Disrupted seasonal biology impacts health, food security and ecosystems.

The rhythm of life on earth is shaped by seasonal changes in the environment. Plants and animals show profound annual cycles in physiology, health, morphology, behaviour and demography in response to environmental cues. Seasonal biology impacts ecosystems and agriculture, with consequences for humans and biodiversity. Human populations show robust annual rhythms in health and well-being, and the birth month can have lasting effects that persist throughout life. This review emphasizes the need for a better understanding of seasonal biology against the backdrop of its rapidly progressing disruption through climate change, human lifestyles and other anthropogenic impact. Climate change is modifying annual rhythms to which numerous organisms have adapted, with potential consequences for industries relating to health, ecosystems and food security. Disconcertingly, human lifestyles under artificial conditions of eternal summer provide the most extreme example for disconnect from natural seasons, making humans vulnerable to increased morbidity and mortality. In this review, we introduce scenarios of seasonal disruption, highlight key aspects of seasonal biology and summarize from biomedical, anthropological, veterinary, agricultural and environmental perspectives the recent evidence for seasonal desynchronization between environmental factors and internal rhythms. Because annual rhythms are pervasive across biological systems, they provide a common framework for trans-disciplinary research.

Mechanical properties of brain tubulin and microtubules.

We measured the elasticity and viscosity of brain tubulin solutions under various conditions with a cone and plate rheometer using both oscillatory and steady shearing modes. Microtubules composed of purified tubulin, purified tubulin with taxol and 3x cycled microtubule protein from pig, cow, and chicken behaved as mechanically indistinguishable viscoelastic materials. Microtubules composed of pure tubulin and heat stable microtubule-associated proteins were also similar but did not recover their mechanical properties after shearing like other samples, even after 60 min. All of the other microtubule samples were more rigid after flow orientation, suggesting that the mechanical properties of anisotropic arrays of microtubules may be substantially greater than those of randomly arranged microtubules. These experiments confirm that MAPs do not cross link microtubules. Surprisingly, under conditions where microtubule assembly is strongly inhibited (either 5 degrees or at 37 degrees C with colchicine or Ca++) tubulin was mechanically indistinguishable from microtubules at 10-20 microM concentration. By electron microscopy and ultracentrifugation these samples were devoid of microtubules or other obvious structures. However, these mechanical data are strong evidence that tubulin will spontaneously assemble into alternate structures (aggregates) in nonpolymerizing conditions. Because unpolymerized tubulin is found in significant quantities in the cytoplasm, it may contribute significantly to the viscoelastic properties of cytoplasm, especially at low deformation rates.

Suprachiasmatic nucleus: use of 14C-labeled deoxyglucose uptake as a functional marker.

Glucose consumption of the rat suprachiasmatic nuclei (SCN) was studied under various experimental conditions by means of the [14C]deoxyglucose (DG) technique. The results show that glucose consumption of the SCN, in contrast to other brain structures, is a function of both the time of day and environmental lighting conditions. These data are consistent with the hypothesis that the SCN have an essential role in circadian rhythm regulation and indicate that the DG technique may provide a novel approach for the study of the central neural mechanisms underlying circadian rhythm regulation.

Rationing health care: the choice before us.

Rapid technological advances and upward pressure on wages of hospital personnel are leading to a steady increase in health care spending that is absorbing an ever-larger fraction of gross national product. Eliminating inefficiencies in the system can provide brief fiscal relief, but rationing of beneficial services, even to the well-insured, offers the only prospect for sustained reduction in the growth of health care spending. The United States, which has negligible direct experience with rationing, can learn about choices it will face from the experience of Great Britain where health care has been rationed explicitly for many years.

Maternal coordination of the fetal biological clock in utero.

Deoxyglucose labeled with carbon-14 was used in studying the utilization of glucose in the suprachiasmatic nuclei of fetal rats. The results showed that an entrainable circadian clock is present in the suprachiasmatic nuclei during fetal development and that the maternal circadian system coordinates the phase of the fetal clock to environmental lighting conditions.

Vasopressin mRNA in the suprachiasmatic nuclei: daily regulation of polyadenylate tail length.

Daily variation has been found in the length of the polyadenylate tail attached to vasopressin messenger RNA in the suprachiasmatic nuclei, which is the location of an endogenous circadian pacemaker in mammals. No such variation was found in the supraoptic or paraventricular nuclei. This variation in the length of the polyadenylate tail may underlie the circadian rhythm of vasopressin peptide levels in cerebrospinal fluid and is a unique example of a daily rhythm in messenger RNA structure.

Antiphase oscillation of the left and right suprachiasmatic nuclei.

