Cichorium intybus root extract: A "vitamin D-like" active ingredient to improve skin barrier function.

During the aging process, the human skin suffers many alterations including dryness, skin barrier function damage. The skin barrier function is important to the prevention of skin alterations and maintenance of homeostasis. So, the objective of this study was to assess the clinical efficacy on skin barrier function of Cichorium intybus root extract in cosmetic formulations with or without UV filters. Fifty women, aged between 45 and 60 years, were divided into two groups. One group received vehicle formulations containing UV filters, and the other group received formulations without UV filters. Both groups received a formulation containing the extract and the vehicle. The formulations were applied twice daily to the upper arms after washing with sodium lauryl sulphate. Transepidermal water loss (TEWL) and skin microrelief were evaluated before and after a 14- and 28-day period of treatment. The control regions and regions where the vehicles were applied showed an increase in the TEWL. For the formulations containing the extract, decreased TEWL and improved microrelief were observed when compared to the vehicle and control areas after a 28-day period. In conclusion, Cichorium intybus root extract showed protective and restructuring effects on the skin and stands out as an innovative ingredient to improve skin barrier function.

Functional interaction between matrix metalloproteinase-3 and semaphorin-3C during cortical axonal growth and guidance.

In the developing cortex, axons and dendrites extend progressively in response to environmental cues attracting or repelling growing processes. Recent evidence suggests the existence of a functional link between guidance molecules and metalloproteinases. Here, we analyzed the putative functional interaction of matrix metalloproteinases (MMPs) with guidance cues of the semaphorin family during growth and guidance of cortical axons. Our results demonstrate that the expression pattern and the proteolytic activity of MMP-3 are consistent with a role of this particular MMP during cortical axon outgrowth. We found that MMP-3 is required for an optimal axon extension and is involved in the Sema3C-dependent chemoattraction of cortical axons by modulating both the growth capacity and the orientation of growth. Interestingly, the inhibitory Sema3A decreased both the expression and activity of MMP-3. Taken together, our results reveal a molecular interaction between MMPs and semaphorins providing new insight into the molecular mechanism allowing axonal growth cone to respond to environmental guidance cues in the context of cortical development.

[The cellular and molecular basis of axonal growth]. / Mécanismes cellulaires et moléculaires de la croissance axonale.

INTRODUCTION: During embryonic and post-natal development, numerous axonal connections are formed establishing a functional nervous system. Knowledge of the underlying molecular and cellular mechanisms controlling this phenomenon is improving. STATE OF THE ART: In this review, we present the general principles of axon guidance together with the major families of guidance signals. This includes the tyrosine kinase receptors Eph and their ligands Ephrins, the netrins, the semaphorins, the slits and other major components of the extracellular matrix. These types of guidance signals share common functional properties leading to actin cytoskeleton remodelling. The direct or indirect interactions between the receptors of these guidance cues and actin modulators is the final step of the signalling cascade constituting the fundamental mechanism defining the orientation and extension of the axonal growth cone. These factors are involved in the formation of many, if not all, axonal projections for which they act as repulsive (inhibitory) or attractive (promoting) signals. PERSPECTIVES: the knowledge of these mechanisms is particularly interesting since the inhibition of axonal outgrowth is considered to be one of the major obstacles to nerve regeneration in the central nervous system. Indeed, most of the guidance signals expressed during brain development are up-regulated in lesion sites where they contribute to the lack of nerve re-growth. Here, we present the nature of the mechanical barrier, the so called glial scar, and we describe the major inhibitory molecules preventing axonal extension. CONCLUSION: the comprehension of the molecular mechanisms involved in axon growth and guidance represents a major advance towards the definition of novel therapeutic strategies improving nerve regeneration. The path to the clinical application of these molecular factors remains long. Nevertheless, the next decade will undoubtedly provide challenging data that will modify the current therapeutic approaches.

Chronic consumption of ethanol leads to substantial cell damage in cultured rat astrocytes in conditions promoting acetaldehyde accumulation.

