Two Types of Clathrin-Coated Vesicles Isolated from Rat Brain: Analysis of Biochemical Properties and Cellular Origin

Two major fractions rich in clathrin-coated vesicles (CVs) (fraction I, rho = 1.140 g/cm3; fraction II, rho = 1.113 g/cm3) were separated from rat brain using a sucrose gradient and compared for their cellular origins and Cl- translocation systems. Electron micrographs showed that both fractions contained CVs of different size distributions (fraction I, 85 +/- 9.5 nm in diameter; fraction II, 72 +/- 6.8 nm in diameter). Fraction II contained potent ouabain-sensitive ATPase activity, whereas fraction I contained only a little activity. Immunoblot analysis for the Na+,K(+)-ATPase catalytic subunit, alpha and alpha(+), demonstrated that fraction II exhibited predominantly alpha(+), whose proportion to alpha was analogous to that observed in the extracts of primary cultured neuronal cells. Furthermore, on a sucrose density gradient, cultured neuronal cells yielded fraction II but not fraction I, whereas primary cultured glial cells yielded fraction I but not fraction II. Labeling-chase experiments using 125I-transferrin in cultured neuronal cells showed the internalized ligand in fraction II and the surface-bound ligand in the fraction with lower density (rho = 1.090 g/cm3), a result suggesting that the involvement of Na+,K(+)-ATPase in fraction II is attributable to endocytic vesicles. Cl- uptake in fraction II was approximately threefold higher than that in fraction I. N-Ethylmaleimide (100 microM) completely inhibited the Cl- uptake in fraction I but partially (approximately 50%) inhibited that in fraction II. These findings suggest that the two CV fractions isolated from rat brain originate from different cell types--glial and neuronal cells--and differ in size distribution of CVs, content of Na+,K(+)-ATPase, and mechanism for Cl- uptake.     

Human T cell leukemia/lymphoma virus type I infection of a CD4+ proliferative/cytotoxic T cell clone progresses in at least two distinct phases based on changes in function and phenotype of the infected cells

The effect of human T cell leukemia/lymphoma virus type I (HTLV-I) infection on the function and the phenotype of a human proliferating/cytotoxic T cell clone, specific for tetanus toxin, was investigated. During the period after infection, two distinct phases were observed, based on growth properties, phenotype, and functional activity of the infected cells. Phase I HTLV-I infected cells (0 to about 150 days after infection) proliferated in an IL-2-dependent way, but without the requirement for repetitive antigenic stimulation. No differences in expression of the CD2, CD3, CD4, Tp103, and CD28 Ag between these cells and the parental cells could be demonstrated, with the exception of the expression of IL-R p55 and HLA-DR Ag, which were constitutively expressed on the phase I cells. The phase I HTLV-I-infected cells, as well as the parental 827 cells reacted with a mAb specific for an epitope on the variable part of the TCR beta-chain, indicating that the TCR was not altered after HTLV-I infection. Like the parental clone, the phase I cells proliferated in response to tetanus toxin, but the tetanus toxin-specific response of the phase I cells did not require the presence of APC. Results of experiments, in which the levels of intracellular Ca2+ were measured, indicated that HTLV-I cells can acquire the capability to process Ag and present that to themselves. Phase I HTLV-I-infected T cells had lost their cytotoxic activity which was likely to be due to an effect on the lytic machinery rather than on Ag recognition by the TCR, inasmuch as it was found that phase I HTLV-I-infected T cells did no longer contain N-alpha-benzyloxy-L-lysine thiobenzylester-serine esterase activity. Furthermore, it was found that phase I HTLV-I-infected T cells had a diminished capacity to form conjugates with target cells. From a period of about 200 days after HTLV-I infection, phase II cells emerged that proliferated strongly in the absence of IL-2 and that had lost all functional activity. These cells did not express the CD3/T cell receptor complex on their surface. Phase I as well as phase II HTLV-I-infected cells were targets for CTL raised in the autologous donor.     

