Malate Dehydrogenase Activity of Rat Testis: Circadian Rhythm and its Ontogeny

Malate dehydrogenase activity and soluble protein content in testes from rats exposed to a 14:00 h light:10:00 h dark photoperiod, have been determined every two or four hours over a 24 hour period in 5, 15, 25 and 120 day-old rats. By using the Cosinor method, the ontogeny of an unimodal rhythm was studied for MDH activity and soluble protein content in testis. In 5 and 15 day-old rats, the MDH acrophases were recorded around 19:00 h and 17:00 h, respectively. Rats aged 25 and 110 days showed the MDH acrophases during the dark period. An inversion of the MDH circadian rhythms was detected in 25 day-old compared to those of 5 and 15 day-old rats. An inversion of the protein circadian rhythm was also detected at 15 days compared to that at 5 days. These inversions persist in the adult rats. The amplitude of the MDH and protein rhythms reached the lowest value in adulthood. The mean daily value of testicular MDH increased between day 5 and 15, decreasing at day 35 and remaining unchanged until adulthood. The variation of malate dehydrogenase activity, soluble protein content levels, and the circadian rhythm parameters during the maturation process may be related to gonad development.     

Ontogeny of alpha-amylase circadian rhythms in rat parotid gland

The content of alpha-amylase (alpha-1,4-glucan-4-glucanohydrolase, EC 3.2.1.1.) and total soluble proteins of parotid glands (from rats exposed to a photoperiod of 14 hr light: 10 hr dark), have been determined every 2 or 3 hr over 24 hr periods in 15, 25 and 90-day-old rats. In 35-, 45- and 72-day-old rats, determinations were performed only at 0100 and 1400 hr. The alpha-amylase and total soluble protein contents from 90-day-old rats show a circadian variation, with a maximum value at 2200 hr and a minimum at 1400 hr. Parotids from 15- and 25-day-old rats also show a circadian rhythm. The minimum value is recorded at 0100 hr and the maximum at 1400 hr. At day 35 and after, there is an inversion of the amylase rhythm. In immature rats, it appears that alpha-amylase and soluble protein are under the influence of another synchronizer, whose timing is independent of that imposed by mastication of solid food.     

Daily profiles of plasma prolactin (PRL), growth hormone (GH), insulin-like growth factor-1 (IGF-1), luteinizing hormone (LH), testosterone, and melatonin, and of pituitary PRL mRNA and GH mRNA in male Long Evans rats in acute phase of adjuvant arthritis

We studied the effects of adjuvant arthritis (AA) on the endocrine circadian rhythms of plasma prolactin (PRL), growth hormone (GH), insulin-like growth factor-1 (IGF-1), luteinizing hormone (LH), testosterone, and melatonin and of pituitary PRL and GH mRNA in male Long Evans rats. Groups of control and AA rats (studied 23 days after AA induction) that were housed under a 12/12 h light/dark cycle (light on at 06:00 h) were killed at 4 h intervals starting at 14:00 h. Cosinor analysis revealed a significant 12 h rhythm in PRL and PRL mRNA (p < 0.001) in controls with peaks at 14:00 h and 02:00 h, respectively. The peak at 02:00 h was abolished in the AA group resulting in a significant 24 h rhythm in parallel with that of PRL (p < 0.05) and PRL mRNA (p < 0.0001). Growth hormone showed no rhythm, but a significant rhythm of GH mRNA was present in both groups (p < 0.0001). Insulin-like growth factor-1 showed a 24 h rhythm in control but not in AA rats. The mean values of GH, GH mRNA, and IGF-1 were significantly reduced in AA. Luteinizing hormone displayed a significant 24 h rhythm (p < 0.01) peaking in the dark period in the control but not AA group. Testosterone showed in phase temporal changes of LH levels with AA abolishing the 02:00 h peak. Melatonin exhibited a significant 24 h rhythm in control (p < 0.001) and AA (p < 0.01) rats with maximum levels during the dark phase; the mesor value was higher in the AA males. These results demonstrate that AA interferes with the rhythms of all the studied hormones except the non-24 h (arrhythmic) GH secretion pattern and the rhythm in melatonin. The persistence of a distinct melatonin rhythm in AA suggests the observed disturbances of hormonal rhythms in this condition do not occur at the level of the pineal gland.     

