Diurnal changes in the 3-hydroxybutyrate dehydrogenase activity of rat liver mitochondria during chronic alcohol consumption and after cessation

The activity of 3-hydroxybutyrate dehydrogenase (EC 1.1.1.30) in the isolated rat liver mitochondria changes but slightly during 24 h. In animals which were fed 10% ethanol solution for 3.5 months the enzyme activity varies within the daily cycle: maximum--at 10 p. m., minimum--at 1-4 p. m. and at 4-7 a. m.; the average daily activity gets three times lower. The cessation of the alcohol consumption makes average daily activity of the enzyme only two times higher, but the character of daily changes in the activity is different: the maximum is observed at 4-7 p. m., the minimum at 4-7 a. m.     

Circadian rhythms of sterol 12alpha-hydroxylase, cholesterol 7alpha-hydroxylase and DBP involved in rat cholesterol catabolism

Circadian rhythms of important enzymes involved in the conversion of cholesterol to bile acids [sterol 12alpha-hydroxylase (12alpha-hydroxylase) and cholesterol 7alpha-hydroxylase (7alpha-hydroxylase)] and an albumin site D-binding protein (DBP) were examined in rats. When the animals were fed freely, they usually ate in the dark and the circadian rhythms of activities of 12alpha-hydroxylase and 7alpha-hydroxylase showed the same peaks (at 10 p.m.) and lows (at 2 p.m.). Their mRNA levels were determined at four timepoints: 3 a.m., 10 a.m., 3 p.m. and 10 p.m. A maximum of the rhythm of 12alpha-hydroxylase was observed at 3 p.m. and the minimum at 3 a.m. These results are distinct from those of 7alpha-hydroxylase, whose maximum point was at 10 p.m. and minimum at 3 p.m. When the rats were fed only in the day-time (from 9 a.m. to 5 p.m.), a marked shift of the activity and mRNA rhythms was observed with both enzymes. The circadian rhythms of the activities of both enzymes showed the same peaks (at 3 p.m.), but the mRNA levels of 12alpha-hydroxylase were distinct from those of 7alpha-hydroxylase, whose maximum point was at 3 a.m. and minimum at 10 p.m. Differences between the maximum and the minimum points of each enzyme mRNA level were statistically significant (P < 0.01 for 12alpha-hydroxylase and 0.05 for 7alpha-hydroxylase). Moreover, circadian rhythms of DBP were also markedly shifted with the change of feeding period. The maximum mRNA level was observed at 10 p.m. instead of 10 a.m. and the minimum was at 10 a.m. instead of 10 p.m.     

Pineal synaptic ribbons in blinded rats

Summary To study the effects of bilateral ophthalmectomy on the circadian rhythm of the pineal gland, the number of the synaptic ribbons and ribbon fields in the pineal gland of female rats were determined by electron microscopy. In a preliminary experiment, the pineal gland was taken from rats at 15 days, and 1, 2, 3, 4, and 6 months after bilateral ophthalmectomy. It was found that the numbers of both synaptic ribbons and ribbon fields decreased markedly and reached a minimum at 1 month postoperatively, but recovered completely after 4 months. In the main experiment, the number of these intracellular elements was counted in both control and enucleated animals killed at 4 h intervals between 02:00 h and 22:00 h at either 1 month or 6 months after operation. All animals were kept under a lighting regimen of 12 h of illumination (06:00 to 18:00) and 12h of darkness (18:00 to 06:00). After 1 month, a remarkable decrease in the number of both the synaptic ribbons and ribbon fields was again noted but the circadian rhythm still remained. Complete quantitative and qualitative recovery in the circadian rhythm was obtained 6 months later.Supported by a grant-in-aid from the Japanese Ministry of Education, Science and Culture The authors wish to thank Mrs. Kazuko Moriwaki for her technical assistance     

Seasonal and circadian fluctuations of the biochemical indices of the blood in mice

Seasonal (in January, April, July, October) changes of aspartate aminotransferase (AST), alanine aminotransferase (ALT), protein, bilirubin, glucose, cholesterol, creatinine, blood urea nitrogen, Cl-, K+, Na+ content were studied in the blood plasma of mice at different time of day (6 p. m., midnight, 6 a. m., midday). The analysis of the average daily indices has shown that the most expressed variations were the following: AST (spring maximum is 3.7 times higher than autumn minimum), ALT (winter maximum is 2.9 times higher than autumn minimum), creatinine (summer maximum is 2.5 times higher than winter minimum), blood urea nitrogen (summer maximum is 2.5 times higher than autumn minimum). Bilirubin and protein content in spring is insignificant, but it is significantly higher than in other seasons. Cholesterol content is lower in winter. No differences in glucose, Cl-, K+, Na+ content in different months have been revealed. The largest circadian synchronization was observed in winter in AST, glucose, cholesterol, protein, Cl-, K+, Na+ (the level observed at 6 p. m. and at midday is higher than that observed at midnight and 6 a. m.) and in autumn in AST, ALT, glucose, cholesterol, blood urea nitrogen, with the circadian curves inverse as compared to the winter period. In spring practically no circadian synchronization was observed.     

