Dueling Hypotheses: Circatidal Versus Circalunidian Battle Basics–Second Engagement

The daily rhythm in body temperature is thought to be the result of the direct effects of activity and the effects of an endogenous circadian clock. Forced desynchrony (FD) is a tool used in human circadian rhythm research to disentangle endogenous and activity-related effects on daily rhythms. In the present study, we applied an FD protocol to rats. We subjected 8 rats for 5 days to a 20h forced activity cycle consisting of lOh of forced wakefulness and lOh for rest and sleep. The procedure aimed to introduce a lOh sleep/ lOh wake cycle, which period was different from the endogenous circadian (about 24h) rhythm. Of the variation in the raw body temperature data, 68–77% could be explained by a summation of estimated endogenous circadian cycle and forced activity cycle components of body temperature. Free-running circadian periods of body temperature during FD were similar to free-running periods measured in constant conditions. The applied forced activity cycle reduced clock-related circadian modulation of activity. This reduction of circadian modulation of activity did not affect body temperature. Also, the effects of the forced activity on body temperature were remarkably small.     

Forced Desynchrony of Orcadian Rhythms of Body Temperature and Activity in Rats

The daily rhythm in body temperature is thought to be the result of the direct effects of activity and the effects of an endogenous circadian clock. Forced desynchrony (FD) is a tool used in human circadian rhythm research to disentangle endogenous and activity-related effects on daily rhythms. In the present study, we applied an FD protocol to rats. We subjected 8 rats for 5 days to a 20h forced activity cycle consisting of lOh of forced wakefulness and lOh for rest and sleep. The procedure aimed to introduce a lOh sleep/ lOh wake cycle, which period was different from the endogenous circadian (about 24h) rhythm. Of the variation in the raw body temperature data, 68-77% could be explained by a summation of estimated endogenous circadian cycle and forced activity cycle components of body temperature. Free-running circadian periods of body temperature during FD were similar to free-running periods measured in constant conditions. The applied forced activity cycle reduced clock-related circadian modulation of activity. This reduction of circadian modulation of activity did not affect body temperature. Also, the effects of the forced activity on body temperature were remarkably small.     

Mechanism of the alcohol cyclic pattern: role of the hypothalamic-pituitary-thyroid axis

The cause of the cycle of urinary alcohol levels (UALs) in rats fed ethanol continually at a fixed rate is unknown. Rats were fed ethanol intragastrically at a constant dose for 2 mo, and daily body temperatures and UALs were recorded. Body temperature cycled inversely to UAL, suggesting that the rate of metabolism could be mechanistically involved in the rate of ethanol elimination during the cycle. To document this, whole body O(2) consumption rate was monitored daily during the cycle. The rate of O(2) consumption correlated positively with the change in body temperature and negatively with the change in UAL. Since the metabolic rate responds to changes in body temperature, thyroid hormone levels were measured during the UAL cycle. T(4) levels correlated positively with the O(2) consumption rate and negatively with the UALs. In a second experiment using propylthiouracil treatment, UALs did not cycle and a fall in body temperature failed to stimulate an increase in the rate of ethanol elimination. Consequently, rats died of overdose. Likewise, in a third experiment using rats with severed pituitary stalks, UALs failed to cycle and rats died of overdose. From these observations it was concluded that the UAL cycle depends on an intact hypothalamic-pituitary-thyroid axis response to the ethanol-induced drop in body temperature by increasing the rate of ethanol elimination.     

Circannual rhythm of food intake in spotted munia and its phase relationship with fattening and reproductive cycles

Summary The tropical spotted munia,Lonchura punctulata, exhibits a pronounced seasonality in reproduction, body weight and food intake. The body weight cycle parallels the reproductive cycle, whereas the food intake cycle is almost in antiphase to it. There is evidence that constant dietary restriction (50% of the maximum intake) causes dissociation of the body weight and reproductive cycles. Because of these relationships we performed experiments on the food intake cycle and its phase relationships with the reproductive and body weight cycles in birds held under constant light. The results indicate persistence of all three cycles. The phase relationships of these three parameters were almost normal, which may indicate that the endogenous oscillators for the cycles of reproduction, body weight and food intake are linked.     

