Metabolic cycles are linked to the cardiovascular diurnal rhythm in rats with essential hypertension

Background

The loss of diurnal rhythm in blood pressure (BP) is an important predictor of end-organ damage in hypertensive and diabetic patients. Recent evidence has suggested that two major physiological circadian rhythms, the metabolic and cardiovascular rhythms, are subject to regulation by overlapping molecular pathways, indicating that dysregulation of metabolic cycles could desynchronize the normal diurnal rhythm of BP with the daily light/dark cycle. However, little is known about the impact of changes in metabolic cycles on BP diurnal rhythm.

Methodology/Principal Findings

To test the hypothesis that feeding-fasting cycles could affect the diurnal pattern of BP, we used spontaneously hypertensive rats (SHR) which develop essential hypertension with disrupted diurnal BP rhythms and examined whether abnormal BP rhythms in SHR were caused by alteration in the daily feeding rhythm. We found that SHR exhibit attenuated feeding rhythm which accompanies disrupted rhythms in metabolic gene expression not only in metabolic tissues but also in cardiovascular tissues. More importantly, the correction of abnormal feeding rhythms in SHR restored the daily BP rhythm and was accompanied by changes in the timing of expression of key circadian and metabolic genes in cardiovascular tissues.

Conclusions/Significance

These results indicate that the metabolic cycle is an important determinant of the cardiovascular diurnal rhythm and that disrupted BP rhythms in hypertensive patients can be normalized by manipulating feeding cycles.     

Circadian rhythm mutants of the prokaryoticSynechococcus RF-1

Synechococcus RF-1 established circadian rhythms in nitrogen fixation and leucine uptake when growing in a diurnal light/dark regimen. The rhythms persisted in subsequent uniform light/light conditions. In order to analyze the circadian rhythm at the genetic level, mutants were induced by N-methyl-N-nitro-N-nitrosoguanidine and then isolated by procedures with the circadian nitrogen-fixing rhythm as a selecton marker. Characterization of the mutants with respect to the circadian rhythm indicated that some mutants were abnormal only in the nitrogen-fixing rhythm, while some simultaneously lost the ability to establish the nitrogen-fixing and leucine-uptake rhythms. The physiological properties of the circadian rhythm were compared. The genetic potential of the mutants that were abnormal in both rhythms is emphasized.     

Relationship between a metabolic rhythm and emergence rhythm in Drosophila melanogaster

Oxygen consumption and lactic acid dehydrogenase (LDH) activity were determined for Drosophila melanogaster pupae and pharate adults exposed to 12 : 12 or 1 : 23 light-dark (LD) regime. Bimodal circadian fluctuations of oxygen consumption were found in pupae and pharate adults exposed to either LD regime and organisms appeared to demonstrate an anticipatory change in oxygen consumption associated with change in illumination. The oxygen-consumption trend for the entire period spent in the puparium showed a high at the time of emergence, but the diurnal rhythm showed a low at the time of emergence suggesting that emergence occurs at a low in the diurnal cycle. Emergence maximum showed a 3 hr lead over the oxygen-consumption maximum. Changing the LD regime produced similar changes in the phasing of both oxygen consumption and emergence rhythms. LDH activity did not demonstrate a detectable circadian rhythm but did show a steady decrease during pupal and pharate adult development.     

浅谈海洋无脊椎动物的生物钟

一般动物(含人类)的生理活动和行为都有不同程度的周期性(periodicity)或节奏性(rhythemicity),而这些现象的表现并不一致:有的较明显,很易发觉(如昼夜垂直移动、体色变化等),而有的较隐蔽,不易发现(如视网膜色素移动等)。生物钟(biological clock)是受时间机制(timing mechanism)调节或控制的一种节奏性或周期性的生理活动(较为隐蔽)     

Role of photoperiodicity and circadian rhythm of glucocorticoids in synchronizing the fluctuations in free-radical oxidation of lipids in rats

A biphasic circadian rhythm in the content of liver lipid peroxidation products has been demonstrated in male Wistar rats housed under the conditions of 12L: 12D, with 3 hours of morning and evening twilight. Maxima of the concentration of the products were observed in the morning and early at night. The rhythm of lipid anti-oxidative activity was found in an anti-phase. Inversion of both the L: D cycle and glucocorticoid circadian rhythms (cortisol injections) led after 14-16 days to the same shifts in the rhythm of anti-oxidative activity. The data indicate that glucocorticoids modulate the diurnal rhythms of lipid anti-oxidative activity and may be responsible for the shifts in the rhythms of free radical oxidation, induced by inversion of the L: D cycle.     

