Your search keyword '"Hilaire G"' showing total 12 results

1. The H3K27 demethylase JMJD3 is required for maintenance of the embryonic respiratory neuronal network, neonatal breathing, and survival.

Author

Burgold T, Voituron N, Caganova M, Tripathi PP, Menuet C, Tusi BK, Spreafico F, Bévengut M, Gestreau C, Buontempo S, Simeone A, Kruidenier L, Natoli G, Casola S, Hilaire G, and Testa G

Subjects

Animals, Cell Line, Embryo, Mammalian metabolism, Embryonic Stem Cells cytology, Embryonic Stem Cells metabolism, Histones metabolism, Jumonji Domain-Containing Histone Demethylases deficiency, Jumonji Domain-Containing Histone Demethylases genetics, Mice, Mice, Inbred C57BL, Mice, Knockout, Perinatal Mortality, Respiratory Burst physiology, Respiratory Insufficiency pathology, Somatostatin metabolism, Jumonji Domain-Containing Histone Demethylases metabolism, Neurons metabolism

Abstract

JMJD3 (KDM6B) antagonizes Polycomb silencing by demethylating lysine 27 on histone H3. The interplay of methyltransferases and demethylases at this residue is thought to underlie critical cell fate transitions, and the dynamics of H3K27me3 during neurogenesis posited for JMJD3 a critical role in the acquisition of neural fate. Despite evidence of its involvement in early neural commitment, however, its role in the emergence and maturation of the mammalian CNS remains unknown. Here, we inactivated Jmjd3 in the mouse and found that its loss causes perinatal lethality with the complete and selective disruption of the pre-Bötzinger complex (PBC), the pacemaker of the respiratory rhythm generator. Through genetic and electrophysiological approaches, we show that the enzymatic activity of JMJD3 is selectively required for the maintenance of the PBC and controls critical regulators of PBC activity, uncovering an unanticipated role of this enzyme in the late structuring and function of neuronal networks., (Copyright © 2012 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2012

2. Possible modulation of the mouse respiratory rhythm generator by A1/C1 neurones.

Author

Zanella S, Roux JC, Viemari JC, and Hilaire G

Subjects

Adrenergic alpha-2 Receptor Antagonists, Adrenergic alpha-Antagonists pharmacology, Age Factors, Analysis of Variance, Animals, Animals, Newborn, Catecholamines physiology, Cervical Vertebrae, In Vitro Techniques, Medulla Oblongata physiology, Mice, Neural Pathways cytology, Neural Pathways physiology, Neurons cytology, Respiratory Center cytology, Respiratory Center physiology, Spinal Cord cytology, Spinal Cord physiology, Yohimbine pharmacology, Medulla Oblongata cytology, Neurons physiology, Periodicity, Receptors, Adrenergic, alpha-2 physiology, Respiration

Abstract

Although compelling evidence exist that the respiratory rhythm generator is modulated by endogenous noradrenaline released from pontine A5 and A6 neurones, we examined whether medullary catecholaminergic neurones also participated in respiratory rhythm modulation. Experiments were performed in neonatal (postnatal days 0-6, P0-P6) and young mice (P14-P18) using "en bloc" medullary preparations (pons resected) and transverse medullary slices. In "en bloc" preparations, blockade of medullary alpha2 adrenoceptors with yohimbine and activation of catecholamine biosynthesis with L-tyrosine significantly depresses and facilitates the respiratory rhythm, respectively. In slices from neonatal and young mice, blockade of medullary alpha2 adrenoceptors also depressed the respiratory rhythm. Yohimbine local applications and lesion-ablation experiments of the dorsal medulla revealed implication of A1/C1 neurones in the yohimbine depressing effect. Although the mechanisms responsible for the yohimbine-depressing effect remain to be elucidated, our in vitro results in neonatal and young mice suggest that endogenous catecholamines released from A1/C1 neurones participate in respiratory rhythm modulation via medullary alpha2 adrenoceptors.

