Skip to main content
Advertisement
Browse Subject Areas
?

Click through the PLOS taxonomy to find articles in your field.

For more information about PLOS Subject Areas, click here.

  • Loading metrics

Circadian Control of Mouse Heart Rate and Blood Pressure by the Suprachiasmatic Nuclei: Behavioral Effects Are More Significant than Direct Outputs

  • W. John Sheward,

    Affiliation Centre for Cardiovascular Science, University of Edinburgh, Edinburgh, United Kingdom

  • Erik Naylor,

    Affiliation Department of Neurology, Northwestern University Medical School, Chicago, Illinois, United States of America

  • Seymour Knowles-Barley,

    Affiliation Institute for Adaptive and Neural Computation, University of Edinburgh, Edinburgh, United Kingdom

  • J. Douglas Armstrong,

    Affiliation Institute for Adaptive and Neural Computation, University of Edinburgh, Edinburgh, United Kingdom

  • Gillian A. Brooker,

    Affiliation Centre for Cardiovascular Science, University of Edinburgh, Edinburgh, United Kingdom

  • Jonathan R. Seckl,

    Affiliation Centre for Cardiovascular Science, University of Edinburgh, Edinburgh, United Kingdom

  • Fred W. Turek,

    Affiliation Department of Neurobiology and Physiology, Northwestern University, Evanston, Illinois, United States of America

  • Megan C. Holmes,

    Affiliation Centre for Cardiovascular Science, University of Edinburgh, Edinburgh, United Kingdom

  • Phyllis C. Zee,

    Affiliation Department of Neurology, Northwestern University Medical School, Chicago, Illinois, United States of America

  • Anthony J. Harmar

    tony.harmar@ed.ac.uk

    Affiliation Centre for Cardiovascular Science, University of Edinburgh, Edinburgh, United Kingdom

Abstract

Background

Diurnal variations in the incidence of events such as heart attack and stroke suggest a role for circadian rhythms in the etiology of cardiovascular disease. The aim of this study was to assess the influence of the suprachiasmatic nucleus (SCN) circadian clock on cardiovascular function.

Methodology/Principal Findings

Heart rate (HR), blood pressure (BP) and locomotor activity (LA) were measured in circadian mutant (Vipr2−/−) mice and wild type littermates, using implanted radio-telemetry devices. Sleep and wakefulness were studied in similar mice implanted with electroencephalograph (EEG) electrodes. There was less diurnal variation in the frequency and duration of bouts of rest/activity and sleep/wake in Vipr2−/− mice than in wild type (WT) and short “ultradian” episodes of arousal were more prominent, especially in constant conditions (DD). Activity was an important determinant of circadian variation in BP and HR in animals of both genotypes; altered timing of episodes of activity and rest (as well as sleep and wakefulness) across the day accounted for most of the difference between Vipr2−/− mice and WT. However, there was also a modest circadian rhythm of resting HR and BP that was independent of LA.

Conclusions/Significance

If appropriate methods of analysis are used that take into account sleep and locomotor activity level, mice are a good model for understanding the contribution of circadian timing to cardiovascular function. Future studies of the influence of sleep and wakefulness on cardiovascular physiology may help to explain accumulating evidence linking disrupted sleep with cardiovascular disease in man.

Introduction

Mammals exhibit daily rhythms in many aspects of their physiology, metabolism and behavior, such as sleep and wakefulness, the secretion of stress hormones, body temperature, heart rate and blood pressure. These rhythms are coordinated by a master circadian clock, situated in the suprachiasmatic nuclei (SCN) of the hypothalamus, which is synchronized to the external environment primarily by signals from the visual system, providing information about the 24-hr light-dark environment. The SCN may also receive timing information about the internal environment from the periphery, and in turn, delivers output circadian signals to the brain, peripheral nervous system and neuroendocrine pathways [1]. Peripheral circadian clocks, which exploit the same biochemical mechanism that drives the SCN clock, are found in most tissues and are thought to play critical roles in the local control of rhythms of physiology and biochemistry. Despite significant progress in elucidating the molecular basis of circadian oscillations, the mechanisms by which the circadian clock organizes daily rhythms of behavior, physiology and metabolism in mammals are incompletely understood. There are two mechanisms by which the SCN may impose rhythmicity: directly, by imposing circadian timing through neural or hormonal signals and indirectly, through effects on rhythms of behavior, such as feeding and the sleep-wake cycle [2].

The mechanisms underlying diurnal rhythms in blood pressure and cardiovascular function are of significant clinical interest, due to the prominent influence of time of day on the frequency of acute cardiovascular events such as myocardial infarction [3], sudden cardiac death [4] and stroke [5]. Disturbances in circadian function and sleep have been reported in mouse models of cardiometabolic disease [6], [7] and cardiovascular disease has been reported to develop in rodents carrying mutations that disrupt circadian function [8], [9]. Furthermore, disruption of normal circadian rhythmicity has been shown to reduce the lifespan of hamsters genetically susceptible to cardiomyopathic heart disease [10].

