Independence of genetic geographical variation between photoperiodic diapause, circadian eclosion rhythm, and Thr-Gly repeat region of the period gene in Drosophila littoralis

Drosophila littoralis is a latitudinally widespread European species of the Drosophila virilis group. The species has ample genetic variation in photoperiodism (adult diapause) and circadian rhythmicity (pupal eclosion rhythm), with adaptive latitudinal clines in both of them. The possible common genetic basis between the variability of photoperiodism and circadian rhythms was studied by a long-term crossing experiment. A northern strain (65 degrees N) having long critical day length (CDL = 19.9 h) for diapause, early phase of the entrained rhythm in LD 3:21 (psi(LD3:21) = 12.3 h), and short period (tau= 18.8 h) of the free-running rhythm for the eclosion rhythm was crossed with a southern strain (42 degrees N) having short CDL (12.4 h), late eclosion phase (psi(LD3:21) = 20.2 h), and long period (tau= 22.8 h). After 54 generations, including free recombination, artificial selection, and genetic drift, a novel strain resulted, having even more "southern" diapause and more "northern" eclosion rhythm characteristics than found in any of the geographical strains. The observed complete separation of eclosion rhythm characteristics from photoperiodism is a new finding in D. littoralis; in earlier studies followed for 16 generations, the changes had been mostly parallel. Evidently, the genes controlling the variability of the eclosion rhythm and photoperiodism in D. littoralis are different but closely linked. To test for the possible gene loci underlying the observed geographical variability, the period gene was studied in 10 strains covering all the known clock variability in D. littoralis. The authors sequenced the most suspected Thr-Gly region, which is known to take part in the adaptive clock variability in Drosophila melanogaster. No coding differences were found in the strains, showing that this region is not included in the adaptive clock variability in D. littoralis.     

Genetic dissection of the Drosophila circadian system

Genetic experiments involving selected strains as well as single gene mutations have provided information concerning the organization of the Drosophila circadian system. The phase of the emergence rhythm of D. pseudoobscura can be altered by genetic selection without significantly affecting the phase and period of the light-sensitive pacemaker. The period of the D. melanogaster pacemaker, over the range 19 hours to 29 hours, can be encoded in the DNA sequence of a single genetic locus. The short-period and long-period mutations do not eliminate the pacemaker's temperature compensation mechanism. The short-period mutation alters the resetting behavior of the pacemaker from weak (type 1) in wild-type to strong (type 0) in the mutant. Five aperiodic mutations isolated in D. pseudoobscura belong to two complementation groups. In complements bearing one mutation from each group, the periodicity of the pacemaker is wild-type, but the phase of the emergence rhythm is 5 hours later than wild-type. Thus mutations in particular genetic loci have dramatic effects on the basic properties of circadian pacemakers and rhythms.     

Real-time monitoring of chloroplast gene expression by a luciferase reporter: evidence for nuclear regulation of chloroplast circadian period

Chloroplast-encoded genes, like nucleus-encoded genes, exhibit circadian expression. How the circadian clock exerts its control over chloroplast gene expression, however, is poorly understood. To facilitate the study of chloroplast circadian gene expression, we developed a codon-optimized firefly luciferase gene for the chloroplast of Chlamydomonas reinhardtii as a real-time bioluminescence reporter and introduced it into the chloroplast genome. The bioluminescence of the reporter strain correlated well with the circadian expression pattern of the introduced gene and satisfied all three criteria for circadian rhythms. Moreover, the period of the rhythm was lengthened in per mutants, which are phototactic rhythm mutants carrying a long-period gene in their nuclear genome. These results demonstrate that chloroplast gene expression rhythm is a bona fide circadian rhythm and that the nucleus-encoded circadian oscillator determines the period length of the chloroplast rhythm. Our reporter strains can serve as a powerful tool not only for analysis of the circadian regulation mechanisms of chloroplast gene expression but also for a genetic approach to the molecular oscillator of the algal circadian clock.     

