Functional characterization of MAT1-1-specific mating-type genes in the homothallic ascomycete Sordaria macrospora provides new insights into essential and nonessential sexual regulators.

Mating-type genes in fungi encode regulators of mating and sexual development. Heterothallic ascomycete species require different sets of mating-type genes to control nonself-recognition and mating of compatible partners of different mating types. Homothallic (self-fertile) species also carry mating-type genes in their genome that are essential for sexual development. To analyze the molecular basis of homothallism and the role of mating-type genes during fruiting-body development, we deleted each of the three genes, SmtA-1 (MAT1-1-1), SmtA-2 (MAT1-1-2), and SmtA-3 (MAT1-1-3), contained in the MAT1-1 part of the mating-type locus of the homothallic ascomycete species Sordaria macrospora. Phenotypic analysis of deletion mutants revealed that the PPF domain protein-encoding gene SmtA-2 is essential for sexual reproduction, whereas the alpha domain protein-encoding genes SmtA-1 and SmtA-3 play no role in fruiting-body development. By means of cross-species microarray analysis using Neurospora crassa oligonucleotide microarrays hybridized with S. macrospora targets and quantitative real-time PCR, we identified genes expressed under the control of SmtA-1 and SmtA-2. Both genes are involved in the regulation of gene expression, including that of pheromone genes.

Interconnected feedback loops in the Neurospora circadian system.

In Neurospora crassa, white collar 1 (WC-1), a transcriptional activator and positive clock element, is rhythmically expressed from a nonrhythmic steady-state pool of wc-1 transcript, consistent with posttranscriptional regulation of rhythmicity. Mutations in frq influence both the level and periodicity of WC-1 expression, and driven FRQ expression not only depresses its own endogenous levels, but positively regulates WC-1 synthesis with a lag of about 8 hours, a delay similar to that seen in the wild-type clock. FRQ thus plays dual roles in the Neurospora clock and thereby, with WC-1, forms a second feedback loop that would promote robustness and stability in this circadian system. The existence also of interlocked loops in Drosophila melanogaster and mouse clocks suggests that such interlocked loops may be a conserved aspect of circadian timing systems.

Neurospora wc-1 and wc-2: transcription, photoresponses, and the origins of circadian rhythmicity.

Circadian rhythmicity is universally associated with the ability to perceive light, and the oscillators ("clocks") giving rise to these rhythms, which are feedback loops based on transcription and translation, are reset by light. Although such loops must contain elements of positive and negative regulation, the clock genes analyzed to date-frq in Neurospora and per and tim in Drosophila-are associated only with negative feedback and their biochemical functions are largely inferred. The white collar-1 and white collar-2 genes, both global regulators of photoresponses in Neurospora, encode DNA binding proteins that contain PAS domains and are believed to act as transcriptional activators. Data shown here suggest that wc-1 is a clock-associated gene and wc-2 is a clock component; both play essential roles in the assembly or operation of the Neurospora circadian oscillator. Thus DNA binding and transcriptional activation can now be associated with a clock gene that may provide a positive element in the feedback loop. In addition, similarities between the PAS-domain regions of molecules involved in light perception and circadian rhythmicity in several organisms suggest an evolutionary link between ancient photoreceptor proteins and more modern proteins required for circadian oscillation.

How temperature changes reset a circadian oscillator.

Circadian rhythms control many physiological activities. The environmental entrainment of rhythms involves the immediate responses of clock components. Levels of the clock protein FRQ were measured in Neurospora at various temperatures; at higher temperatures, the amount of FRQ oscillated around higher levels. Absolute FRQ amounts thus identified different times at different temperatures, so temperature shifts corresponded to shifts in clock time without immediate synthesis or turnover of components. Moderate temperature changes could dominate light-to-dark shifts in the influence of circadian timing. Temperature regulation of clock components could explain temperature resetting of rhythms and how single transitions can initiate rhythmicity from characteristic circadian phases.

Molecular cloning of genes under control of the circadian clock in Neurospora.

