Post-Effects of Time-Restricted Feeding against Adipose Tissue Inflammation and Insulin Resistance in Obese Mice

Time-restricted feeding (TRF) is a dietary regimen with a daily eating window, usually 10 h or less, followed by at least 14 h of fasting [1,2]. Over the past few years, increasing numbers of studies have documented that rodents on TRF are largely protected from developing obesity and several metabolic diseases [3,4,5], and that those with pre-existing obesity also benefit from the therapeutic effects of TRF [6,7,8]. It appears that TRF exerts various effects on multiple tissues, including adipose tissue, bone marrow, and the liver during obesity. In mice receiving a high-fat diet, those on TRF had less severe adipose tissue inflammation compared to their counterparts fed ad libitum [6,8]. In particular, the infiltration of macrophages and expression of inflammation genes restricted to or enriched in macrophages, such as Adgre1 (F4/80) and Tnf [9], were reduced in the adipose tissue of TRF mice [8]. In parallel, TRF intervention was effective in normalizing the obesity-induced expansion of myeloid progenitor populations in the bone marrow and thus the monocyte pool in circulation [10]. Mice on TRF experience extended daily fasting, which alters various hepatic gene expressions, including peroxisome proliferator-activated receptor (PPAR) [4]. While PPARγ level was elevated in the liver of obese mice [4,11], TRF effectively reduced PPARγ and the associated lipogenic gene expression, along with a reduction in fatty liver disease [4]. Additional gene expressions associated with hepatic inflammation were also either reversed or attenuated under TRF intervention [4,12,13].

Most of these benefits have been observed under continuous TRF conditions, and, whilst this is not clear, it is important to know whether these beneficial effects persist after cessation of TRF. This is important before any human trial begins, because individuals often encounter difficulties due to family, social, or work life [14], and may stop TRF intervention. Previously, Chaix et al. reported that mice under 5 days of TRF and 2 days of ad libitum had hepatic gene expression signatures similar to continuous TRF and exhibited improved metabolic parameters compared to those under ad libitum [6]. Although these results suggest that temporal interruption during the weekend may not deter the health benefits of TRF, it remains to be determined whether this can last beyond two days.

The present study aimed to investigate the post-effects of TRF after 2 weeks of cessation on body weight, insulin resistance index, inflammatory responses in adipose tissue and the liver, and on the circulating immune cells of obese mice. By comparing with continuous TRF or ad libitum, this could provide insights into whether 2 weeks of TRF withdrawal could maintain its effect—and thus be worth trying even with a risk of failure—or could further worsen insulin resistance and metabolic tissue inflammation, which may deter individuals from TRF cessation.

Numerous studies suggest that continuous TRF is associated with improvements in the metabolic and immunologic parameters associated with obesity, but the post-effects after TRF cessation are largely unknown. In this study, we showed that, although TRF withdrawal quickly led to increased body weight and adiposity, and reversed FBG, mice in the post-TRF group exhibited FI and insulin resistance index HOMA-IR similar to the TRF group. While circulating monocytes and hepatic gene expressions regarding inflammation returned to the levels seen in the HFD-AL group, the post-TRF cohort exhibited adipose tissue inflammation and macrophage infiltration that was significantly less severe than in the HFD-AL group. These results suggest that (1) continuous TRF is most effective, (2) prior TRF effects last but vary depending on tissues, e.g., the resulting suppression on adipose tissue inflammation and insulin resistance could last a couple of weeks even with obesogenic diets, and (3) the cessation of TRF does not heighten the metabolic risk compared with sustained obesity.

