF stimulation T-cad was redistributed to the sites of cell–cell contact where it colocalized with phosphorylated EGFR^Tyr1068. T-cad redistribution was not affected by endomembrane protein trafficking inhibitor brefeldin A or de novo protein synthesis inhibitor cycloheximide, supporting mobilization of plasma membrane associated T-cad. EGF-induced relocalization of T-cad to cell–cell contacts could be abrogated by specific inhibitors of EGFR tyrosine kinase activity (gefitinib or lapatinib), lipid raft integrity (filipin), actin microfilament polymerization (cytochalasin D or cytochalasin B), p38MAPK (SB203580) or Rac1 (compound4). Erk1/2 inhibitor PD98059 increased phospho-EGFR^tyr1068 levels and not only amplified effects of EGF but also per se promoted some relocalization of T-cad to cell–cell contacts. Rac1 activation by EGF was inhibited by gefitinib, lapatinib or SB203580 but amplified by PD98059. Taken together our data suggest that T-cad translocation to cell–cell contacts is sensitive to the activity status of EGFR, requires lipid raft domain integrity and actin filament polymerization, and crucial intracellular signalling mediators include Rac1 and p38MAPK. The study has revealed a novel aspect of reciprocal cross-talk between EGFR and T-cad.     

Analysis of broth-cultured Bacillus atrophaeus and Bacillus cereus spores

Aims: To compare physical properties of spores that were produced in broth sporulation media at greater than 10⁸ spores ml⁻¹. Methods and Results: Bacillus atrophaeus reproducibly sporulated in nutrient broth (NB) and sporulation salts. Microscopy measurements showed that the spores were 0·68 ± 0·11 μm wide and 1·21 ± 0·18 μm long. Coulter Multisizer (CM3) measurements revealed the spore volumes and volume-equivalent spherical diameters, which were 0·48 ± 0·38 μm³ and 0·97 ± 0·07 μm, respectively. Bacillus cereus reproducibly sporulated in NB, sporulation salts, 200 mmol l⁻¹ glutamate and antifoam. Spores were 0·95 ± 0·11 μm wide and 1·31 ± 0·17 μm long. Spore volumes were 0·78 ± 0·61 μm³ and volume-equivalent spherical diameters were 1·14 ± 0·11 μm. Bacillus atrophaeus spores were hydrophilic and B. cereus spores were hydrophobic. However, spore hydrophobicity was significantly altered after treatment with pH-adjusted bleach. Conclusions: The utility of a CM3 for both quantifying Bacillus spores and measuring spore sizes was demonstrated, although the volume between spore exosporium and spore coat was not measured. This study showed fundamental differences between spores from a Bacillus subtilis- and B. cereus-group species. Significance and Impact of the Study: This is useful for developing standard methods for broth spore production and physical characterization of both living and decontaminated spores.     

Cytochalasin B binding to Ehrlich ascites tumor cells and its relationship to glucose carrier

Cultured Ehrlich ascites tumor cells equilibrate d-glucose via a carrier mechanism with a K_m and V of 14 mM and 3 μmol/s per ml cells, respectively. Cytochalasin B competitively inhibits this carrier-mediated glycose transport with an inhibition constant (K_i) of approx. 5·10^?7 M. Cytochalasin E does not inhibit this carrier function. With cytochalasin B concentrations up to 1·10^?5 M, the range where the inhibition develops to practical completion, three discrete cytochalasin B binding sites, namely L, M and H, are distinguished. The cytochalasin B binding at L site shows a dissociation constant (K_d) of approx. 1·10^-6 M, represents about 30% of the total cytochalasin B binding of the cell (8·10⁶ molecules/cell), is sensitively displaced by cytochalasin E but not by d-glucose, and is located in cytosol. The cytochalasin B binding to M site shows a K_d of 4–6·10^?7 M, represents approx. 60% of the total saturable binding (14·10⁶ molecules/cell), is specifically displaced by d-glucose with a displacement constant of 15 mM, but not by l-glucose, and is insensitive to cytochalasin E. The sites are membrane-bound and extractable with Triton X-100 but not by EDTA in alkaline pH. The cytochalasin B binding at H site shows a K_d of 2–6 · 10^?8 M, represents less than 10% of the total sites (2 · 10⁶ molecules/cell), is not affected by either glucose or cytochalasin E and is of non-cytosol origin. It is concluded that the cytochalasin B binding at M site is responsible for the glucose carrier inhibition by cytochalasin B and the Ehrlich ascites cell is unique among other animal cells in its high content of this site. Approx. 16-fold purification of this site has been achieved.     

