Abstract
To explore mechanisms whereby Malpighian keratinocytes can transdifferentiate into an intestinal-like epithelium, as observed in the early steps of Barrett's esophagus (BE) development, long-standing cultures of esophageal keratinocytes derived from normal mouse esophageal explants were developed. These cells were able to form multilayers and to differentiate on filter support by the formation of differentiated layers of basal cells (cytokeratine 14 positive) on which secondary suprabasal cell layers (cytokeratine 4 positive) spontaneously developed. Thus, these cultured cells, referred to as P3E6, reproduced, at least in part, the proliferation and stratification pattern existing in the normal esophagus. Because chronic exposure to acid pH is known to be a critical factor for BE development, culture medium at pH 3.5 was added into the apical chamber of cell cultures. This led to a decrease in the overall number of cells but it did not affect cell proliferation. Furthermore, external acid environment triggered expression of the GFP reporter gene fused downstream of the cdx2 intestinal homeogene regulatory sequences in P3E6 transfected cells. Expression of the endogenous CDX2 protein, detected by western blot and immunocytochemical analysis, correlated with promoter activation. These findings demonstrate that chronic exposure of esophageal keratinocytes to acid pH induces transcription of cdx2, an intestinal specific homeobox gene known to play a critical role in the differentiation and maintenance of intestinal epithelial functions. The results suggest that chronic acid exposure can modify the fate of P3E6 esophageal keratinocytes towards an intestinal program. This can be a key step in the development of intestinal metaplasia often observed in esophagus-cardia junction.
Highlights
The complex processes that direct cell-specific differentiation are not completely understood, but once the differentiation program is activated cells usually maintain their specific phenotype
Metaplasia is frequently observed in a variety of pathological conditions, the transition that occurs in the progression from normal epithelium to metaplastic epithelium is still not well understood (Eguchi and Kodama, 1993; Slack and Tosh, 2001; Tosh and Slack, 2002)
An important role has been attributed to acidity in the development of the intestinal metaplasia of the esophagus or Barrett’s esophagus (BE) where the normal squamous epithelium of the lower esophagus is replaced by columnar epithelium, principally of intestinal type (Spechler and Goyal, 1996; Sharma, 1999; Jankowski et al, 2000)
Summary
The complex processes that direct cell-specific differentiation are not completely understood, but once the differentiation program is activated cells usually maintain their specific phenotype. In certain pathological conditions the epithelium undergoes changes that transform cells into different phenotypes (Tosh and Slack, 2002). The more evident example remains the pathological condition leading to metaplasia, in which the epithelium acquires a new phenotype (Slack, 1985; Slack, 1986; Tosh and Slack, 2002). Metaplasia is frequently observed in a variety of pathological conditions, the transition that occurs in the progression from normal epithelium to metaplastic epithelium is still not well understood (Eguchi and Kodama, 1993; Slack and Tosh, 2001; Tosh and Slack, 2002). Few studies have documented cellular responses to acid and the molecular pathways involved in these responses (Fitzgerald et al, 1996; Souza et al, 2001)
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