Jean-Michel Fustin

RNA-Methylation-Dependent RNA Processing Controls the Speed of the Circadian Clock

The eukaryotic biological clock involves a negative transcription-translation feedback loop in which clock genes regulate their own transcription and that of output genes of metabolic significance. While around 10% of the liver transcriptome is rhythmic, only about a fifth is driven by de novo transcription, indicating mRNA processing is a major circadian component. Here, we report that inhibition of transmethylation reactions elongates the circadian period. RNA sequencing then reveals methylation inhibition causes widespread changes in the transcription of the RNA processing machinery, associated with m(6)A-RNA methylation. We identify m(6)A sites on many clock gene transcripts and show that specific inhibition of m(6)A methylation by silencing of the m(6)A methylase Mettl3 is sufficient to elicit circadian period elongation and RNA processing delay. Analysis of the circadian nucleocytoplasmic distribution of clock genes Per2 and Arntl then revealed an uncoupling between steady-state pre-mRNA and cytoplasmic mRNA rhythms when m(6)A methylation is inhibited.

Mice Genetically Deficient in Vasopressin V1a and V1b Receptors Are Resistant to Jet Lag

Resetting the Circadian Clock Fatigue and other symptoms of jet lag arise when the bodys internal circadian clock is out of sync with environmental light-dark cycles. Studying genetically modified mice lacking two receptors for the peptide hormone vasopressin under experimental conditions simulating jet lag, Yamaguchi et al. (p. 85; see the Perspective by Hastings) concluded that vasopressin signaling in the suprachiasmatic nucleus (SCN)—a region of the brain known to control circadian rhythms—impedes adjustment to the environmental clock. Infusion of vasopressin receptor antagonists directly into the SCN of wild-type mice accelerated their recovery from jet lag, suggesting that this pathway may merit further investigation as a pharmacological target for treating jet lag. In mice, the pace of recovery from jet lag is partly determined by vasopressin signaling in a certain region of the brain. [Also see Perspective by Hastings] Jet-lag symptoms arise from temporal misalignment between the internal circadian clock and external solar time. We found that circadian rhythms of behavior (locomotor activity), clock gene expression, and body temperature immediately reentrained to phase-shifted light-dark cycles in mice lacking vasopressin receptors V1a and V1b (V1a–/–V1b–/–). Nevertheless, the behavior of V1a–/–V1b–/– mice was still coupled to the internal clock, which oscillated normally under standard conditions. Experiments with suprachiasmatic nucleus (SCN) slices in culture suggested that interneuronal communication mediated by V1a and V1b confers on the SCN an intrinsic resistance to external perturbation. Pharmacological blockade of V1a and V1b in the SCN of wild-type mice resulted in accelerated recovery from jet lag, which highlights the potential of vasopressin signaling as a therapeutic target for management of circadian rhythm misalignment, such as jet lag and shift work.

Circadian regulation of intracellular G-protein signalling mediates intercellular synchrony and rhythmicity in the suprachiasmatic nucleus

Synchronous oscillations of thousands of cellular clocks in the suprachiasmatic nucleus (SCN), the circadian centre, are coordinated by precisely timed cell–cell communication, the principle of which is largely unknown. Here we show that the amount of RGS16 (regulator of G protein signalling 16), a protein known to inactivate Gαi, increases at a selective circadian time to allow time-dependent activation of intracellular cyclic AMP signalling in the SCN. Gene ablation of Rgs16 leads to the loss of circadian production of cAMP and as a result lengthens circadian period of behavioural rhythm. The temporally precise regulation of the cAMP signal by clock-controlled RGS16 is needed for the dorsomedial SCN to maintain a normal phase-relationship to the ventrolateral SCN. Thus, RGS16-dependent temporal regulation of intracellular G protein signalling coordinates the intercellular synchrony of SCN pacemaker neurons and thereby defines the 24 h rhythm in behaviour.

Rhythmic Nucleotide Synthesis in the Liver: Temporal Segregation of Metabolites

The synthesis of nucleotides in the body is centrally controlled by the liver, via salvage or de novo synthesis. We reveal a pervasive circadian influence on hepatic nucleotide metabolism, from rhythmic gene expression of rate-limiting enzymes to oscillating nucleotide metabolome in wild-type (WT) mice. Genetic disruption of the hepatic clock leads to aberrant expression of these enzymes, together with anomalous nucleotide rhythms, such as constant low levels of ATP with an excess in uric acid, the degradation product of purines. These results clearly demonstrate that the hepatic circadian clock orchestrates nucleotide synthesis and degradation. This circadian metabolome timetable, obtained using state-of-the-art capillary electrophoresis time-of-flight mass spectrometry, will guide further investigations in nucleotide metabolism-related disorders.