Vasoactive intestinal peptide (VIP) signaling is important for the maintenance and synchronization of circadian rhythms of clock gene expression and electrical activity in SCN neurons. In mutant mice that lack VIP [11][13] or the VPAC2 subtype of VIP receptor (Vipr2−/−) [11], [14][16], circadian rhythms of gene expression and electrical activity in individual SCN neurons are poorly synchronized and fewer cells exhibit detectable rhythms than in wild type. Consequently, such animals do not display robust circadian rhythms of physiology and behavior [11], [12], [15][19], although the ability of tissues outside the SCN to sustain circadian rhythms of clock gene expression is unimpaired [18]. Vipr2−/− mice are therefore a useful model in which to assess the role of the SCN in the control of physiology and behavior without the confounding effects of damaged neuronal connectivity, which inevitably occur in animals with SCN lesions. The aim of this study was to assess the influence of the SCN on rhythms of heart rate (HR), blood pressure (BP), sleep and wakefulness and locomotor activity by comparing the phenotypes of Vipr2−/− and WT mice.

Methods

Ethics statement

Sleep studies were conducted at Northwestern University using procedures approved in advance by the Institutional Animal Care and Use Committee. All other experimentation was conducted in accordance with the United Kingdom Animals (Scientific Procedures) Act, 1986 using procedures approved by the University of Edinburgh Ethical Review Committee.

Radiotelemetric measurement of blood pressure and activity

Adult male mice (wild type WT or Vipr2−/− on a C57BL/6J background, 3–4 months old) were anaesthetized with ketamine (50 mgkg−1, i.p.) and medetomidine (0.75 mgkg−1, i.p.). Radiotelemetric catheters (PA-C10, Data Sciences International, St Paul MN) were inserted into the left common carotid artery with the transmitter implanted subcutaneously. Mice were housed individually at 22°C, initially with a 12∶12 light dark cycle (LD; lights on 0700 h, lights off 1900 h). After 5–7 days, mice had recovered from surgery and exhibited regular diurnal rhythms of activity. Measurements of heart rate, blood pressure and activity were recorded at 4-minute intervals for the duration of the study. The data from the telemetric device was collected using the Dataquest A.R.T system, version 4.0 (Data Sciences International, St Paul MN) by way of a RPC-1 receiver placed under the mouse cage. After collection of data in LD conditions for 8 days, mice were transferred to constant dark (DD) conditions for a further 8 days. During periods of darkness (in both LD and DD conditions) a dim red light was permanently on to facilitate animal care.

Sleep studies

Seven C57BL/6 male mice lacking the VPAC2 receptor gene (Vipr2−/−) along with six wild-type male, littermate controls (WT) were kept in a 12 hour light/12 hour dark cycle (LD 12∶12) prior to surgery. Animals were age (Vipr2−/−: 8.7±0.6 months, wt: 9.3±0.3 months) and weight (Vipr2−/−: 33.1±1.9 g, wt: 33.7±1.3 g) matched as closely as possible. Food and water were available ad libitum throughout the experiment.

Recording of Sleep

Under ketamine and xylazine anesthesia mice were implanted with electrodes for EEG and EMG recording. EEG recording was accomplished via four stainless steel screws (Small Parts #MX-000120-02FL, Miami, FL) positioned at the following locations: 1.5 mm anterior of bregma, 1 mm left and right of midline, 1 mm anterior of lambda and 1 mm left and right of midline. EMG activity was monitored using Iridium/Silver alloy wires (MedWire #10IR5T, Mt. Vernon, NY) inserted bilaterally into the nuchal muscles. All electrodes were attached to a pre-fabricated head mount board (Pinnacle Technology, Inc, Lawrence, KS) and secured using dental acrylic. Mice were adapted to the recording tether for one week before 48 continuous hours of EEG and EMG waveforms were collected. Mice were then placed into DD conditions within the recording chamber for a minimum of 10 days in order to establish a free-running activity rhythm. Waveforms were then recorded for 48 hours to measure sleep under DD conditions. Analysis during this period included five Vipr2−/− and five WT animals, because two Vipr2−/− mice and one WT mouse had to be excluded from recording due to deteriorating signal quality. Tau was calculated using chi-square analysis over a period of 7–10 days Sleep records within one circadian cycle were then scored and analyzed as a percentage of time with respect to each animal's individual tau. In the case of Vipr2−/− mice, no discernable rhythm could be calculated by either best-fit line or chi-square analysis. To calculate sleep times in Vipr2−/− mice, average tau of the wild-type mice (23.6 h) was used.

