Post-Transcriptional Circadian Regulation in Macrophages Organizes Temporally Distinct Immunometabolic States

Collins, Emily; Cervantes-Silva, Mariana P.; Timmons, George A.; O’Siorain, James R.; Curtis, Annie M.; Hurley, Jennifer M.

doi:10.1101/2020.02.28.970715

Cited by 30 publications

(98 citation statements)

References 86 publications

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“…The rhythmic transcriptional activation on the promoters of these genes from the positive arm is believed to be the primary mechanism of output. In addition, recent work in several eukaryotic species has also shown that there is a great deal of post-transcriptional regulation, for example rhythmic proteins arising from non-rhythmic transcripts [22,[41][42][43][44][45]. This suggests that the canonical TTFL control of output has several as yet undiscovered levels of regulation.…”

Section: Circadian Output and Conserved Molecular Oscillatorsmentioning

confidence: 99%

Intrinsic disorder is an essential characteristic of components in the conserved circadian circuit

2020

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Introduction The circadian circuit, a roughly 24 h molecular feedback loop, or clock, is conserved from bacteria to animals and allows for enhanced organismal survival by facilitating the anticipation of the day/night cycle. With circadian regulation reportedly impacting as high as 80% of protein coding genes in higher eukaryotes, the protein-based circadian clock broadly regulates physiology and behavior. Due to the extensive interconnection between the clock and other cellular systems, chronic disruption of these molecular rhythms leads to a decrease in organismal fitness as well as an increase of disease rates in humans. Importantly, recent research has demonstrated that proteins comprising the circadian clock network display a significant amount of intrinsic disorder. Main body In this work, we focus on the extent of intrinsic disorder in the circadian clock and its potential mechanistic role in circadian timing. We highlight the conservation of disorder by quantifying the extent of computationally-predicted protein disorder in the core clock of the key eukaryotic circadian model organisms Drosophila melanogaster, Neurospora crassa, and Mus musculus. We further examine previously published work, as well as feature novel experimental evidence, demonstrating that the core negative arm circadian period drivers FREQUENCY (Neurospora crassa) and PERIOD-2 (PER2) (Mus musculus), possess biochemical characteristics of intrinsically disordered proteins. Finally, we discuss the potential contributions of the inherent biophysical principals of intrinsically disordered proteins that may explain the vital mechanistic roles they play in the clock to drive their broad evolutionary conservation in circadian timekeeping. Conclusion The pervasive conservation of disorder amongst the clock in the crown eukaryotes suggests that disorder is essential for optimal circadian timing from fungi to animals, providing vital homeostatic cellular maintenance and coordinating organismal physiology across phylogenetic kingdoms. Graphical abstract

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Section: Circadian Output and Conserved Molecular Oscillatorsmentioning

confidence: 99%

Intrinsic disorder is an essential characteristic of components in the conserved circadian circuit

2020

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“…Immune cell function is dependent on a 24-h circadian rhythm that is regulated by the expression of clock genes [ 10 , 11 ]. Key immune cell types, macrophages and monocytes, have a robust intrinsic circadian clock and a high expression of clock genes [ 12 ]. Molecular circadian rhythms are generated by autoregulatory transcription–translation feedback loops [ 13 ].…”

