If it can be concluded that almost any tissue harbors a circadian machinery, it remains that each organ harbors its own set of molecular elements to coordinate its physiological functions. In a study of Panda and others, the overlap between circadian transcripts in the SCN and the liver (among 650 oscillating transcripts) was compared, and only 28 transcripts were found common to the two tissues (Panda et al. 2002). Few of these 28 genes were core clock genes showing that the control of most circadian genes is highly tissue-specific, each peripheral clock being responsible for a specific output program dependent on the physiological functions.

An illustration of how clock-controlled genes are regulated by different zeitgebers has been shown in adrenalectomized mice, deprived of circulating glucocorticoids. Near 2/3 of rhythmic liver transcripts lost their rhythmicity in absence of adrenal glands, none of which were core clock genes (Oishi et al. 2005). These glucocorticoid-controlled genes were in a large part encoding liver enzymes (such as glucokinase, HMG-CoA reductase, and glucose-6-phosphatase). This proportion was replicated in a pharmacological study, in which DEX resynchronized 57% of liver genes from SCN-lesioned animals (Reddy et al. 2007) likely through a mechanism involving GR and CRY interactions (Lamia et al. 2011). Possibly, the SCN controls core clock rhythms, and secondary entrainment cures such as GCs orchestrate the rhythmicity of genes that regulate physiological functions in a given organ.

As such, the adrenal gland emerges as an important relay station downstream of the SCN to synchronize peripheral clock rhythms. Its endocrine functions are regulated in a circadian fashion (e.g., GCs show a rhythmic secretion pattern). The control of GC circadian secretion by the SCN is known from a long time and evidenced by SCN ablations (Moore and Eichler 1972; Stephan and Zucker 1972). In contrast, the pulsatile (or ultradian—see Chap. 2) pattern of GC secretion is independent of the SCN (Waite et al. 2012). The broad range of actions of GCs, from the regulation of stress or immune responses, as well as cognitive functions, suggests that the circadian actions of GCs might serve as key influencers of physiological rhythms. GCs exert their action via the glucocorticoid receptor (GR), expressed throughout the body including the cochlea (Meltser et al. 2014) and the brain—with the exception of the SCN (Balsalobre et al. 2000). GCs also activate the mineralocorticoid receptor (MR). The circadian secretion of GCs is a complex involvement of autonomic innervation controlled by the SCN, the hypothalamic-pituitary-adrenal (HPA) axis, and local adrenocortical clocks.

Transcript analyses using qRT-PCR showed the circadian expression of core clock genes in the heart, lung, liver, stomach, spleen, and kidney (Yamamoto et al. 2004). Using transgenic rats driving luciferase expression under the control of Per1 promoter (Per1-luc), tissue explant cultures showed oscillations in the SCN, skeletal muscle, liver, lung, pineal, adrenal, and thyroid glands (Yamazaki et al. 2000, 2009). Another rodent model in which the luciferase-coding sequence was knocked-in the Per2 mouse locus (PER2::LUC) allowed to identify rhythmic oscillations in additional organs such as the cornea, the pituitary, and the retrochiasmatic area (RCA) (Yoo et al. 2004). How circadian cycles of luciferase expression are captured is illustrated in Fig. 4.3. As a consequence, numerous physiological functions manifest daily oscillations including detoxification processes by the liver, the kidney, and the small intestine (Gachon et al. 2006); carbohydrate and lipid metabolism by the liver, muscle, and adipose tissue (Lamia et al. 2008; Le Martelot et al. 2009); renal flow and urine production, blood pressure; and the rate of heart beats (Gachon et al. 2004a). Understanding of the physiological outputs from molecular clocks in each organ derives mainly from functional studies using mice lacking Bmal1, either systemically or in a tissue-specific manner, or mice lacking Per1 and/or Per2. For instance, mice lacking Bmal1 display a complete loss of circadian behavior, metabolic abnormalities, and subsequent reduced life span (Kondratov et al. 2006). Bmal1 or Clock mutants develop diabetes due to reduced insulin secretion by the pancreatic islets (Marcheva et al. 2010), a process specific to β-cells that regulates insulin secretion in a circadian manner (Perelis et al. 2015).