Independence of genetic variation between circadian rhythm and development time in the seed beetle, Callosobruchus chinensis

A positive genetic correlation between periods of circadian rhythm and developmental time supports the hypothesis that circadian clocks are implicated in the timing of development. Empirical evidence for this genetic correlation in insects has been documented in two fly species. In contrast, here we show that there is no evidence of genetic correlation between circadian rhythm and development time in the adzuki bean beetle, Callosobruchus chinensis. This species has variation that is explained by a major gene in the expression and period length of circadian rhythm between strains. In this study, we found genetic variation in development time between the strains. The development time was not covaried with either the incidence or the period length of circadian rhythm among the strains. Crosses between strains suggest that development time is controlled by a polygene. In the F₂ individuals from the crosses, the circadian rhythm is attributable to allelic variation in the major gene. Across the F₂ individuals, development time was not correlated with either the expression or the period length of circadian rhythm. Thus, we found no effects of major genes responsible for variation in the circadian rhythm on development time in C. chinensis. Our findings collectively give no support to the hypothesis that the circadian clock is involved in the regulation of development time in this species.     

Mutants with Altered Sensitivity to a Calmodulin Antagonist Affect the Circadian Clock in Neurospora Crassa

Two newly isolated mutant strains of Neurospora crassa, cpz-1 and cpz-2, were hypersensitive to chlorpromazine with respect to mycelial growth but responded differently to the drug with respect to the circadian conidiation rhythm. In the wild type, chlorpromazine caused shortening of the period length of the conidiation rhythm. Pulse treatment with the drug shifted the phase and inhibited light-induced phase shifting in Neurospora. By contrast to the wild type, the cpz-2 strain was resistant to these inhibitory effects of chlorpromazine. Inhibition of cpz-2 function by chlorpromazine affected three different parameters of circadian conidiation rhythm, namely, period length, phase and light-induced phase shifting. These results indicate that the cpz-2 gene must be involved in or related closely to the clock mechanism of Neurospora. By contrast, the cpz-1 strain was hypersensitive to chlorpromazine with respect to the circadian conidiation rhythm.     

Circadian Rhythms in Neurospora crassa: The Role of Mitochondria

Energy metabolism and mitochondria have been discussed with respect to their role in the circadian rhythm mechanism for some time. Numerous examples of inhibitors that affect the mitochondria of plants and animals and microorganisms are known, which cause large phase shifts in the rhythms of these organisms. Analogous studies on the role of mitochondria in the Neurospora circadian rhythm mechanism have also been reported and summarized. This communication differs from previous studies on other organisms in that it will focus on two lines of evidence derived from studies on Neurospora strains carrying mutations affecting the mitochondria, (a) Strains whose growth rate is resistant to oligomycin (oli^t) owing to an altered protein in the F₀ sector of the mitochondrial ATPase, showed no phase shifts when pulsed with oligomycin. Control strains (oli⁸) showed large phase shifts when pulsed with oligomycin. This indicates that the phase-shifting effect of oligomycin is due to the direct inhibition of the mitochondrial ATPase and not some side effect of this inhibitor, (b) In Neurospora, many different strains are known that carry mutations in the nuclear or mitochondrial genome that affect mitochondrially localized proteins. Some of these, such as oli', [MI-3], or cya-5, showed shorter (≥ 19-h) periods compared with the normal (21.5-h) period. Others showed little or no change in period. Those mutant strains exhibiting shorter periods also contained ≥60% more mitochondrial protein per gram total protein in extracts compared with the normal strains. Assays of the level of a mitochondrial-specific protein, acyl carrier protein, showed that the cellular content of this protein was approximately doubled. A parallel set of studies on the effects of antimycin or chloramphenicol on Neurospora demonstrated that these inhibitors also produced shorter periods as well as increased amounts of mitochondrial proteins. These two new lines of evidence may be interpreted to indicate that in Neurospora either some part of the oscillator is localized to the mitochondria and/or that mitochondria exert their effect on the clock mechanism through their effects on biosynthetic pathways or by their contribution in determining ion gradients.     

Cellular DBP and E4BP4 proteins are critical for determining the period length of the circadian oscillator

The phenotypes of mice carrying clock gene mutations have been critical to understanding the mammalian clock function. However, behavior does not necessarily reflect cell-autonomous clock phenotypes, because of the hierarchical dominance of the central clock. We performed cell-based siRNA knockdown and cDNA overexpression and monitored rhythm using bioluminescent reporters of clock genes. We found that knockdown of DBP, D-box positive regulator, in our model led to a short-period phenotype, whereas overexpressing of DBP produced a long-period rhythm when compared to controls. Furthermore, knockdown and overexpressing of E4BP4, D-box negative regulator, led to an opposite effect of DBP. Our experiments demonstrated that D-box regulators play a crucial role in determining the period length of Per1 and Per2 promoter-driven circadian rhythms in Rat-1 fibroblasts.     