Morphometric changes associated with the reproductive cycle and behaviour of the intertidal-nesting, male plainfin midshipman Porichthys notatus

Morphometric changes in body condition, liver, sonic muscle and gonadal development associated with the annual reproductive cycle and behaviour of the intertidal-nesting male plainfin midshipman Porichthys notatus were investigated. Body condition of type I males rapidly increased during the pre-nesting (PN) period, peaked at the beginning of the summer nesting cycle and then gradually declined to lowest levels during the non-reproductive (NR) period. The gonado-somatic index of type I males peaked during PN and then declined during the summer nesting cycle to lowest levels at the end of the nest cycle and during NR. Indices of sonic muscle and liver of type I males were lowest during NR, gradually increased during PN and then peaked during the summer nesting cycle. Results indicate that body condition and fecundity of type I males were positively correlated with body mass at the end of the nest cycle. These findings as they relate to the annual reproductive cycle and behaviour of the type I male P. notatus are discussed.     

Changes in Total Body Water and Body Fat in Young Women in the Course of Menstrual Cycle

This paper reports on the changes in total body water and body fat in young women in during the course of the menstrual cycle. We followed 40 young women with an average age of 21.52 years, and took bioelectrical impedance measurements during two menstrual cycles. The measurements were taken in three phases of the menstrual cycle. We found that body mass and total body water fluctuate during the menstrual cycle. Both parameters are highest in the luteal phase and lowest in the late folicular phase; 65% of the young women demonstrated these changes. The presence or absence of premenstrual symptoms had no influence on these values.     

Acetaminophen does not affect 24-h body temperature or sleep in the luteal phase of the menstrual cycle.

Body temperature and sleep change in association with increased progesterone in the luteal phase of the menstrual cycle in young women. The mechanism by which progesterone raises body temperature is not known but may involve prostaglandins, inducing a thermoregulatory adjustment similar to that of fever. Prostaglandins also are involved in sleep regulation and potentially could mediate changes in sleep during the menstrual cycle. We investigated the possible role of central prostaglandins in mediating menstrual-associated 24-h temperature and sleep changes by inhibiting prostaglandin synthesis with a therapeutic dose of the centrally acting cyclooxygenase inhibitor acetaminophen in the luteal and follicular phases of the menstrual cycle in young women. Body temperature was raised, and nocturnal amplitude was blunted, in the luteal phase compared with the follicular phase. Acetaminophen had no effect on the body temperature profile in either menstrual cycle phase. Prostaglandins, therefore, are unlikely to mediate the upward shift of body temperature in the luteal phase. Sleep changed during the menstrual cycle: on the placebo night in the luteal phase the women had less rapid eye movement sleep and more slow-wave sleep than in the follicular phase. Acetaminophen did not alter sleep architecture or subjective sleep quality. Prostaglandin inhibition with acetaminophen, therefore, had no effect on the increase in body temperature or on sleep in the midluteal phase of the menstrual cycle in young women, making it unlikely that central prostaglandin synthesis underlies these luteal events.     

Ecological consequences of scaling of chew cycle duration and daily feeding time in Primates

Feeding systems and behaviors must evolve to satisfy the metabolic needs of organisms. This includes modifications to feeding systems as body size and metabolic needs change. Using our own data and data from the literature, we examine how size-related changes in metabolic needs are met by size-related changes in daily feeding time, chew cycle duration, volume of food processed per chew, and daily food volume intake in primates. Increases in chew cycle duration with body mass in haplorhine primates are described by a simple power function (cycle time α body mass^0.181). Daily feeding time increases with body mass when analyzed using raw data from the “tips” of the primate phylogenetic tree, but not when using phylogenetically independent contrasts. Whether or not daily feeding time remains constant or increases with body mass, isometry of ingested bite size and the slow rate of increase in chew cycle time with body size combine to allow daily ingested food volume to scale faster than predicted by metabolic rate. This positive allometry of daily ingested food volume may compensate for negative allometry of nutrient concentration in primate foods. Food material properties such as toughness and hardness have little impact on scaling of chew cycle durations, sequence durations, or numbers of chews in a sequence. Size-related changes in food processing abilities appear to accommodate size-related changes in food material properties, and primates may alter ingested bite sizes in order to minimize the impacts of food material properties on temporal variables such as chew cycle duration and chew sequence duration.     