Circadian rhythms of DNA content in brain and kidney: effects of environmental stimulation

Male adult Wistar rats kept under natural lighting show circadian rhythms of DNA content and DNA synthesis in the cerebral cortex, cerebellum and kidney. In the cerebral cortex the acrophases of the 2 rhythms almost coincide during the dark period. On the other hand, in kidney, the acrophase of DNA synthesis is phase-advanced by about 14 h with respect to the acrophase of DNA content, which occurs in the dark span, as in the cerebral cortex. Comparable results were obtained in 5 week-old rats raised under artificial lighting conditions (LD 7:19) and exposed for a few days to sensory and social stimulation (an enriched sensory environment). At variance with the latter data, the circadian changes of DNA content and synthesis flattened out and were not statistically significant in the cerebral cortex of 5 week-old rats kept for a few days under conditions of sensory and social deprivation (an impoverished sensory environment). A similar effect occurred in kidney with regard to the rhythm of DNA content, while the circadian rhythm of DNA synthesis remained statistically significant but was phase-delayed by about 6h with respect to the corresponding rhythm occurring in the enriched environment. In sensory impoverished rats, MESOR values of kidney wet weight and DNA specific activity were significantly higher than in sensory enriched rats, while MESOR values of DNA content were significantly lower. The data demonstrate the striking dependence of the circadian variations of DNA content and synthesis on the nature of environmental stimulation.     

Daily rhythms of pituitary-ovarian function in the immature hamster are independent of adrenal and pineal influence

In female hamsters, the daily rhythm of LH appeared on the 15th or 16th day after birth with a peak occurring at about 16:00 h (14L:10D, lights on 06:00 h). Progesterone concentrations increased and became rhythmic a few days later. In serum samples collected at 14, 16, 18, 20, 25, 30, 40 and 60-62 days of age between 13:00 and 23:00 h, significant rhythms of serum cortisol and corticosterone concentrations were not detected before 25 days of age; furthermore, the phase of the rhythms did not stabilize to the adult pattern until about 40 days of age. As in the adult, significant rhythms were present in both sexes and the levels of cortisol were greater than those of corticosterone. Injection of pig ACTH (50 i.u./kg body wt, i.p.) significantly increased serum cortisol by 10 days of age, but corticosterone did not respond until 25 days of age. Thus, for cortisol at least, the appearance of 24-h rhythms in the serum is probably not dependent on the ability of the adrenal to respond to ACTH. Ovariectomy had no effect on the late afternoon surge of serum cortisol; similarly, adrenalectomy of immature females did not abolish the surge of LH. Ovariectomy did not alter the daily rhythm of pineal melatonin content and pinealectomy had no effect on the daily afternoon surge of LH. These results demonstrate functional independence of circadian rhythms in the pituitary-gonadal axis and the pituitary-adrenal axis of the immature hamster and also independence of daily rhythms of pineal melatonin and pituitary release of LH.     

Prenatal and Neonatal Diazepam Administration Synchronizes Testicular Malate Dehydrogenase Circadian Rhythms in Young Rats

Rat or hamster pups exposed to constant light or darkness since birth exhibit many circadian rhythms synchronized with those of the mother. During early development, a number of cues derived from the maternal circadian system synchronize the fetal and neonatal circadian clock. Maternal pineal sympathetic denervation during early pregnancy disrupts maternal synchronization of parotid α-amylase and testicular malate dehydrogenase circadian rhythms in rat pups. Maternal pineal sympathetic denervation was used to study potential agents able to synchronize the fetal or neonatal circadian clock. Melatonin injection to denervated pregnant mothers prevents the pineal sympathetic denervation effect on those circadian rhythms. We now studied the synchronizing effect of a benzodiazepine compound, diazepam. This GABA_A agonist synchronized testicular malate dehydrogenase (MDH) activity of pups when it was injected to sympathetic denervated pregnant dams (a daily dose at 07:00 or 19:00 h from the 14 th to the 20 th day of gestation) or orally administered to the pups (a daily dose at 19:00 h from the 10 th to 24 th day of life). Co-injection of diazepam and GABA_A antagonist, flumazenil, blocked the synchronizing effect of diazepam. The results demonstrate that diazepam has a synchronizing effect on the development of the circadian clock in rats and suggest that modulation of maternal GABA_A could participate in mammalian maternal synchronization.     

