Upregulation of defensins in burn sheep small intestine.

OBJECTIVE: The aim of this study was to visualize and localize the sheep antimicrobials, beta-defensins 1, 2, and 3, (SBD-1, SBD-2, SBD-3), sheep neutrophil defensin alpha (SNP-1), and the cathelicidin LL-37 in sheep small intestine after burn injury, our hypothesis being that these compounds would be upregulated in an effort to overcome a compromised endothelial lining. Response to burn injury includes the release of proinflammatory cytokines and systemic immune suppression that, if untreated, can progress to multiple organ failure and death, so protective mechanisms have to be initiated and implemented. METHODS: Tissue sections were probed with antibodies to the antimicrobials and then visualized with fluorescently labeled secondary antibodies and subjected to fluorescence deconvolution microscopy and image reconstruction. RESULTS: In both the sham and burn samples, all the aforementioned antimicrobials were seen in each of the layers of small intestine, the highest concentration being localized to the epithelium. SBD-2, SBD-3, and SNP-1 were upregulated in both enterocytes and Paneth cells, while SNP-1 and LL-37 showed increases in both the inner circular and outer longitudinal muscle layers of the muscularis externa following burn injury. Each of the defensins, except SBD-1, was also seen in between the muscle layers of the externa and while burn caused slight increases of SBD-2, SBD-3, and SNP-1 in this location, LL-37 content was significantly decreased. CONCLUSION: That while each of these human antimicrobials is present in multiple layers of sheep small intestine, SBD-2, SBD-3, SNP-1, and LL-37 are upregulated in the specific layers of the small intestine.

Construct Validity of the Pig Intestine Model in the Simulation of Laparoscopic Urethrovesical Anastomosis

Introduction: Laparoscopic training models are increasingly important in urology to allow trainees to improve their laparoscopic skills prior to going to the operating room. For a training model to be valid, it must correlate with performance in a real case. The model must also discriminate between experienced and inexperienced subjects. [See PDF for complete abstract]

Suppression by {\it Trypanosoma brucei\/} of anaphylaxis-mediated ion transport in the small intestine of rats

Most tissue-invasive parasitic helminths prime for type 1 hypersensitivity or anaphylaxis during some phase of their life cycles. A prototype in this regard is the nematode Trichinella spiralis. Blood protozoa capable of tissue invasion, such as Trypanosoma brucei, might also be expected to prime for the expression of anaphylaxis. However, this response is usually absent in protozoal infections. The hypothesis tested was that failure of hosts infected with T.brucei to express anaphylaxis is related to this parasite's ability to selectively down-regulate immunoglobulin E (IgE) production, and not to an innate lack of allergenicity on the part of T.brucei-derived antigens. This hypothesis was tested by studying in the intestine of rats, antigen-induced Cl$\sp-$ secretion, which results from a local anaphylactic response mediated by IgE and mucosal mast cells. The Cl$\sp-$ secretory response can be primed either by infection with T.spiralis or by the parenteral administration of antigen. Anaphylaxis-induced Cl$\sp-$ secretion is expressed in vitro, and can be quantified electrophysiologically, as a change in transmural short-circuit current when sensitized intestine is mounted in Ussing chambers and challenged with the sensitizing antigen.^ Rats injected parenterally with trypanosome antigen elicited intestinal anaphylaxis in response to antigenic challenge. In contrast, the intestine of rats infected with T.brucei failed to respond to challenge with trypanosome antigen. Infection with T.brucei also suppressed antigen-induced Cl$\sp-$ secretion in rats sensitized and challenged with various antigens, including T.spiralis antigen. However, T.brucei infection did not inhibit the anaphylactic response in rats concomitantly infected with T.spiralis. Relative to the anaphylactic mediators, T.brucei infection blocked production of IgE in rats parenterally injected with antigen but not in T.spiralis-infected hosts. Also, the mucosal mastocytosis normally associated with trichinosis was unaffected by the trypanosome infection. These results support the conclusion that the failure to express anaphylaxis-mediated Cl$\sp-$ secretion in T.brucei infected rats, is due to this protozoan's ability to inhibit IgE production and not to the lack of allergenicity of trypanosome antigens. ^

Early stages of experimental colon carcinogenesis inhibit mast cell-dependent mucosal immune function of the distal colon

