Apical electrolyte concentration modulates barrier function and tight junction protein localization in bovine mammary epithelium

Department of Anatomy and Physiology, Kansas State University, Manhattan, Kansas Submitted 8 November 2005 ; accepted in final form 22 July 2006 In vitro mammary epithelial cell models typically fail to form a consistently tight barrier that can effectively separate blood from milk. Our hypothesis was that mammary epithelial barrier function would be affected by changes in luminal ion concentration and inflammatory cytokines. Bovine mammary epithelial (BME-UV cell line) cells were grown to confluence on permeable supports with a standard basolateral medium and either high-electrolyte (H-elec) or low-electrolyte (L-elec) apical medium for 14 days. Apical media were changed to/from H-elec medium at predetermined times prior to assay. Transepithelial electrical resistance ( R te ) was highest in monolayers continuously exposed to apical L-elec. A time-dependent decline in R te began within 24 h of H-elec medium exposure. Change from H-elec medium to L-elec medium time-dependently increased R te . Permeation by FITC-conjugated dextran was elevated across monolayers exposed to H-elec, suggesting compromise of a paracellular pathway. Significant alteration in occludin distribution was evident, concomitant with the changes in R te , although total occludin was unchanged. Neither substitution of Na + with N -methyl- D -glucosamine (NMDG + ) nor pharmacological inhibition of transcellular Na + transport pathways abrogated the effects of apical H-elec medium on R te . Tumor necrosis factor alpha, but not interleukin-1 nor interleukin-6, in the apical compartment caused a significant decrease in R te within 8 h. These results indicate that mammary epithelium is a dynamic barrier whose cell-cell contacts are acutely modulated by cytokines and luminal electrolyte environment. Results not only demonstrate that BME-UV cells are a model system representative of mammary epithelium but also provide critical information that can be applied to other mammary model systems to improve their physiological relevance. transepithelial electrical resistance; apical cation concentration; paracellular permeability; mastitis; inflammatory cytokines; occludin Address for reprint requests and other correspondence: B. D. Schultz, Dept. of Anatomy and Physiology, 228 Coles Hall, Kansas State Univ., Manhattan, KS 66506 (e-mail: bschultz{at}vet.ksu.edu ) Related articles in Am J Physiol Cell Physiol: Corrigendum Am J Physiol Cell Physiol 2007 292: C2306-C2309. [Full Text]