A TEMPERATURE-COMPENSATED ULTRADIAN CLOCK OF TETRAHYMENA: OSCILLATIONS IN RESPIRATORY ACTIVITY AND CELL DIVISION

Both a circadian clock and an ultradian clock (period 4—5 h) have previously been described for the ciliated protozoon Tetrahymena. The present communication demonstrates the existence of yet another cellular clock: an ultradian rhythm with a period of about 30 min. The period was found to be well temperature-compensated over the range studied, i.e., between 19°C and 33°C. Ultradian rhythmicity was initiated by dilution of stationary-phase cultures, which were kept previously in a light-dark cycle, into fresh medium. LD treatment during stationary phase was an absolute requirement, since cultures kept in either LL or DD did not produce the ultradian rhythmicity after refeeding. The clock exerts control over respiration; the observed oscillation in oxygen uptake is just a hand of the clock: after a limitation of oxygen supply had ended, the rhythm resumed with the same phase and period as that in control cultures. The clock exerts temporal control also over cell division; in the refed culture cell division resumed with an oscillation in the number of dividing organisms. The period of this oscillation corresponded to that of the rhythm in respiratory activity, indicating that the same ultradian clock may exert control over different cellular functions. Analysis of a second Tetrahymena strain indicates that period length of the ultradian clock is a strain-specific characteristic.     

Molecular and behavioral analysis of four period mutants in Drosophila melanogaster encompassing extreme short,novel long,and unorthodox arrhythmic types.

Of the mutationally defined rhythm genes in Drosophila melanogaster, period (per) has been studied the most. We have molecularly characterized three older per mutants-perT, perClk, and per04-along with a novel long-period one (perSLIH). Each mutant is the result of a single nucleotide change. perT, perClk, and perSLIH are accounted for by amino acid substitutions; per04 is altered at a splice site acceptor and causes aberrant splicing. perSLIH exhibits a long period of 27 hr in constant darkness and entrains to light/dark (L/D) cycles with a later-than-normal evening peak of locomotion. perSLIH males are more rhythmic than females. perSLIH''s clock runs faster at higher temperatures and slower at lower ones, exhibiting a temperature-compensation defect opposite to that of perLong. The per-encoded protein (PER) in the perT mutant cycles in L/D with an earlier-than-normal peak; this peak in perSLIH is later than normal, and there was a slight difference in the PER timecourse of males vs. females. PER in per04 was undetectable. Two of these mutations, perSLIH and perClk, lie within regions of PER that have not been studied previously and may define important functional domains of this clock protein.     

Isolation and Genetic Analysis of Mutant Strains of CHLAMYDOMONAS REINHARDI Defective in Gametic Differentiation

Impotent mutant strains of Chlamydomonas reinhardi, mating-type (mt) plus, are described that have normal growth and motility but fail to differentiate into normal gametes. Procedures for their isolation and their genetic analysis are described. Five of the imp strains (imp-2, imp-5, imp-l, imp-7, and imp-8) exhibit no flagellar agglutination when mixed with mt- or mt+ gametes and the mutations are shown to be unlinked to the mt locus (with the possible exception of imp-7). Two of the strains (imp-3 and imp-4) carry leaky mutations that affect cell fusion; neither mutation is found by tetrad analysis to be linked to mt or to the other. Cells of the imp-1 strain agglutinate well with mt- gametes and active agglutination continues for up to 48 hours, but cell fusion occurs only very rarely. Analysis of these rare zygotes indicates that imp-1 is closely linked to the mt+ locus, and fine-structural studies reveal that imp-1 gametes produce a mutant mating structure involved in zygotic cell fusion. The development of sexuality in C. reinhardi therefore appears amenable to genetic dissection.     

