Hypoxia is both a consequence and cause of many acute and chronic diseases. Severe hypoxia causes hypertension with cardiovascular sequelae; however, the rare studies using moderate severities of hypoxia indicate that it can be beneficial, suggesting that hypoxia may not always be detrimental. Comparisons between studies are difficult because of the varied classifications of hypoxic severities, methods of delivery and use of anaesthetics. Thus, to investigate the long-term effects of moderate hypoxia on cardiovascular health, radiotelemetry was used to obtain in vivo physiological measurements in unanaesthetized mice during 24 h of either moderate or severe hypoxia, followed by 72 h of normoxic recovery. Systolic blood pressure was decreased during recovery following moderate hypoxia but increased following severe hypoxia. Moderate and severe hypoxia increased haeme oxygenase-1 expression during recovery, suggesting parity in hypoxic stress at the level of the artery. Severe but not moderate hypoxia increased the low/high frequency ratio of heart rate variability 72 h post-hypoxia, indicating a shift in sympathovagal balance. Moderate hypoxia dampened the amplitude of circadian rhythm, whereas severe disrupted rhythm during the entire insult, with perturbations persisting throughout normoxic recovery. Thus, hypoxic severity differentially regulates circadian blood pressure.
The obesity epidemic is considered one of the most serious public health problems of the modern world. Physical therapy is the most accessible form of treatment; however, compliance is a major obstacle due to exercise intolerance and dyspnea. Respiratory muscle atrophy is a cause of dyspnea, yet little is known of obesity-induced respiratory muscle dysfunction. Our objective was to investigate whether obesity-induced skeletal muscle wasting occurs in the diaphragm, the main skeletal muscle involved in inspiration, using the Zucker diabetic fatty (ZDF) rat. After 14 wk, ZDF rats developed obesity, hyperglycemia, and insulin resistance, compared with lean controls. Hemodynamic analysis revealed ZDF rats have impaired cardiac relaxation (P = 0.001) with elevated end-diastolic pressure (P = 0.006), indicative of diastolic dysfunction. Assessment of diaphragm function revealed weakness (P = 0.0296) in the absence of intrinsic muscle impairment in ZDF rats. Diaphragm morphology revealed increased fibrosis (P < 0.0001), atrophy (P < 0.0001), and reduced myosin heavy-chain content (P < 0.001), compared with lean controls. These changes are accompanied by activation of the myostatin signaling pathway with increased serum myostatin (P = 0.017), increased gene expression (P = 0.030) in the diaphragm and retroperitoneal adipose (P = 0.033), and increased SMAD2 phosphorylation in the diaphragm (P = 0.048). Here, we have confirmed the presence of respiratory muscle atrophy and weakness in an obese, diabetic model. We have also identified a pathological role for myostatin signaling in obesity, with systemic contributions from the adipose tissue, a nonskeletal muscle source. These findings have significant implications for future treatment strategies of exercise intolerance in an obese, diabetic population.
Background: Physiological rhythms in mammals are essential for maintaining health, whereas disruptions may cause or exacerbate disease pathogenesis. As such, our objective was to characterize how cigarette smoke exposure affects physiological rhythms of otherwise healthy mice using telemetry and cosinor analysis. Methods: Female BALB/c mice were implanted with telemetry devices to measure body temperature, heart rate, systolic blood pressure (SBP), and activity. Following baseline measurements, mice were exposed to cigarette smoke for approximately 50 min twice daily during weekdays over 24 weeks. Physiological parameters were recorded after 1, 4, 8, and 24 weeks of exposure or after 4 weeks cessation following 4 weeks of cigarette smoke exposure. Results: Acute cigarette smoke exposure resulted in anapyrexia, and bradycardia, with divergent effects on SBP. Long term, cigarette smoke exposure disrupted physiological rhythms after just 1 week, which persisted across 24 weeks of exposure (as shown by mixed effects on mesor, amplitude, acrophase, and goodness-of-fit using cosinor analysis). Four weeks of cessation was insufficient to allow full recovery of rhythms. Conclusion: Our characterization of the pathophysiology of cigarette smoke exposure on physiological rhythms of mice suggests that rhythm disruption may precede and contribute to disease pathogenesis. These findings provide a clear rationale and guide for the future use of chronotherapeutics.