Homeostatic and circadian control of body temperature in the fat-tailed gerbil

The interplay of homeostasis and circadian rhythmicity in the control of body temperature was studied in the fat-tailed gerbil (Pachyuromys duprasi). In a first study, the body temperature rhythm of 8 gerbils maintained at 24 degrees C under a 14L:10D light-dark cycle was studied by telemetry. Data from 9 other species of small mammals were also obtained for comparison. The gerbils were found to exhibit a robust rhythm of body temperature (the most robust of the 10 species) with a high plateau during the dark phase of the light-dark cycle and a low plateau during the light phase. In a second experiment, 5 gerbils were allowed to select the temperature of their environment by moving along a thermal gradient. The animals consistently selected higher ambient temperatures during the light phase of the light-dark cycle (when their body temperature was at the low plateau). In a third experiment, the metabolic response of 8 gerbils to an acute cold exposure was determined by indirect calorimetry. Greater cold-induced thermogenesis was observed during the light phase. The fact that the animals selected higher ambient temperatures and displayed greater cold-induced thermogenesis when their body temperature was lower contradicts the hypothesis that the body temperature rhythm is caused by a rhythmic oscillation of the thermoregulatory set point.     

Centriole is the pivot co-ordinating dynamic signaling for cell proliferation and organization during early development in the vertebrates

Vertebrates have an elaborate and functionally segmented body. It evolves from a single cell by systematic cell proliferation but attains a complex body structure with exquisite precision. This development requires two cellular events: cell cycle and ciliogenesis. For these events, the dynamic molecular signaling is converged at the centriole. The cell cycle helps in cell proliferation and growth of the body and is a highly regulated and integrated process. Its errors cause malignancies and developmental disorders. The cells newly proliferated are organized during organogenesis. For a cellular organization, dedicated signaling hubs are developed in the cells, and most often cilia are utilized. The cilium is generated from one of the centrioles involved in cell proliferation. The developmental signaling pathways hosted in cilia are essential for the elaboration of the body plan. The cilium's compartmental seclusion is ideal for noise-free molecular signaling and is essential for the precision of the body layout. The dysfunctional centrioles and primary cilia distort the development of body layout that manifest as serious developmental disorders. Thus, centriole has a dual role in the growth and cellular organization. It organizes dynamically expressed molecules of cell cycle and ciliogenesis and plays a balancing act to generate new cells and organize them during development. A putative master molecule may regulate and co-ordinate the dynamic gene expression at the centrioles. The convergence of many critical signaling components at the centriole reiterates the idea that centriole is a major molecular workstation involved in elaborating the structural design and complexity in vertebrates.     

A kinematic study of crawling behavior in the leech,Hirudo medicinalis

The medicinal leech crawls along a solid substrate by repeated alternating extensions and shortenings of the body. Extension occurs with the posterior sucker attached and the head sucker free. The head sucker then attaches, followed by shortening and release of the tail sucker. The tail sucker is then pulled toward the head, where it reattaches to the substrate. The head sucker then releases, and another crawling cycle begins (Figs. 1, 5). There are two crawling variants: inchworm crawling, in which the head and tail suckers are closely apposed at the end of a cycle and the body forms a loop above the substrate, and vermiform crawling, in which the suckers are placed farther apart and the body remains fairly close to the substrate (Fig. 1). The cycle period and the distance traveled during a cycle are greater in inchworm than in vermiform crawling; however, the velocity of travel is the same for both (Fig. 2). For both variants, the interval between head sucker attachment and tail sucker release is similar at all cycle periods and has a value consistent with direct interneuronal conduction of a signal from head sucker sensory neurons to tail sucker motor neurons. The interval between tail sucker attachment and head sucker release, however, is longer and varies with the cycle period, suggesting a more complex interneuronal circuit in the pathway from tail sucker sensory neurons to head sucker motor neurons (Fig. 4). The onsets of the components of the crawling cycle (extension, post-extension pause, shortening, and post-shortening pause) show an anteroposterior lag (Figs. 5, 7). For both variants, the travel time between segments varies directly with the period (Fig. 8). For both crawl types, the durations of the cycle components vary directly with the period, with several exceptions (Figs. 9, 10). A model is presented that summarizes the coordination of the various motor events in a cycle of leech crawling (Figs. 11 and 12).     

Does the activity of angiotensin converting enzyme depend on sex, age, body weight and phase of the menstruation cycle in women?]

The study involved 274 patients, including 240 women, divided into various subgroups, according to the age, body weight, and a phase of menstruation cycle in women, and a subgroup of 34 men. According to the design of the studies, blood serum ACE activity was determined spectrophotometrically with a technique described by Friedland and Silverstein in all patients. The obtained results suggest that blood serum ACE activity does not depend on the sex, age, body weight, and phase of the menstruation cycle in women.     