Role of microtubules in surfactant secretion

In the isolated perfused rat lung and cultured type II cells, surfactant secretion and cellular adenosine 3',5'-cyclic monophosphate (cAMP) content was stimulated by beta-adrenergic agonists. Isoproterenol-induced surfactant secretion was inhibited by the antimicrotubule agents colchicine and vinblastine. Incorporation of [3H]glycerol into disaturated phosphatidylcholine was augmented by beta-adrenergic agents but was not significantly different from the enhanced incorporation rate when colchicine was present. This suggests that the augmented incorporation of [3H]glycerol into disaturated phosphatidylcholine was a secondary response to storage depletion rather than direct cAMP stimulation. beta-Adrenergic agents shifted the equilibrium in the isolated perfused rat lung and cultured type II cells to favor microtubules. The stimulatory effect of 1.0 microM isoproterenol on tubulin polymerization was observed as early as 1 min and was augmented 2.8-fold at a half-maximal stimulation of 4 nM in cultured type II cells. Cytochalasin B, an antimicrofilament agent, potentiated the isoproterenol-induced secretion. These results suggest that an intact microtubule-microfilament system may be obligatory for enhanced surfactant secretion and that beta-adrenergic agents not only induce surfactant release but also tubulin polymerization.     

Presence of IgE antibodies to bovine serum albumin in a patient developing anaphylaxis after vaccination with human peptide-pulsed dendritic cells

Dendritic cells are professional antigen-presenting cells that can be generated in vitro either from monocytes or from CD34⁺ peripheral blood progenitor cells by using recombinant cytokines. These cells have potential implications for immunotherapeutic approaches in the treatment of cancer and other diseases. We have conducted a phase I study in melanoma patients using peptide-pulsed dendritic cells cultured in medium supplemented with 10% fetal calf serum (FCS) and a cocktail of cytokines. Peptide-pulsed dendritic cells were injected intravenously at 2-week intervals. Here we report on a case of type I hypersensitivity anaphylactic reaction after repetitive vaccination with autologous peptide-pulsed cells. Pre-vaccination and post-vaccination serum samples were evaluated for the presence of antibodies to FCS and bovine serum albumin (BSA). A retrospective study in 7 patients vaccinated with FCS-cultured dendritic cells demonstrated the presence of IgG and IgM antibodies to FCS and BSA after vaccination in 6 out of 7 patients. However, IgE antibodies were absent in all patients with the exception of the patient developing anaphylaxis. The patient's serum was demonstrated to contain a strong IgE response directed against BSA. In contrast, 2 patients vaccinated with dendritic cells cultured under serum-free conditions developed no antibodies to FCS and BSA after repetitive vaccination. We suggest that patients can be sensitized with an IgE response against BSA leading to anaphylactic reactions. On the basis of these data, dendritic cells cultured in autologous serum or under serum-free conditions are recommended for therapeutic applications in vivo. Received: 25 November 1999 / Accepted: 20 January 2000     

Substance P Enhances Desensitization of the Nicotinic Response in Bovine Chromaffin Cells but Enhances Secretion upon Removal

A fundamental process in neurosecretion is desensitization, or a declining response to a stimulus. The response of chromaffin cells to continuous nicotinic stimulation, secretion of catecholamines, desensitizes within a few minutes. The neuropeptide substance P (SP) has been reported to prevent desensitization in culture dish experiments and to enhance desensitization in patch clamp studies. In the present study, these contradictory responses have been demonstrated and the apparent contradictions resolved. We have measured catecholamine secretion by on-line electrochemical detection in a constant-pressure flow system. Isolated chromaffin cells cultured on quartz plates were stimulated with the nicotinic agonist 1,1-dimethyl-4-phenylpiperazinium (DMPP) in the presence and absence of SP. SP inhibited secretion and increase the rate of desensitization compared with stimulation by DMPP alone. However, when the cells were stimulated a second time with DMPP alone immediately after 5-min stimulation with SP + DMPP, the rate of desensitization was markedly lower than the control. Removal of SP after a desensitizing stimulation with SP + DMPP caused a slow secondary release of catecholamine in response to the continued stimulation with DMPP. The kinetic analysis of the secretory response shows that the primary response to SP is enhanced desensitization, but that upon removal of SP the response to DMPP desensitizes less rapidly. We suggest that SP protects some receptors from nicotinic desensitization while holding them in an inactive state, and that upon removal of SP these receptors can slowly respond to DMPP.     

