Calorie restriction reprograms diurnal rhythms in protein translation to regulate metabolism

Makwana, Kuldeep; Gosai, Neha; Poe, Allan; Kondratov, Roman V.

doi:10.1096/fj.201802167r

Cited by 14 publications

(10 citation statements)

References 68 publications

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“…The expression of Acadvl (encodes VLCAD), Acadl (encodes LCAD), and peroxisomal Acot3 and Acot4 was significantly induced by CR in a time of the day‐dependent manner (Figure 2d). mRNA expression was in agreement with protein expression and with published data on polysome association (Makwana et al, 2019). Thus, the changes in mRNA expression might provide a mechanistic explanation for increased protein expression.…”

Section: Resultssupporting

confidence: 90%

“…Discrepancy of results from different reports may be due to different times of feeding for the experiment and analysis of RNA. The feeding/oxidation cycle has 24-h periodicity, which implies a possible interaction with circadian rhythms, and this is supported by evidence of a crosstalk between aging, CR, and the circadian clock (Makwana et al, 2019;Patel et al, 2016;Sato et al, 2017). Therefore, the circadian rhythms must be taken into consideration to understand CR-induced reprogramming of fat metabolism.…”

Section: Introductionmentioning

confidence: 99%

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CR reprograms acetyl‐CoA metabolism and induces long‐chain acyl‐CoA dehydrogenase and CrAT expression

et al. 2020

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Section: Resultssupporting

confidence: 90%

Section: Introductionmentioning

confidence: 99%

CR reprograms acetyl‐CoA metabolism and induces long‐chain acyl‐CoA dehydrogenase and CrAT expression

et al. 2020

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“…The peak (nadir) of those oscillation genes under L-DD occurred at CT9 or CT13. The circadian rhythm of Acot3 and Acot4 are evidently induced by calorie restriction and are transcriptional targets of PPARa [55]. Compared to LD, the circadian rhythm of Acot3, 4, 8 and 13 were also induced by L-DD with increased amplitude.…”

Section: Discussionmentioning

confidence: 94%

Endogenous circadian time genes expressions in the liver of mice under constant darkness

Zhang

et al. 2020

BMC Genomics

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Background: The circadian rhythms regulate physiological functions and metabolism. Circadian Time (CT) is a unit to quantify the rhythm of endogenous circadian clock, independent of light influence. To understand the gene expression changes throughout CT, C57BL/6 J mice were maintained under constant darkness (DD) for 6 weeks, and the liver samples were collected starting at 9:00 AM (CT1), and every 4 h in a 24-h cycle (CT5, CT9, CT13, CT17 and CT21). Total RNA was extracted and subjected to RNA-Seq data (deposited as GSE 133342, L-DD). To compare gene oscillation pattern under normal light-dark condition (LD, GSE114400) and short time (2 days) dark-dark condition (S-DD, GSE70497), these data were retried from GEO database, and the trimmed mean of M-values normalization was used to normalize the three RNA-seq data followed by MetaCycle analysis. Results: Approximate 12.1% of the genes under L-DD exhibited significant rhythmically expression. The top 5 biological processes enriched in L-DD oscillation genes were mRNA processing, aromatic compound catabolic process, mitochondrion organization, heterocycle catabolic process and cellular nitrogen compound mitotic catabolic process. The endogenous circadian rhythms of clock genes, P450 genes and lipid metabolism genes under L-DD were further compared with LD and S-DD. The oscillation patterns were similar but the period and amplitude of those oscillation genes were slightly altered. RT-qPCR confirmed the selected RNA sequence findings. Conclusions: This is the first study to profile oscillation gene expressions under L-DD. Our data indicate that clock genes, P450 genes and lipid metabolism genes expressed rhythmically under L-DD. Light was not the necessary factor for persisting circadian rhythm but influenced the period and amplitude of oscillation genes.

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“…Dietary interventions such as CR, HF, or ketogenic diet affect the circadian clock and rhythms. CR increases the amplitude of clock gene expression and reprograms circadian rhythms in transcription, translation, hormone secretion, and mTOR signaling (Makwana, Gosai, Poe, & Kondratov, 2018; Patel, Velingkaar, Velingkaar, Makwana, Chaudhari, & Kondratov, 2016; Sato et al, 2017; Tulsian, Velingkaar, & Kondratov, 2018). In turn, many metabolic benefits of caloric restriction, including effects on lifespan, are impaired in circadian clock mutants indicating an interaction between CR and the circadian clock (Katewa et al, 2016; Patel, Chaudhari, et al, 2016).…”

Section: Introductionmentioning

confidence: 99%

Reduced caloric intake and periodic fasting independently contribute to metabolic effects of caloric restriction

et al. 2020

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Caloric restriction (CR) has positive effects on health and longevity. CR in mammals implements time‐restricted (TR) feeding, a short period of feeding followed by prolonged fasting. Periodic fasting, in the form of TR or mealtime, improves metabolism without reduction in caloric intake. In order to understand the relative contribution of reduced food intake and periodic fasting to the health benefits of CR, we compared physiological and metabolic changes induced by CR and TR (without reduced food intake) in mice. CR significantly reduced blood glucose and insulin around the clock, improved glucose tolerance, and increased insulin sensitivity (IS). TR reduced blood insulin and increased insulin sensitivity, but in contrast to CR, TR did not improve glucose homeostasis. Liver expression of circadian clock genes was affected by both diets while the mRNA expression of glucose metabolism genes was significantly induced by CR, and not by TR, which is in agreement with the minor effect of TR on glucose metabolism. Thus, periodic fasting contributes to some metabolic benefits of CR, but TR is metabolically different from CR. This difference might contribute to differential effects of CR and TR on longevity.

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Calorie restriction reprograms diurnal rhythms in protein translation to regulate metabolism

Cited by 14 publications

References 68 publications

CR reprograms acetyl‐CoA metabolism and induces long‐chain acyl‐CoA dehydrogenase and CrAT expression

CR reprograms acetyl‐CoA metabolism and induces long‐chain acyl‐CoA dehydrogenase and CrAT expression

Endogenous circadian time genes expressions in the liver of mice under constant darkness

Reduced caloric intake and periodic fasting independently contribute to metabolic effects of caloric restriction

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