AII amacrine neurons of the rat retina show diurnal and circadian rhythms of parvalbumin immunoreactivity

We investigated parvalbumin immunoreactivity (PA-IR) in the retinas of rats maintained on a 12:12 h light:dark cycle, or after being placed in constant darkness for 24–72 h. Retinas were harvested at zeitgeber and circadian times 02:00, 06:00, 10:00, 14:00, 18:00 and 22:00 h. PA-IR was found primarily in retinal amacrine cells of the AII subtype. In a light/dark cycle, PA-IR showed a clear rhythm, with a low near zeitgeber time (ZT) 10:00 h and a peak near ZT 18:00 h. The ratio of immunofluorescence intensities at these timepoints was >15-fold. When animals were kept in complete darkness for 1–3 days, the rhythm of PA-IR was still preserved, but was progressively reduced in amplitude. The rhythm of PA-IR inferred from immunohistochemical data was confirmed by Western blots. We conclude that PA-IR in the rat retina shows an underlying circadian rhythm that is enhanced by cyclic light. The regulation may involve translocation of the protein between cell compartments and/or new protein synthesis.This study was supported by an OTKA grant (T 34160), NIH grants NS 37919 (R.S.) and ET 03570, NSF grant IBN-96418886 (R.S.), and grants from the Helen Hoffritz Charitable Trust and Research to Prevent Blindness, Inc. R.G. was also in receipt of a János Bolyai fellowship     

Maternal Coordination of the Daily Rhythm of Malate Dehydrogenase Activity in Testes from Young Rats: Effect of Maternal Sympathetic Denervation of the Pineal Gland and Administration of Melatonin

Chronic sympathetic denervation of the pineal gland by bilateral removal of the superior cervical ganglia (SCG) was performed on female rats 30 days before impregnation. The offspring, maintained in the dark from birth, had disruption of the malate dehydrogenase circadian rhythm in the testes at 25 days of age. A daily injection of melatonin (1 mg/kg s.c. at 10:00 or 18:00 h) to denervated mothers from the 14th day of pregnancy up to the 10th day postpartum produced one daily phase in the enzyme activity of testes in the offspring. Entrainment of daily enzyme activity also was obtained when the hormone was administered orally to the pups during the postnatal period or when pups were reared by intact (not denervated) foster mothers. The results indicate the involvement of the maternal pineal gland in the maternal transfer of photoperiodic information necessary for the coordination of the circadian system in young rats.     

Maternal Coordination of the Daily Rhythm of Malate Dehydrogenase Activity in Testes from Young Rats: Effect of Maternal Sympathetic Denervation of the Pineal Gland and Administration of Melatonin

Chronic sympathetic denervation of the pineal gland by bilateral removal of the superior cervical ganglia (SCG) was performed on female rats 30 days before impregnation. The offspring, maintained in the dark from birth, had disruption of the malate dehydrogenase circadian rhythm in the testes at 25 days of age. A daily injection of melatonin (1 mg/kg s.c. at 10:00 or 18:00 h) to denervated mothers from the 14th day of pregnancy up to the 10th day postpartum produced one daily phase in the enzyme activity of testes in the offspring. Entrainment of daily enzyme activity also was obtained when the hormone was administered orally to the pups during the postnatal period or when pups were reared by intact (not denervated) foster mothers. The results indicate the involvement of the maternal pineal gland in the maternal transfer of photoperiodic information necessary for the coordination of the circadian system in young rats.     

Suppression of circadian rhythms of pineal and testicular hormones following lithium treatment in normal and reversed light-dark cycles, constant light and constant dark in rats