Isoform-Specific Monoclonal Antibodies Against 3β-Hydroxysteroid Dehydrogenase/Isomerase Family Provide Markers for Subclassification of Human Primary Aldosteronism

CONTEXT Therapeutic management of primary aldosteronism requires accurate differentiation between aldosterone-producing adenoma (APA) and idiopathic hyperaldosteronism (IHA). However, little is known about the molecular features that delineate the difference between APA and IHA. Two different isoforms of 3β-hydroxysteroid dehydrogenase (HSD3B1 and HSD3B2) are thought to be expressed in the human adrenal gland, but the lack of isoform-specific antibody has so far hampered mapping of these isoforms in APA and IHA. OBJECTIVES The aim of our study is to develop and characterize isoform-specific monoclonal antibodies against HSD3B1 and HSD3B2. Using these antibodies, we determined for the first time the immunolocalization of HSD3B1 and HSD3B2 in normal human adrenal cortex as well as in adrenal specimens from APA and IHA. RESULTS Immunohistochemical analysis with isoform-specific antibodies revealed zone-specific expression of HSD3B1 and HSD3B2 in the adrenal cortex. HSD3B1 immunoreactivities were essentially confined to the zona glomerulosa (ZG), in which aldosterone is produced. In contrast, HSD3B2 was not confined to the ZG but was found across the zona fasciculata, which is where cortisol is produced. Moreover, immunohistopathological analysis of primary aldosteronism revealed a previously uncharacterized difference between APA and IHA. Notably, hyperplasia of ZG seen for IHA was accompanied by a robust expression of ZG isoform HSD3B1. In contrast, tumor cells in APA were not immunopositive to HSD3B1. Rather, a strong and dominant expression of HSD3B2 characterized APA. Moreover, perhaps due to compensatory responses to excess aldosterone, APA had an adjacent ZG whose immunoreactivities to HSD3B1 and HSD3B2 were profoundly reduced. CONCLUSIONS Isoform-specific monoclonal antibodies against HSD3B1 and HSD3B2 may be of great value for immunohistochemical differentiation between APA and IHA.

Circadian clock signals in the adrenal cortex

Circadian secretion of steroid hormones by the adrenal cortex is required to maintain whole body homeostasis and to adequately respond to or anticipate environmental changes. The richly vascularized zona glomerulosa (ZG) cells in the pericapsular region regulate osmotic balance of body fluid by secreting mineralocorticoids responding to circulating bioactive substances, and more medially located zona fasciculata (ZF) cells regulate energy supply and consumption by secreting glucocorticoids under neuronal and hormonal regulation. The circadian clock regulates both steroidogenic pathways: the clock within the ZG regulates mineralocorticoid production via controlling rate-limiting synthetic enzymes, and the ZF secretes glucocorticoid hormones into the systemic circulation under the control of central clock in the suprachiasmatic nucleus. A functional biological clock at the systemic and cellular levels is therefore necessary for steroid synthesis and secretion.

Accurate Determination of S-Phase Fraction in Proliferative Cells by Dual Fluorescence and Peroxidase Immunohistochemistry with 5-Bromo-2′-Deoxyuridine (BrdU) and Ki67 Antibodies

To ensure the maintenance of tissues in mammals, cell loss must be balanced with cell production, the proliferative activity being different from tissue to tissue. In this article, the authors propose a new method for the quantification of the proliferative activity, defined as the S-phase fraction of actively cycling cells, by dual labeling with fluorescence and peroxidase immunohistochemistry using BrdU (marker of S-phase) and Ki67 antibodies (marker of G1-, S-, G2-, and M-phases) after a one-step antigen retrieval. In the generative cell zones of fundic and pyloric glandular stomachs, where the majority of cells were cycling, the authors measured a proliferative activity of 31%. In the epithelium of the forestomach and the skin, where cycling cells are intermingled with G0 and differentiated cells, proliferative activities were 21% and 13%, respectively. In the adrenal cortex, in which cycling cells were sparsely distributed, the proliferative activity reached 32%. During the regenerative process in the skin after a lesion, the proliferative activity increased in proximity to the wound. The present one-step dual-labeling method has revealed that the proliferative activity is different between tissues and depends on the physiological or pathological state.