Trans-differentiation of alveolar epithelial type II cells to type I cells involves autocrine signaling by transforming growth factor beta 1 through the Smad pathway

Type II alveolar epithelial cells (AEC II) proliferate and transdifferentiate into type I alveolar epithelial cells (AEC I) when the normal AEC I population is damaged in the lung alveoli. We hypothesized that signaling by transforming growth factor beta1 (TGF beta1), through its downstream Smad proteins, is involved in keeping AEC II quiescent in normal cells and its altered signaling may be involved in the trans-differentiation of AEC II to AEC I. In the normal lung, TGF beta1 and Smad4 were highly expressed in AEC II. Using an in vitro cell culture model, we demonstrated that the trans-differentiation of AEC II into AEC I-like cells began with a proliferative phase, followed by a differentiation phase. The expression of TGF beta1, Smad2, and Samd3 and their phosphorylated protein forms, and cell cycle inhibitors, p15(Ink4b) and p21(Cip1), was lower during the proliferative phase but higher during the differentiation phase. Furthermore, cyclin-dependent kinases 2, 4, and 6 showed an opposite trend of expression. TGF beta1 secretion into the media increased during the differentiation phase, indicating an autocrine regulation. The addition of TGF beta1 neutralizing antibody after the proliferative phase and silencing of Smad4 by RNA interference inhibited the trans-differentiation process. In summary, our results suggest that the trans-differentiation of AEC II to AEC I is modulated by signaling through the Smad-dependent TGF beta1 pathway by altering the expression of proteins that control the G1 to S phase entry in the cell cycle.     

Coronary microvascular endothelial cells cosecrete angiotensin II and endothelin-1 via a regulated pathway

Although endothelial cells produce angiotensin II (ANG II) and endothelin-1 (ET-1), it is not clear whether a single cell produces both peptides, with cosecretion in response to stimulation, or whether different subpopulations of endothelial cells secrete one or the other peptide, with secretion in response to different stimuli. Exposure of cultured coronary microvascular endothelial cells to cycloheximide for 60 min had no effect on ANG II or ET-1 secretion. This result suggested the existence of a preformed intracellular pool of ANG II and ET-1, which is a precondition for regulated secretion. Exposure of endothelial cells to isoproterenol, high extracellular potassium, or cadmium, all of which stimulate peptide secretion via different signaling pathways, significantly (P > 0.001) increased the secretion of both ANG II and ET-1 in a cell size-dependent manner. Sodium nitroprusside and S-nitroso-N-acetyl penicillamine significantly (P > 0.001) decreased ANG II and ET-1 secretion, whereas N(omega)-nitro-L-arginine-methyl ester enhanced it. The similar regulation of ANG II and ET-1 secretion and the presence of both peptides around individual endothelial cells indicate that the autocrine/paracrine regulation of cardiovascular function by endothelial cells is accomplished via cosecretion of ANG II and ET-1.     

