Molecular organization of the mucins and glycocalyx underlying mucus transport over mucosal surfaces of the airways.

Mucus, with its burden of inspired particulates and pathogens, is cleared from mucosal surfaces of the airways by cilia beating within the periciliary layer (PCL). The PCL is held to be "watery" and free of mucus by thixotropic-like forces arising from beating cilia. With radii of gyration ~250 nm, however, polymeric mucins should reptate readily into the PCL, so we assessed the glycocalyx for barrier functions. The PCL stained negative for MUC5AC and MUC5B, but it was positive for keratan sulfate (KS), a glycosaminoglycan commonly associated with glycoconjugates. Shotgun proteomics showed KS-rich fractions from mucus containing abundant tethered mucins, MUC1, MUC4, and MUC16, but no proteoglycans. Immuno-histology by light and electron microscopy localized MUC1 to microvilli, MUC4 and MUC20 to cilia, and MUC16 to goblet cells. Electron and atomic force microscopy revealed molecular lengths of 190-1,500 nm for tethered mucins, and a finely textured glycocalyx matrix filling interciliary spaces. Adenoviral particles were excluded from glycocalyx of the microvilli, whereas the smaller adenoassociated virus penetrated, but were trapped within. Hence, tethered mucins organized as a space-filling glycocalyx function as a selective barrier for the PCL, broadening their role in innate lung defense and offering new molecular targets for conventional and gene therapies.

Influenza M2 envelope protein augments avian influenza hemagglutinin pseudotyping of lentiviral vectors.

Lentivirus-based gene transfer has the potential to efficiently deliver DNA-based therapies into non-dividing epithelial cells of the airway for the treatment of lung diseases such as cystic fibrosis. However, significant barriers both to lung-specific gene transfer and to production of lentivirus vectors must be overcome before these vectors can be routinely used for applications to the lung. In this study, we investigated whether the ability to produce lentiviral vectors pseudotyped with fowl plague virus hemagglutinin (HA) could be improved by co-expression of influenza virus M2 in vector-producing cells. We found that M2 expression led to a 10-30-fold increase in production of HA-pseudotyped lentivirus vectors based upon equine infectious anemia virus (EIAV) or human immunodeficiency virus type 1 (HIV-1). Experiments using the M2 inhibitor amantadine and a drug-resistant mutant of M2 established that the ion channel activity of M2 was important for M2-dependent augmentation of vector production. Furthermore, the neuraminidase activity necessary for particle release from producer cells could also be incorporated into producer cells by co-expression of influenza NA cDNA. Lentiviral vectors pseudotyped with influenza envelope proteins were able to efficiently transduce via the apical membrane of polarized mouse tracheal cultures in vitro as well as mouse tracheal epithelia in vivo.

The coxsackievirus and adenovirus receptor is a transmembrane component of the tight junction.

The coxsackievirus and adenovirus receptor (CAR) mediates viral attachment and infection, but its physiologic functions have not been described. In nonpolarized cells, CAR localized to homotypic intercellular contacts, mediated homotypic cell aggregation, and recruited the tight junction protein ZO-1 to sites of cell-cell contact. In polarized epithelial cells, CAR and ZO-1 colocalized to tight junctions and could be coprecipitated from cell lysates. CAR expression led to reduced passage of macromolecules and ions across cell monolayers, and soluble CAR inhibited the formation of functional tight junctions. Virus entry into polarized epithelium required disruption of tight junctions. These results indicate that CAR is a component of the tight junction and of the functional barrier to paracellular solute movement. Sequestration of CAR in tight junctions may limit virus infection across epithelial surfaces.

Enhancement of adenovirus vector entry into CD70-positive B-cell Lines by using a bispecific CD70-adenovirus fiber antibody.