AIMS: This study aimed at comparing the cerebral cytotoxicity of ethanol and its main metabolite acetaldehyde after acute or chronic exposures of rat astrocytes in primary culture. METHODS: Cytotoxicity was evaluated on the cell reduction of viability (MTT reduction test) and on the characterization of DNA damage by single cell gel electrophoresis (or comet assay). RESULTS: Changes in astrocyte survival and in DNA integrity only occurred when the astrocytes were chronically exposed to ethanol (20 mM; 3, 6 or 9 days). On the other hand, viability and DNA integrity were deeply affected by acute exposure to acetaldehyde. Both effects were dependent on the concentration of acetaldehyde. The cytotoxic effect of acetaldehyde was also indirectly evaluated after modifications of the normal ethanol metabolism by the use of different inducers or inhibitors. In presence of ethanol, the concomitant induction of catalase (i.e. by glucose oxidase) and inhibition of aldehyde dehydrogenase (i.e. by methylene blue) led to acetaldehyde accumulation within cells. It was followed by both a reduction in viability and a substantial increase in DNA strand breaks. CONCLUSIONS: These data were thus consistent with a possible predominant role of acetaldehyde during brain ethanol metabolism. On the other hand, the effects observed after AMT could also suggest a possible direct ethanol effect and a role for free radical attacks. These data were thus consistent with a possible predominant role of acetaldehyde during brain ethanol metabolism. On the other hand, the effects observed after AMT could also suggest a possible direct ethanol effect and a role for free radical attacks.

New antimicrobial activity for the catecholamine release-inhibitory peptide from chromogranin A.

Catestatin (bCGA(344-364)), an endogenous peptide of bovine chromogranin A, was initially characterized for its effect on the inhibition of catecholamine release from chromaffin cells. Catestatin and its active domain (bCGA(344-358)) were identified in chromaffin cells and in secretion medium. The present study identified a potent antimicrobial activity of bCGA(344-358) in the lowmicromolar range against bacteria, fungi and yeasts, without showing any haemolytic activity. Confocal laser microscopy demonstrated penetration of the rhodaminated peptide into the cell membranes of fungi and yeasts and its intracellular accumulation. Time-lapse videomicroscopy showed arrest of fungal growth upon penetration of the labelled peptide into a fungal filament. We identified several catestatin-containing fragments in the stimulated secretion medium of human polymorphonuclear neutrophils, suggesting the N-terminal sequence of catestatin (bCGA(344-358)) (named cateslytin) as a novel component of innate immunity.

Ethanol can modify the effects of certain free radical-generating systems on astrocytes.

The central nervous system is vulnerable to oxidative stress, especially when a toxicant can modify the physiological balance between anti- and pro-oxidant mechanisms. Among brain cells, astrocytes seem less vulnerable than neurons, but their impairment can dramatically affect neurons because of their protective role toward neurons. Ethanol is able to stimulate the formation of reactive oxygen species and modify the activity of most of the antioxidant agents. However, ethanol can react with the OH* radical to form the alpha-hydroxyethyl radical, which is considered to be less toxic. Ethanol also can stimulate H2O2 degradation through catalase activation. This study, therefore, sought to determine whether ethanol affected the sensitivity of astrocytes exposed to various free radical-generating systems. The cellular impact of such exposure was assessed by assays exploring cytotoxicity (i.e., NR (neutral red) and MMT (3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetiazolium bromide) reduction assays) and genotoxicity (comet assay) induced by these treatments. DNA alterations were evaluated by single-cell gel electrophoresis (comet assay), considered a precocious biomarker of intracellular alterations. After concomitant exposure to H2O2 and ethanol, the viability of astrocytes decreased significantly whereas the mean percentage of DNA in the tail increased,reflecting DNA damage (H2O2 was either directly added to the culture medium or endogenously produced from menadione). Ethanol also reduced the loss of viability and DNA alterations after exposure to OH* radicals produced by a Fenton system. The exposure to a xanthine/xanthine oxidase system had the same effect.

Impact of ethanol and acetaldehyde on DNA and cell viability of cultured neurones.

Ethanol consumption has long been associated with brain damage. However, the mechanism underlying this deleterious effect remains unclear. Among different hypotheses, acetaldehyde is regarded by certain authors as playing a major role in the expression of ethanol toxicity, but there are still some uncertainties about the exact nature of its implication. We therefore tried to characterize the profile of the alterations of neuronal viability and DNA integrity obtained after either a direct exposure to ethanol or to acetaldehyde. Ethanol at concentrations within the range of blood alcohol levels in intoxicated humans (< or = 100 mmol/L) induced DNA alterations without any apparent effect on cell viability. Acetaldehyde (< or = 1000 micromol/L) can also induce DNA alterations but with a different profile of the DNA cellular alterations. The comparison between the distributions of the comet tail DNA indicated that ethanol induced strong breaks (tail DNA > or = 60 a.u.) generation whereas acetaldehyde rather induced lower breaks (20 < or = tail DNA < or = 50 a.u.) formation but affecting a greater number of neurones. Acetaldehyde had thus a different genotoxic potential which may suggest a different mode of action or a different cellular target. Furthermore, when a single 100 mmol/L ethanol exposure did not lead to any loss of cell viability, the addition of an inhibitor of aldehyde dehydrogenase was followed by a significant loss in viability. In contrast, the inhibition of catalase, which suppresses acetaldehyde synthesis, led to no reduced viability in the same exposure conditions. ROS also reduced viability, but this was observed only after both cytochrome P450 stimulation and catalase inhibition. These combined results could suggest that acetaldehyde may play a significant role in the expression of ethanol toxicity in brain.

