Abstract
BackgroundThough it is well-known that a high-salt diet (HSD) is associated with many chronic diseases, the effects of long-term high-salt intake on physiological functions and homeostasis remain elusive. In this study, we investigated whether and how an HSD affects mouse nociceptive thresholds, and myeloid cell trafficking and activation.MethodsHealthy C57BL/6 male and female mice were fed an HSD (containing 4% NaCl in chow and 1% NaCl in water) from the time of weaning for 3 to 4 months. Circulating monocytes, nerve macrophages, spinal microglia, and associated inflammatory responses were scrutinized using flow cytometry, immunohistochemistry, and quantitative real-time polymerase chain reaction (qPCR) approaches. Mouse pain sensitivity to mechanical stimuli was monitored with von Frey tests along the experimental duration.ResultsMice on an HSD have reduced mechanical thresholds. They feel more pain than those on a normal diet (ND), e.g., regular laboratory chow (0.3% NaCl in chow). An HSD induced not only a remarkable expansion of circulating monocytes, CCR2+Ly6Chi inflammatory monocytes in particular, but also an accumulation of CD11b+F4/80+ macrophages in the peripheral nerves and an activation of Iba-1+ spinal microglia. Replacing an HSD with a ND was unable to reverse the HSD-induced mechanical hypersensitivity or rescue the altered immune responses. However, treating HSD-fed mice with a chemokine receptor CCR2 antagonist effectively normalized the pain thresholds and immune cell profile in the periphery and spinal cord. An HSD failed to alter pain thresholds and myeloid cell activation in CCR2-deficient mice. Spinal microglial activation is required for HSD-induced mechanical hypersensitivity in male, but not in female mice.ConclusionOverall, this study provides evidence that an HSD has a long-term impact on physiological function. CCR2-mediated cellular response, including myeloid cell trafficking and associated inflammation, plays pivotal roles in salt-dietary modulation of pain sensitivity.
Highlights
Though it is well-known that a high-salt diet (HSD) is associated with many chronic diseases, the effects of long-term high-salt intake on physiological functions and homeostasis remain elusive
While an increase in salt-enriched “fast food” consumption has been considered a putative factor for many pathological conditions, there is no data available to delineate whether a long-term high-salt diet (HSD) may disturb pain sensitivity
An HSD induces long-lasting mechanical hypersensitivity in mice, which is not made reversible by returning to a normal diet To mimic the circumstances in certain regions of the world wherein people grow up with a higher-thanaverage salt intake [19], we began feeding mice an HSD directly after weaning, at the age of 3 weeks
Summary
Though it is well-known that a high-salt diet (HSD) is associated with many chronic diseases, the effects of long-term high-salt intake on physiological functions and homeostasis remain elusive. Sodium plays a vital role in the regulation of many physiological functions, including blood volume maintenance, water balance, cell membrane potential, acidbase balance, and nerve conduction. While an increase in salt-enriched “fast food” consumption has been considered a putative factor for many pathological conditions, there is no (animal or human) data available to delineate whether a long-term high-salt diet (HSD) may disturb pain sensitivity. The ability to sense pain is one of the prerequisites for survival. Thresholds to painful stimuli may vary among individuals, often attributed to genetic variances, but it is interesting to examine whether a subject’s environment, lifestyle, or diet impacts their ability to sense pain
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