Mast Cell Responses to Food Toxins

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Description
Mast cells, components of the immune system, promote allergic symptoms such as itching, sneezing, and increased intestinal motility. Although mast cells have a detrimental role in allergies, they might have unrecognized physiological functions. Indeed, mast cells have been reported to

Mast cells, components of the immune system, promote allergic symptoms such as itching, sneezing, and increased intestinal motility. Although mast cells have a detrimental role in allergies, they might have unrecognized physiological functions. Indeed, mast cells have been reported to protect against lethal envenomation. I hypothesized that mast cells have a protective role in the defense against toxins. Because toxin-induced diarrheal diseases are one of the top five causes of mortality in children worldwide (induced by cholera toxin, for example), I tested the role of mast cells in sensing relevant dietary toxins. My goals were to a) establish an in vitro model of mast cell activation using foodborne toxins and b) determine the mast cell transcriptional programs induced by these toxins. To establish the in vitro model, I generated mast cells from murine bone marrow precursors and cultured them in mast cell-specific media for 5 weeks. Mature mast cells were then stimulated with toxins from phylogenetically distinct origins. I found that, surprisingly, no toxin was able to induce significant cell death, even after 24h of culturing, suggesting that mast cells are resistant to the toxic effects of these compounds. To assess mast cell activation, I quantified the levels of TNF-α 6h after toxin exposure. None of the toxins were able to induce TNF-α production by mast cells, suggesting that toxins might not induce inflammation in mast cells. However, I found that mast cells induced expression of activation-related transcripts like Il1b, Tpsab1, Alox5, Egr1, Tnfa and Hdc in response to cholera toxin, when compared with controls. Mast cells stimulated with retrorsine induced the expression of Tph1, Alox5, Il1b and Hdc. Deoxynivalenol induced Ltc4, Il6, Tpsab1, Tnfa, Hdc, and Alox5 while okadaic acid induced Il6, Tnfa, Tph1, Alox5, Egr1, Il1b and Hdc expression. Aconitine only induced Il6, Hdc, and Tpsab1. Lastly, Ochratoxin A induced expression of Il1b, Il6, Tpsab1, Egr1 and Hdc. Altogether, these results suggest that mast cells directly sense and respond to food toxins, which was unknown. How exactly mast cells contribute to toxin defenses will be crucial to investigate as they impact both toxin-induced and inflammatory diseases.
Date Created
2023
Agent

Serp-1 Treatment for Diffuse Alveolar Hemorrhage in Systemic Lupus Erythematosus; Analysis of Efficacy and Mechanism of Action

Description

Systemic Lupus Erythematosus (SLE) is an autoimmune disease resulting in widespread inflammation of various organ tissues including the lung, heart, kidneys, brain, joints, vasculature, and more. Systemic Lupus Erythematosus (SLE) has at present no cure and therefore, treatments focus on

Systemic Lupus Erythematosus (SLE) is an autoimmune disease resulting in widespread inflammation of various organ tissues including the lung, heart, kidneys, brain, joints, vasculature, and more. Systemic Lupus Erythematosus (SLE) has at present no cure and therefore, treatments focus on improving quality of life by targeting flare-ups of inflammation (6). Diffuse Alveolar Hemorrhage (DAH) is a rare complication of SLE affecting 1-5% of people diagnosed with SLE. DAH is characterized by bleeding into the lung alveolar spaces and is associated with inflammation, potentially caused by infections and injuries. While the prevalence of DAH is low, the mortality rate is high at 50-80% (5). DAH has no proven effective treatment and many treatments used have severe side effects. Serp-1 is a Myxomavirus derived immune modulating serine protease inhibitor, a serpin, with proven efficacy in a wide range of inflammation-associated disorders (1). Due to the efficacy of Serp-1 in reducing arterial inflammation and lung consolidation in mouse herpes virus infections, Serp-1 treatment in a mouse model of pristane-induced DAH was investigated. Multiple groups were tested including mouse models that were not given pristane as well as mice with pristane-induced DAH treated with saline control, wild-type unmodified Serp-1, and a polyethylene glycol-modified variant of Serp-1 termed PEGSerp-1.

