Axially chiral BODIPYs.

The synthesis and resolution of a class of chiral organic fluorophores, axially chiral 4,4-difluoro-4-bora-3a,4a-diaza-s-indacenes (Ax*-BODIPY), is described. Ax*-BODIPYs were prepared through a modular synthesis combined with a late stage Heck functionalisation. Resolution was achieved by preparative chiral HPLC. Absolute stereochemical assignment was performed by comparison of experimental ECD spectra with TD-DFT calculations.

Large Stokes shift fluorescent dyes based on a highly substituted terephthalic acid core.

The synthesis of dyes based on a highly substituted terephthalic acid core is described, starting from readily available 2,5-dihydroxy-terephthalic acid diethyl ester. The dyes are highly colored, soluble in organic solvents and reasonably fluorescent in solution and in the solid state. The maxima for absorption and emission are around 402 and 502 nm, respectively. The fluorophores are readily cyclized to generate compounds which comprise the basic 6,13-dihydroxy-chromeno[2,3-b]xanthene-7,14-dione unit. These new derivatives are nonfluorescent.

Rhythms of differentiation and diacylglycerol in Neurospora.

Although the fungus Neurospora crassa is a relatively simple lower eukaryote, its circadian system may be more complex than previously thought. In this paper we review evidence suggesting that there may be several output pathways coupled in complex ways to a single oscillator, or that there may be more than one oscillator driving independent output pathways. We have described two new rhythms in Neurospora that are not tightly coupled to the rhythm of conidiation bands that is the standard assay for the state of the Neurospora circadian clock. The first is a rhythm in the timing of differentiation, i.e. the production of aerial hyphae and spores. Large regions of the mycelium differentiate synchronously, as if responding to a spatially widespread signal. This rhythm may be distinct from the timer that sets the determination switch controlling the spatial pattern of conidiation bands. The second new rhythm is an oscillation in the levels of the neutral lipid diacylglycerol (DAG). This rhythm is found in all regions of a colony and is not always in phase with the rhythm of conidiation bands. The DAG rhythm shares some characteristics with the differentiation rhythm and has the potential to act as the signal that induces rhythmic differentiation.

The Neurospora circadian clock: simple or complex?

The fungus Neurospora crassa is being used by a number of research groups as a model organism to investigate circadian (daily) rhythmicity. In this review we concentrate on recent work relating to the complexity of the circadian system in this organism. We discuss: the advantages of Neurospora as a model system for clock studies; the frequency (frq), white collar-1 and white collar-2 genes and their roles in rhythmicity; the phenomenon of rhythmicity in null frq mutants and its implications for clock mechanisms; the study of output pathways using clock-controlled genes; other rhythms in fungi; mathematical modelling of the Neurospora circadian system; and the application of new technologies to the study of Neurospora rhythmicity. We conclude that there may be many gene products involved in the clock mechanism, there may be multiple interacting oscillators comprising the clock mechanism, there may be feedback from output pathways onto the oscillator(s) and from the oscillator(s) onto input pathways, and there may be several independent clocks coexisting in one organism. Thus even a relatively simple lower eukaryote can be used to address questions about a complex, networked circadian system.

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.

TOXNET: A computerized collection of toxicological and environmental health information.

The Toxicology and Environmental Health Information Program, managed by the National Library of Medicine's Division of Specialized Information Services, provides access to a number of online bibliographic and factual computer files concerned with the toxicology, safety and handling, and environmental fate of chemicals, along with other files that cover genetic toxicology, developmental and reproductive toxicology, mutagenesis, carcinogenesis and toxic chemical releases.

Circadian rhythms: new functions for old clock genes.

The mechanisms of circadian clocks, which time daily events, are being investigated by characterizing 'clock genes' that affect daily rhythms. The core of the clock mechanism in Drosophila, Neurospora, mammals and cyanobacteria is described by a transcription-translation feedback-loop model. However, problems with this model could indicate that it is time to look at the functions of these genes in a different light. Our a priori assumptions about the nature of circadian clocks might have restricted our search for new mutants in ways that prevent us from finding important clock genes.

Circadian rhythms in Neurospora crassa: lipid deficiencies restore robust rhythmicity to null frequency and white-collar mutants.