Combinatorial insulin secretion dynamics of recombinant hepatic and enteroendocrine cells

One of the most promising cell-based therapies for combating insulin-dependent diabetes entails the use of genetically engineered non-β cells that secrete insulin in response to physiologic stimuli. A normal pancreatic β cell secretes insulin in a biphasic manner in response to glucose. The first phase is characterized by a transient stimulation of insulin to rapidly lower the blood glucose levels, which is followed by a second phase of insulin secretion to sustain the lowered blood glucose levels over a longer period of time. Previous studies have demonstrated hepatic and enteroendocrine cells to be appropriate hosts for recombinant insulin expression. Due to different insulin secretion kinetics from these cells, we hypothesized that a combination of the two cell types would mimic the biphasic insulin secretion of normal β cells with higher fidelity than either cell type alone. In this study, insulin secretion experiments were conducted with two hepatic cell lines (HepG2 and H4IIE) transduced with 1 of 3 adenoviruses expressing the insulin transgene and with a stably transfected recombinant intestinal cell line (GLUTag-INS). Insulin secretion was stimulated by exposing the cells to glucose only (hepatic cells), meat hydrolysate only (GLUTag-INS), or to a cocktail of the two secretagogues. It was found experimentally that the recombinant hepatic cells secreted insulin in a more sustained manner, whereas the recombinant intestinal cell line exhibited rapid insulin secretion kinetics upon stimulation. The insulin secretion profiles were computationally combined at different cell ratios to arrive at the combinatorial kinetics. Results indicate that combinations of these two cell types allow for tuning the first and second phase of insulin secretion better than either cell type alone. This work provides the basic framework in understanding the secretion kinetics of the combined system and advances it towards preclinical studies.     

Control of aldosterone secretion in zona glomerulosa cell suspensions and in the perfused adrenal gland of the rat

The secretion of aldosterone and its responses to stimulation have been studied in rat adrenal zona glomerulosa tissue incubated as intact capsules or as collagenase-dispersed cell suspensions, and in intact perfused rat adrenal glands. Several differences are apparent in the functions of the various preparations. Aldosterone secretion rates are similar in incubated intact capsules and in the perfused gland. Relative to corticosterone, lower yields of aldosterone are obtained in dispersed glomerulosa cell in vitro. This may be related to the loss in the dispersed cells of a pool of tissue steroid (aldosterone or a precursor) which is revealed only in intact tissue incubations by trypsin stimulation of aldosterone secretion. Trypsin-released aldosterone is increased by prior dietary sodium restriction. In addition, differences occur in the responses of dispersed cells and perfused glands to stimulation. Perfused glands from animals on a normal diet are less sensitive to stimulation by ACTH or alpha-MSH, but more sensitive than dispersed cells to angiotensin II amide. In the perfused gland, sensitivity of response (lowest effective concentration) to all three stimulants is increased by prior dietary sodium restriction, in contrast to dispersed cells in which increased sensitivity has been reported only to alpha-MSH. The perfused gland is particularly sensitive to angiotensin II amide, and a bolus administration of 1 amol gives significant stimulation in glands from animals on low sodium intake. Electrical (field) stimulation or dopamine administration at 10(-6) mol/l (which is ineffective in dispersed cells) both depress aldosterone secretion by the perfused gland. The data suggest that the sequestered pool of steroid is utilized in the perfused gland for aldosterone secretion. They furthermore suggest that in the intact gland there are mechanisms, which involve neural components, for intraglandular regulation of aldosterone secretion, which are lost in dispersed cells in vitro. Such mechanisms may be involved in sensitivity increases in sodium depletion.     

Responses of cells in the somatosensory cortex of unanaesthetized cats after sinusoidal displacements of single vibrissae