Published

2006

3. Ret deficiency in mice impairs the development of A5 and A6 neurons and the functional maturation of the respiratory rhythm.

Author

Viemari JC, Maussion G, Bévengut M, Burnet H, Pequignot JM, Népote V, Pachnis V, Simonneau M, and Hilaire G

Subjects

Animals, Biogenic Monoamines metabolism, Brain Stem cytology, Brain Stem growth & development, Female, Genotype, Homeodomain Proteins genetics, Immunohistochemistry, In Situ Hybridization, Mice, Mice, Inbred C57BL, Mice, Knockout, Nerve Net embryology, Nerve Net growth & development, Nerve Net physiology, Norepinephrine physiology, Pons metabolism, Pregnancy, Proto-Oncogene Proteins c-ret biosynthesis, Proto-Oncogene Proteins c-ret genetics, RNA, Messenger biosynthesis, RNA, Messenger genetics, Respiratory System embryology, Rhombencephalon enzymology, Rhombencephalon growth & development, Neurons physiology, Proto-Oncogene Proteins c-ret physiology, Respiratory Mechanics physiology, Respiratory System growth & development, Respiratory System innervation

Abstract

Although a normal respiratory rhythm is vital at birth, little is known about the genetic factors controlling the prenatal maturation of the respiratory network in mammals. In Phox2a mutant mice, which do not express A6 neurons, we previously hypothesized that the release of endogenous norepinephrine by A6 neurons is required for a normal respiratory rhythm to occur at birth. Here we investigated the role of the Ret gene, which encodes a transmembrane tyrosine kinase receptor, in the maturation of norepinephrine and respiratory systems. As Ret-null mutants (Ret-/-) did not survive after birth, our experiments were performed in wild-type (wt) and Ret-/- fetuses exteriorized from pregnant heterozygous mice at gestational day 18. First, in wt fetuses, quantitative in situ hybridization revealed high levels of Ret transcripts in the pontine A5 and A6 areas. Second, in Ret-/- fetuses, high-pressure liquid chromatography showed significantly reduced norepinephrine contents in the pons but not the medulla. Third, tyrosine hydroxylase immunocytochemistry revealed a significantly reduced number of pontine A5 and A6 neurons but not medullary norepinephrine neurons in Ret-/- fetuses. Finally, electrophysiological and pharmacological experiments performed on brainstem 'en bloc' preparations demonstrated impaired resting respiratory activity and abnormal responses to central hypoxia and norepinephrine application in Ret-/- fetuses. To conclude, our results show that Ret gene contributes to the prenatal maturation of A6 and A5 neurons and respiratory system. They support the hypothesis that the normal maturation of the respiratory network requires afferent activity corresponding to the A6 excitatory and A5 inhibitory input balance.

Published

2005

4. Modulation of the respiratory rhythm generator by the pontine noradrenergic A5 and A6 groups in rodents.

Author

Hilaire G, Viemari JC, Coulon P, Simonneau M, and Bévengut M

Subjects

Animals, Animals, Newborn, Mice, Mice, Mutant Strains, Models, Neurological, Neurons classification, Pons cytology, Pons growth & development, Rats, Receptors, Adrenergic physiology, Respiratory Center drug effects, Respiratory Center physiology, Rodentia physiology, Neurons physiology, Norepinephrine physiology, Periodicity, Pons physiology, Respiration

Abstract

The aim of the present review is to summarise available studies dealing with the respiratory control exerted by pontine noradrenergic neurones in neonatal and adult mammals. During the perinatal period, in vitro studies on neonatal rodents have shown that A5 and A6 neurones exert opposite modulations onto the respiratory rhythm generator, inhibitory and facilitatory respectively, that the anatomical support for these modulations already exists at birth, and that genetically induced alterations in the formation of A5 and A6 neurones affect the maturation of the respiratory rhythm generator, leading to lethal respiratory deficits at birth. The A5-A6 modulation of the respiratory rhythm generator is not transient, occurring solely during the perinatal period but it persists throughout life: A5 and A6 neurones display a respiratory-related activity, receive inputs from and send information to the medullary respiratory centres and contribute to the adaptation of adult breathing to physiological needs.

