Peter H. S. Sporn scite author profile

Elevated blood and tissue CO(2), or hypercapnia, is common in severe lung disease. Patients with hypercapnia often develop lung infections and have an increased risk of death following pneumonia. To explore whether hypercapnia interferes with host defense, we studied the effects of elevated P(CO2) on macrophage innate immune responses. In differentiated human THP-1 macrophages and human and mouse alveolar macrophages stimulated with lipopolysaccharide (LPS) and other Toll-like receptor ligands, hypercapnia inhibited expression of tumor necrosis factor and interleukin (IL)-6, nuclear factor (NF)-kappaB-dependent cytokines critical for antimicrobial host defense. Inhibition of IL-6 expression by hypercapnia was concentration dependent, rapid, reversible, and independent of extracellular and intracellular acidosis. In contrast, hypercapnia did not down-regulate IL-10 or interferon-beta, which do not require NF-kappaB. Notably, hypercapnia did not affect LPS-induced degradation of IkappaB alpha, nuclear translocation of RelA/p65, or activation of mitogen-activated protein kinases, but it did block IL-6 promoter-driven luciferase activity in mouse RAW 264.7 macrophages. Elevated P(CO2) also decreased phagocytosis of opsonized polystyrene beads and heat-killed bacteria in THP-1 and human alveolar macrophages. By interfering with essential innate immune functions in the macrophage, hypercapnia may cause a previously unrecognized defect in resistance to pulmonary infection in patients with advanced lung disease.

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Elevated CO₂suppresses specific Drosophila innate immune responses and resistance to bacterial infection

Helenius

Krupinski

Turnbull

et al. 2009

Proc. Natl. Acad. Sci. U.S.A.

123

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Elevated CO2 levels (hypercapnia) frequently occur in patients with obstructive pulmonary diseases and are associated with increased mortality. However, the effects of hypercapnia on non-neuronal tissues and the mechanisms that mediate these effects are largely unknown. Here, we develop Drosophila as a genetically tractable model for defining non-neuronal CO 2 responses and response pathways. We show that hypercapnia significantly impairs embryonic morphogenesis, egg laying, and egg hatching even in mutants lacking the Gr63a neuronal CO 2 sensor. Consistent with previous reports that hypercapnic acidosis can suppress mammalian NF-B-regulated innate immune genes, we find that in adult flies and the phagocytic immune-responsive S2* cell line, hypercapnia suppresses induction of specific antimicrobial peptides that are regulated by Relish, a conserved Rel/NF-B family member. Correspondingly, modest hypercapnia (7-13%) increases mortality of flies inoculated with E. faecalis, A. tumefaciens, or S. aureus. During E. faecalis and A. tumefaciens infection, increased bacterial loads were observed, indicating that hypercapnia can decrease host resistance. Hypercapnic immune suppression is not mediated by acidosis, the olfactory CO 2 receptor Gr63a, or by nitric oxide signaling. Further, hypercapnia does not induce responses characteristic of hypoxia, oxidative stress, or heat shock. Finally, proteolysis of the Relish IB-like domain is unaffected by hypercapnia, indicating that immunosuppression acts downstream of, or in parallel to, Relish proteolytic activation. Our results suggest that hypercapnic immune suppression is mediated by a conserved response pathway, and illustrate a mechanism by which hypercapnia could contribute to worse outcomes of patients with advanced lung disease, who frequently suffer from both hypercapnia and respiratory infections.COPD ͉ hypercapnia ͉ Relish ͉ NF-B ͉ Gr63a

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Carbon dioxide-sensing in organisms and its implications for human disease

Cummins

Selfridge

Sporn

et al. 2013

Cell. Mol. Life Sci.

116

117

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The capacity of organisms to sense changes in the levels of internal and external gases and to respond accordingly is central to a range of physiologic and pathophysiologic processes. Carbon dioxide, a primary product of oxidative metabolism is one such gas that can be sensed by both prokaryotic and eukaryotic cells and in response to altered levels, elicit the activation of multiple adaptive pathways. The outcomes of activating CO2-sensitive pathways in various species include increased virulence of fungal and bacterial pathogens, prey-seeking behavior in insects as well as taste perception, lung function, and the control of immunity in mammals. In this review, we discuss what is known about the mechanisms underpinning CO2 sensing across a range of species and consider the implications of this for physiology, disease progression, and the possibility of developing new therapeutics for inflammatory and infectious disease.

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Reduced Superoxide Dismutase in Lung Cells of Patients with Asthma

Smith

Shamsuddin

Sporn

et al. 1997

Free Radical Biology and Medicine

150

106

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Peter H. S. Sporn

Elevated CO₂selectively inhibits interleukin‐6 and tumor necrosis factor expression and decreases phagocytosis in the macrophage

Elevated CO₂suppresses specific Drosophila innate immune responses and resistance to bacterial infection

Carbon dioxide-sensing in organisms and its implications for human disease

Reduced Superoxide Dismutase in Lung Cells of Patients with Asthma

Contact Info

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Resources

About

Peter H. S. Sporn

Elevated CO2selectively inhibits interleukin‐6 and tumor necrosis factor expression and decreases phagocytosis in the macrophage

Elevated CO2suppresses specific Drosophila innate immune responses and resistance to bacterial infection

Carbon dioxide-sensing in organisms and its implications for human disease

Reduced Superoxide Dismutase in Lung Cells of Patients with Asthma

Contact Info

Product

Resources

About

Elevated CO₂selectively inhibits interleukin‐6 and tumor necrosis factor expression and decreases phagocytosis in the macrophage

Elevated CO₂suppresses specific Drosophila innate immune responses and resistance to bacterial infection