Cholinergic neurotransmission links solitary chemosensory cells to nasal inflammation

Saunders, Cecil J.; Christensen, Michael; Finger, Thomas E.; Tizzano, Marco

doi:10.1073/pnas.1402251111

Cited by 179 publications

(253 citation statements)

References 50 publications

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“…Furthermore, in vivo studies demonstrated that mice exposed to acyl-homoserine lactones via the retronasal stream experienced significant reductions in respiratory rate, suggesting that interactions between bacterial acyl-homoserine lactones and chemosensory cells are capable of inducing responses indicative of nasal trigeminal irritants (304). The activation of nasal solitary chemosensory cells by acyl-homoserine lactones triggers a proinflammatory response (328); this response may damage the integrity of the epithelium and enable bacteria to access the trigeminal nerve endings. Once bacteria have penetrated the epithelium, they may potentially travel along the olfactory and/or trigeminal nerves to the brain, within axons, between the axons, within the surrounding glia (olfactory ensheathing cells or Schwann cells), or between the glia and the connective tissue sheath (perineurium) that contains the nerve bundle.…”

Section: Pathogens That Enter the Brain Through The Nose Bacteriamentioning

confidence: 99%

Pathogens Penetrating the Central Nervous System: Infection Pathways and the Cellular and Molecular Mechanisms of Invasion

et al. 2014

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SUMMARY The brain is well protected against microbial invasion by cellular barriers, such as the blood-brain barrier (BBB) and the blood-cerebrospinal fluid barrier (BCSFB). In addition, cells within the central nervous system (CNS) are capable of producing an immune response against invading pathogens. Nonetheless, a range of pathogenic microbes make their way to the CNS, and the resulting infections can cause significant morbidity and mortality. Bacteria, amoebae, fungi, and viruses are capable of CNS invasion, with the latter using axonal transport as a common route of infection. In this review, we compare the mechanisms by which bacterial pathogens reach the CNS and infect the brain. In particular, we focus on recent data regarding mechanisms of bacterial translocation from the nasal mucosa to the brain, which represents a little explored pathway of bacterial invasion but has been proposed as being particularly important in explaining how infection with Burkholderia pseudomallei can result in melioidosis encephalomyelitis.

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Section: Pathogens That Enter the Brain Through The Nose Bacteriamentioning

confidence: 99%

Pathogens Penetrating the Central Nervous System: Infection Pathways and the Cellular and Molecular Mechanisms of Invasion

et al. 2014

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“…However, while the expression of taste receptors in the sinonasal epithelium is ubiquitous on disparate cell types, including ciliated cells and solitary chemosensory cells, in the tongue taste receptor expression is confined to type II cells within the taste buds. Furthermore, while some bitter taste receptors in the airway are upstream of a nervous signaling cascade, others act in a cell-autonomous fashion only [8,19,20]. When a ligand binds to a taste GPCR, there is activation of phospholipase C isoform β2 (PLCB2), which triggers downstream inositol 1,4,5-trisphosphate (IP3) production.…”

Section: Taste Receptor Physiologymentioning

confidence: 99%

“…These cells are immunoreactive with α-gustducin, a taste signalling component, and they share many similarities with taste bud cells [28]. Because of their rarity, they are difficult to isolate experimentally [19]. Solitary chemosensory cells express both sweet and bitter taste receptors that are capable of responding to a variety of compounds [8,20,27,56,57].…”

Section: Taste Receptors On Solitary Chemosensory Cellsmentioning

confidence: 99%

“…In response to bitter stimulation, these cells do not activate NO production, but instead mediate a separate cohort of responses. In mouse SCCs, the calcium response resulting from bitter taste receptor stimulation causes acetylcholine (ACh) release that has breath holding effects and also results in downstream inflammatory mediator release [8,19,20]. Both of these responses are at least partially immunomodulatory in nature: breath holding limits toxin or organism aspiration, while inflammatory mediators often participate in a larger immune signaling cascade.…”

Section: Taste Receptors On Solitary Chemosensory Cellsmentioning

confidence: 99%

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The Role of Taste Receptors in Airway Innate Immune Defense

et al. 2018

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Bitter (T2R) and sweet (T1R) taste receptors are expressed in the upper airway, where they play key roles in antimicrobial innate immune defense. Bitter bacterial products are detected by taste receptors on ciliated cells and solitary chemosensory cells, resulting in downstream nitric oxide and antimicrobial peptide release, respectively. Genetic polymorphisms in taste receptors contribute to variations in T1R and T2R functionality, and phenotypic differences correlate with disease status and disease severity in chronic rhinosinusitis (CRS). Correspondingly, there are also subjective bitter and sweet taste differences between patients with CRS and individuals without CRS across a number of compounds. The ability to capture these differences with a simple and inexpensive taste test provides a potentially useful diagnostic tool, while bitter compounds themselves could potentially serve as therapeutic agents. The present review examines the physiology of airway taste receptors and the recent literature elucidating the role taste receptors play in rhinologic disease.

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“…Utilizing receptors and signaling cascades classically associated with the detection of bitter tastants, SCCs effectively enhance the chemosensory repertoire of the TN, facilitating its indirect activation by hydrophilic compounds that cannot readily cross epithelial layers to reach chemosensitive TN fibers. These specialized cells are present in functionally relevant areas of the respiratory epithelia of humans and rodents, where they respond to irritants and bacterial metabolites, trigger respiratory and other responses, and excite TN fibers upon activation (Saunders et al 2014;Barham et al 2013;Tizzano et al 2010;Finger et al 2003).…”

Section: Introductionmentioning

confidence: 99%

Nasal Chemesthesis: Similarities Between Humans and Rats Observed in In Vivo Experiments

Alimohammadi

Silver

2015

Chem. Percept.

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Introduction Recent advancements in the study of nasal chemesthesis have primarily been achieved through in vitro, cellular, and molecular techniques, with a resultant shift of focus away from in vivo experimental methodology. Psychophysical and electrophysiological data derived from long-standing in vivo methods form our core understanding of trigeminal chemoreception, including the functional characterization of responses to many known trigeminal stimuli, across species. Methods We selected relevant in vivo data from existing studies relating to nasal trigeminal nerve-mediated chemesthesis and performed a series of inter-species comparisons in cases where the methodological and procedural similarities between studies allowed for a productive analysis. Results There was a remarkable similarity between human and rat nasal chemesthesis in terms of comparative sensitivity to select compounds, structure-activity assessments, and mechanisms of action. Conclusions The parallels between rat and human nasal chemesthesis suggest that the rat represents an excellent model for the assessment of human trigeminal chemosensitivity. The similarities presented here are not surprising considering the primitive and adaptive nature of the chemesthetic sense.

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Cholinergic neurotransmission links solitary chemosensory cells to nasal inflammation

Cited by 179 publications

References 50 publications

Pathogens Penetrating the Central Nervous System: Infection Pathways and the Cellular and Molecular Mechanisms of Invasion

Pathogens Penetrating the Central Nervous System: Infection Pathways and the Cellular and Molecular Mechanisms of Invasion

The Role of Taste Receptors in Airway Innate Immune Defense

Nasal Chemesthesis: Similarities Between Humans and Rats Observed in In Vivo Experiments

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