Background and Aims: Neural Wiskott-Aldrich Syndrome protein (N-WASP) is a key regulator of the actin cytoskeleton in epithelial tissues and is poised to mediate cytoskeletal-dependent aspects of apical junction complex (AJC) homeostasis. Attaching-and-effacing (AE) pathogens disrupt this homeostasis through translocation of the effector molecule early secreted antigenic target-6 (ESX)-1 secretion-associated protein F (EspF). Although the mechanisms underlying AJC disruption by EspF are unknown, EspF contains putative binding sites for N-WASP and the endocytic regulator sorting nexin 9 (SNX9). We hypothesized that N-WASP regulates AJC integrity and AE pathogens use EspF to induce junction disassembly through an N-WASP- and SNX9-dependent pathway. Methods: We analyzed mice with intestine-specific N-WASP deletion and generated cell lines with N-WASP and SNX9 depletion for dynamic functional assays. We generated EPEC and Citrobacter rodentium strains complemented with EspF bearing point mutations abolishing N-WASP and SNX9 binding to investigate the requirement for these interactions. Results: Mice lacking N-WASP in the intestinal epithelium showed spontaneously increased permeability, abnormal AJC morphology, and mislocalization of occludin. N-WASP depletion in epithelial cell lines led to impaired assembly and disassembly of tight junctions in response to changes in extracellular calcium. Cells lacking N-WASP or SNX9 supported actin pedestals and type III secretion, but were resistant to EPEC-induced AJC disassembly and loss of transepithelial resistance. We found that during in vivo infection with AE pathogens, EspF must bind both N-WASP and SNX9 to disrupt AJCs and induce intestinal barrier dysfunction. Conclusions: Overall, these studies show that N-WASP critically regulates AJC homeostasis, and the AE pathogen effector EspF specifically exploits both N-WASP and SNX9 to disrupt intestinal barrier integrity during infection.

Antibody class switching is mediated by a DNA recombination event that replaces the C mu gene with one of the other heavy (H) chain constant region (CH) genes located 3' to the C mu gene. The regulation of this process is essential to the immune response because different CH regions provide different biological functions. Correlative evidence indicates that the isotype (class) specificity of the switch is determined by the accessibility of specific CH genes as indicated by hypomethylation and transcriptional activity. For example, RNAs transcribed from specific unrearranged CH genes are induced prior to switching under conditions that promote subsequent switching to these same CH genes. The function of transcription of these germline CH genes is unknown. In this report, we describe the structure of RNA transcribed from unrearranged gamma 1 genes in mouse spleen cells treated with LPS plus a HeLa cell supernatant containing recombinant interleukin 4. The germline gamma 1 RNA is initiated at multiple start sites 5' to the tandem repeats of the gamma 1 switch (S gamma 1) region. As is true for analogous RNAs transcribed from unrearranged gamma 2b and alpha genes, the germline gamma 1 RNA has an I exon transcribed from the region 5' to S gamma 1 sequences, which is spliced at a unique site to the C gamma gene. The germline gamma 1 RNA has an open-reading frame (ORF) that potentially encodes a small protein 48 amino acid in length.