Long-Term Effects of Altered Photoperiod During Pregnancy on Liver Gene Expression of the Progeny

The environment during early life influences the risk of developing pathophysiological processes later; the field recognized as the developmental origins of health and disease (DOHaD) (Calkins et al., 2011; Capra et al., 2013; Hanson and Gluckman, 2014). In particular shows an association with NCDs (Fowden et al., 2006; Marsh et al., 2011) as CVD (Thompson and Trask, 2016).

In modern society, exposure to environmental light at night (e.g., chronic shift work, work at night), disarranging the internal biological clock; thus producing a significant disturbance of the circadian organization of physiology known as chronodisruption (Erren and Reiter, 2009). Circadian rhythms are intrinsic biological oscillations with a 24-h period driven by the circadian timing system, coordinating physiology and behavior with the daily light/dark cycle (Mazzoccoli et al., 2012; Partch et al., 2014; Tarquini and Mazzoccoli, 2017). This system is organized by the central clock, located in the suprachiasmatic nucleus; which is entrained by the light/dark cycle as a dominant signal, in addition to several peripheral clocks located throughout the body. At the cell level, circadian rhythmicity relies on clock gene expression in central and accessory interlocking transcription/translation feedback loops (TTFL) (Mohawk et al., 2013; Curtis et al., 2014; Takahashi, 2016). In turn, these core clock genes promote the expression of downstream genes (CCGs) (Albrecht, 2012; Liu and Chu, 2013). Significant changes in the expression of clock genes can affect physiological processes controlled by the biological clock and have been associated with the development of NCDs (Plano et al., 2017; Touitou et al., 2017).

The misalignment of the maternal circadian system (gestational chronodisruption) impacts fetal health (Serón-Ferré et al., 2012, 2013). This field is of great interest because of the potential long-term effects on the adult offspring’s health and disease status (Amaral et al., 2014; Varcoe et al., 2017; Richter et al., 2018). The available evidence has demonstrated different consequences of chronodisruption on maternal physiology (Gatford et al., 2019). In animal model, the maternal exposure to CPS disrupted the biological clocks in the pregnant female, altering physiological parameters throughout gestation such as the circadian profile of plasma hormones, changes in the liver metabolic gene expression and alterations in the clock gene expression profile (Varcoe et al., 2013; Mendez et al., 2016). Meanwhile, in the adult offspring gestational chronodisruption induced effects such as hyperleptinemia, hyperinsulinemia, impaired glucose tolerance (Varcoe et al., 2011); alterations in the plasma circadian profile of melatonin and corticosterone (Mendez et al., 2016); as well as alteration of adrenal endocrine messengers. In fact, there is strong evidence suggesting that the adrenal gland loses the ability to respond to ACTH (Mendez et al., 2016; Salazar et al., 2018). Given that the endocrine adrenal outputs play a key role in the development and entrainment of the fetal clock in the suprachiasmatic nucleus (Čečmanová et al., 2019), coordinating metabolic responses and acting as time-giving signals to other peripheral circadian oscillators such as the liver (Pezük et al., 2012); long-term alterations of adrenal function can lead to multiple pathophysiological processes.

The liver is a well-described peripheral clock and as such, its physiology is controlled by circadian rhythms, the clock regulates the transcription of CCGs that participate in a wide array of the physiological process in the liver (Reinke and Asher, 2016; Tahara and Shibata, 2016; Zwighaft et al., 2016) and the evidence supports that synchronized liver clockwork machinery develops gradually during ontogenesis (Sumová et al., 2008). On the other hand, the liver is the major site of Pai-1 synthesis, being regulated transcriptionally by endocrine signals of the adrenal gland, which in turn strongly responds to light input (Dimova and Kietzmann, 2008; Aoshima et al., 2014). Also, Pai-1 is a CCG (Haus, 2007) and its expression is upregulated through binding of the CLOCK: BMAL heterodimer to E-box sites of the Pai-1 gene promoter region (Maemura et al., 2000; Schoenhard et al., 2003; Ohkura et al., 2006). Also, the transcription of Pai-1 is promoted by RORα and repressed by REV-ERBα acting on RORE sites (Wang et al., 2006), all of them important members of the clock molecular machinery. Of note, epidemiological studies identify PAI-1 as a risk factor for CVD (Tofler et al., 2016; Jung et al., 2018).

Our hypothesis is that gestational chronodisruption promotes changes in the adult offspring, specifically, alterations of the regulation of molecular machinery of the liver clock genes; which in turn regulate the transcriptional pattern of the Pai-1 in the liver. To test our hypothesis, we used a rat model of gestational chronodisruption. Our specific aims were to investigate the impact of prenatal CPS in the liver of adult male progeny on (1) clock gene transcription patterns; and (2) the fibrinolytic system, particularly in the Pai-1 transcriptional levels.