Diurnal rhythm of male–male combat behavior in the bean bug Riptortus pedestris (Heteroptera: Alydidae)

In many insects, mating is affected by the day–night cycle, i.e., diurnal rhythm. Although there are many reports that mating and other reproductive behaviors are controlled by daily rhythms in various taxonomic insect species, little attention has been paid to the effect of daily rhythms on male fighting behavior. Here, we investigate whether the frequency and escalation of male–male aggressive interaction exhibit diurnal rhythms under a long‐day condition in the bean bug Riptortus pedestris. Despite the fact that male aggressive behaviors were most often observed in the middle of the later half of light periods, no interaction was found between escalation of fighting and the time period. The results, at least, suggest that male aggressive behaviors are influenced by diurnal rhythms like other reproductive behaviors in R. pedestris.     

Association of worse prognosis with an aberrant diurnal cortisol rhythm in patients with advanced lung cancer

A flatter diurnal rhythm of cortisol has been reported to be associated with early mortality in patients with metastatic breast cancer. The clinical stage of disease at the time of diagnosis and the patient's performance status (PS) are known to be important prognostic factors for lung cancer (LC) survival. The authors examined the relationship between diurnal cortisol rhythms and these prognostic factors in patients with advanced LC. Cortisol concentrations were measured in saliva samples collected from 52 patients (37 males/15 females) with advanced LC and from 56 healthy subjects (32 males/24 females) to characterize the diurnal cortisol rhythm, specifically the cortisol awakening response (CAR) and diurnal cortisol decline (DCD). Variations of CAR and DCD in the patients were analyzed according to their clinical disease stage and PS score, and the differences in CAR and DCD between patients and healthy controls were compared. The patient group showed significantly reduced diurnal cortisol secretory activity and rhythmicity, compared with healthy controls. When the patients were subgrouped according to their clinical disease stage, patients with stage 4 disease showed significantly reduced CAR and flatter DCD compared with the healthy controls. However, the CAR and DCD in patients with stage 3a and 3b disease were comparable to those of healthy controls. Neither the CAR nor the DCD showed stepwise changes as the disease stage worsened. When patients were subgrouped according to their Eastern Cooperative Oncology Group (ECOG) PS score, there was stepwise reduction in the CAR and flattening of the DCD as the PS score increased. Both an abolished CAR and a flattened DCD were common in patients with ECOG PS scores of 3 and 4. These results indicate that alteration of the diurnal cortisol rhythm in patients with advanced LC is more closely associated with their PS score than with their clinical disease stage. Gradual alteration of the CAR and DCD, indicative of loss of 24-h cortisol rhythm, in concert with increase in PS score implies that endogenous circadian rhythms may also be disintegrating as the PS score worsens in these patients. (Author correspondence: ryunsup@yahoo.co.kr ).     

Diurnal rhythm in mRNA expression of genes encoding amino acid transporter and circadian gene cry in intestinal mucosa of piglets