Summary Neurones in the somatosensory cortex of unanaesthetized restrained cats were recorded during single trapezoid and repetitive sinusoidal displacements of single vibrissae. Responses to trapezoid displacements were similar to those described previously in anaesthetized cats (Hellweg et al., 1977).During repetitive mechanical stimulation cortical cells showed adaptive behaviour so that at higher stimulation frequencies the number of cell discharges per stimulus cycle decreased. The ability to follow the repetition of the stimulus at a one to one ratio was lost in the frequency range between 20 Hz and 60 Hz. A few exceptional cells, while not following at a one to one ratio, still showed some periodicities in their response histograms corresponding to repetition rates of up to 100 Hz. In about 10% of the cells nonmonotonic functions between stimulation frequency and response per cycle were found. These nonmonotonic functions as well as the different adaptive behaviour of cells could not be predicted on the basis of their response to trapezoid stimuli.Measurements of the phase differences between stimulus cycle and response peaks during repetitive stimulation showed that both can vary as a function of stimulation frequency. It is discussed whether these findings could be compatible with the concept of phase coding in the somatosensory cortex.     

Developmental regulation of phospholipid secretion by fetal type II pneumocytes

Surfactant sufficiency is dependent upon adequate synthesis and secretion of surfactant by the type II alveolar epithelium. Our laboratory has previously shown that basal secretion of surfactant phospholipid by differentiated fetal type II cells is lower than the basal secretion by adult cells. The purposes of this study were to determine if undifferentiated fetal type II cells can secrete phosphatidylcholine, to determine if terbutaline, a β-adrenergic agonist, stimulates secretion of surfactant phospholipids by undifferentiated fetal cells and to examine the effects of differentiation on secretion of surfactant phospholipids by fetal cells. Constitutive (basal) secretion of phosphatidylcholine increased linearly as a function of time in both undifferentiated and differentiated cells, but the rate of secretion was greater in differentiated cells than the rate of secretion in undifferentiated cells. Terbutaline caused a concentration-dependent increase in secretion in both undifferentiated and differentiated cells. Maximal effective concentration and EC₅₀ were similar for undifferentiated (10⁻⁶ M, 0.2 μM) and differentiated (10⁻⁵ M, 0.3 μM) cells. The relative stimulation of secretion above control values was greater for undifferentiated cells. The kinetics of terbutaline stimulation varied significantly with cellular differentiation. Terbutaline resulted in 230% stimulation of secretion in undifferentiated cells at 30 min followed by a decline in the response to terbutaline at 60 to 120 min. In contrast, terbutaline stimulated secretion by differentiated cells showed a sustained linear increase from 0 to 120 min. This regulation of stimulated secretion is not present in undifferentiated cells. We conclude that undifferentiated type II cells are capable of the secretion of phosphatidylcholine and that terbutaline stimulates secretion by undifferentiated cells. Furthermore, basal secretion increases as a function of differentiation of type II cells and the regulation of stimulated secretion seen in differentiated cells is not developed in undifferentiated cells. The developmental regulation of the secretion of surfactant is complex and probably involves both excitatory as well as inhibitory mechanisms which develop at different stages of differentiation of the type II cell.     

Duplexes of 21 nucleotide RNA specific for COX II mediates RNA interference in cultured bovine aortic coronary endothelial cells (BAECs)

The present study was conducted to utilize a double-stranded RNA (dsRNA) specific for cyclooxygenase (COX) II and demonstrate inhibition of the expression of COX II protein and its product PGE. A 21-dsRNA specific for COX II was introduced by lipofectamine into a primary cell culture of bovine aortic coronary endothelial cells (BAECs). BAECs basally express COX I but not COX II, and COX II expression is only apparent after stimulation with phorbol 12-myristate acetate (PMA). We first demonstrated that the lipofected fluorescent dsRNA-COX II is accumulated and localized within the cultured cells. We then demonstrated gene silencing of PMA-induced COX II protein expression by dsRNA-COX II using immuno-histochemistry. Western blot analysis and radioimmunoassay were used to quantitate the percent of inhibition. It was found that lipofected dsRNA-COX II reduced the percent of PMA-induced COX II enzyme by 36% and PGE production by 40%. There was no demonstrable effect of dsRNA-COX II or PMA on COX I expression.     

Regulation of the synthesis and secretion of transferrin and cyclic protein-2/cathepsin L by mature rat Sertoli cells in culture.