Cerebral Cortical Glucose Utilization in the Conscious Rat: Evidence for a Circadian Rhythm

Abstract: The presence of a circadian rhythm of glucose utilization was demonstrated in vivo in rat cerebral cortex. The activity pattern of the rats, living in a controlled lighting regimen with lights on from 7 a.m. to 7 p. m., appeared to coincide with the rate of glucose consumption in the brain. The rate of utilization was measured at 3-h intervals throughout the day and was found to fall from a maximum at 3 a.m. of 0.98 ± 0.13 μmol min⁻¹ g⁻¹ to a minimum of 0.70 ± 0.08 μmol min⁻¹ g⁻¹ at 3 p. m. Brain glucose also varied with time and its fluctuating level weakly correlated with its rate of utilization. Animals entrained on a 5-h (4: 30-9: 30 p. m.) feeding schedule had a similar circadian rhythm, with only a slight increase in amplitude. Reversal of the light cycle caused a disruption in the normal rhythm, but utilization still varied significantly with time of day. The results both indicate the potential error that can be encountered in experiments done at different times of the day and stress the need for awareness of time of day as a factor in measurements of alterations of metabolic rate in the brain.     

Total plasma homocysteine: influence of some common physiological variables

Summary The purpose of this study was to investigate H(e) concentration in plasma from 80 healthy donors in relation to age (6 newborns are also included), sex, daily variation (9, 11 a.m.; 2, 6, 12 p.m.) and a period of 5 subsequent months. A significant correlation (r = 0.63, p < 0.001) was observed between plasma H(e) and age and a statistical difference (p < 0.05) was found between female and male. No circadian rhythm or significant variations over 5 months were found.     

Circadian rhythm of hypothalamo-hypophyseal-adrenal activity in the chicken.

Corticosteroid production, ACTH content in the adenohypophysis and CRF content in the median eminence were studied in vitro and in vivo in the 3-weeks-old chicken according to SAFFRAN and SCHALLY in four different parts of the day: at 6 and 12 a.m., and 6 and 12 p.m. The chicken adrenals in vitro produced only corticosterone in fluorimetrically measurable amounts, with the maximum during the day and the minimum in the evening and at night. Sensitivity to ACTH of the adrenals in vitro was higher during the day than in the evening or at night. After paper-chromatographic separation, steroid hormones equivalent to corticosterone and cortisol could be detected fluorimetrically in the plasma. The "cortisol" level was about 2-2.5 times higher than the corticosterone level. Plasma "cortisol" level displayed the peak at 6 a.m. and the minimum at 12 p.m., while corticosterone at 12 a.m. and 12 p.m., respectively. ACTH content in the adenohypophysis was lowest at 6 a.m. then increased gradually until 12 p.m. CRF level in the median eminence fell during the forenoon, was lowest at noon, to rise up to 6 p.m. and persist at a high level between 6 p.m. and 6 a.m. Thus, in the 3-week-old chicken the functioning of the hypothalamo-hypophyseal-adrenal system displays a circadian rhythm characteristic of animals showing diurnal activity.     

植物生长季退化草毡寒冻雏形土CO2释放特征

对中国科学院海北高寒草甸生态系统定位站地区退化草毡寒冻雏形土CO2释放的全天候连续观测结果表明,退化草毡寒冻雏形土CO2的释放有明显的日变化和季节动态,日最大释放速率出现于12：00-14：00,最小释放速率出现于6：00-8：00;植物生长季的最大振幅为462.49mg·m^-2·h^-1（8月18日）,最小振幅为114.97mg·m^-2·h^-1（5月9日）,CO2释放速率白天大于夜晚。不同物候期CO2释放速率亦不同,草盛期>枯黄期>青期。最大日均值为480.76mg·m^-2·h^-1（8月18日）,最小日均值为140.77mg·m^-2·h^-1（5月9日）。释放速率与气温、地表温度及土壤5cm地温均呈显著或极显著相关关系,表明温度是决定CO2释放速率季节变化的首要因素。     

Effects of a combination of rhGH and metformin on adiponectin levels in patients with metabolic syndrome.

