A circadian clock in macrophages controls inflammatory immune responses
Time of day-dependent variations of immune system parameters are ubiquitous phenomena in immunology. The circadian clock has been attributed with coordinating these variations on multiple levels; however, their molecular basis is little understood. Here, we systematically investigated the link between the circadian clock and rhythmic immune functions. We show that spleen, lymph nodes, and peritoneal macrophages of mice contain intrinsic circadian clockworks that operate autonomously even ex vivo. These clocks regulate circadian rhythms in inflammatory innate immune functions: Isolated spleen cells stimulated with bacterial endotoxin at different circadian times display circadian rhythms in TNF-␣ and IL-6 secretion. Interestingly, we found that these rhythms are not driven by systemic glucocorticoid variations nor are they due to the detected circadian fluctuation in the cellular constitution of the spleen. Rather, a local circadian clock operative in splenic macrophages likely governs these oscillations as indicated by endotoxin stimulation experiments in rhythmic primary cell cultures. On the molecular level, we show that >8% of the macrophage transcriptome oscillates in a circadian fashion, including many important regulators for pathogen recognition and cytokine secretion. As such, understanding the cross-talk between the circadian clock and the immune system provides insights into the timing mechanism of physiological and pathophysiological immune functions.adrenalectomy ͉ LPS ͉ IL-6 ͉ microarray ͉ TNF-␣ A 24-h periodicity in the environment has led to the evolution of molecular circadian clocks in organisms ranging from cyanobacteria to humans. Circadian rhythms display a near 24-h period and persist even in the absence of external timing information. In mammals, a small hypothalamic region, the suprachiasmatic nucleus (SCN), has been identified as the master pacemaker regulating circadian rhythms in physiology, metabolism, and behavior (1). Recent evidence shows that also peripheral organs such as liver, heart, kidney, skin, and even cultured cell lines contain circadian oscillators. Although the SCN probably sets the phase of these peripheral clocks (by as yet unknown means), recent reports implicate peripheral clocks in the regulation of local physiology (2-4). The fundamental mechanism of rhythm generation is cell autonomous and highly conserved in SCN and peripheral cells: Interlocked transcriptional/translational feedback loops involving clock genes, such as Per1-3, Cry1-2, Clock, Bmal1, and Rev-Erb␣ create oscillations on the molecular level (reviewed in ref. 2).In the immune system, many functions and parameters have been described to be time-of-day dependent, e.g., lymphocyte proliferation (5), natural killer (NK) cell activity (6), humoral immune response (7), rhythms in absolute and relative numbers of circulating white blood cells and their subsets (8), cytokine levels (9), and serum cortisol (10) (reviewed in ref. 11). In addition, time-of-day variation in susceptibility to infection (12), cour...
In a screen for potential mediators of brassinosteroid (BR) e¡ects, the EXORDIUM (EXO) protein was identi¢ed as a regulator of BR-responsive genes. The EXO gene was characterized as a BR-up-regulated gene. EXO overexpression under the control of the 35SCaMV promoter resulted in increased transcript levels of the BR-up-regulated KCS1, Exp5, N N-TIP, and AGP4 genes, which likely are involved in the mediation of BR-promoted growth. 35S: :EXO lines grown in soil or in synthetic medium showed increased vegetative growth in comparison to wild-type plants, resembling the growth phenotype of BRtreated plants. Thus, the EXO protein most likely promotes growth via the modulation of gene expression patterns.
Asr genes are exclusively found in the genomes of higher plants. In many species, this gene family is expressed under abiotic stress conditions and during fruit ripening. The encoded proteins have nuclear localisation and consequently a transcription factor function has been suggested. Interestingly, yeast-one-hybrid experiments revealed that a grape ASR binds to the promoter of a hexose transporter gene (VvHT1). However, the role of these proteins in planta is still elusive. By using a reverse genetics approach in potato we found that modification of Asr1 expression has no incidence on the aerial phenotype of the plant but exerts a dramatic effect in tuber. Asr1 antisense potatoes displayed decreased tuber fresh weight whereas Asr1 overexpressors had a diminished number of tubers. Moreover, overexpression lines showed lower transcript levels of a plasma membrane hexose transporter and a concomitant decrease in glucose content in parenchyma cells of potato tubers. On the same hand glucose uptake rate was also reduced in one of the overexpressing lines. It thus seems likely that Asr1 is involved in the control of hexose uptake in heterotrophic organs. In addition, the transgenic plants were characterized by several other changes in steady state metabolite levels. Results presented here support a role for ci21A/Asr1 in glucose metabolism of potato tuber.
