Partial Raphe Dysfunction in Neurotransmission Is Sufficient to Increase Mortality after Anoxic Exposures in Mice at a Critical Period in Postnatal Development.
Karlene T BarrettRyan T Dosumu-JohnsonJ Andrew DaubenspeckRachael D BrustVasileios KreouzisJun Chul KimAihua LiSusan M DymeckiEugene E NattiePublished in: The Journal of neuroscience : the official journal of the Society for Neuroscience (2016)
Many sudden infant death syndrome (SIDS) cases exhibit a partial (∼26%) brainstem serotonin deficiency. Using recombinase drivers, we targeted different fractions of serotonergic and raphe neurons in mice for tetanus toxin light chain expression, which prevented vesicular neurotransmitter release. In one model, approximately one-third of medullary Tph2(+) neurons are silenced by postnatal (P) days 5 and 12, along with some Pet1(+),Tph2(low or negative) raphe cells; in the other, approximately three-fourths of medullary Tph2(+) neurons, also with some Tph2(low or negative) cells. Both models demonstrated excessive mortality to anoxia (a postulated SIDS stressor) at P5 and P8. We demonstrated fatal vulnerability to anoxic stress at a specific time in postnatal life induced by a partial defect in raphe function. This models features of SIDS.
Keyphrases
- induced apoptosis
- preterm infants
- spinal cord
- cell cycle arrest
- poor prognosis
- escherichia coli
- oxidative stress
- endoplasmic reticulum stress
- high fat diet induced
- type diabetes
- climate change
- computed tomography
- air pollution
- cell death
- risk factors
- metabolic syndrome
- cancer therapy
- cardiovascular events
- drug delivery
- physical activity
- coronary artery disease
- adipose tissue
- cell proliferation
- positron emission tomography
- insulin resistance