Previous reports have shown that weight fluctuations due to alternating low-/high-fat diets worsens systemic glucose tolerance in rodents [22,23]. These studies also indicate that inflammatory phenotypes in adipose tissue were exacerbated in those with weight fluctuations compared with sustained obesity [23,24]. However, in our model, rather than drastic changes in diet composition, we employed a mouse model under the same obesogenic diet to define the role of TRF and its post-effects on the metabolic and immunologic parameters associated with obesity. We found that, although the post-TRF group had a slight fluctuation in body weight, their final weight was maintained at lower levels than those under chronic ad libitum feeding. In addition, the post-TRF group had insulin resistance index that was significantly less severe than the HFD-AL group, which had persistent weight gain. Moreover, this cohort exhibited a reduced gene expression of proinflammatory molecules Adgre1 (F4/80) by 38.1%, Itgax (CD11c) by 57.0%, and Tnf by 30.5% in adipose tissue, compared to the HFD-AL group. One of the characteristic changes in adipose tissues during obesity is the accumulation of CD11c⁺F4/80⁺ macrophages, which express high levels of proinflammatory mediators [25]. In contrast, the conditional deletion of the CD11c gene in obese mice could reduce metabolic inflammation and normalize insulin sensitivity [26]. Previously, we demonstrated that TRF decreased the numbers of total and proinflammatory CD11c⁺ macrophages in adipose tissue, along with reduced Adgre1 and Itgax transcripts [8]. Thus, the decreased expression of Adgre1 and Itgax seen in the post-TRF group may contribute to a metabolically healthier phenotype (including insulin sensitivity), even after TRF cessation. We acknowledge that, preferably, the measurement of protein levels would have further verified these results, which is a limitation of the current study.

PPARγ is a transcription factor that belongs to the nuclear receptor superfamily. It is predominantly expressed in adipose tissue and, to a lesser extent, in the spleen and immune system [11]. PPARγ is required for adipocyte differentiation, the regulation of insulin sensitivity, lipogenesis, and adipocyte survival and function [27]. Previously, it was shown that PPARγ expression at both mRNA and protein levels was reduced in the adipose tissue of mice and humans with obesity [18]. These alterations appear to be associated with the dysfunction of adipose tissue, while the overexpression of Pparg in adipogenic precursors drives healthy adipose tissue expansion with fewer crown-like structures and reduced adipose tissue inflammation, as well as an improvement in glucose homeostasis [28]. In contrast, the loss of Pparg in adipogenic precursors triggers pathologic visceral expansion with HFD feeding [28]. Interestingly, the macrophage-specific depletion of Pparg in mice impaired the anti-inflammatory phenotype of adipose tissue macrophages, and predisposed them to the development of obesity and insulin resistance [29,30]. Although we cannot distinguish the effects on adipocytes or macrophages that are abundant in obese adipose tissue, the current results showed a significant decrease in Pparg mRNA levels in the adipose tissue of obese mice. Additionally, Pparg downregulation was restored to the control level completely by TRF and, to a lesser degree, after its cessation. Thus, resistance against Pparg downregulation may contribute to the sustained benefits associated with post-TRF.

Compared to PPARγ in adipose tissue, the basal expression of PPARγ is very low in the liver [31]. However, PPARγ is strongly upregulated in steatotic livers [19,32]. By using adenovirus or high-fat diet feeding, the overexpression of hepatic PPARγ on a PPARα^−/− background was shown to increase hepatic lipid accumulation and fatty liver phenotypes [33,34]. In contrast, mice lacking Pparg, specifically in the liver, were protected from hepatic steatosis [35]. In the current study, hepatic Pparg mRNA expression in the TRF group was as low as in the LFD-AL group, despite the obesogenic diet in the former. In addition, the post-TRF group had hepatic Pparg mRNA levels higher than the TRF group, but significantly lower than the HFD-AL group. These results indicate that post-TRF could maintain partial but significant protection against the upregulation of the hepatic Pparg mRNA level, thereby reducing the risk of hepatic steatosis.

PPARα is mainly present in metabolically active tissues including the liver, where it plays a pivotal role in fatty acid catabolism. Although the expression of PPARα in adipose tissue is much lower compared to PPARγ, there is evidence that PPARα activation may reduce adipose tissue inflammation during obesity by decreasing adipocyte hypertrophy, by regulating inflammatory gene expression via locally expressed PPARα, and/or by systemic events likely originating from the liver [19]. Conversely, adipose-specific PPARα^−/− mice had increased lipogenesis and a polarity shift toward inflammatory macrophages in adipose tissue [36]. Although we cannot completely rule out the possibility that post-TRF maintains its systemic effect through the liver PPARα, we observed no difference in Ppara mRNA levels in the liver between the HFD-AL and post-TRF groups. Instead, we found that the post-TRF group had Ppara mRNA levels in adipose tissue as high as those in the LFD-AL group, along with decreased inflammatory gene expression. Thus, TRF, even after cessation, could help maintain the Ppara level in adipose tissue, which possibly contributes to the reduced inflammatory status of the tissue.