Section: Introductionmentioning

confidence: 99%

Circadian rhythms in septic shock patients

Lachmann

Ananthasubramaniam

Wünsch

et al. 2021

Ann. Intensive Care

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Background Despite the intensive efforts to improve the diagnosis and therapy of sepsis over the last decade, the mortality of septic shock remains high and causes substantial socioeconomical burden of disease. The function of immune cells is time-of-day-dependent and is regulated by several circadian clock genes. This study aims to investigate whether the rhythmicity of clock gene expression is altered in patients with septic shock. Methods This prospective pilot study was performed at the university hospital Charité–Universitätsmedizin Berlin, Department of Anesthesiology and Operative Intensive Care Medicine (CCM, CVK). We included 20 patients with septic shock between May 2014 and January 2018, from whom blood was drawn every 4 h over a 24-h period to isolate CD14-positive monocytes and to measure the expression of 17 clock and clock-associated genes. Of these patients, 3 whose samples expressed fewer than 8 clock genes were excluded from the final analysis. A rhythmicity score SP was calculated, which comprises values between -1 (arrhythmic) and 1 (rhythmic), and expression data were compared to data of a healthy study population additionally. Results 77% of the measured clock genes showed inconclusive rhythms, i.e., neither rhythmic nor arrhythmic. The clock genes NR1D1, NR1D2 and CRY2 were the most rhythmic, while CLOCK and ARNTL were the least rhythmic. Overall, the rhythmicity scores for septic shock patients were significantly (p < 0.0001) lower (0.23 ± 0.26) compared to the control group (12 healthy young men, 0.70 ± 0.18). In addition, the expression of clock genes CRY1, NR1D1, NR1D2, DBP, and PER2 was suppressed in septic shock patients and CRY2 was significantly upregulated compared to controls. Conclusion Molecular rhythms in immune cells of septic shock patients were substantially altered and decreased compared to healthy young men. The decrease in rhythmicity was clock gene-dependent. The loss of rhythmicity and down-regulation of clock gene expression might be caused by sepsis and might further deteriorate immune responses and organ injury, but further studies are necessary to understand underlying pathophysiological mechanisms. Trail registration Clinical trial registered with www.ClinicalTrials.gov (NCT02044575) on 24 January 2014.

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“…the cell cycle. As multi-omics circadian data becomes more prevalent (Collins et al, 2020;Campbell et al, 2020;Hughes et al, 2017), MOSAIC will provide an important role in finding and understanding both oscillatory and non-oscillatory trends in a variety of organisms and processes.…”

Section: Discussionmentioning

confidence: 99%

“…Hurley et al (2018), that rhythmic RNA expression does not necessarily imply rhythmic protein expression and vice versa (Hurley et al, 2018), These data suggest that there may be extensive post-transcriptional regulation in the clock's output and beyond. The exact mechanisms of this regulation are currently unknown, though translation and degradation are predicted to be involved (Hurley et al, 2018;Lück et al, 2014;Collins et al, 2020).…”

Section: Introductionmentioning

confidence: 99%

MOSAIC: a joint modeling methodology for combined circadian and non-circadian analysis of multi-omics data

2020

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Motivation Circadian rhythms are approximately 24 hour endogenous cycles that control many biological functions. To identify these rhythms, biological samples are taken over circadian time and analyzed using a single omics type, such as transcriptomics or proteomics. By comparing data from these single omics approaches, it has been shown that transcriptional rhythms are not necessarily conserved at the protein level, implying extensive circadian post-transcriptional regulation. However, as proteomics methods are known to be noisier than transcriptomic methods, this suggests that previously identified arrhythmic proteins with rhythmic transcripts could have been missed due to noise and may not be due to post-transcriptional regulation. Results To determine if one can use information from less-noisy transcriptomic data to inform rhythms in more-noisy proteomic data, and thus more accurately identify rhythms in the proteome, we have created the MOSAIC (Multi-Omics Selection with Amplitude Independent Criteria) application. MOSAIC combines model selection and joint modeling of multiple omics types to recover significant circadian and non-circadian trends. Using both synthetic data and proteomic data from Neurospora crassa, we showed that MOSAIC accurately recovers circadian rhythms at higher rates in not only the proteome but the transcriptome as well, outperforming existing methods for rhythm identification. In addition, by quantifying non-circadian trends in addition to circadian trends in data, our methodology allowed for the recognition of the diversity of circadian regulation as compared to non-circadian regulation. Availability MOSAIC’s full interface is available at https://github.com/delosh653/MOSAIC. An R package for this functionality, mosaic.find, can be downloaded at https://CRAN.R-project.org/package=mosaic.find. Supplementary information Supplementary data are available at Bioinformatics online.

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Post-Transcriptional Circadian Regulation in Macrophages Organizes Temporally Distinct Immunometabolic States

Cited by 30 publications

References 86 publications

Intrinsic disorder is an essential characteristic of components in the conserved circadian circuit

Intrinsic disorder is an essential characteristic of components in the conserved circadian circuit

Circadian rhythms in septic shock patients

MOSAIC: a joint modeling methodology for combined circadian and non-circadian analysis of multi-omics data

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