An unusual property of the circadian timekeeping systems of animals is rhythm "splitting," in which a single daily period of physical activity (usually measured as wheel running) dissociates into two stably coupled components about 12 hours apart; this behavior has been ascribed to a clock composed of two circadian oscillators cycling in antiphase. We analyzed gene expression in the hypothalamic circadian clock, the suprachiasmatic nucleus (SCN), of behaviorally "split" hamsters housed in constant light. The results show that the two oscillators underlying the split condition correspond to the left and right sides of the bilaterally paired SCN.

Metabolic mapping of functional activity in the hypothalamo-neurohypophysial system of the rat.

Physiological stimulation of the hypothalamo-neurohypophysial system by salt loading of rats resulted in a dramatically increased glucose utilization in the posterior pituitary but not in the paraventricular or supraoptic nuclei. The good correlation between glucose utilization and neural activity in the posterior pituitary (that is, nerve terminals) contrasted with the lack of correlation in the paraventricular and supraoptic nuclei (that is, the sites of the cell bodies of the same neurons). This difference in the metabolic response to functional activity between the two regions of these neurons can be explained by the differences in surface-to-volume ratios of these regions.

Metabolite of (-)-trans-delta 8-tetrahydrocannabinol: identification and synthesis.

The major metabolite of (-)-trans-Delta(8)-tetrahydrocannabinol observed in vivo and formed by hepatic microsomes in vitro is 11-hydroxy-trans-Delta(8)-tetrahydrocannabinol. The metabolite was identified spectroscopically and was synthesized from trans-Delta(8)-tetrahydrocannabinol. In tests with rats, the metabolite produced behavioral effects similar to those imparted by Delta(8)- and Delta(9)-tetrahydrocannabinol.

A MEMS-based high frequency x-ray chopper.

Time-resolved x-ray experiments require intensity modulation at high frequencies (advanced rotating choppers have nowadays reached the kHz range). We here demonstrate that a silicon microlever oscillating at 13 kHz with nanometric amplitude can be used as a high frequency x-ray chopper. We claim that using micro-and nanoelectromechanical systems (MEMS and NEMS), it will be possible to achieve higher frequencies in excess of hundreds of megahertz. Working at such a frequency can open a wealth of possibilities in chemistry, biology and physics time-resolved experiments.

[Cloning and characterization of a large metagenomic DNA fragment containing glycosyl-hydrolase genes].

The problem of search for and characterization of enzymes synthesized by non-cultivated microorganisms is presently being settled by creating metagenomic libraries. A 6000-clone library with the average size of its inserts amounting to 15 bp has been constructed on the basis of total DNA isolated from cow rumen microorganisms. As the result of the screening of the library on plates with different substrates, a clone was selected that efficiently hydrolyzed lichenan and carboxymethylcellulose. The clone contained the recombinant plasmid pBlue-13 bearing a 12071 bp.-long metagenomic fragment carrying ten open reading frames, two of them being identified as glycosyl hydrolase genes. No homology of the metagenomic DNA with any known microorganism genomes was revealed. The amino acid sequence, deduced on the basis of frame 4 and denoted by Xyl3A, bears resemblance with beta-xylosidases of glycosyl hydrolase Family 3. Frame 6 encodes polypeptide Cel5A homologous to cellulases of glycosyl hydrolase Family 5. The amino acid sequences deduced on the basis of seven out of ten open reading frames were homologous to proteins of microorganisms belonging to the Bacteroides sp. family, the bacteria inhabiting mammalian intestines.

Compositional changes of AP-1 DNA-binding proteins are regulated by light in a mammalian circadian clock.

Recent reports have shown that the nuclear phosphoprotein Fos is induced by light in a mammalian circadian clock, the suprachiasmatic nucleus. To learn how light and circadian phase affect the binding of Fos to DNA, we analyzed the photic and temporal regulation of immunoreactive Jun protein expression and AP-1 DNA-binding activity in the rat suprachiasmatic nucleus. Immunohistochemistry and gel mobility shift assays suggest that AP-1 activity during the night and after a light pulse consists of constant, as well as variable, protein components; JunD could be identified as a constituent of both dark- and light-activated binding complexes, whereas binding by JunB and Fos could be implicated only after photic stimulation. Since JunD or JunB could be colocalized with Fos in individual suprachiasmatic nucleus cell nuclei, light may be acting in at least some suprachiasmatic nucleus cells by altering AP-1 protein composition rather than binding site occupancy.

Morning and evening circadian oscillations in the suprachiasmatic nucleus in vitro.

