Extracellular traps are associated with human and mouse neutrophil and macrophage mediated killing of larval Strongyloides stercoralis.

Neutrophils are multifaceted cells that are often the immune system's first line of defense. Human and murine cells release extracellular DNA traps (ETs) in response to several pathogens and diseases. Neutrophil extracellular trap (NET) formation is crucial to trapping and killing extracellular pathogens. Aside from neutrophils, macrophages and eosinophils also release ETs. We hypothesized that ETs serve as a mechanism of ensnaring the large and highly motile helminth parasite Strongyloides stercoralis thereby providing a static target for the immune response. We demonstrated that S. stercoralis larvae trigger the release of ETs by human neutrophils and macrophages. Analysis of NETs revealed that NETs trapped but did not kill larvae. Induction of NETs was essential for larval killing by human but not murine neutrophils and macrophages in vitro. In mice, extracellular traps were induced following infection with S. stercoralis larvae and were present in the microenvironment of worms being killed in vivo. These findings demonstrate that NETs ensnare the parasite facilitating larval killing by cells of the immune system.

Human and mouse macrophages collaborate with neutrophils to kill larval Strongyloides stercoralis.

Macrophages are multifunctional cells that are active in TH1- and TH2-mediated responses. In this study, we demonstrate that human and mouse macrophages collaborate with neutrophils and complement to kill the parasite Strongyloides stercoralis in vitro. Infection of mice with worms resulted in the induction of alternatively activated macrophages (AAM) within the peritoneal cavity. These cells killed the worms in vivo and collaborated with neutrophils and complement during the in vitro killing process. AAM generated in vitro killed larvae more rapidly than naive macrophages, which killed larvae after a longer time period. In contrast, classically activated macrophages were unable to kill larvae either in vitro or in vivo. This study adds macrophages to the armamentarium of immune components that function in elimination of parasitic helminths and demonstrate a novel function by which AAM control large extracellular parasites.

Aspirin and low-dose nitric oxide-donating aspirin increase life span in a Lynch syndrome mouse model.

Nonsteroidal anti-inflammatory drugs (NSAID) appear to be effective cancer chemopreventives. Previous cellular studies showed that aspirin (acetylsalicylic acid: ASA) and nitric oxide-donating ASA (NO-ASA) suppressed microsatellite instability (MSI) in mismatch repair (MMR)-deficient cells linked to the common cancer predisposition syndrome hereditary nonpolyposis colorectal cancer or Lynch syndrome (LS/HNPCC), at doses 300- to 3,000-fold less than ASA. Using a mouse model that develops MMR-deficient intestinal tumors that appear pathologically identical to LS/HNPCC, we show that ASA (400 mg/kg) and low-dose NO-ASA (72 mg/kg) increased life span by 18% to 21%. We also note a trend where ASA treatment resulted in intestinal tumors with reduced high MSI (H-MSI) and increased low MSI (L-MSI) as defined by the Bethesda Criteria. Low-dose NO-ASA had a minimal effect on MSI status. In contrast to previous studies, high-dose NO-ASA (720/1,500 mg/kg) treatments increased tumor burden, decreased life span, and exacerbated MSI uniquely in the LS/HNPCC mouse model. These results suggest that MMR-deficient tissues/mice may be specifically sensitive to intrinsic pharmacokinetic features of this drug. It is likely that long-term treatment with ASA may represent a chemopreventive option for LS/HNPCC patients. Moreover, as low-dose NO-ASA shows equivalent life span increase at 10-fold lower doses than ASA, it may have the potential to significantly reduce the gastropathy associated with long-term ASA treatment.

D-Serine exposure resulted in gene expression changes implicated in neurodegenerative disorders and neuronal dysfunction in male Fischer 344 rats.

