Mice Lacking Brain-Derived Neurotrophic Factor Exhibit Visceral Sensory Neuron Losses Distinct from Mice Lacking NT4 and Display a Severe Developmental Deficit in Control of Breathing

Erickson, Jeffery T.; Conover, Joanne C.; Borday, Véronique; Champagnat, Jean; Barbacid, Mariano; Yancopouloš, George D.; Katz, David M.

doi:10.1523/jneurosci.16-17-05361.1996

Cited by 275 publications

(256 citation statements)

References 67 publications

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“…There is little information regarding the in vivo respiration of the adult mouse (Tankersley et al, 1997(Tankersley et al, , 1999. In addition, the availability of transgenic mice that present interesting mutations affecting the maturation and activity of respiratory network components (Erickson et al, 1996;Jacquin et al, 1996;Bou-Flores et al, 2000) is useful for analyzing the activity and regulations of respiration.…”

Section: Abstract: Breathing Patterns; Inspiratory Neuron and Motonementioning

confidence: 99%

“…The ventilatory responses to hypoxia were studied by the whole-body plethysmography technique, as modified by Bartlett and Tenney (1970) and used repeatedly for studying breathing patterns in mice (Erickson et al, 1996;Jacquin et al, 1996;Tankersley et al, 1997Tankersley et al, , 1999. The animal chamber (200 ml), equipped with a temperature sensor (Checktemp 1, Hanna Instruments, Lingolsheim, France), was connected to a reference chamber of identical volume.…”

Section: Measurements and Recordingsmentioning

confidence: 99%

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Altered Respiratory Activity and Respiratory Regulations in Adult Monoamine Oxidase A-Deficient Mice

et al. 2001

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The abnormal metabolism of serotonin during the perinatal period alters respiratory network maturation at birth as revealed by comparing the monoamine oxidase A-deficient transgenic (Tg8) with the control (C3H) mice (Bou-Flores et al., 2000). To know whether these alterations occur only transiently or induce persistent respiratory dysfunction during adulthood, we studied the respiratory activity and regulations in adult C3H and Tg8 mice. First, plethysmographic and pneumotachographic analyses of breathing patterns revealed weaker tidal volumes and shorter inspiratory durations in Tg8 than in C3H mice. Second, electrophysiological studies showed that the firing activity of inspiratory medullary neurons and phrenic motoneurons is higher in Tg8 mice and that of the intercostal motoneurons in C3H mice. Third, histological studies indicated abnormally large cell bodies of Tg8 intercostal but not phrenic motoneurons. Finally, respiratory responses to hypoxia and lung inflation are weaker in Tg8 than in C3H mice. DL-p-chlorophenyl-alanine treatments applied to Tg8 mice depress the high serotonin level present during adulthood; the treated mice recover normal respiratory responses to both hypoxia and lung inflation, but their breathing parameters are not significantly affected. Therefore in Tg8 mice the high serotonin level occurring during the perinatal period alters respiratory network maturation and produces a permanent respiratory dysfunction, whereas the high serotonin level present in adults alters the respiratory regulatory processes. In conclusion, the metabolism of serotonin plays a crucial role in the maturation of the respiratory network and in both the respiratory activity and the respiratory regulations.

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Section: Abstract: Breathing Patterns; Inspiratory Neuron and Motonementioning

confidence: 99%

Section: Measurements and Recordingsmentioning

confidence: 99%

Altered Respiratory Activity and Respiratory Regulations in Adult Monoamine Oxidase A-Deficient Mice

et al. 2001

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“…Respiratory frequency, neonatal apnoeas and survival were normal. Interestingly, the reverse phenotype (a small tidal volume) has been reported after the decrease (instead of increase) in the peripheral chemoreceptor afferent population by the invalidation of the BDNF (Erickson et al 1996). Diamonds, WT; triangles, Phox2a þ/2 .…”