To investigate the regulation of messenger RNA abundance by circadian clocks, genomic and complementary DNA libraries were screened with complementary DNA probes enriched, by means of sequential rounds of subtractive hybridization, for sequences complementary to transcripts specific to either early morning or early evening cultures of Neurospora. Only two morning-specific genes were identified through this protocol. RNA blot analysis verified that the abundance of the transcripts arising from these genes oscillates with a period of 21.5 hours in a clock wild-type strain and 29 hours in the long-period clock mutant strain frq7. Genetic mapping through the use of restriction fragment length polymorphisms shows the two genes, ccg-1 and ccg-2, to be unlinked. These data provide a view of the extent of clock control of gene expression.

Negative feedback defining a circadian clock: autoregulation of the clock gene frequency.

The frequency (frq) locus of Neurospora crassa was originally identified in searches for loci encoding components of the circadian clock. The frq gene is now shown to encode a central component in a molecular feedback loop in which the product of frq negatively regulated its own transcript, which resulted in a daily oscillation in the amount of frq transcript. Rhythmic messenger RNA expression was essential for overt rhythmicity in the organism and no amount of constitutive expression rescued normal rhythmicity in frq loss-of-function mutants. Step reductions in the amount of FRQ-encoding transcript set the clock to a specific and predicted phase. These results establish frq as encoding a central component in a circadian oscillator.

Common threads in eukaryotic circadian systems.

Within the past 18 months, common regulatory patterns have emerged among eukaryotic circadian systems--extending from fungi through to mammals. Heterodimeric complexes of PAS-domain-containing transcription factors play positive roles in clock-associated feedback loops, and classic clock proteins like FREQUENCY (FRQ), PERIOD (PER), and TIMELESS (TIM) appear as negative elements. Post-transcriptional control governs the amount and type of FRQ and makes the clock responsive to temperature.

Circadian biology: clocks for the real world.

The circadian system of Neurospora crassa includes a molecular feedback loop that is entrainable by light. A recent study has shown that a second, elusive oscillator interacts with the feedback loop to drive output rhythms.

Closely watched clocks: molecular analysis of circadian rhythms in Neurospora and Drosophila.

Circadian rhythms represent a type of cellular regulation common to most eukaryotes. Analysis of the genetic basis of this phenomenon is beginning to provide information about how clocks function at the molecular level. Surprisingly, the first two cloned 'clock genes', one from a fruit fly and one from a fungus, share some common characteristics both genetically and in the nature of the proteins they encode. In related work, the recent identification and molecular analysis of clock-controlled genes is revealing how biological clocks control gene expression, and may pave the way for the isolation of novel 'clock genes' in the future.

Neurospora crassa clock-controlled genes are regulated at the level of transcription.

Although an extensive number of biological processes are under the daily control of the circadian biological clock, little is known about how the clock maintains its regulatory networks within a cell. An important aspect of this temporal control is the daily control of gene expression. Previously we identified two morning-specific genes that are regulated by the clock through daily control of gene expression (J. Loros, S. Denome, and J.C. Dunlap, Science 243:385-388, 1989). We have now introduced a method for transcriptional analysis in Neurospora crassa and used this nuclear run-on procedure to show that regulation of mRNA abundance for these two morning-specific genes occurs at the level of transcription. This transcriptional regulation by the circadian clock provides a basis for isolating circadian rhythm mutants.

Distinct cis-acting elements mediate clock, light, and developmental regulation of the Neurospora crassa eas (ccg-2) gene.

The Neurospora crassa eas (ccg-2) gene, which encodes a fungal hydrophobin, is transcriptionally regulated by the circadian clock. In addition, eas (ccg-2) is positively regulated by light and transcripts accumulate during asexual development. To sort out the basis of this complex regulation, deletion analyses of the eas (ccg-2) promoter were carried out to localize the cis-acting elements mediating clock, light, and developmental control. The primary sequence determinants of a positive activating clock element (ACE) were found to reside in a 45-bp region, just upstream from the TATA box. Using a novel unregulated promoter/reporter system developed for this study, we show that a 68-bp sequence encompassing the ACE is sufficient to confer clock regulation on the eas (ccg-2) gene. Electrophoretic mobility shift assays using the ACE reveal factors present in N. crassa protein extracts that recognize and bind specifically to DNA containing this element. Separate regions of the eas (ccg-2) promoter involved in light induction and developmental control are identified and shown not to be required for clock-regulated expression of eas (ccg-2). The distinct nature of the ACE validates its use as a tool for the identification of upstream regulatory factors involved in clock control of gene expression.