Published

2004

5. Phox2a gene, A6 neurons, and noradrenaline are essential for development of normal respiratory rhythm in mice.

Author

Viemari JC, Bévengut M, Burnet H, Coulon P, Pequignot JM, Tiveron MC, and Hilaire G

Subjects

Animals, Animals, Newborn, Dyspnea genetics, Dyspnea physiopathology, Fetus, Medulla Oblongata embryology, Medulla Oblongata growth & development, Medulla Oblongata physiology, Mice, Mice, Inbred C57BL, Mice, Mutant Strains, Nerve Net embryology, Nerve Net growth & development, Nerve Net physiology, Nerve Tissue Proteins, Neurons metabolism, Norepinephrine metabolism, Plethysmography, Pons metabolism, Respiratory Center embryology, Respiratory Center growth & development, Homeodomain Proteins genetics, Neurons physiology, Norepinephrine physiology, Periodicity, Respiration genetics, Respiratory Center physiology, Transcription Factors genetics

Abstract

Although respiration is vital to the survival of all mammals from the moment of birth, little is known about the genetic factors controlling the prenatal maturation of this physiological process. Here we investigated the role of the Phox2a gene that encodes for a homeodomain protein involved in the generation of noradrenergic A6 neurons in the maturation of the respiratory network. First, comparisons of the respiratory activity of fetuses delivered surgically from heterozygous Phox2a pregnant mice on gestational day 18 showed that the mutants had impaired in vivo ventilation, in vitro respiratory-like activity, and in vitro respiratory responses to central hypoxia and noradrenaline. Second, pharmacological studies on wild-type neonates showed that endogenous noradrenaline released from pontine A6 neurons potentiates rhythmic respiratory activity via alpha1 medullary adrenoceptors. Third, transynaptic tracing experiments in which rabies virus was injected into the diaphragm confirmed that A6 neurons were connected to the neonatal respiratory network. Fourth, blocking the alpha1 adrenoceptors in wild-type dams during late gestation with daily injections of the alpha1 adrenoceptor antagonist prazosin induced in vivo and in vitro neonatal respiratory deficits similar to those observed in Phox2a mutants. These results suggest that noradrenaline, A6 neurons, and the Phox2a gene, which is crucial for the generation of A6 neurons, are essential for development of normal respiratory rhythm in neonatal mice. Metabolic noradrenaline disorders occurring during gestation therefore may induce neonatal respiratory deficits, in agreement with the catecholamine anomalies reported in victims of sudden infant death syndrome.

Published

2004

6. MafB deficiency causes defective respiratory rhythmogenesis and fatal central apnea at birth.

Author

Blanchi B, Kelly LM, Viemari JC, Lafon I, Burnet H, Bévengut M, Tillmanns S, Daniel L, Graf T, Hilaire G, and Sieweke MH

Subjects

Action Potentials drug effects, Action Potentials physiology, Afferent Pathways drug effects, Afferent Pathways embryology, Afferent Pathways metabolism, Animals, Animals, Newborn, Biomarkers, DNA-Binding Proteins genetics, Disease Models, Animal, Electric Stimulation, Fetus, Homeodomain Proteins metabolism, MafB Transcription Factor, Mice, Mice, Knockout, Nerve Net drug effects, Nerve Net embryology, Nerve Net metabolism, Neurons drug effects, Neurons pathology, Organ Culture Techniques, Periodicity, Receptors, Neurokinin-1 agonists, Receptors, Neurokinin-1 metabolism, Respiration drug effects, Respiratory Center abnormalities, Respiratory Center pathology, Sleep Apnea, Central metabolism, Sleep Apnea, Central physiopathology, Substance P metabolism, Substance P pharmacology, Transcription Factors genetics, Transcription Factors metabolism, Avian Proteins, DNA-Binding Proteins deficiency, Neurons metabolism, Oncogene Proteins, Respiration genetics, Respiratory Center physiopathology, Sleep Apnea, Central genetics, Transcription Factors deficiency