Although many recombinant adenovirus vectors (rAd) have been developed, especially by using group C adenoviruses, to transfer and express genes, such rAd do not readily infect B-cell lines due to the lack of the coxsackievirus-adenovirus receptor. Bispecific antibodies have been used in different cell systems to facilitate entry of rAd into otherwise nonpermissive cells. Bispecific antibody is synthesized by covalently linking two monoclonal antibodies with distinct specificities. It has been shown that lymphoproliferative tumors commonly express the cell surface protein CD70, while this receptor is normally expressed on only a small subset of highly activated B cells and T cells. We therefore investigated whether a bispecific antibody with specificities for the adenovirus fiber protein and CD70 can facilitate rAd entry and subsequent expression of rAd-encoded genes in CD70-positive B cells. We found high CD70 expression on Epstein-Barr virus (EBV)-transformed lymphoblastoid cell lines (LCLs), as well as some, but not all, Burkitt lymphoma (BL) lines. We show here that rAd encoding green fluorescent protein (Ad-GFP) infects EBV-transformed LCLs and a CD70-positive BL line 10- to 20-fold more efficiently in the presence of the CD70-fiber bispecific antibody. In contrast, the bispecific antibody does not enhance Ad-GFP infection in CD70-deficient BL cells. Using the CD70-fiber bispecific antibody, we increased the ability of rAd vectors encoding the EBV immediate-early proteins BZLF1 and BRLF1 to induce the lytic form of EBV infection in LCLs. These results indicate that the CD70-fiber bispecific antibody can enhance rAd infection of CD70-positive B cells and suggest the use of this vector to explore EBV-positive LCLs.

Efficiency of adenovirus-mediated gene transfer to oropharyngeal epithelial cells correlates with cellular differentiation and human coxsackie and adenovirus receptor expression.

Adenovirus-mediated gene transfer is a novel treatment strategy for head and neck squamous cell carcinoma (HNSCC) that may improve the unacceptable morbidity and mortality associated with conventional treatment. Efficient adenoviral (AdV) infection largely depends on cellular expression of the human coxsackie and adenovirus receptor (hCAR); however, the relatively recent identification of this receptor precludes a comprehensive description of its tissue distribution. We have created tissue culture model systems that approximate the differentiation and three-dimensional structure of stratified squamous epithelium characteristic of head and neck mucosa. Using these systems, we have found that expression of hCAR in native and modeled normal oropharyngeal epithelium decreased as cells differentiated with the most superficial and differentiated cells expressing no detectable hCAR. In contrast, modeled stratified HNSCC cells, which did not differentiate morphologically and did not express cytokeratin markers of differentiation, had equivalent expression of hCAR in superficial and basal layers. The expression of hCAR in our models correlated not only with the undifferentiated state, but also with efficiency of AdV infection. Despite expression of hCAR in underlying basal and suprabasal cells, topical application of AdV to normal modeled epithelium resulted in inefficient transduction of the most superficial cell layer without any infection of underlying cells. These data suggest that in normal epithelium the overlying squamous cells act as a barrier preventing infection of underlying cells that would otherwise be easily infected. In modeled stratified HNSCC, transduction was much more efficient and occurred up to four cell layers deep, suggesting that unlike normal superficial epithelial cells, the superficial cells of stratified HNSCC do not act as an effective barrier to adenoviral infection. The distribution of hCAR in native tissue and the enhanced susceptibility of undifferentiated oropharyngeal epithelial cells, including undifferentiated cancer cells, to AdV infection has important implications for the development of AdV-based targeting strategies for the treatment of head and neck cancer or premalignancies.

G-protein-coupled receptors as targets for gene transfer vectors using natural small-molecule ligands.

Gene therapy for cystic fibrosis (CF) has focused on correcting electrolyte transport in airway epithelia. However, success has been limited by the failure of vectors to attach and enter into airway epithelia, and may require redirecting vectors to targets on the apical membrane of airway cells that mediate these functions. The G-protein-coupled P2Y2 receptor (P2Y2-R) is abundantly expressed on the airway lumenal surface and internalizes into coated pits upon agonist activation. We tested whether a small-molecule-agonist (UTP) could direct vectors to P2Y2-R and mediate attachment, internalization, and gene transfer. Fluorescein-UTP studies demonstrated that P2Y2-R agonists internalized with their receptor, and biotinylated UTP (BUTP) mediated P2Y2-R-specific internalization of fluorescently labeled streptavidin (SAF) or SAF conjugated to biotinylated Cy3 adenoviral-vector (BCAV). BUTP conjugated to BCAV mediated P2Y2-R-specific gene transfer in (1) adenoviral-resistant A9 and polarized MDCK cells by means of heterologous P2Y2-R, and (2) well-differentiated human airway epithelial cells by means of endogenous P2Y2-R. Targeting vectors with small-molecule-ligands to apical membrane G-protein-coupled receptors may be a feasible approach for successful CF gene therapy.

Retargeting the coxsackievirus and adenovirus receptor to the apical surface of polarized epithelial cells reveals the glycocalyx as a barrier to adenovirus-mediated gene transfer.

