Limited role of nuclear receptor Nur77 in Escherichia coli-induced peritonitis.

Nuclear receptor Nur77 (NR4A1, TR3, or NGFI-B) has been shown to play an anti-inflammatory role in macrophages, which have a crucial function in defense against peritonitis. The function of Nur77 in Escherichia coli-induced peritoneal sepsis has not yet been investigated. Wild-type and Nur77-knockout mice were inoculated with E. coli, and bacterial outgrowth, cell recruitment, cytokine profiles, and tissue damage were investigated. We found only a minor transient decrease in bacterial loads in lung and liver of Nur77-knockout compared to wild-type mice at 14 h postinfection, yet no changes were found in the peritoneal lavage fluid or blood. No differences in inflammatory cytokine levels or neutrophil/macrophage numbers were observed, and bacterial loads were equal in wild-type and Nur77-knockout mice at 20 h postinfection in all body compartments tested. Also, isolated peritoneal macrophages did not show any differences in cytokine expression patterns in response to E. coli. In endothelial cells, Nur77 strongly downregulated both protein and mRNA expression of claudin-5, VE-cadherin, occludin, ZO-1, and ß-catenin, and accordingly, these genes were upregulated in lungs of Nur77-deficient mice. Functional permeability tests pointed toward a strong role for Nur77 in endothelial barrier function. Indeed, tissue damage in E. coli-induced peritonitis was notably modulated by Nur77; liver necrosis and plasma aspartate aminotransferase (ASAT)/alanine aminotransferase (ALAT) levels were lower in Nur77-knockout mice. These data suggest that Nur77 does not play a role in the host response to E. coli in the peritoneal and blood compartments. However, Nur77 does modulate bacterial influx into the organs via increased vascular permeability, thereby aggravating distant organ damage.

Diphtheria toxoid and N-trimethyl chitosan layer-by-layer coated pH-sensitive microneedles induce potent immune responses upon dermal vaccination in mice.

Dermal immunization using antigen-coated microneedle arrays is a promising vaccination strategy. However, reduction of microneedle sharpness and the available surface area for antigen coating is a limiting factor. To overcome these obstacles, a layer-by-layer coating approach can be applied onto pH-sensitive microneedles. Following this approach, pH-sensitive microneedle arrays (positively charged at coating pH5.8 and nearly uncharged at pH7.4) were alternatingly coated with negatively charged diphtheria toxoid (DT) and N-trimethyl chitosan (TMC), a cationic adjuvant. First, the optimal DT dose for intradermal immunization was determined in a dose-response study, which revealed that low-dose intradermal immunization was more efficient than subcutaneous immunization and that the EC50 dose of DT upon intradermal immunization is 3-fold lower, as compared to subcutaneous immunization. In a subsequent immunization study, microneedle arrays coated with an increasing number (2, 5, and 10) of DT/TMC bilayers resulted in step-wise increasing DT-specific immune responses. Dermal immunization with microneedle arrays coated with 10 bilayers of DT/TMC (corresponding with ±0.6µg DT delivered intradermally) resulted in similar DT-specific immune responses as subcutaneous immunization with 5µg of DT adjuvanted with aluminum phosphate (8-fold dose reduction). Summarizing, the layer-by-layer coating approach onto pH-sensitive microneedles is a versatile method to precisely control the amount of coated and dermally-delivered antigen that is highly suitable for dermal immunization.