Differential Effects of Constant Light and Dim Light at Night on the Circadian Control of Metabolism and Behavior

Melatonin levels in mice vary greatly and many strains do not even produce this hormone [50], therefore, there are not much data on how LL influences melatonin levels. However, urinary 6-sulfatoxymelatonin is suppressed in melatonin-producing mice (CH3-HePas mice) during the subjective night in LL [51]. Unlike mice, rats produce melatonin, and its synthesis is highly sensitive to light exposure [52,53] (Table 1). Nocturnal, but not daytime, plasma melatonin levels are suppressed in LL, resulting in a loss of melatonin rhythm [54,55,56,57,58,59]. The same pattern is observed in urine 6-sulfatoxymelatonin concentrations [60].

Due to CORT rhythmicity, most studies measured its levels at the beginning and end of the inactive phase (the subjective day in constant conditions). In mice, LL was claimed to reduce CORT concentrations at the end of the subjective day [61,62,63]. However, this conclusion must be taken with a reservation because it is based on the two-points studies, which can miss shifts of acrophases of the rhythm. Therefore, studies measuring the 24 h profile of CORT in mice in LL are needed to elucidate the effects of constant light on circulating levels of this dominant glucocorticoid. The effects of LL on CORT in rats are diverse. In rats, its rhythm is abolished due to either the suppression of the peak [57,60] or the elevation of levels during the subjective day [59,64,65,66]. The effects do not seem to be strain-dependent since both changes are observed in Sprague–Dawley and Wistar rats, as shown in Table 1. Besides the altered plasma CORT, the adrenal CORT was elevated in the morning of the subjective day, resulting in the loss of diurnal variability which is in line with vanished differences between morning and afternoon in the adrenocorticotropic hormone that regulates the production of CORT in the adrenal gland [64]. The regulatory proteins of CORT synthesis and secretion, such as steroidogenic acute regulatory protein and steroidogenic factor 1, lost their daily variability on the mRNA and protein level. The loss of daily variability could be caused by the disturbed adrenal clock, since the CLOCK and BMAL1 regulate the production of steroidogenic acute regulatory protein [67]. Diminished signals from SCN, or the different distribution of food intake due to LL (described in the next section), could also impair the adrenal clock. The findings show that exposure to LL can influence the regulatory hypothalamo–pituitary–adrenal axis of CORT [64].

Similar to LL conditions, dLAN reduced nocturnal melatonin levels in rats [56,68,69]. The melatonin biosynthesis is highly sensitive to nocturnal light exposure, and even the illumination of 0.2 lx efficiently suppressed its high night-time concentration [56]. These suppressive effects on melatonin are comparable between LL and dLAN, regardless of the species or strain (Table 1 and Table 2).

There is limited information about how dLAN influences CORT levels. The rhythm of CORT did not change in mice exposed to dLAN [62]. On the other hand, the cortisol peak was suppressed, and the rhythm was abolished in female Siberian hamsters [70]. In diurnal grass rats exposed to dLAN, CORT levels rose in the first half of the light phase [71] suggesting that diurnal and nocturnal species may differ in the response of this stress hormone to environmental lighting conditions. In rats exposed to dim red light at night, the CORT levels were reduced and phase-advanced compared to controls [68]. These studies suggest that there are interspecies and sex differences in the reaction of CORT to dLAN exposure (Table 2). Responses could also differ based on used lighting conditions, such as intensity, type of lighting or duration. To summarize, even though the responses of CORT to LL differ between species as well as strains, the loss of daily variability is often observed. However, there is not enough evidence on its rhythmicity in rodents exposed to LL or dLAN because in most experiments, CORT was measured only in two time-points of 24-h period.

After LL exposure, the free-running rhythm with the lengthened period was described in locomotor activity, while mice exposed to LL for a longer time can display arrhythmic behavior (Table 1). Only one week of LL with an illuminance of 60 lx was not sufficient to induce the arrhythmicity of locomotor activity in mice, but one month initiated this change [91]. The manifestation of arrhythmicity can be accelerated by higher illumination. Mice under <10 lx LL displayed a lengthened period of their locomotor activity, and a similar effect was also observed under >200 lx, but some of the individuals became arrhythmic. This effect was even more apparent at higher intensities since 50% of mice were arrhythmic after exposure to >500 lx [92]. These findings were supported by other studies where the free-running rhythm with a lengthened period and the reduced strength of the rhythm appeared under LL of ≥180 and 100 lx [61,75], while the arrhythmicity occurred under much higher intensity (~580 lx) [72]. On the other hand, mice exposed to low illumination also developed arrhythmic locomotor activity without changes in total 24 h activity, but the experiment lasted two times longer [62]. The fact that not all mice became arrhythmic shows that the interindividual differences may also play an important role in the behavioral changes. In a study conducted with Per1:GFP transgenic mice, three types of behavioral changes were observed after LL exposure: a) arrhythmicity, b) period lengthening, and c) split rhythms [93]. Not only was locomotor activity varied among individuals, but the SCN neuronal activity changed and was in coincidence with alterations of behavior [61,93]. In arrhythmic mice, the clocks in SCN cells are desynchronized among each other, while they remain in synchrony in individuals with the longer free-running period. Splitting of the rhythm causes misalignment between SCN nuclei, the clocks of which are in antiphase [93]. Coincidence in locomotor and SCN neuronal activity indicates that the disruption of SCN has effects on locomotor activity and therefore, decoupling of the neurons in SCN could be one of the mechanisms behind the development of the arrhythmic locomotor activity in mice after exposure to LL (Figure 1).