Section: Resultsmentioning

confidence: 96%

“…This phenotype, accompanied by an unaltered frequency, is evident at birth and persists afterwards (it was followed until post-natal day 10). Morphological analysis of Phox2a þ/2 animals reveals no anomaly in the pons (parabrachial medial and Kö lliker -Fuse nuclei, pediculo-pontine tegmentum, superior cerebellar peduncles) or in the locus coeruleus region, but highlighted an increase in the number of cells expressing the catecholamine-synthesizing enzyme-tyrosine hydroxylase, a marker of peripheral chemoreceptor afferent neurons (Katz & Black 1986;Erickson et al 1996), in the petrosal sensory ganglion (figure 4a). These data indicate that Phox2a plays a critical role in the ontogeny of the reflex control of inspiration and that abnormality may independently affect rhythm generators and pontine/sensory inspiratory controllers as well as their peripheral reflex control.…”

Section: Control Of Inspirations By Peripheral Chemoreceptor Afferentmentioning

confidence: 99%

Developmental basis of the rostro-caudal organization of the brainstem respiratory rhythm generator

Champagnat

Morin-Surun

Fortin

et al. 2009

Phil. Trans. R. Soc. B

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The Hox genetic network plays a key role in the anteroposterior patterning of the rhombencephalon at pre-and early-segmental stages of development of the neural tube. In the mouse, it controls development of the entire brainstem respiratory neuronal network, including the pons, the parafacial respiratory group (pFRG) and the pre-Bö tzinger complex (preBö tC). Inactivation of Krox20/Egr2 eliminates the pFRG activity, thereby causing life-threatening neonatal apnoeas alternating with respiration at low frequency. Another respiratory abnormality, the complete absence of breathing, is induced when neuronal synchronization fails to develop in the preBö tC. The present paper summarizes data on a third type of respiratory deficits induced by altering Hox function at pontine levels. Inactivation of Hoxa2, the most rostrally expressed Hox gene in the hindbrain, disturbs embryonic development of the pons and alters neonatal inspiratory shaping without affecting respiratory frequency and apnoeas. The same result is obtained by the Phox2a þ/2 mutation modifying the number of petrosal chemoafferent neurons, by eliminating acetylcholinesterase and by altering Hox-dependent development of the pons with retinoic acid administration at embryonic day 7.5. In addition, embryos treated with retinoic acid provide a mouse model for hyperpnoeic episodic breathing, widely reported in pre-term neonates, young girls with Rett's syndrome, patients with Joubert syndrome and adults with Cheyne -Stokes respiration. We conclude that specific respiratory deficits in vivo are assignable to anteroposterior segments of the brainstem, suggesting that the adult respiratory neuronal network is functionally organized according to the rhombomeric, Hox-dependent segmentation of the brainstem in embryos.

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“…BDNF is active until adulthood, particularly on the serotonergic spinal plasticity of breathing caused by intermittent hypoxia. Null mutant newborn mice lacking BDNF had a low respiratory rate and numerous apneas (29). Discharge frequency recorded in brain stem-spinal cord preparations from BDNF mutant newborn mice was more severely decreased in homozygous than in heterozygous animals (3).…”

Section: Mutant Newborn Mice With Abnormal Rhythmogenesismentioning

confidence: 99%

Neural control of breathing: insights from genetic mouse models

Gaultier¹,

Gallego²

2008

Journal of Applied Physiology

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Mice Lacking Brain-Derived Neurotrophic Factor Exhibit Visceral Sensory Neuron Losses Distinct from Mice Lacking NT4 and Display a Severe Developmental Deficit in Control of Breathing

Cited by 275 publications

References 67 publications

Altered Respiratory Activity and Respiratory Regulations in Adult Monoamine Oxidase A-Deficient Mice

Altered Respiratory Activity and Respiratory Regulations in Adult Monoamine Oxidase A-Deficient Mice

Developmental basis of the rostro-caudal organization of the brainstem respiratory rhythm generator

Neural control of breathing: insights from genetic mouse models

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