Modern lifestyles are strongly correlated with misalignment of biological clocks. In this context, circadian disruption act as a sustained environmental factor that leads to conflicts between endogenous biologic clock cycles and the environment (Bass and Lazar, 2016). In the present study, gene expression patterns in the peripheral liver clock and fibrinolytic system were assessed to determine the long-term effects of gestational chronic photoperiod shifting (mimicking repeated night shift work schedules in pregnant women) on the adult offspring.

Hormonal disturbances have also been linked to altered photoperiods. Impaired secretion of corticosterone, aldosterone, and the loss of response to ACTH of the adrenal gland have been observed in progeny gestated under CPS (Mendez et al., 2016; Salazar et al., 2018). Adrenal function is directly regulated by the photoperiod as it is strictly controlled by the master clock residing in the suprachiasmatic nucleus (Aoshima et al., 2014; Plano et al., 2017). Moreover, the adrenal gland is an important oscillator from fetal to postnatal period of life (Torres-Farfan et al., 2011; Roa et al., 2017; Salazar et al., 2018) that synchronizes the rhythmic signaling of glucocorticoids and catecholamines to peripheral clocks such as the liver (Kalsbeek et al., 2012; Pezük et al., 2012). In fact, a significant desynchronization is observed in the liver of adult rats subjected to adrenalectomy (Pezük et al., 2012), strongly suggesting that the adrenal peripheral oscillator plays a crucial role in synchronizing the circadian rhythm of the liver. Previous findings in adult rats gestated under CPS indicate significant desynchronization of daily rhythms of plasma corticosterone, whereas the daily pattern of plasma ACTH was similar in both CPS and control offspring; however, corticosterone response to ACTH was lost in CPS adrenals (Mendez et al., 2016; Salazar et al., 2018). These lines of evidence could be associated with the alteration of the hepatic circadian clock. In the liver, our results demonstrated that transcript levels of Bmal1 and the phase of the daily peak expression of Clock and Nfil3 were significantly affected in adult males gestated in CPS. Interestingly, gestational CPS disrupted daily rhythms in the liver of these clock-genes even after 3 months of exposure to LD photoperiod during the postnatal developing (P90). These results reveal a long-term effect on the expression of the clock genes that changes the phenotype displayed at the adult stage under LD photoperiod in a male gestated in CPS protocol. Importantly, Bmal1 plays a key role in the regulation of the hemostatic function of the liver and also in the progression of the prothrombotic state in aging (Hemmeryckx et al., 2011, 2019).

Alterations of the molecular clock at the accessory loop (RORE site) in the male adult progeny were also evidenced. Specifically, transcript levels of the clock genes Rorα and Rorγ (Rorα/γ) were increased in adult CPS males. The expression of Rorα/γ clock genes has been described to be positively controlled by the BMAL/CLOCK heterodimer. However, as it was described before, the transcript levels of Bmal1 were downregulated in adult males gestated under CPS relative to LD conditions. That can be explained by the fact that posttranslational modifications of the BMAL/CLOCK heterodimer have been shown play a key role in terms to modify its activity independently of mRNA level regulation (Hirayama et al., 2007; Bellet and Sassone-Corsi, 2010; Preußner and Heyd, 2016). Additionally, it has been demonstrated that Rorα/γ expression is controlled by other circadian signals via cAMP response elements (CREs) (O’Neill et al., 2008) that could increase its role under the effects of gestational CPS. In order to determine if increased transcript levels of Rorα/γ may have functional consequences, we evaluated transcript levels of Nfil3 in the liver, because its expression is principally regulated by Rorγ (Ueda et al., 2005; Takeda et al., 2012). The transcription level of Nfil3 was significantly increased in adult males gestated in CPS. Also, the phase (ZT) of the daily peak expression of Nfil3 was significantly affected (3.5 h) in males gestated in CPS (Supplementary Tables 3–5). This finding emphasizes that the effects on the accessory loop of the molecular clock could deregulate CCGs and therefore alter physiological functions. Moreover, endocrine signal as insulin is also important in the regulation of the expression of Nfil3 (Keniry et al., 2014) and as previously mentioned, hyperinsulinemia has been reported in adult offspring gestated in CPS (Varcoe et al., 2011).