Date Created
2023-05
Agent

Therapeutic application of an immunomodulatory viral serpin in a murine DSS-induced colitis model

Description

Inflammatory bowel disease (IBD), including Crohn’s disease and ulcerative colitis, is an immune disorder that causes chronic inflammation of the gastrointestinal tract. There is an unmet need for effective pharmacological treatments as current standard therapies including aspirin derivatives and corticosteroids

Inflammatory bowel disease (IBD), including Crohn’s disease and ulcerative colitis, is an immune disorder that causes chronic inflammation of the gastrointestinal tract. There is an unmet need for effective pharmacological treatments as current standard therapies including aspirin derivatives and corticosteroids often fail to control the disease. For a significant portion, 30% or more, of patients, surgical removal of the affected bowel is required at some point in their disease course to address complications of bleeding, infections with sepsis, toxic megacolon among many others. There are also associated severe complications involving many other organs due to the underlying immune mediated reactions. In this study, PEGylated Serp-1 (PEGSerp-1) a modified Myxomavirus-derived serine protease inhibitor that binds and inhibits serine proteases in the coagulation and complement cascades, is evaluated in a pre-clinical model of IBD. Experimental colitis was induced in male C57BL/6J mice by oral administration of dextran sulfate sodium (DSS). In mice with acute colitis induced by exposure to 5% DSS for 6 days, daily treatment with PEGSerp-1 significantly improved survival. When initiation of treatment was delayed by 7 days in this acute colitis model, PEGSerp-1 treatment improved markers of disease severity and significantly reduced inflammation in the colon. PEGSerp-1 is an effective treatment of acute DSS-induced colitis when used as a preventative or delayed treatment.

Date Created
2022-12
Agent

Microbiome and Immune Modulation in Renal Subcapsular Allograft Acute Rejection

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Description

The microbiome and the immune system are known to work in conjunction to modulate the clearance of pathogens and tolerance of beneficial microbes. A growing area of research seeks to study the potential extent of the involvement of the microbiome

The microbiome and the immune system are known to work in conjunction to modulate the clearance of pathogens and tolerance of beneficial microbes. A growing area of research seeks to study the potential extent of the involvement of the microbiome in modulating and supporting the immune system during acute allograft rejection. It has been hypothesized that the localized microbiota in each organ produce metabolites that instigate inflammatory immune responses, but whether microbiota interactions precipitate acute allograft rejection is unknown. Therefore, this study focuses on microbiome shifts in the gut and kidney after inducing acute renal transplant rejection in order to implicate gut dysbiosis as a precursor or supporter of allograft rejection. This study also subsequently explores the use of an immune-modulating protein in order to determine differences in the outcome of transplant rejection and potential differences in intestinal microbial load. This experiment sought to induce rejection in BALB/c mice through the use of C57BL/6 mouse renal slivers. Microbiome abundance was analyzed in all experimental groups. Understanding the role of the microbiome in transplant rejection has vast clinical implications and has the potential to enhance pre- and post-operative treatment, and immune management and quality of life following organ transplant.

Date Created
2021-05
Agent

Loss of Kaiso Expression in Breast Cancer Cells Prevents Intra-Vascular Invasion in the Lung and Secondary Metastasis

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Description

The metastatic activity of breast carcinomas results from complex genetic changes in epithelial tumor cells and accounts for 90% of deaths in affected patients. Although the invasion of the local lymphatic vessels and veins by malignant breast tumor cells and

The metastatic activity of breast carcinomas results from complex genetic changes in epithelial tumor cells and accounts for 90% of deaths in affected patients. Although the invasion of the local lymphatic vessels and veins by malignant breast tumor cells and their subsequent metastasis to the lung, has been recognized, the mechanisms behind the metastatic activity of breast tumor cells to other distal organs and the pathogenesis of metastatic cancer are not well understood. In this study, we utilized derivatives of the well-established and highly metastatic triple negative breast cancer (TNBC) cell line MDA-MB-231 (MDA-231) to study breast tumor metastasis in a mouse model. These MDA-231 derivatives had depleted expression of Kaiso, a POZ-ZF transcription factor that is highly expressed in malignant, triple negative breast cancers. We previously reported that Kaiso depletion attenuates the metastasis of xenografted MDA-231 cells. Herein, we describe the pathological features of the metastatic activity of parental (Kaisopositive) versus Kaisodepleted MDA-231 cells. Both Kaisopositive and Kaisodepleted MDA-231 cells metastasized from the original tumor in the mammary fat pad to the lung. However, while Kaisopositive cells formed large masses in the lung parenchyma, invaded large pulmonary blood vessels and formed secondary metastases and large tumors in the distal organs, Kaisodepleted cells metastasized only to the lung where they formed small metastatic lesions. Importantly, intravascular invasion and secondary metastases in distal organs were not observed in mice xenografted with Kaisodepleted cells. It thus appears that the lung may constitute a barrier for less invasive breast tumors such as the Kaisodepleted TNBC cells; this barrier may limit tumor growth and prevents Kaisodepleted TNBC cells from invading the pulmonary blood vessels and forming secondary metastases in distal organs.

Date Created
2017-09-07
Agent