Long chain PUFA contents in plasma and liver both exhibited diurnal rhythms in pigs. However, whether mRNA expression of amino acid transporter and circadian gene Cry in intestinal mucosa is also rhythmic is yet to be known. The purpose of this study aims to investigate the diurnal rhythm in mRNA expression of genes encoding amino acid transporter and whether their rhythm was related to the expression of circadian gene Cry in intestinal mucosa of piglets. Thirty-six piglets (Duroc?×?Landrace?×?Large Yorkshire) at the age of 35 days were selected and fed for three weeks, and then samples were collected at 3:00 am (Clo3), 7:00 am (Clo7), 11:00 am (Clo11), 3:00 pm (Clo15), 7:00 pm (Clo19), and 11:00 pm (Clo23) at the age of 56 days. At each time point, small intestinal mucosa samples were collected from duodenum, jejunum, and ileum for detection of mRNA expression of the amino acid transporters and circadian gene Cry. The results showed that mRNA expression of most amino acid transporters in intestinal mucosa was higher at night and lower during the daytime. Expression of SLC1A2, SLC6A20, SLC7A1, and SLC6A14 in duodenal mucosa reached the peak at Clo3 and Clo7; the diurnal rhythm of expression of SLC1A2, SLC6A20, and SLC7A1 was similar to Cry1, while the diurnal rhythm of expression of SLC6A14 had a similar trend to Cry2. Expression of SLC16A10, SLC1A2, and SLC7A1 in jejunal mucosa reached the peak at Clo7, while SLC6A14 reached the peak at Clo3; the diurnal rhythm of expression of SLC1A2 showed a similarity with Cry1, while the diurnal rhythm of expression of SLC16A10, SLC7A1, and SLC6A14 was similar to Cry2. Expression of SLC6A14, SLC6A20, and SLC7A1 in ileal mucosa reached the peak at Clo3; the diurnal rhythm of expression of SLC6A20 has a similarity with Cry1, while the diurnal rhythm of expression of SLC7A1 and SLC6A14 was similar to Cry2. The results suggested that the mRNA expression of most genes encoding amino acid transporters exhibited diurnal rhythms in the intestinal mucosa of piglets, and SLC7A1, SLC6A14, and SLC1A2 have a similar rhythm with circadian clock genes Cry1 and 2, and they reached the peak at Clo3 and Clo7.     

Endogenous rhythms of haemolymph flow and cardiac performance in the crab Cancer magister

Heart rate and arterial haemolymph flow rates were measured in freshly trapped Dungeness crabs, Cancer magister, using a pulsed-Doppler flowmeter. In the laboratory, freshly collected subtidal crabs exhibited endogenous rhythms in both cardiac function and haemolymph flow through one or more arterial systems, of both tidal and diurnal periodicity. The strongest tidal rhythms were recorded in the sternal and paired anterolateral arteries. These endogenous rhythms of selective tissue perfusion are related to an underlying locomotor activity, but may also be involved with hormonal transport or feeding. Changes in both heart rate and stroke volume were responsible for the increases in haemolymph flow rates. These rhythms were not entrained by aerial exposure, since confinement of arhythmic crabs in intertidal cages did not re-entrain an endogenous tidal rhythm. Endogenous locomotory rhythms are known to be controlled by neurohormones released in cycles from the sinus gland on the eyestalk. These hormones may also control the endogenous cardiovascular rhythms, since these were abolished after eyestalk ablation in freshly collected Cancer magister. These results suggest that hormones synthesized and released by the X-organ/sinus gland complex may, together with pericardial hormones, play a role in modulation of crustacean cardiovascular function.     

