Liver Transcriptome Dynamics During Hibernation Are Shaped by a Shifting Balance Between Transcription and RNA Stability

Gillen, Austin E.; Fu, Rui; Riemondy, Kent; Jager, Jennifer; Fang, Bin; Lazar, Mitchell A.; Martin, Sandra L.

doi:10.3389/fphys.2021.662132

Cited by 16 publications

(23 citation statements)

References 88 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…This is supported by studies in mice demonstrating that mice preconditioned with sub-lethal ischemia before more severe ischemia can increase ischemic tolerance through induction of DNA repair mechanisms 91 . To continue, when observing hibernating animals, transcriptomic studies of the liver in hibernating 13-lined ground squirrels (Ictidomys tridecemlineatus) also found enrichment of genes involved in double-strand break repair with upregulation of genes such as DDX11 that were correlated with colder body temperatures 92 . Similar observations were made by Jenson et al, who reported DNA repair-related GO terms in the liver of hibernating grizzly bears (Ursus arctos horribilis) involving serval DNA repair (e.g.…”

Section: Hypo-metabolic State Confers An Anti-apoptotic Phenotype The...mentioning

confidence: 99%

Investigating the effects of chronic low-dose radiation exposure in the liver of a hypothermic zebrafish model

Cahill

Silveira

Renaud

et al. 2023

Sci Rep

View full text Add to dashboard Cite

Mankind’s quest for a manned mission to Mars is placing increased emphasis on the development of innovative radio-protective countermeasures for long-term space travel. Hibernation confers radio-protective effects in hibernating animals, and this has led to the investigation of synthetic torpor to mitigate the deleterious effects of chronic low-dose-rate radiation exposure. Here we describe an induced torpor model we developed using the zebrafish. We explored the effects of radiation exposure on this model with a focus on the liver. Transcriptomic and behavioural analyses were performed. Radiation exposure resulted in transcriptomic perturbations in lipid metabolism and absorption, wound healing, immune response, and fibrogenic pathways. Induced torpor reduced metabolism and increased pro-survival, anti-apoptotic, and DNA repair pathways. Coupled with radiation exposure, induced torpor led to a stress response but also revealed maintenance of DNA repair mechanisms, pro-survival and anti-apoptotic signals. To further characterise our model of induced torpor, the zebrafish model was compared with hepatic transcriptomic data from hibernating grizzly bears (Ursus arctos horribilis) and active controls revealing conserved responses in gene expression associated with anti-apoptotic processes, DNA damage repair, cell survival, proliferation, and antioxidant response. Similarly, the radiation group was compared with space-flown mice revealing shared changes in lipid metabolism.

show abstract

Section: Hypo-metabolic State Confers An Anti-apoptotic Phenotype The...mentioning

confidence: 99%

Investigating the effects of chronic low-dose radiation exposure in the liver of a hypothermic zebrafish model

Cahill

Silveira

Renaud

et al. 2023

Sci Rep

View full text Add to dashboard Cite

show abstract

“…In animals, the expression or repression of certain genes modulates hibernation processes and adaptive evolution. For example, in the livers of thirteen‐lined ground squirrels, the expression of genes associated with fatty acid, cholesterol and steroid biosynthesis, xenobiotic, and amino acid metabolism were reduced 13 . In Arctic ground squirrels, high expression of Pck1 , a crucial enzyme of gluconeogenesis, coupled with low expression of Gck , was observed to improve energy distribution during hibernation 14 .…”

Section: Introductionmentioning

confidence: 99%

Adapting to stress: The effects of hibernation and hibernacula temperature on the hepatic transcriptome of Rhinolophus pusillus

