Quantitative proteomics analysis reveals the pathogenesis of obstructed defecation syndrome caused by abnormal expression of dystrophin

Abstract

BACKGROUND Obstructed defecation syndrome (ODS) represents the most prevalent form of chronic constipation, affecting a diverse patient population, leading to numerous complications, and imposing a significant burden on healthcare resources. Most ODS patients have insufficient rectal propulsion, but the exact mechanism underlying the pathogenesis of ODS remains unclear. AIM To explore the molecular mechanism underlying the pathogenesis of ODS. METHODS A total of 30 pairs of rectal samples were collected from patients with ODS (ODS group) or grade IV prolapsed hemorrhoids without constipation (control group) for quantitative proteomic and bioinformatic analysis. Subsequently, 50 pairs of paraffin-embedded rectal specimens were selected for immunohistochemistry and immunofluorescence studies to validate the analysis results. Human intestinal smooth cell contractile function experiments and electrophysiological experiments were conducted to verify the physiological functions of target proteins. Cellular ultrastructure was detected using transmission electron microscopy. RESULTS In comparison to the control group, the expression level of dystrophin (DMD) in rectal specimens from ODS patients was markedly reduced. This finding was corroborated using immunohistochemistry and immunofluorescence techniques. The diminished expression of DMD compromised the contractile function of intestinal smooth muscle cells. At the molecular level, nucleoporin protein 153 and L-type voltage-gated calcium channel were found to be overexpressed in intestinal smooth muscle cells exhibiting downregulated DMD expression. Electrophysiological experiments confirmed an excessive influx of calcium ions into these cells. Moreover, vacuolar-like structures which may be associated with excessive calcium influx were observed in the cells by transmission electron microscopy. CONCLUSION Decreased DMD expression in intestinal smooth muscle may upregulate L-type voltage-gated calcium channel expression, leading to excessive calcium influx which may cause a decrease in rectal propulsion, thereby contributing to the pathogenesis of ODS.