Acute exposure of cultured neurones to ethanol results in reversible DNA single-strand breaks; whereas chronic exposure causes loss of cell viability.

AIMS: Ethanol can create progressive neuropathological and functional alterations of neurones. However, the influence of exposure duration is still debated. It is difficult to specify the level of alcohol consumption leading to alcohol-induced brain damage. Moreover, the mechanism of toxicity is assumed to combine direct and metabolically induced effects, although numerous uncertainties remain. Finally, the genotoxic power of ethanol has not fully been investigated in the brain. In the experiment reported herein, primary cultures of neurones were exposed either chronically or acutely to doses of ethanol within the range of blood alcohol levels in intoxicated humans. The impact on the integrity of neurones was assessed by cytotoxicity tests and DNA alterations by single-cell gel electrophoresis (Comet assay) and flow cytometry. Chronic ethanol exposure, even at a low dose, was more harmful to neurones than acute exposure. Both significant reductions in cell viability and DNA alterations were observed in this condition. On the other hand, DNA repair capacities seemed to be preserved as long as the viability measured by specific tests was not affected. Instead, neurones entered a death cell process compatible with apoptosis.

Microsomal metabolism of ciprofloxacin generates free radicals.

Ciprofloxacin (CPFX) is a widely used fluoroquinolone antibiotic with a broad spectrum of activity. However, clinical experience has shown a possible incidence of undesirable adverse effects including gastrointestinal, skin, hepatic, and central nervous system (CNS) functions, and phototoxicity. Several examples in the literature data indicate that free radical formation might play a role in the mechanism of some of these adverse effects, including phototoxicity and cartilage defects. The purpose of this study is to investigate free radical formation during the metabolism of CPFX in hepatic microsomes using electron spin resonance (ESR) spectroscopy and spin trapping technique. We then investigate the effects of a cytochrome P450 inhibitor, SKF 525A, Trolox, and ZnCl2 on CPFX-induced free radical production. Our results show that CPFX induces free radical production in a dose- and time-dependent manner. The generation of 4-POBN/radical adduct is dependent on the presence of NADPH, CPFX, and active microsomes. Furthermore, free radical production is completely inhibited by SKF 525A, Trolox, or ZnCl2.

Effects of chronic ethanol exposure on acetaldehyde and free radical production by astrocytes in culture.

In a previous study, the production of acetaldehyde and free radicals derived from ethanol was characterized in astrocytes in primary culture. In the present study, the effects of chronic exposure on the production of both compounds as well as on the main antioxidant system were compared with those of an acute exposure. This was done to better understand the different ways the brain reacts to these modes of exposure. Under these conditions, both a time-dependent increase in the accumulation of acetaldehyde and a decreased formation of the alpha-hydroxyethyl radical were shown. This was associated with increased activities of catalase, superoxide dismutase (SOD), and glutathione peroxidase (GPX) and with decreased glutathione (GSH) content. These effects, which counteract reactive oxygen species (ROS) formation by stimulating the main enzymes of the antioxidant system, were also associated with the reduced amount of radicals derived from ethanol. This could be a beneficial effect, but this was counter-balanced by the increased rate of acetaldehyde accumulation, whose high toxicity is well known. All these effects underline the crucial role played by catalase which, on one hand converts hydrogen peroxide to water and, on the other hand, ethanol to acetaldehyde.

Characterization of the production of acetaldehyde by astrocytes in culture after ethanol exposure.

The nervous system is one of the main targets of ethanol toxicity. Astrocytes might play an important role in ethanol-induced brain toxicity, because their integrity is essential for the normal growth and functioning of neurons. On the other hand, acetaldehyde has been implicated as a mediator in some of the biochemical, pharmacological, and behavioral effects of ethanol. The present study aimed at demonstrating the ability of astrocytes in culture to produce acetaldehyde from ethanol. Significant metabolization of ethanol with production of acetaldehyde was demonstrated in the primary culture of astrocytes. This production was quite low, compared with that usually observed in hepatocytes, but was in the same range as that measured in whole brain homogenates and corresponded to biologically active levels. Such a demonstration could bring new elements for understanding of ethanol neurotoxicity.

There is not simple method to maintain a constant ethanol concentration in long-term cell culture: keys to a solution applied to the survey of astrocytic ethanol absorption.

