Laura Rivero-Nava scite author profile

-The transmembrane glycoprotein CD38 in airway smooth muscle is the source of cyclic-ADP ribose, an intracellular calcium-releasing molecule, and is subject to regulatory effects of cytokines such as interleukin (IL)-13, a cytokine implicated in asthma. We investigated the role of CD38 in airway hyperresponsiveness using a mouse model of IL-13-induced airway disease. Wild-type (WT) and CD38-deficient (CD38KO) mice were intranasally challenged with 5 g of IL-13 three times on alternate days under isoflurane anesthesia. Lung resistance (RL) in response to inhaled methacholine was measured 24 h after the last challenge in pentobarbital-anesthetized, tracheostomized, and mechanically ventilated mice. Bronchoalveolar cytokines, bronchoalveolar and parenchymal inflammation, and smooth muscle contractility and relaxation using tracheal segments were also evaluated. Changes in methacholine-induced R L were significantly greater in the WT than in the CD38KO mice following intranasal IL-13 challenges. Airway reactivity after IL-13 exposure, as measured by the slope of the methacholine dose-response curve, was significantly higher in the WT than in the CD38KO mice. The rate of isometric force generation in tracheal segments (e.g., smooth muscle reactivity) was greater in the WT than in the CD38KO mice following incubation with IL-13. IL-13 treatment reduced isoproterenol-induced relaxations to similar magnitudes in tracheal segments obtained from WT and CD38KO mice. Both WT and CD38KO mice developed significant bronchoalveolar and parenchymal inflammation after IL-13 challenges compared with naïve controls. The results indicate that CD38 contributes to airway hyperresponsiveness in lungs exposed to IL-13 at least partly by increasing airway smooth muscle reactivity to contractile agonists. interleukin-13; inflammation; asthma; eosinophil; airway smooth muscle CD38 IS A MULTIFUNCTIONAL ECTOENZYME that catalyzes the conversion of ␤-nicotinamide adenine dinucleotide to cyclic ADP-ribose (cADPR) and ADP-ribose (16). Both CD38 and its product cADPR are present in airway smooth muscle (ASM) cells and other mammalian cell types (8,26,32,39). Together with inositol 1,4,5-trisphosphate, cADPR is an important mediator of intracellular calcium ([Ca 2ϩ ] i ) release in smooth muscle cells including that of the airways (7,20,31). The dynamics of [Ca 2ϩ ] i responses to stimuli are central in the regulation of ASM contraction, bronchomotor tone, and airway caliber (33). cADPR induces Ca 2ϩ release from the sarcoplasmic reticulum through activation of ryanodine receptor channels in ASM cells (31). The [Ca 2ϩ ] i responses of human ASM cells exposed to acetylcholine, thrombin, and bradykinin are reduced by the competitive cADPR antagonist 8-bromo-cADPR in a magnitude that correlates positively with the level of CD38 expression (6).CD38-deficient (CD38KO) mice have been used to elucidate the role of CD38 in the function of several organs. CD38-generated cADPR plays a critical role in Ca 2ϩ -induced insulin secretion (21), os...

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CD38: An Ecto-Enzyme at the Crossroads of Innate and Adaptive Immune Responses

Partida-Sánchez

Rivero-Nava

Shi

et al. 2007

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Airway responsiveness in CD38-deficient mice in allergic airway disease: studies with bone marrow chimeras

Guedes

Jude

Paulin

et al. 2015

American Journal of Physiology-Lung Cellular and Molecular Phys

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CD38 is a cell-surface protein involved in calcium signaling and contractility of airway smooth muscle. It has a role in normal airway responsiveness and in airway hyperresponsiveness (AHR) developed following airway exposure to IL-13 and TNF-α but appears not to be critical to airway inflammation in response to the cytokines. CD38 is also involved in T cell-mediated immune response to protein antigens. In this study, we assessed the contribution of CD38 to AHR and inflammation to two distinct allergens, ovalbumin and the epidemiologically relevant environmental fungus Alternaria. We also generated bone marrow chimeras to assess whether Cd38(+/+) inflammatory cells would restore AHR in the CD38-deficient (Cd38(-/-)) hosts following ovalbumin challenge. Results show that wild-type (WT) mice develop greater AHR to inhaled methacholine than Cd38(-/-) mice following challenge with either allergen, with comparable airway inflammation. Reciprocal bone marrow transfers did not change the native airway phenotypic differences between WT and Cd38(-/-) mice, indicating that the lower airway reactivity of Cd38(-/-) mice stems from Cd38(-/-) lung parenchymal cells. Following bone marrow transfer from either source and ovalbumin challenge, the phenotype of Cd38(-/-) hosts was partially reversed, whereas the airway phenotype of the WT hosts was preserved. Airway inflammation was similar in Cd38(-/-) and WT chimeras. These results indicate that loss of CD38 on hematopoietic cells is not sufficient to prevent AHR and that the magnitude of airway inflammation is not the predominant underlying determinant of AHR in mice.

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Entamoeba histolytica: acute granulomatous intestinal lesions in normal and neutrophil-depleted mice

Rivero-Nava

Aguirre-Garcı́a

Shibayama-Salas

et al. 2002

Experimental Parasitology

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Protective Effects of STI-2020 Antibody Delivered Post-Infection by the Intranasal or Intravenous Route in a Syrian Golden Hamster COVID-19 Model

Maruyama

Singh

et al. 2020

Preprint

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We have previously reported that the SARS-CoV-2 neutralizing antibody, STI-2020, potently inhibits cytopathic effects of infection by genetically diverse clinical SARS-CoV-2 pandemic isolates in vitro, and has demonstrated efficacy in a hamster model of COVID-19 when administered by the intravenous route immediately following infection. We now have extended our in vivo studies of STI-2020 to include disease treatment efficacy, profiling of biodistribution of STI-2020 in mice when antibody is delivered intranasally (IN) or intravenously (IV), as well as pharmacokinetics in mice following IN antibody administration. Importantly, SARS-CoV-2-infected hamsters were treated with STI-2020 using these routes, and treatment effects on severity and duration of COVID-19-like disease in this model were evaluated. In SARS-CoV-2 infected hamsters, treatment with STI-2020 12 hours post-infection using the IN route led to a decrease in severity of clinical disease signs and a more robust recovery during 9 days of infection as compared to animals treated with an isotype control antibody. Treatment via the IV route using the same dose and timing regimen resulted in a decrease in the average number of consecutive days that infected animals experienced weight loss, shortening the duration of disease and allowing recovery to begin more rapidly in STI-2020 treated animals. Following IN administration in mice, STI-2020 was detected within 10 minutes in both lung tissue and lung lavage. The half-life of STI-2020 in lung tissue is approximately 25 hours. We are currently investigating the minimum effective dose of IN-delivered STI-2020 in the hamster model as well as establishing the relative benefit of delivering neutralizing antibodies by both IV and IN routes.

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