Recently, it was shown that a fasting could influence the monocyte metabolic and inflammatory activity, and reduce the number of circulating monocytes, in lean mice and healthy humans [37]. However, genetically obese ob/ob mice, or mice with ad libitum feeding of HFD, had an enhanced production of monocytes in the bone marrow [38] which, in turn, potentiates macrophage accumulation in the adipose tissue [39,40]. We previously demonstrated that prolonged fasting on a daily basis by TRF could normalize monocyte production in bone marrow and thus, circulating monocytes in overweight and obese mice [10]. Here, we showed that the post-TRF group at 1 week after cessation had monocytes in circulation similar in quantity to the LFD-AL group as well as the TRF group. However, the post-effects did not last after 2 weeks of cessation, which indicates a catch up of macrophage accumulation in adipose tissues.

Despite the accumulating evidence of the metabolic benefits of TRF in rodent models, the effects of time-restricted eating in humans appear to be less obvious. Recent meta-analyses indicated that time-restricted eating resulted in a significant decrease in body weight and fat mass [41,42,43], but waist circumference, body mass index, fasting glucose, glycosylated hemoglobin, and blood pressures remained unchanged or had modest reduction depending on the study [41,42,43]. The differences in study design, including study duration, daily eating window, and compliance rates, among others, may in part account for the confusing results. For instance, time-restricted eating to the early part of the day was shown to improve fasting glucose and ameliorate inflammation markers in healthy subjects, but not in those under eating restricted to the middle of the day [44]. Thus, further clinical studies are needed to draw definitive conclusions for the usefulness of time-restricted eating in humans.

This study has several limitations. Firstly, our study included only male mice. Although female mice gained less weight than males upon HFD feeding [45], our results need to be confirmed as to whether this is also true in female models. Secondly, we did not include TRF and post-TRF regimens with LFD feeding. Since mice fed an LFD, even under ad libitum regimen, showed diurnal rhythms in food intake unlike those fed an HFD [2,4], we suspect that obese mice on TRF dramatically experience extended daily fasting and they benefit more against the metabolic inflammation associated with obesity. However, future studies employing an LFD regimen are necessary to confirm that TRF could deliver additional health benefits in the lean control. In addition, although circulating monocytes were measured for one and two weeks after the TRF cessation in obese mice, more extended time-courses of post-TRF were not performed in this study. Thus, the lasting effects on lean and obese mice could be different, which needs to be confirmed in a time-course of TRF cessation, for example, one, two, four weeks, and beyond. Finally, we measured metabolic and inflammatory markers in the blood after an 6 h fast (ZT23-ZT5) and in tissues harvested at ZT6. We chose an 6 h fast (morning fast) within a more physiological context since overnight fasting generates a starvation state in mice and could reduce lean body mass up to 15% [46,47]. It is noteworthy that, in mice fed an HFD ad libitum, the hepatic mRNA expression of Pparg was constitutively high, although rhythmic transcription existed [6]. Although we matched the fasting duration and time of day, it would be advisable to perform this at various time points, including during dark phases, to elaborate the effect of TRF and post-TRF in association with circadian rhythms.

Our findings suggest that, while continuous TRF is the most effective, its health benefits, including the maintenance of insulin sensitivity, may last for a period of time after the cessation of TRF practice. Given the observed tendency for HFD-related indicators to rebound after TRF cessation, further studies are needed to determine how metabolic and immunologic parameters are changed during repeated TRF interventions and, furthermore, a longer follow-up period is necessary so that a better understanding for the effectiveness of TRF can be achieved.