Influence of various factors on the measurement of multifrequency bioimpedance

Body impedance values at various frequencies (from 1 to 100 kHz) were determined in 104 subjects on seven separate days over a two-week period. The variability of body impedance in different measurement conditions was studied. In particular, the effects of the electrode locations, the ingestion of some substances (sugar, alcohol, mineral salts), body spatial geometry, the time spent in the supine position and the menstrual cycle were assessed. Under standardized conditions (in the morning, in the fasting state, with an empty bladder and with the body in a standardised spatial position), the within-subject day-to-day variability was 3-14 Ohms. Under different experimental conditions, the within-subject variability was generally much higher. This was particularly evident for female subjects. We observed significant mean variations in relation to the different experimental factors introduced one at a time, with the exception of the menstrual cycle. For example, half an hour after the intake of various substances, body impedance had generally increased by 6-17 Ohms in comparison with values in the fasting state. Changes in body impedance during the menstrual cycle, however, were small and never statistically significant. The impedance variations obviously caused significant changes in estimated parameters of body composition. It is concluded that controlled conditions and standardization of multifrequency bioimpedance analysis (MBIA) methods are indispensable for the application of this technique.     

Overexpression of suppressor of cytokine signaling 3 in the arcuate nucleus of juvenile Phodopus sungorus alters seasonal body weight changes

The profound seasonal cycle in body weight exhibited by the Djungarian hamster (Phodopus sungorus) is associated with the development of hypothalamic leptin resistance during long day photoperiod (LD, 16:8 h light dark cycle), when body weight is elevated relative to short day photoperiod (SD, 8:16 h light dark cycle). We previously have shown that this seasonal change in physiology is associated with higher levels of mRNA for the potent inhibitor of leptin signaling, suppressor of cytokine signaling-3 (SOCS3), in the arcuate nucleus (ARC) of LD hamsters relative to hamsters in SD. The alteration in SOCS3 gene expression preceded the body weight change suggesting that SOCS3 might be the molecular switch of seasonal body weight changes. To functionally characterize the role of SOCS3 in seasonal body weight regulation, we injected SOCS3 expressing recombinant adeno-associated virus type-2 (rAAV2-SOCS3) constructs into the ARC of leptin sensitive SD hamsters immediately after weaning. Hamsters that received rAAV2 expressing enhanced green fluorescent protein (rAAV2-EGFP) served as controls. ARC-directed SOCS3 overexpression led to a significant increase in body weight over a period of 12 weeks without fully restoring the LD phenotype. This increase was partially due to elevated brown and white adipose tissue mass. Gene expression of pro-opiomelanocortin was increased while thyroid hormone converting enzyme DIO3 mRNA levels were reduced in SD hamsters with SOCS3 overexpression. In conclusion, our data suggest that ARC-directed SOCS3 overexpression partially overcomes the profound seasonal body weight cycle exhibited by the hamster which is associated with altered pro-opiomelanocortin and DIO3 gene expression.     

Burrowing of Priapulus caudatus (Vermes) and the significance of the direct peristaltic wave

Priapulus caudatus is an active predatory animal found burrowing in soft mud. It may employ relatively high body fluid pressures during escape reactions (up to 6 kPa recorded) but normal burrowing probably involves much lower pressures (< 2 kPa). Three points d'appui are formed during the burrowing cycle. A characteristic direct peristaltic wave (DPW) occurs at a low pressure stage in each cycle (<0–5 kPa). The DPW is regarded as an adaptation to burrowing in soft mud. Its function appears to be to transfer body wall anteriorily, providing "slack", which is used to allow the trunk to extend forward into the cavity vacated by retraction of the large praesoma at the end of each cycle. The circular and longitudinal muscles of the posterior trunk act synergically through most of the burrowing cycle.     