In rats, shortly after LL exposure, the rhythm of the locomotor activity became free-running with a longer period, but this rhythmicity was gradually lost, until, after approximately one month, the behavior was absolutely arrhythmic in all individuals [65,66,78], which is in agreement with other studies [54,57,76,78,79,94]. The displayed changes are comparable with changes in the behavior of mice; however, the interindividual differences are far more pronounced in mice. The free-running period observed in Long Evans rats exposed to LL for 17 days [55] could only represent the transition state after LL exposure [78]. The rhythms of bmal1 and rev-erbα expression were abolished in the SCN of rats exposed to LL, but the expression of per1 and per2 genes maintained its rhythmicity [79]. Thus, the persistent rhythm in the expression of per genes was not sufficient to preserve daily changes in the locomotor activity. One of the mechanisms behind the alterations is the influence of melatonin on the locomotor activity. Melatonin increases the release of acetylcholine from the hypothalamic nucleus accumbens, and consequently, it leads to increased locomotor activity [95], suggesting that suppressed nocturnal melatonin levels are insufficient to stimulate acetylcholine release; therefore, the locomotor activity became reduced in Long Evans rats [55]. However, several mice strains do not produce melatonin [50], and even in melatonin producing and pigmented C3H/He mice, the interindividual differences in response to LL were described [96]. The locomotor activity might be re-entrained by other stimuli than light. For example, the rhythmic hormonal treatment with CORT and melatonin restored the rhythmicity of locomotor activity [57]. Another way to restore rhythmic behavior is through restricted feeding that synchronizes locomotor activity with the time of food access. Rats kept in LL with restricted feeding maintained the mRNA rhythmicity of per2, bmal1 and rev-erbα, while the expression of per1 was abolished in the SCN [79].

The total amount of 24 h activity did not change after exposure to dLAN in Swiss Webster mice; however, there are insufficient data to demonstrate changes during the 24 h cycle [62,81,82,83,84,85,86]. The disrupted wheel-running rhythmicity was observed in four out of nine Swiss Webster mice that became arrhythmic [87] indicating the interindividual differences in sensitivity to circadian disruption. The wheel-running activity of C57Bl/6 mice was phase delayed after 5 days but not 3 weeks of dLAN [80], and these changes could be explained by a transition state. The rhythmicity of PER1 and PER2 was suppressed either in the SCN or the whole hypothalamus on both protein and mRNA levels, respectively [85]. However, the studies do not provide a detailed analysis of locomotor activity or the activity of single neurons in SCN; thus, further research is needed in this area. Long-term exposure (3 months) of more than 6 months old mice induced the attenuation of locomotor activity’s rhythm [97]. Higher light intensity (20 lx) increased daytime activity and phase-advanced the onset and offset of the locomotor activity [98]. Therefore, both age and illuminance level can modify the response to dLAN (Table 2). The total locomotor activity and rhythmicity under dLAN were comparable with LD conditions in diurnal grass rats [71]. The different response is described in Wistar rats that displayed dual rhythmicity of the locomotor activity that was not present in constant dim light conditions—therefore, the second peak developed specifically in dLAN conditions [89].

In contrast to LL, the arrhythmic locomotor activity was not recorded in both mice or rats kept in dLAN. Therefore, dLAN preserved the behavioral variation between the light and dim light phase, while the rhythmicity of the locomotor activity can be either unaffected, dampened or the second rhythm appears (Table 2).

Constant light did not influence total 24 h food intake [51,61,62,73,74,75], but the daily variation was suppressed mostly due to increased food consumption in mice during the subjective day [51,61,62,73,74]. On the other hand, total food intake was reduced in mice fed a high-fat diet [61]. These results suggest that the abnormal distribution of food intake can initiate elevated body weight gain [51,61,73,74] together with fat mass (Table 1) [51,72,74]. Even if the body mass is equal to the control group, the increase in fat mass and adipocyte size is observed [72].

