Surface properties of diarrhoeagenic Escherichia coli isolates.

The surface properties of various Escherichia coli isolates associated with diarrhoeal illness were compared by aqueous partitioning between polyethylene glycol (PEG) and Dextran phases. Two well characterised strains of enteropathogenic E. coli (EPEC) were found to be very hydrophobic, based on the critical polymer concentration. EPEC strain E2348 cured of the EPEC adherence factor (EAF) plasmid had much reduced surface hydrophobicity. Partitioning of a series of diarrhoeagenic E. coli strains demonstrated that the majority of EAF+ EPEC strains were significantly more hydrophobic than EAF- EPEC strains. E. coli strains defined as enteroaggregative on the basis of hybridisation with a specific DNA probe showed much greater heterogeneity in their partitioning behaviour, possibly indicating that the AAF/I pili were not expressed in all strains. The E. coli K-12 strain used as a transformation host for adhesion studies had very low surface hydrophobicity but had a detectable negative charge. No alteration in these properties was observed when transformed with EPEC and recombinant plasmids known to specify adherence to tissue culture cells.

Growth and propagation of normal rat intestinal epithelial cells.

A combination of mild proteolytic digestion and selective growth stimulation has been used to isolate and propagate adult rat intestinal epithelial cells with a finite life span. Growth of these cells on a variety of matrices and on mesenchymal cells has resulted in the expression of brush border enzymes including sucrase-isomaltase, aminopeptidase N, and alkaline phosphatase. Examination of the cells at the electron microscopic level has revealed that although these cells express key brush border enzymes, they do not have a fully formed brush border. These findings suggest that the expression of brush border enzymes and structural proteins represent distinct stages of enterocyte differentiation that are under separate transcriptional and temporal control.

Effects of concanavalin A and pokeweed lectins on microvillar membrane proteins during the organ culture of rabbit intestinal mucosa.

The effects of pokeweed lectin (PWL) and concanavalin A (Con A) on microvillar membrane (MVM) proteins during the organ culture of rabbit ileal explants for 24 hours were compared with the known effects of enteropathogenic Escherichia coli (EPEC). PWL resulted in the accelerated release of brush border enzymes into the culture medium, accompanied by decreased tissue activities and an increase in the total activity present in the tissue and culture medium. Con A had less effect on the release and tissue activities of brush border enzymes and the total activity was not increased. Sucrose density gradient centrifugation of the culture medium showed that MVM enzymes were predominantly particulate, consistent with their release as vesicles. Centrifugation of ileal explants showed that PWL, but not Con A, resulted in a decrease in the modal density of the brush border which was consistent with a lower glycoprotein-to-lipid ratio. These findings suggest that PWL, in common with EPEC, may cause the disruption and vesiculation of microvilli and the compensatory stimulation of MVM protein synthesis.

Evidence for a compensatory increase in synthesis of brush border enzymes in the jejunum of Irish Setters with gluten-sensitive enteropathy.

OBJECTIVE: To determine whether biosynthesis of aminopeptidase N (ApN), alkaline phosphatase (AP), and total microvillus membrane protein is altered in Irish Setters with gluten-sensitive enteropathy (GSE). ANIMALS: A litter of 6 Irish Setters with GSE and 3 healthy Greyhounds. PROCEDURES: Explants obtained from affected dogs at 4 and 12 months were maintained in vitro and were compared with material from healthy control dogs. Biosynthesis of ApN and AP was monitored by incorporation of [35S]methionine and immunoprecipitation of these enzymes. RESULTS: Jejunal explants from affected Irish Setters had significantly higher rates of biosynthesis of total protein, microvillus membrane protein, AP, and ApN, compared with control tissue. Two forms of ApN with apparent molecular mass of 155 and 135 kd and 4 forms of AP with apparent molecular mass of 210 to 260, 150, 130, and 105 kd were identified in total membrane fractions from control and affected dogs. CONCLUSIONS: Reduced activities of ApN and AP in dogs with GSE are not attributable to decreased synthesis of these proteins and document enhanced synthesis of microvillar membrane proteins, which may be a compensatory response to enterocyte damage. The 150-kd form of AP was most prominent in tissue from the most affected dogs, probably representing an early form of this enzyme. In contrast, the 105-kd form was most intense in tissue from controls and less intense in tissue of affected dogs.