Comparative study on effects of cytochalasins B and D on F-actin content in different cell lines and different culture conditions.

Effects of cytochalasins on actin polymerization state in living cells were measured using fluorimetry of TRITC-phalloidin bound to F-actin. Normal (3T3) and tumour (SV-3T3, B16 melanoma, and Ehrlich ascites) cells were treated with cytochalasin B and cytochalasin D (1 microgram/ml). Three effects of cytochalasins were demonstrated--depolymerization of F-actin, promotion of polymerization, and redistribution of actin without change in polymerization state. Occurrence of a given effect was dependent on cell type, cell density, cytochalasin concentration and type. This indicates that cells from different lines, and even the same cells in different culture conditions may differ significantly in their state of actin polymerization, which we suppose is the cause of their different reactions to cytochalasins. Accordingly, caution should be taken in generalizing the results concerning the effect of cytochalasis on the polymerization state of actin.     

Actin polymerization in murine B lymphocytes is stimulated by cytochalasin D but not by anti-immunoglobulin.

One might predict that cytochalasin D, which slows polymerization of actin in solution and which inhibits actin-containing microfilament function in live B lymphocytes, would also prevent actin polymerization in these cells. However, we have used the NBD-Phallacidin flow cytometric assay for F-actin and the DNase I inhibition assay for G-actin to demonstrate that cytochalasin D (at 20 micrograms/ml and higher) stimulates actin polymerization in murine B lymphocytes within the first 30 sec of exposure. A similar response was seen in human neutrophils. Actin polymerization induced in neutrophils by chemotactic peptides has been linked to activation of the polyphosphoinositide-calcium increase-protein kinase C signal transduction pathway. As B lymphocytes also transduce signals using this pathway, we investigated whether cytochalasin D induced actin polymerization by activating this pathway. Cytochalasin D and ionomycin both stimulated a rapid increase in internal calcium (by 1 min) in the B cell which was inhibitable by EGTA, implicating calcium influx. Ionomycin also induced actin polymerization, detectable later, by 10 min. EGTA blocked the ionomycin-induced actin polymerization, but not that induced by cytochalasin D. Cytochalasin D-induced actin polymerization was not associated with detectable hydrolysis of polyphosphoinositides, nor was it inhibited by H7 (a protein kinase C inhibitor) or by HA1004 (an inhibitor of cyclic nucleotide-dependent kinases). Furthermore, anti-immunoglobulin antibodies, which stimulate B lymphocytes through the polyphosphoinositide hydrolysis-calcium increase-protein kinase C pathway, failed to induce actin polymerization in these cells. These antibodies did, however, stimulate the cells to perform activities that involve actin-containing microfilaments. Other primary activators of B lymphocytes (dextran sulfate, PMA, and LPS) and a panel of lymphokines previously shown to enhance B lymphocyte activation (IL-1, IL-2, IL-4, IL-5) were also screened in the F-actin assay and no evidence for actin polymerization was found. We conclude that the actin polymerization response to cytochalasin D in the B cell does not involve the polyphosphoinositide hydrolysis-calcium increase-protein kinase C pathway, nor does it depend on cyclic nucleotide-dependent kinases. Furthermore, our studies failed to provide any evidence that early actin polymerization occurs in murine B lymphocyte activation.     

Binding of [3H]cytochalasin B and [3H]colchicine to isolated liver plasma membranes