D-Serine, an endogenous amino acid, is involved in many physiological processes through its interaction with the glycine binding site of the N-methyl-D-aspartate (NMDA) receptor. It has important roles in development, learning, and cell death signaling. Recent evidence suggests that decreased function of the NMDA receptor is related to the etiology of schizophrenia, and the use of D-serine as add-on therapy is beneficial in alleviating the symptoms of treatment-refractory schizophrenia. The NMDA receptor also plays a major role in neuronal cell death and neurodegeneration mediated by excitatory amino acid toxicity in ischemia, epilepsy, and trauma. Due to its co-activator function, D-serine can markedly potentiate NMDA-mediated excitotoxicity. To investigate potential adverse effects of D-serine treatment, we investigated gene expression changes in the forebrain of male F-344 rats treated with a single intraperitoneal injection of D-serine (5, 20, 50, 200, or 500 mg/kg) at 96 h post-treatment. Gene expression profiling using Affymetrix Rat Genome 230 2.0 arrays revealed that D-serine treatment resulted in up- and down-regulation of 134 and 52 genes, respectively, based on the common genes identified using three statistical methods, i.e. t test (p < 0.01 over two consecutive doses), ANOVA (with adjusted Bonferonni correction for multiple testing) and significance analysis of microarray (SAM). Self organized map (SOM) clustering analysis of the differentially expressed genes showed two clusters, one with all 134 up-regulated probe sets and the other with all 52 down-regulated probe sets. The dose-response pattern of the down-regulated cluster showed nearly a perfect mirror image of that of the up-regulated one. Gene ontology analysis revealed that pathways implicated in neuronal functions and/or neurodegenerative disorders are over-represented among the differentially expressed genes. Specifically, genes involved in vesicle-mediated transport, endocytosis, ubiquitin conjugation pathway, regulation of actin filament polymerization/depolymerization, focal adhesion, Wnt signaling, and insulin signaling were up-regulated, while genes involved in RNA metabolism/splicing/processing and Notch signaling were down-regulated. Consistent with this finding, pathway analysis using GenMAPP showed a significant number of differentially expressed genes in these pathways. In addition, the GenMAPP result also showed activation of the signaling pathways of several proinflammatory cytokines (including IL-2, IL-3, IL-5, IL-6 and TNF-alpha), which might suggest the onset of neuroinflammation. Biological association network analysis showed that several nuclear factors implicated in transcription regulation (including Taf1, Max, Myc, and Hnf4a) are highly connected to a large number of up-regulated genes. While the transcript levels of these transcription factors were not changed, their connections to Ddx3x, a gene involved in mRNA processing and translation initiation, raise the possibility that they may be up-regulated at the post-transcriptional level. The observation that Ubqln1 and Ube2d, two differentially expressed genes involved in ubiquitin-mediated proteolysis and implicated in neurodegenerative disorders, are highly connected in this network suggests a role of ubiquitination proteasome pathway in response to D-serine exposure. This finding is consistent with the result of gene ontology analysis and suggests that D-serine treatment might result in damage to cellular proteins and subsequent up-regulation of ubiquitination proteasome pathway to clear these damaged proteins. In summary, D-serine exposure resulted in perturbation of a number of pathways implicated in neuronal functions and neurodegenerative disorders. However, activation of cellular response to counter the toxic effects of D-serine might be hindered due to the down-regulation of such important cellular machinery like RNA metabolism, splicing and processing. Consequently, cell damage might be further exacerbated. Taken together, these findings highlight the potential impacts of D-serine exposure on neuronal functions.

Toll-like receptor 4 (TLR4) is required for protective immunity to larval Strongyloides stercoralis in mice.

TLR4 is important for immunity to various unicellular organisms and has been implicated in the immune responses to helminth parasites. The immune response against helminths is generally Th2-mediated and studies have shown that TLR4 is required for the development of a Th2 response against allergens and helminth antigens in mice. C3H/HeJ mice, which have a point mutation in the Tlr4 gene, were used in this study to determine the role of TLR4 in protective immunity to the nematode Strongyloides stercoralis. It was demonstrated that TLR4 was not required for killing larval S. stercoralis during the innate immune response, but was required for killing the parasites during the adaptive immune response. No differences were seen in the IL-5 and IFN-gamma responses, antibody responses or cell recruitment between wild type and C3H/HeJ mice after immunization. Protective immunity was restored in immunized C3H/HeJ mice by the addition of wild type peritoneal exudate cells in the environment of the larvae. It was therefore concluded that the inability of TLR4-mutant mice to kill larval S. stercoralis during the adaptive immune response is due to a defect in the effector cells recruited to the microenvironment of the larvae.

