A diurnal plasma vasopressin rhythm in rats

The purpose of this paper was to determine whether there is a diurnal plasma arginine vasopressin (AVP) rhythm in rats. Using an AVP radioimmunoassay, plasma AVP levels were determined at frequent intervals throughout a 24-hour period in adult male rats. Our data revealed a diurnal rhythm in plasma AVP levels, with mid-afternoon and early evening levels significantly greater than those in the morning and late evening.     

A morphometric study of cellular autophagy including diurnal variations in kidney tubules of normal rats

Cellular autophagy in convoluted tubules of kidney was studied in 24 rats, killed in pairs at constant time intervals during one diurnal cycle, by (a) morphometric evaluation of tubular cells by the point-counting method in randomly sampled micrographs, and (b) selective search for autophagic vacuoles (AV) directly on the electron microscopy screen. The total area of tubular cells recorded in the electron microscopy sections was 93 X 10(-4) mum2. Since the distal convoluted tubules, covering about 12% of the whole tubulocellular area, contained only 3-4% of all AV, they were omitted from the main calculations. The number of AV per area unit and the total amount of segregated material showed a distinct diurnal rhythm, synchronous for the different types of AV which were distinguished from each other according to their contents. The minimum was found during the night, the maximum during the day. This rhythm appears similar to that described elsewhere in liver cells. The mean segregated fractions were calculated from the relation of segregated to nonsegregated material in proximal convoluted tubular cells. The segregated fraction of the mitochondria was 4.4 X 10(-4). This value could account for the degradation of all mitochondria in a cell within 15 days, i.e., the upper limit of the lifetime of mitochondrial DNA in the cortex of the kidney, if one assumes that a mitochondrion is destroyed within 10 min after being segregated. The degregated fraction of microbodies was 11.7 X 10(-4). This suggests a shorter lifetime of these organelles. It is concluded that cellular autophagy plays a significant role in the turnover of cytoplasmic constituents, including the membranes of the endoplasmic reticulum.     

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.     

Timing of a single daily meal affects daily serum prolactin rhythm in gulf killifish, Fundulus grandis

Fish fed at one of two different times of day had differences in mean levels of serum prolactin throughout the day. Although the forms of the daily rhythms from the two groups were similar, they differed at one time of day.     

Meal cysteine improves postprandial glucose control in rats fed a high-sucrose meal

Whey protein, particularly the alpha-lactalbumin fraction, are rich in cysteine (cys) and could therefore favor postprandial glucose homeostasis by a glutathione-mediated effect. This work investigates the effects of the ingestion of an alpha-lactalbumin-rich whey concentrate (alpha-LAC) during a high-sucrose (HS) meal on postprandial glucose homeostasis in healthy rats. In the first experiment, rats received an HS meal containing 14% protein, in which the protein source was either alpha-LAC (HS(a)) or total milk proteins, alone (HS(0)) or supplemented with 17 mg (HS(1)) or 59 mg (HS(2)) of N-acetylcysteine (NAC). This resulted in a total cys content 3.6-fold higher in the HS(1) and HS(a) meals and 12-fold higher in the HS(2) meal, when compared to the HS(0) meal. Postprandial parameters were monitored for 3 h after ingestion of the meal. The same measurements were performed on rats injected with 4 mmol/kg of buthionine sulfoximine (BSO), a specific inhibitor of glutathione synthesis. Increasing the meal's cys content dose-dependently reduced both postprandial glucose and insulin (P<.05). The inhibition of glutathione synthesis with BSO injection abrogated the beneficial effects of NAC supplementation on postprandial glucose response but did not affect those of alpha-LAC. These results show that (1) the substitution of alpha-LAC for total milk protein reduces glucose response, as does the addition of a cys donor to the meal, (2) but contrary to those of a simple cys donor, the beneficial effects of alpha-LAC are not entirely mediated by glutathione synthesis, suggesting additional mechanisms.     