A reduced fibrinolytic activity due to an increase in the expression of PAI-1 is a characteristic risk factor for CVD (Mavri et al., 2004; Oishi, 2009). Liver physiology is heavily involved in the regulation of fibrinolytic activity since many of its components, like plasminogen (Cesarman-Maus and Hajjar, 2005; Leebeek and Rijken, 2015) and PAI-1 (Oishi, 2009; Declerck and Gils, 2013) are mainly synthesized by this organ. In adult mice, it has been reported that chronic alteration of the photoperiod was associated with the deregulation of the Pai-1 expression in the liver (Oishi and Ohkura, 2013). On the other hand, previous evidence indicates that clock genes regulate the expression of PAI-1 (Schoenhard et al., 2003; Ohkura et al., 2006; Wang et al., 2006). For instance, a mouse model deficient in Bmal1 (Bmal1^–/–) displayed elevated plasma levels of PAI-1, which were associated with a prothrombotic phenotype (Hemmeryckx et al., 2011; Somanath et al., 2011). Regarding gestational chronodisruption, our results showed increased levels of Pai-1 in the liver of male adult offspring gestated under CPS. This observation is relevant because we previously showed a significant increase in blood pressure in CPS males at P90 (Mendez et al., 2016). Both, increased levels of PAI-1 associated with clock genes deregulation here reported and high pressure described previously are recognized like a CVD risk factors. Some factors that induce Pai-1 gene expression are insulin, glucocorticoids (Irigoyen et al., 1999; Mavri et al., 2004; Dimova and Kietzmann, 2008). Interestingly, factors as hyperinsulinemia and alteration of corticosterone circadian rhythm also described in this animal model (Varcoe et al., 2011; Mendez et al., 2016) have been shown to induce greater expression of Pai-1 in the liver. On the other hand, our data showed a decreased expression of Bmal1 clock gene in the males gestated in CPS. Previous evidence supports the idea that reduced expression of Bmal1 in the liver results in increased expression levels of Pai-1. In particular, the upregulation of PAI-1 is associated with an increase in thrombosis propensity during the aging process (Hemmeryckx et al., 2011, 2019; Somanath et al., 2011). In addition, REV-ERBα is a negative regulator of Pai-1 (Wang et al., 2006) expression by a mechanism involving its competition with RORα, a positive regulator that our results showed that is increased at transcript level and also rhythmic with a phase (ZT) of the daily peak expression in the active phase (dark) in CPS adult progeny. We did not observe differences in Rev-Erbα daily total expression between adult males gestated under CPS and LD conditions, suggesting an inclination to induce Pai-1 expression by RORα rather than repression by REV-ERBα.

The appearance of a marked daily oscillation at the transcript level of the clock gene Rorα in adult CPS but not in LD offspring was another interesting finding. The induction of rhythmic expression of genes that are not oscillatory could be mediated by epigenetic mechanisms, which are involved in the regulation of the transcriptional machinery and reveal that expression of genes that are not rhythmic could be induced (Masri et al., 2014). The induction of the rhythmic expression pattern in Rorα in CPS adult males suggests that epigenetic mechanisms might play a role in the long-term effects observed.

At the protein level, results obtained for daily plasma concentration of PAI-1 did not show significant differences between CPS and LD male offspring. However, daily rhythms were found for PAI-1 plasma protein; displaying a daily peak expression of the protein in the active phase (dark) of the daily cycle that are in agreement with data previously reported in rodents for LD condition (Ohkura et al., 2006). Notably, at P90 of development, the amplitude of the oscillation of plasma concentration in the active phase was increased in adult males which had been gestated under CPS relative to LD offspring (Supplementary Table 6).

It has been described that older humans are more susceptible to thrombosis under septic conditions (Balleisen et al., 1985; Aillaud et al., 1986). In addition, murine models have been demonstrated that the aging process increases the endotoxin-induced thrombosis by a mechanism that involves increased expression of PAI-1 protein in the plasma and at mRNA level in the liver. This tendency is linked to an enhanced inflammatory response in aged mice (Yamamoto et al., 2002). Connected with this previous literature we found a circadian rhythm in the ex vivo coagulation time that was increased at postnatal age of 180 days in CPS gestated male in a process that is age-dependent because this difference was not observed at P60 or P120.

The datasets generated for this study are available on request to the corresponding author.

The animal study was reviewed and approved by Bioethics Commission of the Universidad Austral de Chile (CBA number 267/2016).

PC and JS contributed to the conception, design, and drafting of the work. PC wrote the first draft of the manuscript. PC, BP, CT, NM, GE, and KV worked on animal handling and acquisition of data. PC, JS, and FM analyzed and interpreted the data. CT-F, HR, and PB critically reviewed the manuscript for important intellectual content. All authors contributed to the manuscript revision, and read and approved the submitted version.

The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.

This work was supported by Grant N°1150789 from the Fondo Nacional de Desarrollo Científico y Tecnológico (FONDECYT), Chile, and ANILLO ACT-1116. PC was supported by Fellowship N°21171387 from the Comisión Nacional de Investigación Científica y Tecnológica (CONICYT), Chile.

The Supplementary Material for this article can be found online at: https://www.frontiersin.org/articles/10.3389/fphys.2019.01377/full#supplementary-material↗