Circadian Rhythms in Neurospora crassa: The Role of Mitochondria

Energy metabolism and mitochondria have been discussed with respect to their role in the circadian rhythm mechanism for some time. Numerous examples of inhibitors that affect the mitochondria of plants and animals and microorganisms are known, which cause large phase shifts in the rhythms of these organisms. Analogous studies on the role of mitochondria in the Neurospora circadian rhythm mechanism have also been reported and summarized. This communication differs from previous studies on other organisms in that it will focus on two lines of evidence derived from studies on Neurospora strains carrying mutations affecting the mitochondria, (a) Strains whose growth rate is resistant to oligomycin (oli^t) owing to an altered protein in the F₀ sector of the mitochondrial ATPase, showed no phase shifts when pulsed with oligomycin. Control strains (oli⁸) showed large phase shifts when pulsed with oligomycin. This indicates that the phase-shifting effect of oligomycin is due to the direct inhibition of the mitochondrial ATPase and not some side effect of this inhibitor, (b) In Neurospora, many different strains are known that carry mutations in the nuclear or mitochondrial genome that affect mitochondrially localized proteins. Some of these, such as oli', [MI-3], or cya-5, showed shorter (≥ 19-h) periods compared with the normal (21.5-h) period. Others showed little or no change in period. Those mutant strains exhibiting shorter periods also contained ≥60% more mitochondrial protein per gram total protein in extracts compared with the normal strains. Assays of the level of a mitochondrial-specific protein, acyl carrier protein, showed that the cellular content of this protein was approximately doubled. A parallel set of studies on the effects of antimycin or chloramphenicol on Neurospora demonstrated that these inhibitors also produced shorter periods as well as increased amounts of mitochondrial proteins. These two new lines of evidence may be interpreted to indicate that in Neurospora either some part of the oscillator is localized to the mitochondria and/or that mitochondria exert their effect on the clock mechanism through their effects on biosynthetic pathways or by their contribution in determining ion gradients.     

Epistatic and synergistic interactions between circadian clock mutations in Neurospora crassa

We identified a series of epistatic and synergistic interactions among the circadian clock mutations of Neurospora crassa that indicate possible physical interactions among the various clock components encoded by these genes. The period-6 (prd-6) mutation, a short-period temperature-sensitive clock mutation, is epistatic to both the prd-2 and prd-3 mutations. The prd-2 and prd-3 long-period mutations show a synergistic interaction in that the period length of the double mutant strain is considerably longer than predicted. In addition, the prd-2 prd-3 double mutant strain also exhibits overcompensation to changes in ambient temperature, suggesting a role in the temperature compensation machinery of the clock. The prd-2, prd-3, and prd-6 mutations also show significant interactions with the frq(7) long-period mutation. These results suggest that the gene products of prd-2, prd-3, and prd-6 play an important role in both the timing and temperature compensation mechanisms of the circadian clock and may interact with the FRQ protein.     

Correlation between circadian periods and cellular activities in Paramecium bursaria

Paramecium bursaria shows a circadian rhythm of photoaccumulation: photoaccumulation is stronger during the day than at night. We obtained five strains of P. bursaria having different circadian periods under continuous light conditions, ranging from 20.9 to 27.9 h. Various physiological activities were compared in the cells of these strains. The periods of contractile vacuole contraction were in the range 10–15 s, which was almost proportional to the periods of the circadian rhythm in each strain. Swimming velocities were inversely proportional to the circadian period; i.e. swimming velocities were high in strains whose circadian periods were short. Resting membrane potential was more depolarized in strains with longer circadian periods. Finally, the membrane resistance of the resting state was reduced in proportion to the increase of the circadian period. Such correlation between the cellular properties and the circadian period suggests that the circadian clock mechanism is associated with various physiological activities of the cell.     

Resetting of the circadian clock by phytochromes and cryptochromes in Arabidopsis.

The authors sought to investigate the role of phytochromes A and B (phyA and phyB) and cryptochromes 1 and 2 (cryl and cry2) in the synchronization of the leaf position rhythm in Arabidopsis thaliana. The seedlings were transferred from white light-dark cycles to free-running conditions with or without exposure to a light treatment during the final hours of the last dark period. The phase advance caused by a far-red light treatment was absent in the phyA mutant, deficient in the fhy1 and fhy3 mutants involved in phyA signaling, and normal in the cryl and cryl cry2 mutants. The phase shift caused by blue light was normal in the cry2 mutant; reduced in the phyA, cryl, phyA cry1, and cry1 cry2 mutants; and abolished in the phyA cryl cry2 triple mutant. The phase shift caused by red light was partially retained by the phyA phyB double mutant. The authors conclude that cryl and cry2 participate as photoreceptors in the blue light input to the clock but are not required for the phyA-mediated effects on the phase of the circadian rhythm of leaf position. The signaling proteins FHY1 and FHY3 are shared by phyA-mediated photomorphogenesis and phyA input to the clock.     