Asr (for ABA, stress, ripening) genes are exclusively found in the genomes of higher plants, and the encoded proteins have been found localized both to the nucleus and cytoplasm. However, before the mechanisms underlying the activity of ASR proteins can be determined, the role of these proteins in planta should be deciphered. Results from this study suggest that ASR is positioned within the signaling cascade of interactions among glucose, abscisic acid, and gibberellins. Tobacco (Nicotiana tabacum) transgenic lines with reduced levels of ASR protein showed impaired glucose metabolism and altered abscisic acid and gibberellin levels. These changes were associated with dwarfism, reduced carbon dioxide assimilation, and accelerated leaf senescence as a consequence of a fine regulation exerted by ASR to the glucose metabolism. This regulation resulted in an impact on glucose signaling mediated by Hexokinase1 and Snf1-related kinase, which would subsequently have been responsible for photosynthesis, leaf senescence, and hormone level alterations. It thus can be postulated that ASR is not only involved in the control of hexose uptake in heterotrophic organs, as we have previously reported, but also in the control of carbon fixation by the leaves mediated by a similar mechanism.
The mammalian circadian clock and the cell cycle are two major biological oscillators whose coupling influences cell fate decisions. In the present study, we use a model-driven experimental approach to investigate the interplay between clock and cell cycle components and the dysregulatory effects of RAS on this coupled system. In particular, we focus on the Ink4a/Arf locus as one of the bridging clock-cell cycle elements. Upon perturbations by the rat sarcoma viral oncogene (RAS), differential effects on the circadian phenotype were observed in wild-type and Ink4a/Arf knock-out mouse embryonic fibroblasts (MEFs), which could be reproduced by our modelling simulations and correlated with opposing cell cycle fate decisions. Interestingly, the observed changes can be attributed to in silico phase shifts in the expression of core-clock elements. A genome-wide analysis revealed a set of differentially expressed genes that form an intricate network with the circadian system with enriched pathways involved in opposing cell cycle phenotypes. In addition, a machine learning approach complemented by cell cycle analysis classified the observed cell cycle fate decisions as dependent on Ink4a/Arf and the oncogene RAS and highlighted a putative fine-tuning role of Bmal1 as an elicitor of such processes, ultimately resulting in increased cell proliferation in the Ink4a/Arf knock-out scenario. This indicates that the dysregulation of the core-clock might work as an enhancer of RAS-mediated regulation of the cell cycle. Our combined in silico and in vitro approach highlights the important role of the circadian clock as an Ink4a/Arf-dependent modulator of oncogene-induced cell fate decisions, reinforcing its function as a tumour-suppressor and the close interplay between the clock and the cell cycle network.
Our results suggest that the modulation of the dietary fat and carbohydrate content alters the function of the central and peripheral circadian clocks in humans.
Background The circadian variation of clinical symptoms and the underlying variation of cytokine and hormone levels in rheumatoid arthritis (RA) are well described and have already led to the successful application of chronotherapy with prednisone (Buttgereit et al., Lancet, 2008). Much less is known about the circadian rhythms of different immune cell populations in RA. Objectives In this pilot study we investigated molecular, cellular and humoral circadian parameters in postmenopausal female RA patients in comparison to healthy control subjects. Methods Blood samples from postmenopausal female patients with active RA (DAS 28 ≥4.2) (n=5) and postmenopausal female healthy controls (n=5) were collected every 2 hours for 24 hours and analysed by flow cytometry and multiplex suspension array of 28 cytokines. Clock gene expression of isolated CD14+ monocytes was analysed by quantitative RT-PCR. Endogenous circadian rhythm dynamics of macrophages were determined by means of a Bmal1-promotor driven luciferase reporter construct. COSINOR analysis was used for statistical analysis of the groups. Results Expression of the clock gene RevErbα in CD14+ monocytes showed a significant circadian expression pattern in both RA patients and healthy controls subjects, whereas the clock genes Per2 and Per3 were not expressed in a circadian manner in RA patients but in healthy controls only. The amplitude of the endogenous circadian rhythm of macrophages tended to be lower in RA patients than in healthy controls, whereas period length was not altered. In flow cytometric analysis of surface marker expression of blood cells we found a significant circadian rhythm in RA patients and healthy subjects for the frequency of CD3-CD56+ natural killer (NK) cells, Interleukin-8 Receptor (IL-8R) expressing CD4+ T helper and CD8+ cytotoxic T cells, and CXCR4 expressing CD4+ T helper and CD8+ cytotoxic cells. A significant circadian rhythm was not detectable in RA patients but in healthy controls only for CD3+CD56+ NK T cells. In contrast, a significant circadian expression of IL-8R+ monocytes was found in RA patients only but not in healthy subjects. Of note, CCR7 did not at all show a circadian expression. A significant circadian cytokine expression was detected only for MCP-1 in healthy controls. Conclusions This is the first indication of alterations of clock gene expression and endogenous circadian rhythms in immune cells of RA patients. Traffic of peripheral blood cells shows circadian variation in RA patients and healthy controls with characteristic peak phases, especially in NK cells and chemokine receptor expressing cells. NKT and other cells may lose their normal circadian rhythm in RA, whereas IL-8R expression on monocytes may be established as new “inflammatory” circadian rhythm in RA patients. These findings provide new aspects of RA chronobiology and may have therapeutic implications. Disclosure of Interest C. Spies: None Declared, T. Gaber: None Declared, P. Hoff: None Declared, J. Mazuch: None Declared, B. Maier: None Declared,...
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