The binding to isolated hepatocyte plasma membranes of radioactively labelled inhibitors of microfilamentous and microtubular protein function ([³H]cytochalasin B and [³H]colchicine, respectively) was studied as one means of assessing the degree of association of these proteins with cell surface membranes. [³H]Cytochalasin B which behaved identically to the unlabelled compound with respect to binding to these membranes was prepared by reduction of cytochalasin A with NaB³H₄. The binding was rapid, readily reversible, proportional to the amount of membrane and relatively insentive to changes of pH or ionic strength. At 10^?6 M [³H]cytochalasin B, glucose or p-chloromercuribenzoate, an inhibitor of glucose transport inhibited binding by about 20%; treatment of membranes with 0.6 M KI which depolymerizes F actin to G actin caused about 60% inhibition of binding. These two types of inhibition were additive indicating two separate classes of binding sites, one associated with sugar transport and one with microfilaments. Filamentous structures with the diameter of microfilaments (50 Å) were seen in electron micrographs of thin sections of the membranes. At concentrations greater than 10^?5 M [³H]cytochalasin B, binding was proportional to drug concentration, characteristic of non-specific adsorption or partitioning. Intracellular membranes of the hepatocyte also bound [³H]cytochalasin B, those of the smooth endoplasmic reticulum to a greater extent than plasma membranes.[³H]Colchicine bound to plasma membranes in proportion to the amount of membrane and at a rate compatible with binding to tubulin. However, other properties of the binding including effects of temperature, drug concentration and antisera against tubulin were different from those of binding to tubulin. Hence, no evidence was obtained for association of microtubular elements with these membranes. Despite this there appeared to be an interdependence between microtubule and microfilament inhibitors: vinblastine sulfate stimulated [³H]cytochalasin B binding and cytochalasin B stimulated ³H colchicine binding. [³H]Colchicine also bound to intracellular membranes, especially smooth microsomes.     

Kocuria SM1 controls vibriosis in rainbow trout (Oncorhynchus mykiss,Walbaum)

Aims: To develop probiotics for the control of vibriosis caused by Vibrio anguillarum and Vibrio ordalii in finfish. Methods and Results: Kocuria SM1, isolated from the digestive tract of rainbow trout, was administered orally to rainbow trout (Oncorhynchus mykiss) for 2 weeks at a dose equivalent to c. 10⁸ cells per g of feed and then challenged intraperitoneally with V. anguillarum and V. ordalii. Use of SM1 led to a reduction in mortalities to 15–20% compared to 74–80% mortalities in the controls. SM1 stimulated both cellular and humoral immune responses in rainbow trout, by elevation of leucocytes (5·5 ± 0·8 × 10⁶ ml^?1 from 3·7 ± 0·8 × 10⁶ ml^?1), erythrocytes (1·2 ± 0·1 × 10⁸ ml^?1 from 0·8 ± 0·1 × 10⁸ ml^?1), protein (23 ± 4·4 mg ml^?1 from 16 ± 1·3 mg ml^?1), globulin (15·7 ± 0·2 mg ml^?1 from 9·9 ± 0·1 mg ml^?1) and albumin (7·3 ± 0·2 mg ml^?1 from 6·1 ± 0·1 mg ml^?1) levels, upregulation of respiratory burst (0·05 ± 0·01 from 0·02 ± 0·01), complement (56 ± 7·2 units ml^?1 from 40 ± 8·0 units ml^?1), lysozyme (920 ± 128·8 units ml^?1 from 760 ± 115·3 units ml^?1) and bacterial killing activities. Conclusions: Kocuria SM1 successfully controlled vibriosis in rainbow trout, and the mode of action reflected stimulation of the host innate immune system. Significance and Impact of the Study: Probiotics can contribute a significant role in fish disease control strategies, and their use may replace some of the inhibitory chemicals currently used in fish farms.     

A pivotal role of bone remodeling in granulocyte colony stimulating factor induced hematopoietic stem/progenitor cells mobilization

The majority of hematopoietic stem/progenitor cells (HSPCs) reside in bone marrow (BM) surrounded by a specialized environment, which governs HSPC function. Here we investigated the potential role of bone remodeling cells (osteoblasts and osteoclasts) in homeostasis and stress‐induced HSPC mobilization. Peripheral blood (PB) and BM in steady/mobilized state were collected from healthy donors undergoing allogeneic transplantation and from mice treated with granulocyte colony stimulating factor (G‐CSF), parathyroid hormone (PTH), or receptor activator of nuclear factor kappa‐B ligand (RANKL). The number and the functional markers of osteoblasts and osteoclasts were checked by a series of experiments. Our data showed that the number of CD45^?Ter119^? osteopontin (OPN)⁺ osteoblasts was significantly reduced from 4,085 ± 135 cells/femur on Day 0 to 1,032 ± 55 cells/femur on Day 5 in mice (P = 0.02) and from 21.38 ± 0.66 on Day 0 to 14.78 ± 0.65 on Day 5 in healthy donors (P < 0.01). Decrease of osteoblast number leads to reduced level of HSPC mobilization regulators stromal cell‐derived factor‐1 (SDF‐1), stem cell factor (SCF), and OPN. The osteoclast number at bone surface (OC.N/B.s) was significantly increased from 1.53 ± 0.12 on Day 0 to 4.42 ± 0.46 on Day 5 (P < 0.01) in G‐CSF‐treated mice and from 0.88 ± 0.20 on Day 0 to 3.24 ± 0.31 on Day 5 (P < 0.01) in human. Serum TRACP‐5b level showed a biphasic trend during G‐CSF treatment. The ratio of osteoblasts number per bone surface (OB.N/B.s) to OC.N/B.s was changed after adding PTH plus RANKL during G‐CSF treatment. In conclusion, short term G‐CSF treatment leads to reduction of osteoblasts and stimulation of osteoclasts, and interrupting bone remodeling balance may contribute to HSPC mobilization. J. Cell. Physiol. © 2012 Wiley Periodicals, Inc.     

