The timSL mutant affects a restricted portion of the Drosophila melanogaster circadian cycle.

The circadian rhythm genes period (per) and timeless (tim) are central to contemporary studies on Drosophila circadian rhythms. Mutations in these genes give rise to arrhythmic or period-altered phenotypes, and per and tim gene expression is under clock control. per and tim proteins (PER and TIM) also undergo circadian changes in level and phosphorylation state. The authors previously described a period-altering tim mutation, timSL, with allele-specific effects in different per backgrounds. This mutation also affected the TIM phosphorylation profile during the mid-late night. The authors show here that the single amino acid alteration in TIM-SL is indeed responsible for the phenotype, as a timSL transgene recapitulates the original mutant phenotype and shortens the period of perL flies by 3 h. The authors also show that this mutation has comparable effects in a light-dark cycle, as timSL also accelerates the activity offset during the mid-late night of perL flies. Importantly, timSL advances predominantly the mid-late night region of the perL phase response curve, consistent with the notion that this portion of the cycle is governed by unique rate-limiting steps. The authors propose that TIM and PER phosphorylation are normally rate determining during the mid-late night region of the circadian cycle.

CYCLE is a second bHLH-PAS clock protein essential for circadian rhythmicity and transcription of Drosophila period and timeless.

We report the identification, characterization, and cloning of another novel Drosophila clock gene, cycle (cyc). Homozygous cyc flies are completely arrhythmic. Heterozygous cyc/+ flies are rhythmic but have altered periods, indicating that the cyc locus has a dosage effect on period. The molecular circadian phenotype of homozygous cyc flies is like homozygous Clk flies presented in the accompanying paper: mutant flies have little or no transcription of the per and tim genes. Cloning of the gene indicates that it also encodes a bHLH-PAS transcription factor and is a Drosophila homolog of the human protein BMAL1. cyc is a nonsense mutation, consistent with its strong loss-of-function phenotype. We propose that the CYC:CLK heterodimer binds to per and tim E boxes and makes a major contribution to the circadian transcription of Drosophila clock genes.

The timSL mutant of the Drosophila rhythm gene timeless manifests allele-specific interactions with period gene mutants.

To identify new components of the Drosophila circadian clock, we screened chemically mutagenized flies for suppressors or enhancers of the long periods characteristic of the period (per) mutant allele perL. We isolated a novel mutant that maps to the rhythm gene timeless (tim). This novel allele, timSL, alters the temporal pattern of perL protein nuclear localization and restores temperature compensation to perL flies. timSL more generally manifests specific interactions with different per alleles. The identification of this first period-altering tim allele provides further evidence that TIM is a major component of the clock, and the allele-specific interactions with PER provide evidence that the PER/TIM heterodimer is a unit of circadian function. Although timSL fails to restore PER-L/TIM temperature insensitivity in yeast, it alters the TIM phosphorylation pattern during the late night. The effects on phosphorylation suggest that timSL functions as a partial bypass suppressor of perL and provide evidence that the TIM phosphorylation program contributes to the circadian timekeeping mechanism.

Dosage compensation of the period gene in Drosophila melanogaster.

The period (per) gene is located on the X chromosome of Drosophila melanogaster. Its expression influences biological clocks in this fruit fly, including the one that subserves circadian rhythms of locomotor activity. Like most X-linked genes in Drosophila, per is under the regulatory control of gene dosage compensation. In this study, we assessed the activity of altered or augmented per+ DNA fragments in transformants. Relative expression levels in male and female adults were inferred from periodicities associated with locomotor behavioral rhythms, and by histochemically assessing beta-galactosidase levels in transgenics carrying different kinds of per-lacZ fusion genes. The results suggest that per contains multipartite regulatory information for dosage compensation within the large first intron and also within the 3' half of this genetic locus.

Phase shifting of the circadian clock by induction of the Drosophila period protein.

Virtually all organisms manifest circadian (24-hour) rhythms, governed by an ill-defined endogenous pacemaker or clock. Several lines of evidence suggest that the Drosophila melanogaster period gene product PER is a clock component. If PER were central to the time-keeping mechanism, a transient increase in its concentration would cause a stable shift in the phase of the clock. Therefore, transgenic flies bearing a heat-inducible copy of PER were subjected to temperature pulses. This treatment caused long-lasting phase shifts in the locomotor activity circadian rhythm, a result that supports the contention that PER is a bona fide clock component.

The analysis of new short-period circadian rhythm mutants suggests features of D. melanogaster period gene function.

A number of new period gene (per) mutants were generated by in vitro mutagenesis and germ line transformation. Missense mutations were made at amino acid 589, which is altered in the 19 h short-period (per(s)) mutant, and insertion mutations were generated with peptides commonly used for epitope tagging. Most of these new per mutants had short behavioral rhythms. Flies with heteroallelic combinations of these new mutant per genes were found to have "hybrid" periods, i.e., they had values that were usually in between those of the individual alleles. These findings suggest that short-period per mutants are not unusual gain-of-function mutants but rather more traditional loss-of-function mutants that are unable to influence the circadian pacemaker in a proper manner. The data also suggest that the per protein may engage in important intermolecular interactions.

Molecular transfer of a species-specific behavior from Drosophila simulans to Drosophila melanogaster.

Drosophila males modulate the interpulse intervals produced during their courtship songs. These song cycles, which are altered by mutations in the clock gene period, exhibit a species-specific variation that facilitates mating. We have used chimeric period gene constructs from Drosophila melanogaster and Drosophila simulans in germline transformation experiments to map the genetic control of their song rhythm difference to a small segment of the amino acid encoding information within this gene.

Viral growth, origin binding, and p53 binding properties of simian virus 40 large T antigen transformation and replication mutants.

The viability, p53 binding, and SV40 origin binding of a series of SV40 large T antigen point mutants, which map to the amino terminal one-third of the molecule, were examined. Two mutants which yield small plaques were found to have altered kinetics of replication upon infection of permissive cells. Mutants which did not bind to the origin of replication were not able to replicate, but the reverse was not always true. Replication defective mutants which bound the SV40 origin were found; these map both inside and outside of the origin binding domain. All the transformation defective mutants bound the cellular protein, p53.

Replication and transformation functions of in vitro-generated simian virus 40 large T antigen mutants.

We used sodium bisulfite mutagenesis to introduce point mutations within the early region of the simian virus 40 genome. Seventeen mutants which contained amino acid changes in the amino-terminal half of the large T antigen coding sequence were assayed for their ability to replicate viral DNA and to induce transformation in the established rodent cell line Rat-3. The mutants fell into four basic classes with respect to these two biological functions. Five mutants had wild-type replication and transformation activities, six were totally defective, three were replication deficient and transformation competent, and two were replication competent and transformation deficient. Within these classes were mutants which displayed intermediate phenotypes, such as four mutants which were not totally deficient in viral replication or cellular transformation but instead showed reduced large T antigen function relative to wild type. Three large T mutants displayed transforming activity that was greater than that of wild type and are called supertransforming mutants. Of the most interest are mutants differentially defective in replication and transformation activities. These results both support and extend previous findings that two important biological functions of large T antigen can be genetically separated.