Differential control of gene activity by isoforms A, B1 and B2 of the Drosophila ecdysone receptor.

The steroid hormone ecdysone initiates molting and metamorphosis in Drosophila via a heterodimeric receptor consisting of EcR that binds hormone, and USP, a homolog of the vertebrate RXR receptor. EcR exists in three isoforms EcRA, EcRB1 and EcRB2 that are thought to direct specific physiological responses to ecdysone. These three isoforms differ only in their N-terminal A/B domain that implies that sequences responsible for the differential physiological effects lie within the A/B domains of the EcR isoforms. In the present study, we set out to determine the capability of the three isoforms and their A/B domains to control gene transcription. When full-length EcR plasmids were cotransfected into mammalian cells with a USP expressing and a cognate reporter plasmid, the three EcR isoforms showed striking differences in their ability to control gene transcription, both in the presence and in the absence of hormone. Furthermore, the A/B domains of EcRB1 and of EcRB2 when fused to the GAL4 DNA binding domain are sufficient to activate transcription of a reporter gene, in yeast as well as in mammalian cells. In contrast, a fusion construct containing the A/B domain of EcRA represses basal transcription of the reporter gene. All these findings emphasize the importance of the A/B domains of the three EcR isoforms for differentially controlling gene transcription. Furthermore, they provide evidence for the existence of an autonomous ligand-independent activation function (AF1) in the A/B domains of EcRB1 and EcRB2 and of an inhibitory function (IF) in the A/B domain of EcRA.

Developmental effects of a chimeric ultraspiracle gene derived from Drosophila and Chironomus.

The ultraspiracle (usp) gene encodes a nuclear receptor that forms a heterodimer with the ecdysone receptor (EcR) to mediate transcriptional responses to the insect steroid hormone, 20-hydroxyecdysone (20HE). The responses ultimately elicit changes associated with molting and metamorphosis. Although Ultraspiracle (USP) is required at several developmental times, it is unclear whether USP plays stage-specific roles in Drosophila. A chimeric transgene (d/cusp), produced by replacing the ligand-binding domain (LBD) of Drosophila USP with the equivalent domain from another Diptera, Chironomus tentans, was tested for its ability to rescue Drosophila usp mutants from early larval lethality. A single copy of the d/cusp was sufficient to rescue transformants from several lines through larval development but they died suddenly during the late third instar. Additional doses of d/cusp were required to allow survival through the adult stage, but they did not restore a normal prepupal contraction. Thus, the arrest at the onset of metamorphosis apparently is caused by the impaired ability of the chimeric USP to mediate a stage-specific function associated with the LBD.

Functional characterization of two Ultraspiracle forms (CtUSP-1 and CtUSP-2) from Chironomus tentans.

Two forms, CtUSP-1 and CtUSP-2, of the Chironomus tentans homolog of Ultraspiracle (new nomenclature: Chironomus NR2B4) were described and verified as components of the functional ecdysteroid receptor. The two forms differed from each other in the most N-terminal regions of the A/B domain and were tested for several properties. Both forms showed the ability to heterodimerize with CtEcR and interact with a variety of direct repeat and palindromic EcREs, and both conferred specific ligand binding when heterodimerized with EcR. CtUSP-2 showed a twofold higher ponasterone-binding potential than CtUSP-1. Both USP forms demonstrated the ability to activate ecdysteroid-inducible transcription in HeLa cells and the variations in the A/B domain of these forms were not associated with detectable differences in transcriptional activation. Thus, the two forms function similarly. Among species for which USP forms have been reported, Chironomus is the most closely related one evolutionarily to Drosophila. Despite this proximity, a variety of structural differences were noted in both the A/B and E domains of USP between the two species. The Chironomus USP forms lack many of the amino acid residues associated with the ligand-dependent AF2 transactivation function found in all other RXRs and USPs reported so far.

High level transactivation by the ecdysone receptor complex at the core recognition motif.

Ecdysteroid signaling in insects is mediated by the ecdysone receptor complex that is composed of a heterodimer of the ecdysone receptor and Ultraspiracle. The DNA binding specificity plays a critical role of defining the repertoire of target genes that respond to the hormone. We report here the determination of the preferred core recognition motif by a binding site selection procedure. The consensus sequence consists of a perfect palindrome of the heptameric half-site sequence GAGGTCA that is separated by a single A/T base pair. No binding polarity of the ecdysone receptor/Ultraspiracle heterodimer to the core recognition motif was observed. This core motif mediated the highest level of ligand-induced transactivation when compared to a series of synthetic ecdysone response elements and to the natural element of the Drosophila hsp27 gene. This is the first report of a palindromic sequence identified as the highest affinity DNA binding site for a heterodimeric nuclear hormone receptor complex. We further present evidence that the ligand of the ecdysone receptor preferentially drives Ultraspiracle from a homodimer into a heterodimer. This mechanism might contribute additionally to a tight control of target gene expression.