Wang,

Chen

et al. 2024

The FASEB Journal

View full text Add to dashboard Cite

Hibernation, a survival strategy in mammals for extreme climates, induces physiological phenomena such as ischemia–reperfusion and metabolic shifts that hold great potential for advancements in modern medicine. Despite this, the molecular mechanisms underpinning hibernation remain largely unclear. This study used RNA‐seq and Iso‐seq techniques to investigate the changes in liver transcriptome expression of Rhinolophus pusillus during hibernation and active periods, as well as under different microhabitat temperatures. We identified 11 457 differentially expressed genes during hibernation and active periods, of which 395 showed significant differential expression. Genes associated with fatty acid catabolism were significantly upregulated during hibernation, whereas genes related to carbohydrate metabolism and glycogen synthesis were downregulated. Conversely, immune‐related genes displayed differential expression patterns: genes tied to innate immunity were significantly upregulated, while those linked to adaptive immunity and inflammatory response were downregulated. The analysis of transcriptomic data obtained from different microhabitat temperatures revealed that R. pusillus exhibited an upregulation of genes associated with lipid metabolism in lower microhabitat temperature. This upregulation facilitated an enhanced utilization rate of triglyceride, ultimately resulting in increased energy provision for the organism. Additionally, R. pusillus upregulated gluconeogenesis‐related genes regardless of the microhabitat temperature, demonstrating the importance of maintaining blood glucose levels during hibernation. Our transcriptomic data reveal that these changes in liver gene expression optimize energy allocation during hibernation, suggesting that liver tissue adaptively responds to the inherent stress of its function during hibernation. This study sheds light on the role of differential gene expression in promoting more efficient energy allocation during hibernation. It contributes to our understanding of how liver tissue adapts to the stressors associated with this state.

show abstract

“…To test for tissue specificity of gene expression, we sampled three different tissues (brain, cochlea, and liver) for each individual. Brain and liver were commonly used to investigate seasonal differences in gene expression (e.g., Gillen et al, 2021 ; Johnston et al, 2016 ; Schwartz et al, 2013 ; Xiao et al, 2015 ; Zhao et al, 2016 ). In this study, we also included cochlea tissue because previous studies have indicated seasonal changes in echolocation calls and auditory processing in bats (Grilliot et al, 2014 ; Miller et al, 2016 ).…”

Section: Introductionmentioning

confidence: 99%

Impacts of seasonality on gene expression in the Chinese horseshoe bat

Chen

Mao

2022

Ecology and Evolution

View full text Add to dashboard Cite

Seasonality can cause changes in many environmental factors which potentially affects gene expression. Here, we used a bat species ( Rhinolophus sinicus ) from eastern China as a model to explore the molecular mechanisms of seasonal effects, in particular during phenological shifts in the spring and autumn. Based on the analysis of 45 RNA‐seq samples, we found strong seasonal effects on gene expression, with a large number of genes identified as either specific or biased to each season. Weighted gene co‐expression network analysis also identified multiple modules significantly associated with each season. These seasonal genes were further enriched into different functional categories. Consistent with effects of phenological shifts on bats, we found that genes related to promoting food intake were highly expressed in both autumn and spring. In addition, immunity genes were also highly expressed in both seasons although this seasonal immune response had tissue specificity in different seasons. In female bats, genes related to the delay of ovulation (e.g., NPPC , natriuretic peptide precursor type C) were highly expressed in October, while genes associated with the promotion of reproduction (e.g., DIO2 , iodothyronine deiodinase 2) were biasedly expressed in April. Lastly, we found multiple known core clock genes in both October‐biased and April‐biased expressed genes, which may be involved in regulating the start and end of hibernation, respectively. Overall, together with studies in other land and aquatic animals, our work supports that seasonal gene expression variations may be a general evolutionary response to environmental changes in wild animals.

show abstract

Liver Transcriptome Dynamics During Hibernation Are Shaped by a Shifting Balance Between Transcription and RNA Stability

Cited by 16 publications

References 88 publications

Investigating the effects of chronic low-dose radiation exposure in the liver of a hypothermic zebrafish model

Investigating the effects of chronic low-dose radiation exposure in the liver of a hypothermic zebrafish model

Adapting to stress: The effects of hibernation and hibernacula temperature on the hepatic transcriptome of Rhinolophus pusillus

Impacts of seasonality on gene expression in the Chinese horseshoe bat

Contact Info

Product

Resources

About