The aim of the current investigation was to study the effect of lithium on circadian rhythms of pineal - testicular hormones by quantitations of pineal and serum serotonin, N-acetylserotonin and melatonin, and serum testosterone at four time points (06.00, 12.00, 18.00 and 24.00) of a 24-hr period under normal photoperiod (L:D), reversed photoperiod (D:L), constant light (L:L) and constant dark phase (D:D) in rats. Circadian rhythms were observed in pineal hormones in all the combinations of photoperiodic regimens, except in constant light, and in testosterone levels in all the photoperiodic combinations. Pineal and serum N-acetylserotonin and melatonin levels were higher than serotonin at night (24.00 hr), in natural L:D cycle, in reversed L:D cycle or similar to normal L:D cycle in constant dark phase, without any change in constant light. In contrast, testosterone level was higher in light phase (12.00 hr through 18.00 hr) than in the dark phase (24.00 hr through 06.00 hr) in normal L:D cycle, in reversed L:D cycle, similar to normal L:D cycle in constant dark (D:D), and reversed to that of the normal L:D cycle in constant light (L:L). Lithium treatment (2 mEq/kg body weight daily for 15 days) suppressed the magnitude of circadian rhythms of pineal and serum serotonin, N-acetylserotonin and melatonin, and testosterone levels by decreasing their levels at four time points of a 24-hr period in natural L:D or reversed D:L cycle and in constant dark (D:D). Pineal indoleamine levels were reduced after lithium treatment even in constant light (L:L). Moreover, lithium abolished the melatonin rhythms in rats exposed to normal (L:D) and reversed L:D (D:L) cycles, and sustained the rhythms in constant dark. But testosterone rhythm was abolished after lithium treatment in normal (L:D)/reversed L:D (D:L) cycle or even in constant light/dark. The findings indicate that the circadian rhythm exists in pineal hormones in alternate light - dark cycle (L:D/D:L) and in constant dark (D:D), but was absent in constant light phase (L:L) in rats. Lithium not only suppresses the circadian rhythms of pineal hormones, but abolishes the pineal melatonin rhythm only in alternate light - dark cycles, but sustains it in constant dark. The testosterone rhythm is abolished after lithium treatment in alternate light - dark cycle and constant light/dark. It is suggested that (a) normal circadian rhythms of pineal hormones are regulated by pulse dark phase in normal rats, (b) lithium abolishes pineal hormonal rhythm only in pulse light but sustains it in constant dark phase, and (c) circadian testosterone rhythm occurs in both pulse light or pulse dark phase in normal rats, and lithium abolishes the rhythm in all the combinations of the photoperiod. The differential responses of circadian rhythms of pineal and testicular hormones to pulse light or pulse dark in normal and lithium recipients are discussed.     

Prenatal Entrainment of Rat Testicular Malate Dehydrogenase Activity Circadian Rhythm

In mammals the photoperiodic synchronization of circadian system starts before birth. During fetal and neonatal period mothers relay the photoperiodic information to their litter. The maternal pineal melatonin 24 h cycle acts as a synchronizing signal. We have studied the effect of pineal maternal sympathetic denervation and administration of melatonin to mothers denervated during gestation on the prenatal synchronization of testicular malate dehydrogenase (MDH) activity circadian rhythm of the offspring 25 days after birth. When mothers were denervated at the 7th, 10th or 11th day of gestation, pups showed disruption of testicular MDH activity circadian rhythms. In contrast, no disruptive effect was observed when the mothers were denervated on the 12th or 14th day of gestation. When denervated mothers (7th day of gestation) were treated with a daily dose of melatonin from the 11th to the 14th day of gestation, pups showed a MDH activity circadian rhythm. The hormone failed to impose a daily phase when administered from the 9th to the 12th day of gestation. Results suggest that prenatal synchronization in the rat occurs very early in the development, before suprachiasmatic nuclei morphologic arrangement and functional activity begin.     

Prenatal Entrainment of Rat Testicular Malate Dehydrogenase Activity Circadian Rhythm

In mammals the photoperiodic synchronization of circadian system starts before birth. During fetal and neonatal period mothers relay the photoperiodic information to their litter. The maternal pineal melatonin 24 h cycle acts as a synchronizing signal. We have studied the effect of pineal maternal sympathetic denervation and administration of melatonin to mothers denervated during gestation on the prenatal synchronization of testicular malate dehydrogenase (MDH) activity circadian rhythm of the offspring 25 days after birth. When mothers were denervated at the 7th, 10th or 11th day of gestation, pups showed disruption of testicular MDH activity circadian rhythms. In contrast, no disruptive effect was observed when the mothers were denervated on the 12th or 14th day of gestation. When denervated mothers (7th day of gestation) were treated with a daily dose of melatonin from the 11th to the 14th day of gestation, pups showed a MDH activity circadian rhythm. The hormone failed to impose a daily phase when administered from the 9th to the 12th day of gestation. Results suggest that prenatal synchronization in the rat occurs very early in the development, before suprachiasmatic nuclei morphologic arrangement and functional activity begin.     