Abstract

The genetic basis for the development of brainstem neurons that generate respiratory rhythm is unknown. Here we show that mice deficient for the transcription factor MafB die from central apnea at birth and are defective for respiratory rhythmogenesis in vitro. MafB is expressed in a subpopulation of neurons in the preBötzinger complex (preBötC), a putative principal site of rhythmogenesis. Brainstems from Mafb(-/-) mice are insensitive to preBötC electrolytic lesion or stimulation and modulation of rhythmogenesis by hypoxia or peptidergic input. Furthermore, in Mafb(-/-) mice the preBötC, but not major neuromodulatory groups, presents severe anatomical defects with loss of cellularity. Our results show an essential role of MafB in central respiratory control, possibly involving the specification of rhythmogenic preBötC neurons.

Published

2003

7. Identification of central nervous system neurons innervating the respiratory muscles of the mouse: a transneuronal tracing study.

Author

Gaytán SP, Pásaro R, Coulon P, Bevengut M, and Hilaire G

Subjects

Animals, Brain Mapping, Central Nervous System cytology, Interneurons physiology, Mice, Mice, Inbred Strains, Motor Neurons physiology, Nerve Net physiology, Rabies virus, Synaptic Transmission, Central Nervous System physiology, Neurons physiology, Respiratory Muscles innervation

Abstract

In recent years, the central control of breathing in mammals has been the subject of numerous studies. The aim of the present one was to characterize the neuronal network projecting to the main respiratory motoneurons, in adult mice. To this end, the morphology and location of the respiratory motoneurons and their sequential connections with other neurons were revealed using a transneuronal tracing technique by means of the rabies virus infection. The injections of the rabies virus in the respiratory muscles resulted in labeling the motoneurons and their serially connected interneurons at multiple levels of the mouse central nervous system: spinal cord, pons and medulla, cerebellum, mesencephalon, diencephalon, and telencephalon. Most of these labeled areas have been previously identified in the control of cardiorespiratory regulation, as well as in other autonomic functions. These anatomical data provide support for the integration of respiratory-related activities in complex behavioral responses. Furthermore, these data suggest similarities in the evolution of central respiratory networks in mammals.

Published

2002

8. Dorsal and ventral respiratory groups of neurons in the medulla of the rat.

Author

Saether K, Hilaire G, and Monteau R

Subjects

Action Potentials, Animals, Functional Laterality physiology, Laryngeal Nerves physiology, Lung innervation, Lung physiology, Medulla Oblongata cytology, Neurons classification, Phrenic Nerve physiology, Rats, Rats, Inbred Strains, Spinal Cord physiology, Medulla Oblongata physiology, Neurons physiology, Respiratory Center physiology

Abstract

The aim of the present work was to identify and localize in rat the medullary neurons involved in respiration. Neural activity was recorded in ketamine-anesthetized, paralyzed and artificially ventilated rats. Active sites were marked by electrocoagulation. Neurons firing in relation to phrenic nerve activity were located between 0.5 and 2 mm lateral to the midline, extending from 0.5 mm caudal to 2 mm rostral to the posterior end of the area postrema. Two groups of respiratory neurons were found: a dorsal group located ventrolateral to the tractus solitarius and a ventral group located in the ventrolateral reticular formation close to the nucleus ambiguus. Neurons were classified as bulbospinal or laryngeal if stimulation of the spinal cord or the vagus nerve, respectively, elicited antidromic action potentials, or as propriobulbar if they were not activated. Neurons firing synchronously with lung inflation were termed pump (P) cells. The dorsal respiratory group includes inspiratory (I) bulbospinal and propriobulbar neurons, P cells, but few expiratory (E) propriobulbar neurons. The ventral respiratory group includes bulbospinal, laryngeal and propriobulbar I and E neurons. Laryngeal motoneurons project ipsilaterally whereas bulbospinal neurons project contralaterally. Cross-correlations between inspiratory bulbospinal neuronal activity and phrenic discharge suggest that bulbospinal I neurons of dorsal and ventral groups project monosynaptically to contralateral phrenic motoneurons. These results indicate a similarity of the medullary respiratory centers of rats and cats, suggesting that rats may profitably be used in studies of respiratory rhythmogenesis.