Activation of AMPA Receptors in the Suprachiasmatic Nucleus Phase-Shifts the Mouse Circadian Clock In Vivo and In Vitro

The glutamatergic neurotransmission in the suprachiasmatic nucleus (SCN) plays a central role in the entrainment of the circadian rhythms to environmental light-dark cycles. Although the glutamatergic effect operating via NMDAR (N-methyl D-aspartate receptor) is well elucidated, much less is known about a role of AMPAR (α-amino-3-hydroxy-5-methylisoxazole-4-propionic acid receptor) in circadian entrainment. Here we show that, in the mouse SCN, GluR2 and GluR4 AMPAR subtypes are abundantly expressed in the retinorecipient area. In vivo microinjection of AMPA in the SCN during the early subjective night phase-delays the behavioral rhythm. In the organotypic SCN slice culture, AMPA application induces phase-dependent phase-shifts of core-clock gene transcription rhythms. These data demonstrate that activation of AMPAR is capable of phase-shifting the circadian clock both in vivo and in vitro, and are consistent with the hypothesis that activation of AMPA receptors is a critical step in the transmission of photic information to the SCN.

Hypertension Due to Loss of Clock: Novel Insight From the Molecular Analysis of Cry1/Cry2–Deleted Mice

In our consumer-oriented society, in which productivity requires around-the-clock activity and demanding shift work, the biologic system that regulates our internal rhythms is being compromised. Poor sleep patterns and hectic lifestyle are detrimental to harmonious physiological and metabolic body systems, with severe impact on public health. Over a trillion peripheral cellular clocks throughout the body, supervised by the master clock located in the hypothalamic suprachiasmatic nucleus, govern most aspects of physiology and behavior. To exemplify the importance of the biologic clock for health, we have recently demonstrated that mice that are arrhythmic because of the deletion of Cry1 and Cry2 clock genes suffer from salt-sensitive hypertension. In these mice, a novel 3β-hydroxyl-steroid dehydrogenase (3β–Hsd) gene under clock control is severely overexpressed specifically in aldosterone-producing cells in the adrenal cortex, leading to hyperaldosteronism and ultimately to salt-sensitive hypertension. The human homologue of this aldosterone-producing, cell-specific enzyme was also characterized and represents a new possibility in the pathogenesis of hypertension.

Transportin 1 in the mouse brain: Appearance in regions of neurogenesis, cerebrospinal fluid production/sensing, and circadian clock

Transportin1 (Tnpo1) is a carrier protein belonging to the importin‐β family, which transports substrates between the cytoplasm and the nucleus. To gain insight into the role of Tnpo1 gene in the brain, we investigated the localization of Tnpo1‐, Tnpo2‐, and Tnpo3‐expressing cells by in situ hybridization histochemistry. Tnpo1 mRNA‐positive cells were distributed throughout the brain from the olfactory bulb to the medulla oblongata. The cells in the subventricular zone of the lateral ventricle, where neurogenesis occurs even in the adult, and its progeny neurons in the granular cells of the olfactory bulb and the islands of Calleja were strongly labeled. It is also noteworthy that cerebrospinal fluid (CSF)‐generating epithelial cells in the choroid plexus and CSF‐contacting and ‐sensing circumventricular organs, including organum vasculosum lamina terminalis, subfornical organ, and subcommissural organ, expressed high amounts of Tnpo1. The strongest signals were found in the suprachiasmatic nucleus (SCN), where the biological clock resides, which prompted us to examine the circadian characteristics of Tnpo1. Under constant‐dark conditions, the circadian expression profiles of Tnpo1 mRNA in the SCN showed a peak in the subjective night and a trough in the subjective day. Tnpo2 and Tnpo3 showed similar patterns of expression, except in the choroids plexus, the subventricular zone, and the SCN, where the expression was notably weaker. These findings suggest that Tnpo1 is involved in a variety of functions in the adult brain, including neurogenesis, CSF production and sensing, and circadian rhythms. J. Comp. Neurol. 519:1770‐1780, 2011.