Circadian Rhythm of the Liver of Male Rats Pre-Treated with Phenobarbital—ii. Hexobarbital Sleeping Time and Lipids Content in Liver and Serum

The circadian rhythm of hexobarbital sleeping time and lipids content in liver and serum were studied in 226 male Sprague-Dawley rats pretreated daily at 0800-0900 with 70 mg/kg (study 1 or 3) or 50 mg/kg (study 2) phenobarbital (PB) orally for 7 days. Thereafter, eight (study 1) or five (study 2 and 3) rats each were studied at 4-hr intervals at 1000, 1400, 1800, 2200, 0200, 0600 and 1000 through the following day. The lighting schedule in the colony was 12:12 ± light:dark (light from 0600 to 1800). The hexobarbital sleeping times of PB-pretreated rats were generally shortened compared to the controls and no circadian rhythm was observed. PB-treatment increased slightly the liver content of cholesterol, and significantly that of triglycerides and phospholipids. Liver cholesterol and phospholipids showed circadian rhythms with peaks during the dark phase. No circadian rhythm of liver triglycerides existed. In serum, levels of triglycerides and phospholipids were slightly lowered by PB-treatment, while levels of cholesterol and beta-lipoprotein were not influenced. Serum values did not exhibit circadian rhythms.     

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.     

Treatment-time-dependent difference of ketamine pharmacological response and toxicity in rats

Circadian rhythms impact many physiological functions that may affect drug pharmacological response. Ketamine is a dissociative agent commonly used for surgical anesthesia in rats. The aim of the present study was to analyze the central nervous system (CNS) depression and lethality of ketamine injected intraperitoneally at different times during the 24 h. The study was conducted in October 2001, spring in the Southern hemisphere. Female prepuberal Sprague-Dawley rats synchronized to a 12h light:12h dark cycle (light, 07:00h-19:00h) were studied. Ketamine (40 mg/kg) was administered to one of six different clock-time treatment groups (n=6-7 rats each). Duration of latency period, ataxia, loss of righting reflex (LRR), post-LRR ataxia, and total pharmacological response were determined by visual assessment. To investigate acute toxicity, ketamine lethal dose 50 (148.0 mg/kg) was also administered as a single injection to six different treatment-time groups of rats. Significant temporal differences and circadian rhythms were detected in drug-induced post-LRR ataxia and total pharmacological response duration. The longest pharmacological response occurred in rats injected during the light (rest) phase and the shortest response in the dark (activity) phase. No circadian rhythm was detected in acute toxicity. The study findings indicate that the duration of CNS depression of ketamine in rats exhibits circadian rhythmic variation.     

Circadian rhythm of lactate dehydrogenase in rat testis

Activity of total lactate dehydrogenase (LDH) and of the isozyme X (LDH X or C4) have been determined at 2 hr intervals during 24 hr cycles in testis of adult rats maintained since birth in a photoperiod of 14 hr light: 10 hr dark. LDH X activity of epididymal sections (caput, corpus and cauda) from the same animals was also determined. Total LDH and LDH X activities in testis exhibited circadian rhythms with different timing. LDH X in the three portions of epididymis showed diurnal variations similar to those in testis. Rats subjected to constant light or constant dark presented marked modifications of LDH X profiles, indicating that the photoperiod plays a synchronizer role. While total soluble proteins did not show variations in testis of rats exposed to the photoperiod, a circadian rhythm was demonstrated in animals maintained in constant light or dark.     

The Role of Wheel Running in the Coupling of Two Simultaneous Circadian Rhythms of Motor Activity in the Rat

Motor activity is among the non-photic stimuli that act on the internal clock. We have tested the role of motor activity in the circadian pattern of rats under conditions near the lower limits of entrainment, that induce circadian rhythm dissociation. Three groups of 8 rats each were used: a) rats kept individually in 25×25×15 cm cages, b) rats in 50×25×15 cm cages, and c) rats in 50×25×15 cm cages with access to a running wheel. All the rats were kept under light-dark cycles of 22 hours (T22, 11L:11D) for 50 days, after which they were transferred to constant darkness. All the rats without a running wheel showed a motor activity pattern with two statistically significant circadian rhythms in the periodogram of Sokolove and Bushell: one circadian component entrained by the LD cycle, and another free-running. The rats with access to a running wheel showed several patterns: 5 rats showed only one rhythm entrained to the LD cycle, 2 rats showed circadian rhythm dissociation, and 1 showed only a free running rhythm. We believe that the simultaneous manifestation of two circadian components reflects the functional dissociation of the oscillators population that constitutes the circadian pacemaker, of the rat. Physical exercise acts on the pacemaker reinforcing the strongest group of oscillators, which, depending on the structure of the circadian system of the rat, is usually the one entrained to the LD cycle. This study supports the hypothesis that motor activity couples the oscillators that form the circadian system of the rat.     

