A pilot characterization of the human chronobiome

Carsten Skarke; Nicholas F. Lahens; Seth D. Rhoades; Amy Campbell; Kyle Bittinger; Aubrey Bailey; Christian Hoffmann; Randal S. Olson; Lihong Chen; Guangrui Yang; Thomas S. Price; Jason H. Moore; Frederic D. Bushman; Casey S. Greene; Gregory R. Grant; Aalim M. Weljie; Garret A. Fitzgerald

doi:10.1038/s41598-017-17362-6

A pilot characterization of the human chronobiome

Carsten Skarke^*
, Nicholas F. Lahens
, Seth D. Rhoades
, Amy Campbell
, Kyle Bittinger
, Aubrey Bailey
, Christian Hoffmann
, Randal S. Olson
, Lihong Chen
, Guangrui Yang
, Thomas S. Price
, Jason H. Moore
, Frederic D. Bushman
, Casey S. Greene
, Gregory R. Grant
, Aalim M. Weljie
, Garret A. Fitzgerald

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

67 Scopus citations

Abstract

Physiological function, disease expression and drug effects vary by time-of-day. Clock disruption in mice results in cardio-metabolic, immunological and neurological dysfunction; circadian misalignment using forced desynchrony increases cardiovascular risk factors in humans. Here we integrated data from remote sensors, physiological and multi-omics analyses to assess the feasibility of detecting time dependent signals - the chronobiome - despite the "noise" attributable to the behavioral differences of free-living human volunteers. The majority (62%) of sensor readouts showed time-specific variability including the expected variation in blood pressure, heart rate, and cortisol. While variance in the multi-omics is dominated by inter-individual differences, temporal patterns are evident in the metabolome (5.4% in plasma, 5.6% in saliva) and in several genera of the oral microbiome. This demonstrates, despite a small sample size and limited sampling, the feasibility of characterizing at scale the human chronobiome "in the wild". Such reference data at scale are a prerequisite to detect and mechanistically interpret discordant data derived from patients with temporal patterns of disease expression, to develop time-specific therapeutic strategies and to refine existing treatments.

Original language	English
Article number	17141
Journal	Scientific Reports
Volume	7
Issue number	1
DOIs	https://doi.org/10.1038/s41598-017-17362-6
State	Published - 1 Dec 2017
Externally published	Yes

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10.1038/s41598-017-17362-6

Cite this

Skarke, C., Lahens, N. F., Rhoades, S. D., Campbell, A., Bittinger, K., Bailey, A., Hoffmann, C., Olson, R. S., Chen, L., Yang, G., Price, T. S., Moore, J. H., Bushman, F. D., Greene, C. S., Grant, G. R., Weljie, A. M., & Fitzgerald, G. A. (2017). A pilot characterization of the human chronobiome. Scientific Reports, 7(1), Article 17141. https://doi.org/10.1038/s41598-017-17362-6

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abstract = "Physiological function, disease expression and drug effects vary by time-of-day. Clock disruption in mice results in cardio-metabolic, immunological and neurological dysfunction; circadian misalignment using forced desynchrony increases cardiovascular risk factors in humans. Here we integrated data from remote sensors, physiological and multi-omics analyses to assess the feasibility of detecting time dependent signals - the chronobiome - despite the {"}noise{"} attributable to the behavioral differences of free-living human volunteers. The majority (62\%) of sensor readouts showed time-specific variability including the expected variation in blood pressure, heart rate, and cortisol. While variance in the multi-omics is dominated by inter-individual differences, temporal patterns are evident in the metabolome (5.4\% in plasma, 5.6\% in saliva) and in several genera of the oral microbiome. This demonstrates, despite a small sample size and limited sampling, the feasibility of characterizing at scale the human chronobiome {"}in the wild{"}. Such reference data at scale are a prerequisite to detect and mechanistically interpret discordant data derived from patients with temporal patterns of disease expression, to develop time-specific therapeutic strategies and to refine existing treatments.",

author = "Carsten Skarke and Lahens, \{Nicholas F.\} and Rhoades, \{Seth D.\} and Amy Campbell and Kyle Bittinger and Aubrey Bailey and Christian Hoffmann and Olson, \{Randal S.\} and Lihong Chen and Guangrui Yang and Price, \{Thomas S.\} and Moore, \{Jason H.\} and Bushman, \{Frederic D.\} and Greene, \{Casey S.\} and Grant, \{Gregory R.\} and Weljie, \{Aalim M.\} and Fitzgerald, \{Garret A.\}",

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AU - Skarke, Carsten

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AU - Bailey, Aubrey

AU - Hoffmann, Christian

AU - Olson, Randal S.

AU - Chen, Lihong

AU - Yang, Guangrui

AU - Price, Thomas S.

AU - Moore, Jason H.

AU - Bushman, Frederic D.

AU - Greene, Casey S.

AU - Grant, Gregory R.

AU - Weljie, Aalim M.

AU - Fitzgerald, Garret A.

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N2 - Physiological function, disease expression and drug effects vary by time-of-day. Clock disruption in mice results in cardio-metabolic, immunological and neurological dysfunction; circadian misalignment using forced desynchrony increases cardiovascular risk factors in humans. Here we integrated data from remote sensors, physiological and multi-omics analyses to assess the feasibility of detecting time dependent signals - the chronobiome - despite the "noise" attributable to the behavioral differences of free-living human volunteers. The majority (62%) of sensor readouts showed time-specific variability including the expected variation in blood pressure, heart rate, and cortisol. While variance in the multi-omics is dominated by inter-individual differences, temporal patterns are evident in the metabolome (5.4% in plasma, 5.6% in saliva) and in several genera of the oral microbiome. This demonstrates, despite a small sample size and limited sampling, the feasibility of characterizing at scale the human chronobiome "in the wild". Such reference data at scale are a prerequisite to detect and mechanistically interpret discordant data derived from patients with temporal patterns of disease expression, to develop time-specific therapeutic strategies and to refine existing treatments.

AB - Physiological function, disease expression and drug effects vary by time-of-day. Clock disruption in mice results in cardio-metabolic, immunological and neurological dysfunction; circadian misalignment using forced desynchrony increases cardiovascular risk factors in humans. Here we integrated data from remote sensors, physiological and multi-omics analyses to assess the feasibility of detecting time dependent signals - the chronobiome - despite the "noise" attributable to the behavioral differences of free-living human volunteers. The majority (62%) of sensor readouts showed time-specific variability including the expected variation in blood pressure, heart rate, and cortisol. While variance in the multi-omics is dominated by inter-individual differences, temporal patterns are evident in the metabolome (5.4% in plasma, 5.6% in saliva) and in several genera of the oral microbiome. This demonstrates, despite a small sample size and limited sampling, the feasibility of characterizing at scale the human chronobiome "in the wild". Such reference data at scale are a prerequisite to detect and mechanistically interpret discordant data derived from patients with temporal patterns of disease expression, to develop time-specific therapeutic strategies and to refine existing treatments.

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SN - 2045-2322

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JO - Scientific Reports

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A pilot characterization of the human chronobiome

Abstract

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