Skeletal muscle gene expression dysregulation in long-term spaceflights and aging is clock-dependent

Malhan, Deeksha; Yalçin, Müge; Schoenrock, Britt; Blottner, Dieter; Relógio, Angela

doi:10.1038/s41526-023-00273-4

Cited by 7 publications

(7 citation statements)

References 167 publications

(213 reference statements)

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“…These genes can feedback to inhibit Clock/Npas2 and Bmal1 as part of a feedback loop 94,95 , and also regulate other the clock controlled genes such as DBP, HLF and TEF, significantly downregulated, and Nfil3 (E4BP4), significantly upregulated after 56 days of spaceflight. These spaceflight-associated changes in core clock genes, such as upregulation of Bmal1, Arntl and Npas2, largely agree with those found in murine muscle tissue after longer-term spaceflight which were characterised as similar to age-related gene expression on earth 96 .…”

Section: Intestinal Bile Acid and Circadian Rhythm Gene Expressionsupporting

confidence: 81%

Spaceflight alters host-gut microbiota interactions

Gonzalez,

Lee,

Tierney

et al. 2024

Preprint

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The rodent habitat on the International Space Station has provided crucial insights into the impact of spaceflight on mammals, including observation of symptoms characteristic of liver disease, insulin resistance, osteopenia and myopathy. Although these physiological responses can involve the microbiome when observed on Earth, changes in host-microbiota interactions during spaceflight are still being elucidated. Here, NASA GeneLab multiomic data from the Rodent Research 6 mission are used to determine changes to gut microbiota and murine host colon and liver gene expression after 29 and 56-days of spaceflight. Using hybrid amplicon and whole metagenome sequencing analysis, significant spaceflight-associated alterations to 42 microbiome species were identified. These included relative reductions of bacteria associated with bile acid and butyrate metabolism, such as Extibacter muris and Dysosmobacter welbionis. Functional prediction suggested over-representation of fatty acid and bile acid metabolism, extracellular matrix interactions, and antibiotic resistance genes within the gut microbiome, while host intestinal and hepatic gene expression described corresponding changes to host bile acid and energy metabolism, and immune suppression from spaceflight. Taken together, these changes imply that interactions at the host-gut microbiome interface contribute to spaceflight pathology and highlight how these interactions might critically influence human health and the feasibility of long-duration spaceflight.

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Section: Intestinal Bile Acid and Circadian Rhythm Gene Expressionsupporting

confidence: 81%

Spaceflight alters host-gut microbiota interactions

Gonzalez,

Lee,

Tierney

et al. 2024

Preprint

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“…Miller MJ et al showed that Atf4 is an essential mediator of skeletal muscle aging, and its loss in mice exhibited significant protection from age‐related decline in skeletal muscle strength (Miller et al, 2023 ). In a recent study from our group, we reported clock regulated expression of Atf4 in human and mice skeletal muscle (Malhan et al, 2023 ). A cross‐sectional study performed on elderly women identified a specific polymorphism in ACTN3 (R577X), which contributes to a higher risk of developing sarcopenia (Romero‐Blanco et al, 2021 ).…”

Section: A Link Between the Circadian Clock And Agingmentioning

confidence: 88%

“…Thus, investigating the circadian clock and its misalignments in Space is of major relevance to get a deeper understanding of the potential key roles in many functional impairments in human physiology on the ground and in spaceflight. A recent comprehensive bioinformatics and computational analysis using 1179 mammalian skeletal muscle samples from 28 published genomics and proteomics datasets, by our group showed common gene expression changes in the circadian clock and skeletal muscle associated pathways due to aging on Earth and long‐term spaceflight in mammalian skeletal muscle (Malhan et al, 2023 ).…”

Section: Alteration Of Circadian Clock and Spaceflight: An (Anti)agin...mentioning

confidence: 99%

“…Aging phenotype results from alterations in telomere length, epigenetic regulation, and mitochondrial function, along with dysregulations in nine other processes (proteostasis, macroautophagy, cellular senescence, stem cell exhaustion, intercellular communication, chronic inflammation, dysbiosis, genomic instability, and nutrient‐sensing), which are altogether referred to as the hallmarks of aging (López‐Otín et al, 2023 ). Interestingly, recent studies associate aging to spaceflight with contradictory conclusions (Biolo et al, 2003 ; Cannavo et al, 2022 ; Garrett‐Bakelman et al, 2019 ; Honda et al, 2012 ; Ma et al, 2015 ; Malhan et al, 2023 ; Nwanaji‐Enwerem et al, 2020 ; Otsuka et al, 2019 ; 2022 ; Wang, 1999 ), while some of the studies report an anti‐aging impact of spaceflight, others observed progressive aging due to spaceflight. Whether the anti‐aging impact of spaceflight correlates with the “twin paradox” (Gron, 2006 ) based on the theory of relativity coined by Albert Einstein, which proposes that an individual in Space ages slower compared to his/her biological twin on Earth, remains to be shown.…”

