The Drosophila clock gene per affects intercellular junctional communication

The per locus of Drosophila has been implicated in the control of behavioural rhythms. In fruitfly embryos and larvae per is expressed in salivary glands. Per mutations have striking effects on intercellular communication in salivary glands: gap junction channels are modulated so that their conductance varies inversely with the period of behavioural rhythms in the mutants. A similar effect on junctional communication in the nervous system may explain how per influences behavioural rhythms.     

Chromosome cohesion is regulated by a clock gene paralogue TIM-1

Faithful transmission of the genome requires that a protein complex called cohesin establishes and maintains the regulated linkage between replicated chromosomes before their segregation. Here we report the unforeseen participation of Caenorhabditis elegans TIM-1, a paralogue of the Drosophila clock protein TIMELESS, in the regulation of chromosome cohesion. Our biochemical experiments defined the C. elegans cohesin complex and revealed its physical association with TIM-1. Functional relevance of the interaction was demonstrated by aberrant mitotic chromosome behaviour, embryonic lethality and defective meiotic chromosome cohesion caused by the disruption of either TIM-1 or cohesin. TIM-1 depletion prevented the assembly of non-SMC (structural maintenance of chromosome) cohesin subunits onto meiotic chromosomes; however, unexpectedly, a partial cohesin complex composed of SMC components still loaded. Further disruption of cohesin activity in meiosis by the simultaneous depletion of TIM-1 and an SMC subunit decreased homologous chromosome pairing before synapsis, revealing a new role for cohesin in metazoans. On the basis of comparisons between TIMELESS homologues in worms, flies and mice, we propose that chromosome cohesion, rather than circadian clock regulation, is the ancient and conserved function for TIMELESS-like proteins.     

Action potential mutations stop a biological clock in Drosophila

The Drosophila melanogaster male produces a species-specific courtship song by wing vibration. The most conspicuous feature of the song is a series of pulses with a 30-40-ms interpulse interval (IPI) which oscillate in wild-type males with a period of 50-60 s. This short-term biological rhythm in IPI is influenced by several gene mutations at the period (per) locus, which alter the normal 24-h free-running period of the circadian clock and have corresponding effects on the song cycle. The present study reveals that, under restrictive conditions, temperature-sensitive mutations which affect neuronal membrane excitability seem to stop the biological clock underlying the fruitfly's song rhythm.     

A conserved DNA sequence in homoeotic genes of the Drosophila Antennapedia and bithorax complexes

A repetitive DNA sequence has been identified in the Drosophila melanogaster genome that appears to be localized specifically within genes of the bithorax and Antennapedia complexes that are required for correct segmental development. Initially identified in cloned copies of the genes Antennapedia, Ultrabithorax and fushi tarazu, the sequence is also contained within two other DNA clones that have characteristics strongly suggesting that they derive from other homoeotic genes.     

Deformed autoregulatory element from Drosophila functions in a conserved manner in transgenic mice.

The striking similarities in the structure, organization and anterior-posterior expression patterns between the murine Hox gene system and the Drosophila homeotic gene complexes, called HOM-C (ref. 3), may point to highly conserved mechanisms for specifying positional identities (reviewed in ref. 4). Strong support for this concept lies in the observation of conserved colinearity between the genomic order of the Hox/HOM genes and their unique successive expression domains along the anterior-posterior axes of both mouse and fly embryos. These unique and precise expression patterns appear to be facilitated by multiple cis-regulatory elements (reviewed in ref. 5). One of the few elements characterized in detail is the autoregulatory enhancer of the homeotic gene Deformed (Dfd), which supports expression in subregions of posterior head segments of Drosophila embryos. Here we present evidence that this enhancer is capable of conferring reporter gene expression to a discrete subregion of the hindbrain in transgenic mouse embryos. Remarkably, this anterior-posterior subregion lies within the common anterior expression domain of the Dfd cognate Hox genes in the postotic hindbrain. Our results indicate that the Dfd autoregulatory enhancer is part of a highly conserved mechanism for establishing region-specific gene expression along the anterior-posterior axis of the embryo.     

Dependence of position-effect variegation in Drosophila on dose of a gene encoding an unusual zinc-finger protein

Position-effect variegation is the inactivation in some cells of a gene translocated next to heterochromatin, the region of the chromosome that is permanently condensed. The number of copies of the Drosophila gene Suvar(3)7 is a dose-limiting factor in this phenomenon, and seems from its sequence that it encodes a protein with five widely spaced zinc-fingers. This novel arrangement of zinc-fingers could help in packaging the chromatin fibre into heterochromatin, and also reflect a novel method of controlling the expression from DNA domains.     

Isolation of a gene from Drosophila by complementation in yeast

Transformation of mutant yeast cells by cloned genomic DNA from a higher eukaryote has made it possible to isolate a Drosophila DNA sequence that complements a yeast adenine-8-mutation. A 0.8-kilobase poly(A)-containing RNA is transcribed from the cloned Drosophila segment in transformed yeast cells and can account for functional expression of the gene.     

An unusual DNA structure detected in a telomeric sequence under superhelical stress and at low pH

Telomeric sequences of DNA, which are found at the ends of linear chromosomes, have been attracting attention as potential sites for the formation of unusual DNA structures. They consist of (GnTm) or (GnATm) motifs (n greater than or equal to m) and, in the single-stranded state, form hairpins stabilized by non-canonical G.G pairs. In the duplex state and under superhelical stress they exhibit hypersensitivity to SI nuclease which by analogy with homopurine-homopyrimidine sequences may reflect the formation of an unusual structure. To determine whether this is the case we have inserted into a plasmid the Tetrahymena telomeric motif (G4T2).(A2C4) and probed it by two-dimensional gel electrophoresis, chemical modification and oligonucleotide binding. Our data demonstrate that, under superhelical stress and at low pH, the insert does indeed adopt a novel DNA conformation. We have concluded that in this structure the C-rich strand forms a hairpin stabilized by non-Watson-Crick base pairs C.C+ and A.A+, whereas the G-rich strand remains unstructured. We term this new DNA structure the (C,A)-hairpin.     

An unusual oviraptorosaurian dinosaur from China

Oviraptorosaurians are an unusual group of theropod dinosaurs, with highly specialized skulls. Here we report a new oviraptorosaurian, Incisivosaurus gauthieri, gen. et sp. nov., from the lowest part of the Lower Cretaceous Yixian Formation of China. This oviraptorosaurian displays a number of characters closer to more typical theropods, such as a low skull and toothed jaws, thus greatly reducing the morphological gap between oviraptorosaurs and other theropods. Incisivosaurus has a pair of premaxillary teeth resembling rodent incisors and small, lanceolate cheek teeth with large wear facets. These dental features were previously unknown among theropods and suggest a herbivorous diet. The new discovery provides a case of convergent evolution and demonstrates that non-avian theropods were much more diverse ecologically than previously suspected.