Adiponectin is a recently discovered adipocytokine that correlates negatively with body mass index and body fat. In patients with GH deficiency, treatment with recombinant human growth hormone (rhGH) reduces body fat mass and thus may also have a favorable effect in patients with metabolic syndrome, and would also be expected to increase adiponectin levels. However, due to its diabetogenic effect, rhGH treatment also bears an increased risk for the development of type 2 diabetes mellitus. We conducted a 18-month randomized, double-blind, placebo-controlled study to assess the effect of rhGH in combination with metformin (MGH) in 14 obese men (7 MGH; 7 Metformin+Placebo, 54 +/- 2 years, BMI 33.0 +/- 1.2 kg/m(2)) with mildly elevated fasting plasma glucose (FPG) at screening (6.1-8.0 mmol/l). All patients received metformin (850 mg twice daily) for treatment of type 2 diabetes mellitus/impaired glucose tolerance, either alone or in combination with rhGH (daily dose 9.5 mug/kg body weight). Glucose disposal rate (GDR) was measured using the euglycemic hyperinsulinemic clamp technique, and body composition was measured by DEXA at 0 and 18 months. After 18 months, the mean adiponectin concentration increased by 32 +/- 11 % (p = 0.018) in the MGH group and did not change in the MP group (- 10 +/- 13 %; p = n. s.). The difference in relative changes in adiponectin levels between the two groups after 18 months was statistically significant (p = 0.026). Improvement in insulin sensitivity (GDR) correlated positively with adiponectin levels (r = 0.73; p = 0.004). In conclusion, the additional administration of rhGH increased adiponectin levels in patients with metabolic syndrome, indicating its potential role in adiponectin-associated insulin sensitivity alterations.     

Respiratory response to chemical stimuli and exercise capacity under conditions of acute hypoxia in elite mountain climbers]

To investigate the factors that modulate exercise performance at extreme altitude, the role of the following variables was analyzed in 16 climbers: 1) ventilatory response to chemical stimuli (hypoxia and hypercapnia); and, 2) maximum exercise performance while breathing room air and during acute hypoxia (F1O2, 0.11). Seven climbers (elite climbers, AE) had previously ascended to 8,000 m or more above sea level, and 9 (A) had never achieved such extreme altitude. Then healthy sedentary subjects (C) of similar age (31.1 +/- 6.0 SD years) were used as control group. Elite climbers showed higher ventilatory responses to both transient hypoxia (-0.49 +/- 0.13 L x min-1 x %-1) (p less than 0.05) and progressive hypoxia (-0.47 +/- 0.13 L x min-1 x %-1) than C (-0.33 +/- 0.14 and -0.30 +/- 0.15 L x min-1 x %-1, respectively). By contrast, no differences were observed between the two groups of climbers. The ventilatory response to hypercapnia was higher in AE (3.04 +/- 1.03 L x min-1 mmHg-1) compared to A (1.85 +/- 0.73 L x min-1 mmHg-1) (p less than 0.05) but similar to that observed in C. Breathing 11% O2, maximum workload and oxyhemoglobin desaturation during maximum exercise were similar in both groups of climbers. Additionally, the ventilatory response to hypoxia did not correlate with maximum workload (F1O2, 0.11), maximal ventilation during exercise (F1O2, 0.11), nor with the altitude score. The present study supports previous reports that inform about the role of the ventilatory response to hypoxia in the exercise performance at high altitude.(ABSTRACT TRUNCATED AT 250 WORDS)     

Cold entrainment of the annual cycle of ovarian activity in the lizard Lacerta vivipara: thermoperiodic rhythm versus hibernation.