The role of microfilaments and of microtubules in taurocholate uptake by isolated rat liver cells

The role of microfilaments and microtubules on bile salt transport was studied by investigating the influence of a microfilament and a microtubule inhibitor, cytochalasin B and colchicine, respectively, on taurocholate uptake by isolated hepatocytes in vitro. Hepatocytes were prepared by the enzyme perfusion method and [¹⁴C]taurocholate uptake velocity was determined by a filtration assay. Taurocholate uptake obeyed Michaelis-Menten kinetics, maximal uptake velocity and apparent half-saturation constants averaging $\text{0.87 ±}\text{SD}\text{0.05}\text{nmol}\text{· s}{}^{\mathrm{?1}}\text{· 10}{}^{\mathrm{?6}}\text{cells}$ and $\text{10.9 ± 1.8 μ}\text{M}$, respectively. Cytochalasin B ($\text{4.2–420 μ}\text{M}$) inhibited taurocholate uptake in a competitive fashion; $\text{K}{}_{\mathrm{<mtext>i</mtext>}}$ being $\text{33 ± 7 μ}\text{M}$. At concentrations above 100 μM the compound decreased ³⁶Cl membrane potential and intracellular K⁺ concentration. Other parameters of cell viability were not affected by cytochalasin B. Colchicine (0.1–1.0 mM), by contrast, inhibited taurocholate uptake non-competitively, $\text{K}{}_{\mathrm{<mtext>i</mtext>}}$ being $\text{0.47 ± 0.07}\text{mM}$. The inhibition brought about by colchicine was considerably smaller than that induced by cytochalasin B. None of the parameters of cell viability tested was affected by colchicine. These results suggest that microfilaments may be involved in the carrier-mediated hepatocellular transport of bile salts. This could, at least in part, account for cytochalasin B-induced cholestasis. The contribution of the microtubular system, if any, is less important quantitatively. The mechanisms whereby these two components of the cytoskeleton partake in bile salt transport remain to be elucidated.     

Effect of fasting on glycogen metabolism and activities of glycolytic and gluconeogenic enzymes in the mudskipper Boleophthalmus boddaerti

During starvation, muscle glycogen in Boleophthalmus boddaerti was utilized preferentially over liver glycogen. In the first 10 days of fasting, the ratio of the active‘a’form of glycogen phosphorylase to total phosphorylase present in the liver was small. During this period, the active‘I’form of glycogen synthetase increased in the same tissue. In the muscle, the phosphorylase‘a’activity declined during the first 7 days and increased thereafter while the total glycogen synthetase activity showed a drastic decline during the first 13 days of fasting. The glycogen level in the liver and muscle of mudskippers starved for 21 days increased after refeeding. After 6 and 12 h refeeding, liver glycogen level was 8·5 ± 2·3 and 6·9 ± 4·5 mg·g wet wt ¹, respectively, as compared to 5·8 ± l·6mg·g wet wt ¹ in unfed fish. Muscle glycogen level after 6 and 12 h refeeding was 0·96±0·76 and 0·82 ± 0·50 mg·g wet wt ¹, respectively, as opposed to 0·21 ± 0·12 mg·g wet wt ¹ in the 21-days fasted fish. At the same time, activities of glycogen phosphorylase in the muscle and liver increased while the active‘I’form of glycogen synthetase showed higher activity in the liver. Since glycogen was resynthesized upon refeeding, this eliminated the possibility that glycogen depletion during starvation was due to stress or physical exhaustion after handling by the investigator. Throughout the experimental starvation period, the body weight of the mudskipper decreased, with a maximum of 12% weight loss after 21 days. Liver lipid reserves were utilized at the onset of fasting but were thereafter resynthesized. Muscle proteins were also metabolized as the fish were visibly thinner. However, no apparent change in protein content expressed as per gram wet weight was detected as the tissue hydration state was maintained constant. The increased degradation of liver and muscle reserves was coupled to an increase in the activities of key gluconeogenic enzymes in the liver (G6Pase, FDPase, PEPCK, MDH and PC). The increase in glucose synthesis was possibly necessary to counteract hypoglycemia brought about by starvation in B. boddaerti.     

