David E. Kling

The human milk oligosaccharide 2′-fucosyllactose modulates CD14 expression in human enterocytes, thereby attenuating LPS-induced inflammation

Background A major cause of enteric infection, Gram-negative pathogenic bacteria activate mucosal inflammation through lipopolysaccharide (LPS) binding to intestinal toll-like receptor 4 (TLR4). Breast feeding lowers risk of disease, and human milk modulates inflammation. Objective This study tested whether human milk oligosaccharides (HMOSs) influence pathogenic Escherichia coli-induced interleukin (IL)-8 release by intestinal epithelial cells (IECs), identified specific proinflammatory signalling molecules modulated by HMOSs, specified the active HMOS and determined its mechanism of action. Methods Models of inflammation were IECs invaded by type 1 pili enterotoxigenic E. coli (ETEC) in vitro: T84 modelled mature, and H4 modelled immature IECs. LPS-induced signalling molecules co-varying with IL-8 release in the presence or absence of HMOSs were identified. Knockdown and overexpression verified signalling mediators. The oligosaccharide responsible for altered signalling was identified. Results HMOSs attenuated LPS-dependent induction of IL-8 caused by ETEC, uropathogenic E. coli, and adherent-invasive E. coli (AIEC) infection, and suppressed CD14 transcription and translation. CD14 knockdown recapitulated HMOS-induced attenuation. Overexpression of CD14 increased the inflammatory response to ETEC and sensitivity to inhibition by HMOSs. 2′-fucosyllactose (2′-FL), at milk concentrations, displayed equivalent ability as total HMOSs to suppress CD14 expression, and protected AIEC-infected mice. Conclusions HMOSs and 2′-FL directly inhibit LPS-mediated inflammation during ETEC invasion of T84 and H4 IECs through attenuation of CD14 induction. CD14 expression mediates LPS-TLR4 stimulation of portions of the ‘macrophage migration inhibitory factors’ inflammatory pathway via suppressors of cytokine signalling 2/signal transducer and activator of transcription 3/NF-κB. HMOS direct inhibition of inflammation supports its functioning as an innate immune system whereby the mother protects her vulnerable neonate through her milk. 2′-FL, a principal HMOS, quenches inflammatory signalling.

Human Milk Mucin 1 and Mucin 4 Inhibit Salmonella enterica Serovar Typhimurium Invasion of Human Intestinal Epithelial Cells In Vitro

Many human milk glycans inhibit pathogen binding to host receptors and their consumption by infants is associated with reduced risk of disease. Salmonella infection is more frequent among infants than among the general population, but the incidence is lower in breast-fed babies, suggesting that human milk could contain components that inhibit Salmonella. This study aimed to test whether human milk per se inhibits Salmonella invasion of human intestinal epithelial cells in vitro and, if so, to identify the milk components responsible for inhibition. Salmonella enterica serovar Typhimurium SL1344 (SL1344) invasion of FHs 74 Int and Caco-2 cells were the models of human intestinal epithelium infection. Internalization of fluorescein-5-isothiocyanate-labeled SL1344 into intestinal cells was measured by flow cytometry to quantify infection. Human milk and its fractions inhibited infection; the inhibitory activity localized to the high molecular weight glycans. Mucin 1 and mucin 4 were isolated to homogeneity. At 150 μg/L, a typical concentration in milk, human milk mucin 1 and mucin 4 inhibited SL1344 invasion of both target cell types. These mucins inhibited SL1344 invasion of epithelial cells in a dose-dependent manner. Thus, mucins may prove useful as a basis for developing novel oral prophylactic and therapeutic agents that inhibit infant diseases caused by Salmonella and related pathogens.

Vitamin A deficiency (VAD), teratogenic, and surgical models of congenital diaphragmatic hernia (CDH)†

Congenital diaphragmatic hernia (CDH) is a congenital malformation that occurs with a frequency of 0.08 to 0.45 per 1,000 births. Children with CDH are born with the abdominal contents herniated through the diaphragm and exhibit an associated pulmonary hypoplasia which is frequently accompanied by severe morbidity and mortality. Although the etiology of CDH is largely unknown, considerable progress has been made in understanding its molecular mechanisms through the usage of genetic, teratogenic, and surgical models. The following review focuses on the teratogenic and surgical models of CDH and the possible molecular mechanisms of nitrofen (a diphenyl ether, formerly used as an herbicide) in both induction of CDH and pulmonary hypoplasia. In addition, the mechanisms of other compounds including several anti‐inflammatory agents that have been linked to CDH will be discussed. Furthermore, this review will also explore the importance of vitamin A in lung and diaphragm development and the possible mechanisms of teratogen interference in vitamin A homeostasis. Continued exploration of these models will bring forth a clearer understanding of CDH and its molecular underpinnings, which will ultimately facilitate development of therapeutic strategies.