TIDAL RHYTHMS: THE CLOCK CONTROL OF THE RHYTHMIC PHYSIOLOGY OF MARINE ORGANISMS

1. A great number of vital processes are rhythmic and the rhythms quite often persist in constant conditions. The best-known rhythms are circadian; much less is known about circalunadian rhythms, and this review was prepared in an attempt to rectify this deficiency. All through the article comparisons are drawn between circalunadian and circacian rhythms. 2. Activity rhythms. (a) The activity patterns of 28 intertidal animals are discussed. All describe a periodicity with a basic component of 24.8 hours, and this approximate period persists in the laboratory in constant light and temperature and in the absence of the tides. The duration of persistence ranges from a few cycles to months, and is a function of the species studied, the conditions imposed, and individual tenacity. (b) In those few cases where relatively long-term observations have been made, there is a trend for the period of the rhythm to become circatidal, or better, circalunadian. (c) The ‘desired’ phase relationship between rhythm and tidal cycle is species-specific. Geographical translocation experiments have shown that the phase is set by the local tides. (d) In some cases the amplitude of the persistent rhythm mimics the semidiurnal inequality of the tides. (e) In about a third of the species discussed, a circadian component has been found combined with the tidal component. Many of the other studies were of such short duration that a low-amplitude circadian component would have gone unnoticed. (f) The tidal rhythm is innate. However, the rhythm is (i) sometimes lacking in organisms living in non-tidal habitats, or (ii) fades after a spell of incarceration in constant conditions. Various treatments — some aperiodic — can induce the expression of the missing tidal rhythm. (g) In the green crab, removal of the eyestalks destroys the activity rhythm. 3. Vertical migration rhythms. (a) A rather surprisingly large number of intertidal animals have been found to undergo migration rhythms between the upper layers of the substratum and its surface. The movements are synchronized with the tides in nature, but most species have either been shown to be diurnal in constant conditions, or in cases where adequate testing has not been done, suspected of being so. (b) In only one species has confirming work shown that the fundamental frequency is truly tidal. This finding is especially important as it shows that tidal rhythms need only the single-cell level of organization for expression. Even at this level there appears to be a dictatorial override by a circadian clock. 4. Colour change. Low-amplitude tidal rhythms in colour change — superimposed on a more dominant circadian change — have been reported to be intrinsic in four species and inducible in a fifth. 5. Oxygen consumption. Tidal rhythms in oxygen consumption have been described for seven invertebrates and one alga; six of the species have superimposed solar-day rhythmic components also. 6. Translocation. A total of five geographical translocation experiments, in which the organisms were maintained in constant conditions throughout, have been tried. Unequivocally in one case, and possibly in a second, the test organisms rephased spontaneously to the times commensurate with local tidal conditions. In two other cases, the pretranslocation phase was retained. The fifth experiment has not been reproducible. 7. Determination of phase. (a) The tidal cycle on the home shoreline sets the phase of the inhabitant's rhythms. Even the location of a crab's burrow on the beach incline can play a determining role. (b) Paradoxically, the periodic wetting by inundation is not an important entraining factor for most intertidal organisms. Instead, the effective portions of the tidal cycle include one or more of the following. (i) Mechanical agitation, especially for animals living in an uprush zone where they are periodically subjected to the pounding surf, (ii) Temperature cycles, though they have not yet been systematically investigated, have very pronounced entraining roles in crabs. (iii) Pressure is probably not a generally important entraining agent for most intertidal organisms, but it is so for the green crab. (c) Light-dark cycles in general, whether daily or tidal in length, have no effect on the entrainment or phase setting of many tidal rhythms. There are two exceptions: (i) a 24-hour light-dark cycle is known to keep a tidal locomotor rhythm (one that becomes circalunadian in constant conditions) at a strict tidal frequency. (ii) In rhythms with both daily and tidal components, when the former is shifted by light stimuli, the latter is affected in a nearly identical manner. 8. Temperature. (a) The role of temperature on tidal rhythms is compared with its role on circadian rhythms. (b) The effects of different constant temperatures have so far been studied on only four tidal rhythms. All studies indicate a lack of any permanent change in period, which is not so with most circadian rhythms; the latter having temperature coefficients around 1.1. In two of the studies the rhythms under test temperatures were followed for less than a day, and a third study cannot be repeated. (c) Short exposure to very cold temperature pulses produced a response that may be interpreted as a temporary stoppage of the clock. Exposure to relatively less-cold pulses appear simply to reset the hands of the clock. The same responses have been demonstrated with circadian rhythms. (d) In the case of green crabs, which had become arrhythmic during prolongued captivity in the laboratory, a tidal rhythm could be reinitiated by a single short cold treatment. The cold pulse also set the phase of the rhythm. (e) A few superficial studies employing temperature steps or pulses have produced results which suggest that a phase-change sensitivity rhythm — just like that found associated with circadian rhythms — may underlie tidal rhythms. Certainly a determined search for this rhythm should be made in the near future. 9. Clock control of rhythms. (a) An argument is constructed claiming that tidal rhythms have a basic period of about 24–8 hours rather than the more expected tidal interval of 12.4 hours. In constant conditions, a circalunadian period is usually displayed. (b) After speculating that a frequency-transforming coupler may function between the clock and the overt rhythm, reasons are given that lead to the further speculation that both circadian and circalunadian rhythms could be generated by a single clock, via specific coupling mechanisms. (c) Two current hypotheses concerning the nature of the clockworks are reviewed and discussed. (d) Suggestions are made for future investigations.     

