Time-dependent effects of leptin on food intake and locomotor activity in goldfish

The present study investigates the possible circadian dependence of leptin effects on food intake, locomotor activity, glycemia and plasma cortisol levels in goldfish (Carassius auratus). Fish were maintained under 12L:12D photoperiod and subjected to two different feeding schedules, one group fed during photophase (10:00) and the other one during scotophase (22:00). Leptin or saline were intraperitoneally injected at two different times (10:00 or 22:00), coincident or not with the meal time. To eliminate the entraining effect of the light/dark cycle, goldfish maintained under 24 h light (LL) were fed and leptin-injected at 10:00. A reduction in food intake and locomotor activity and an increase in glycemia were found in goldfish fed and leptin-injected at 10:00. No significant changes in circulating cortisol were observed. Those effects were not observed when leptin was administered during the scotophase, regardless the feeding schedule; neither in fish maintained under LL, suggesting that a day/night cycle would be necessary to observe the actions of leptin administered during the photophase. Changes in locomotor activity and glycemia were only observed in goldfish when leptin was injected at daytime, coincident with the feeding schedule, suggesting that these leptin actions could be dependent on the feeding time as zeitgeber. In view of these results it appears that the circadian dependence of leptin actions in goldfish can be determined by the combination of both zeitgebers, light/dark cycle and food. Our results point out the relevance of the administration time when investigating regulatory functions of hormones.     

Feeding time synchronizes clock gene rhythmic expression in brain and liver of goldfish (Carassius auratus)

Little is known about the feeding time dependence of clock gene expression in fish. The aim of the present study was to investigate whether a scheduled feeding time can entrain the rhythmic expression of several clock genes (period and cryptocrome) in the brain and liver of a teleost, the goldfish. Fish maintained under continuous light (LL) conditions were divided into 3 groups. Two groups were fed daily at 1000 h and 2200 h, respectively, and the third group was subjected to a random schedule regime. After 30 days, the fishes under 24-h food deprivation were sacrificed through a 24-h cycle, and clock gene expression in the optic tectum, hypothalamus, and liver was quantified by real-time PCR. The findings pointed to differences between the central and peripheral tissues studied. In the absence of a light-dark cycle (constant light), a scheduled feeding regime was necessary and sufficient to maintain both the rhythmic expression of several clock genes in the optic tectum and hypothalamus, as well as daily rhythms in locomotor activity. In contrast, neither locomotor activity nor clock gene expression in brain tissues was synchronized in randomly fed fish. However, in the liver, most of the clock genes studied presented significant daily rhythms in phase (related to the time of the last meal) in all 3 experimental groups, suggesting that the daily rhythm of clock genes in this organ only depends on the last meal time. The data suggest that, as in mammals, the smooth running of the food entrainable oscillator (FEO) in fish involves the rhythmic expression of several clock genes (Per1 and Cry3) in the central and peripheral structures. The results also indicate that the food anticipatory activity (FAA) in goldfish is not only the result of rhythmic clock gene expression in the liver because rhythmic clock gene expression was observed in randomly fed fishes, while FAA was not observed.     

Influence of light on feeding anticipatory activity in goldfish

Most animals when presented with food on a periodic basis develop feeding anticipatory activity (FAA). The objective of the present study was to investigate the synchronization of activity rhythms to light and feeding in single goldfish given a single daily meal and exposed to different light regimes. In the 1st experiment, the group of fish fed at the end of the day showed a longer FAA (228 +/- 27 min) than the group fed 1 h after lights-on (97 +/- 31 min). In the 2nd experiment, goldfish under conflicting zeitgebers, LD (T = 26) and feeding (T = 24) cycles, initially synchronized to the light cycle although feeding time gradually assumed greater importance as the experiment progressed. In the 3rd experiment, after altering the feeding cycles by advancing or delaying feeding time by 4 h in LD 0.25:23.75, most goldfish resynchronized to the feeding stimulus and developed FAA. In conclusion, the authors' results revealed that FAA in goldfish is driven by an endogenous timing system that is entrainable by periodic feeding and influenced by the light regime.     