The total food intake of rats in LL was mostly unaffected [56,58,76,77], but the distribution changed, causing the gradual loss of rhythmicity corresponding with changes in locomotor activity and neuronal activity in SCN [78]. The total food and water intake was reduced in Long Evans rats, probably due to strain differences or short-term exposure [55]. Despite this, the food efficiency was higher, therefore, rats gained more weight per gram of consumed food, although no change in body weight was noticed. Even though the distribution of food intake was altered, the body weight was not affected in rats [54,55,56,58,76,77], but still, the higher visceral adiposity was found [55], as indicated in Table 1. Only one study reported increased body weight and fat mass in Wistar rats after LL exposure [57].

In male Swiss Webster mice, dLAN increased the daytime food consumption, body mass and fat mass, while the total 24-h food intake was unaffected [62,81,82,83,84,85,86,87,88,99]. Female mice of the same strain exhibited an increased total food intake in dLAN [81], suggesting the existence of sex-dependent differences in response to dLAN. Food and water intake, body mass and fat mass were unaffected by dLAN in diurnal grass rats and nocturnal rats [56,68,71,89,90], although, in contrast to mice, the night-time food intake was reduced in rats [89]. Clearly, the interspecies differences can be observed in the responses of behavior and body weight to dLAN (Table 2). Regardless of lighting conditions, the loss of daily variability in feeding activity is often present, explaining at least partially the increased body weight and fat mass in mice, as well as in rats exposed to LL (Table 1).

In mice, most studies have shown the loss of daily variation in metabolic measures due to LL conditions (Table 1). Insulin sensitivity was diminished during the subjective night, causing the loss of diurnal variation [51,61], which is in line with changes in insulin and glucose levels [51], as well as endogenous glucose production [61]. Glucose tolerance was impaired during the subjective day [62,74]. These data suggest that lower insulin sensitivity during the subjective night can advance the development of insulin resistance under LL. Another contributing factor could be the increased food intake during the daytime when the insulin sensitivity is lower and glucose tolerance is lower. It is known that feeding during an inappropriate phase of the day can misalign peripheral clocks, as well as the expression of metabolic genes and can disrupt energy balance, causing increased body weight gain [100]. CD-1 mice could be more resilient to LL, since, to our knowledge, it is the only strain without changes in glucose levels or glucose tolerance [75], or the potential effects of LL were not detected due to the chosen sampling time-point.

Carbohydrates require less oxygen to be completely oxidized in comparison with fats [101,102], and the relative carbohydrate to fat oxidation ratio can be evaluated by the respiratory exchange ratio (RER) [103]. The higher total 24 h RER and a loss of variability was found in mice exposed to LL, indicating the preferential oxidation of carbohydrates over lipids [61]. Both high and low RER values are associated with obesity in mice [104,105,106]. Obese animals with decreased RER develop insulin resistance and they are probably not able to efficiently utilize carbohydrates and switch to fatty acid oxidation as the main energy source [104]. The lost diurnal pattern can be caused by changes in food intake, since higher RER values are in line with the loss of daily variability in the feeding activity [43]. In an agreement, another study showed that the light phase-fed mice displayed the elevated RER during the inactive phase [100].

On the other hand, the uptake of glucose and fatty acids was decreased by brown adipose tissue during the subjective day in mice after LL exposure, probably due to diminished β-adrenergic signaling, which also caused the suppressed expression of regulatory proteins, phosphorylated AMP-activated protein kinase and phosphorylated cAMP response element-binding protein [72]. AMP-activated protein kinase plays an important role in conserving and producing energy when there is a shortage of adenosine triphosphate (ATP). Therefore, it induces processes generating energy (e.g., fatty acid oxidation) and suppresses ATP-consuming processes (e.g., lipogenesis) [107,108]. The inefficient activity of brown adipose tissue and its lowered nutrient uptake can result in the lipid accumulation in the white adipose tissue [72]. After LL exposure, lost rhythmicity between subjective day and night was described in hepatic lipogenesis enzymes, fatty acid synthase and ATP citrate lyase, due to their elevated expression during the subjective day [51]. All these alterations lead to increased fat mass [51,62,72,74] and ectopic accumulation of lipids observed after exposure to LL [51,74]. Lipogenesis is regulated by transcription factors, sterol regulatory element-binding protein 1c and carbohydrate-responsive element-binding protein [109,110]; however, LL did not change their expression [51], suggesting the different mechanism of regulation. One of the regulatory proteins could be REV-ERBα which is involved in the control of lipid metabolism, especially in the suppression of lipogenesis, thus interconnecting metabolism with circadian clocks [111,112]. Suppressed expression of rev-erbα under LL conditions is in line with increased expression of lipogenic enzymes [51]. However, different results were observed in C57Bl6/J mice exposed to LL, in which hepatic triacylglycerols lost their rhythmicity, probably due to abolished rhythmicity and the suppression of the gene expression of lipogenic enzymes and transcriptional factors [73]. In this study, the rhythms in the expression of hepatic clock genes (clock, cry1, per1 and rorα) were suppressed after exposure to LL, probably due to the altered distribution of food intake, which can efficiently entrain hepatic clocks. The response to LL differs between tissues, since the clock and metabolic genes in the liver were more affected than in the white adipose tissue [73]. These findings suggest the misalignment among peripheral organs, which can advance the development of metabolic diseases. However, the same strain of mice reacted differentially to the longer exposure of LL [74]. Changes occurred mainly during the subjective night and consisted of the increased hepatic accumulation and expression of metabolic genes and proteins involved in the control of lipogenesis and lipid metabolism [74].

