The role of rectal chloride secretion in childhood constipation.

BACKGROUND: Disturbance in fluid secretion, driven by chloride secretion, might play a role in constipation. However, disturbed chloride secretion in those patients has yet to be evaluated. Therefore, the aim of this study was to compare chloride secretion in rectal biopsies of children with functional constipation (FC) to those without constipation. METHODS: To measure changes in short circuit current (I(sc) in µA cm(-2)) reflecting chloride secretion, intestinal biopsies from children with constipation, to either exclude or diagnose Hirschsprung's disease, and from children without constipation (controls) undergoing colonoscopy for screening of familial adenomatous polyposis, juvenile polyps or inflammatory bowel disease (IBD), were compared and studied in Ussing chambers. Following electrogenic sodium absorption blockade by amiloride, chloride secretory responses to calcium-linked (histamine, carbachol) and cAMP-linked (IBMX/forskolin) secretagogues were assessed. KEY RESULTS: Ninety-six patients (46 FC) participated; nine FC patients (n = 1 congenital syndrome and n = 8 technical problems) and 13 controls (n = 6 IBD; n = 7 technical problems) were excluded. No significant difference was found in mean (±SE) basal chloride currents between children with FC and controls (9.6 ± 1.1 vs 9.2 ± 0.8; P = 0.75, respectively). Responses to calcium-linked chloride secretagogues (histamine and carbachol) were significantly higher in controls (33.0 ± 3.0 vs 24.5 ± 2.3; P = 0.03 and 33.6 ± 3.4 vs 26.4 ± 2.7; P = 0.05 following histamine and carbachol, respectively). CONCLUSIONS & INFERENCES: Calcium-linked chloride secretion is disturbed in children with FC. Whether this defect occurs at the level of histamine receptors, components of receptor-linked signal transduction pathways or basolateral Ca(2+) -sensitive K(+) channels enhancing the electrical driving force for apical chloride secretion, remains to be explored.

Aberrant expression of complement regulatory proteins, membrane cofactor protein and decay accelerating factor, in the involved epidermis of patients with vitiligo.

BACKGROUND: Vitiligo is a pigmentary disorder of the skin characterized by the complete absence of melanocytes from the lesion. Complement-activating antimelanocyte antibodies have been implicated in vitiligo pathogenesis. As membrane regulators of complement activation, membrane cofactor protein, decay accelerating factor and CD59 protect cells from elimination by autologous complement, their absence or downregulation on melanocytes may be associated with autoantibody and complement-mediated melanocyte destruction in vitiligo. OBJECTIVES: We studied the expression of these regulatory proteins in non-lesional, perilesional and lesional vitiligo skin compared with those of control specimens. METHODS: We used immunohistochemistry to study the expression of the regulatory proteins, and flow cytometric analysis of cultured melanocytes to investigate possible constitutive changes in the expression levels of these molecules. We also investigated whether melanocytes can influence keratinocyte susceptibility to autologous complement by regulating keratinocytic decay accelerating factor and membrane cofactor protein expression levels. RESULTS: Immunohistochemical data showed that expression of membrane cofactor protein and decay accelerating factor in whole epidermis was lower in lesional and perilesional skin in comparison with non-lesional skin. The reduced in situ expression appeared to be specific to vitiligo. However, coculture experiments indicated that melanocytes do not influence keratinocyte susceptibility to autologous complement. Further, flow cytometric analysis of cultured melanocytes convincingly demonstrated that non-lesional vitiligo and control melanocytes have comparable decay accelerating factor, membrane cofactor protein and CD59 expression levels. CONCLUSIONS: It is therefore concluded that there is no constitutive melanocyte defect per se that could be related to the in vivo expression of these molecules in vitiligo. Nevertheless, the present data suggest that both keratinocytes and melanocytes in the involved vitiliginous whole epidermis express lower levels of decay accelerating factor and membrane cofactor protein compared with controls that could render them more vulnerable to autologous complement attack.