Daily patterns of mRNA expression of two core circadian regulatory proteins, Clock2 and Per1, and two appetite-regulating peptides, OX and NPY, in goldfish (Carassius auratus)

The aim of this study was to examine the daily hypothalamic mRNA expression profiles for two core circadian regulatory proteins, CLOCK2 and PER1, and for two neuropeptides that regulate wakefulness and food intake, OX and NPY, in goldfish. The profiles were determined for fish at different nutritional states (i.e. fed or unfed on sampling day) and held at different photoperiods (i.e. 16L:8D photoperiod vs. constant light LL). Our results show that under a 16L:8D photoperiod, both fed and unfed goldfish exhibit clear antiphasic daily rhythms of hypothalamic Clock2 and Per1 mRNA expression levels, whereas under LL, daily Clock2 rhythms are seen in both fed and unfed fish while significant rhythms of Per1 mRNA expression only persist in unfed fish. In fish held under 16L:8D, but not under LL, there was significantly higher Per1 expression in fed fish at feeding time than in unfed fish. Daily variations in hypothalamic OX mRNA expression levels with peaks observed prior to both feeding time and the onset of darkness, were displayed under a 16L:8D photoperiod, whereas exposure to LL resulted in lower expression levels with no significant daily variations. Fish held under LL, but not under 16L:8D, showed significant daily variations in NPY mRNA expression with a peak prior to feeding time. Taken together, our results suggest that the mRNA expression of both appetite-regulating and circadian proteins display daily variations and that these patterns can be affected by external cues such as feeding and photoperiod.     

Feeding entrainment of locomotor activity rhythms in the goldfish is mediated by a feeding-entrainable circadian oscillator

Periodic food availability can act as a potent zeitgeber capable of synchronizing many biological rhythms in fishes, including locomotor activity rhythms. In the present paper we investigated entrainment of locomotor rhythms to scheduled feeding under different light and feeding regimes. In experiment 1, fish were exposed to a 12:12?h light/dark cycle and fed one single daily meal in the middle of the light phase. In experiment 2, we tested the effect of random versus scheduled feeding on the daily distribution of activity. During random feeding, meals were randomly scheduled with intervals ranging from 12 to 36?h, while scheduled feeding consisted of one single daily meal set in the middle of the light or dark phase. Finally, in experiment 3, we studied the synchronization of activity rhythms to feeding under constant darkness (DD) and after shifting the feeding cycle by either advancing or delaying the feeding cycle by 9?h. The results revealed that goldfish synchronized to feeding, overcame light entrainment and significantly changed their daily distribution of activity according to their feeding schedule. In addition, the daily activity pattern modulated by feeding differed between layers: a peak of activity being noticeable directly after feeding at the bottom, while an anticipatory behaviour was obvious at the surface of the tank. Under DD and no food, free-running rhythms averaging 25.5?± 1.9?h (mean?±?SD) were detected. In conclusion, some properties of feeding entrainment (e.g. anticipation of the feeding time, free-running rhythms following termination of periodic feeding, and the stability of ø after shifting the feeding cycle) suggested that goldfish have (a) separate but tightly coupled light- and food-entrainable oscillators, or (b) a single oscillator that is entrainable by both light and food (one synchronizer being eventually stronger than the other).     