Lumenal delivery of adenovirus vectors (AdV) results in inefficient gene transfer to human airway epithelium. The human coxsackievirus and adenovirus receptor (hCAR) was detected by immunofluorescence selectively at the basolateral surfaces of freshly excised human airway epithelial cells, suggesting that the absence of apical hCAR constitutes a barrier to adenovirus-mediated gene delivery in vivo. In transfected polarized Madin-Darby canine kidney cells, wild-type hCAR was expressed selectively at the basolateral membrane, whereas hCAR lacking the transmembrane and/or cytoplasmic domains was expressed on both the basolateral and apical membranes. Cells expressing apical hCAR still were not efficiently transduced by AdV applied to the apical surface. However, after the cells were treated with agents that remove components of the apical surface glycocalyx, AdV transduction occurred. These results indicate that adenovirus can infect via receptors located at the apical cell membrane but that the glycocalyx impedes interaction of AdV with apical receptors.

Limited entry of adenovirus vectors into well-differentiated airway epithelium is responsible for inefficient gene transfer.

Investigations of the efficiency and safety of human adenovirus vector (AdV)-mediated gene transfer in the airways of patients with cystic fibrosis (CF) in vivo have demonstrated little success in correcting the CF bioelectrical functional defect, reflecting the inefficiency of AdV-mediated gene transfer to the epithelial cells that line the airway luminal surface. In this study, we demonstrate that low AdV-mediated gene transfer efficiency to well-differentiated (WD) cultured airway epithelial cells is due to three distinct steps in the apical membrane of the airway epithelial cells: (i) the absence of specific adenovirus fiber-knob protein attachment receptors; (ii) the absence of alphavbeta3/5 integrins, reported to partially mediate the internalization of AdV into the cell cytoplasm; and (iii) the low rate of apical plasma membrane uptake pathways of WD airway epithelial cells. Attempts to increase gene transfer efficiency by increasing nonspecific attachment of AdV were unsuccessful, reflecting the inability of the attached vector to enter (penetrate) WD cells via nonspecific entry paths. Strategies to improve the efficiency of AdV for the treatment of CF lung disease will require methods to increase the attachment of AdV to and promote its internalization into the WD respiratory epithelium.

Transduction of non-small cell lung cancer cells by adenoviral and retroviral vectors.

Gene transfer into a panel of non-small cell lung cancer (NSCLC) cells by adenoviral (Ad) and retroviral (RV) vectors was studied. Indexed to multiplicity of infection (MOI), Ad vectors transduce squamous, adenosquamous, and malignant mesothelioma cells with greater efficiency than large cells or adenocarcinoma cells. Transduction-sensitive cells bind the Ad vector with specificity for the Ad fiber knob, and internalize vector efficiently. Transduction-refractory cells bind and internalize vector by less efficient pathways. Like Ad vectors, there is heterogeneity in RV transduction efficiencies of different NSCLC subtypes. With respect to the most common cell type metastatic to the pleural space (adenocarcinoma), amphotropic retroviral vectors transduce cells of this subtype more efficiently (at a lower MOI) than Ad. RV transduction is not solely dependent on cellular replication, and both permissive and refractory cell lines express the mRNA for the amphotropic RV receptor. These observations suggest that neither Ad nor RV vectors will suffice a priori as the optimal gene transfer vehicle, and successful gene therapy of lung cancer may require tumor-specific or patient-specific vectors.

Replication-deficient adenoviral vector for gene transfer potentiates airway neurogenic inflammation.

Human trials for the treatment of cystic fibrosis lung disease with adenoviral vectors have been complicated by acute inflammatory reactions of unknown etiology. Because replicating respiratory viruses can potentiate tachykinin-mediated neurogenic inflammatory responses in airways, we studied whether the endotracheal administration of a replication-deficient adenoviral vector potentiated this response. The vector Ad5CMVLacZ was administered endotracheally to rats and the leakage of Evans blue dye was used to measure the capsaicin-induced neurogenic albumin extravasation. These studies show that neurogenic albumin extravasation is significantly potentiated in the airways of rats after administration of Ad5CMVLacZ. This inflammatory response can be blocked by selective antagonists of the substance P receptor or by glucocorticoids. Therefore, (1) the acute airway inflammation observed in patients after exposure to adenoviral vectors may exhibit a neurogenic component, which can be blocked pharmacologically, and (2) preclinical adenoviral vector safety studies of other organs innervated by the tachykinin system, e.g., coronary arteries and gastrointestinal tract, should include assessment of neurogenic inflammation.

Towards a gene therapy for cystic fibrosis lung disease.