Photoperiod affects the diurnal rhythm of hippocampal neuronal morphology of siberian hamsters

Individuals of many species can regulate their physiology, morphology, and behavior in response to annual changes of day length (photoperiod). In mammals, the photoperiodic signal is mediated by a change in the duration of melatonin, leading to alterations in gene expressions, neuronal circuits, and hormonal secretion. The hippocampus is one of the most plastic structures in the adult brain and hippocampal neuronal morphology displays photoperiod-induced differences. Because the hippocampus is important for emotional and cognitive behaviors, photoperiod-driven remodeling of hippocampal neurons is implicated in seasonal differences of affect, including seasonal affective disorder (SAD) in humans. Because neuronal architecture is also affected by the day-night cycle in several brain areas, we hypothesized that hippocampal neuronal morphology would display a diurnal rhythm and that day length would influence that rhythm. In the present study, we examined diurnal and seasonal differences in hippocampal neuronal morphology, as well as mRNA expression of the neurotrophic factors (i.e., brain-derived neurotrophic factor [Bdnf], tropomyosin receptor kinase B [trkB; a receptor for BDNF], and vascular endothelial growth factor [Vegf]) and a circadian clock gene, Bmal1, in the hippocampus of Siberian hamsters. Diurnal rhythms in total length of dendrites, the number of primary dendrites, dendritic complexity, and distance of the furthest intersection from the cell body were observed only in long-day animals; however, diurnal rhythms in the number of branch points and mean length of segments were observed only in short-day animals. Spine density of dendrites displayed diurnal rhythmicity with different peak times between the CA1 and DG subregions and between long and short days. These results indicate that photoperiod affects daily morphological changes of hippocampal neurons and the daily rhythm of spine density, suggesting the possibility that photoperiod-induced adjustments of hippocampal neuronal dynamics might underlie seasonal difference of affective responses. Bmal1 mRNA showed a diurnal rhythm and different expression levels between long and short days were observed. However, there were no strong effects of day length on Bdnf. trkb, and Vegf gene expression, suggesting that these genes are not involved in the photoperiodic effects on hippocampal neurons.     

8-hour rhythm of ovarian progesterone secretion in ewe

Pulse character of hormones secretion in the hypothalamus-pituitary-gonads system is a necessary condition of physiological regulation of reproduction. At the same time, the rhythms of ovarian hormones secretion have not been adequately explored. The researches study mainly three sexually mature ewes. The stages of oestrus cycle were determined on behavioral reactions of females in the presence of ram. Blood samples from jugular vein were collected hourly over 24-hour period during follicular (15-16 days), early (3-4 days) and middle (7-9 days) luteal phase of oestrus cycle, pregnancy (40-105 days) and lactation (30-45 days). 27 experiments were performed. Plasma progesterone was determined by enzyme-immunoassay method. There was no diurnal rhythm of ovarian progesterone secretion in ewes. During early and middle luteal phase of oestrus cycle and lactation, an 8-hour rhythm of progesterone secretion was detected. Follicular phase of oestrus cycle and pregnancy were characterized by irregular rises of fluctuations of progesterone level. It seems that the 8-hour rhythm of progesterone secretion during luteal phase and lactation is controlled by action of intraovarian generator of ultradian rhythms.     

Entrainment of the activity rhythm of the mole crab Emerita talpoida

The mole crab Emerita talpoida migrates with the tide in the swash zone of sand beaches. A circatidal rhythm in vertical swimming underlies movement, in which mature male crabs show peak swimming activity 1-2 h after the time of high tides at the collection site. In addition, there is a secondary rhythm in activity amplitude, in which crabs are maximally active following low amplitude high tides and minimally active following high amplitude high tides. The present study determined the phase response relationship for entrainment of the circatidal rhythm with mechanical agitation and whether the cycle in activity related to tidal amplitude could be entrained by a cycle in the duration of mechanical agitation at the times of consecutive high tides. After entrainment with mechanical agitation on an orbital shaker, activity of individual crabs was monitored in constant conditions with a video system and quantified as the number of ascents from the sand each 0.5 h. Mechanical agitation at the times of high tide, mid-ebb and low tide reset the timing of the circatidal rhythm according to the timing relationship to high tide. However, mechanical agitation during flood tide had no entrainment effect. In addition, a cycle in duration of mechanical agitation entrained the rhythm in activity amplitude associated with tidal amplitude. Both rhythms and entrainment effectiveness over the tidal cycle may function to reduce the likelihood of stranding above the swash zone.     