Data analysis of sleep/wake recordings

All signals were amplified 100X at the preamplifier stage before passing through the tether and swivel. At the main amplifier stage, EEG signals were amplified an additional 100X (10,000X total) and EMG signals were amplified an additional 50X (5,000X total). Both EEG channels were subjected to high pass filtering at 0.5 Hz and low-pass filtered at 50 Hz. EMG signals were high pass filtered at 10 Hz and low-pass filtered at 200 Hz. A 60 Hz digital notch filter was applied to all signal channels. Signals were sampled at 400 Hz and digitized using a 14-bit A/D converter (Texas Instruments ADS7871). Waveforms were collected and stored on a standard desktop PC running the Sirenia hardware and collection suite (Pinnacle Technology, Inc. Lawrence, KS). Waveform data was divided into 10 sec. epochs and classified into one of three vigilance states (wake, NREM sleep or REM sleep) based on predefined criteria [20][22]. Post scoring processing was accomplished using the Sirenia analysis package (Pinnacle Technology, Inc. Lawrence, KS).

Statistical analysis

Data are expressed as mean ± SEM. The significance of the difference between means was tested by appropriate t-tests or a non-parametric Mann-Whitney U test. For statistical analysis of changes in sleep parameters over time repeated measures ANOVA with Tukey's post- hoc tests was used.

Results

Effects of the Vipr2 mutation on locomotor activity

There were robust diurnal rhythms of locomotor activity in both Vipr2−/− and WT mice (Figure 1a, d; Figure S2), but in Vipr2−/− mice a greater proportion of daily activity took place in the last 8 h of the light period (25±4% vs 14±3%; P<0.05) and a lower proportion in the last 8 h of the dark period (29±3% vs 44±2%; P<0.001) than in WT. Records from individual animals (Figure 2a, d) showed that this was because Vipr2−/− mice exhibited less sustained activity at the beginning of the dark period and more prominent short (“ultradian”) cycles of activity and rest than WT in both light and dark periods. Serial correlation analysis of the intervals between successive activity onsets [23][25] indicated that the ultradian activity bouts were not generated by an oscillatory mechanism (serial correlation coefficients were 0.030±0.05 in WT and 0.128±0.083 in Vipr2−/− mice). To define a measure of ultradian activity that could be used to compare the behavior of mice of the two genotypes, we examined the durations of periods of activity and rest (activity signal  = 0). K-means clustering analysis (MatLab 7.0 Statistical Toolbox) revealed that the durations of periods of rest were distributed bimodally in all mice, with two components of short (“ultradian”: 1.53±0.71 h; mean ± SD) and long (5.50±1.80 h; mean ± SD) duration respectively (Figure 3). The time spent in rest periods less than 3 h in duration was thus a measure of ultradian activity, which robustly distinguished the behavior of Vipr2−/− mice from WT.

thumbnail
Figure 1. Mean activity, blood pressure and heart rate in WT and Vipr2−/− mice in a light-dark cycle.

Activity (a, d), mean arterial pressure (MAP: b, e) and heart rate (c, f) were measured over 60 h. Values plotted are hourly means (± SEM, n = 5) for groups of WT (a–c) and Vipr2−/− (d–f) mice. Solid lines represent data smoothing using the weighted average of the 9 nearest points [26]. The bars at the top of each panel indicate the dark period in black and the light period in white.

https://doi.org/10.1371/journal.pone.0009783.g001

thumbnail
Figure 2. Activity, blood pressure and heart rate in individual WT and Vipr2−/− mice in a light-dark cycle.

Activity (a, d), mean arterial pressure (MAP: b, e) and heart rate (c, f) were measured over 60 h in representative individual WT (a–c) and Vipr2−/− (d–f) mice. The bars at the top of each panel indicate the dark period in black and the light period in white.

https://doi.org/10.1371/journal.pone.0009783.g002

thumbnail
Figure 3. K-means clustering of the durations of periods of activity in WT mice in a LD cycle showing a bimodal distribution.

https://doi.org/10.1371/journal.pone.0009783.g003

In WT mice, periods of rest >3 h occurred predominantly during the inactive (light) period whereas the time spent in ultradian episodes of rest and activity was similar between day and night (Table 1). Vipr2−/− mice spent significantly more time than WT in ultradian episodes of rest, which occurred mostly during the light period, and significantly less time in rest periods >3 h. When transferred into constant (DD) conditions, Vipr2−/− mice continued to display significant 24 h periodicity in their locomotor activity (Figure S2), but this was less robust than in WT and ultradian cycles of activity and rest predominated (Figure S1). In contrast, WT mice continued to display robust circadian rhythms of locomotor activity, with long periods of rest occurring predominantly during light period (Table 1 and Figure S1).

thumbnail
Table 1. Time spent in short “ultradian” and long periods of rest and sleep.

https://doi.org/10.1371/journal.pone.0009783.t001

Effects of the Vipr2 mutation on BP and HR

Mean values of BP, HR and locomotor activity in Vipr2−/− and WT mice maintained on a light-dark (LD) cycle are listed in Table S1, with periodogram analysis shown in Figure S2. Diurnal variations in HR and BP closely followed the activity profiles of animals of the respective genotypes, with Vipr2−/− mice displaying lower average levels of HR and BP than WT in the last 8 h of the dark period (Figure 1a–f). Examination of records from individual animals showed that BP and HR fluctuated much more dramatically between periods of activity and rest than they did across the 24 h cycle (Figure 2a–f). Thus, the timing of episodes of activity and rest across the day was clearly a major factor contributing to the diurnal rhythm of BP and HR. K-means clustering analysis showed that the durations of periods of elevated BP and HR were distributed bimodally in all mice, consistent with the bimodal distribution of periods of activity (data not shown).

