Time-Restricted Feeding during Puberty Ameliorates Adiposity and Prevents Hepatic Steatosis in a Mouse Model of Childhood Obesity

Childhood obesity is one of the most serious public health challenges of the 21st century. In 2016, around 41 million children under the age of five were overweight or obese. Childhood obesity is a major risk factor for other adult co-morbidities, including type-2 diabetes, cardiovascular disease, non-alcoholic fatty liver disease, kidney failure, and some types of cancer [1,2,3], which collectively shorten lifespan [4]. Current interventions are largely ineffective because their benefits are typically transient and tend to fade away over time [5,6]. The causes leading to childhood obesity are complex and include both genetic and environmental factors, such as high calorie intake and physical inactivity. In accordance, recent observational studies have established infant nutrition as a major factor that leads to rapid growth (i.e. weight gain), early adiposity and later disease risk [7]. Currently, the molecular mechanisms that contribute to the long-lasting metabolic effects associated to early nutrition and adiposity remain poorly characterized [8,9,10,11].

We have previously developed a mouse model of early adiposity (i.e., childhood obesity) through litter size reduction [12]. Mice bred in small litters (SL) exhibited rapid neonatal growth and developed obesity as early as by the age of 15 days [13,14]. As adults, SL mice displayed several metabolic disturbances, including glucose intolerance, insulin resistance, adult obesity and hepatic steatosis [13,14]. The liver played a major role in triggering early-onset insulin resistance. At the molecular level, hepatic steatosis and hepatic insulin resistance were attributed, in part, to misalignment of the hepatic circadian rhythm [15].

Time-restricted feeding (TRF) has recently emerged as a promising strategy for treating obesity and type-2 diabetes [16,17,18]. It is a dietary approach that limits the access to the food for a limited number of hours during the active phase of the day. Typically, the temporal feeding windows span from 6 to 10 h. Notably, the TRFs exert their beneficial effects, in part, through modulating the circadian rhythm [19], which in turn regulates metabolic outcomes [20]. However, to the best of our knowledge, there are no studies centered in children and/or adolescents [21,22]. Hence, it is currently unknown whether these types of chrono-nutrition interventions might be also effective for children with overweigh or obesity.

Here we aimed to explore whether TRF during the pre-pubertal period might improve the metabolism of SL mice. We show that 4-weeks intervention (8 h feeding/16 h fasting) ameliorated adiposity and prevented the development of hepatic steatosis. These effects were partly associated to better alignment of the hepatic circadian rhythm. Together, we provide evidence that early TRF, during pre-pubertal age, is an effective and safe means to improve metabolic health in the context of childhood obesity, without causing major impairments on appropriate growth.

We have previously developed a mouse model of early adiposity (i.e., childhood obesity) through litter size reduction (Figure 1a) [12,13]. Mice reared in small litters grew faster that the controls (Figure 1b) and developed obesity by 4 weeks of age (Figure 1c). At the end of the 4-week intervention, the SL mice fed ad libitum (SL-AL) developed hyperglycemia, hyperinsulinemia, and insulin resistance (HOMA-IR), as determined at two independent periods of the light cycle, ZT0 and ZT12 (Figure 1d). In contrast, plasma triglyceride and cholesterol levels remained normal in SL-AL mice, when compared to the controls (Figure S1A). We tested whether two independent TRFs might effectively improve metabolism in these obese pre-pubertal mice (Figure 1a).

Chrono-nutrition strategies have become powerful tools for improving metabolic health in adults with obesity and/or diabetes [16]. Likewise, TRFs have been effectively applied to adult rodent models of metabolic disease [19]. However, the feasibility of TRF interventions in pre-pubertal subjects improving or preventing late-onset metabolic derangements is under-reported [21,22]. Here we provide strong evidence to support that short-term chrono-nutrition interventions have a profound beneficial impact on metabolism in pre-pubertal rodents with obesity. These data open the rationale for designing a similar type of interventions for children or adolescents with overweight/obesity.

In this study, we conducted two independent chrono-nutrition based interventions that consisted of cycles of 8-h feeding/16-h fasting. They differed regarding the time of the day when the feeding/fasting cycles were applied. In the first one (TRF1), food was available during to the dark cycle, from ZT14-ZT22 (Figure 1a). In the second one (TRF2), food was available during the dark:light transitions, from ZT10-ZT14 and ZT22-ZT2. In an attempt at translating them into the human practice, the TRF1 should be considered a “breakfast skipping” intervention, while the TRF2 should be a “lunch skipping” condition.

