Temperature-sensitive and circadian oscillators of Neurospora crassa share components

In Neurospora crassa, the interactions between products of the frequency (frq), frequency-interacting RNA helicase (frh), white collar-1 (wc-1), and white collar-2 (wc-2) genes establish a molecular circadian clockwork, called the FRQ-WC-Oscillator (FWO), which is required for the generation of molecular and overt circadian rhythmicity. In strains carrying nonfunctional frq alleles, circadian rhythms in asexual spore development (conidiation) are abolished in constant conditions, yet conidiation remains rhythmic in temperature cycles. Certain characteristics of these temperature-synchronized rhythms have been attributed to the activity of a FRQ-less oscillator (FLO). The molecular components of this FLO are as yet unknown. To test whether the FLO depends on other circadian clock components, we created a strain that carries deletions in the frq, wc-1, wc-2, and vivid (vvd) genes. Conidiation in this ΔFWO strain was still synchronized to cyclic temperature programs, but temperature-induced rhythmicity was distinct from that seen in single frq knockout strains. These results and other evidence presented indicate that components of the FWO are part of the temperature-induced FLO.     

Unique self-sustaining circadian oscillators within the brain of Drosophila melanogaster

In Drosophila circadian rhythms persist in constant darkness (DD). The small ventral Lateral Neurons (s-LN_v) mainly control the behavioral circadian rhythm in consortium with the large ventral Lateral Neurons (l-LN_v) and dorsal Lateral Neurons (LN_d). It is believed that the molecular oscillations of clock genes are the source of this persistent behavior. Indeed the s-LN_v, LN_d, Dorsal Neurons (DN)-DN₂ and DN₃ displayed self-sustained molecular oscillations in DD both at RNA and protein levels, except the DN₂ oscillates in anti-phase. In contrast, the l-LN_v and DN₁ displayed self-sustained oscillations at the RNA level, but protein oscillations quickly dampened. Having self-sustained and dampened molecular oscillators together in the DN groups suggested that they play different roles. However, all DN groups seemed to contribute together to the light-dark (LD) behavioral rhythm. The LD entrainment of LN oscillators is achieved through Rhodopsin (RH) and Cryptochrome (CRY). CRY's expression in all DN groups implicates also its role in LD entrainment of DN, like in DN₁. However, mutations in cry and glass that did not inflict LD synchronization of the DN₂, DN₃ oscillator implicate the existence of a novel photoreceptor at least in DN₃.     

The mutagenicity of azathioprine in mice, Drosophila melanogaster and Neurospora crassa.

The chemotherapeutic coumpound azathioprine was tested for possible mutagenicity in Swiss Albino mice, Drosophila melanogaster and Neurospora crassa. Utilizing the dominant-lethal assay it was found that acute oral doses of azathioprine (2 times 25 mg/kg body weight), induced dominant-lethal mutations in mouse spermatocytes. Chronic oral doses of azathioprine (2 times 25 mg/kg body weight/week for 10 weeks) resulted in a greater rate of dominant-lethality. This increase was not permanent, and by week 4 of gamete sampling there was no significant increase in dominant-lethal mutations. Histological sections showed that chronic treatment of male mice with azathioprine caused pyknosis of spermatocyte nuclei and depletion of the spermatid population. Both acute and chronic doses of azathioprine caused a temporary reduction in sperm viability. Oral treatment of male Canton-S, D. melanogaster with azathioprine caused an increase in dominant-lethality in broods assumed to correspond to spermatid and spermaotcyte stages. Azathioprine also increased the rate of non-disjunction of the X and Y chromosomes, loss of the long arm of the Y chromosome, and loss of the X or Y chromosome in treated male R(I)2, vf/BsYy+D. melanogaster. Since sex-ratio deviation did not occur in progeny from treated rod-X (yv/B2Yy+) male D. melanogaster, it was concluded that the observed sex-ration deviation in the treated ring-X stock was the result of induced ring-X lethality. Azathioprine induced recessive-lethal mutations in the ad-3 region of a N. crassa heterokaryon. In the host-mediated assay using this same heterokaryon and male Swiss Albino mice as host, the mutagenic activity of azathioprine did not appear to be potentiated or detoxified by the host. The results show that azathioprine has a deleterious effect on reproduction in mice and probably induces mutational events in mice, D. melanogaster and N. crassa.     

A case for multiple oscillators controlling different circadian rhythms in Drosophila melanogaster

A population of the fruit fly Drosophila melanogaster was raised in periodic light/dark (LD) cycles of 12:12 h for about 35 generations. Eclosion, locomotor activity, and oviposition were found to be rhythmic in these flies, when assayed in constant laboratory conditions where the light intensity, temperature, humidity and other factors which could possibly act as time cue for these flies, were kept constant. These rhythms also entrained to a LD cycle of 12:12 h in the laboratory with each of them adopting a different temporal niche. The free-running periods (tau) of the eclosion, locomotor activity and oviposition rhythms were significantly different from each other. The peak of eclosion and the onset of locomotor activity occurred during the light phase of the LD cycle, whereas the peak of oviposition was found to occur during the dark phase of the LD cycle. Based on these results, we conclude that different circadian oscillators control the eclosion, locomotor activity and oviposition rhythms in the fruit fly D. melanogaster.     

