http://jbr.sagepub.com Journal of Biological Rhythms RSS feed -- current issue December 2009 Journal of Biological Rhythms 0748-7304 http://jbr.sagepub.com:80/icons/banner/title.gif http://jbr.sagepub.com http://jbr.sagepub.com/cgi/reprint/24/6/443?rss=1 Thu, 19 Nov 2009 11:24:28 PST info:doi/10.1177/0748730409349141 Society for Research on Biological Rhythms 6 24 443 2009-12-01 443 Articles http://jbr.sagepub.com/cgi/content/abstract/24/6/444?rss=1 Different mosquito species show a full range of activity patterns, including diurnal, crepuscular, and nocturnal behaviors. Although activity and blood-feeding rhythms are controlled by the circadian clock, it is not yet known whether such species-specific differences in behavior are controlled directly by core clock genes or instead reflect differences in how the information of the central clock is translated into output signals. The authors have analyzed the circadian expression of clock genes in two important mosquito vectors of tropical diseases, Aedes aegypti and Culex quinquefasciatus . Although these two species show very different locomotor activity patterns and are estimated to have diverged more than 22 million years ago, they show conserved circadian expression patterns for all major cycling clock genes except mammalian-like cryptochrome2 (cry2). The results indicate that different mechanisms for cry2 regulation may exist for the two species. The authors speculate that the correlation between the differences in behavior between Ae. aegypti and Cx. quinquefasciatus and their corresponding cry2 mRNA profiles suggests a potential role for this clock gene in controlling species-specific rhythmic behavior. However, further work is needed to establish that this is the case as the different cry2 expression patterns might reflect differences between the Aedes and Culex lineages that are not directly related to changes in behavior.

]]> Thu, 19 Nov 2009 11:24:28 PST info:doi/10.1177/0748730409349169 Society for Research on Biological Rhythms 6 24 451 2009-12-01 444 Articles http://jbr.sagepub.com/cgi/content/abstract/24/6/452?rss=1 Daily light and temperature cycles are considered the most important zeitgebers for circadian clocks in many organisms. The influence of each single zeitgeber on the clock has been well studied, but little is known about any synergistic effects of both zeitgebers on the clock. In nature, light and temperature show characteristic daily oscillations with the temperature rising during the light phase and reaching its maximum in the late afternoon. Here, we studied behavioral and molecular rhythms in Drosophila melanogaster under simulated natural low light-dark (LD) and temperature (T) cycles that typically occur during the September equinox. Wild-type flies were either subjected to simulated LD or T cycles alone or to a combination of both. Behavioral rhythms and molecular rhythms in the different clock neurons were assessed under the 3 different conditions. Although behavioral rhythms entrained to all conditions, the rhythms were most robust under the combination of LD and T cycles. The clock neurons responded differently to LD and T cycles. Some were not entrained by T cycles alone; others were only slightly entrained by LD cycles alone. The amplitude of the molecular cycling was not different between LD alone and T cycles alone; but LD alone could set the pacemaker neurons to similar phases, whereas T cycles alone could not. The combination of the 2 zeitgebers entrained all clock neurons not only with similar phase but also enhanced the amplitude of Timeless cycling in the majority of cells. Our results show that the 2 zeitgebers synergistically entrain behavioral and molecular rhythms of Drosophila melanogaster.

]]> Thu, 19 Nov 2009 11:24:28 PST info:doi/10.1177/0748730409348551 Society for Research on Biological Rhythms 6 24 464 2009-12-01 452 Articles http://jbr.sagepub.com/cgi/content/abstract/24/6/465?rss=1 The impact of the circadian timing system upon behavior and physiology is pervasive, and previous evidence suggests a circadian modulation of drug-seeking behavior and responsiveness to drugs of abuse. To further characterize daily rhythms in reward and to extend these observations to natural reinforcers, diurnal variation in the rewarding value of sex and systemic amphetamine was assessed via the conditioned place preference paradigm. To identify potential mechanisms for rhythmicity in reward, levels of tyrosine hydroxylase (TH) and core clock proteins (Period1 and Bmal1) were examined across the day in the ventral tegmental area (VTA) and the nucleus accumbens (NAcc). During an initial training period, male rat sexual performance varied diurnally with a nadir near the light-to-dark transition. Diurnal rhythms also were evident for both mating and amphetamine-related reward. However, the rhythms for these particular stimuli exhibited differences in their pattern of timing, with sex reward showing a peak during the middark period and amphetamine reward exhibiting high points during the late night and midday with a nadir prior to the light-to-dark transition. A diurnal variation also was seen for the locomotor-activating effect of acute amphetamine administration with a peak during the late night. Western blot analyses revealed that Period1 and Bmal1 protein levels were rhythmic in the NAcc but not in the VTA. By contrast, TH protein levels were rhythmic in both the NAcc and VTA, but the peaks differed with that in the NAcc coinciding with the peak of sex reward and that in the VTA associated with the peak in amphetamine reward. Thus, it appears that both natural and drug-related reward vary in a diurnal fashion but differ in the timing of their peak and nadir levels. The phase relationships between reward rhythms and mesolimbic TH protein levels suggest that an increased capacity for the release of dopamine in the NAcc may underlie the rhythms in sex-related reward, while amphetamine-related reward occurs at a time when the likelihood of evoked NAcc DA release is relatively low.