Nitrofen Induces Apoptosis Independently of Retinaldehyde Dehydrogenase (RALDH) Inhibition

BACKGROUND Nitrofen is a diphenyl ether that induces congenital diaphragmatic hernia (CDH) in rodents. Its mechanism of action has been hypothesized as inhibition of the retinaldehyde dehydrogenase (RALDH) enzymes with consequent reduced retinoic acid signaling. METHODS To determine if nitrofen inhibits RALDH enzymes, a reporter gene construct containing a retinoic acid response-element (RARE) was transfected into HEK-293 cells and treated with varying concentrations of nitrofen in the presence of retinaldehyde (retinal). Cell death was characterized by caspace-cleavage microplate assays and terminal deoxynucleotidyl transferase dUTP nick end-labeling (TUNEL) assays. Ex vivo analyses of cell viability were characterized in fetal rat lung explants using Live/Dead staining. Cell proliferation and apoptosis were assessed using fluorescent immunohistochemistry with phosphorylated histone and activated caspase antibodies on explant tissues. Nile red staining was used to identify intracellular lipid droplets. RESULTS Nitrofen-induced dose-dependent declines in RARE-reporter gene expression. However, similar reductions were observed in control-reporter constructs suggesting that nitrofen compromised cell viability. These observed declines in cell viability resulted from increased cell death and were confirmed using two independent assays. Ex vivo analyses showed that mesenchymal cells were particularly susceptible to nitrofen-induced apoptosis while epithelial cell proliferation was dramatically reduced in fetal rat lung explants. Nitrofen treatment of these explants also showed profound lipid redistribution, primarily to phagocytes. CONCLUSIONS The observed declines in nitrofen-associated retinoic acid signaling appear to be independent of RALDH inhibition and likely result from nitrofen induced cell death/apoptosis. These results support a cellular apoptotic mechanism of CDH development, independent of RALDH inhibition.

Lactic acid is a potential virulence factor for group B Streptococcus

Group B Streptococcus (GBS) is a Gram-positive bacterium that causes sepsis and meningitis in neonates and infants. Although several GBS-associated virulence factors have been described, the mechanisms of GBS invasive disease are not well understood. To characterize additional virulence factors, a novel in vitro infection assay was developed using rat fetal lung explants. However, application of GBS to the system induced rapid lung tissue destruction associated with increased media acidity. Since lactic acid produced by other streptococci is an important virulence factor, we hypothesized that lactic acid contributed to the virulence of GBS. Spent growth media and neutralized-spent media were applied to explants and results indicated that neutralization of the media completely protected the tissue from degradation. These results were verified using multiple viability assays and with transformed cell lines. Furthermore, comparable spent media from Escherichia coli did not induce tissue cytotoxicity, suggesting that GBS produces organic acids in excess of other potential bacterial pathogens. Analysis of the spent media indicated that l-lactate levels reached approximately 70 mM, indicating that lactic acid is a major constituent of the metabolic acid produced by GBS. Treatment of explants with lactic acid alone produced dose-dependent tissue degradation, indicating that lactic acid is independently sufficient to induce target-tissue cytotoxicity. Finally, both spent media and 23.6 mM lactic acid produced dramatic tissue autofluorescence; the basis for this is currently unknown. These studies demonstrate that GBS-produced lactic acid is a potential virulence factor and may contribute to GBS invasive disease.

Retinoic acid decreases fetal lung mesenchymal cell proliferation in vivo and in vitro

Retinoic acid (RA) is an important coordinator of mammalian organogenesis. RA is implicated in critical lung developmental events. Cell proliferation is precisely regulated during development. We investigated the effect of RA on proliferating mesenchymal cells in both whole organ lung cultures and cell cultures. The potential pathways required for the response were studied in cultures of lung mesenchymal cells from embryonic day (e) 12. We observed an RA‐dependent reduction in proliferation of mesenchymal cells in both whole organ and in cell culture. In mesenchymal cell cultures, RA decreased proliferation in lung mesenchymal cells by 72%. This was associated with a decrease of erk‐1/2 activity by 68%. Mesenchymal cell proliferation is erk‐1/2 dependent. Erk‐1/2 can be activated by G‐protein coupled receptors (GPCR) or tyrosine kinase receptors (RTK). RA treatment altered both the RTK and the GPCR pathways in primary lung mesenchymal cells. The Epidermal Growth Factor (EGF) dependent erk‐1/2 activation was increased by 35% whereas the Gi‐protein cascade was inhibited by 44% in cells treated with RA. Our results suggest that RA decreases proliferation of lung mesenchyme via a Gi‐protein and the erk‐1/2 signaling cascade.