鳜肝脏和心脏生物钟基因表达节律分析

在12h光照、12h黑暗交替(Light-Dark; LD)光制下,研究分析了褪黑素和皮质醇水平在鳜血清中的昼夜变化规律,以及13个生物钟基因(Arntl1、Clock、Cry1a、Cry3、Cry-dash、Npas2、Npas4、Nr1d1、Nr1d2、Per1、Per3、Rora和Tim)在鳜(Siniperca chuatsi)肝脏和心脏中的昼夜表达规律。试验在一昼夜内的ZT0(06:00)、ZT3(09:00),ZT6(12:00),ZT9(15:00),ZT12(18:00),ZT15(21:00),ZT18(24:00),ZT21(03:00,2nd d),ZT24(06:00,2nd d) (Zone time,ZT) 9个时间点随机抽取3尾鳜采集其血清、肝脏和心脏。经SPSS 单因素方差分析和Matlab余弦分析,结果显示: 鳜血清中褪黑素和皮质醇含量均呈现出昼夜节律性振荡,褪黑素含量白天显著降低(P0.05),夜间显著上升,皮质醇含量白天缓慢降低,夜间ZT15(21:00)-ZT18(24:00)显著升高,随后开始缓慢降低; 两种激素最低相位都为ZT15(21:00)。在13个生物钟基因中,Cry-dash、Npas4、Nr1d1、Per1和Tim 5个基因在鳜肝脏内具有明显的昼夜节律性,其中Npas4、Nr1d1、Per1、Tim的表达规律相似,皆呈现出光照阶段表达降低,黑暗阶段表达升高的趋势; 但Cry-dash则表现出光照阶段先升高后降低,黑暗阶段先降低后升高的规律。在鳜心脏中,Arntl1、Clock、Cry1a、Npas2、Nr1d1、Nr1d2、Per3、Rora和Tim 9个基因都表现出明显的昼夜节律,表达趋势分为两种: Arntl1、Clock、Nr1d2的表达量在光照阶段降低,黑暗阶段升高; 而Cry1a、Npas2、Nr1d1、Per3、Rora和Tim的表达量在ZT0(06:00)-ZT15(21:00)持续低水平,ZT15(21:00)-ZT18(24:00)表达量显著上升,ZT18(24:00)-ZT21(03:00)表达量降低。研究结果表明: 生物钟基因在鳜肝脏和心脏中所表达的昼夜节律不同。     

Photoperiod affects growth, behaviour and stress variables in Clarias gariepinus

Short periods of light or no light (18D : 06L and 24D : 00L) resulted in an increased growth compared to extended periods of light (06D : 18L and 12D : 12L) in African catfish Clarias gariepinus . Fish under longer periods of light (12D : 12L and 18D : 06L) showed higher swimming activity, more aggression (injuries on the body) and higher lactate, free fatty acids and cortisol levels compared to those who were reared at shorter periods of light (24D : 00L and 18D : 06L). Feeding activity during light and dark periods in this experiment showed that C. gariepinus had both night and day feeding activities, with a preference to diurnal feeding in the 12D : 12L photoperiod. The results showed that light plays an important role in the African catfish behaviour and its well‐being. As the hours of light increased during the 24 h cycle, data suggests that the fish were more stressed and aggressive, compared to those under a reduced number of light hours.     

Timing of a single daily meal and diel variations of serum thyroxine,triiodothyronine and cortisol in goldfish carassius auratus

Two groups of goldfish were maintained on a 12L:12D photoperiod at 19°C and fed either at 0800 (light onset) or 1600 h daily. After 3 weeks, blood samples were taken at one of six times of day and the serum was analyzed for thyroxine, triiodothyronine, and cortisol by radioimmunoassay. Fish fed in the morning had significant diel variations in circulating titers of thyroxine and cortisol, those fed in the afternoon had significant variations of thyroxine and triiodothyronine. Meal feeding appeared to entrain, and phase shift, the cortisol rhythm but not the rhythms of thyroid hormones. These results are briefly discussed in light of the effects of timing the daily meal on weight gain in fish.     

