Hibernation induces widespread transcriptional remodeling in metabolic tissues of the grizzly bear.

Revealing the mechanisms underlying the reversible physiology of hibernation could have applications to both human and animal health as hibernation is often associated with disease-like states. The present study uses RNA-sequencing to reveal the tissue and seasonal transcriptional changes occurring...

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Bibliographic Details
Main Authors: Jansen, Heiko T, Trojahn, Shawn, Saxton, Michael W, Quackenbush, Corey R, Evans Hutzenbiler, Brandon D, Nelson, O Lynne, Cornejo, Omar E, Robbins, Charles T, Kelley, Joanna L
Format: Article in Journal/Newspaper
Language:unknown
Published: eScholarship, University of California 2019
Subjects:
Animals
Ursidae
Gene Expression Profiling
Hibernation
Organ Specificity
Energy Metabolism
Transcriptome
Animal physiology
Gene expression
Gene regulation
Genetics
Genomics
Human Genome
Biotechnology
Digestive Diseases
Aetiology
2.1 Biological and endogenous factors
Musculoskeletal
Metabolic and endocrine
Ursus arctos
Online Access:https://escholarship.org/uc/item/98s231fk
Description
Summary:Revealing the mechanisms underlying the reversible physiology of hibernation could have applications to both human and animal health as hibernation is often associated with disease-like states. The present study uses RNA-sequencing to reveal the tissue and seasonal transcriptional changes occurring in grizzly bears (Ursus arctos horribilis). Comparing hibernation to other seasons, bear adipose has a greater number of differentially expressed genes than liver and skeletal muscle. During hyperphagia, adipose has more than 900 differentially expressed genes compared to active season. Hibernation is characterized by reduced expression of genes associated with insulin signaling, muscle protein degradation, and urea production, and increased expression within muscle protein anabolic pathways. Across all three tissues we find a subset of shared differentially expressed genes, some of which are uncharacterized, that together may reflect a common regulatory mechanism. The identified gene families could be useful for developing novel therapeutics to treat human and animal diseases.

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