The Drosophila clock gene double-time encodes a protein closely related to human casein kinase Iepsilon

The cloning of double-time (dbt) is reported. DOUBLETIME protein (DBT) is most closely related to human casein kinase Iepsilon. dbtS and dbtL mutations, which alter period length of Drosophila circadian rhythms, produce single amino acid changes in conserved regions of the predicted kinase. dbtP mutants, which eliminate rhythms of per and tim expression and constitutively overproduce hypophosphorylated PER proteins, abolish most dbt expression. dbt mRNA appears to be expressed in the same cell types as are per and tim and shows no evident oscillation in wild-type heads. DBT is capable of binding to PER in vitro and in Drosophila cells, suggesting that a physical association of PER and DBT regulates PER phosphorylation and accumulation in vivo.

Comparison of chromosomal DNA composing timeless in Drosophila melanogaster and D. virilis suggests a new conserved structure for the TIMELESS protein

Two proteins, TIM and PER, physically interact to control circadian cycles of tim and per transcription in Drosophila melanogaster. In the present study the structure of TIM protein expressed by D. virilis was determined by isolation and sequence analysis of genomic DNA (gDNA) corresponding to the D. virilis tim locus (v tim ). Comparison of v tim and m tim gDNA revealed high conservation of the TIM protein. This contrasts with poor sequence conservation previously observed for the TIM partner protein PER in these species. Inspection of the v tim sequence suggests an alternative structure for most TIM proteins. Sequences forming an intron in a previously characterized D. melanogaster tim cDNA appear to be most often translated to produce a longer TIM protein in both species. The N-terminal sequence of vTIM and sequence analysis of genomic DNA from several strains of D. melanogaster suggest that only one of two possible translation initiation sites found in tim mRNA is sufficient to generate circadian rhythms in D. melanogaster. TIM translation may be affected by multiple AUG codons that appear to have been conserved in sequences composing the 5'-untranslated tim mRNA leader.

Diverse roles for the Notch receptor in the development of D. melanogaster

Notch proteins appear to be involved in cell fate commitments with deep evolutionary roots. Homologues have been shown to play key roles in the development of nematodes, insects, amphibia, and mammals. Activity of the Notch receptor has been observed in the patterning of ectoderm, mesoderm, and endoderm, indicating an origin prior to the functional differentiation of these germ layers. To understand how a single receptor can participate so widely in development, we have been examining the role of specific extracellular segments of Notch. Early studies of mutations affecting widely separated EGF-like elements of Notch first raised the possibility for interaction with multiple ligands. Biochemical approaches, and exhaustive structure function studies in transgenic Drosophila are beginning to reveal how this receptor is activated, and point to a range of physical interactions with other proteins.

Regulation of nuclear entry of the Drosophila clock proteins period and timeless

Two genes, period (per) and timeless (tim), are essential for circadian rhythmicity in Drosophila. The encoded proteins (PER and TIM) physically interact. Here, it is shown that TIM and PER accumulate in the cytoplasm when independently expressed in cultured (S2) Drosophila cells. However, the proteins move to the nuclei of these cells if coexpressed. Domains of PER and TIM have been identified that block nuclear localization of the monomeric proteins. In vitro protein interaction studies indicate that the sequence inhibiting the nuclear accumulation of PER forms a binding site for TIM. The results indicate a mechanism for controlled nuclear localization in which suppression of cytoplasmic localization is accomplished by direct interaction of PER and TIM. No other clock functions are required for nuclear localization. The findings suggest that a checkpoint in the circadian cycle is established by requiring cytoplasmic assembly of a PER/TIM complex as a condition for nuclear transport of either protein.

Light-induced degradation of TIMELESS and entrainment of the Drosophila circadian clock

Two genes, period (per) and timeless (tim), are required for production of circadian rhythms in Drosophila. The proteins encoded by these genes (PER and TIM) physically interact, and the timing of their association and nuclear localization is believed to promote cycles of per and tim transcription through an autoregulatory feedback loop. Here it is shown that TIM protein may also couple this molecular pacemaker to the environment, because TIM is rapidly degraded after exposure to light. TIM accumulated rhythmically in nuclei of eyes and in pacemaker cells of the brain. The phase of these rhythms was differentially advanced or delayed by light pulses delivered at different times of day, corresponding with phase shifts induced in the behavioral rhythms.