Evidence of a diurnal rhythm in implicit reward learning

Many aspects of hedonic behavior, including self-administration of natural and drug rewards, as well as human positive affect, follow a diurnal cycle that peaks during the species-specific active period. This variation has been linked to circadian modulation of the mesolimbic dopamine system, and is hypothesized to serve an adaptive function by driving an organism to engage with the environment during times where the opportunity for obtaining rewards is high. However, relatively little is known about whether more complex facets of hedonic behavior – in particular, reward learning – follow the same diurnal cycle. The current study aimed to address this gap by examining evidence for diurnal variation in reward learning on a well-validated probabilistic reward learning task (PRT). PRT data from a large normative sample (N = 516) of non-clinical individuals, recruited across eight studies, were examined for the current study. The PRT uses an asymmetrical reinforcement ratio to induce a behavioral response bias, and reward learning was operationalized as the strength of this response bias across blocks of the task. Results revealed significant diurnal variation in reward learning, however in contrast to patterns previously observed in other aspects of hedonic behavior, reward learning was lowest in the middle of the day. Although a diurnal pattern was also observed on a measure of more general task performance (discriminability), this did not account for the variation observed in reward learning. Taken together, these findings point to a distinct diurnal pattern in reward learning that differs from that observed in other aspects of hedonic behavior. The results of this study have important implications for our understanding of clinical disorders characterized by both circadian and reward learning disturbances, and future research is needed to confirm whether this diurnal variation has a truly circadian origin.     

Postprandial intestinal and whole body nitrogen kinetics and distribution in piglets fed a single meal

Our aim was to characterize the postprandial total and dietary N fluxes in the portal drained viscera (PDV) and whole body after administration of a single meal in young pigs. Seven 4-wk-old piglets, implanted with a portal flow probe and portal, arterial and venous catheters, received a primed constant [(18)O]urea intravenous infusion and were studied for 8 h after a bolus mixed meal ingestion (46 mmol N/kg body wt) intrinsically labeled with (15)N to trace dietary N fluxes. The real cecal digestibility of the formula was 94.3% (SD 1.8). PDV output of dietary N was found principally in the pool of circulating protein (51% of the measured dietary N PDV output), in the free alpha-amino N pool (44%), and to a lesser extent in ammonia (5%). Dietary N release in alpha-amino N and ammonia mainly occurred during the first 3 h. Total and exogenous postprandial urea productions were 5.8 and 2.0 mmol N/kg body wt, respectively. At the end of the postprandial period, losses of dietary N amounted to 10.3% of the dose: 5.7% through ileal losses and 4.6% by deamination and transfer to urea. Net postprandial retention of dietary N was 90.4% (SD 1.3), of which 20% was found in splanchnic zone (small intestine 10%, liver 5%, and plasma protein 3%) and 42% in peripheral zone (muscle 31%, skin 6%). In conclusion, our results show a high efficiency of dietary N utilization for muscular uptake and anabolic utilization. However, the results obtained point out the necessity to further explore the form of dietary N released into the portal blood.     

Circadian rhythm of plasma sodium is disrupted in spontaneously hypertensive rats fed a high-NaCl diet

High-NaCl diets elevate arterial pressure in NaCl-sensitive individuals, and increases in plasma sodium may trigger this effect. The present study tests the hypotheses that 1) plasma sodium displays a circadian rhythm in rats, 2) the plasma sodium rhythm is disturbed in spontaneously hypertensive rats (SHR), and 3) excess dietary NaCl elevates plasma sodium concentration in SHR. The results demonstrate that plasma sodium has a circadian rhythm that is inversely related to the circadian rhythm of arterial pressure. Although the plasma sodium rhythms of SHR and control rats are nearly identical, the plasma sodium concentrations are significantly higher in SHR throughout the 24-h cycle. Maintenance on a high-NaCl diet increases plasma sodium concentration similarly in both SHR and control rats, but it blunts the plasma sodium rhythm only in SHR. These results demonstrate that in rats, plasma sodium has a circadian rhythm and that high-NaCl diets increase plasma sodium concentration.     

Inhibition of cellular autophagy in proximal tubular cells of the kidney in streptozotocin-diabetic and uninephrectomized rats.

