Autonomic Nervous System Dysregulation: Breathing and Heart Rate Perturbation During Wakefulness in Young Girls with Rett Syndrome
This study characterizes cardiorespiratory dysregulation in young girls with MECP2 mutation-confirmed Rett syndrome (RS). Respiratory inductance plethysmography of chest/abdomen and ECG was obtained during daytime wakefulness in 47 girls with MECP2 mutation-confirmed RS and 47 age-, gender-, and ethnicitymatched controls (ages 2-7 y). An in-home breath-to-breath and beat-to-beat characterization was conducted and revealed that breathing was more irregular, with an increased breathing frequency, mean airflow, and heart rate in RS versus controls. There was a decreased correlation between normal breathing and heart rate variability, and an exaggerated increase in heart rate response to breathholds in RS versus controls. We conclude that girls with RS have cardiorespiratory dysregulation during breathholds as well as during "normal" breaths and during breaths before and subsequent to breathholds. This dysregulation may offer insight into the mechanisms that render girls with RS more vulnerable to sudden death. R S is one of a growing number of disorders characterized by autonomic nervous system dysfunction/dysregulation (1). Diagnosis of RS is based on clinical criteria (2-4), with more than 85% of identified girls having mutations in MECP2 on the X chromosome (5; B. Roa, personal communication). The RS phenotype includes normal development until 6 -18 mo of age, then regression with slowing of head circumference growth, loss of language, development of stereotypical hand movements, gait and truncal apraxia, EEG abnormalities, seizures, spasticity, and scoliosis (2).Breathing irregularities consistent with autonomic dysregulation in RS include characteristic patterns variably described as hyperventilation, Valsalva maneuvers, apnea, apneusis, breathholding, and rapid shallow breathing (6 -17). These irregularities are reported to occur near-exclusively during wakefulness (8,17). Age may play a role, as more breathholds and forceful breathing are reported in 5-10-y-old patients compared with more of a Valsalva pattern in young adults (13). Conclusions regarding imbalance of sympathovagal input have been made primarily from heart rate and blood pressure monitoring during spontaneously occurring breathholds, coupled with analytical measures derived from these signals (4,11,13). Julu and others proposed a disturbance in cardiovascular and respiratory system integration, describing their findings as central autonomic dysfunction (4,11,13). Further support for autonomic dysregulation comes from observations of decreased heart rate variability, longer corrected QT intervals, sinus bradycardia, gaseous abdominal distension, sweating, cool extremities (3,7,18 -23), flushing and temperature dysregulation (M. Coenraads, personal communication).Despite survival into adulthood, Kerr and colleagues (24,25) reported that 20 -26% of RS deaths are sudden and unexpected, and that the deaths occur primarily during wakefulness. QT prolongation and nonspecific ST changes in RS suggest cardiac causes for sudden death, though ...
Autonomic dysregulation in young girls with Rett Syndrome during nighttime in‐home recordings
This study was designed to specifically characterize the autonomic phenotype of cardiorespiratory dysregulation during the nighttime in young girls with MECP2 mutation-confirmed Rett Syndrome (RS), studied in their home environment. Computerized breath-to-breath and beat-to-beat characterization of at-home continuously recorded respiratory inductance plethysmography of chest/abdomen and ECG (VivoMetrics, Inc.) was obtained during overnight recordings in 47 girls with MECP2 mutation-confirmed RS and 47 age-, gender-, and ethnicity-matched screened controls (ages 2-7 years). We determined that although the breathing and heart rate appear more regular during the night compared to the day, young girls with RS demonstrate apparent nocturnal irregularities. Comparing daytime versus nighttime, breathing was more irregular, with an increased breathing frequency (and irregularity), mean amplitude of respiratory inductance plethysmography sum (AMP)/T(I), and heart rate and decreased AMP in girls with RS. Comparing girls with RS versus controls during nighttime recording, breathing was more irregular, with an increased breathing frequency (and irregularity), mean AMP/T(I), and heart rate. An increased uncoupling between measures of breathing and heart rate control indicates malregulation in the autonomic nervous system, and is apparent during the day as well as the night. This uncoupling may represent a mechanism that renders the girls with RS more vulnerable to sudden death.