While numerous studies have examined the response of immature rat Sertoli cells to specific hormones and growth factors, the regulation of mature cells in vitro has not been well examined because highly purified cells have been difficult to isolate. We now describe a detailed method for isolating Sertoli cells from mature (> 60 days of age) rats and generating primary cultures of these cells greater than 90% in purity. We demonstrate that cell density, hormones, and growth factors regulate the synthesis or secretion of two Sertoli cell products, transferrin and Cyclic Protein-2 (CP-2)/cathepsin L. Cell density modulated the response of mature Sertoli cells to some hormones; insulin (at 10 micrograms/ml) and epidermal growth factor (EGF) acted synergistically to stimulate transferrin synthesis by 80% when cells were cultured at a density of 1.65 x 10(5) cells/cm2 but had no effect on transferrin synthesis by cells cultured at 1.46 x 10(5) cells/cm2. A mixture of FSH, retinol, and testosterone increased transferrin synthesis by 30% at both cell densities, and this stimulation was independent of the effect of EGF and insulin. CP-2/cathepsin L synthesis was significantly stimulated by increased cell density. FSH, retinol, and testosterone also stimulated CP-2/cathepsin L synthesis by 30%; however, this stimulation just missed being statistically significant. Finally, we demonstrated that secretion of transferrin and CP-2 was reduced when cells were cultured in the presence of interleukin-1 alpha, a cytokine synthesized by Sertoli cells.(ABSTRACT TRUNCATED AT 250 WORDS)     

Pulmonary surfactant secretion in briefly cultured mouse type II cells

There is little information on the regulation of surfactant secretion in mouse type II cells. We isolated type II cells from C57BL/6 and FVB mice, cultured them overnight, and then examined their response to known surfactant secretagogues. Secretion of phosphatidylcholine, surfactant protein (SP)-B and SP-C was stimulated by terbutaline, 5'-N-ethylcarboxyamidoadenosine (NECA), ATP, UTP, TPA, and ionomycin. Phosphatidylcholine secretion was increased approximately twofold by all agonists in both strains of mice. The response to terbutaline and NECA is the same as in rat type II cells, whereas the response to ATP, UTP, TPA, and ionomycin is considerably less. Secretion of SP-B and SP-C was increased sevenfold by terbutaline and threefold by ATP, effects similar to those in rat type II cells. The response to terbutaline was significantly decreased in type II cells from beta(2)-adrenergic receptor null mice. These data establish that briefly cultured type II cells provide a suitable model for investigation of surfactant secretion in normal and genetically altered mice.     

Evaluation of the cytotoxic mechanisms mediated by the broad-spectrum antitumor alkaloid acronycine and selected semisynthetic derivatives.

Acronycine (I) is a broad-spectrum antitumor agent whose development as a clinically useful agent has been hindered, in part, due to its poor solubility characteristics. With the goal of acquiring information that may prove of value in the development of structurally related compounds of greater clinical utility, mechanistic studies were performed with acronycine (I) and two semisynthetic derivatives, 2-nitroacronycine (II) and acronycine azine (III). These three substances demonstrated cytotoxic activity with several human tumor cell lines (breast, colon, lung, melanoma, KB-3, and drug-resistant KB-V1). Compounds II and III demonstrated greater activity than I, and more detailed studies were performed with cultured human breast cancer cells (UISO-BCA-1). Acronycine azine (III) induced the cells to accumulate in the G0/G1 phase of the cell cycle. It effectively inhibited the in vitro catalytic activities of partially purified DNA and RNA polymerases in a manner that was competitive with respect to DNA substrate. As judged by spectrophotometric titration, compound III interacted with calf thymus DNA, calf liver RNA, and a variety of single- and double-stranded (deoxy)ribonucleotides. Although no nucleic acid base specificity was discernable, this interaction appeared to be related to the cytotoxic mechanism of this dimeric substance. Monomeric compounds I and II did not interact with nucleic acids, but were effective inhibitors of DNA and RNA synthesis as judged by in vitro systems comprised of cultured UISO-BCA-1 cells or homogenates derived from these cells. The relative inhibitory activities of compounds I and II correlated with their cytotoxic activities suggesting a causal relationship. In addition, these two compounds induced cultured cells to accumulate in the phase of the cell cycle wherein the DNA content ranged from 2n-4n (S + G2/M), and inhibited in vitro DNA and RNA synthesis in a manner that was competitive with respect to nucleotide (TTP or UTP) substrate. Compounds I and II demonstrated greater cytotoxic activity with drug-resistant KB-V1 cells as compared with the parent (drug-sensitive) cell line, whereas this was not the case with compound III. Based on these results and previous literature reports, compounds I, II and III are likely to function by multiple mechanisms of action. However, it appears that alteration of nucleic acid metabolism is key to the activity of each of the substances.     