]]> Thu, 19 Nov 2009 11:24:28 PST info:doi/10.1177/0748730409346657 Society for Research on Biological Rhythms 6 24 476 2009-12-01 465 Articles http://jbr.sagepub.com/cgi/content/abstract/24/6/477?rss=1 The SCN of the hypothalamus contains a major pacemaker, which exhibits 24-h rhythms in electrical impulse frequency. Although it is known that SCN electrical activity is high during the day and low during the night, the precise relationship between electrical activity and behavioral rhythms is almost entirely unknown. The authors performed long-term recordings of SCN multiple unit activity with the aid of implanted microelectrodes in parallel with the drinking activity in freely moving mice. The animals were kept in a 12h:12h light-dark cycle (LD 12:12) and in short-day (LD 8:16) and long-day photoperiods (LD 16:8). Onsets and offsets of behavioral activity occurred when SCN discharge was around half-maximum value. Of the onsets 80%, and of the offsets 62%, occurred when SCN electrical activity differed less than 15% from the half-maximum electrical activity levels. Transitions between rest and activity could be described by a sigmoid shaped probability curve with Hill coefficients of 7.0 for onsets and 5.7 for offsets. The similarity in the onset and offset levels shows an absence of hysteresis in the control of behavioral activity by the SCN. Exposure to short- or long-day photoperiods induced significant alterations in the waveform of electrical activity but did not affect SCN electrical activity levels at which behavioral transitions occurred. In all photoperiods, the SCN signal was skewed with more rapid discharge changes during onsets (19% per hour) than offsets (11% per hour). The precision of the circadian system appears optimized, as transitions between behavioral activity and rest occur when the change in SCN electrical activity is maximal, both during the declining and rising phase. The authors conclude that transitions in behavioral state can be described by a probability function around half-maximum electrical activity levels and that the parameters of the SCN, predicting onset and offset of behavior, are remarkably insensitive to environmental conditions.

]]> Thu, 19 Nov 2009 11:24:28 PST info:doi/10.1177/0748730409349895 Society for Research on Biological Rhythms 6 24 487 2009-12-01 477 Articles http://jbr.sagepub.com/cgi/content/abstract/24/6/488?rss=1 Calbindin-D28K (CalB)—containing cells form a distinct cluster within the core of the hamster suprachiasmatic nucleus (SCN). These cells are directly retinorecipient but lack detectable rhythms in clock gene expression or electrical activity. In studies exploring SCN connectivity using double-label immunochemistry, we previously reported an absence of contacts among CalB fibers and vasopressin (VP) cells in animals sacrificed during the day. Here, we explored circadian variations in CalB-immunoreactivity (-ir) and re-examined the connections between CalB and other SCN cell types at zeitgeber times (ZT) 4 and 14. The results reveal a circadian rhythm of CalB-ir in fibers of SCN cells with high expression during the night and subjective night and low expression during the day and subjective day. This circadian difference is not seen in the other brain regions studied. Significantly more appositions were detected between CalB fibers and VP cells during the night than during the day, while circadian variation in numbers of contacts was not seen between CalB fibers and vasoactive intestinal polypeptide (VIP), cholecystokinin (CCK), or gastrin-releasing peptide (GRP) cells. There was no detectable variation in appositions from any peptidergic fiber type onto CalB cells. The present findings suggest that CalB cells relay photic information to VP oscillator cells of the SCN shell in a temporally gated manner.