Relation between cytoskeleton,hypo-osmotic treatment and volume regulation in Ehrlich ascites tumor cells

Summary Pretreatment with cytochalasin B, which is known to disrupt microfilaments, significantly inhibits regulatory volume decrease (RVD) in Ehrlich ascites tumor cells, suggesting that an intact microfilament network is a prerequisite for a normal RVD response. Colchicine, which is known to disrupt microtubules, has no significant effect on RVD. Ehrlich cells have a cortical three-dimensional, orthogonal F-actin filament network which makes the cells look completely black in light microscopy following immunogold/silver staining using anti-actin antibodies. After addition of cytochalasin B, the stained cells get lighter with black dots localized to the plasma membrane and appearance of multiple knobby protrusions at cell periphery. Also, a significant decrease in the staining of the cells is seen after 15 min of RVD in hypotonic medium. This microfilament reorganization appears during RVD in the presence of external Ca²⁺ or Ca²⁺-ionophore A23187. It is, however, abolished in the absence of extracellular calcium, with or without prior depletion of intracellular Ca²⁺ stores. An effect of increased calcium influx might therefore be considered. The microfilament reorganization during RVD is abolished by the calmodulin antagonists pimozide and trifluoperazine, suggesting the involvement of calmodulin in the process. The microfilament reorganization is also prevented by addition of quinine. This quinine inhibition is overcome by addition of the K⁺ ionophore valinomycin.     

Ecophysiology of the hypotonic response in the salt-tolerant charophyte alga Lamprothamnium papulosum

The ecophysiology of the hypotonic response was studied in the charophyte alga, Lamprothamnium papulosum, which was grown in a marine (SW; 1072 mosmol kg^–1) and a brackish (1/2 SW; 536 mosmol kg^–1) environment. The cells produced an extracellular mucilage identified by histochemical staining as a mixture of sulphated and carboxylated polysaccharides. The thickness and chemical composition of the mucilage layer was a function of environmental salinity and cell age. Mucilage progressively increased in thickness from the apex (9 SW cells: 12·6 ± 1·8 μm; 15 1/2 SW cells: 4·8 ± 0·7 μm) to the base of the plants (15 SW cells: 44·8 ± 3·3 μm; nine 1/2 SW cells: 23·8 ± 2·5 μm); with a corresponding increase in the sulphated proportion. The mucilage was significantly thicker in SW plants. Hydraulic conductivity (Lp) at the apex of SW plants, measured by transcellular osmosis, was 8·3 × 10^–13 m s^–1 Pa^–1. This was close to Lp of freshwater Chara (8·5 × 10^–13 m s^–1 Pa^–1) which lacked mucilage. Basal SW cells with thicker mucilage had a smaller apparent Lp of 3·5 × 10^–13 m s^–1 Pa^–1. The electrophysiology of the resting state and hypotonic response was compared in cells from the two environments based on current/voltage (I/V) analysis. The resting potential difference (PD) and conductance differed (11 SW cells: – 102·4 ± 10·1 mV, eight SW cells: 18·6 ± 2·4 S m^–2; 19 1/2 SW cells: –125·7 ± 5·9 mV, 8·3 ± 0·8 S m^–2). The type of cellular response to a hypotonic shock (decrease of 268 mosmol kg^–1) also differed. In 1/2 SW plants, only the apical cells with thin mucilage responded classically with depolarization, conductance increase, Ca²⁺ influx, cessation of cytoplasmic streaming, and K⁺ and Cl^– effluxes. Older cells making up the bulk of the plants responded with depolarization, but continued cytoplasmic streaming, and had only a small increase in conductance; or depolarized transiently without altering the I/V profile, conductance or streaming speed. Most cells remained depolarized and in the K⁺ state 1 h post-shock. Cells treated with the K⁺ channel blocker tetraethylammonium chloride also depolarized and remained depolarized. The SW cells depolarized but otherwise responded minimally to a 268 mosmol kg^–1 drop in osmolarity and required a further 268 mosmol kg^–1 down-step to elicit a change in the conductance. A spectrum of responses was measured in successively older and more mucilaginous cells from the same marine plant. We discuss the ecophysiological significance of the mucilage layer which modulates the cellular response to osmotic shock and which can be secreted to different degrees by plants inhabiting environments of different salinity.     