Melatonin in the circadian system

In Mammals, the master circadian clock is located in the suprachiasmatic nuclei of the hypothalamus. This clock is synchronized with the astronomical time, essentially by the light/dark cycle. The different zeitgebers studied act on the Per1 and/or Per2 genes from the main molecular loop which initiates the circadian oscillations. Once synchronized with the environment, circadian oscillations are distributed through the organism by efferent signals, and the complex interaction of neural, hormonal and behavioural outputs from the circadian clock drive circadian expression of events, either directly or through coordination of the timing of peripheral oscillators. Melatonin, one of the endocrine output signals of the clock, provides the organism with circadian information, and can be considered as an endogenous synchronizer. Melatonin receptors are present in the suprachiasmatic nuclei which allows the hormone to feed back on the clock. To day, the physiological role of this peculiar feed-back has not yet been established. However, the presence of these receptors indicates that through an action on the circadian clock, exogenous melatonin can affect all levels of the circadian network and its capacity to entrain circadian rhythms to 24 h has been demonstrated. Melatonin is thus a zeitgeber. However, surprisingly, and different from the action mechanism of other zeitgebers on the clock, the chronobiotic effect of melatonin does not implicate Per1 and/or Per2. Rather, Rev-erb alpha could be the link between the physiological action of melatonin and the core of the molecular circadian clock.     

Naphthol-yellow-S protein content of individual rat hepatocytes as related to food intake and short-term starvation

With regard to the protein content, as analysed cytophotometrically, of hepatocytes from rats kept under a 12L 12D photoperiod (photophase 7:00-19:00), the following facts have been established: 1) Hepatocytes of different classes of ploidy all demonstrate, more or less equally, daily variations in protein content and also its reduction after 24-h fasting. 2) With computer analysis of data obtained at eight time points during a period of 24 h, a sinusoidal curve of the protein content of individual mononuclear tetraploid hepatocytes throughout the day could be demonstrated with a maximum at 6:20 and a minimum at 18:20. 3) Animals, fed with meals via a dispensing machine from 23:00 to 24:00 only, show a similar sinusoidal curve but with higher amplitude, and a virtually identical mean value as those fed ad libitum. The maximum was found at 10:40, revealing a time lag of 12 h after food intake, the minimum at 22:40. 4) Trained animals deprived of food during the standardized feeding time revealed a moderate reduction of their hepatocyte protein content in the first 6 h, then a 6-h period with a steep fall followed by a slower reduction. After 24 h, the mean hepatocyte protein mass had decreased to 72% of that at the commencement of fasting at 23:00.     

Feeding cues and injected nutrients induce acute expression of multiple clock genes in the mouse liver

The circadian clock is closely associated with energy metabolism. The liver clock can rapidly adapt to a new feeding cycle within a few days, whereas the lung clock is gradually entrained over one week. However, the mechanism underlying tissue-specific clock resetting is not fully understood. To characterize the rapid response to feeding cues in the liver clock, we examined the effects of a single time-delayed feeding on circadian rhythms in the liver and lungs of Per2::Luc reporter knockin mice. After adapting to a night-time restricted feeding schedule, the mice were fed according to a 4, 8, or 13 h delayed schedule on the last day. The phase of the liver clock was delayed in all groups with delayed feeding, whereas the lung clock remained unaffected. We then examined the acute response of clock and metabolism-related genes in the liver using focused DNA-microarrays. Clock mutant mice were bred under constant light to attenuate the endogenous circadian rhythm, and gene expression profiles were determined during 24 h of fasting followed by 8 h of feeding. Per2 and Dec1 were significantly increased within 1 h of feeding. Real-time RT-PCR analysis revealed a similarly acute response in hepatic clock gene expression caused by feeding wild type mice after an overnight fast. In addition to Per2 and Dec1, the expression of Per1 increased, and that of Rev-erbα decreased in the liver within 1 h of feeding after fasting, whereas none of these clock genes were affected in the lung. Moreover, an intraperitoneal injection of glucose combined with amino acids, but not either alone, reproduced a similar hepatic response. Our findings show that multiple clock genes respond to nutritional cues within 1 h in the liver but not in the lung.     