Ethanol evaporation from the culture medium is a potential source of misinterpretation of long-term exposure of cells. Different methods have been proposed to prevent this evaporation, the most effective being the saturation of the atmosphere over the culture medium with ethanol. Unfortunately, no simple predictive method has been devised to determine the appropriate concentration of ethanol in the system avoiding either evaporation or contamination of the culture medium. We present some keys to a solution adapted to the culture of astrocytes, which allow for the first time a direct evaluation of ethanol absorption by these cells. The system described remains compatible with normal growth and viability.

Free radical production after exposure of astrocytes and astrocytic C6 glioma cells to ethanol. Preliminary results.

Formation of the alpha-hydroxyethyl radical (CH3 degree CHOH) has already been extensively demonstrated after ethanol metabolism in the liver. Despite favourable conditions, this formation in the brain has remained speculative since there is no direct experimental evidence in intact brain cells. In this preliminary study, the formation of such a radical was observed after exposure of astrocytes and astrocytic C6 glioma cells to ethanol. These cells were studied because astrocyte integrity is essential for normal growth and functioning of neurons. The free radicals were detected by EPR spectroscopy using the spin trapping technique. Astrocytes appeared to be more sensitive than the C6 cells to free radical formation as the intensity of the signal was higher after exposure of the astrocytes and increased with time, a fact not observed after exposure of the C6 cells.

A morphometric evaluation of the effects of trichloroethylene and dichloroacetylene on the rat mental nerve. Preliminary results.

Morphometric analysis was used to compare the effects of trichloroethylene (Tri) and dichloroacetylene (Dca) on the fibre parameters of the trigeminal nerve. Treated animals were clearly separated from controls according to a discriminant analysis. Furthermore, in the class of nerve fibres defined by a clustering analysis and corresponding to the largest fibres, myelin thickness was significantly decreased in the Dca group, but less so in the Tri group. In the group of the smallest fibres however, the myelin thickness was significantly increased by the treatments, but especially by Tri. Such a variability in the effects of Tri has already been demonstrated. Mechanisms for this are quite unclear although demyelination could be involved as already suggested. Our results thus show the ability of Tri and Dca to alter nerve parameters but probably with different modes of action depending on the size of the fibre.

Electron spin resonance study of free radicals produced from ethanol and acetaldehyde after exposure to a Fenton system or to brain and liver microsomes.

Free radical formation from ethanol and acetaldehyde was studied in the presence of a spin-trap and a NADPH generating system with a chemical model, Fenton's reagent, or by enzymatic oxidation of these solvents by rat liver and brain microsomes. The free radicals were detected by electron spin resonance spectroscopy (E.S.R.), using the spin-trapping agent, alpha-(4-pyridyl l-oxide)-N-tertbutyl-nitrone (POBN). Under such conditions, the hydroxyethyl radical derived from ethanol was obtained after both incubation in liver and brain microsomes as well as after exposure to the Fenton system. Enzymatic inhibition and activation showed that the mixed function oxidase system plays an important role in the generation of such a radical, even in the brain. Under all the experimental conditions acetaldehyde could also generate a free radical deriving directly from the parent molecule and modified by enzymatic activation or inhibition. A second, longer lasting radical was also observed in the presence of acetaldehyde. On the basis of a comparative study to a known process causing lipoperoxidation, its lipidic origin was suggested.

In-vitro spin-trapping of free radicals produced during trichloroethylene and diethylether metabolism.

Free-radical production during the metabolism of various xenobiotics represents a frequent mechanistic explanation for their toxicity. We tested the hypothesis of production of free radicals from two solvents, diethylether and trichloroethylene (TRI), and from two metabolites of TRI, namely trichloroethanol (TCE) and trichloroacetic acid (TCA). The formation of free radicals was detected by electron spin resonance spectroscopy (ESR), using a spin-trapping agent, alpha-(4-pyridyl-1-oxide)-N-tert-butyl-nitrone (POBN). Two experimental models were used. The first was a chemical model using Fenton's reagent, a mixture of Fe(II)-chelator and H2O2, for which the normal reaction is OH. production, and the second, a preparation from rat liver and brain microsomes containing NADPH and achieving enzymatic oxidation of the solvents. After addition of diethylether, free-radical production was demonstrated under the two experimental conditions. This free radical probably derived from the parent molecule by hydrogen abstraction. TRI and TCE additions to the Fenton system suppressed normal OH. production whereas this production was increased after TCA addition. The addition of TCE to the microsomal preparations was followed by free-radical production which could derive either from the parent molecule or from other sources, e.g. from membrane degradation, with a preference for the first hypothesis because of the characteristics of the signal. This result was not observed after addition of TRI or TCA. In conclusion, these preliminary results confirm the validity of the hypothesis of production of free radicals from diethylether, but they are less consistent for TRI as this production was observed only after addition of TCE; this result is interesting, however, as TCE is considered to play a major role in the toxicity observed after TRI exposure in humans.