The conidiation rhythm in the fungus Neurospora crassa is a model system for investigating the genetics of circadian clocks. Null mutants at the frq (frequency) locus (frq(9) and frq(10)) make no functional frq gene products and are arrhythmic under standard conditions. The white-collar strains (wc-1 and wc-2) are insensitive to most effects of light, and are also arrhythmic. All three genes are proposed to be central components of the circadian oscillator. We have been investigating two mutants, cel (chain-elongation) and chol-1 (choline-requirer), which are defective in lipid synthesis and affect the period and temperature compensation of the rhythm. We have constructed the double mutant strains chol-1 frq(9), chol-1 frq(10), chol-1 wc-1, chol-1 wc-2, cel frq(9), cel frq(10), and cel wc-2. We find that these double mutant strains are robustly rhythmic when assayed under lipid-deficient conditions, indicating that free-running rhythmicity does not require the frq, wc-1, or wc-2 gene products. The rhythms in the double mutant strains are similar to the cel and chol-1 parents, except that they are less sensitive to light. This suggests that the frq, wc-1, and wc-2 gene products may be components of a pathway that normally supplies input to a core oscillator to transduce light signals and sustain rhythmicity. This pathway can be bypassed when lipid metabolism is altered.

Inheritance of Carboxin Resistance in a European Field Isolate of Ustilago nuda.

ABSTRACT Two carboxin-resistant field isolates of Ustilago nuda from Europe were crossed with a carboxin-sensitive field isolate from North America. Meiotic tetrads isolated from germinating F(1) teliospores of one of the hybrids were tested for carboxin resistance and mating type. Carboxin resistance was shown to be controlled by a single gene (CBX1R), because a 1:1 segregation of carboxin resistance was observed in all 27 tetrads. Tetrad analysis indicated that the loci for carboxin resistance (Cbx1) and mating type (MAT1) segregate independently but may be located on the same chromosome. Tetrad analysis was not possible with the F(1) hybrid of he other field isolate, and its resistance cannot yet be attributed to CBX1R. Carboxin resistance was qualitatively dominant to sensitivity in vitro, as demonstrated by triad analysis of germinating F(1) teliospores. Quantitative in planta infection percents supported the conclusion that CBX1R is dominant, although incompletely, in the F(1) hybrid of one of the field isolates. Also, fewer than expected carboxin-sensitive F(2) individuals were observed in planta. However, inoculations of host plants with U. nuda have resulted in similar, unexpected variation in the past.

Choline depletion, frq mutations, and temperature compensation of the circadian rhythm in Neurospora crassa.

In the fungus Neurospora crassa, the chol-1 mutation blocks the synthesis of the lipid phosphatidylcholine and also lengthens the period of the circadian rhythm of conidiation under conditions of choline depletion. The frq mutations, which have no known metabolic defect, affect both the period of the rhythm and temperature compensation. In this article, the chol-1 mutant strain has been further characterized with respect to its temperature compensation and its interactions with frq. Choline depletion of chol-1 abolishes good temperature compensation: Low temperatures lengthen the period under choline-depleted conditions, and low choline lengthens the period at any one temperature. Double-mutant strains carrying both chol-1 and one of a series of frq alleles demonstrate interactions between chol-1 and frq: On high choline, the periods of the double mutants are identical to the corresponding chol+ strains, whereas on low choline all double mutants display very long periods (greater than 50 h). Short-period frq mutations shorten the long period on low choline, whereas long-period frq mutations frq mutations have no effect. A null frq mutation in the chol-1 background is arrhythmic on high choline but is robustly rhythmic on low choline and has no effect on the long period. The interactions between frq and chol-1 are similar to the interactions between frq and cel, another lipid-deficient mutant. These results provide support for the hypothesis that membrane lipids may be involved in temperature compensation of the circadian rhythm. The possibility is discussed that the frq gene may not be required for circadian rhythmicity under some conditions and therefore may not be a central component of the circadian oscillator but rather a component of an input pathway.

Temperature compensation and membrane composition in Neurospora crassa.

The link between temperature compensation of the circadian rhythm and temperature-induced adjustment of membrane composition in Neurospora crassa is briefly reviewed. In common with most organisms, Neurospora responds to changes in growth temperature by adjusting its lipid composition, primarily by increasing the degree of unsaturation of its fatty acids at low temperature. This may result in maintenance of either membrane fluidity or phase transition behavior over a range of temperatures. In Neurospora, there are three mutations (frq, cel, and chol-1) that affect temperature compensation of the circadian rhythm; cel and chol-1 are defective in lipid synthesis, and frq interacts with the other two in double-mutant strains. This suggests that lipid metabolism may play a role in temperature compensation of the rhythm, and that the FRQ gene product may also be involved in membrane function, either in regulating lipid composition or as a sensor responding to changes in lipid composition.

Long-Term Storage of Ustilago tritici.

An extensive collection of isolates of Ustilago tritici from around the world is maintained at the Cereal Research Centre. As the collection size increases, however, the time and effort needed to maintain the collection becomes greater, as does the need for a good technique for long term storage of U. tritici. Race T2 of U. tritici was inoculated to spikelets of wheat in February 1976. The matured inoculated heads were thrashed and the seed stored in a desiccator with silica-gel at -15°C. Every 2 years, 60 seeds were removed and planted to determine viability and proportion of infected adult plants. Between 57 and 83% of the seed produced adult plants, and the percent of infected plants ranged between 56 and 98% during the 20 years. There was no significant change in seed germination over time, but there was a positive relationship (P < 0.0664, R2 = 0.452) between the time of storage and the arcsine of the proportion of smutted plants. Storage of U. tritici in infected seed at -15°C and low relative humidity is an efficient method for long-term storage of this fungus.