Effects of selenium toxicity on oestrous cyclicity, ovarian follicles, ovulation and foetal survival in rats

Effects of intraperitoneal injections of sodium selenite (2.0 and 4.0 mg/kg body weight) to normally cycling female albino Wistar rats daily for 30 days, and of single injection either during proestrous or oestrous and at each stage of the 4-day oestrous cycle were determined on oestrous cyclicity, ovarian follicles, ovulation, implantation and pregnancy outcome on day 14 of gestation. Administration of selenite for 30 days had no effect on the duration of first two oestrous cycles but afterwards the rats remained at the dioestrus stage. Their ovaries developed cystic follicles. Selenite treatments during the oestrous cycle preceding mating affects the implantation and pregnancy outcome in a dose-related manner. Its single dose containing 2.0 mg/kg body weight administered either at proestrous or oestrous, though had no effect on different reproductive parameters investigated in this study but its daily dose during the 4 day oestrous cycle reduced the number of corpora lutea and implantations as compared to saline injected control female rats. Similar effects of a single dose of selenite (4.0 mg/kg body weight) when injected at proestrous were recorded. Higher dose of selenite at oestrous or throughout the cycle decreased the number of implantations, but in addition, also increased the resorption rate/litter on day 14 of gestation. The present studies clearly show that high selenium levels in the body during the oestrous cycle preceding mating affects the number of ovulations, implantations and live embryos depending upon its dose and stage of administration.     

Changes of Body Temperature and Thermoregulation in the Course of the Ovarian Cycle in Laboratory Mice

In the course of the ovarian cycle, numerous physiological functions, particularly body temperature, undergo pronounced changes. The role played in cycle-dependent changes by activity is still a matter of debate. In female laboratory mice, body temperature and motor activity have been measured telemetrically, every 10 min for one month, while the stage of the estrous cycle was determined by means of vaginal smears. The circadian rhythm of body temperature underwent regular infradian changes corresponding to the sexual cycle, with body temperature higher on the days of estrous. Also, the level of motor activity was slightly elevated on days of estrous, though less consistently so. As shown by the method of purification, the temperature increase on the days of estrous was not caused by the higher activity but, presumably, rather by hormonal changes around the time of ovulation. After removing the direct effect of motor activity on the body temperature, the difference between estrous and non-estrous days was even more marked. The purification method also enabled the gradient of temperature change per unit activity, a measure of thermoregulatory efficiency, to be estimated. This gradient was lower on the days of estrous, mainly because of the higher temperatures then, but also partly due to changed thermoregulatory mechanisms. Thus, it would seem that hormones not only increase the body temperature in estrous but also promote-heat loss mechanisms. Despite the quite marked cycle-dependent changes in body temperature, it was not possible to use the temperature profile on a particular day to classify that day as an estrous or a non-estrous day; only a consideration of data from several consecutive days allowed this determination to be made.     

Physiological aspects of multiple blood feeding in the malaria vector Anopheles tessellatus

The malaria vector Anopheles tessellatus is able to take several blood meals in a gonotrophic cycle. The fecundity is largely dependent on the first blood meal and is not generally increased by subsequent blood meals during a gonotrophic cycle. Larval rearing densities influenced adult body size. There is an inverse relationship between wing length and larval rearing densities. Smaller mosquitoes produced from larvae reared at higher densities had reduced body reserves of protein, lipid and carbohydrates. At emergence, ovarian development in An. tessellatus is in the previtellogenic stage and it remained at this stage until the intake of a blood meal. The number of ovarian follicles is related to wing length and, irrespective of adult body size, An. tessellatus developed oocytes to maturity with a single blood meal. This is attributed to the availability of metabolic reserves above the threshold level required for further development of oocytes. Mosquitoes that took more than one blood meal had largely digested their previous blood meal and had ongoing vitellogenesis. Blood meals subsequent to the first one apparently contribute mainly to increasing metabolic reserves. The stimulus for a second and third blood meal in An. tessellatus appears to be completion of the digestion of the previous blood meal. There was no evidence that multiple blood meals taken in the first gonotrophic cycle influenced fecundity significantly in the second cycle.     

Carnivore body size: Ecological and taxonomic correlates

Summary Variation in body size (weight) is examined across the order Carnivora in relation to taxonomy (phylogeny), latitude, habitat, zonation, activity cycle, diet, prey size, and prey diversity. Significant differences in body weight are observed with respect to family membership. Some of these differences may be explained by phylogenetic history and/or dietary effects. Body weight is not correlated with habitat, zonation, activity cycle or latitudinal gradients. Significant differences in body weight are found among insectivorous, herbivorous and carnivorous species, and some of these differences may relate to energetic constraints. Among predatory carnivores, prey size and diversity increases with body weight. The adaptive significance, both intra- and inter-specifically, of prey characteristics (size, availability, diversity) and carnivore body weight qualities (strength, endurance, hunting technique) is discussed.