Positional cloning and sequence analysis of the Drosophila clock gene, timeless

The Drosophila genes timeless (tim) and period (per) interact, and both are required for production of circadian rhythms. Here the positional cloning and sequencing of tim are reported. The tim gene encodes a previously uncharacterized protein of 1389 amino acids, and possibly another protein of 1122 amino acids. The arrhythmic mutation tim01 is a 64-base pair deletion that truncates TIM to 749 amino acids. Absence of sequence similarity to the PER dimerization motif (PAS) indicates that direct interaction between PER and TIM would require a heterotypic protein association.

Isolation of timeless by PER protein interaction: defective interaction between timeless protein and long-period mutant PERL

The period (per) gene likely encodes a component of the Drosophila circadian clock. Circadian oscillations in the abundance of per messenger RNA and per protein (PER) are thought to arise from negative feedback control of per gene transcription by PER. A recently identified second clock locus, timeless (tim), apparently regulates entry of PER into the nucleus. Reported here are the cloning of complementary DNAs derived from the tim gene in a two-hybrid screen for PER-interacting proteins and the demonstration of a physical interaction between the tim protein (TIM) and PER in vitro. A restricted segment of TIM binds directly to a part of the PER dimerization domain PAS. PERL, a mutation that causes a temperature-sensitive lengthening of circadian period and a temperature-sensitive delay in PER nuclear entry, exhibits a temperature-sensitive defect in binding to TIM. These results suggest that the interaction between TIM and PER determines the timing of PER nuclear entry and therefore the duration of part of the circadian cycle.

Rhythmic expression of timeless: a basis for promoting circadian cycles in period gene autoregulation

The clock gene timeless (tim) is required for circadian rhythmicity in Drosophila. The accumulation of tim RNA followed a circadian rhythm, and the phase and period of the tim RNA rhythm were indistinguishable from those that have been reported for per. The tim RNA oscillations were found to be dependent on the presence of PER and TIM proteins, which demonstrates feedback control of tim by a mechanism previously shown to regulate per expression. The cyclic expression of tim appears to dictate the timing of PER protein accumulation and nuclear localization, suggesting that tim promotes circadian rhythms of per and tim transcription by restricting per RNA and PER protein accumulation to separate times of day.

Suppression of PERIOD protein abundance and circadian cycling by the Drosophila clock mutation timeless

The timeless mutation (tim) leads to loss of circadian behavioral rhythms in Drosophila melanogaster. The effects of tim on rhythmicity involve interactions with period (per), a second essential clock gene, as the tim mutation suppresses circadian oscillations of per transcription and blocks nuclear localization of a PER reporter protein. In the present study it was found that the tim mutant constitutively produces a low level of PER protein that is comparable with that produced late in the day by wild-type flies. In addition, it was shown that tim suppresses circadian cycling of PER protein abundance and circadian regulation of PER phosphorylation. Transfer of wild-type flies to constant light also suppressed cycling of PER abundance and phosphorylation and produced constitutively low levels of PER. In the tim mutant there was no additional effect of constant light on PER. These results suggest that constant light and the tim mutation produce related changes in the underlying biological clock. We further suggest that the multiple effects of tim are due to a primary effect on per expression at the posttranscriptional level. The effects of tim on behavioral rhythms and per RNA cycling are therefore likely to involve effects on PER protein through previously proposed feedback mechanisms.

Circadian rhythms in Drosophila can be driven by period expression in a restricted group of central brain cells

Neural tissues controlling circadian rhythmicity have been identified in a variety of organisms and are often closely associated with the visual system. In Drosophila, the clock gene period (per), which is required for circadian rhythms, is expressed in many neurons and glia throughout the eye and brain. We asked whether biological rhythms could be generated if per expression were restricted to a subset of these cells that is involved in photoreception. Here we demonstrate that expression of per under the control of the glass promoter confers both behavioral and molecular rhythmicity. glass is required for development of Drosophila photoreceptors, and this promoter is active in eyes, ocelli, and certain cells of the central brain. When we genetically removed all external photoreceptor cells, rhythms persisted in these transgenic animals. This suggests that a few central brain cells producing glass and per are capable of generating biological rhythms.