Circadian clock-specific roles for the light response protein WHITE COLLAR-2.

To understand the role of white collar-2 in the Neurospora circadian clock, we examined alleles of wc-2 thought to encode partially functional proteins. We found that wc-2 allele ER24 contained a conservative mutation in the zinc finger. This mutation results in reduced levels of circadian rhythm-critical clock gene products, frq mRNA and FRQ protein, and in a lengthened period of the circadian clock. In addition, this mutation altered a second canonical property of the clock, temperature compensation: as temperature increased, period length decreased substantially. This temperature compensation defect correlated with a temperature-dependent increase in overall FRQ protein levels, with the relative increase being greater in wc-2 (ER24) than in wild type, while overall frq mRNA levels were largely unaltered by temperature. We suggest that this temperature-dependent increase in FRQ levels partially rescues the lowered levels of FRQ resulting from the wc-2 (ER24) defect, yielding a shorter period at higher temperatures. Thus, normal activity of the essential clock component WC-2, a positive regulator of frq, is critical for establishing period length and temperature compensation in this circadian system.

Microbial circadian oscillatory systems in Neurospora and Synechococcus: models for cellular clocks.

Common regulatory patterns have emerged among the feedback loops lying within circadian systems. Significant progress in dissecting the mechanism of clock resetting by temperature and the role of the WC proteins in the Neurospora light response has accompanied documentation of the importance of nuclear localization and phosphorylation-induced turnover of FRQ to this circadian cycle. The long-awaited molecular description of a transcription/translation loop in the Synechococcus circadian system represents a quantal step forward, followed by the identification of additional important proteins and interactions. Finally, the adaptive significance of rhythms in Synechococcus and by extension in all clocks nicely ties up an extraordinary year.

Fungal Light Sensing at the Bench and Beyond.

Visible light is a pervasive environmental signal that orients most organisms in space and time. For a fungus, the detection of light is facilitated by diverse classes of photoreceptor proteins, which in turn coordinate growth, spore dispersal, stress resistance, primary metabolism, and toxin production. We will first provide a discussion on signal input, focusing on recent insights into how fungal photoreceptors detect and transmit information at the biochemical and molecular levels. We will then pivot our discussion to how light influences fungal behaviors that are of industrial, agricultural, or even medical relevance. Because the light environment can be easily manipulated in many contexts, we will argue that understanding fungal photobiology is both an important basic and applied endeavor.

Isolation and analysis of the arg-13 gene of Neurospora crassa.

Mutations in arg-13 result in slow growth in minimal medium and can suppress mutations in carbamyl phosphate synthase-aspartate carbamyl transferase within the pyrimidine pathway; the exact biochemical function of the gene product is unknown. To understand the role of arg-13 in arginine metabolism, cosmids rescuing growth in arg-13 mutants were cloned and mapped to the position of arg-13 on LG IR. Northern analysis showed the arg-13 message to contain approximately 2100 nt, although a 1.4-kb genomic fragment truncated at the 5' and 3' ends of the gene encodes a shortened transcript that can rescue arg-13 function. Expression of mRNA arising from the mutant arg-13 gene is induced by arginine starvation, although wild type (arg-13+) is not derepressed in minimal medium. The sequence of the arg-13 gene shows ARG-13 to be a member of the mitochondrial carrier superfamily with three repeats of a approximately 100-amino acid domain, six putative membrane spanning regions, and three copies of the mitochondrial carrier consensus pattern. This information plus available and new nutritional data are consistent with the hypothesis that arg-13 encodes a mitochondrial basic amino acid carrier whose existence was predicted based upon previous physiological, nutritional and biochemical data.

Analysis of expressed sequence tags from two starvation, time-of-day-specific libraries of Neurospora crassa reveals novel clock-controlled genes.