The Role of Wheel Running in the Coupling of Two Simultaneous Circadian Rhythms of Motor Activity in the Rat

Motor activity is among the non-photic stimuli that act on the internal clock. We have tested the role of motor activity in the circadian pattern of rats under conditions near the lower limits of entrainment, that induce circadian rhythm dissociation. Three groups of 8 rats each were used: a) rats kept individually in 25×25×15 cm cages, b) rats in 50×25×15 cm cages, and c) rats in 50×25×15 cm cages with access to a running wheel. All the rats were kept under light-dark cycles of 22 hours (T22, 11L:11D) for 50 days, after which they were transferred to constant darkness. All the rats without a running wheel showed a motor activity pattern with two statistically significant circadian rhythms in the periodogram of Sokolove and Bushell: one circadian component entrained by the LD cycle, and another free-running. The rats with access to a running wheel showed several patterns: 5 rats showed only one rhythm entrained to the LD cycle, 2 rats showed circadian rhythm dissociation, and 1 showed only a free running rhythm. We believe that the simultaneous manifestation of two circadian components reflects the functional dissociation of the oscillators population that constitutes the circadian pacemaker, of the rat. Physical exercise acts on the pacemaker reinforcing the strongest group of oscillators, which, depending on the structure of the circadian system of the rat, is usually the one entrained to the LD cycle. This study supports the hypothesis that motor activity couples the oscillators that form the circadian system of the rat.     

Postnatal development of TRH and TSH rhythms in the rat

We previously observed that under a 12-hour light/12-hour dark schedule (lights off at 19.00 h), adult male Sprague-Dawley rats showed a circadian rhythm for serum thyroid-stimulating hormone (TSH) with a zenith near midday. In the present work, the ontogenesis of serum TSH rhythm was determined as well as pituitary TSH variations. In addition, hypothalamic and blood TRH were measured in these rats aged 15, 25, 40 and 70 days when sacrificed. As from the first age studied (15 days), a hypothalamic thyrotropin-releasing hormone (TRH) circadian rhythm was present. The mesor and the amplitude of this hypothalamic TRH rhythm increased while the rats were growing up, in contrast with the decrease observed for these parameters as far as blood TRH circadian rhythm is concerned. The time of the acrophase moved from 17.32 h in the 15-day-old rats to 13.57 h in the 70-day-old rats, being constantly in phase opposition with the blood TRH acrophase. The low amplitude pituitary TSH circadian rhythm detected in the young rat disappeared in the adult while, in contrast, the serum TSH rhythm became consistent to reach the well-characterized circadian midday peak in the 70-day-old rats.     

Circadian Rhythms of Plasma Concentrations of Na+ and K+ and Their Urinary Excretion in Normal and Diabetic Rats

The effects of streptozotocin induced diabetes (50 mg/Kg) on the circadian rhythms in the excretion of sodium and potassium as well as their plasma concentration rhythms were investigated. Control (C) and diabetic (D) rats were studied during a light-dark (12h:12h) cycle and fed ad libitum. Statistically significant circadian rhythms were found for sodium and potassium excretion in C rats. The orthophases of both rhythms occurred in the dark phase, the potassium one occurring before that of sodium. In D rats there is increased excretion of both sodium and potassium with the rhythmicity maintained for sodium excretion only, which has an earlier orthophase than in the C rats. Plasma sodium and potassium concentrations showed a statistically significant circadian pattern in C rats, with orthophase in the light phase. This rhythmicity only appears in plasma potassium concentration for D rats, with orthophase at the end of the dark phase. The results in diabetic rats may suggest that the glomerular filtration rate (GFR) and/or tubular reabsorption rhythms are still contributing to the sodium excretory rhythm, and that the loss of the circadian rhythm in sodium plasma concentration has no influence on the sodium excretion rhythm. Nevertheless, the loss of the potassium excretion rhythm may suggest a disruption of the variations in the secretory process, as this excretion seems to be independent of the plasma potassium concentration rhythm, which is not lost in D rats.