Published

1987

9. A cross-correlation study of interactions among respiratory neurons of dorsal, ventral and retrofacial groups in cat medulla.

Author

Hilaire G, Monteau R, and Bianchi AL

Subjects

Action Potentials, Afferent Pathways physiology, Animals, Cardiovascular Physiological Phenomena, Cats, Decerebrate State, Electric Conductivity, Electric Stimulation, Female, Male, Microelectrodes, Spinal Cord physiology, Vagus Nerve physiology, Medulla Oblongata physiology, Neurons physiology, Respiration

Abstract

In anesthetized or decerebrated cats, extracellular activities of pairs of respiratory neurons located in the regions of the dorsal (DRN), ventral (VRN) and retrofacial (RFN) medullary respiratory nuclei were recorded using two separate microelectrodes. Neurons were classified as bulbospinal or laryngeal if stimulation of the spinal cord or vagus nerve elicited antidromic action potentials, or as propriobulbar if they were not antidromically activated. Of 163 pairs of single unit activities, either inspiratory (143 pairs) or expiratory (20 pairs), cross-correlation analyses indicated that 23% had short latency peaks, either broad (12%) or sharp (1%) in their cross-correlograms, 3% had short latency troughs and 74% had flat cross-correlograms. When the two neurons were located in the DRN (68 pairs) the probability of obtaining a positive cross-correlogram was high for inspiratory bulbospinal neurons, indicating shared inputs and excitatory relationships. When one neuron of the pair was located in the RFN and the other in either the DRN or VRN (95 pairs), cross-correlation analysis revealed shared inputs, excitatory and inhibitory relationships. Among expiratory neurons interactions were only inhibitory with a more frequent incidence (3/20) than between inspiratory neurons (2/143). Our results indicate that: short time scale synchrony due to shared inputs (broad peaks) are largely distributed in the respiratory neuronal network and operate over long distance (i.e. RFN, caudal medulla); excitatory coupling may exist between remote neurons but is more frequent between inspiratory bulbospinal neurons located in the DRN.

Published

1984

10. [Comparative study of the activity of medullary respiratory neurones during polypnea triggered by hypothalamic electrical stimulation or by hypothalamic heating (author's transl)].

Author

Monteau R and Hilaire G

Subjects

Animals, Cats, Electric Stimulation, Hot Temperature, Physical Stimulation, Recruitment, Neurophysiological, Hypothalamus physiology, Neurons physiology, Respiration, Respiratory Center physiology

Abstract

We have compared in "encéphale isolé bas" cats the activity of medullary respiratory neurones during polypnea triggered by electrical stimulation (PSt) or by heating (PTh) of the hypothalamus. The medullary respiratory neurones are classified according to:--their anatomical localization (dorsal or ventral respiratory nucleus);--their axon destination (spinal : bulbo-spinal respiratory neurones; non spinal : propriobulbar neurones);--their discharge pattern;--the correlation coefficient between the number of spikes delivered in each burst and the duration of the corresponding respiratory phase (HILAIRE et MONTEAU, 1975). 1. During the two polypneas (PSt and PTh), we observe:--a reduction of activity that preferentially affects some groups of neurones (propriobulbar neurones) (fig. 3);--an inversion of the discharge firing rate, which increases during inspiration in normopnea and decreases in polypnea (fig. 1; fig. 6);--a decrease of the maximal discharge firing rate for the neurones of different groups (Table V). 2. However, two differences exist : during PSt, the maximal discharge firing rate increases for the inspiratory bulbo-spinal neurones of the dorsal nucleus and for the early-burster inspiratory propriobulbar neurones. The recruitment of the bulbo-spinal inspiratory neurones seems to be different; they are activated earlier during PSt than during PTh (Table VI). 3. Some of the observed differences are probably quantitative and we think that polypnea triggered by hypothalamic electrical stimulation is a good model for thermal polypnea.