In an effort to determine genes that are expressed in mycelial cultures of Neurospora crassa over the course of the circadian day, we have sequenced 13,000 cDNA clones from two time-of-day-specific libraries (morning and evening library) generating approximately 20,000 sequences. Contig analysis allowed the identification of 445 unique expressed sequence tags (ESTs) and 986 ESTs present in multiple cDNA clones. For approximately 50% of the sequences (710 of 1431), significant matches to sequences in the National Center for Biotechnology Information database (of known or unknown function) were detected. About 50% of the ESTs (721 of 1431) showed no similarity to previously identified genes. We hybridized Northern blots with probes derived from 26 clones chosen from contigs identified by multiple cDNA clones and EST sequences. Using these sequences, the representation of genes among the morning and evening sequences, respectively, in most cases does not reflect their expression patterns over the course of the day. Nevertheless, we were able to identify four new clock-controlled genes. On the basis of these data we predict that a significant proportion of the expressed Neurospora genes may be regulated by the circadian clock. The mRNA levels of all four genes peak in the subjective morning as is the case with previously identified ccgs.

The genetic and molecular dissection of a prototypic circadian system.

A great deal is known about this archetypal circadian system, and it is likely that Neurospora will represent the first circadian system in which it will be possible to provide a complete description of the flow of information from the photoreceptor, through the components of oscillator, out to a terminal aspect of regulation. In Neurospora the strongest case has been made for there being a state variable of clock identified (Hall, 1995), it has now been shown that light resetting of the clock is mediated by the rapid light induction of the gene encoding this state variable, and a number of defined clock-regulated output genes have been identified, in two of which the clock-specific parts of the promoters have been localized. In addition to the importance of these factoids themselves, our efforts towards understanding of this system has allowed the development of tools and paradigms (e.g. Loros et al., 1989; Loros and Dunlap, 1991; Aronson et al., 1994a) that will help to pave the way for proving the identity of clock components in more complex systems, for understanding how clocks are regulated by entraining factors, and for showing how time information eventually is used to regulate the behaviors of clock cells, and of whole organisms.

Molecular analysis of the Neurospora clock: cloning and characterization of the frequency and period-4 genes.

Genetic analysis of Neurospora crassa has identified many mutants that affect the biological clock. In this article we review the cloning of two of these genes, frq and prd-4. Both genes were isolated using a chromosome walk technique. Subcloning experiments and subsequent Northern analysis of frq implicate the importance of two transcripts that emanate from this locus. In preliminary data, no protein-coding region is evident in the smaller transcript; the larger transcript contains a 962-amino acid open reading frame. The open reading frame shows limited homology to per, a clock gene identified in Drosophila. Sequence analysis of all existing frq alleles suggests that the defect in each case lies within the open reading frame. Successful cloning of the prd-4 gene required walking a distance of greater than 40 kb. A physical map of this region has been constructed using restriction analysis. The dominance-recessive relationship of prd-4 and prd-4+ was established by examining the period lengths of strains harboring a wide range of prd-4/prd-4+ nuclear ratios.

The circadian Per1 and Per2 genes influence alcohol intake, reinforcement, and blood alcohol levels.

BACKGROUND: Perturbations in the function of core circadian clock components such as the Period (Per) family of genes are associated with alcohol use disorder, and disruptions in circadian cycles may contribute to alcohol abuse and relapse. This study tested ethanol consumption, reinforcement, and metabolism in mice containing functional mutations in Per1 and/or Per2 genes on an ethanol-preferring background, C57BL/6J mice. METHODS: Mice were tested in: (A) free-access intake with ascending concentrations of ethanol (2-16%, v/v), (B) conditioned place preference using ethanol (2g/kg for males; 2.5g/kg for females) vs. saline injections, (C) recovery of the righting reflex following a 4g/kg bolus of ethanol, and (D) blood ethanol levels 1h after a 2g/kg bolus of ethanol. RESULTS: All Per mutant (mPer) mice showed increased ethanol intake and condition place preference compared to controls. There were also genotypic differences in blood ethanol concentration: in males, only mPer1 mice showed a significantly higher blood ethanol concentration than WT mice, but in females, all mPer mice showed higher blood ethanol levels than WT mice. CONCLUSIONS: Mutation of either Per1 or Per2, as well as mutations of both genes, increases ethanol intake and reinforcement in an ethanol-preferring mouse model. In addition, this increase in ethanol seeking behavior seems to result both from a change in ethanol metabolism and a change in reward responding to ethanol, but not from any change in sensitivity to ethanol's sedating effects.