Inflammasomes in livestock and wildlife: Insights into the intersection of pathogens and natural host species

Vrentas, Catherine E.; Schaut, Robert G.; Boggiatto, Paola M.; Olsen, Steven C.; Sutterwala, Fayyaz S.; Moayeri, Mahtab

doi:10.1016/j.vetimm.2018.05.008

Cited by 22 publications

(11 citation statements)

References 102 publications

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“…The gene MAP2K7 is involved in the signal transduction mediating the cell responses to environmental stresses and is a candidate region for milk yield in buffalo (Du et al, 2019); LRRC8E forms volume-regulated anion channels, a key structure that regulates osmotic volume regulation (König and Stauber, 2019); and OXCT1 plays a role in ketone body catabolism in mammary glands during lactation, and it is related to fat percentage (Bionaz and Loor, 2008). The QTL regions associated with milk protein in this study have been previously found to be related to SCS (SNAPC2, CTXN1, ELAVL1, CCL25, FBN3, CERS4, CD320, NDUFA7, KANK3, ANGPTL4, RAB11B, MYO1F, ADAMTS10, ACTL9, GFUS, PYCR3, TIGD5, EEF1D, NAPRT, MROH6, GSDMD, ZC3H3, MAFA, and RHPN1) and immune system (TRIP10, C3, TNFSF14, CD70, and TNFSF9; Griesbeck-Zilch et al, 2009;Li et al, 2010b;Chen et al, 2015;Vrentas et al, 2018;Wu et al, 2019;Rabe et al, 2020). In addition, MicroRNA MIR339B plays a regulatory role in hematopoiesis, mastitis, and breast cancer (Bruchova et al, 2007;Wu et al, 2010;Li et al, 2014).…”

Section: Candidate Genes For Ppsupporting

confidence: 57%

Genome-wide association study on milk production and somatic cell score for Thai dairy cattle using weighted single-step approach with random regression test-day model

Buaban¹,

Lengnudum²,

Boonkum³

et al. 2022

Journal of Dairy Science

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Section: Candidate Genes For Ppsupporting

confidence: 57%

Genome-wide association study on milk production and somatic cell score for Thai dairy cattle using weighted single-step approach with random regression test-day model

Buaban¹,

Lengnudum²,

Boonkum³

et al. 2022

Journal of Dairy Science

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“…While current knowledge of the role of the inflammasome in livestock vectors of disease is still limited, there is an expanding literature on the impact of the NLRP3 inflammasome in multiple livestock species, especially swine (reviewed in Vrentas et al). 22 Expansion of our characterization of inflammasomes in bovine species has the potential to contribute to our understanding of differences between either bovine and human, or bovine and wildlife, species in terms of susceptibility to zoonotic infections, differences in disease virulence and persistence, and/or differences in vaccine responses.…”

Section: Discussionmentioning

confidence: 99%

“…Despite the detailed characterization of inflammasome pathways in rodent and human systems, our understanding of inflammasome activation in livestock hosts of disease is limited (reviewed in Vrentas et al). 22 Recently, the first characterization of NLRP3 activation in bovine cells was published, 23 but nothing is known of NLRP1 responses in these species, despite the fact that herbivores like cattle and bison, rather than rodents, are the most common hosts for anthrax in natural environments. Similarly, shedding of Shigella and Listeria from large ruminants is an important contributor to the environmental spread of these bacteria, which can also cause active disease in ruminants.…”

Section: Introductionmentioning

confidence: 99%

Characterization of the NLRP1 inflammasome response in bovine species

et al. 2019

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Inflammasomes act as sensors of infection or damage to initiate immune responses. While extensively studied in rodents, understanding of livestock inflammasomes is limited. The NLRP1 inflammasome sensor in rodents is activated by Toxoplasma gondii, Bacillus anthracis lethal toxin (LT), and potentially other zoonotic pathogens. LT activates NLRP1 by N-terminal proteolysis, inducing macrophage pyroptosis and a pro-inflammatory cytokine response. In contrast, NLRP1 in macrophages from humans and certain rodent strains is resistant to LT cleavage, and pyroptosis is not induced. Evolution of NLRP1 sequences towards those leading to pyroptosis is of interest in understanding innate immune responses in different hosts. We characterized NLRP1 in cattle ( Bos taurus) and American bison ( Bison bison). Bovine NLRP1 is not cleaved by LT, and cattle and bison macrophages do not undergo toxin-induced pyroptosis. Additionally, we found a predicted Nlrp1 splicing isoform in cattle macrophages lacking the N-terminal domain. Resistance to LT in bovine and human NLRP1 correlates with evolutionary sequence similarity to rodents. Consistent with LT-resistant rodents, bovine macrophages undergo a slower non-pyroptotic death in the presence of LPS and LT. Overall, our findings support the model that NLRP1 activation by LT requires N-terminal cleavage, and provide novel information on mechanisms underlying immune response diversity.

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“…202 However, given its inextricable role in infectious diseases, pyroptosis has been also recently implicated in numerous diseases of domestic animals, such as porcine reproductive and respiratory syndrome virus (PRRSV) infection and classical swine fever virus infection, in which it causes release of IL-1beta by macrophages. 305 The finding of increased NLRP3 labeling in the glomeruli of dogs infected with Leishmania infantum led to the hypothesis regarding a potential role of the NLRP3 inflammasome engagement in the pathogenesis. 83 Although little is known about inflammasome responses in cattle, in vitro studies demonstrated caspase-1 activation in bovine herpesvirus 1 infections, as well as IL-1beta secretion from bovine monocyte-derived macrophages in the presence of bovine viral diarrhea virus type 2 and LPS.…”

Section: Pyroptosismentioning

confidence: 99%

Mechanisms of Regulated Cell Death: Current Perspectives

Santagostino¹,

Assenmacher

Tarrant

et al. 2021

Vet Pathol

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Balancing cell survival and cell death is fundamental to development and homeostasis. Cell death is regulated by multiple interconnected signaling pathways and molecular mechanisms. Regulated cell death (RCD) is implicated in fundamental processes such as organogenesis and tissue remodeling, removal of unnecessary structures or cells, and regulation of cell numbers. RCD can also be triggered by exogenous perturbations of the intracellular or extracellular microenvironment when the adaptive processes that respond to stress fail. During the past few years, many novel forms of non-apoptotic RCD have been identified, and the characterization of RCD mechanisms at a molecular level has deepened our understanding of diseases encountered in human and veterinary medicine. Given the complexity of these processes, it has become clear that the identification of RCD cannot be based simply on morphologic characteristics and that descriptive and diagnostic terms presently used by pathologists—such as individual cell apoptosis or necrosis—appear inadequate and possibly misleading. In this review, the current understanding of the molecular machinery of each type of non-apoptotic RCD mechanisms is outlined. Due to the continuous discovery of new mechanisms or nuances of previously described processes, the limitations of the terms apoptosis and necrosis to indicate microscopic findings are also reported. In addition, the need for a standard panel of biomarkers and functional tests to adequately characterize the underlying RCD and its role as a mechanism of disease is considered.

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Inflammasomes in livestock and wildlife: Insights into the intersection of pathogens and natural host species

Cited by 22 publications

References 102 publications

Genome-wide association study on milk production and somatic cell score for Thai dairy cattle using weighted single-step approach with random regression test-day model

Genome-wide association study on milk production and somatic cell score for Thai dairy cattle using weighted single-step approach with random regression test-day model

Characterization of the NLRP1 inflammasome response in bovine species

Mechanisms of Regulated Cell Death: Current Perspectives

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