Inhibition of local host immune reactions is one mechanism contributing to tumor progression. To determine if alterations in local immune functioning occur during colon carcinogenesis, a model mucosal immune response, type I hypersensitivity against the intestinal parasite Trichinella spiralis, was first characterized in normal mice and then examined during experimental colon carcinogenesis. Segments of sensitized colon mounted in Ussing chambers and challenged with T. spiralis-derived antigen resulted in a rise in short-circuit current ($\rm\Delta I\sb{sc}$) that was antigen-specific and inhibited by furosemide, implicating epithelial Cl$\sp-$ secretion as the ionic mechanism. The immune-regulated Cl$\sp-$ secretion by colonic epithelial cells required the presence of mast cells with surface IgE. Inhibition of potential anaphylactic mediators with various pharmacological agents in vitro implicated prostaglandins and leukotrienes as the principal mediators of the antigen-induced $\rm\Delta I\sb{sc}$, with 5-hydroxytryptamine also playing a role. Distal colon from immune mice fed an aspirin-containing diet (800 mg/kg powdered diet) ad libitum for 6 wk had a decreased response to antigen, confirming the major role of prostaglandins in generating the colonic I$\sb{\rm sc}$. To determine the effects of early stages of colon carcinogenesis on this mucosal immune response, mice were immunized with T. spiralis 1 day after or 8 wk prior to the first of 6 weekly injections of the procarcinogen 1,2-dimethylhydrazine (DMH). Responsiveness to antigenic challenge was suppressed in the distal colon 4-6 wk after the final injection of DMH. One injection of DMH was not sufficient to inhibit antigen responsiveness. The colonic epithelium remained sensitive to direct stimulation by exogenous Cl$\sp-$ secretagogues. Decreased antigen-induced $\rm\Delta I\sb{sc}$ in the distal colon was not due to systemic immune suppression by DMH, as the proximal colon and jejunum maintained responsiveness to antigen. Also, rejection of a secondary T. spiralis infection from the small intestine was not altered. Tumors eventually developed 25-30 wk after the final injection of DMH only in the distal portions of the colon. These results suggest that early stages of DMH-induced colon carcinogenesis manipulate the microenvironment such that mucosal immune function, as measured by immune-regulated Cl$\sp-$ secretion, is suppressed in the distal colon, but not in other regions of the gut. Future elucidation of the mechanisms by which this localized inhibition of immune-mediated ion transport occurs may provide possible clues to the microenvironmental changes necessary for tumor progression in the distal colon. ^

{\it In vivo\/} induction of DNA changes in cervicovaginal epithelium by perinatal estrogen exposure

Epidemiological studies have associated estrogens with human neoplasm such as the endometrium, cervix, vagina, breast, and liver. Perinatal exposure to natural (17$\beta$-estradiol (17$\beta$-E$\sb2)\rbrack$ and synthetic (diethylstilbestrol (DES)) estrogens induces neoplastic changes in humans and rodents. Previous studies demonstrated that neonatal 17$\beta$-E$\sb2$ treatment increased the nuclear DNA content of mouse cervicovaginal epithelium that preceded histologically evident neoplasia. In order to determine whether this effect was specific to 17$\beta$-E$\sb2,$ associated with chromosomal changes, and relevant to the human, female BALB/c mice were treated neonatally with either 17$\alpha$-estradiol (17$\alpha$-E$\sb2)$ and 5$\beta$-dihydrotestosterone ($5\beta$-DHT), both inactive steroids in adult reproductive tissue, or 17$\beta$-E$\sb2.$ Ten-day-old mice received pellet implants of 17$\beta$-E$\sb2,$ 17$\alpha$-E$\sb2,$ $5\beta$-DHT, or cholesterol. Seventy-day-old cervicovaginal tracts were examined histologically and flow cytometrically. 17$\beta$-E$\sb2$-treated animals were evaluated by fluorescent in situ hybridization (FISH) using a probe specific for chromosome 1. Trisomy of chromosomes 1, 7, 11, and 17 was evaluated by FISH in cervicovaginal material from 19 DES-exposed and 19 control patients.^ $17\beta$-E$\sb2, 17\alpha$-E$\sb2$, and $5\beta$-DHT-induced dramatic developmental and histological changes in the cervicovaginal tract, including hypospadia, hyperplasia, and persistent cornification. The changes induced by 17$\alpha$-E$\sb2$ were equivalent to 17$\beta$-E$\sb2.$ Neonatal 17$\alpha$-E$\sb2$-induced adenosquamous cervicovaginal tumors at 24 months. 17$\alpha$-E$\sb2$ and $5\beta$-DHT significantly increased the nuclear DNA content over control animals, but at significantly lower levels than 17$\beta$-E$\sb2.$ DNA ploidy changes were highest (80%) in animals treated neonatally and secondarily with 17$\beta$-E$\sb2.$ Secondary 17$\alpha$-E$\sb2$ and $5\beta$-DHT administration, unlike 17$\beta$-E$\sb2,$ didn't significantly increase DNA content. Chromosome 1 trisomy incidence was 66% in neonatal 17$\beta$-E$\sb2$-treated animals. Trisomy was evident in 4 DES-exposed patients: one patient with trisomy of chromosomes 1, 7, and 11; one patient with chromosome 7 trisomy; and two patients with chromosome 1 trisomy. These data demonstrated the biological effects of 17$\alpha$-E$\sb2$ and $5\beta$-DHT were age-dependent, 17$\alpha$-E$\sb2$ was equivalent to 17$\beta$-E$\sb2$ and tumorigenic when administered neonatally, and histological changes were not steroid specific. Chromosomal changes were associated with increased nuclear DNA content and chromosomal changes may be an early event in the development of tumors in human DES-exposed tissues. ^

A dual oxidase generates a protective oxidative burst during infection in C. elegans