Gene therapy for the treatment of the pulmonary manifestations of cystic fibrosis (CF) has been at the forefront of gene therapy research over the last several years. During this time, however, despite immense efforts, controlled clinical trials with CF patients have failed to demonstrate significant and reproducible ;correction' of the CF bioelectrical functional defect. The target tissue requiring ;correction' in CF lung disease is the respiratory epithelium that lines the airways of the lung, and evidence is now emerging that the epithelium has evolved to elude the uptake of potential pathogens, including viruses, bacteria and gene transfer vectors. The majority of studies with gene transfer to the airway epithelium have used the adenovirus as the gene delivery vector, since high efficiency gene transfer to airway epithelial cells grown in culture can be demonstrated. However, when these vectors are tested in the airways of animals and humans in vivo, the efficiency of gene transfer is low. It is likely that these observations are not limited to adenoviral vectors (Ad), since similar gene transfer discrepancies are observed with a range of vector systems being developed for CF lung gene therapy. Therefore, this update will focus on the factors responsible for efficient gene transfer to airway epithelial cells in vitro and, using Ad as examples, discuss the development of ;targeted' gene transfer vectors that may overcome the resistance of the airway epithelium in vivo to efficient gene transfer.

Efficient adenovirus-mediated gene transfer to basal but not columnar cells of cartilaginous airway epithelia.

Adenoviral vectors (AdV) developed for treatment of the pulmonary manifestations of cystic fibrosis (CF) can deliver, with high efficiency, transgenes to respiratory epithelial cells grown in culture. This study investigated the efficiency of AdV-mediated gene transfer to murine and human respiratory epithelium in vivo and concluded that the epithelial cells facing the lumen of the respiratory cartilaginous airways (columnar cells) are poorly transduced with AdV. Mechanical injury to the epithelium, however, leads to efficient in vivo gene transfer by exposing a susceptible epithelial subtype (basal cells). Increased gene transfer efficiency in vivo after injury is not a nonspecific response because the proliferative status of the epithelium after injury was shown not to correlate temporally to the increased transduction susceptibility of the epithelium. Although basal cells were the cell type transduced at the time of vector delivery, with time, basal cell differentiation to columnar cells occurred with maintenance of transgene expression. Collectively, these results show that murine and human cartilaginous airways are poorly transduced by AdV. To correct the cartilaginous airway CF bioelectrical defect in vivo, efforts should be directed to increase the tropism of AdV to the columnar airway epithelial cells.

In vitro assessment of variables affecting the efficiency and efficacy of adenovirus-mediated gene transfer to cystic fibrosis airway epithelia.

Primary cultures of airway epithelia were used to evaluate variables pertinent to adenovirus (Ad)-mediated gene transfer efficiency and efficacy including: (i) Ad-vectors with different promoters, (ii) the duration of vector incubation with cells, (iii) the concentration and depth of vector-containing medium at constant multiplicity of infection (moi) (10(3)), and (iv) the relative sensitivity of reverse transcription polymerase chain reaction (RT-PCR) versus functional analysis for the detection of transduced cystic fibrosis transmembrane conductance regulator (CFTR). An Ad5-lacZ vector with a cytomegalovirus (CMV) enhancer/promoter transduced the greatest amount of beta-galactosidase (beta-Gal) activity, while an Ad2-lacZ vector with an E1a enhancer/promoter transduced the least. Ad5-lacZ vectors with the Rous sarcoma virus (RSV), E1a/RSV, or CMV enhancer/beta-actin (CB) promoters transduced intermediate levels of beta-Gal. Optimal gene transfer efficiency was detected with a 4-8 hr incubation of Ad5-CMVlacZ with cells, although optimal CFTR Cl-transport function was detectable after only a 30 min incubation of Ad5-CBCFTR with cells, consistent with correction of > or = 6-10% of cells in the epithelial sheet. Ad5-CBCFTR transduction of CF airway epithelial cells (moi = 10(3)) was optimal when higher concentrations, lower volumes, or smaller depths of vector-containing medium were utilized. RT-PCR was at least 100-fold more sensitive for the detection of transduced CFTR than functional analysis, and could detect as few as 0.001% Ad5-CBCFTR-infected CF cells admixed with uninfected CF cells. In summary, the variables studied clearly affect the efficiency of Ad-mediated gene transfer in vitro and potentially in vivo. They also suggest that RT-PCR is a poor marker of gene transfer efficiency and efficacy.

Inefficient gene transfer by adenovirus vector to cystic fibrosis airway epithelia of mice and humans.