A constant warm thermoperiod maintains ovarian quiescence in the lizard Lacerta vivipara, whereas a 4-month artificial hibernation rapidly induces synchronized vitellogenesis after transfer to warmth. The present study examined the possibility of a thermoperiodic regulation of the ovarian cycle and the formal properties of an internal temporal program. These questions were addressed using 24-hr thermoperiodic conditions that combined a long or a short thermophase (6 or 2 hr of basking) with a warm (19-21 degrees C), a cool (5-15 degrees C), or a cold (3-7 degrees C) cryophase. Lizards were exposed to the natural photocycle or to LD 12:12. Occurrence and timing of vitellogenesis completion were monitored using immunodetection of plasma vitellogenin and laparotomies. Cold remained stimulatory when given intermittently with a 24-hr periodicity. However, under long-thermophase conditions, lizards responded poorly to cool cryophases but fully to cold ones (72.7-100% vitellogenesis). Thus a certain amount of cold must be provided during each 24-hr cycle in order to be effective through the succession of thermocycles. Reduction of the daily heat input from 6 to 2 hr modulated the stimulating effects of cold cryophases: The median date for the beginning of vitellogenesis occurred 1 month earlier, but the number of responding females decreased from 100% to 40%. The thermoperiodic regulation of the ovarian cycle also relies upon a precise heat-cold balance per nycthemeral unit. This ensures the entrainment of an internal rhythm, since the timing of reproductive responses varies with the date of transfer from the inhibitory warm thermoperiod to the inducing thermoperiod (long thermophase, cold cryophase). At least half the females started vitellogenesis within 1-2 months after a late transfer (winter solstice) instead of 6 months after an early one (autumn equinox), and the median date for onset differed by 1 month between the two groups. However, autumn transfer was the only one to induce a group response in close agreement with the natural timing.     

Influence of the light regimen on the circadian rhythm of serum lipids in the laboratory rat

Young male rats of a conventional Wistar breed were adapted for several weeks (3-6) to a 12:12 h light:dark (7 a.m. - 7 p.m., 7 p.m. - 7 a.m.) regimen (LD), to inversion of this standard regimen (DL), to continuous darkness (DD) or to continuous light (LL). After adaptation, groups of animals were killed at 3-hour intervals during the day and the basic lipid fractions were determined in their serum. Under the standard light regimen the cosinor test demonstrated a rhythm in all the indicators (triacylglycerols, total cholesterol, phospholipids) except for non-esterified fatty acids. When the regimen was inverted (DL), the peaks of the circadian non-esterified fatty acid and triacylglycerol curves shifted to the antiphase. The acrophases of "free-running" serum lipid rhythm under the DD regimen of the standard regimen rhythms differed in the case of cholesterol and phospholipids. In the case of triacylglycerols and phospholipids there was disagreement between the DD and LL regimen curves. With reference to the localization of the acrophase under the DD and LD regimens it was assumed that the influence of the light regimen on the synchronization of circadian rhythms is small in the case of serum non-esterified fatty acids and triacylglycerols and that it is greater in the case of serum cholesterol and phospholipids.     

The Circadian Rhythm of Body Temperature of the Horse

Rectal temperature of 10 female adult horses was recorded every 2 h for 10 consecutive days under a natural winter photoperiod (9 h of light and 15 h of darkness per day). A robust daily rhythm of body temperature was observed in all animals. The rhythm had a mean level of 38.3°C and a range of excursion of 1.0°C. Temperature started its daily ascent at dawn each day and reached a maximum 14 hours later. Body temperature of 5 of the horses was studied for 10 more days under constant illumination. The rhythm persisted under this condition, although with a slightly longer period of 24.2 h, which confirms the endogenous nature of the rhythm. Despite the fact that the body size of the horse is several orders of magnitude greater than that of rodents, the various parameters of the body temperature rhythm of the horse are similar to those of several species of rodents previously studied.     

The Circadian Rhythm of Body Temperature of the Horse

Rectal temperature of 10 female adult horses was recorded every 2 h for 10 consecutive days under a natural winter photoperiod (9 h of light and 15 h of darkness per day). A robust daily rhythm of body temperature was observed in all animals. The rhythm had a mean level of 38.3°C and a range of excursion of 1.0°C. Temperature started its daily ascent at dawn each day and reached a maximum 14 hours later. Body temperature of 5 of the horses was studied for 10 more days under constant illumination. The rhythm persisted under this condition, although with a slightly longer period of 24.2 h, which confirms the endogenous nature of the rhythm. Despite the fact that the body size of the horse is several orders of magnitude greater than that of rodents, the various parameters of the body temperature rhythm of the horse are similar to those of several species of rodents previously studied.     