Caenorhabditis elegans has recently been developed as a model system to study both pathogen virulence mechanisms and host defense responses. We have shown that C. elegans produces reactive oxygen species (ROS) in response to exposure to the important Gram-positive, noscomial pathogen, Enterococcus faecalis. We have also shown evidence of oxidative stress and upregulation of stress response after exposure to the pathogen. As in mammalian systems, this work shows that production of ROS for innate immune functions occurs via an NADPH oxidase. Specifically, reducing expression of a dual oxidase, Ce-duox1/BLI-3 causes a decrease in ROS production in response to E. faecalis. We also present evidence that reduction of expression of Ce-duox1/BLI-3 increases susceptibility to this pathogen, specifically when expression is reduced in the intestine and the hypodermis. This dual oxidase has previously been localized to the hypodermis, but we show that it is additionally localized to the intestine of C. elegans. To further demonstrate the protective effects of the pathogen-induced ROS production, we demonstrate that antioxidants that scavenge ROS, increase the sensitivity of the nematode to the infection, in stark contrast to their longevity-promoting effects under non-pathogenic conditions. In conclusion, we postulate that the generation of ROS by NADPH oxidases in the barrier epithelium is an ancient, highly conserved innate immune defense mechanism.^

REGULATION OF TOXIN SYNTHESIS BY CLOSTRIDIUM DIFFICILE

Clostridium difficile is the leading definable cause of nosocomial diarrhea worldwide due to its virulence, multi-drug resistance, spore-forming ability, and environmental persistence. The incidence of C. difficile infection (CDI) has been increasing exponentially in the last decade. Virulent strains of C. difficile produce either toxin A and/or toxin B, which are essential for the pathogenesis of this bacterium. Current methods for diagnosing CDI are mostly qualitative tests that detect the bacterium, the toxins, or the toxin genes. These methods do not differentiate virulent C. difficile strains that produce active toxins from non-virulent strains that do not produce toxins or produce inactive toxins. Based on the knowledge that C. difficile toxins A and B cleave a substrate that is stereochemically similar to the native substrate of the toxins, uridine diphosphoglucose, a quantitative, cost-efficient assay, the Cdifftox activity assay, was developed to measure C. difficile toxin activity. The concept behind the activity assay was modified to develop a novel, rapid, sensitive, and specific assay for C. difficile toxins in the form of a selective and differential agar plate culture medium, the Cdifftox Plate assay (CDPA). This assay combines in a single step the specific identification of C. difficile strains and the detection of active toxin(s). The CDPA was determined to be extremely accurate (99.8% effective) at detecting toxin-producing strains based on the analysis of 528 C. difficile isolates selected from 50 tissue culture cytotoxicity assay-positive clinical stool samples. This new assay advances and improves the culture methodology in that only C. difficile strains will grow on this medium and virulent strains producing active toxins can be differentiated from non-virulent strains. This new method reduces the time and effort required to isolate and confirm toxin-producing C. difficile strains and provides a clinical isolate for antibiotic susceptibility testing and strain typing. The Cdifftox activity assay was used to screen for inhibitors of toxin activity. Physiological levels of the common human conjugated bile salt, taurocholate, was found to inhibit toxin A and B in vitro activities. When co-incubated ex vivo with purified toxin B, taurocholate protected Caco-2 colonic epithelial cells from the damaging effects of the toxin. Furthermore, using a caspase-3 detection assay, taurocholate reduced the extent of toxin B-induced Caco-2 cell apoptosis. These results suggest that bile salts can be effective in protecting the gut epithelium from C. difficile toxin damage, thus, the delivery of physiologic amounts of taurocholate to the colon, where it is normally in low concentration, could be useful in CDI treatment. These findings may help to explain why bile rich small intestine is spared damage in CDI, while the bile salt poor colon is vulnerable in CDI. Toxin synthesis in C. difficile occurs during the stationary phase, but little is known about the regulation of these toxins. It was hypothesized that C. difficile toxin synthesis is regulated by a quorum sensing mechanism. Two lines of evidence supported this hypothesis. First, a small (KDa), diffusible, heat-stable toxin-inducing activity accumulates in the medium of high-density C. difficile cells. This conditioned medium when incubated with low-density log-phase cells causes them to produce toxin early (2-4 hrs instead of 12-16 hrs) and at elevated levels when compared with cells grown in fresh medium. These data suggested that C. difficile cells extracellularly release an inducing molecule during growth that is able to activate toxin synthesis prematurely and demonstrates for the first time that toxin synthesis in C. difficile is regulated by quorum signaling. Second, this toxin-inducing activity was partially purified from high-density stationary-phase culture supernatant fluid by HPLC and confirmed to induce early toxin synthesis, even in C. difficile virulent strains that over-produce the toxins. Mass spectrometry analysis of the purified toxin-inducing fraction from HPLC revealed a cyclic compound with a mass of 655.8 Da. It is anticipated that identification of this toxin-inducing compound will advance our understanding of the mechanism involved in the quorum-dependent regulation of C. difficile toxin synthesis. This finding should lead to the development of even more sensitive tests to diagnose CDI and may lead to the discovery of promising novel therapeutic targets that could be harnessed for the treatment C. difficile infections.