Effects of administration of somatostatin-14 and immunoneutralization of somatostatin on endocrine and growth responses in rainbow trout

Injection of somatostatin‐14 (SS‐14) at 5 ng g^?1 body mass (BM) into rainbow trout Oncorhynchus mykiss decreased (P < 0·05, cubic, r² = 0·54) levels of growth hormone (GH) (1·5 ± 0·9 ng ml^?1v. 6·6 ± 0·6 ng ml^?1) over time when compared to controls. Somatostatin‐14 at 50 ng g^?1 BM also decreased (P = 0·064, quadratic; r² = 0·30) levels of GH (3·6 ± 2·1 ng ml^?1v. 6·6 ± 0·6 ng ml^?1) over time compared to controls. In a second study, passive immunization against SS‐14 (1 : 25 dose) increased (P = 0·10, cubic, r² = 0·12) levels of GH (11·0 ± 4·8 ng ml^?1v. 5·2 ± 1·4 ng ml^?1) over time. Passively immunizing against SS‐14 (1 : 50 dose) increased (P < 0·05, cubic, r² = 0·10) levels of GH (8·2 ± 2·3 ng ml^?1v. 5·2 ± 1·4 ng ml^?1) over time compared to controls. Overall, in the active immunization study there was no difference (P > 0·10) in specific growth rate (G) or feed conversion ratio (FCR) between the three treatment groups during the 9 weeks of the study. Only four of the fish immunized against SS‐14, however, developed antibody titres against SS. Compared to controls, these fish exhibited a G of 0·89 ± 0·09 v. 0·56 ± 0·09% per 3 weeks and FCR of 0·80 ± 0·04 v. 1·20 ± 0·05 g g^?1. In SS‐14 immunized fish, levels of GH decreased (P < 0·05) by day 63 while levels of insulin like growth factor‐I (IGF‐I) increased (P < 0·05) by day 42 and 63. These results indicate the hypothalamic hormone SS‐14 regulates GH secretion similarly in rainbow trout as it does in mammals. Active immunization against SS‐14 could improve growth performance in rainbow trout but enhanced G and FCR is dependent upon generation of antibody titres.     

The critical swimming speed of Iberian barbel Barbus bocagei in relation to size and sex

The swimming capacity of Barbus bocagei was measured with the critical swimming speed (U_crit) standard test in a modified Bla?ka‐type swim tunnel. Sixty B. bocagei were tested and they exhibited a mean ±s .d . U_crit of 0·81 ± 0·11 m s^?1 or 3·1 ± 0·86 total lengths per second (L_T s^?1). Sex had no effect on U_crit but significant differences were found between the swimming performance of fish with distinct sizes.     

Fate of microfilaments in vero cells infected with measles virus and herpes simplex virus type 1.

In herpes simplex virus type 1-infected Vero cells, reorganization of microfilaments was observed approximately 4 h postinfection. Conversion of F (filamentous) actin to G (globular) actin, as assessed by a DNase I inhibition assay, was continuous over the next 12 to 16 h, at which time a level of G actin of about twice that observed in uninfected cells was measured. Fluorescent localization of F actin, using 7-nitrobenz-2-oxa-1,3-diazole (NBD)-phallacidin, demonstrated that microfilament fibers began to diminish at about 16 to 18 h postinfection, roughly corresponding to the time that G actin levels peaked and virus-induced cytopathology was first observable. In measles virus-infected cells, no such disassembly of microfilaments occurred. Rather, there was a modest decrease in G actin levels. Fluorescent localization of F actin showed that measles virus-infected Vero cells maintained a complex microfilament network characterized by fibers which spanned the entire length of the newly formed giant cells. Disruption of microfilaments with cytochalasin B, which inhibits measles virus-specific cytopathology, was not inhibitory to measles virus production at high multiplicities of infection (MOI) but was progressively inhibitory as the MOI was lowered. The carbobenzoxy tripeptide SV-4814, which inhibits the ability of Vero cells to fuse after measles virus infection, like cytochalasin B, inhibited measles virus production at low MOI but not at high MOI. Thus, it appears that agents which affect the ability of Vero cells to fuse after measles virus infection may be inhibitory to virus production and that the actin network is essential to this process.