Glucose levels were not affected in Sprague–Dawley rats during the subjective day in LL [54,56], but animals were hyperglycemic in the middle of the subjective night [56]. However, another study did not prove these changes since plasma glucose remained rhythmic under LL [76]. On the other hand, insulin lost its diurnal variation without changes in total 24 h mean values [76]. Strain can also play a role in different responses to LL (Table 1), since Wistar rats developed impaired glucose tolerance together with increased fasting glucose levels at the beginning of the subjective day [57] and increased insulin levels [57,58]. These changes in glucose and insulin concentrations increased the homeostatic model assessment of insulin resistance [57], which is used for establishing insulin resistance and β-cell function [113]. Another study did not find alterations in glucose—however, concentrations were measured in the middle of the light phase [58] in comparison to the onset of the light phase, as in the former study [57]. Nevertheless, hepatic glycogen and glycogen phosphorylase were reduced in rats exposed to LL [58], suggesting the decreased storage of glucose. Similar to mice, rats kept in LL probably utilized more carbohydrates, and therefore their deposition was suppressed and the hepatic accumulation of lipids was increased [57,58]. Plasma lipids also lost the daily variation in LL [56], probably due to different distribution of food intake.

Constant light, in combination with other factors, can have even more deteriorating effects on insulin resistance (Table 1), since it was further aggravated in mice fed a high-fat diet while kept in LL [61]. Similar to mice, LL can also deteriorate the symptoms of other diseases in rats, such as diabetes. Impaired β-cell function and their increased apoptosis in rats kept in LL resulted in hyperglycemia and the loss of diurnal variation in insulin levels [76]. The diabetic strain of rats had accelerated development of hyperglycemia and suppressed insulin secretion from β-cells of pancreatic islets, probably due to increased apoptosis and decreased mass of β-cells during the subjective day [54].

Dim light at night was not effective enough to change the daytime plasma glucose levels in mice [83,85], except in 3-week-old males that had reduced glucose levels during the light phase [83]. Glucose tolerance was impaired in adult mice [62,84,86] but not in young and adolescent animals exposed to dLAN, as shown in Table 2 [83]. The positive outcome of the studies was that disturbed glucose tolerance could be reversed by returning animals to dark nights [84] or by restricted feeding during the night [62]. Similarly to results from studies with LL, the RER was increased at the end of the dark phase and beginning of the light phase, suggesting the preferential oxidation of carbohydrates over lipids [82] and probably reflecting changes in food intake. Similarly to LL, the hepatic expression of rev-erbα was suppressed during the light phase in adult mice [85]; thus, the lipid metabolism can also be altered. However, altered expression of rev-erbα was not found in young or adolescent mice kept in dLAN [83]. Dim light at night differently influenced clock gene expression in white adipose tissue and liver, indicating the desynchronization among tissues [85].

In rats, levels of glucose and other metabolites were not affected by dLAN [56,89,90] and, contrary to mice (Table 2), glucose tolerance did not differ compared to control conditions during the light phase [89].

Similar to LL conditions, dLAN can also aggravate developed metabolic diseases in both mice and rats (Table 2). In diabetic mice, dLAN decreased survival and increased number of cases as well as accelerated development of glucose tolerance, insulin tolerance and increased fasting glucose levels [88]. In spontaneously hypertensive rats, the glucose levels were not affected by dLAN, but already high plasma insulin levels were even more aggravated after exposure to dLAN, suggesting that dLAN can deepen insulin resistance at least in this animal model [90]. This conclusion was supported by decreased gene expression of glucose transporter 4 in the left ventricle of the heart in spontaneously hypertensive rats exposed to dLAN. Moreover, the hepatic triacylglycerol content was elevated in rats after 2 but not 5 weeks of dLAN, and this could be explained by up-regulated gene expression of fatty acid synthase. The gene expression of peroxisome proliferator-activated receptor γ, the important transcription factor of genes involved in lipogenesis [114], has the opposite pattern to hepatic lipids [90,115], suggesting compensating effects of this nuclear transcriptional factor in lipid metabolism after 5 weeks of dLAN. The results from LL and dLAN conditions suggest that animals with early symptoms or developed diseases can be more vulnerable to the altered lighting conditions.