Igloo, a GAP-43-related gene expressed in the developing nervous system of Drosophila

GAP-43 (growth-associated protein, 43 × 10(3) M(r)) is an essential, membrane-associated, neuronal phosphoprotein in vertebrates. The protein is abundantly produced in the growth cones of developing and regenerating neurons, and it is phosphorylated upon induction of long-term potentiation (LTP). Prior work has identified GAP-43-like proteins only in chordates. In this paper, a nervous system-specific gene from Drosophila melanogaster is described that encodes two proteins sharing biochemical activities and sequence homology with GAP-43. The region of homology encompasses the calmodulin-binding domain and protein kinase C (PKC) phosphorylation site of GAP-43. The fly proteins are shown to bind Drosophila calmodulin (CaM), and are phosphorylated by purified PKC after a fashion predicted from prior work with vertebrate GAP-43. GAP-43 is modified by palmitoylation. An amino-terminal myristoylation site is described for the Drosophila protein, which may play a similar role in membrane association in the fly. While a small family of GAP-43-related genes has been recognized in vertebrates, only a single gene appears to be present in the fly. As the Drosophila gene encodes two proteins, each with multiple calmodulin-binding domains and repeated sites for PKC phosphorylation, it may afford functions provided by the family of vertebrate genes.

Block in nuclear localization of period protein by a second clock mutation, timeless

In wild-type Drosophila, the period protein (PER) is found in nuclei of the eyes and brain, and PER immunoreactivity oscillates with a circadian rhythm. The studies described here indicate that the nuclear localization of PER is blocked by timeless (tim), a second chromosome mutation that, like per null mutations, abolishes circadian rhythms. PER fusion proteins without a conserved domain (PAS) and some flanking sequences are nuclear in tim mutants. This suggests that a segment of PER inhibits nuclear localization in tim mutants. The tim gene may have a role in establishing rhythms of PER abundance and nuclear localization in wild-type flies.

Loss of circadian behavioral rhythms and per RNA oscillations in the Drosophila mutant timeless

Eclosion, or emergence of adult flies from the pupa, and locomotor activity of adults occur rhythmically in Drosophila melanogaster, with a circadian period of about 24 hours. Here, a clock mutation, timeless (tim), is described that produces arrhythmia for both behaviors. The effects of tim on behavioral rhythms are likely to involve products of the X chromosome-linked clock gene period (per), because tim alters circadian oscillations of per RNA. Genetic mapping places tim on the left arm of the second chromosome between dumpy (dp) and decapentaplegic (dpp).

Rapid sequential walking from termini of cosmid, P1 and YAC inserts

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Further evidence for function of the Drosophila Notch protein as a transmembrane receptor

N locus mutations associated with unusual mutant phenotypes were found to alter the structure of the encoded protein. Two mutations, NCo and N60g11, eliminate much of the cytoplasmic domain. NCo can act as a null allele or as a competitive inhibitor of N+ function, whereas N60g11 produces dominant gain of function in some cell types. This difference in function can be attributed to retention of cdc10/SWI6 repeats in the Notch60g11 protein. The results suggest a role for these repeats in intracellular signaling and are consistent with action of Notch as a receptor. nd3 and l(1)NB alter extracellular epidermal growth factor-like and lin-12/Notch elements, respectively. nd3 eliminates a conserved cysteine residue, so the mutation may result in complete loss of function for a single Notch epidermal growth factor element. N60g11 and l(1)NB produce related gain-of-function phenotypes. It is proposed that l(1)NB produces an extracellular modification of the protein that stimulates aberrant intracellular signaling by the Notch cytoplasmic domain.

Antineurogenic phenotypes induced by truncated Notch proteins indicate a role in signal transduction and may point to a novel function for Notch in nuclei