To determine whether there were underlying circadian rhythms in BP and HR independent of the influence of activity, we analyzed data from WT and KO mice using only measurements from times when the corresponding activity signal was 0 [26], [27]. This analysis indicated that in LD, there was a significant diurnal rhythm in resting HR in WT but not in Vipr2−/− mice, confirmed by chi-square periodogram analysis, which peaked at around the time of the light-dark transition (Figure 4). There was also modest diurnal rhythmicity in BP in both WT and Vipr2−/− animals. In constant (DD) conditions, there were significant circadian rhythms in resting HR and BP in WT mice but not in Vipr2−/− animals (Figure 4).

thumbnail
Figure 4. Rhythms of resting blood pressure and heart rate.

Panels a – d show mean (± S.E.M., n = 5) heart rate (a, c) and MAP (b, d) during periods of inactivity, averaged over 2 h time periods across 24 h, extracted from 10 day recordings from WT (-•-) and Vipr2−/− (-□-) mice in a light-dark cycle (LD: a, b) and in constant conditions (DD: c, d). The bars at the top indicate the dark period in black and the light period in white (a, b) or subjective night in black and subjective day in gray (c, d). In (e–l), average Chi-square periodograms were constructed (using a formula appropriate for records containing gaps) from “binned” heart rate (e, g, i, k) and MAP (f, h, j, l) records (4 min bins) from WT (e–h) and Vipr2−/− (i–l) mice (n = 5 of each genotype) over 10 day periods in a light-dark cycle (LD: e, f, i, j) and in constant conditions (DD: g, h, k, l). The Qp statistic was calculated for periods between 5 and 28 h. The Qp statistic represents the degree to which each period is present in the data, after accounting for differences due to chance. Dashed lines indicate the value of Qp required to achieve statistical significance (P<0.01). Where significant rhythmicity was found, the estimate of τ, the circadian period, is shown.

https://doi.org/10.1371/journal.pone.0009783.g004

We used two statistical approaches to determine the relative contributions of locomotor activity and the day/night cycle to variability in HR and BP. Using the squared correlation coefficient (R2) measure for explained variance [28] we found that the day/night cycle explained less of the variability in heart rate and blood pressure in WT mice than locomotor activity in all conditions (Table S2); in Vipr2−/− mice the contribution of the day/night cycle was very small (less than 5%). We also calculated information gain, using the Kullback-Leibler divergence, which does not assume a linear relationship [29]. This produced similar results, with the activity signal providing more information gain about HR and BP than the time of day in all conditions (data not shown).

Effects of the Vipr2 mutation on sleep

Consistent with locomotor activity data, there was an altered diurnal rhythm of sleep and wakefulness in Vipr2−/− mice compared to WT (Figures 5,6). WT mice were predominantly awake in the dark phase and asleep during the light phase, with fewer but significantly longer wake bouts during the dark period, chiefly due to the concentrated and prolonged activity immediately following lights-off (Figures 5,6 and Table S3). In Vipr2−/− mice, bouts of sleep and wakefulness were more similar in number and duration between the dark and light phases. Vipr2−/− mice also demonstrated more stage shifts between wake, NREM and REM sleep and more arousals than WT mice. Over 24 hours, Vipr2−/− mice had an average of 46 minutes more NREM sleep time compared to WT mice. REM sleep, however, was similar between the two genotypes over the 24 hours.

thumbnail
Figure 5. Sleep patterns of individual Vipr2−/− and wild-type mice under entrained (LD) and constant (DD) conditions.

Representative records of wake/sleep patterns from individual WT (a, c) and Vipr2−/− (b, d) mice in LD (a, b) and DD (c, d) conditions. Values plotted are the percentage of each 5 min interval during which animals were awake; the bars at the top indicate the dark period in black and the light period in white (a, b) or subjective night in black and subjective day in gray (c, d).

https://doi.org/10.1371/journal.pone.0009783.g005

thumbnail
Figure 6. Sleep patterns of Vipr2−/− and wild-type mice under entrained (LD) conditions.