Kinetics of circadian band development in Neurospora crassa

The circadian rhythm of Neurospora crassa can be seen as a conidiation rhythm that produces concentric rings of bands (conidiating regions) alternating with interbands (non-conidiating regions) on the surface of an agar medium. To follow quantitatively this rhythm, densitometric analysis, gravimetric procedures, and video microscopy were employed. The circadian behavior of N. crassa is commonly monitored by cultivation in race tubes; in this work we report different growth kinetics during cultivation in conventional Petri dish cultures. Two different growth parameters were measured: total colony mass (true growth rate) and distance (colony radial expansion or hyphal elongation). Determinations of cellular mass revealed a dramatic circadian oscillation with a marked drop in growth rate during new interband formation followed by a sharp increase during the development of a new conidiation band. On the other hand, we found that the radial expansion of the colony previously reported to decrease periodically seemed unaffected by the circadian clock. Densitometric analysis showed no initial difference in the expanding margin of the colony, independent of whether that area was destined to be a band or an interband. The band areas increased rapidly in density for about 15 h whereas the interband areas maintained an equally rapid rate of increase for only 6h. The density of band areas kept increasing slowly for almost 40 h, along with an increase in the amount of conidia. Video microscopy showed the importance of cytoplasmic flow in colony development with continuous forward flow to support hyphal morphogenesis and reverse flow to support an extended period of conidiogenesis. Our results indicate that the circadian system of Neurospora can be expressed at the level of cellular mass formation, not just as the developmental conidiation rhythm.     

How temperature affects the circadian clock of Neurospora crassa

Light and temperature are major environmental cues that influence circadian clocks. The molecular effects of these zeitgebers on the circadian clock of Neurospora crassa have been studied intensively during the last decade. While signal transduction of light into the circadian clock is quite well characterized, we have only recently begun to understand the molecular mechanisms that underlie temperature sensing. Here we summarize briefly the current knowledge about the effects of temperature on the circadian clock of Neurospora crassa.     

How temperature affects the circadian clock of Neurospora crassa

Light and temperature are major environmental cues that influence circadian clocks. The molecular effects of these zeitgebers on the circadian clock of Neurospora crassa have been studied intensively during the last decade. While signal transduction of light into the circadian clock is quite well characterized, we have only recently begun to understand the molecular mechanisms that underlie temperature sensing. Here we summarize briefly the current knowledge about the effects of temperature on the circadian clock of Neurospora crassa.     

How temperature affects the circadian clock of Neurospora crassa

Light and temperature are major environmental cues that influence circadian clocks. The molecular effects of these zeitgebers on the circadian clock of Neurospora crassa have been studied intensively during the last decade. While signal transduction of light into the circadian clock is quite well characterized, we have only recently begun to understand the molecular mechanisms that underlie temperature sensing. Here we summarize briefly the current knowledge about the effects of temperature on the circadian clock of Neurospora crassa.     

Qualitative similarities between the behavior of coupled oscillators and circadian rhythms

This paper summarizes in a nonmathematical way the major properties of coupled oscillators which relate to circadian rhythms. For certain values of the coupling strength it is far easier to maintain synchrony than to achieve it among the various interacting units. This property not only simulates the free run period lability but also the effects of critical pulses.     

Quantitative trait loci for the circadian clock in Neurospora crassa

Neurospora crassa has been a model organism for the study of circadian clocks for the past four decades. Among natural accessions of Neurospora crassa, there is significant variation in clock phenotypes. In an attempt to investigate natural allelic variants contributing to quantitative variation, we used a quantitative trait loci mapping approach to analyze three independent mapping populations whose progenitors were collected from geographically isolated locations. Two circadian clock phenotypes, free-running period and entrained phase, were evaluated in the 188 F(1) progeny of each mapping population. To identify the clock QTL, we applied two QTL mapping analyses: composite interval mapping (CIM) and Bayesian multiple QTL analysis (BMQ). When controlling false positive rates < or =0.05, BMQ appears to be the more sensitive of the two approaches. BMQ confirmed most of the QTL from CIM (18 QTL) and identified 23 additional QTL. While 13 QTL colocalize with previously identified clock genes, we identified 30 QTL that were not linked with any previously characterized clock genes. These are candidate regions where clock genes may be located and are expected to lead to new insights in clock regulation.     

