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1.
Neurobiol Dis ; 38(1): 125-35, 2010 Apr.
Article in English | MEDLINE | ID: mdl-20085811

ABSTRACT

Spinal muscular atrophy (SMA) is caused by insufficient levels of the survival motor neuron (SMN) protein leading to muscle paralysis and respiratory failure. In mouse, introducing the human SMN2 gene partially rescues Smn(-)(/)(-) embryonic lethality. However current models were either too severe or nearly unaffected precluding convenient drug testing for SMA. We report here new SMN2;Smn(-/-) lines carrying one to four copies of the human SMN2 gene. Mice carrying three SMN2 copies exhibited an intermediate phenotype with delayed appearance of motor defects and developmental breathing disorders reminiscent of those found in severe SMA patients. Although normal at birth, at 7 days of age respiratory rate was decreased and apnea frequency was increased in SMA mice in parallel with the appearance of neuromuscular junction defects in the diaphragm. With median survival of 15 days and postnatal onset of neurodegeneration, these mice could be an important tool for evaluating new therapeutics.


Subject(s)
Muscular Atrophy, Spinal/physiopathology , Neuromuscular Junction Diseases/physiopathology , Respiratory Paralysis/physiopathology , Animals , Diaphragm/innervation , Diaphragm/physiopathology , Disease Models, Animal , Disease Progression , Genes, Lethal/physiology , Genetic Predisposition to Disease/genetics , Humans , Mice , Mice, Transgenic , Muscular Atrophy, Spinal/genetics , Muscular Atrophy, Spinal/metabolism , Neuromuscular Junction/genetics , Neuromuscular Junction/metabolism , Neuromuscular Junction/pathology , Neuromuscular Junction Diseases/genetics , Neuromuscular Junction Diseases/metabolism , Respiratory Insufficiency/genetics , Respiratory Insufficiency/metabolism , Respiratory Insufficiency/physiopathology , Respiratory Paralysis/genetics , Respiratory Paralysis/metabolism , Survival of Motor Neuron 2 Protein/genetics
2.
Front Cell Neurosci ; 5: 24, 2011.
Article in English | MEDLINE | ID: mdl-22125512

ABSTRACT

Adult motor coordination requires strong coincident cortical excitatory input to hyperpolarized medium spiny neurons (MSNs), the dominant neuronal population of the striatum. However, cortical and subcortical neurons generate during development large ongoing patterns required for activity-dependent construction of networks. This raises the question of whether immature MSNs have adult features from early stages or whether they generate immature patterns that are timely silenced to enable locomotion. Using a wide range of techniques including dynamic two-photon imaging, whole cell or single-channel patch clamp recording in slices from Nkx2.1-GFP mice, we now report a silencing of MSNs that timely coincides with locomotion. At embryonic stage (as early as E16) and during early postnatal days, genetically identified MSNs have a depolarized resting membrane potential, a high input resistance and lack both inward rectifying (IK(IR)) and early slowly inactivating (I(D)) potassium currents. They generate intrinsic voltage-gated clustered calcium activity without synaptic components. From postnatal days 5-7, the striatal network transiently generates synapse-driven giant depolarizing potentials when activation of cortical inputs evokes long lasting EPSCs in MSNs. Both are mediated by NR2C/D-receptors. These immature features are abruptly replaced by adult ones before P10: MSNs express IK(IR) and I(D) and generate short lasting, time-locked cortico-striatal AMPA/NMDA EPSCs with no NR2C/D component. This shift parallels the onset of quadruped motion by the pup. Therefore, MSNs generate immature patterns that are timely shut off to enable the coordination of motor programs.

3.
Am J Physiol Regul Integr Comp Physiol ; 296(5): R1503-11, 2009 May.
Article in English | MEDLINE | ID: mdl-19297539

ABSTRACT

In newborns, hypoxia elicits increased ventilation, arousal followed by defensive movements, and cries. Cold is known to affect the ventilatory response to hypoxia, but whether it affects the arousal response remains unknown. The aim of the present study was to assess the effects of cold on the ventilatory and arousal responses to hypoxia in newborn mice. We designed an original platform measuring noninvasively and simultaneously the breathing pattern by whole body plethysmography, body temperature by infrared thermography, as well as motor and ultrasonic vocal (USV) responses. Six-day-old mice were exposed twice to 10% O(2) for 3 min at either cold temperature (26 degrees C) or thermoneutrality (33 degrees C). At 33 degrees C, hypoxia elicited a marked increase in ventilation followed by a small ventilatory decline, small motor response, and almost no USVs. Body temperature was not influenced by hypoxia, and oxygen consumption (Vo(2)) displayed minimal changes. At 26 degrees C, hypoxia elicited a slight increase in ventilation with a large ventilatory decline and a large drop of Vo(2). This response was accompanied by marked USV and motor responses. Hypoxia elicited a small decrease in temperature after the return to normoxia, thus precluding any causal influence on the motor and USV responses to hypoxia. In conclusion, cold stimulated arousal and stress responses to hypoxia, while depressing hypoxic hyperpnea. Arousal is an important defense mechanism against sleep-disordered breathing. The dissociation between ventilatory and behavioral responses to hypoxia suggests that deficits in the arousal response associated with sleep breathing disorders cannot be attributed to a depressed hypoxic response.


Subject(s)
Animals, Newborn/physiology , Behavior, Animal/physiology , Cold Temperature , Hypoxia/physiopathology , Animals , Body Temperature/physiology , Female , Mice , Models, Animal , Motor Activity/physiology , Oxygen Consumption/physiology , Pulmonary Ventilation/physiology , Sleep Arousal Disorders/physiopathology , Vocalization, Animal/physiology
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