Altered eating regimes, sleep and wake cycles, as well as medications can potentially alter the synchronicity of different organs and their harmonization at the body level leading to abnormal physiological functions. Shift workers suffer from the chronic desynchronization of their body with the regular environmental cues and of the SCN and peripheral clocks leading to increased prevalence of symptoms of the metabolic syndrome (Evans and Davidson 2013). Despite the fact that the SCN rapidly synchronizes its rhythms to light cues (e.g., in long-distance travelers changing time zones), their organs require more time to readjust their rhythms (jet lag). Underlying the human relevance, polymorphisms in hPER2 and hCRY2 associate with blood glucose levels. Those in hCLOCK are linked with obesity and hBMAL1 with hypertension and type 2 diabetes (Dibner and Schibler 2015).

The fact that sensitivity to noise also varies at different times of the day was unknown until recently. Awake mice (non-anesthetized) exposed to a noise trauma (6–12 kHz, 1 h, 100 dB SPL) during the night (9 PM) displayed permanent shifts in hearing thresholds measured by auditory brainstem responses (ABRs) 2 weeks after noise trauma, whereas those exposed during daytime (9 AM) recovered to normal hearing thresholds (Meltser et al. 2014). Interestingly, ABRs measured 24 h post-trauma revealed equivalent shifts in hearing thresholds (15–30 dB, from 8 to 24 kHz) in day or night exposed animals. Although distortion products of otoacoustic emissions (DPOAEs) were not performed in this study, cochleograms revealed that no hair cell loss had occurred in both day and night noise groups. These findings suggest that immediate synaptic uncoupling, mainly caused by glutamate excitotoxicity after noise exposure, is similar during the day or during the night. Although levels of glutamate in the cochlea were not measured after day or night noise exposure, no differences were found in the wave I amplitude of the ABR 24 h post-trauma suggesting that animals were exposed to similar levels of sound in this paradigm (unpublished observations). This notion is important since nocturnal animals are more active during the night, whereas they are sleepy during daytime, and the resulting differences in hearing thresholds after day or night noise exposure could be due to varying levels of sound reaching the ear simply because of different behavioral patterns. This potential bias appeared to be negligible since fine and gross locomotor activity (measured by infrared beam breakage) showed no difference during day or night noise exposure (Park et al. 2016).

A potential mechanism to explain the day and night differences in response to noise trauma included neurotrophic signaling in the cochlea (Meltser et al. 2014). Neurotrophins are important regulators of synaptogenesis and synaptic plasticity in the cochlea. Two important neutrophins, namely, neurotrophin-3 (NT-3) and brain-derived neurotrophic factor (BDNF), play an important role during cochlear development and in adult auditory recovery. Mice lacking NT-3 or BDNF, or their respective ligand-specific receptors of tropomyosin receptor kinase (TrkC or TrkB), lack a portion of the auditory neurons (Fritzsch et al. 2004). TrkC appears more important to auditory neuron development since its genetic ablation leads to the loss of 51–66% of auditory neurons, whereas loss of TrkB function causes a loss of only 15–20% of auditory neurons (from the high-frequency region). Their role appear inverted in the vestibular system where TrkB −/− mice show a loss of 56–85% of vestibular neurons whereas TrkC −/− only have 16–29% loss (Fritzsch et al. 2004). The similitude between the neurotrophin mutants and the receptor mutants provides strong evidence of their important contribution for the innervation in the inner ear.

The study from Meltser et al. revealed that the response of Bdnf transcription differed after day or night noise exposure. During the day, noise caused a 32-fold increase in Bdnf mRNA transcript levels, whereas no increase was after night noise. These findings indicate that the incapability of the cochlea to trigger a BDNF-dependent protective response after night noise could underlie the increased vulnerability to night noise exposure. Treatment before night noise exposure with dihydroxyflavone (DHF), a selective agonist of TrkB (Jang et al. 2010), restored the recovery of hearing thresholds to a level comparable to day noise exposure (in absence of drug treatment). Interestingly, night noise exposure caused a twofold reduction of the synaptic ribbons 2 weeks after noise exposure and DHF pretreatment protected synaptic ribbons (Meltser et al. 2014). These findings provide an evidence of the involvement of neurotrophins in the circadian recovery to noise trauma.