Daily biological rhythms are governed by an innate timekeeping mechanism, or 'circadian clock'. In mammals, a clock in the suprachiasmatic nucleus (SCN) comprises multiple autonomous single-cell oscillators, but it is unclear how SCN cells interact to form a tissue with coherent metabolic and electrical rhythms that might account for circadian animal behaviors. Here we demonstrate that the circadian rhythm of SCN electrophysiological activity, recorded as a single daytime peak in hamster hypothalamic coronal slices, shows two distinct peaks when slices are cut in the horizontal plane. Substantiating an idea initially derived from behavioral observations, the properties of these two peaks indicate functional organization of SCN tissue as a clock with two oscillating components.

The effects of chronic hypoxemia on electrolyte and acid-base equilibrium: an examination of normocapneic hypoxemia and of the influence of hypoxemia on the adaptation to chronic hypercapnia.

We have carried out balance studies in normal dogs in order to appraise the effects of chronic hypoxemia on acid-base and electrolyte equilibrium. During the first phase of observation we produced a state of "pure" hypoxemia by reducing the oxygen concentration (utilizing nitrogen as a diluent) and by adding carbon dioxide to the environment in a concentration sufficient to keep arterial CO(2) tension (PCO(2)) within normal limits. The data demonstrate that such a 9-day period of normocapneic hypoxemia has no effect on electrolyte excretion and is virtually without effect on plasma composition. During the second phase of observation we subjected the hypoxemic dogs to stepwise increments in arterial carbon dioxide tension in order to evaluate the effects of the low oxygen tension on the acid-base adjustments to a chronic state of hypercapnia. At least 6 days was allowed for extracellular composition to reach a new steady state at each level of inspired carbon dioxide. The data demonstrate a rise in both plasma bicarbonate concentration and renal acid excretion that was not significantly different from that which has been described previously for hypercapnia without hypoxemia. Just as in these earlier studies, plasma hydrogen ion concentration rose with each increment in carbon dioxide tension, each millimeter Hg increment in PCO(2) leading to an increase in hydrogen ion concentration of 0.32 nmole per L. It thus appears that the chronic"carbon dioxide response curve" is not significantly influenced by moderately severe hypoxemia.

The maladaptive renal response to secondary hypocapnia during chronic HCl acidosis in the dog.

It has generally been thought that homeostatic mechanisms of renal origin are responsible for minimizing the alkalemia produced by chronic hypocapnia. Recent observations from this laboratory have demonstrated, however, that the decrement in [HCO(-) (3)], which "protects" extracellular pH in normal dogs, is simply the by-product of a nonspecific effect of Paco(2) on renal hydrogen ion secretion; chronic primary hypocapnia produces virtually the same decrement in plasma [HCO(-) (3)] in dogs with chronic HCl acidosis as in normal dogs (Delta[HCO(-) (3)]/DeltaPaco(2) = 0.5), with the result that plasma [H(+)] in animals with severe acidosis rises rather than falls during superimposed forced hyperventilation. This observation raised the possibility that the secondary hypocapnia which normally accompanies metabolic acidosis, if persistent, might induce an analogous renal response and thereby contribute to the steady-state decrement in plasma [HCO(-) (3)] observed during HCl feeding. We reasoned that if sustained secondary hypocapnia provoked the kidney to depress renal bicarbonate reabsorption, the acute salutary effect of hypocapnia on plasma acidity might be seriously undermined. To isolate the possible effects of secondary hypocapnia from those of the hydrogen ion load, per se, animals were maintained in an atmosphere of 2.6% CO(2) during an initial 8-day period of acid feeding (7 mmol/kg per day); this maneuver allowed Paco(2) to be held constant at the control level of 36 mm Hg despite the hyperventilation induced by the acidemia. Steady-state bicarbonate concentration during the period of eucapnia fell from 20.8 to 16.0 meq/liter, while [H(+)] rose from 42 to 55 neq/liter. During the second phase of the study, acid feeding was continued but CO(2) was removed from the inspired air, permitting Paco(2) to fall by 6 mm Hg. In response to this secondary hypocapnia, bicarbonate concentration fell by an additional 3.0 meq/liter to a new steady-state level of 13.0 meq/liter. This reduction in bicarbonate was of sufficient magnitude to more than offset the acute salutary effect of the hypocapnia on plasma hydrogen ion concentration; in fact, steady-state [H(+)] rose as a function of the adaptive fall in Paco(2), Delta[H(+)]/Delta Paco(2) = -0.44. That the fall in bicarbonate observed in response to chronic secondary hypocapnia was the result of the change in Paco(2) was confirmed by the observation that plasma bicarbonate returned to its eucapnic level in a subgroup of animals re-exposed to 2.6% CO(2). These data indicate that the decrement in plasma [HCO(-) (3)] seen in chronic HCl acidosis is a composite function of (a) the acid load itself and (b) the renal response to the associated hyperventilation. We conclude that this renal response is maladaptive because it clearly diminishes the degree to which plasma acidity is protected by secondary hypocapnia acutely. Moreover, under some circumstances, this maladaptation actually results in more severe acidemia than would occur in the complete absence of secondary hypocapnia.