Light and feeding entrainment of the molecular circadian clock in a marine teleost (Sparus aurata)

Daily light and feeding cycles act as powerful synchronizers of circadian rhythmicity. Ultimately, these external cues entrain the expression of clock genes, which generate daily rhythmic behavioral and physiological responses in vertebrates. In the present study, we investigated clock genes in a marine teleost (gilthead sea bream). Partial cDNA sequences of key elements from both positive (Bmal1, Clock) and negative (Per2, Cry1) regulatory loops were cloned before studying how feeding time affects the daily rhythms of locomotor activity and clock gene expression in the central (brain) and peripheral (liver) oscillators. To this end, all fish were kept under a light-dark (LD) cycle and were divided into three experimental groups, depending on the time of their daily meal: mid-light (ML), mid-darkness (MD), or at random (RD) times. Finally, the existence of circadian control on gene expression was investigated in the absence of external cues (DD?+?RD). The behavioral results showed that seabream fed at ML or RD displayed a diurnal activity pattern (>91% of activity during the day), whereas fish fed at MD were nocturnal (89% of activity during the night). Moreover, seabream subjected to regular feeding cycles (ML and MD groups) showed food-anticipatory activity (FAA). Regardless of the mealtime, the daily rhythm of clock gene expression in the brain peaked close to the light-dark transition in the case of Bmal1 and Clock, and at the beginning of the light phase in the case of Per2 and Cry1, showing the existence of phase delay between the positive and negative elements of the molecular clock. In the liver, however, the acrophases of the daily rhythms differed depending on the feeding regime: the maximum expression of Bmal1 and Clock in the ML and RD groups was in antiphase to the expression pattern observed in the fish fed at MD. Under constant conditions (DD?+?RD), Per2 and Cry1 showed circadian rhythmicity in the brain, whereas Bmal1, Clock, and Per2 did in the liver. Our results indicate that the seabream clock gene expression is endogenously controlled and in liver it is strongly entrained by food signals, rather than by the LD cycle, and that scheduled feeding can shift the phase of the daily rhythm of clock gene expression in a peripheral organ (liver) without changing the phase of these rhythms in a central oscillator (brain), suggesting uncoupling of the light-entrainable oscillator (LEO) from the food-entrainable oscillator (FEO). These findings provide the basis and new tools for improving our knowledge of the circadian system and entraining pathways of this fish species, which is of great interest for the Mediterranean aquaculture. (Author correspondence: javisan@um.es).     

Daily rhythms of swimming activity,synchronization to different feeding times and effects on anesthesia practice in an Amazon fish species (Colossoma macropomum)

ABSTRACT

This study aimed to investigate the existence of day-night differences in the time for anesthesia and recovery in tambaqui exposed to the anesthetic eugenol and the influence of feeding time. Thus, we evaluated: (1) swimming activity; (2) food anticipatory activity (FAA) as a synchronizer of swimming activity and change to susceptibility to anesthetic; and (3) the effects of diurnal/nocturnal anesthesia exposure of fish feeding in the mid-light phase: 12:00 h (ML) and fish feeding in the mid-dark phase: 00:00 h (MD). Our findings revealed strictly nocturnal activity for tambaqui (94.2%), known as diurnal fish to date. Moreover, FAA was observed in tambaqui fed at MD, which showed a sustained increase in activity that began 2 h before feeding time and lasted until feeding. In contrast, no FAA was observed in fish fed at ML. Regarding anesthesia by day or night, the tambaqui treated with eugenol exhibited no difference in induction time. However, differences were observed in recovery times, with fish anesthetized at day recovering in 1–2 min and fish anesthetized at night recovering in 5–7 min. In short, our findings revealed for the first time the nocturnal behavior of tambaqui. These results indicated that recovery by day/night by eugenol in tambaqui has a strong dependence of behavioral patterns and the time of day.     

Effect of food deprivation on quantitative and time characteristics of feeding of goldfish Carassius auratus in norm and under action of adrenaline