Isoform switching facilitates period control in the Neurospora crassa circadian clock

A striking and defining feature of circadian clocks is the small variation in period over a physiological range of temperatures. This is referred to as temperature compensation, although recent work has suggested that the variation observed is a specific, adaptive control of period. Moreover, given that many biological rate constants have a Q₁₀ of around 2, it is remarkable that such clocks remain rhythmic under significant temperature changes. We introduce a new mathematical model for the Neurospora crassa circadian network incorporating experimental work showing that temperature alters the balance of translation between a short and long form of the FREQUENCY (FRQ) protein. This is used to discuss period control and functionality for the Neurospora system. The model reproduces a broad range of key experimental data on temperature dependence and rhythmicity, both in wild‐type and mutant strains. We present a simple mechanism utilising the presence of the FRQ isoforms (isoform switching) by which period control could have evolved, and argue that this regulatory structure may also increase the temperature range where the clock is robustly rhythmic.     

Differences and similarities in chromatin structure of Neurospora crassa and higher eucaryotes.

The subunit structure of Neurospora chromatin which contains a full histone complement (Goff, 1976) exhibits both differences and similarities to chromatin of higher eucaryotes. The size of the DNA per subunit is only 170 +/- 5 base pairs, as compared to 200 base pairs in higher eucaryotes. However, the internal structures of the subunits are closely related. They contain 140 base pairs of DNA that are more tightly associated with the histone core and similarly arranged on the outside of the subunit. Hence the difference in structure resides in a shorter linker region of adjacent subunits in Neurospora chromatin. This is supported by a reduced primary cutting site and a lower content of lysines in histone H1. The role of H1 and its relation to the linker region are discussed.     

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.     

sn-1,2-diacylglycerol levels in the fungus Neurospora crassa display circadian rhythmicity

The fungus Neurospora crassa is a model organism for investigating the biochemical mechanism of circadian (daily) rhythmicity. When a choline-requiring strain (chol-1) is depleted of choline, the period of the conidiation rhythm lengthens. We have found that the levels of sn-1,2-diacylglycerol (DAG) increase in proportion to the increase in period. Other clock mutations that change the period do not affect the levels of DAG. Membrane-permeant DAGs and inhibitors of DAG kinase were found to further lengthen the period of choline-depleted cultures. The level of DAG oscillates with a period comparable to the rhythm of conidiation in wild-type strains, choline-depleted cultures, and frq mutants, including a null frq strain. The DAG rhythm is present at the growing margin and also persists in older areas that have completed development. The phase of the DAG rhythm can be set by the light-to-dark transition, but the level of DAG is not immediately affected by light. Our results indicate that rhythms in DAG levels in Neurospora are driven by a light-sensitive circadian oscillator that does not require the frq gene product. High levels of DAG may feed back on that oscillator to lengthen its period.     

A genetic selection for circadian output pathway mutations in Neurospora crassa

In most organisms, circadian oscillators regulate the daily rhythmic expression of clock-controlled genes (ccgs). However, little is known about the pathways between the circadian oscillator(s) and the ccgs. In Neurospora crassa, the frq, wc-1, and wc-2 genes encode components of the frq-oscillator. A functional frq-oscillator is required for rhythmic expression of the morning-specific ccg-1 and ccg-2 genes. In frq-null or wc-1 mutant strains, ccg-1 mRNA levels fluctuate near peak levels over the course of the day, whereas ccg-2 mRNA remains at trough levels. The simplest model that fits the above observations is that the frq-oscillator regulates a repressor of ccg-1 and an activator of ccg-2. We utilized a genetic selection for mutations that affect the regulation of ccg-1 and ccg-2 by the frq-oscillator. We find that there is at least one mutant strain, COP1-1 (circadian output pathway derived from ccg-1), that has altered expression of ccg-1 mRNA, but normal ccg-2 expression levels. However, the clock does not appear to simply regulate a repressor of ccg-1 and an activator of ccg-2 in two independent pathways, since in our selection we identified three mutant strains, COP1-2, COP1-3, and COP1-4, in which a single mutation in each strain affects the expression levels and rhythmicity of both ccg-1 and ccg-2.     

Phase shifting of the circadian conidiation rhythm in Neurospora crassa by calmodulin antagonists

The effects of chemicals capable of antagonizing the functions of calmodulin, such as trifluoperazine, chlorpromazine, imipramine, alprenolol, W7, and W13, on the circadian conidiation rhythm of Neurospora crassa were examined. Trifluoperazine, at a 30-microM concentration, was most effective in shifting the phase of the conidiation rhythm and caused a maximum phase delay at circadian time (CT) 6 and maximum phase advance at CT 9. Chlorpromazine was less effective than trifluoperazine, and a 300-microM concentration of chlorpromazine was required for a similar phase shift. Imipramine, at a 1-mM concentration, caused only a small phase shift, while alprenolol had little effect on biological clock function. W7 and W13 caused phase delays longer than 10 hr at CT 6 and caused a phase advance of about 5 hr at CT 10 when present at a 200-microM concentration. However, W5 and W12, the dechlorinated homologues of W7 and W13, had no effects on clock function at the same concentration. Calmodulin was assayed by measurements of stimulation of cyclic nucleotide diphosphodiesterase activity. Calmodulin content remained constant in trifluoperazine-sensitive and trifluoperazine-insensitive phases for two cycles following the light-dark transition.