Both interventions improved the metabolism of SL mice, although with slightly different final outcomes. These differences could be attributed, at least in part, to disparities in the feeding windows, which in turn might influence total calorie intake: In the TRF1, mice had access to the diet for 8 h during the dark cycle, which is the period of the day when rodents consume most of their calories. In the TRF2, this window was fragmented in two 4-h intervals that spanned a few hours of the light cycle, when rodents typically rest. We speculate that this fragmentation, together with conflicts with the light:dark signals, will shorten the effective time that SL-TRF2 mice spend on feeding and contribute to decreased food intake. Interestingly, this effect was specific to the SL-TRF2 mice. The Control healthy mice exposed to the same type of chrono-nutrition intervention did not experience reductions in caloric intake nor exhibited obvious metabolic derangements. These data suggest that these types of nutritional interventions are safe and could be potentially translated into the clinical practice. We recognize, though, that extreme cautiousness is needed before implementing these interventions in children. For example, “lunch skipping” interventions might be hard to implement in children. However, we argue that “breakfast skipping” approaches might be reasonably implemented in children. Firstly, it is shown that in adults, breakfast-skipping approaches are more efficient than lunch- or dinner-skipping formulas [27]. This is because “skipping breakfast” interventions have greater adherence to the treatment than other approaches. Secondly, a few studies have now suggested that age is an important factor in TRF, as young individuals may be more susceptible to its benefits than older counterparts. While clearly attractive, additional long-term experiments should be conducted in the future. A recent study reported some opposite data to ours: Pre-pubertal mice were subjected to short 4-week TRF intervention, followed by ad lib feeding for 4 additional weeks. This protocol compromised metabolic health, including obesity, hyperglycemia and hepatic steatosis in wild type mice [28]. While the authors have not explored whether their approach might have beneficial/detrimental effects in obese pre-pubertal mice, additional experiments are warranted to elucidate long-term effects of TRF in young rodents.

Our data support that in pre-pubertal obese mice, two independent short-term TRFs prevented the development of hepatic steatosis. This was accomplished, at least in part, through normalizing the expression of genes involved in lipogenesis (Fasn, Pparg) and FFA oxidation (Cpt1a). Some evidence supports that the TRFs improve metabolic health, at least in part, through modulating the circadian rhythm [29,30]. Indeed, we had previously shown that hepatic steatosis in SL mice might be attributed to dysregulation of peripheral clock genes [15]. Hence, here we speculate that normalization of TAG concentration in our model might be accomplished through re-setting the hepatic circadian rhythm. Indeed, we found that both TRFs induced dramatic changes in amplitude/acrophase of several core clock genes. Both interventions tended to increase the amplitudes of the core clock genes. In agreement, it is shown that other chrono-nutritional interventions also increased the amplitude of clock genes, which is generally associated to improvements in metabolic profile [31]. Interestingly, in our model the TRFs primarily modified those clock genes that are partially entrained by nutritional cues, including Per1-3 or Cry1-2 [20,32,33]. In turn, Period and Cryptochrome genes can regulate hepatic lipid content through directly influencing the expression of lipogenic genes [15,26]. Hence, here we proposed that the TRFs contribute to restore hepatic lipid content, in part, through re-setting the clock genes, which in turn, modify the expression of lipid-related genes.

We indirectly addressed this question through regression analyses (correlogram). While we recognize that it is not possible to establish causal relationships through regression assays, our data suggest that the hepatic clock genes might play a moderate role in modulating the expression of the downstream lipid-related genes Pparg and Cpt1a. Specifically, the TRF1 strengthened the correlations that already existed between the core clock genes and Pparg-Cpt1a (Figure 6). On the other hand, the TRF2 partially re-set these associations: Several new correlations were established whereas a few others vanished (Figure 6). Nevertheless, the fact that Fasn showed no direct correlation with either clock gene in any intervention strongly suggests that additional clock-independent mechanisms should contribute to normalize the lipid content in SL mice, [29,33] (Figure 6). For example, it has been recently shown that time-restricted feeding in pre-pubertal mice may permanently miss-program the gut microbiota composition [34,35] which in turn can influence whole body physiology, including hepatic steatosis [35]. Clearly, the potential impact of the gut microbiota and/or other fasting-derived signals in our model deserves being studied in the future.

In conclusion, time-restricted feeding during early life is a feasible nutritional strategy for preventing metabolic derangements in the context of childhood/adolescent overweight. Significantly, in our experimental setting, neither TRF induced obvious physiologic disturbances in the Control groups, which indicates that they are safe and, thus, potentially applicable for the pediatric population [11]. However, we recognize that this study has some limitations. Firstly, we have undertaken short-term experiments, and the long-term impact of these types of interventions will require further experiments before they might be implanted to humans. Secondly, the actual mechanisms involved in reversing hepatic steatosis and insulin resistance are far from being fully elucidated. Although we suggest that the clock genes might be involved in ameliorating hepatic steatosis, the data are based on associative studies. Therefore, additional experiments are needed to understand the molecular mechanisms involved in both processes. Finally, as we have extensively discussed, their implementation in clinical practice requires further careful evaluation. Specifically, here, we have conducted “breakfast skipping” and “lunch skipping” interventions. Pilot studies are required before translating them into the clinics.