Background: The single-layer epithelial cells linked by tight junctions (TJs) act as physical barriers to separate the microbiota from the lamina propria. Bacterial translocation (BT) and septic complications are documented in intestinal obstruction (IO). Whether bacterial crosses the epithelial layer through transcellular or intercellular routes in IO is poorly understood. Bacterial internalization to epithelial cells has been documented in IO, and is associated with interferon-gamma (IFNγ) production. It remains unclear how bacteria gain access to epithelial soma through densely packed microvilli rooted on terminal web (TW) and if myosin light chain kinase (MLCK)-dependent brush border (BB) fanning plays a role. On the other hand, intercellular epithelial permeability is regulated by TJ reorganization and myosin light chain (MLC) phosphorylation. Overexpression of inducible nitric oxide synthase (iNOS) is implicated in the pathogenesis of BT, of which the mechanism remains unclear. Aim: Our research objectives were to investigate the molecular mechanism of transcellular bacterial endocytosis (focusing on regulatory roles of IFNγ and MLCK) and intercellular tight junctional impairment (focusing on the roles of ROCK and PKCzeta in epithelial iNOS-mediated permeability increase) using a mouse model with IO. Methods: Mouse distal small intestines were obstructed by loop ligation in which vehicle, ML-7 (a MLCK inhibitor) or L-Nil (an iNOS inhibitor), or Y27632 (a ROCK inhibitor) was luminally administered. After obstruction for 6 or 24 hours, intestinal tissues were mounted on Ussing chambers for macromolecular flux. Liver and spleen tissues were assessed for bacterial counts. Caco-2 cells were exposed to 100 IU/ml IFNγ and 1 mM SNAP (a NO donor), and transepithelial resistance (TER) and permeability were evaluated. Results: Our results showed that following IO for 6 hrs, epithelial endocytosis was observed in the absence of TJ damage. Enhanced TW MLC phosphorylation, arc formation and BB fanning coincided with intermicrovillous bacterial penetration, which were inhibited by ML-7 (a MLCK inhibitor) and neutralizing anti-IFNγ, but not Y27632. The phenomena were not seen in mice deficient of long MLCK-210 or IFNγ. Stimulation of human Caco-2BBe cells with IFNγ caused MLCK-dependent BB fanning, which preceded caveolin-mediated bacterial internalization through cholesterol-rich lipid rafts. On the other hand, mice with IO for 24 hrs displayed epithelial permeability rise and BT, associated with TJ disruption and MLC phosphorylation. Enteric instillation of L-Nil (an iNOS inhibitor) and Y27632 (a ROCK inhibitor) attenuated the IO-induced barrier damage. L-Nil decreased IO-induced MLC, MYPT1 and PKCzeta phosphorylation, suggesting that iNOS is upstream of ROCK and PKCzeta signaling. In vitro studies showed that SNAP (a NO donor) induced transepithelial electrical resistance drop and permeability rise via ROCK-dependent MLC phosphorylation and PKCzeta-dependent TJ reorganization. In summary, we showed that epithelial iNOS activates two distinct signals, PKCzeta and ROCK, to disrupt TJs leading to bacterial influx. Conclusion: MLCK-dependent BB fanning and bacterial endocytosis were seen after 6 hrs of IO and ROCK-dependent TJ disruption in enterocytes and intercellular permeability increase were noted after 24 hrs of IO. Impaired epithelial barrier allowing intercellular and transcytotic penetration of bacteria may contribute to initiation or relapse of chronic gut inflammation and septic complications.