Transepithelial bioelectrical properties of rabbit acinar cell monolayers on polyester membrane scaffolds

In our quest to develop a tissue-engineered tear secretory system, we have tried to demonstrate active transepithelial ion fluxes across rabbit lacrimal acinar cell monolayers on polyester membrane scaffolds to evaluate the bioelectrical properties of the cultured cells. Purified lacrimal gland acinar cells were seeded onto polyester membrane inserts and cultured to confluency. Morphological properties of the cell monolayers were evaluated by transmission electron microscopy and immunofluorescence staining for Na(+),K(+)-ATPase and the tight junction-associated protein occludin. Sections revealed cell monolayers with well-maintained epithelial cell polarity, i.e., presence of apical (AP) secretory granules, microvilli, and junctional complexes. Na(+),K(+)-ATPase was localized on both the basal-lateral and apical plasma membranes. The presence of tight cell junctions was demonstrated by a positive circumferential stain for occludin. Bioelectrical properties of the cell monolayers were studied in Ussing chambers under short-circuit conditions. Active ion fluxes were evaluated by inhibiting the short-circuit current (I(sc)) with a Na(+),K(+)-ATPase inhibitor, ouabain (100 microM; basal-lateral, BL), and under Cl(-)-free buffer conditions after carbachol stimulation (CCh; 100 microM). The directional apical secretion of Cl(-) was demonstrated through pharmacological analysis, using amiloride (1 mM; BL) and bumetanide (0.1 mM; BL), respectively. Regulated protein secretion was evaluated by measuring the beta-hexosaminidase catalytic activity in the AP culture medium in response to 100 microM basal CCh. In summary, rabbit lacrimal acinar cell monolayers generate a Cl(-)-dependent, ouabain-sensitive AP --> BL I(sc) in response to CCh, consistent with current models for Na(+)-dependent Cl(-) secretion.     

The transmission of impulses in the ectodermal slow conduction system of the sea anemone Calliactis parasitica (Couch).

1. The SS 1 fatigues in response to repetitive electrical stimulation. This fatigue is manifested by an increased conduction delay and a decreased SS 1 pulse amplitude. 2. Continued repetitive stimulation leads to the failure of the system. Recovery may take many seconds. Narrow strips of column fail more rapidly than wide strips. 3. The increased conduction delay is explained in terms of a decrease in the population of spiking cells. 4. A computer model is described and analysed. It suggests that conduction between electrically coupled ectoderm cells could be the basis for the SS1. The SS 1 may have properties not so far experimentally demonstrated; for example, under certain conditions it could behave as a local system.     