Diurnal rhythm of galanin-like immunoreactivity in the paraventricular and suprachiasmatic nuclei and other hypothalamic areas

The peptide galanin (GAL), when injected into the rat hypothalamus, is known to stimulate feeding behavior and affect the secretion of various hormones, including insulin and the adrenal steroid, corticosterone. To determine whether endogenous peptide levels shift in relation to natural rhythms of feeding and circulating hormone levels, rats were sacrificed at different times of the light/dark cycle, and their GAL levels were measured, via radioimmunoassay, in medial hypothalamic dissections and micropunched hypothalamic areas. The results suggest the existence of two distinct diurnal rhythms for hypothalamic GAL. One rhythm, detected exclusively in the area of the SCN, is characterized by bimodal peaks of GAL, threefold higher than basal peptide levels, around the onset of the dark and light periods. The second rhythm shows a single peak of GAL towards the middle of the nocturnal feeding cycle, specifically between the third and sixth hour. This latter rhythm is evident in the dorsal region of the medial hypothalamus, localized specifically to the lateral portion of the PVN. Moreover, it is inversely related to circulating insulin but unrelated to the adrenal steroids, suggesting a possible association between this pancreatic hormone and GAL in the PVN.     

Circadian rhythm of cell division and mitosis duration in the root meristem of the common pea under normal conditions and under the influence of thyroxine]

Daily rhythms of the mitotic activity (MA) and mitosis duration were studied in meristem of the Pisum sativum L. primary roots. It is determined that MA increases in the day time. The daily rhythm of mitosis duration is absent. The germination of Pisum sativum seeds in solution with 1-thyroxine revealed that thyroxine increases average diurnal MA and results in formation of two-phases rhythm of mitosis number. The additional (night) increase of MA is connected with prolongation of mitosis.     

A daily rhythm in mating behavior in a diurnal murid rodent Arvicanthis niloticus

The time of day at which mating occurs is dramatically different in diurnal compared to nocturnal rodents. We used a diurnal murid rodent, Arvicanthis niloticus, to determine if inverted rhythms in responsiveness to hormones contribute to this difference. Male and hormone-primed female grass rats were tested for mating behavior at four different times of day (ZT 5, 11, 17, 23; ZT 0=lights-on). In females, there was considerable inter-individual variability with respect to patterns of responsiveness to hormones. Overall, the lordosis quotient (LQ) was rhythmic with a single peak just before lights-on (ZT 23); however, while roughly half of the females (7/15) exhibited this clear daily rhythm, the remaining animals (8/15) had relatively high LQs that did not change as a function of time. Males had their shortest ejaculation latencies and their highest number of ejaculations at ZT 23. Rhythms in mount frequency and post-ejaculatory refractory period were bimodal, with peaks around lights-on and -off (ZT 23 and 11). This temporal pattern of mounting behavior closely parallels previously documented patterns of general activity, whereas rhythms in the more reflexive components of sex behavior (LQ and ejaculation) had more restricted peaks that coincided with just the onset of rhythms in general activity. These rhythms in sexual behavior are essentially reversed relative to those previously documented in lab rats.     