Section: Introductionmentioning

confidence: 99%

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Circadian regulation in aging: Implications for spaceflight and life on earth

et al. 2023

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Alterations in the circadian system are characteristic of aging on Earth. With the decline in physiological processes due to aging, several health concerns including vision loss, cardiovascular disorders, cognitive impairments, and muscle mass loss arise in elderly populations. Similar health risks are reported as “red flag” risks among astronauts during and after a long‐term Space exploration journey. However, little is known about the common molecular alterations underlying terrestrial aging and space‐related aging in astronauts, and controversial conclusions have been recently reported. In light of the regulatory role of the circadian clock in the maintenance of human health, we review here the overlapping role of the circadian clock both on aging on Earth and spaceflight with a focus on the four most affected systems: visual, cardiovascular, central nervous, and musculoskeletal systems. In this review, we briefly introduce the regulatory role of the circadian clock in specific cellular processes followed by alterations in those processes due to aging. We next summarize the known molecular alterations associated with spaceflight, highlighting involved clock‐regulated genes in space flown Drosophila, nematodes, small mammals, and astronauts. Finally, we discuss common genes that are altered in terms of their expression due to aging on Earth and spaceflight. Altogether, the data elaborated in this review strengthen our hypothesis regarding the timely need to include circadian dysregulation as an emerging hallmark of aging on Earth and beyond.

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“… 89 Therefore, clock gene disruption is associated with ageing. 90 Even though the connection between telomere length and sarcopenia is not fully elucidated, shorter telomere length is linked to decreased grip strength—a sarcopenia marker. 91 Furthermore, epigenetic mechanisms such as histone alterations, including acetylation and methylation, play a role in regulating CLOCK transcription factor expression.…”

Section: Sarcopenia and Clock Genes: A Comprehensive Explorationmentioning

confidence: 99%

The effect of low birth weight as an intrauterine exposure on the early onset of sarcopenia through possible molecular pathways

Celik,

Campisi,

Cannella

et al. 2024

J cachexia sarcopenia muscle

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Sarcopenia, a musculoskeletal disease characterized by the progressive loss of skeletal muscle mass, strength, and physical performance, presents significant challenges to global public health due to its adverse effects on mobility, morbidity, mortality, and healthcare costs. This comprehensive review explores the intricate connections between sarcopenia and low birth weight (LBW), emphasizing the developmental origins of health and disease (DOHaD) hypothesis, inflammatory processes (inflammaging), mitochondrial dysfunction, circadian rhythm disruptions, epigenetic mechanisms, and genetic variations revealed through genome‐wide studies (GWAS). A systematic search strategy was developed using PubMed to identify relevant English‐language publications on sarcopenia, LBW, DOHaD, inflammaging, mitochondrial dysfunction, circadian disruption, epigenetic mechanisms, and GWAS. The publications consist of 46.2% reviews, 21.2% cohort studies, 4.8% systematic reviews, 1.9% cross‐sectional studies, 13.4% animal studies, 4.8% genome‐wide studies, 5.8% epigenome‐wide studies, and 1.9% book chapters. The review identified key factors contributing to sarcopenia development, including the DOHaD hypothesis, LBW impact on muscle mass, inflammaging, mitochondrial dysfunction, the influence of clock genes, the role of epigenetic mechanisms, and genetic variations revealed through GWAS. The DOHaD theory suggests that LBW induces epigenetic alterations during foetal development, impacting long‐term health outcomes, including the early onset of sarcopenia. LBW correlates with reduced muscle mass, grip strength, and lean body mass in adulthood, increasing the risk of sarcopenia. Chronic inflammation (inflammaging) and mitochondrial dysfunction contribute to sarcopenia, with LBW linked to increased oxidative stress and dysfunction. Disrupted circadian rhythms, regulated by genes such as BMAL1 and CLOCK, are associated with both LBW and sarcopenia, impacting lipid metabolism, muscle mass, and the ageing process. Early‐life exposures, including LBW, induce epigenetic modifications like DNA methylation (DNAm) and histone changes, playing a pivotal role in sarcopenia development. Genome‐wide studies have identified candidate genes and variants associated with lean body mass, muscle weakness, and sarcopenia, providing insights into genetic factors contributing to the disorder. LBW emerges as a potential early predictor of sarcopenia development, reflecting the impact of intrauterine exposures on long‐term health outcomes. Understanding the complex interplay between LBW with inflammaging, mitochondrial dysfunction, circadian disruption, and epigenetic factors is essential for elucidating the pathogenesis of sarcopenia and developing targeted interventions. Future research on GWAS and the underlying mechanisms of LBW‐associated sarcopenia is warranted to inform preventive strategies and improve public health outcomes.

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Skeletal muscle gene expression dysregulation in long-term spaceflights and aging is clock-dependent

Cited by 7 publications

References 167 publications

Spaceflight alters host-gut microbiota interactions

Spaceflight alters host-gut microbiota interactions

Circadian regulation in aging: Implications for spaceflight and life on earth

The effect of low birth weight as an intrauterine exposure on the early onset of sarcopenia through possible molecular pathways

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