To examine the significance of anti-catabolism in renal hypertrophy, cellular autophagy was investigated by electron microscopic morphometry in proximal tubular cells (PTCs) of the outer cortex of the rat kidney after the induction of diabetes mellitus by streptozotocin (STZ) and after unilateral nephrectomy. Adult male Sprague-Dawley rats were divided into three groups and killed by retrograde perfusion fixation, 1, 2 and 3 days after the induction of diabetes (group D; n = 24), after unilateral nephrectomy (group N; n = 24) and after combined treatment (group DN; n = 24). Untreated, age-matched litter mates served as controls (group C; n = 24). By comparison with these controls, the left kidney to initial body weight ratio was increased by 8, 23, and 15% in group D animals, by 8, 23, and 24% in group N animals, and by 10, 21, and 25% in group DN animals at the first, second and third day, respectively. Quantitative evaluation of large test areas showed that the volume and numerical densities of autophagic vacuoles (AVs) in PTCs were significantly lower in these hypertrophed kidneys than in the controls. The average reduction in AV volume density was about 65% in group D animals, about 50% in group N animals and about 75% in group DN animals. These data show that autophagic degradation of cytoplasmic components in PTCs is inhibited in renal hypertrophy independently of the growth stimulus, i.e. uninephrectomy or diabetes. Since insulin per se inhibits cellular autophagy in PTCs, the expected effect of insulin dificiency seems to be counteracted by as yet undefined stimuli that may be related to metabolic work load.     

Circadian rhythm of serum and tissue lipids in fed and fasted rats

The oscillations of the free fatty acid concentration in the serum and white (epididymal) adipose tissue, of triglycerides in the serum and liver, of total serum, liver and adrenal cholesterol and of serum phospholipids were studied at 3-hour intervals for a period of 24 hours in fed male Wistar rats and in animals fasted for 24 hours (both adapted to an illumination regimen of 12 hours' light and 12 hours' darkness. The rhythm--studied by means of the cosinor analysis--was present in most of the given parameters; it was not recorded in the liver triglycerides and serum phospholipids of fasted rats and in the adrenal cholesterol of fed animals. Apart from the circadian rhythm, many parameters distinctly displayed an ultradian rhythm, mainly an approximately 12-hour period. In general, one day's starvation did not significantly affect the course of the circadian oscillations of the given indicators of rat lipid metabolism.     

Studies on cellular autophagocytosis : Vinblastine-induced autophagy in the rat liver

Administration of vinblastine (5 mg/kg) in two doses intraperitoneally to rats induced a prominent formation of autophagic vacuoles in rat liver parenchymal cells. Four hours after the first injection of vinblastine, clearly recognizable organelles were seen inside these vacuoles, and by 12 h the cells were filled with residual body type of lysosomes. As compared with glucagon administration, vinblastine was followed by a far greater degree of autophagy, and therefore, offers an excellent model for future studies on autophagy.     

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.     

Increased cellular proliferation in adipose tissue of adult rats fed a high-fat diet.

The feeding of a high-fat diet to adult rats was shown to increase the incorporation of [3H]thymidine into DNA of the adipocyte and stromal fractions. After only 2 days on a high-fat diet there was a marked increase in the incorporation of label. When a 2-week period was interposed between [3H]thymidine administration and determination of DNA specific activity, the greatest increase in incorporation of label was found after 1 week on the diet, when incorporation increased 6-fold or more in both adipocytes and stroma and subsequently decreased to stabilize at a level two or three times that of chow-fed rats in the adipocyte fraction. Rats labeled when young and later placed on a high-fat diet showed a decrease in DNA specific activity in both adipocytes and stroma, confirming that cellular proliferation had occurred in both fractions. The specific activities of both stromal and adipocyte DNA were very similar at all time points studied. An attempt to increase the difference in specific activities by waiting many weeks after [3H]thymidine injection before isolating DNA was not successful. This may be because the total amount of DNA in the stromal and adipocyte fractions increases in parallel on the diet. The significance of these findings in terms of the normal turnover of adipose tissue DNA and the responsiveness to diet is discussed.