Activators of liver X receptors (LXR) stimulate epidermal differentiation and development, but inhibit keratinocyte proliferation. In this study, the anti-inflammatory effects of two oxysterols, 22(R)-hydroxy-cholesterol (22ROH) and 25-hydroxycholesterol (25OH), and a nonsterol activator of LXR, GW3965, were examined utilizing models of irritant and allergic contact dermatitis. Irritant dermatitis was induced by applying phorbol 12-myristate-13-acetate (TPA) to the surface of the ears of CD1 mice, followed by treatment with 22ROH, 25OH, GW3965, or vehicle alone. Whereas TPA treatment alone induced an approximately 2-fold increase in ear weight and thickness, 22ROH, 25OH, or GW3965 markedly suppressed the increase (greater than 50% decrease), and to an extent comparable to that observed with 0.05% clobetasol treatment. Histology also revealed a marked decrease in TPA-induced cutaneous inflammation in oxysterol-treated animals. As topical treatment with cholesterol did not reduce the TPA-induced inflammation, and the nonsterol LXR activator (GW3965) inhibited inflammation, the anti-inflammatory effects of oxysterols cannot be ascribed to a nonspecific sterol effect. In addition, 22ROH did not reduce inflammation in LXRbeta-/- or LXRalphabeta-/- animals, indicating that LXRbeta is required for this anti-inflammatory effect. 22ROH also caused a partial reduction in ear thickness in LXRalpha-/- animals, however (approximately 50% of that observed in wild-type mice), suggesting that this receptor also mediates the anti-inflammatory effects of oxysterols. Both ear thickness and weight increased (approximately 1.5-fold) in the oxazolone-induced allergic dermatitis model, and 22ROH and GW3965 reduced inflammation by approximately 50% and approximately 30%, respectively. Finally, immunohistochemistry demonstrated an inhibition in the production of the pro-inflammatory cytokines interleukin-1alpha and tumor necrosis factor alpha in the oxysterol-treated sites from both TPA- and oxazolone-treated animals. These studies demonstrate that activators of LXR display potent anti-inflammatory activity in both irritant and allergic contact models of dermatitis, requiring the participation of both LXRalpha and LXRbeta. LXR activators could provide a new class of therapeutic agents for the treatment of cutaneous inflammatory disorders.
The relationship between the in vivo irritation potential of sodium lauryl sulfate (SLS) and linear alkyl benzene sulfonate (LAS) and the ability of these two surfactants to remove lipid from the stratum corneum (SC) in vitro were investigated. Either surfactant removes detectable levels of lipids only above its critical micelle concentration (CMC). At high concentrations the surfactants removed only very small amounts of cholesterol, free fatty acid the esters of those materials, and possibly squalene. SLS and LAS have been shown, below the CMC, to bind to and irritate the SC. Thus, clinical irritation provoked by SLS or LAS is unlikely to be directly linked with extraction of SC lipid. The milder forms of irritation – dry ness tightness roughness – may involve both surfactant binding to and denaturation of keratin as well as disruption of lipid. Our findings challenge earlier assumptions that surfactants’ degreasing of the SC is involved in the induction of erythema.
Exposure of the skin to surfactant-based products can result in irritation. To control this effect researchers are probing mechanisms of surfactant action. In vitro studies show that mixing surfactants often results in less denaturation (swelling) of stratum corneum. We have explored the in vivo human irritation response (using a 21-day cumulative irritation test) to two of these surfactants – sodium lauryl sulfate (SLS) and (C12–C14) alkyl, 7-ethoxy sulfate (AEOS-7EO). Results demonstrate that addition of AEOS-7EO to a constant dose of SLS results in a significant reduction in erythema, hence producing a milder system. The reason for the synergism is unclear, but may relate to experimentally determined alterations in the micellar solution properties of the SLS upon addition of AEOS-7EO.
The role of cilia in recognition of olfactory stimuli has been controversial. Cilia from the intact olfactory rosettes of the rainbow trout Salmo gairdneri were isolated, characterized biochemically, and examined by electron microscopy. The markers studied are those associated with cilia in other organisms. Dynein arms contain Mg2+-ATPase; this enzyme was enriched in the isolated cilia preparation. Guanine nucleotides are associated with the outer microtubule doublets of cilia but adenine nucleotides are not; a substantial enrichment in guanine, relative to adenine, was found in the cilia preparation. Tubulin, the structural protein component of microtubules, occurs in large amounts in cilia. Disc gel electrophoresis indicated tubulin in the cilia preparation. Electron microscopy confirmed the presence of cilia in the isolated preparation. Rainbow trout have an acute sense of smell and many amino acids are odorants to this species. Functional activity of the cilia preparation relevant to odorant recognition was assessed by using binding of radioactively labeled odorant amino acids. L-Alanine, Lserine, L-threonine, L-lysine, and Dalanine bound to the cilia preparation. This study provides direct biochemical evidence that olfactory cilia bind odorant molecules and supports the hypothesis that odorant recognition sites are integral parts of the cilia. The biochemical basis of odorant recognition is beginning to be understood. The numerous hypotheses proposed to explain odor specificity (1) are generally based upon structure-activity correlations made either psychologically in human subjects or electrophysiologically in various animal species. The rainbow trout Salmo gairdneri, which has a functional olfactory system, provides a suitable biochemical model for studying the specificity of odorant interactions with receptor sites. Their olfactory receptors are sensitive to amino acids as stimuli (2, 3). Amino acids bind specifically to a sedimentable fraction isolated from rainbow trout olfactory tissue (4). The extent of binding corresponds to the stimulatory effectiveness recorded electrophysiologically (3) from the olfactory bulb of the brain.The hypothesis that olfactory cilia are the loci of olfactory receptor sites had been postulated for many years (5, 6) but has remained controversial. A widely cited preliminary report (7) described results suggesting that removal of cilia, by use of detergents, from turtle olfactory epithelium resulted in a preparation that continued to be electrophysiologically active.Earlier experiments by Shibuya (8) wete unclear regarding involvement of cilia, but recent results described by Bronshtein and Minor (9) support the hypothesis. They showed that, following removal of frog olfactory cilia with detergent, the electroolfactogram responses to chemical stimulation declined. Upon regeneration of cilia, observed by electron microscopy, the responses reappeared.tThe publication costs of this article were defrayed in part by page charge payment. This article must therfore be here...
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