Matthew Dickinson scite author profile

Surfactant proteins A and D (SP-A and SP-D) are lung collectins composed of two regions, a globular head domain that binds PAMPs and a collagenous tail domain that initiates phagocytosis. We provide evidence that SP-A and SP-D act in a dual manner, to enhance or suppress inflammatory mediator production depending on binding orientation. SP-A and SP-D bind SIRPalpha through their globular heads to initiate a signaling pathway that blocks proinflammatory mediator production. In contrast, their collagenous tails stimulate proinflammatory mediator production through binding to calreticulin/CD91. Together a model is implied in which SP-A and SP-D help maintain a non/anti-inflammatory lung environment by stimulating SIRPalpha on resident cells through their globular heads. However, interaction of these heads with PAMPs on foreign organisms or damaged cells and presentation of the collagenous tails in an aggregated state to calreticulin/CD91, stimulates phagocytosis and proinflammatory responses.

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Surfactant Proteins A and D Suppress Alveolar Macrophage Phagocytosis via Interaction with SIRPα

Janssen

McPhillips²,

Dickinson³

et al. 2008

Am J Respir Crit Care Med

183

167

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Rationale: Efficient removal of apoptotic cells is essential for the resolution of acute pulmonary inflammation. Alveolar macrophages ingest apoptotic cells less avidly than other professional phagocytes at rest but overcome this defect during acute inflammation. Surfactant protein (SP)-A and SP-D are potent modulators of macrophage function and may suppress clearance of apoptotic cells through activation of the transmembrane receptor signal inhibitory regulatory protein a (SIRPa). Objectives: To investigate whether binding of SP-A and SP-D to SIRPa on alveolar macrophages suppresses apoptotic cell clearance. Methods: Phagocytosis of apoptotic cells was assessed using macrophages pretreated with SP-A, SP-D, or the collectin-like molecule C1q. Binding of SP-A and SP-D to SIRPa was confirmed in vitro using blocking antibodies and fibroblasts transfected with active and mutant SIRPa. The effects of downstream molecules SHP-1 and RhoA on phagocytosis were studied using SHP-1-deficient mice, sodium stibogluconate, and a Rho kinase inhibitor. Lipopolysaccharide was given to chimeric mice to study the effects of SP-A and SP-D binding on inflammatory macrophages.

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Pharmacological activation of the circadian component REV-ERB inhibits HIV-1 replication

Borrmann

Davies

Dickinson

et al. 2020

Sci Rep

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Human immunodeficiency virus 1 (HIV-1) is a life-threatening pathogen that still lacks a curative therapy or vaccine. Despite the reduction in AIDS-related deaths achieved by current antiretroviral therapies, drawbacks including drug resistance and the failure to eradicate infection highlight the need to identify new pathways to target the infection. Circadian rhythms are endogenous 24-h oscillations which regulate physiological processes including immune responses to infection, and there is an emerging role for the circadian components in regulating viral replication. The molecular clock consists of transcriptional/translational feedback loops that generate rhythms. In mammals, BMAL1 and CLOCK activate rhythmic transcription of genes including the nuclear receptor REV-ERBα, which represses BMAL1 and plays an essential role in sustaining a functional clock. We investigated whether REV-ERB activity regulates HIV-1 replication and found REV-ERB agonists inhibited HIV-1 promoter activity in cell lines, primary human CD4 T cells and macrophages, whilst antagonism or genetic disruption of REV-ERB increased promoter activity. The REV-ERB agonist SR9009 inhibited promoter activity of diverse HIV-subtypes and HIV-1 replication in primary T cells. This study shows a role for REV-ERB synthetic agonists to inhibit HIV-1 LTR promoter activity and viral replication, supporting a role for circadian clock components in regulating HIV-1 replication. All life forms have evolved under a rhythmically changing light/dark cycle due to the Earth's rotation. From bacteria to man, all organisms possess an internal clock that oscillates in a 24-h manner to anticipate environmental changes. The central clock and peripheral oscillators share a common molecular architecture and consist of transcriptional/translational feedback loops that regulate rhythmic gene expression 1. In mammals, BMAL1 and CLOCK dimerize and the complex can bind E-box motifs in the promoter/enhancer of various clock genes, including Per and Cry, to activate their transcription. In turn, the PER and CRY proteins repress BMAL1/CLOCK function and thereby shut down their own transcription. An additional feedback loop involves the nuclear receptors REV-ERBα and RORα. RORα competes with REV-ERBα for binding to the Bmal1 promoter ROR element (RORE) site and activates Bmal1 transcription. REV-ERBα and RORα coordinate a regulatory loop which is crucial for stabilizing the core clock machinery 2 (Fig. 1). The circadian system regulates host innate and adaptive immune responses to microbial pathogens 3-5 and host susceptibility to an infectious agent is not only dependent on the inoculum size, transmission route and length of exposure, but on the time of day when the pathogen is encountered 6. Recent clinical studies show that the time of vaccination can influence host immune responses and vaccine efficacy 7. Viruses are obligate parasites that rely on host cell synthesis machinery for their replication, survival and dissemination. The potential for circadian pathways to regulat...

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Dynamics of Transforming Growth Factor (TGF)-β Superfamily Cytokine Induction During HIV-1 Infection Are Distinct From Other Innate Cytokines

et al. 2020

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Human immunodeficiency virus type 1 (HIV-1) infection triggers rapid induction of multiple innate cytokines including type I interferons, which play important roles in viral control and disease pathogenesis. The transforming growth factor (TGF)-β superfamily is a pleiotropic innate cytokine family, some members of which (activins and bone morphogenetic proteins (BMPs)) were recently demonstrated to exert antiviral activity against Zika and hepatitis B and C viruses but are poorly studied in HIV-1 infection. Here, we show that TGF-β1 is systemically induced with very rapid kinetics (as early as 1–4 days after viremic spread begins) in acute HIV-1 infection, likely due to release from platelets, and remains upregulated throughout infection. Contrastingly, no substantial systemic upregulation of activins A and B or BMP-2 was observed during acute infection, although plasma activin levels trended to be elevated during chronic infection. HIV-1 triggered production of type I interferons but not TGF-β superfamily cytokines from plasmacytoid dendritic cells (DCs) in vitro, putatively explaining their differing in vivo induction; whilst lipopolysaccharide (but not HIV-1) elicited activin A production from myeloid DCs. These findings underscore the need for better definition of the protective and pathogenic capacity of TGF-β superfamily cytokines, to enable appropriate modulation for therapeutic purposes.

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