Membrane-associated carbonic anhydrase activity in the brain of CA II-deficient mice

Membrane-associated carbonic anhydrase (CA) activity is of importance for transepithelial transport of ions and fluid. Histochemical studies have indicated its presence in the brain, but the data are difficult to evaluate because of interference from cytoplasmic CA isozymes, of which CA II is the predominant one. CA II-deficient mice offer a possibility to study the location of membrane-associated CA-activity, without interference from CA II. The location of CA activity in the brain of CA II-deficient and normal mice was studied by the cobalt-phosphate histochemical method, and that of CA I, CA II and CA III by an immunocytochemical method. The brains of both types of mice lacked cytoplasmic isozymes CA I and CA III, and the CA II-deficient mice also lacked CA II. In the normal mice, oligodendrocytes and choroid epithelium stained for CA II in the cytoplasm. In normal and CA (II)D-mice there was an intense membrane associated histochemical CA activity in neuronal processes. Neuronal perikarya were not stained. Endothelial membranes of brain capillaries showed strong histochemical CA-activity. Choroid epithelial cells had histochemical CA activity in the cytoplasm and along apical and baso-lateral cell membranes. The results suggest that membrane-associated CA-activity found along neuronal processes probably modulates pH of the extracellular fluid and thus neuronal activity. CA II and the membrane-associated CA of choroidal epithelium are probably involved in the secretion of cerebrospinal fluid.     

Secretion of neurophysins by the ovary in sheep

Measurements of venoarterial concentration differences across the ovary in anesthetized sheep have demonstrated that the ovary secretes ovine neurophysin I/II (oNP I/II) and that this process is stimulated by the prostaglandin F2 alpha analogue, cloprostenol. A parallel increase in the secretion of oxytocin (OT) was observed in response to cloprostenol, and the mean molar ratio of oNP I/II to OT secreted was 1.2. There was no detectable ovarian secretion of oNP III. Secretion of oNP I/II and OT was absent after hysterectomy. The data support other evidence indicating that the corpus luteum synthesizes OT, and confirm that the neurophysin associated with OT in the sheep is oNP I/II.     

Culture of differentiated and undifferentiated type II cells from fetal rat lung

We have developed a relatively simple and reproducible method for the isolation and culture of both differentiated and undifferentiated type II cells from fetal rat lung. The technique involves an initial period of explant culture in serum and hormone free medium, followed by enzymatic dissociation of the explants, differential adhesion to remove fibroblasts, incubation of the cell pellet to promote aggregation of the type II cells and monolayer culture of the type II cells. The type II cells form clusters which are surrounded by scattered fibroblasts. When the technique was performed with three differential adhesion steps, cultures contained 86.0 +/- 1.4% type II cells. To obtain a higher degree of purity and greater yield, two differential adhesions followed by gentle trypsinization of the cultures which selectively removes the isolated fibroblasts was performed. This resulted in cultures with 89.4 +/- 1.7% type II cells. The differentiated fetal type II cell cultures were prepared from 19-day fetal rat lungs which were initially maintained in explant culture for 48 h. These differentiated cells demonstrated the characteristic morphologic features of type II cells including lamellar bodies and microvilli. Undifferentiated fetal cells were prepared in a similar manner from 18-day fetal rat lung maintained in explant culture for 24 h. These cells did not contain intracellular osmiophilic granules; the appearance of these granules could, however, be induced by hormones. For this reason they are considered to be pre-type II cells. The viability of the cultured cells was 97%. Both the differentiated and undifferentiated fetal type II cells specifically bound the Maclura pomifera lectin, a type II cell surface marker. The phospholipid profile of the fetal cells was similar to that of adult rat type II cells; the differentiated fetal cells, however, synthesized less phosphatidylcholine than the adult cells did, but more than the undifferentiated fetal cells. The differentiated fetal cells secreted phosphatidylcholine at a basal rate of 0.6% +/- 0.1% during a 90-min incubation. There was dose-dependent stimulation of phosphatidylcholine secretion after exposure to terbutaline. Maximum stimulation (76%) was observed at a concentration of 10 microM. This culture system provides a valuable model for studies of the maturation of the undifferentiated fetal type II cell and surfactant metabolism and secretion in the differentiated fetal type II cell.