Age-dependent responses to chemosensory cues mediating kin recognition in dogs (Canis familiaris)

During individually administered 5-min tests conducted in a neutral cage, four age groups (n = 10 males and 10 females per group) of purebred beagles reacted to bedding from their home cage vs. bedding from another litter of the same age. The 20-24-day-old males and females preferred (p < 0.05) home cage bedding over strange cage bedding. Those aged 31-36 days or 66-72 days showed no reliable preference for either type of bedding. Among pups aged 52-56 days, the males preferred (p < 0.05) strange cage bedding, but the females showed no reliable preference. Chemosensory cues are sufficient as mediators of kin recognition in beagles, but their reactions to such cues vary with age-dependent factors, some stemming from changes in the strength of the mother-litter bond. The dogs providing the two types of bedding lived in the same room and on the same diet. Therefore, kin recognition could not have been mediated by different chemosensory cues produced by variations in these environmental factors.

Evidence against a direct role for inositol phosphate metabolism in the circadian oscillator and the blue-light signal transduction pathway in Neurospora crassa.

The inositol-depletion hypothesis proposes that the effects of Li+ on cellular functions are the result of inhibition by Li+ of the inositol monophosphate phosphatase and subsequent depletion of inositol lipids. This mechanism has been proposed to account for the effects of Li+ on the period of the circadian oscillator. Inositol phosphate metabolism has also been proposed as part of the blue-light signal-transduction pathway through which the phase of the circadian oscillator can be reset by light pulses. Four predictions of these two hypotheses have been tested in the fungus Neurospora crassa and all have been found to fail: (1) inositol supplementation does not reverse the effects of Li+ on the period of the circadian rhythm; (2) inositol depletion of an inositol-requiring mutant does not mimic the effects of Li+; (3) depletion of inositol lipids does not inhibit the response to light; and (4) a phase-resetting pulse of light does not increase the levels of inositol phosphates, including Ins(1,4,5)P3.

Effects of inositol starvation on the levels of inositol phosphates and inositol lipids in Neurospora crassa.

An inositol-requiring strain of Neurospora crassa was labelled during growth in liquid medium with [3H]inositol, and the levels of inositol phosphates and phosphoinositides were determined under inositol-sufficient and inositol-starved conditions. Because the mutant has an absolute requirement for inositol, the total mass of inositol-containing compounds could be determined. Inositol-containing lipids were identified by deacylation and co-migration with standards on h.p.l.c.; PtdIns3P, PtdIns4P, and PtdIns(4,5)P2 were found in approximately equal amounts, in addition to large amounts of PtdIns. Inositol starvation decreased the level of PtdIns to 10% of the sufficient level, and decreased the levels of the other phosphoinositides to about 25%. A number of inositol phosphates were found, including several InsP3s, InsP4s and InsP5s and phytic acid. Ins(1,4,5)P3 was identified by co-migration with standards on h.p.l.c. and by digestion with inositol phosphomonoesterase. High concentrations of all inositol phosphates were found in the extracellular medium in inositol-starved cultures. Inositol starvation on both liquid and solid agar media decreased the intracellular levels of some inositol phosphates, but increased the levels of phytic acid and several other inositol phosphates which may be its precursors and/or breakdown products. These results may indicate that inositol starvation induces phytic acid synthesis as a protection against the free-radical production and lipid peroxidation characteristic of inositol-less death.

Phase resetting of the Neurospora crassa circadian oscillator: effects of inositol depletion on sensitivity to light.

The input pathway between the blue-light photoreceptor and the circadian oscillator of Neurospora crassa has not yet been identified. To test the hypothesis that an inositol phospholipid signaling system might be involved in blue-light signal transduction, phase resetting by light was assayed in the inositol-requiring inl strain under conditions of inositol depletion. Phase-resetting curves and dose-response curves indicated that cultures maintained on low inositol (25 microM) were several orders of magnitude more sensitive to light than those maintained on high inositol (250 microM). This difference in light sensitivity was a property of inositol auxotrophy and was not seen in the wild type or in an inositol-independent inl+ revertant. Phase resetting by temperature was not affected by inositol depletion, indicating that the effect on light resetting is specific to the light input pathway and is not the result of a change in the amplitude of the oscillator itself. The results indicate an indirect role for inositol metabolites in the light input pathway--one that is not likely to involve direct participation of an inositol phospholipid signal transduction mechanism.