The influence of graded degrees of chronic hypercapnia on the acute carbon dioxide titration curve.

Studies were carried out to determine the influence of the chronic level of arterial carbon dioxide tension upon the buffering response to acute changes in arterial carbon dioxide tension. After chronic adaptation to six levels of arterial CO(2) tension, ranging between 35 and 110 mm Hg, unanesthetized dogs underwent acute whole body CO(2) titrations. In each instance a linear relationship was observed between the plasma hydrogen ion concentration and the arterial carbon dioxide tension. Because of this linear relationship, it has been convenient to compare the acute buffering responses among dogs in terms of the slope, dH(+)/dPaco(2). With increasing chronic hypercapnia there was a decrease in this slope, i.e. an improvement in buffer capacity, which is expressed by the equation dH(+)/dPaco(2)=-0.005 (Paco(2))(chronic) + 0.95. In effect, the ability to defend pH during acute titration virtually doubled as chronic Paco(2) increased from 35 to 110 mm Hg. The change in slope, dH(+)/dPaco(2), was the consequence of the following two factors: the rise in plasma bicarbonate concentration which occurs with chronic hypercapnia of increasing severity, and the greater change in bicarbonate concentration which occurred during the acute CO(2) titration in the animals with more severe chronic hypercapnia. These findings demonstrate the importance of the acid-base status before acute titration in determining the character of the carbon dioxide titration curve. They also suggest that a quantitative definition of the interplay between acute and chronic hypercapnia in man should assist in the rational analysis of acid-base disorders in chronic pulmonary insufficiency.

The nature of the renal adaptation to chronic hypocapnia.

Metabolic balance studies were carried out in normal dogs to define the renal mechanisms responsible for the adaptation to, and recovery from, chronic hypocapnia. A chronic reduction in arterial CO(2) tension (Pa(CO2)) of some 15 mm Hg was achieved by means of chronic exposure of the animals to 9% oxygen in an environmental chamber. The development of hypocapnia was associated with a marked suppression of net acid excretion which, together with a slight accumulation of organic acids, produced a reduction in plasma bicarbonate concentration (8 mEq/liter) that led to nearly full protection of extracellular pH (DeltaH(+) = - 2.5 nmoles/liter). When Pa(CO2) was returned to control levels, an augmentation of acid excretion restored plasma composition to normal after a brief period of "posthypocapneic metabolic acidosis."The changes in renal acid excretion during both adaptation and recovery were accomplished in a fashion notably different from that previously observed in chronic hypercapnia, being linked to changes in cation rather than chloride excretion. Thus, in dogs ingesting a normal NaCl diet, suppression of hydrogen ion excretion during adaptation to hypocapnia was associated with an increased excretion of sodium rather than with a retention of chloride. The fact that this loss of sodium occurred without a concomitant loss of potassium strongly suggests that the hypocapneic state specifically depressed distal sodium reabsorption; if distal sodium reabsorption had not been depressed, a reduction in proximal sodium reabsorption or a diminution in distal hydrogen ion secretion (or both) should have produced an increase in potassium excretion. The interpretation that chronic hypocapnia diminished sodium reabsorption was supported by the finding that when renal sodium avidity was enhanced by restriction of sodium intake, acid retention was accomplished by a loss of potassium rather than of sodium. The accompanying reduction in plasma bicarbonate concentration was slightly less than that observed in dogs ingesting a normal NaCl diet, a finding probably accounted for by a slight difference in the availability of cation for excretion under the two experimental circumstances. These findings, taken together with the observation that augmented acid excretion during recovery from hypocapnia is linked to cation retention, suggest that an adequate intake of cation during both adaptation and recovery from chronic hypocapnia may be critical to the physiologic regulation of acid-base equilibrium.

Aldosterone in metabolic alkalosis.