There was studied effect of intraperitoneally administered adrenaline (0.14 mg/kg) on volume and time characteristics of feeding (duration of single, grouped, and total nutrition) of goldfish Carassius auratus (L.) previously maintained on normal and restricted (for 10 and 15 days) diet. The fish on restricted diet demonstrated the biphasic alimentary response to the adrenaline administration, similar with that in the normally fed fish: a decrease of volume, duration of the grouped and total feeding at the first phase of action of hormone and an increase--at the second phase; however, the value of the response at the first phase of the hormone action was lower, whereas at the second phase--higher than in the fish obtaining a sufficient amount of food prior to the experiment. Duration of the single feeding rose in fish of all groups including the control one, the maximum increase being observed in the goldfish submitted to food deprivation. The glycogen content in hepatopancreas of the normally fed goldfish exceeded by the end of the experiment 4.5-6 times that in the food-deprived ones. The obtained results confirm suggestion that a decrease of the level of reserve substances in the body leads to a decrease of the fish receptivity to the stress hormone--adrenaline and, hence, to a change of the value of its effects on the food-searching goldfish activity, with preservation of dynamics of the parameters.     

西伯利亚鲟在高温下饥饿后的补偿生长

在高温(29±1)℃下将西伯利亚鲟幼鱼(21.61±0.03)g饥饿0(对照)、6、12和18d后恢复摄食3周, 研究摄食、生长和鱼体组成的变化。结果表明, 经过不同程度饥饿的鱼体重均显著低于对照组(P0.05), 而饥饿18d(S18组)的鱼体重显著低于对照(P0.05)。在饥饿过程中,鱼体脂肪含量和肝脏肝糖原含量下降的同时, 各饥饿组的灰分含量上升, 但仅S18组与对照差异显著(P0.05)。结果表明, 西伯利亚鲟在高温下表现出完全补偿现象, 且是通过同时提高摄食率和饲料效率来实现补偿生长的, 因此在夏季高温时对鲟鱼进行一段时间适度的饥饿可以在不影响生长和体成分的前提下节约饲料成本, 减少因过量投饵而引起的环境污染。       

饲料中豆粕替代鱼粉蛋白对异育银鲫生长、代谢及免疫功能的影响

本实验评价了饲料中豆粕替代鱼粉蛋白后对异育银鲫的生长、饲料利用、氮代谢和鱼体免疫力等的影响。实验设计4种等氮等能的饲料,每种3个重复,分别以豆粕替代饲料中鱼粉蛋白的0%（对照,D1）、20%（D2）、80%（D3）和100%（D4）。实验在半循环水养殖系统持续16周,鱼的初重约2.32g,实验期间水温23－30℃。结果表明,随着饲料中豆粕含量的升高,摄食率显著升高(P＜0.05),特定生长率、饲料转化效率、蛋白沉积率和能量沉积率显著降低(P＜0.05);蛋白表观消化率显著升高,干物质和能量表观消化率则显著降低(P＜0.05);总氮摄入量、表观氮摄入量、粪氮排出量、非粪氮排泄量、总氮沉积率均随着饲料中豆粕含量的升高呈显著降低到的趋势(P< 0.05),生产每千克鱼的氮排放量则随着饲料中豆粕含量的升高显著升高(P< 0.05);血清葡萄糖和甘油三酯的含量显著升高,而胆固醇的含量显著降低(P＜0.05);血清的溶菌酶显著降低,超氧化物岐化酶逐渐升高(P＜0.05)。     

Digestibility of chitin in cod,Gadus morhua,in vivo

Sixteen cod,Gadus morhua (L.), were individually fed a single ration of shrimps,Crangon allmanni. Four fish were killed and examined 6, 12, 24 and 48 h after the fish had been fed. Chitinase activities were measured in the extracts of stomach contents, stomach tissue, pyloric caecae, intestinal contents and intestinal tissue. The level of enzyme activity in different parts of the digestive tract was shown to be dependent on the phase of the digestive process. High concentrations of the chitin degradation product N-acetyl-D-glucosamine were determined in the stomach and in the intestinal contents. Based on the chitin concentration in the food organisms and the individual food uptake, the amount of chitin consumed by each fish could be calculated. Only up to 9% of the ingested chitin was recovered from the intestinal contents of the fish at any given time after feeding (6, 12, 24 and 48 h). In addition, only 2.4% of the chitin consumed with the food could be recovered in the collected faeces of the fish. The 4 cod killed 48 h after feeding had completely emptied their stomach. Chitin digestion in these fish was calculated to have been 90%.