Orcadian rhythm of Oecophylla longinoda in relation to territoriality and predatory behaviour

Abstract Circadian rhythms of activity in four societies of Oecophylla longinoda (Latreille) have been studied. Activity is continuous, but diurnal activity is greater than the nocturnal activity. This species is characterized by a strong sense of territoriality and the workers occupy: central territories, trees and immediate surroundings occupied by the society; secondary territories, used for hunting purposes, in natural conditions located on the ground; and intermittent territories in the forest zone (diurnal), scarcely used for hunting, but mainly in relation to the tending of homopterans.
The circadian rhythm of activity can be reversed by artificially lighting certain territories at night (reinforcement by attraction of numerous prey). This reversal can only be obtained progressively. By permanent surveillance of the territories and efficient recruitment, the societies rapidly adapt to fluctuations in the quantity of prey. There is a close correlation between agressive territoriality and predation.     

Entrainment of the larval release rhythm of the crab Rhithropanopeus harrisii (Brachyura: Xanthidae) by cycles in hydrostatic pressure

This study investigated the entrainment of a larval release rhythm by determining whether a tidal cycle in hydrostatic pressure could entrain the circatidal rhythm in larval release by the crab Rhithropanopeus harrisii (Gould). Ovigerous females were collected from a non-tidal estuary. The time of larval release by individual crabs was monitored under constant conditions with a time-lapse video system. Crabs with mature embryos at the time of collection had a pronounced circadian rhythm in larval release with a free running period of 25.1 h. Crabs with immature embryos that were maintained under constant conditions from the time of collection until larval release retained a weak circadian rhythm. Other crabs with immature embryos were exposed to a tidal cycle in step changes in hydrostatic pressure equivalent to 1 m of water. This cycle entrained a circatidal rhythm in larval release. The free-running period was 12.1 h and larvae were released at the time of the transition from low to high pressure. Although past studies demonstrated that a tidal cycle in hydrostatic pressure could entrain activity rhythms in crustaceans, this is the first study to show that pressure can entrain a larval release rhythm.     

Circadian organization inAplysia: internal desynchronization and amplitude of locomotor rhythm

Summary We have tested the hypothesis that the circadian oscillators in the eyes ofAplysia are coequal driver oscillators for the circadian locomotor rhythm. Three predictions based on this hypothesis were tested. Prediction 1: at a time when the phase difference between the eye rhythms is small, the amplitude of the locomotor rhythm in two eyed animals will be as great or greater than the amplitude in one eyed animals. Prediction 2: the amplitude of the locomotor rhythm of two eyed animals will decline under conditions in which the two eye rhythms become out of phase with each other. Prediction 3: the form of the locomotor rhythm will broaden or become biphasic in two eyed animals when the two eye rhythms become out of phase with each other.None of the predictions was confirmed. One eyedAplysia had higher amplitude locomotor rhythms than two eyedAplysia, even under conditions in which the two eye rhythms were probably not far out of phase with each other. There was no tendency for the amplitude of the locomotor rhythm of two eyed animals to decline under circumstances in which the phase difference between the two eye rhythms changes from less than 4 h to as much as 11.5 h. There was no tendency in two eyed animals for the locomotor rhythm to broaden or become biphasic as the eye rhythms became more out of phase with each other.The results led us to reject the hypothesis that the eyes are co-equal drivers for the locomotor rhythm. The ocular influence on locomotion is more likely to be mediated via mechanisms in the central nervous system that do not faithfully conserve the phase of the eye rhythms. One possibility is that the driver is a third circadian oscillator that interacts with the two eye oscillators.Abbreviations CAP compound action potentials - CC constant conditions - CT circadian time - DO driver oscillator - EO eye oscillator - RSD relative standard deviations (see Methods)     

Light pulses entrain the circadian activity rhythm of a diurnal rodent (Ammospermophilus leucurus)

Circadian rhythms of wheel-running activity of the antelope ground squirrel (Ammospermophilus leucurus) were entrained by light-dark cycles (LD: 100 1x vs total darkness) with periods (T) between ca 23.75 and 24.75 hr. Two 1-hr light pulses per cycle ('skeleton photoperiods') with T = 24.25 hr as well as one 1-hr light pulse per cycle with Ts of 23.75 and 24.25 hr were effective in entraining the circadian activity rhythms in at least 50% of the antelope ground squirrels. Phase and period responses to single 1-hr light pulses were measured which depend on the initial phase and period of the rhythm. It is concluded that discrete (phasic) light input contributes to the mechanism of entrainment to LD cycles in diurnal rodents.