Studies have been carried out in human volunteer subjects to evaluate the role of aldosterone in the development, maintenance, and correction of metabolic alkalosis induced by selective depletion of hydrochloric acid. During the first phase of our study the rate of aldosterone secretion was measured before the induction of alkalosis (while the subjects were on a low salt diet) and again after a steady state of metabolic alkalosis had been established. The data demonstrate a fall in aldosterone secretion from a value of approximately 500 mug/day to a value of approximately 200 mug/day. Thus, it appears that an increased rate of aldosterone secretion is not a prerequisite to the elevation of the renal bicarbonate threshold. During the second phase of our study, aldosterone was administered to the alkalotic subjects in doses of 1000 mug/day (or deoxycorticosterone acetate in doses of 40 mg/day) in order to determine the effects of a persistent steroid excess on the ability of sodium chloride to correct the acid-base disturbance. The data demonstrate that despite the administration of steroid, the ingestion of sodium chloride led to a reduction in plasma bicarbonate concentration from 39 to 29 mEq/liter, accompanied by a suppression of renal acid excretion. This reduction in plasma bicarbonate concentration occurred without a concomitant retention of potassium, a deficit of as much as 400-500 mEq of potassium persisting during repair of the acid-base disturbance. Our findings suggest that "saline-resistant" alkalosis, when it occurs in the absence of primary hyperadrenalism, cannot be attributed to aldosterone excess and/or potassium depletion of the magnitude seen in our study. We also suggest the need for a reappraisal of the way in which aldosterone excess contributes to the genesis and maintenance of alkalosis in primary aldosteronism.

Regulation of acid-base equilibrium in chronic hypocapnia. Evidence that the response of the kidney is not geared to the defense of extracellular (H+).

It is generally believed that the reduction in plasma [HCO3] characteristic of chronic hypocapnia results from renal homeostatic mechanisms designed to minimize the alkalemia produced by.the hypocapneic state. To test this hypothesis, we have induced chronic hypocapnia in dogs in which plasma [HCO3] had previously been markedly reduced (from 21 to 15 meq/liter) by the prolonged feeding of HCl. The PaCO2 of chronically acid-fed animals was reduced from 32 to 15 mm Hg by placing the animials in a large environmental chamber containing 9% oxygen. In response to this reduction in PaCO2, mean plasma [HCO3] fell by 8.6 meq/liter, reaching a new steady-state level of 6.4 meq/liter. This decrement in plasma [HCO3] is almost identical to the 8.1 meq/liter decrement previously observed in normal (nonacid-fed) animals in which the same degree of chronic hypocapnia had been induced. Thus, in both normal and HCl-fed animals, the renal response to chronic hypocapnia causes plasma [HCO3] to fall by approximately 0.5 meq/liter for each millimeter of Hg reduction in CO2 tension. By contrast, the response of plasma [H+] in the two groups was markedly different. Instead of the fall in [H+] which is seen during chronic hypocapnia in normal animals, [H+] in HCl-fed animals rose significantly from 53 to 59 neq/liter (pH 7.28-7.23). This seemingly paradoxical response is, of course, an expression of the constraints imposed by the Henderson equation and reflects the fact that the percent fall in [HCO3] in the HCl-fed animals was greater than the percent fall in PaCO2. These findings clearly indicate that in chronic hypocapnia the kidney cannot be regarded as the effector limb in a homeostatic feedback system geared to the defense of systemic acidity.

The effect of chronic hypotonic volume expansion on the renal regulation of acid-base equilibrium.

Balance studies have been carried out to evaluate the influence of vasopressin-induced volume expansion on acid-base equilibrium in normal dogs and in dogs with steady-state metabolic acidosis induced by the administration of 5-7 mmoles/kg per day of hydrochloric acid.Hypotonic expansion in dogs with metabolic acidosis (mean plasma bicarbonate concentration 14 mEq/liter) produced a marked increase in renal acid excretion that restored plasma bicarbonate concentration to normal (20-21 mEq/liter) despite continued ingestion of acid. When water was restricted during the vasopressin period, and fluid retention thus prevented, no increase in acid excretion or plasma bicarbonate concentration occurred. From these findings we conclude that hypotonic expansion is a potent stimulus to renal hydrogen ion secretion and greatly facilitates the renal removal of an acid load. Normal dogs subjected to expansion demonstrated no change in net acid excretion or in plasma bicarbonate concentration even in the face of a marked diuresis of sodium and chloride and a reduction in plasma sodium concentration to approximately 110 mEq/liter. The animals did, however, regularly lose potassium, a finding that clearly indicates an acceleration of distal sodiumcation exchange. On the basis of these observations, and the findings in the expanded acidotic dogs, we suggest that in the expanded normal dogs acceleration of sodium-hydrogen exchange was responsible for preventing a bicarbonate diuresis and for stabilizing plasma bicarbonate concentration. These studies clearly demonstrate that chronic hypotonic expansion exerts a major influence on the renal regulation of acid-base equilibrium. The exact nature of the mechanism responsible for the increase in sodium-hydrogen exchange during hypotonic expansion remains to be determined.