Published

1978

11. [Discharge pattern of medullary respiratory neurones during thermal polypnea (author's transl)].

Author

Monteau R and Hilaire G

Subjects

Action Potentials, Animals, Axons physiology, Cats, Hot Temperature, Hypothalamus, Anterior, Motor Neurons physiology, Neural Conduction, Periodicity, Phrenic Nerve physiology, Spinal Cord physiology, Time Factors, Neurons physiology, Respiration, Respiratory Center physiology

Abstract

1 In "encephale isole" cats with a spinal section in C7, we have recorded the activity of 108 medullary inspiratory or expiratory neurones during normopnea or polypnea induced by local warming of the anterior hypothalamic region. The neurones were grouped according to their axon destination, their discharge pattern, and the correlation level between their unit activity and the phrenic neurogram. 2 In polypnea, 71% of inspiratory neurones remain active. Their firing rates, which increase during inspiratory discharges in normopnea, decrease during inspiratory discharges in polypnea. However, this inversion of discharge pattern is less marked than with phrenic motoneurones. 3 The reduction of activity in polypnea preferentially strikes certain types of neurones. While bulbo-spinal inspiratory neurones all remain active, the propriobulbar inspiratory neurones can be grouped into those which remain active and whose activity is well correlated with the phrenic neurogram, and those which become silent and showing a poor correlation. As a general rule, activity in polypnea and correlation (in normopnea) go together. 4 In polypnea, 56% of expiratory neurones cease discharging. This activity decrease applies to bulbo-spinal expiratory neurones (5 out of 14) and to propriobulbar expiratory neurones (20 out of 31). Among the expiratory neurones, only those with an elevated discharge firing rate and significant correlation coefficient values remain active in polypnea. At this time they generally exhibit a decreasing firing rate and emit only a few spikes in each burst. 5 The results suggest that during polypnea the genesis of the respiratory rhythm is dependent upon a different mechanism than in normopnea.

Published

1976

12. Central determination of recruitment order: intracellular study of phrenic motoneurons.

Author

Monteau R, Khatib M, and Hilaire G

Subjects

Animals, Cats, Diaphragm physiology, Electromyography, Electrophysiology, Evoked Potentials, Muscle Contraction, Phrenic Nerve physiology, Reaction Time, Respiration, Medulla Oblongata physiology, Neural Conduction, Neurons physiology, Phrenic Nerve cytology, Recruitment, Neurophysiological

Abstract

Simultaneous recordings were made intracellularly from phrenic motoneurons (PMs) and extracellularly from their central drivers, the inspiratory bulbospinal neurons (IBSNs) of the dorsal respiratory nucleus. On the basis of their order of recruitment from the beginning of inspiration (as estimated by the phrenic discharge). PMs and IBSNs were classified as early (E) or late (L) units. Unitary excitatory postsynaptic potentials (EPSPs) evoked in the PM by the IBSN were frequently observed between IBSNs and PMs with a similar recruitment, both E, 11/28 or both L, 10/13, and were scarce between IBSNs and PMs with different recruitment. E and L, 8/28, or L and E, 2/11. Since measured membrane resistances of E and L PMs were not statistically different, the recruitment order of PMs may be considered as mainly determined by the timing (E or L) of the central drive that they received.

Published

1985