Circadian clocks and adaptation in Arabidopsis

Endogenous circadian rhythms are almost ubiquitous among organisms from cyanobacteria to mammals and regulate diverse physiological processes. It has been suggested that having an endogenous circadian system enables an organism to anticipate periodic environmental changes and adapt its physiological and developmental states accordingly, thus conferring a fitness advantage. However, it is hard to measure fitness directly and there is, to date, only limited evidence supporting the assumption that having a circadian system can increase fitness and therefore be adaptive. In this article, we report an evolutionary approach to examine the adaptive significance of a circadian system. By crossing Arabidopsis thaliana plants containing mutations that cause changes in circadian rhythms, we have created heterozygous 'Mother' (F1) plants with genetic variance for circadian rhythmicity. The segregating F2 offspring present a range of circadian rhythm periods. We have applied a selection to the F2 plants of short and long T-cycles under different competition strengths and found that the average phenotype of circadian period of the resulting F3 plants show a strong positive correlation with the T-cycle growth conditions for the competing F2 plants. Consistent with their circadian phenotypes, the frequency of long-period alleles was altered in the F3 plants. Our results show that F2 plants with endogenous rhythms that more closely match the environmental T-cycle are fitter, producing relatively more viable offspring in the F3 population. Thus, having a circadian clock that matches with the environment is adaptive in Arabidopsis.     

Circadian Rhythms in NEUROSPORA CRASSA: Interactions between Clock Mutations

Mutations at four loci in Neurospora crassa that alter the period of the circadian rhythm have been used to construct a series of double mutant strains in order to detect interactions between these mutations. Strains carrying mutations at three of these loci have altered periods on minimal media: prd-1, several alleles at the olir (oligomycin resistance) locus and four alleles at the frq locus. A mutation at the fourth locus, cel, which results in a defect in fatty acid synthesis, also leads to lengthening of the period when the medium is supplemented with linoleic acid (18:2). The cel mutation was crossed into strains carrying the frq, prd-1 and olir mutations, and the periods of the double mutant strains with and without 18:2 supplementation were determined. In addition, data from the literature for other combinations of loci and/or chemical effects on the period have been reanalyzed.--It was found that both prd-1 and olir are epistatic to the effects of 18:2 on cel; in the series of cel frq double mutant strains, the period-lengthening effect of 18:2 is inversely proportional to the period of the frq parent, indicating an interaction between frq and cel; period effects reported in the literature can be described as changes by a fixed ratio or percentage of the period rather than by a fixed number of hours, and the data, therefore, can support a multiplicative as well as an additive model.--Several biochemical interpretations of these interactions are discussed, based on simple chemical kinetics, enzyme inhibition kinetics and the control of flux through metabolic pathways.     

The Goodwin model: simulating the effect of cycloheximide and heat shock on the sporulation rhythm of Neurospora crassa

The Goodwin model is a negative feedback oscillator which describes rather closely the putative molecular mechanism of the circadian clock of Neurospora and Drosophila. An essential feature is that one or two clock proteins are synthesized and degraded in a rhythmic fashion. When protein synthesis in N. crassa (wild-type frq+and long-period mutant frq7) was inhibited by continuous incubation with increasing concentrations of cycloheximide (CHX) the period of the circadian sporulation rhythmicity is only slightly increased. The explanation of this effect may be seen in the inhibition of protein synthesis and protein degradation. In the model, increasing inhibition of both processes led to very similar results with respect to period length. That protein degradation is, in fact, inhibited by CHX is shown by determining protein degradation in N. crassa by means of pulse chase experiments. Phase response curves (PRCs) of the N. crassa sporulation rhythm toward CHX which were reported in the literature and investigated in this paper revealed significant differences between frq+and the long period mutants frq7and csp -1 frq7. These PRCs were also convincingly simulated by the model, if a transient inhibition of protein degradation by CHX is assumed as well as a lower constitutive degradation rate of FRQ-protein in the frq7/ csp -1 frq7mutants. The lower sensitivities of frq7and csp -1 frq7towards CHX may thus be explained by a lower degradation rate of clock protein FRQ7. The phase shifting by moderate temperature pulses (from 25 to 30 degrees C) can also be simulated by the Goodwin model and shows large phase advances at about CT 16-20 as observed in experiments. In case of higher temperature pulses (from 35 to 42 or 45 degrees C=heat shock) the phase position and form of the PRC changes as protein synthesis is increasingly inhibited. It is known from earlier experiments that heat shock not only inhibits the synthesis of many proteins but also inhibits protein degradation. Taking this into account, the Goodwin model also simulates the PRCs of high temperature (heat shock) pulses.