Isolation and characterization of the ecdysone receptor and its heterodimeric partner ultraspiracle through development in Sciara coprophila.

Regulation of DNA replication is critical, and loss of control can lead to DNA amplification. Naturally occurring, developmentally regulated DNA amplification occurs in the DNA puffs of the late larval salivary gland giant polytene chromosomes in the fungus fly, Sciara coprophila. The steroid hormone ecdysone induces DNA amplification in Sciara, and the amplification origin of DNA puff II/9A contains a putative binding site for the ecdysone receptor (EcR). We report here the isolation, cloning, and characterizing of two ecdysone receptor isoforms in Sciara (ScEcR-A and ScEcR-B) and the heterodimeric partner, ultraspiracle (ScUSP). ScEcR-A is the predominant isoform in larval tissues and ScEcR-B in adult tissues, contrary to the pattern in Drosophila. Moreover, ScEcR-A is produced at amplification but is absent just prior. We discuss these results in relation to the model of ecdysone regulation of DNA amplification.

Initiation of DNA replication in multicellular eukaryotes.

Three questions central to understanding the initiation of DNA replication in eukaryotes are: (1) Does DNA synthesis begin at a defined place? (2) What determines replication initiation sites? (3) What regulates an origin to fire only once per cell cycle? A key player in this is the origin recognition complex (ORC), required for assembly of the pre-replication complex (pre-RC), that is converted later to the initiation complex (IC). In both yeast ARS1 and DNA puff II/9A of the metazoan fly Sciara, there is a defined start site of replication adjacent to an ORC-binding site. Although ORC has some inherent preference for certain DNA sequences, other factors may also modulate its binding to DNA. The preferred site where DNA synthesis starts at Sciara II/9A and the boundaries of the initiation zone change during development, when DNA puff amplification occurs. The position of the initiation zone may be influenced by the transcriptional machinery and/or chromatin structure. With regard to the third question, rereplication of the whole genome in yeast occurs when components of the pre-RC are stabilized by mutation. In contrast, a locus-specific amplification factor probably exists to account for site-specific DNA amplification in flies.

Two splice variants of Nopp140 in Drosophila melanogaster.

The Nopp140 gene of Drosophila maps within 79A5 of chromosome 3. Alternative splicing yields two variants. DmNopp140 (654 residues) is the sequence homolog of vertebrate Nopp140. Its carboxy terminus is 64% identical to that of the prototypical rat Nopp140. DmNopp140-RGG (688 residues) is identical to DmNopp140 throughout its first 551 residues, but its carboxy terminus contains a glycine/arginine-rich domain that is often found in RNA-binding proteins such as vertebrate nucleolin. Both Drosophila variants localize to nucleoli in Drosophila Schneider II cells and Xenopus oocytes, specifically within the dense fibrillar components. In HeLa cells, DmNopp140-RGG localizes to intact nucleoli, whereas DmNopp140 partitions HeLa nucleoli into phase-light and phase-dark regions. The phase-light regions contain DmNopp140 and endogenous fibrillarin, whereas the phase-dark regions contain endogenous nucleolin. When coexpressed, both Drosophila variants colocalize to HeLa cell nucleoli. Both variants fail to localize to endogenous Cajal bodies in Xenopus oocyte nuclei and in HeLa cell nuclei. Endogenous HeLa coilin, however, accumulates around the periphery of phase-light regions in cells expressing DmNopp140. The carboxy truncation (DmNopp140DeltaRGG) also fails to localize to Cajal bodies, but it forms similar phase-light regions that peripherally accumulate endogenous coilin. Conversely, we see no unusual accumulation of coilin in cells expressing DmNopp140-RGG.