Patients with systemic lupus erythematosus (SLE) show an over-expression of Type I Interferon (IFN) responsive genes called “Interferon Signature”. We found that the B6.NZMSle1/Sle2/Sle3 (Sle1,2,3) lupus-prone mice also express an Interferon Signature compared to non autoimmune C57BL/6 mice. In vitro, myeloid dendritic cells (mDCs)(GM-CSF bone marrow-derived BMDCs) from Sle1,2,3 mice constitutively over-expressed IFN responsive genes such as IFNb, Oas-3, Mx-1, ISG-15 and CXCL10, and the members of IFN signaling pathway STAT1, STAT2, and IRF7. The Interferon Signature was similar in Sle1,2,3 BMDCs from young, pre-autoimmune mice and from mice with high titers of autoantibodies, suggesting that the Interferon Signature in mDCs precedes disease onset and it is independent from the autoantibodies. Sle1,2,3 BMDCs hyper-responded to stimulation with IFNa and the TLR7 and TLR9 agonists R848 and CpGs. We propose that this hyper-response is induced by the Interferon Signature and only partially contributes to the Signature, since oligonucleotides inhibitory for TLR7 and TLR9 only partially suppressed the constitutive Interferon Signature and pre-exposure to IFNa induced the same hyper-response in wild type BMDCs than in Sle1,2,3 BMDCs. In vivo, mDCs and with lesser extent T and B cells from young pre-diseased Sle1,2,3 mice also expressed the Interferon Signature, although they lacked the strength that BMDCs showed in vitro. Sle1,2,3 plasmacytoid DCs expressed the Interferon Signature in vitro but not in vivo, suggesting that mDCs may be more relevant before disease onset. We propose that Sle1,2,3 mice are useful tools to study the role of the Interferon Signature in lupus pathogenesis.
BackgroundSleep deprivation impairs learning, causes stress, and can lead to death. Notch and JNK-1 pathways impact C. elegans sleep in complex ways; these have been hypothesized to involve compensatory sleep. C. elegans DAF-16, a FoxO transcription factor, is required for homeostatic response to decreased sleep and DAF-16 loss decreases survival after sleep bout deprivation. Here, we investigate connections between these pathways and the requirement for sleep after mechanical stress.ResultsReduced function of Notch ligand LAG-2 or JNK-1 kinase resulted in increased time in sleep bouts during development. These animals were inappropriately easy to arouse using sensory stimulation, but only during sleep bouts. This constellation of defects suggested that poor quality sleep bouts in these animals might activate homeostatic mechanisms, driving compensatory increased sleep bouts. Testing this hypothesis, we found that DAF-16 FoxO function was required for increased sleep bouts in animals with defective lag-2 and jnk-1, as loss of daf-16 reduced sleep bouts back to normal levels. However, loss of daf-16 did not suppress arousal thresholds defects. Where DAF-16 function was required differed; in lag-2 and jnk-1 animals, daf-16 function was required in neurons or muscles, respectively, suggesting that disparate tissues can drive a coordinated response to sleep need. Sleep deprivation due to mechanical stimulation can cause death in many species, including C. elegans, suggesting that sleep is essential. We found that loss of sleep bouts in C. elegans due to genetic manipulation did not impact their survival, even in animals lacking DAF-16 function. However, we found that sleep bout deprivation was often fatal when combined with the concurrent stress of mechanical stimulation.ConclusionsTogether, these results in C. elegans confirm that Notch and JNK-1 signaling are required to achieve normal sleep depth, suggest that DAF-16 is required for increased sleep bouts when signaling decreases, and that failure to enter sleep bouts is not sufficient to cause death in C. elegans, unless paired with concurrent mechanical stress. These results suggest that mechanical stress may directly contribute to death observed in previous studies of sleep deprivation and/or that sleep bouts have a uniquely restorative role in C. elegans sleep.Electronic supplementary materialThe online version of this article (10.1186/s12868-018-0408-1) contains supplementary material, which is available to authorized users.
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