Human Intestinal Circadian Clock: Expression of Clock Genes in Colonocytes Lining the Crypt
Biological clock components have been detected in many epithelial tissues of the digestive tract of mammals (oral mucosa, pancreas, and liver), suggesting the existence of peripheral circadian clocks that may be entrainable by food. Our aim was to investigate the expression of main peripheral clock genes in colonocytes of healthy humans and in human colon carcinoma cell lines. The presence of clock components was investigated in single intact colonic crypts isolated by chelation from the biopsies of 25 patients (free of any sign of colonic lesions) undergoing routine colonoscopy and in cell lines of human colon carcinoma (Caco2 and HT29 clone 19A). Per-1, per-2, and clock mRNA were detected by real-time RT-PCR. The three-dimensional distributions of PER-1, PER-2, CLOCK, and BMAL1 proteins were recorded along colonic crypts by immunofluorescent confocal imaging. We demonstrate the presence of per-1, per-2, and clock mRNA in samples prepared from colonic crypts of 5 patients and in all cell lines. We also demonstrate the presence of two circadian clock proteins, PER-1 and CLOCK, in human colonocytes on crypts isolated from 20 patients (15 patients for PER-1 and 6 for CLOCK) and in colon carcinoma cells. Establishing the presence of clock proteins in human colonic crypts is the first step toward the study of the regulation of the intestinal circadian clock by nutrients and feeding rhythms.
Robust incremental compensation of the light attenuation with depth in 3D fluorescence microscopy
SummaryFluorescent signal intensities from confocal laser scanning microscopes (CLSM) suffer from several distortions inherent to the method. Namely, layers which lie deeper within the specimen are relatively dark due to absorption and scattering of both excitation and fluorescent light, photobleaching and/ or other factors. Because of these effects, a quantitative analysis of images is not always possible without correction. Under certain assumptions, the decay of intensities can be estimated and used for a partial depth intensity correction. In this paper we propose an original robust incremental method for compensating the attenuation of intensity signals. Most previous correction methods are more or less empirical and based on fitting a decreasing parametric function to the section mean intensity curve computed by summing all pixel values in each section. The fitted curve is then used for the calculation of correction factors for each section and a new compensated sections series is computed. However, these methods do not perfectly correct the images. Hence, the algorithm we propose for the automatic correction of intensities relies on robust estimation, which automatically ignores pixels where measurements deviate from the decay model. It is based on techniques adopted from the computer vision literature for image motion estimation. The resulting algorithm is used to correct volumes acquired in CLSM. An implementation of such a restoration filter is discussed and examples of successful restorations are given.
-The mammalian genome encodes at least a dozen of genes directly involved in the regulation of the feedback loops constituting the circadian clock. The circadian system is built up on a multitude of oscillators organized according to a hierarchical model in which neurons of the suprachiasmatic nuclei of the hypothalamus may drive the central circadian clock and all the other somatic cells may possess the molecular components allowing tissues and organs to constitute peripheral clocks. Suprachiasmatic neurons are driving the central circadian clock which is reset by lighting cues captured and integrated by the melanopsin cells of the retina and define the daily rhythms of locomotor activity and associated physiological regulatory pathways like feeding and metabolism. This central clock entrains peripheral clocks which can be synchronized by non-photic environmental cues and uncoupled from the central one depending on the nature and the strength of the circadian signal. The human circadian clock and its functioning in central or peripheral tissues are currently being explored to increase the therapeutic efficacy of timed administration of drugs or radiation, and to offer better advice on lighting and meal timing useful for frequent travelers suffering from jet lag and for night workers' comfort. However, the molecular mechanism driving and coordinating the central and peripheral clocks through a wide range of synchronizers (lighting, feeding, physical or social activities) remains a mystery. mammals / human / circadian rhythms / nutrients Abbreviations: SCN: suprachiasmatic nuclei, HNF: hepatocyte nuclear factor, TGF-alpha: transforming-growth-factor alpha, NAD(H), NADP(H): nicotinamide adenine dinucleotide (phosphate), NO: nitric oxide.Convention: For a better understanding, genes are written in italics, proteins in capitals.
The clock genes family is expressed by all the somatic cells driving central and peripheral circadian rhythms through transcription/translation feedback loops. The circadian clock provides a local time for a cell and a way to integrate the normal environmental changes to smoothly adapt the cellular machinery to new conditions. The central circadian rhythm is retained in primary cultures by neurons of the suprachiasmatic nuclei. The peripheral circadian rhythms of the other somatic cells are progressively dampened down up to loss unless neuronal signals of the central clock are provided for re-entrainment. Under typical culture conditions (obscurity, 37 +/- 1 degrees C, 5-7% CO(2)), freshly explanted peripheral cells harbor chaotic expression of clock genes for 12-14 h and loose, coordinated oscillating patterns of clock components. Cells of normal or cancerous phenotypes established in culture harbor low levels of clock genes idling up to the re-occurrence of new synchronizer signals. Synchronizers are physicochemical cues (like thermic oscillations, short-term exposure to high concentrations of serum or single medium exchange) able to re-induce molecular oscillations of clock genes. The environmental synchronizers are integrated by response elements located in the promoter region of period genes that drive the central oscillator complex (CLOCK:BMAL1 and NPAS2:BMAL1 heterodimers). Only a few cell lines from different species and lineages have been tested for the existence or the functioning of a circadian clockwork. The best characterized cell lines are the immortalized SCN2.2 neurons of rat suprachiasmatic nuclei for the central clock and the Rat-1 fibroblasts or the NIH/3T3 cells for peripheral clocks. Isolation methods of fragile cell phenotypes may benefit from research on the biological clocks to design improved tissue culture media and new bioassays to diagnose pernicious consequences for health of circadian rhythm alterations.
The clock genes family is expressed by all the somatic cells driving central and peripheral circadian rhythms through transcription/translation feedback loops. The circadian clock provides a local time for a cell and a way to integrate the normal environmental changes to smoothly adapt the cellular machinery to new conditions. The central circadian rhythm is retained in primary cultures by neurons of the suprachiasmatic nuclei. The peripheral circadian rhythms of the other somatic cells are progressively dampened down up to loss unless neuronal signals of the central clock are provided for re-entrainment. Under typical culture conditions (obscurity, 37 +/- 1 degrees C, 5-7% CO(2)), freshly explanted peripheral cells harbor chaotic expression of clock genes for 12-14 h and loose, coordinated oscillating patterns of clock components. Cells of normal or cancerous phenotypes established in culture harbor low levels of clock genes idling up to the re-occurrence of new synchronizer signals. Synchronizers are physicochemical cues (like thermic oscillations, short-term exposure to high concentrations of serum or single medium exchange) able to re-induce molecular oscillations of clock genes. The environmental synchronizers are integrated by response elements located in the promoter region of period genes that drive the central oscillator complex (CLOCK:BMAL1 and NPAS2:BMAL1 heterodimers). Only a few cell lines from different species and lineages have been tested for the existence or the functioning of a circadian clockwork. The best characterized cell lines are the immortalized SCN2.2 neurons of rat suprachiasmatic nuclei for the central clock and the Rat-1 fibroblasts or the NIH/3T3 cells for peripheral clocks. Isolation methods of fragile cell phenotypes may benefit from research on the biological clocks to design improved tissue culture media and new bioassays to diagnose pernicious consequences for health of circadian rhythm alterations.
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