Baseline sleep patterns for six wild-type control mice (black symbols) and seven Vipr2−/− (white symbols) under entrained (LD 12∶12) conditions are shown. In a, c and e, the time in each sleep stage is shown as a percentage of the recording time in 2 h intervals (mean ± SEM). The bars at the top indicate the dark period in black and the light period in white. * indicates significant differences (P<0.05) between mouse genotypes at that time point (RM-ANOVA df  = 1,11; Fisher's post-hoc). b, d and f show sleep times averaged over the entire 24 h recording period as well as during both the 12 h light and 12 h dark phase (mean ± SEM). Significant differences between genotypes are shown: *  =  P<0.05, **  =  P<0.005, ***  =  P<0.0005; t test for independent samples. NREM  =  non-rapid eye movement; REM  =  rapid eye movement.

https://doi.org/10.1371/journal.pone.0009783.g006

As with LA data, the duration of periods of sleep (REM + NREM) was best fitted by a bimodal distribution, with two components of short (1.60±0.67 h; mean ± SD) and long (5.31±1.51 h; mean ± SD) duration; the time spent in periods of sleep greater and less than 3 h in duration robustly distinguished the behavior of Vipr2−/− mice, which spent significantly less time in periods of sleep >3 h during the light phase and more time in periods of sleep <3 h during the dark phase than WT (Table 1). In constant (DD) conditions, WT mice continued to display robust circadian rhythms of sleep and wakefulness, with periods of sleep occurring predominantly during the subjective day, whereas in Vipr2−/− mice short “ultradian” cycles of sleep and wake predominated at all times (Table 1, Figure 5d). During conditions of constant darkness, total wake (Vipr2−/− 56.2%±1.7%, wt 55.0%±0.9%; P>0.05, t test), NREM (Vipr2−/− 39.4%±1.5%, wt 40.1%±1.0%; P>0.05, t test), and REM (Vipr2−/− 4.4%±0.3%, wt 4.9%±0.2%; P>0.05, t test) sleep times and total NREM delta energy did not differ between Vipr2−/− and WT mice.

Discussion

In this study we have shown that Vipr2−/− mice, which lack a robust SCN clock, display altered diurnal rhythms of locomotor activity, sleep and wakefulness compared to WT when entrained to a light-dark cycle. In WT mice, periods of activity and of wakefulness were largely confined to the dark period whereas Vipr2−/− mice exhibited less sustained activity in the dark period and more prominent short cycles of activity/rest and sleep/wake than WT in both light and dark periods. In constant conditions, ultradian cycles of activity/rest and sleep/wake predominated in Vipr2−/− mice, whereas WT mice displayed robust circadian rhythms of behavior. The behavioral phenotype of Vipr2−/− mice was similar to that of other mice with mutations that disable the circadian clock in all tissues of the body. Like Vipr2−/− mice, Bmal1 null [21], mPer1, mPer2 double mutants [30] and Cry1, Cry2 double mutants [31] all display altered diurnal rhythms of activity, sleep and wakefulness in a LD cycle but become arrhythmic in constant conditions, displaying ultradian bouts of sleep and wakefulness. These ultradian rhythms appear not to be driven by an oscillatory mechanism; rather, the duration of periods of inactivity appears to be determined stochastically (randomly) [23], [32]. Studies on sleep and locomotor activity in mice [22], [33] and rats [34] with SCN lesions have used animals that were behaviorally arrhythmic in LD, suggesting that pathways required for the suppression of activity (“masking”) by light were interrupted, either through collateral damage from the lesions or because these pathways pass through the SCN. Vipr2−/− mice are therefore more informative than lesioned animals in defining the role of the SCN in the control of sleep and wakefulness and other aspects of physiology and behavior.

The importance of locomotor activity as a determinant of BP and HR in mice has been demonstrated in previous studies [26], [27], but our analysis is the first to assess the contribution of activity to circadian rhythms of cardiovascular physiology. There were robust diurnal rhythms in HR and BP in Vipr2−/− mice lacking a functional SCN clock, but these were largely due to rhythms of activity. When the contribution of locomotor activity was taken into consideration by analyzing only data from periods when animals were at rest, we found significant residual rhythms in resting HR in WT mice but not in Vipr2−/− mutants. There was also evidence for a modest influence of the circadian clock on resting BP, which was rhythmic in WT animals but not in Vipr2−/− mutants in constant conditions. A rhythm of resting BP was seen in both WT and Vipr2−/− mice in a LD cycle. We speculate that the diurnal rhythms of physiology (including activity and feeding), imposed by a LD cycle, may influence vascular tone through the entrainment of peripheral circadian clocks.

Studies of the circadian control of cardiovascular function in human volunteers, in contrast to those in rodents, can use protocols that not only remove periodic influences from the environment but also remove influences due to periodic changes in behavior (activity, food intake and sleep/wakefulness) [35]. Consistent with our findings in mice, such human studies have provided evidence for an endogenous circadian rhythm of HR, independent of the effects of activity [36][40]. Circadian variation of BP was absent [38], [39], perhaps because the experimental subjects were prevented from engaging in physical activity or sleep and the rate of food intake was held constant across the day. Thus, in both rodents and humans, some aspects of cardiovascular function appear to be under direct circadian control, but others may be secondary to changes in behavior.

A number of published studies [41][47] have reported mutations in mice that attenuate diurnal or circadian variation in BP and HR. Suprachiasmatic nucleus lesions have also been reported to abolish circadian variation in blood pressure in rats [48], [49]. However, these studies did not take into account the influence of changes in patterns of locomotor activity in such animals. In one study that did take account of activity levels when analyzing the BP rhythm [26], an apparent effect of deficiency in β1 and β2-adrenergic receptors on circadian variation in BP was no longer evident when the effects of locomotor activity were corrected for. Our findings emphasize the importance of considering the effects of activity when analyzing BP and HR data and indicate that the main influence of the circadian clock on cardiovascular physiology is mediated indirectly, through effects on arousal.