Techniques to comprehensively evaluate pulmonary function carry a variety of limitations, including the ability to continuously record intrathoracic pressures (ITP), acutely and chronically, in a natural state of freely behaving animals. Measurement of ITP can be used to derive other respiratory parameters, which provide insight to lung health. Our aim was to develop a surgical approach for the placement of a telemetry pressure sensor to measure ITP, providing the ability to chronically measure peak pressure, breath frequency, and timing of the respiratory cycle to facilitate circadian analyses related to breathing patterns. Applications of this technique are shown using a moderate hypoxic challenge. Male C57Bl6 mice were implanted with radio-telemetry devices to record heart rate, temperature, activity, and ITP during 24 h normoxia, 24 h hypoxia (FIO2 = 0.15), and return to 48 h normoxia. Radio-telemetry of ITP permitted the detection of hypoxia-induced increases in 'the ITP-equivalent' of ventilation, which were driven by increases in breathing frequency and ITP on a short-term timescale. Respiratory frequency, derived from pressure waveforms, was increased by a decrease in expiratory time without changes in inspiratory time. Chronically, telemetric recording allowed for circadian analyses of respiratory drive, as assessed by inspiratory pressure divided by inspiratory time, which was increased by hypoxia and remained elevated for 48 h of recovery. Further, respiratory frequency demonstrated a circadian rhythm, which was disrupted through the recovery period. Radio telemetry of ITP is a viable, long-term, chronic methodology that extends traditional methods to evaluate respiratory function in mice.
Erythropoietin (EPO) is widely recognized as the principle regulator of erythropoiesis, however, extra‐erythropoietic functions have been identified including cytoprotection, cardiac inotropy, cellular proliferation, and embryonic development. Whole body deletion of either EPO or the EPO receptor is embryonic lethal with impaired cardiogenesis leading to ventricular hypoplasia. While multiple extra‐renal tissue and cell types produce EPO, whether the heart is a direct source remains unclear. Human recombinant EPO increases myocardial contractility and confers cytoprotection against cardiac injury, which suggests a role for EPO signalling in the heart. Our objectives were to (1) confirm whether the heart produces EPO and (2) determine if there is a role for paracrine EPO signalling during cardiogenesis. We generated constitutive, cardiomyocyte‐specific EPO knockout mice driven by the Mlc2v promoter (EPOfl/fl:Mlc2v‐cre+/−; EPOΔ/Δ‐CM). We confirmed that the heart is a source of EPO expression with a distinct circadian rhythm in adult hearts and increased expression during embryonic development. During cardiogenesis, cardiac EPO expression was reduced, but not eliminated, in EPOΔ/Δ‐CM hearts with decreased cardiac cell proliferation. This suggests EPO signalling is partially compensated by an alternate cardiac cell type during cardiac development. In adult EPOΔ/Δ‐CM mice, global cardiac mass was preserved while cardiomyocyte cross‐sectional area was increased. Taken together, cellular cardiomyocyte hypertrophy in the absence of gross organ hypertrophy, and the observed reduction in cardiac cell proliferation during cardiogenesis, points towards a reduction in the overall number of cardiomyocytes in EPOΔ/Δ‐CM mice. Collectively, these data identify the first physiological roles of extra‐renal EPO by confirming that the heart is a source of EPO and that paracrine expression is required for cardiogenesis. Further, cardiac EPO expression is a complex interplay of multiple cell types where loss of cardiomyocyte production results in compensation from other cardiac cell lineages. Support or Funding Information This work was funded in part by the Canadian Institutes of Health Research (JAS), the Natural Sciences and Engineering Research Council of Canada (KRB, MKV, and JAS), the Canadian Glycomics Network (JAS), and the Heart and Stroke Foundation of Canada (KRB and JAS). JAS is also a new investigator with the Heart and Stroke Foundation of Ontario.
Impairments in O2 delivery are a common feature of many chronic diseases (e.g., COPD, diabetes, and anemia). It reduces quality of life and increases morbidity, mortality and hospitalizations in patients. Circadian rhythms in mammals, including humans, are essential to health whereas disruptions exacerbate disease pathogenesis. While severe hypoxia can abolish circadian rhythm, moderate hypoxia is more clinically relevant but its effects on circadian rhythm are unknown. Our objective was to investigate the effects of moderate hypoxia on circadian rhythm. Methods: Mice were implanted with telemetry devices to measure heart rate (HR) and body temperature (Tb). Baseline measurements were obtained and animals subjected to 24 hours of moderate hypoxia (O2 = 15%) followed by 24 hours of normoxic recovery. Results: Moderate hypoxia disrupted, but did not abolish, the circadian rhythm of HR and Tb. Amplitude of circadian rhythm for HR was altered during both sleep and active states whereas Tb amplitude was altered only during sleep. Importantly, these disruptions persisted following 24 hours of normoxic recovery. Conclusions: A single 24 hour exposure of moderate hypoxia is sufficient to alter HR and Tb circadian rhythm, which does not recover within 24 hours of reoxygenation. This suggests that moderate hypoxia may have a critical role in disease pathogenesis. Grant Funding Source: Supported by Canadian Institute of Health Research
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