Loss of any one of several neurogenic genes of Drosophila results in overproduction of embryonic neuroblasts at the expense of epidermoblasts. In this paper a variety of altered Notch proteins are expressed in transgenic flies. Dominant lethal, antineurogenic phenotypes were produced by expression of three classes of mutant proteins: (1) a protein comprised of the cytoplasmic domain of Notch and devoid of sequences permitting membrane association; (2) a transmembrane protein lacking the extracellular, lin12/Notch repeats; and (3) transmembrane proteins carrying amino acid substitutions replacing one or both extracellular cysteines thought to be involved in Notch dimerization. These Notch proteins not only suppress the neural hypertrophy observed in Notch- embryos, but also generate a phenotype in which elements of the embryonic nervous system are underproduced. Action of the intracellular cdc10 repeats appears to be essential for wild-type Notch function or for the antineurogenic activity of these proteins. The activities of the dominant, gain-of-function proteins indicate that Notch functions as a signal transducing receptor during ectoderm development. Production of antineurogenic Notch proteins in embryos deficient for the other neurogenic genes allowed functional dependencies to be established. Delta, mastermind, bigbrain, and neuralized appear to function in elaboration of a signal upstream of Notch. Genes of the Enhancer of split complex act after Notch. The cytoplasmic domain of Notch contains nuclear localization sequences that function in cultured cells, and one of the Notch antineurogenic proteins, the cytoplasmic domain, accumulates in nuclei in vivo.

Single amino acid substitutions in EGF-like elements of Notch and Delta modify Drosophila development and affect cell adhesion in vitro

Notch locus EGF-like element mutations spl, altering eye development, and AxE2, affecting wing and sensilla development, are modified by mutations at Delta. It is shown that two allele-specific suppressors of spl involve single amino acid substitutions in the 4th (Dlsup5) and 9th (Dlsup4) EGF-like elements of the Delta protein. Cultured cells producing spl or AxE2 aggregate with cells producing wild-type Delta or Dlsup5 protein, and Dlsup5-producing cells adhere to cells producing wild-type Notch protein. However, spl,AxE2, and Dlsup5 are each defective in promoting these cell affinities, as none of the mutant proteins can compete with the corresponding wild-type proteins for formation of cell aggregates. Thus, widely separated EGF-like elements of Notch and Delta appear to participate in functional molecular interactions between the proteins. Dlsup5 does not improve adhesiveness of spl in vitro, so suppression in vivo may involve altered developmental signaling by spl-Dlsup5 complexes, rather than modified cell adhesion.

New short period mutations of the Drosophila clock gene per

Earlier work has indicated that the period length of Drosophila circadian behavioral rhythms is dependent on the abundance of the period (per) gene product. Increased expression of this gene has been associated with period shortening for both the circadian eclosion (pupal hatching) rhythm and circadian locomotor activity rhythms of adult Drosophila. In this study it is shown that a wide variety of missense mutations, affecting a region of the per protein consisting of approximately 20 aa, predominantly generate short period phenotypes. The prevalence of such mutations suggests that short period phenotypes may result from loss or depression of function in this domain of the per protein. Possibly mutations in the region eliminate a regulatory function provided by this segment, or substantially increase stability of the mutant protein.

Ontogeny of a biological clock in Drosophila melanogaster

Drosophila melanogaster born and reared in constant darkness exhibit circadian locomotor activity rhythms as adults. However, the rhythms of the individual flies composing these populations are not synchronized with one another. This lack of synchrony is evident in populations of flies commencing development at the same time, indicating that a biological clock controlling circadian rhythmicity in Drosophila begins to function without a requirement for light and without a developmentally imparted phase. It is possible to synchronize the phases of rhythms produced by dark-reared flies with light treatments ending as early as the developmental transition from embryo to first-instar larva: Light treatments occurring at developmental times preceding hatching of the first-instar larva fail to synchronize adult locomotor activity rhythms, while treatments ending at completion of larval hatching entrain these rhythms. The synchronized rhythmic behavior of adult flies receiving such light treatments suggests that a clock controlling circadian rhythms may function continuously from the time of larval hatching to adulthood.

A role for the Drosophila neurogenic genes in mesoderm differentiation

The neurogenic genes of Drosophila have long been known to regulate cell fate decisions in the developing ectoderm. In this paper we show that these genes also control mesoderm development. Embryonic cells that express the muscle-specific gene nautilus are overproduced in each of seven neurogenic mutants (Notch, Delta, Enhancer of split, big brain, mastermind, neuralized, and almondex), at the apparent expense of neighboring, nonexpressing mesodermal cells. The mesodermal defect does not appear to be a simple consequence of associated neural hypertrophy, suggesting that the neurogenic genes may function similarly and independently in establishing cell fates in both ectoderm and mesoderm. Altered patterns of beta 3-tubulin and myosin heavy chain gene expression in the mutants indicate a role for the neurogenic genes in development of most visceral and somatic muscles. We propose that the signal produced by the neurogenic genes is a general one, effective in both ectoderm and mesoderm.