If rodents are to be useful tools for translational medicine, it is important that the findings of experimental studies in preclinical models and in humans be consistent. Activity and rest exert much more profound influences on physiology in small rodents than they do in humans. Nevertheless, our findings indicate that, with appropriate methods of analysis, mouse cardiovascular data is consistent with that obtained in human volunteers under rigorously controlled conditions. Evidence from clinical studies suggests that disturbances in sleep and sleep disorders play a role in the morbidity of cardiovascular disease [50], [51] Future studies of the influence of sleep and wakefulness on cardiovascular physiology in rodents may help to explain these links.

Supporting Information

Figure S1.

Activity (a, d), HR (b, e) and MAP (c, f) in representative individual WT (a–c) and Vipr2−/− (d–f) mice in DD conditions. The bars at the top of each panel indicate the subjective night in gray and the subjective night in black.

https://doi.org/10.1371/journal.pone.0009783.s001

(3.80 MB TIF)

Figure S2.

Periodogram analysis of activity, HR and MAP. Chi-square periodograms of activity (a–d), HR (e–h) and BP (i–l) from WT (a, c, e, g, i, k) and Vipr2−/− (b, d, f, h, j, l) mice (n = 5 of each genotype) over 10 day periods in a light-dark cycle (LD: a, b, e, f, i, j) and in constant conditions (DD: c, d, g, h, k, l). The Qp statistic was calculated for periods between 5 and 28 h. Dashed lines indicate the value of Qp required to achieve statistical significance (P<0.01).

https://doi.org/10.1371/journal.pone.0009783.s002

(3.31 MB TIF)

Table S1.

Summary of basic hemodynamics and activity for wild-type and Vipr2−/−mice under entrained (LD 12∶12) conditions. * P<0.05, ** P<0.005, compared with WT (unpaired t-test) †P<0.05, ‡P<0.01, §P<0.005, ¶P<0.001 compared with corresponding value in the light period (paired t-test).

https://doi.org/10.1371/journal.pone.0009783.s003

(0.07 MB PDF)

Table S2.

Relative contributions of locomotor activity and the day/night cycle to variability in HR and BP. Percentage (mean ± SEM) of the total variance in HR and BP explained by locomotor activity and the day/night cycle, calculated using the squared correlation coefficient (R2) measure for explained variance.

https://doi.org/10.1371/journal.pone.0009783.s004

(0.08 MB PDF)

Table S3.

Number and average length of wake and sleep bouts greater than 30 sec. for seven Vipr2−/− and six wild-type mice under entrained (LD 12∶12) conditions.*P<0.05, †P<0.02, ‡P<0.01, §P<0.005 compared with WT.

https://doi.org/10.1371/journal.pone.0009783.s005

(0.08 MB PDF)

Author Contributions

Conceived and designed the experiments: WJS EN DA FWT MCH PCZ AJH. Performed the experiments: WJS EN GAB. Analyzed the data: WJS EN SKB DA FWT MCH PCZ AJH. Wrote the paper: WJS EN JRS AJH.