The success of adenoviral vectors for gene therapy of lung disease in cystic fibrosis (CF) depends on efficient transfer of the complementary DNA encoding the correct version of the cystic fibrosis transmembrane regulator (CFTR) to the affected columnar epithelial cells lining the airways of the lung. Pre-clinical studies in vitro suggest that low doses of adenovirus vectors carrying this CFTR cDNA can correct defective Cl- transport in cultured human CF airway epithelia. Here we use mice carrying the disrupted CF gene to test the efficacy of this transfer system in vivo. We find that even repeated high doses can only partially (50%) correct the CF defect in Cl- transport in vivo and do not correct the Na+ transport defect at all. We investigated this discrepancy between the in vivo and in vitro transfer efficiency using CF mouse and human samples, and found that it reflects a difference in the susceptibility to adenovirus-5 transduction of the epithelial cell types dosed in vivo (columnar) and in vitro (basal-cell-like). These studies indicate that more efficient adenoviral gene-transfer vectors and/or refinement of dosing strategies are needed for therapy of CF lung disease.

Cyclic AMP and Ca2+ interactions affecting epithelial chloride secretion in human cultured colonic epithelia.

1. Chloride secretion in three types of cultured epithelial monolayers derived from a single human colonic adenocarcinoma was measured in terms of short circuit current. The three cell types were designated HCA-7, Colony 3 and Colony 29. 2. Responses of HCA-7 monolayers to basolaterally applied lysylbradykinin (LBK) (10-1000 nM) or carbachol (1-100 microM) were potentiated by pre-exposure to forskolin (10 microM) for 5 min. Forskolin itself increased short circuit current (SCC), so that the total response to forskolin and LBK or carbachol were non-additive. 3. Colony 3 cells did not respond to LBK on either face but did to carbachol on the basolateral side, while Colony 29 epithelia responded to LBK on both sides and to carbachol and histamine basolaterally. Unlike HCA-7 epithelia, responses in Colony 3 and Colony 29 epithelia were not potentiated by forskolin, but were attenuated by piroxicam. 4. In the presence of piroxicam, both forskolin and prostaglandin E2 were able to potentiate the action of both LBK and carbachol in Colony 29 epithelia. 5. LBK receptor activation in Colony 29 epithelia is transduced into an increase in intracellular Ca2+ and cyclic AMP, while in HCA-7 epithelia there is only an increase in intracellular Ca2+ (Cai). These conclusions are considered to apply to both apical and basolateral kinin receptors. 6. It is shown that forskolin has no effect on the elevation of Ca2+ by LBK in either HCA-7 or Colony 29 cells. 7. It is concluded that potentiation of agonist responses occurs when cyclic AMP is raised at the time that intracellular Ca2+ increases. No potentiation of LBK or carbachol by forskolin occurs in Colony 29 monolayers as these agonists increase cyclic AMP via eicosanoid production.

Antagonism of kinin effects on epithelial by Hoe 140: apparently competitive and non-competitive interactions.

1. Hoe-140, a potent kinin receptor antagonist, was investigated for its ability to inhibit the effects of lysylbradykinin (kallidin) on a cultured colonic epithelium, HCA-7 Colony 29, derived from a human adenocarcinoma. 2. Measurements of electrogenic chloride secretion (as short circuit current), and of intracellular Ca2+ (from Fura-2 fluorescence) were used to assess the action of lysylbradykinin in the absence and presence of Hoe 140. 3. From short circuit current data, Hoe 140 appeared to be a competitive antagonist with a Ki value of 5 nM. However, with measurements of intracellular Ca2+ Hoe 140 was apparently a non-competitive antagonist with a Ki of between 4-6 nM. 4. Because of the unexpected finding of non-competitive antagonism, measurements were made with a second antagonist pair, histamine and mepyramine. Mepyramine behaved as a competitive antagonist against responses to histamine with a Ki value of approximately 5 nM when short circuit current measurements were evaluated. However, when intracellular Ca2+ concentration was used as a measure mepyramine, 30 nM, produced a near parallel shift in the response curve, but at 100 nM the maximal response was depressed. 5. The reasons why the apparent type of antagonism depends upon the method of measurement is discussed, bearing in mind that the increase in intracellular Ca2+ is a signal which precedes the increase in short circuit current.

Failure of thapsigargin to alter ion transport in human sweat gland epithelia while intracellular Ca2+ concentration is raised.