]]> Thu, 19 Nov 2009 11:24:28 PST info:doi/10.1177/0748730409350876 Society for Research on Biological Rhythms 6 24 496 2009-12-01 488 Articles http://jbr.sagepub.com/cgi/content/abstract/24/6/497?rss=1 Masking, measured as a decrease in nocturnal rodent wheel running, is a visual system response to rod/cone and retinal ganglion cell photoreception. Here, the authors show that a few milliseconds of light are sufficient to initiate masking, which continues for many minutes without additional photic stimulation. C57J/B6 mice were tested using flash stimuli previously shown to elicit large circadian rhythm phase shifts. Ten flashes, 2 msec each and equally distributed over 5 min, activate locomotor suppression that endures for an additional 25 to 35 min in the dark and does not differ in magnitude or duration from that elicited by 5-min saturating light pulse. Locomotor activity by mice without access to running wheels is also suppressed by light flashes. The effects of various light flash patterns on mouse locomotor suppression are similar to those previously described for hamster phase shifts. Video analysis of active mice indicates that light flashes initiated at ZT13 rapidly induce an interval of behavioral quiescence that lasts about 10 min at which time the animals assume a typical sleep posture that is maintained for an additional 25 min. Thus, the period coincident with light-induced wheel running suppression appears to consist of two distinct behavioral states, one interval during which locomotor quiescence is initiated and maintained, followed by a second interval characterized by behavioral sleep. Given this sequence effected by light stimulation, we suggest that it be referred to as "photosomnolence," the term reflecting upon both the nature of the stimulus and the associated behavioral change.

]]> Thu, 19 Nov 2009 11:24:28 PST info:doi/10.1177/0748730409349059 Society for Research on Biological Rhythms 6 24 508 2009-12-01 497 Articles http://jbr.sagepub.com/cgi/content/abstract/24/6/509?rss=1 Seasonal changes in numerous aspects of mammalian immune function arise as a result of the annual variation in environmental day length (photoperiod), but it is not known if absolute photoperiod or relative change in photoperiod drives these changes. This experiment tested the hypothesis that an individual’s history of exposure to day length determines immune responses to ambiguous, intermediate-duration day lengths. Immunological (blood leukocytes, delayed-type hypersensitivity reactions [DTH]), reproductive, and adrenocortical responses were assessed in adult Siberian hamsters (Phodopus sungorus) that had been raised initially in categorically long (15-h light/day; 15L) or short (9L) photoperiods and were subsequently transferred to 1 of 7 cardinal experimental photoperiods between 9L and 15L, inclusive. Initial photoperiod history interacted with contemporary experimental photoperiods to determine reproductive responses: 11L, 12L, and 13L caused gonadal regression in hamsters previously exposed to 15L, but elicited growth in hamsters previously in 9L. In hamsters with a 15L photoperiod history, photoperiods ≤ 11L elicited sustained enhancement of DTH responses, whereas in hamsters with a 9L photoperiod history, DTH responses were largely unaffected by increases in day length. Enhancement and suppression of blood leukocyte concentrations occurred at 13L in hamsters with photoperiod histories of 15L and 9L, respectively; however, prior exposure to 9L imparted marked hysteresis effects, which suppressed baseline leukocyte concentrations. Cortisol concentrations were only enhanced in 15L hamsters transferred to 9L and, in common with DTH, were unaffected by photoperiod treatments in hamsters with a 9L photoperiod history. Photoperiod history acquired in adulthood impacts immune responses to photoperiod, but manifests in a markedly dissimilar fashion as compared to the reproductive system. Prior photoperiod exposure has an enduring impact on the ability of the immune system to respond to subsequent changes in day length.

]]> Thu, 19 Nov 2009 11:24:28 PST info:doi/10.1177/0748730409349714 Society for Research on Biological Rhythms 6 24 522 2009-12-01 509 Articles http://jbr.sagepub.com/cgi/content/abstract/24/6/523?rss=1 We introduce a physiology-based mathematical model of sleep-wake cycles, suggesting a novel mechanism of homeostatic regulation of sleep. In this model, the homeostatic process is determined by the neuropeptide hypocretin/ orexin, which is a cotransmitter of the lateral hypothalamus. Hypocretin/ orexin neurons are silent during sleep and active during wakefulness. Firing of these neurons is sustained by reciprocal excitatory synaptic connections with local glutamate interneurons. This feedback loop has been simulated with a minimal but physiologically plausible model. It includes 2 simplified Hodgkin-Huxley type neurons that are connected via glutamate synapses, one of which additionally contains hypocretin/orexin as the functionally relevant cotransmitter. During the active state (wakefulness), the synaptic efficacy of hypocretin/orexin declines as a result of the ongoing firing. It recovers during the silent (sleep) state. We demonstrate that these homeostatic changes can account for typical alterations of sleep-wake transitions, for example, introduced by napping, sleep deprivation, or alarm clock. In combination with a circadian input, the model mimics the transitions between silent and firing states in agreement with sleep-wake cycles. These simulation results support the concept of state-dependent alterations of hypocretin/orexin effects as an important homeostatic process in sleep-wake regulation, although additional mechanisms can be involved.

]]> Thu, 19 Nov 2009 11:24:28 PST info:doi/10.1177/0748730409346655 Society for Research on Biological Rhythms 6 24 535 2009-12-01 523 Articles