References

  1. 1. Green CB, Takahashi JS, Bass J (2008) The meter of metabolism. Cell 134: 728–742.
  2. 2. Turek FW, Dugovic C, Laposky A (2005) Master Circadian Clock, Master Circadian Rhythm. In: Kryger MH, Roth T, Dement WC, editors. Principles and Practice of Sleep Medicine, Fourth Edition. New York: WB Saunders. pp. 318–320. 4th ed.
  3. 3. Muller JE, Stone PH, Turi ZG, Rutherford JD, Czeisler CA, et al. (1985) Circadian variation in the frequency of onset of acute myocardial infarction. N Engl J Med 313: 1315–1322.
  4. 4. Arntz HR, Willich SN, Oeff M, Bruggemann T, Stern R, et al. (1993) Circadian variation of sudden cardiac death reflects age-related variability in ventricular fibrillation. Circulation 88: 2284–2289.
  5. 5. Elliott WJ (1998) Circadian variation in the timing of stroke onset: a meta-analysis. Stroke 29: 992–996.
  6. 6. Laposky AD, Shelton J, Bass J, Dugovic C, Perrino N, et al. (2006) Altered sleep regulation in leptin-deficient mice. Am J Physiol Regul Integr Comp Physiol 290: R894–903.
  7. 7. Laposky AD, Bradley MA, Williams DL, Bass J, Turek FW (2008) Sleep-wake regulation is altered in leptin-resistant (db/db) genetically obese and diabetic mice. Am J Physiol Regul Integr Comp Physiol 295: R2059–2066.
  8. 8. Martino TA, Oudit GY, Herzenberg AM, Tata N, Koletar MM, et al. (2008) Circadian rhythm disorganization produces profound cardiovascular and renal disease in hamsters. Am J Physiol Regul Integr Comp Physiol 294: R1675–1683.
  9. 9. Scott EM, Carter AM, Grant PJ (2008) Association between polymorphisms in the Clock gene, obesity and the metabolic syndrome in man. Int J Obes (Lond) 32: 658–662.
  10. 10. Penev PD, Kolker DE, Zee PC, Turek FW (1998) Chronic circadian desynchronization decreases the survival of animals with cardiomyopathic heart disease. Am J Physiol 275: H2334–2337.
  11. 11. Aton SJ, Colwell CS, Harmar AJ, Waschek J, Herzog ED (2005) Vasoactive intestinal polypeptide mediates circadian rhythmicity and synchrony in mammalian clock neurons. Nat Neurosci 8: 476–483.
  12. 12. Ciarleglio CM, Gamble KL, Axley JC, Strauss BR, Cohen JY, et al. (2009) Population encoding by circadian clock neurons organizes circadian behavior. J Neurosci 29: 1670–1676.
  13. 13. Brown TM, Colwell CS, Waschek JA, Piggins HD (2007) Disrupted neuronal activity rhythms in the suprachiasmatic nuclei of vasoactive intestinal polypeptide-deficient mice. J Neurophysiol 97: 2553–2558.
  14. 14. Maywood ES, Reddy AB, Wong GK, O'Neill JS, O'Brien JA, et al. (2006) Synchronization and maintenance of timekeeping in suprachiasmatic circadian clock cells by neuropeptidergic signaling. Curr Biol 16: 599–605.
  15. 15. Cutler DJ, Haraura M, Reed HE, Shen S, Sheward WJ, et al. (2003) The mouse VPAC2 receptor confers suprachiasmatic nuclei cellular rhythmicity and responsiveness to vasoactive intestinal polypeptide in vitro. Eur J Neurosci 17: 197–204.
  16. 16. Hughes AT, Guilding C, Lennox L, Samuels RE, McMahon DG, et al. (2008) Live imaging of altered period1 expression in the suprachiasmatic nuclei of Vipr2-/- mice. J Neurochem 106: 1646–1657.
  17. 17. Harmar AJ, Marston HM, Shen S, Spratt C, West KM, et al. (2002) The VPAC2 receptor is essential for circadian function in the mouse suprachiasmatic nuclei. Cell 109: 497–508.
  18. 18. Sheward WJ, Maywood ES, French KL, Horn JM, Hastings MH, et al. (2007) Entrainment to feeding but not to light: circadian phenotype of VPAC2 receptor-null mice. J Neurosci 27: 4351–4358.
  19. 19. Colwell CS, Michel S, Itri J, Rodriguez W, Tam J, et al. (2003) Disrupted circadian rhythms in VIP- and PHI-deficient mice. Am J Physiol Regul Integr Comp Physiol 285: R939–949.
  20. 20. Naylor E, Bergmann BM, Krauski K, Zee PC, Takahashi JS, et al. (2000) The circadian clock mutation alters sleep homeostasis in the mouse. J Neurosci 20: 8138–8143.
  21. 21. Laposky A, Easton A, Dugovic C, Walisser J, Bradfield C, et al. (2005) Deletion of the mammalian circadian clock gene BMAL1/Mop3 alters baseline sleep architecture and the response to sleep deprivation. Sleep 28: 395–409.
  22. 22. Easton A, Meerlo P, Bergmann B, Turek FW (2004) The suprachiasmatic nucleus regulates sleep timing and amount in mice. Sleep 27: 1307–1318.
  23. 23. Lehmann U (1976) Stochastic principles in the temporal control of activity behaviour. Int J Chronobiol 4: 223–266.
  24. 24. Pittendrigh CS, Daan S (1976) A functional analysis of circadian pacemakers in nocturnal rodents. I. The stability and lability of spontaneous frequency. J Comp Physiol [A] 106: 223–252.
  25. 25. Welsh DK, Engel EM, Richardson GS, Dement WC (1986) Precision of circadian wake and activity onset timing in the mouse. J Comp Physiol [A] 158: 827–834.