Cai in cultured human sweat gland epithelial monolayers was measured using Fura-2 fluorescence. Thapsigargin (Tg) caused a sustained increase in Cai, the rate of rise being slower but the magnitude greater than with the agonists lysylbradykinin and ATP. Tg caused an irreversible change such that even after it was removed Cai was dependent on the ambient calcium concentration, consistent with the hypothesis that Ca2+ entry is controlled by the state of the intracellular stores. Calcium entry after Tg was not modified by nimodipine, omega-conotoxin, or BAY K8644 but could be blocked by low concentrations (0.5 mM) of La3+. High concentrations of La3+ (2 mM) caused an increase in the response to Tg, suggesting that membrane ATPase exerts a major Cai lowering effect. Intracellular Ca2+ ion chelation with 1,2-bis(2-aminophenoxy) ethane-N,N,N',N'-tetraacetic acid significantly blunted the response to Tg. Finally, Mn2+ entry rate into epithelial cells was doubled by Tg. In spite of the evidence that Tg raises Cai to values greater and for longer than calcium requiring agonists only the latter affected transepithelial transport processes. It is shown that Tg neither affects transepithelial sodium transport nor chloride conductance, both of which increase in response to lysylbradykinin or ATP. It is concluded that spatio-temporal patterns of Cai increase after Tg and other agonists are different.

Stimulation of sodium transport by duramycin in cultured human colonic epithelia.

Effects of two peptide antibiotics, duramycin and Ro 09-0198, on ion transport in cultured human colonic epithelia were investigated. Both peptides acted on the apical face of epithelial monolayers, causing an increase in ion transport measured as short circuit current. Concentration-response relationships were complex, because above a concentration of 2 to 5 microM, the peptides caused currents either to decline toward zero or become large and unstable. Ion substitution experiments showed that the majority of the current response was due to electrogenic sodium absorption. An outward chloride current could also be induced by duramycin, provided an outwardly directed chloride gradient was imposed. It was also shown that the peptides could increase [Ca]i, probably by creating entry sites in the apical face. Duramycin was also able to create large conductance (2000 pS) channels in "black" lipid bilayers. It is proposed that the antibiotics interact with membrane lipids in the apical faces of colonic epithelia to create artificial nonspecific ion channels. The prevailing electrochemical gradients which exist when the epithelia are bathed symmetrically in Krebs-Henseleit solution result in increased electrogenic sodium transport. No evidence was found for colonic epithelia that duramycin or Ro 09-0198 interacted specifically with either membrane channels or receptors to increase ion transport.

Synchronous transporting activity in epithelial cells in relation to intracellular calcium concentration.

Cultured monolayers of human sweat-gland epithelia have been used to measure electrogenic sodium transport, as short-circuit current, and intracellular Ca2+ concentration ([Ca]i) from Fura-2 fluorescence. The sodium currents in response to the agonists lysylbradykinin, histamine and carbachol show oscillatory behaviour in the 1-2 per minute frequency range. The oscillations can be terminated either by using specific antagonists or with amiloride, which prevents sodium entry into the epithelium. Oscillatory behaviour is also seen when [Ca]i is measured and occurs in the same frequency range. Sodium transport in these cultured epithelia is thought to result from an increase in [Ca]i, which in turn activates calcium-sensitive potassium channels, so increasing the electrochemical gradient for sodium entry. The oscillatory behaviour implies that the epithelial cells behave in synchrony to increase [Ca]i, so inducing synchronous changes in sodium current. It is shown that the behaviour is not unique to sodium-absorbing epithelia, and the possible utility of synchronous behaviour in epithelial tissues is discussed.

Relation of anion secretory activity to intracellular Ca2+ in response to lysylbradykinin and histamine in a cultured human colonic epithelium.

A cultured human epithelial cell line, Colony 29, has been used to investigate the relation between anion secretion and intracellular Ca2+ concentration (Cai) in response to the secretagogues, lysylbradykinin (LBk) and histamine. Anion secretion was measured as short-circuit current (SCC) responses in epithelia cultured on previous supports. Cai was measured both in cell suspensions and epithelial monolayers using Fura-2 fluorescence. While it is concluded that raised Cai is responsible for anion secretion the relationship is complex. For both secretagogues there is a receptor reserve, that is the maximal Cai increase is greater than that required to cause a maximal secretory response. By examining the interactions between maximally effective concentrations of LBk and histamine it was shown that neither the SCC nor Cai responses behaved additively. From observations in the absence of external Ca2+ it was concluded that both secretagogues cause Ca2+ release from the same intracellular source, but that in normal conditions Ca2+ derived from intracellular and extracellular sources is responsible for the full effect.