Complement component C3 is required for protective innate and adaptive immunity to larval strongyloides stercoralis in mice.

This study examines the role of complement components C3 and C5 in innate and adaptive protective immunity to larval Strongyloides stercoralis in mice. Larval survival in naive C3(-/-) mice was increased as compared with survival in wild-type mice, whereas C3aR(-/-) and wild-type mice had equivalent levels of larval killing. Larval killing in naive mice was shown to be a coordinated effort between effector cells and C3. There was no difference between survival in wild-type and naive C5(-/-) mice, indicating that C5 was not required during the innate immune response. Naive B cell-deficient and wild-type mice killed larvae at comparable levels, suggesting that activation of the classical complement pathway was not required for innate immunity. Adaptive immunity was equivalent in wild-type and C5(-/-) mice; thus, C5 was also not required during the adaptive immune response. Larval killing was completely ablated in immunized C3(-/-) mice, even though the protective parasite-specific IgM response developed and effector cells were recruited. Protective immunity was restored to immunized C3(-/-) mice by transferring untreated naive serum, but not C3-depleted heat-inactivated serum to the location of the parasites. Finally, immunized C3aR(-/-) mice killed larvae during the adaptive immune response as efficiently as wild-type mice. Therefore, C3 was not required for the development of adaptive immunity, but was required for the larval killing process during both protective innate and adaptive immune responses in mice against larval S. stercoralis.

Protective immunity to the larval stages of onchocerca volvulus is dependent on Toll-like receptor 4.

Toll-like receptor 4 (TLR4) has been shown to be important for the induction of Th2-dependent immune responses in mice. Protective immunity against larval Onchocerca volvulus in mice depends on the development of a Th2 immune response mediated by both interleukin-4 (IL-4) and IL-5. In addition, O. volvulus contains the rickettsial endosymbiont Wolbachia, which has molecules with lipopolysaccharide-like activities that also signal through TLR4. We therefore hypothesized that protective immunity to O. volvulus would not develop in C3H/HeJ mice which have a mutation in the Tlr4 gene (TLR4 mutant), either because of a decreased Th2 response to the larvae or because of the absence of a response to Wolbachia. TLR4-mutant mice were immunized against O. volvulus with irradiated third-stage larvae, and it was observed that Th2 responses were elevated based on increased IL-5 production, total immunoglobulin E (IgE) levels, antigen-specific IgG1 response, and eosinophil recruitment. Protective immunity, however, did not develop in the TLR4-mutant mice. The Th1 response, as measured by gamma interferon production from spleen cells, was comparable in both wild-type and TLR4-mutant mice. Furthermore, antibody responses to Wolbachia were absent in both wild-type and TLR4-mutant mice. Therefore, the defect in the development of a protective immune response against O. volvulus in TLR4-mutant mice is not due to loss of Th2 immunity or the response to Wolbachia but is due to an unidentified TLR4-dependent larval killing mechanism.

DNA immunization with Na+-K+ ATPase (Sseat-6) induces protective immunity to larval Strongyloides stercoralis in mice.

Strongyloides stercoralis causes chronic asymptomatic infections which can be maintained in the human host for many decades. Identification and treatment of S. stercoralis-infected individuals is required because immunosuppression can lead to fatal hyperinfection. In this study, human immunoglobulin G (IgG) that had previously been shown to transfer protective immunity to mice was used to identify potential protective antigens. Three antigens or genes from S. stercoralis larvae were identified as tropomyosin (Sstmy-1), Na+-K+ ATPase (Sseat-6), and LEC-5 (Sslec-5). The genes were cloned into plasmids for DNA immunization, and mice were immunized intradermally with the three plasmids individually in combination with a plasmid containing murine granulocyte-macrophage colony-stimulating factor. Only Na+-K+ ATPase induced a significant reduction in larval survival after DNA immunization. Immunization with a combination of all three plasmids, including Na+-K+ ATPase, did not induce protective immunity. Serum from mice immunized with DNA encoding Na+-K+ ATPase was transferred to naive mice and resulted in partial protective immunity. Therefore, DNA immunization with Na+-K+ ATPase induces protective immunity in mice, and it is the first identified vaccine candidate against infection with larval S. stercoralis.