Daily and seasonal variations in plasma LH and testosterone concentrations in the adult male hedgehog (Erinaceus europaeus)

A double-antibody heterologous radioimmunoassay (RIA) was developed to measure plasma LH values in hedgehogs. This RIA system used anti-rat LH serum and rabbit LH (AFP-559B) for radioiodination and as standard. The accuracy of the method was evaluated and indicated the ability to detect various relative concentrations of LH in plasma. The minimum detectable dose was 0.2 ng/ml. The intra- and inter-assay coefficients of variation were 4.2 and 7.9% respectively. Biological tests, e.g. effect of castration, effect of castration + testosterone implant and GnRH administration, confirmed that this method was suitable to determine subsequent changes in pituitary gonadotrophic activity in the hedgehog. LH concentrations were determined in blood samples obtained during 1 year: (a) each month, at 4-h intervals during 24 h, from different groups of unanaesthetized animals fitted with a catheter and (b) twice a month, under a light anaesthesia, from the same group of 6 animals. During the year: (1) the range of LH change was narrow (minimum values congruent to 0.25 ng/ml and maximum values congruent to 2.00 ng/ml); (2) the 24-h LH patterns did not exhibit any daily rhythm; (3) a clear annual rhythm was observed with the highest values from February to April and the lowest values in October and November. LH decreased rapidly at the end of summer and increased progressively from December to February, during hibernation. In these experiments, it was not possible to determine the characteristics of LH release patterns in the hedgehog but individual profiles indicated clearly the episodic secretion of LH, particularly during the highest pituitary activity period. During the year, a close relationship between the seasonal cycles of plasma LH and testosterone was observed.     

Effect of calorie restriction on the free-living physical activity levels of nonobese humans: results of three randomized trials

The objective of this study was to evaluate the influence of calorie restriction (CR) on free-living physical activity levels among humans. Data were from three CALERIE phase I site-specific protocols. Participants were nonobese (body mass index = 23.5-29.9 kg/m2 adults randomly assigned to 25% CR, low-calorie diet (LCD, 890 kcal/day supplement diet until 15% weight loss, then weight maintenance), or control at Pennington Biomedical Research Center (PBRC); 30% or 10% CR at Tufts University; and 20% CR or control at Washington University School of Medicine (WUSM). Activity was measured at months 0, 3, and 6 (PBRC) and at months 0, 3, 6, 9, and 12 (WUSM and Tufts). Total daily energy expenditure (TEE) by doubly labeled water and resting metabolic rate (RMR) were used to compute activity energy expenditure: AEE = TEE - RMR - 0.1 * TEE. Accelerometry and 7-day recall categorized activities by intensity. At Tufts, the 10% and 30% CR groups experienced significant decreases in AEE at months 6, 9, and 12. At month 6, a larger decrease in AEE was observed in the CR than the control group at WUSM. At months 3 and 6, larger decreases in AEE were observed in the CR and LCD groups than the control group at PBRC. Accelerometry and 7-day PAR did not consistently detect changes in activity categories. CR-associated changes in AEE were variable but, generally, reduced the energy deficit, which would reduce the expected rate of weight loss. Accelerometry and recall did not consistently explain reduced AEE, suggesting that increased muscle efficiency and/or decreased fidgeting accounted for decreased AEE. Inaccuracy of accelerometry and recall also likely negatively affected sensitivity.     

Circadian periods of sensitivity for ramelteon on the onset of running-wheel activity and the peak of suprachiasmatic nucleus neuronal firing rhythms in C3H/HeN mice

Ramelteon, an MT(1)/MT(2) melatonin receptor agonist, is used for the treatment of sleep-onset insomnia and circadian sleep disorders. Ramelteon phase shifts circadian rhythms in rodents and humans when given at the end of the subjective day; however, its efficacy at other circadian times is not known. Here, the authors determined in C3H/HeN mice the maximal circadian sensitivity for ramelteon in vivo on the onset of circadian running-wheel activity rhythms, and in vitro on the peak of circadian rhythm of neuronal firing in suprachiasmatic nucleus (SCN) brain slices. The phase response curve (PRC) for ramelteon (90?μg/mouse, subcutaneous [sc]) on circadian wheel-activity rhythms shows maximal sensitivity during the late mid to end of the subjective day, between CT8 and CT12 (phase advance), and late subjective night and early subjective day, between CT20 and CT2 (phase delay), using a 3-day-pulse treatment regimen in C3H/HeN mice. The PRC for ramelteon resembles that for melatonin in C3H/HeN mice, showing the same magnitude of maximal shifts at CT10 and CT2, except that the range of sensitivity for ramelteon (CT8-CT12) during the subjective day is broader. Furthermore, in SCN brain slices in vitro, ramelteon (10 pM) administered at CT10 phase advances (5.6?±?0.29?h, n?=?3) and at CT2 phase delays (-3.2?±?0.12?h, n?=?6) the peak of circadian rhythm of neuronal firing, with the shifts being significantly larger than those induced by melatonin (10 pM) at the same circadian times (CT10: 2.7?±?0.15?h, n?=?4, p?相似文献   