These results are somewhat conflicting with genetic studies that evaluated the contribution of NT-3 and BDNF to noise injury. In elegant genetic gain and loss of function studies, mice overexpressing Ntf3 or Bdnf via a tamoxifen-inducible Cre system (Ntf3 ^STOP :Plp1/CreER ^T or Bdnf ^STOP :Plp1/CreER ^T ) showed different responses to noise trauma, whereby only mice overexpressing Ntf3 showed accelerated recovery—not those overexpressing Bdnf (Wan et al. 2014). A potential explanation for the differences between Meltser et al. and Wan et al. is that DHF treatment (that mimics Bdnf actions on TrkB) was acute (single injection) and performed at night, whereas the genetic model of Ntf3 overexpression is comparable to a constitutively active (chronic) TrkC system. The role of Ntf3 in the differential responses to day or night noise exposure remains to be investigated.

The differential response to day or night noise trauma led to the hypothesis that the cochlea could harbor a clock machinery. Using a mouse reporter in which the luciferase gene was fused in frame with the endogenous Period 2 gene (PER2::LUC) (Yoo et al. 2004), real-time bioluminescence from cochlear explants could be monitored as a readout of PER2 expression. PER2::LUC rhythms from the cochlea ex vivo appeared as ample as those from the liver (Fig. 4.4a), and after fading out, these rhythms could be kicked off with dexamethasone treatment, a known synchronizing agent (Meltser et al. 2014). PER2 protein expression originated from hair cells and spiral ganglion neurons (Fig. 4.4b).

The expression of core clock genes was further evidenced by qRT-PCR, thanks to improvements in a method of cochlear RNA extraction, yielding high quantities of RNA of a quality suitable for such molecular analyses (Vikhe Patil et al. 2015). Subsequently, the circadian expression of Per1, Per2, Bmal1, and Rev -Erβα was revealed, demonstrating that the cochlea harbors key components of the core clock machinery (Fig. 4.4c). Presence of additional circadian genes was revealed using a more sensitive methodology, namely, the NanoString nCounter (Cederroth and Canlon, unpublished observations).

Interestingly, noise exposure at night affected to a greater extent than day noise exposure the amplitude of Per1, Per2, Bmal1, and Rev -Erβα mRNA expression, a finding further validated via the monitoring of PER2::LUC rhythms in vitro. In addition, activation of TrkB with DHF modulated PER2::LUC oscillations to a greater extend in the day than in the night (Meltser et al. 2014). How these changes in cochlear rhythms are coupled to the physiological responses to noise trauma is a challenging area of research, but overall these findings illustrate the complex and interdependent links between noise, neurotrophins, and circadian rhythms in the cochlea.

Recent experimental work from our laboratory revealed that the IC, an important relay of the auditory pathway involved in tinnitus, also possesses a molecular clock (Park et al. 2016). PER2::LUC rhythms in vitro were also captured in whole mount or sectioned IC (Fig. 4.5a). Immunohistochemistry revealed that PER2 is homogeneously expressed throughout the IC according to the different subdivisions, namely, the central nucleus of the IC (CIC), dorsal cortex of the IC (DIC), and external cortex of the IC (ECIC) along the rostro-caudal axis (Fig. 4.5b). NanoString nCounter arrays revealed circadian mRNA transcript profiles for Per1, Per2, and Bmal1, among others, and the clock-dependent genes Dbp (Fig. 4.5c). Curiously, the analysis of PER2::LUC rhythms indicates that the IC in the postnatal stage showed more robust circadian oscillations than the adult stage. In postnatal day 4 (P4) ICs, 100% of cultured IC oscillated, and in adult ones (P50), this dropped to 30%. To explain this phenomenon, multiple factors were investigated such as the experimenter, the gender of the animals, whole mount vs sections, the thickness of the sections, and their orientations (coronal, sagittal, horizontal), but none explained this decline in successful oscillations. A potential explanation is that aging influences the synchronicity of the oscillations, which suggests that a greater proportion of ICs might fail to show oscillations in adult stage, or that as an animal ages, components of the expression of core clock machinery could decrease until affecting the whole machinery.