  26. 26. Kim SM, Huang Y, Qin Y, Mizel D, Schnermann J, et al. (2008) Persistence of circadian variation in arterial blood pressure in β1/β2-adrenergic receptor-deficient mice. Am J Physiol Regul Integr Comp Physiol 294: R1427–1434.
  27. 27. Van Vliet BN, Chafe LL, Montani JP (2003) Characteristics of 24 h telemetered blood pressure in eNOS-knockout and C57Bl/6J control mice. J Physiol 549: 313–325.
  28. 28. Nagelkerke NJD (1991) A Note on a General Definition of the Coefficient of Determination. Biometrika 78: 691–692.
  29. 29. Kullback S, Leibler RA (1951) On Information and Sufficiency. Ann Math Statist 22: 79–86.
  30. 30. Shiromani PJ, Xu M, Winston EM, Shiromani SN, Gerashchenko D, et al. (2004) Sleep rhythmicity and homeostasis in mice with targeted disruption of mPeriod genes. Am J Physiol Regul Integr Comp Physiol 287: R47–57.
  31. 31. Wisor JP, O'Hara BF, Terao A, Selby CP, Kilduff TS, et al. (2002) A role for cryptochromes in sleep regulation. BMC Neurosci 3: 20.
  32. 32. Bunger MK, Wilsbacher LD, Moran SM, Clendenin C, Radcliffe LA, et al. (2000) Mop3 is an essential component of the master circadian pacemaker in mammals. Cell 103: 1009–1017.
  33. 33. Ibuka N, Nihonmatsu I, Sekiguchi S (1980) Sleep-wakefulness rhythms in mice after suprachiasmatic nucleus lesions. Waking Sleeping 4: 167–173.
  34. 34. Mistlberger RE, Bergmann BM, Waldenar W, Rechtschaffen A (1983) Recovery sleep following sleep deprivation in intact and suprachiasmatic nuclei-lesioned rats. Sleep 6: 217–233.
  35. 35. Duffy JF, Dijk DJ (2002) Getting through to circadian oscillators: why use constant routines? J Biol Rhythms 17: 4–13.
  36. 36. Krauchi K, Wirz-Justice A (1994) Circadian rhythm of heat production, heart rate, and skin and core temperature under unmasking conditions in men. Am J Physiol 267: R819–829.
  37. 37. Vandewalle G, Middleton B, Rajaratnam SM, Stone BM, Thorleifsdottir B, et al. (2007) Robust circadian rhythm in heart rate and its variability: influence of exogenous melatonin and photoperiod. J Sleep Res 16: 148–155.
  38. 38. Kerkhof GA, Van Dongen HP, Bobbert AC (1998) Absence of endogenous circadian rhythmicity in blood pressure? Am J Hypertens 11: 373–377.
  39. 39. Van Dongen HP, Maislin G, Kerkhof GA (2001) Repeated assessment of the endogenous 24-hour profile of blood pressure under constant routine. Chronobiol Int 18: 85–98.
  40. 40. Scheer FA, van Doornen LJ, Buijs RM (1999) Light and diurnal cycle affect human heart rate: possible role for the circadian pacemaker. J Biol Rhythms 14: 202–212.
  41. 41. Curtis AM, Cheng Y, Kapoor S, Reilly D, Price TS, et al. (2007) Circadian variation of blood pressure and the vascular response to asynchronous stress. Proc Natl Acad Sci U S A 104: 3450–3455.
  42. 42. Wang N, Yang G, Jia Z, Zhang H, Aoyagi T, et al. (2008) Vascular PPARγ controls circadian variation in blood pressure and heart rate through Bmal1. Cell Metab 8: 482–491.
  43. 43. Swoap SJ, Weinshenker D, Palmiter RD, Garber G (2004) Dbh(−/−) mice are hypotensive, have altered circadian rhythms, and have abnormal responses to dieting and stress. Am J Physiol Regul Integr Comp Physiol 286: R108–113.
  44. 44. Sei H, Oishi K, Chikahisa S, Kitaoka K, Takeda E, et al. (2008) Diurnal amplitudes of arterial pressure and heart rate are dampened in Clock mutant mice and adrenalectomized mice. Endocrinology 149: 3576–3580.
  45. 45. Masuki S, Todo T, Nakano Y, Okamura H, Nose H (2005) Reduced α-adrenoceptor responsiveness and enhanced baroreflex sensitivity in Cry-deficient mice lacking a biological clock. J Physiol 566: 213–224.
  46. 46. Kunieda T, Minamino T, Miura K, Katsuno T, Tateno K, et al. (2008) Reduced nitric oxide causes age-associated impairment of circadian rhythmicity. Circ Res 102: 607–614.
  47. 47. Su W, Guo Z, Randall DC, Cassis L, Brown DR, et al. (2008) Hypertension and disrupted blood pressure circadian rhythm in type 2 diabetic db/db mice. Am J Physiol Heart Circ Physiol 295: H1634–1641.
  48. 48. Janssen BJ, Tyssen CM, Duindam H, Rietveld WJ (1994) Suprachiasmatic lesions eliminate 24-h blood pressure variability in rats. Physiol Behav 55: 307–311.
  49. 49. Sano H, Hayashi H, Makino M, Takezawa H, Hirai M, et al. (1995) Effects of suprachiasmatic lesions on circadian rhythms of blood pressure, heart rate and locomotor activity in the rat. Jpn Circ J 59: 565–573.
  50. 50. Knutson KL, Van Cauter E, Rathouz PJ, Yan LL, Hulley SB, et al. (2009) Association Between Sleep and Blood Pressure in Midlife: The CARDIA Sleep Study. Arch Intern Med 169: 1055–1061.
  51. 51. Malhotra A, Loscalzo J (2009) Sleep and cardiovascular disease: an overview. Prog Cardiovasc Dis 51: 279–284.