Combined effect of epinephrine and chalone extracted from Ehrlich ascites carcinoma administered during different time of day on cell division in the tumor

The biphasic circadian rhythm of mitotic activity has been demonstrated in a 5-day Ehrlich's ascites carcinoma (EAC) in mice. Adrenaline injected intraperitoneally in a dose of 1.5 micrograms/g bw produced an inhibitory effect on cell division that lasted over 4 hours and reached maximum at injection to mice during light time of the day. EAC extract in a dose of 1 ml also inhibited the mitosis during 4 hours, but the greatest fall in the mitotic activity was observed during the minimum mitotic activity in the control animals. Combined administration of adrenaline and the extract resulted in the phenomenon of prolonged inhibition of cell division, that persisted for maximum 6-8 hours, if the preparations were injected in the middle of the day light time. Of definite importance was the rhythm of changes in the sensitivity of proliferating tumor cells.     

Influence of the seasons on the circadian rhythm of blood glucose and tissue glycogen in male Wistar rats

Adult, ad libitum fed male Wistar rats were adapted for three weeks to standard laboratory conditions and a 12:12 h light:dark regimen (7 a.m. to 7 p.m., 7 p.m. to 7 a.m.). In January, in April, in July and in October they were decapitated at 3-hour intervals and the glucose level was determined in their blood and the glycogen concentration in their liver, skeletal muscle, heart and white and brown adipose tissue. The influence of the seasons on circadian variation of the given parameters was not the same in all the tissues. Circadian variation of the liver and heart glycogen concentration was the least affected. The liver glycogen curves attained the maximum at the beginning of the light part of the day in all the seasons except the autumn; the rhythm was present everywhere. The rhythm was not demonstrated in the heart in the winter only and except for the summer the curves attained the maximum at the end of the dark part of the day. Pronounced seasonal changes were observed in the blood glucose and skeletal muscle glycogen concentration, whose curves reached the maximum in various parts of the day and where the rhythm was absent in the autumn - and in the case of skeletal muscle in the summer as well. The glycogen concentration in the two adipose tissues displayed the greatest seasonal changes. The shape of the circadian oscillation curves and their maxima in the various seasons were very different, with absence of the rhythm in the autumn. Determination of the influence of the photoperiodic reactions and of changes in hormones and the key enzymes regulating the main metabolic routes might help to explain the basis of circaannual variations in the metabolism of the laboratory rat.     

Descriptive phenology and seasonality of a Canadian brown-water stream

A phenological-type synthesis was attempted for 10 years of limnological data of a brown-water stream of Alberta, Canada. The objectives were to predict the normal occurrence of seasonal events in the stream and to formulate indices upon which to base general stream management strategies. The stream supports a diverse chironomid fauna (109 species); and four taxa, chironomids, ostracods and the ephemeropteransLeptophlebia cupida andBaetis tricaudatus, account for 61% of the total yearly fauna by numbers. There are two obvious major seasons: a 7 month ice-free season (ca 15 April–15 November) and a 5 month winter season. Based on numerical classification of physical and chemical parameters, the ice-free season is separated into spring (April and May), summer (June, July and August) and autumn (September and October) seasons; and these four seasons can serve as the basis for describing biological seasonality. There are few detectable periodic events during the long, 5-month winter season: flow and water temperature are relatively constant and at minimum values. There are no reproductive periods for species studied; no new generations appear; drift densities are at minimum values; and for most taxa, little growth takes place in winter. Some of the important phenological events of the three ice-free seasons include: (1) a total emergence, hence reproductive, period of 6 months (April–September) for aquatic insects studied, with the largest number of taxa reproducing in late June and early July; (2) a 31/2 month period (late April–early August) when water temperatures are on the rise (log phase of total degree days curve), with maximum rate increase in May, maximum rate decrease in October, and maximum water temperature values in early August; (3) a completely green (trees and marsh grasses) watershed of less than 2 months (late June–early August); (4) a leaf-drop period of 11/2 months (September–mid October), with maximum litter-fall rate in early September; (5) maximum discharge in April; (6) minimum standing crop by numbers in April and maximum numbers in September; (7) maximum daily drift and drift densities (all taxa) in August; (8) maximum impounding effect of beaver dams in September; (9) maximum aquatic macrophyte standing crop in September; and (10) maximum ‘potential’ food resources (detritus of aquatic macrophyte and terrestrial leaf origin) in mid October.