Human immunoglobulin G mediates protective immunity and identifies protective antigens against larval Strongyloides stercoralis in mice.

Protective immunity to larval Strongyloides stercoralis in mice has been shown to be dependent on antibody, complement, and granulocytes. The goals of the present study was to determine the following: (1) whether human serum could passively transfer immunity to mice, (2) the mechanism by which the serum mediated killing, and (3) whether the antigens (Ags) recognized by the protective human antibody could induce protective immunity in mice. Immunoglobulin G (IgG) from a S. stercoralis-seropositive individual passively transferred immunity to mice. The antibody required granulocytes, but not eosinophils, and complement activation to kill the larvae. Antibody-dependent cellular cytotoxicity was not required for larval killing. Immunization of mice with soluble larval Ags isolated by use of the protective immune IgG resulted in protective immunity. In conclusion, immunity could be transferred to mice by IgG from immune humans, and Ags identified by the immune human IgG induced protective immunity in mice, which thereby suggests their possible use in a vaccine against this infection.

Immunoglobulin E and eosinophil-dependent protective immunity to larval Onchocerca volvulus in mice immunized with irradiated larvae.

Mice immunized with irradiated Onchocerca volvulus third-stage larvae developed protective immunity. Eosinophil levels were elevated in the parasite microenvironment at the time of larval killing, and measurements of total serum antibody levels revealed an increase in the immunoglobulin E (IgE) level in immunized mice. The goal of the present study was to identify the role of granulocytes and antibodies in the protective immune response to the larval stages of O. volvulus in mice immunized with irradiated larvae. Immunity did not develop in mice if granulocytes, including both neutrophils and eosinophils, were eliminated, nor did it develop if only eosinophils were eliminated. Moreover, larvae were killed in naïve interleukin-5 transgenic mice, and the killing coincided with an increase in the number of eosinophils and the eosinophil peroxidase (EPO) level in the animals. To determine if EPO was required for protective immunity, mice that were genetically deficient in EPO were immunized, and there were no differences in the rates of parasite recovery in EPO-deficient mice and wild-type mice. Two mouse strains were used to study B-cell function; micro MT mice lacked all mature B cells, and Xid mice had deficiencies in the B-1 cell population. Immunity did not develop in the micro MT mice but did develop in the Xid mice. Finally, protective immunity was abolished in mice treated to eliminate IgE from the blood. We therefore concluded that IgE and eosinophils are required for adaptive protective immunity to larval O. volvulus in mice.

Specificity and mechanism of immunoglobulin M (IgM)- and IgG-dependent protective immunity to larval Strongyloides stercoralis in mice.

Protective immunity in mice to the infective third-stage larvae (L3) of Strongyloides stercoralis was shown to be dependent on immunoglobulin M (IgM), complement activation, and granulocytes. The objectives of the present study were to determine whether IgG was also a protective antibody isotype and to define the specificity and the mechanism by which IgG functions. Purified IgG recovered from mice 3 weeks after a booster immunization with live L3 was shown to transfer high levels of protective immunity to naïve mice. IgG transferred into mice treated to block complement activation or to eliminate granulocytes failed to kill the challenge larvae. Transfer of immune IgG into IL-5 knockout (KO) mice, which are deficient in eosinophils, resulted in larval attrition, while transfer into FcRgamma KO mice did not result in larval killing. These findings suggest that IgG from mice immunized with live L3 requires complement activation and neutrophils for killing of L3 through an antibody-dependent cellular cytotoxicity (ADCC) mechanism. This is in contrast to the results of investigations using IgM from mice immunized with live L3 and IgG from mice immunized with larval antigens soluble in deoxycholate in which protective immunity was shown to be ADCC independent. Western blot analyses with immune IgM and IgG identified few antigens recognized by all protective antibody isotypes. Results from immunoelectron microscopy demonstrated that the protective antibodies bound to different regions in the L3. It was therefore concluded that while IgM and IgG antibodies are both protective against larval S. stercoralis, they recognize different antigens and utilize different killing mechanisms.