Expression of EcR and USP in Escherichia coli: purification and functional studies.

The functional ecdysteroid receptor complex consists of a nuclear receptor heterodimer of ecdysteroid receptor (EcR) and ultraspiracle (USP). EcR and USP of both Chironomus tentans and Drosophila melanogaster were expressed in Escherichia coli as fusion proteins with glutathione S-transferase (GST). Cell lysis and protein solubilization with the anionic detergent sarkosyl yielded preparations of EcR and USP with properties similar to those of the endogenous receptors in various respects. The heterodimer of the expressed proteins specifically bound the labeled ecdysteroid (Ec) [3H]ponasterone A. Furthermore, it preferentially recognized the palindromic ecdysone response element (EcRE) PALI. Interestingly, binding to the PAL1 element was also observed for EcR homodimers. USP homodimers, in turn, preferentially bound to the direct repeat element DR1. When incubated with native polytene chromosomes of Chironomus, EcR/USP specifically accumulated at the early Ec-inducible puff site IV-2B.

Immunological studies on the developmental and chromosomal distribution of ecdysteroid receptor protein in Chironomus tentans.

Antisera were raised against different domains of a putative ecdysteroid receptor (cEcRH) of Chironomus tentans. All the antisera reacted with a 68,000 dalton protein exhibiting DNA binding properties. Additionally, we were able to demonstrate that the antisera immunoprecipitate protein which binds a radioactively labeled ecdysteroid (Ec), i.e., [3H]ponasterone A, with high specificity. These properties indicate that the antisera recognize specifically an endogenous ecdysteroid receptor protein (cEcR) in C. tentans cells and thus are suitable for the following quantitative and qualitative immunological and immunohistochemical investigations. The cellular level of cEcR varies during development, and it is particularly low in oligopausing larvae. In polytene chromosomes of prepupal salivary glands, cEcR is located at approximately 50 transcriptionally active loci. These loci include both early ecdysteroid (Ec)-inducible puff sites, such as the locus containing the gene coding for the homolog of the E75 protein in Drosophila melanogaster, as well as late Ec-inducible puff-sites. The latter group comprises a locus of a gene specifying the homolog of the D. melanogaster ultraspiracle protein. However, loci of genes coding for salivary gland secretory proteins (e.g., Balbiani ring forming chromosome regions) do not specifically react with the antisera. Thus, the developmental regulation of these genes is not directly controlled by Ec. Polytene chromosomes of oligopausing larvae show hardly any loci that contain cEcR. The few detected correspond, with few exceptions, to the most potent cEcR binding sites found in prepupae.

afsR2: a previously undetected gene encoding a 63-amino-acid protein that stimulates antibiotic production in Streptomyces lividans.

Earlier work has shown that the afsR genetic locus promotes formation of the pigmented antibiotics actinorhodin and undecylprodigiosin in Streptomyces lividans and its close relative, Streptomyces coelicolor. A protein designated as AfsR has been implicated in this activity. We report here the existence of a previously unknown gene, afsR2, which is separate from and adjacent to the AfsR-encoding sequence and which, when present at high copy number, (i) stimulates transcription of biosynthetic and regulatory genes in the actinorhodin gene cluster (act), and (ii) stimulates the synthesis of undecylprodigiosin. We show that the effects of afsR2 on actinorhodin synthesis are mediated through transcription of the actII-ORF4 locus, which encodes a transcriptional activator of other genes in the act cluster. Analysis of the cloned afsR2 gene indicates that its activity is the result of the 63-amino-acid protein it specifies.

The chromosomal integration site for the Streptomyces plasmid SLP1 is a functional tRNA(Tyr) gene essential for cell viability.

The genetic element SLP1 exists in nature as a single DNA segment integrated into the genome of Streptomyces coelicolor. Upon mating with Streptomyces lividans, a closely related species, SLP1 undergoes precise excision from its chromosomal site and is transferred into the recipient where it integrates chromosomally. Previous work has shown that integration and excision involve site-specific recombination between a chromosomal site, attB, and a virtually identical sequence, attP, on SLP1. We demonstrate here by means of gene replacement that a tRNA(Tyr) sequence that overlaps part of the attB site of S. lividans is both biologically functional and essential for cell viability. The requirement for this tRNA gene has been used to stabilize the inheritance of a segrationally unstable plasmid in cells lacking a chromosomal attB site. The evolution of an essential DNA locus as an attachment site for a chromosomally integrating genetic element represents a novel mechanism of biological adaptation.

Extremely large chromosomal deletions are intimately involved in genetic instability and genomic rearrangements in Streptomyces glaucescens.

Genetic instability in Streptomyces glaucescens characteristically involves the occurrence of gross genomic rearrangements including high-level sequence amplification and extensive deletion. We investigated the relationship of the unstable melC and strS loci and a 100 kb region of the chromosome which frequently gives rise to intense heterogeneous DNA amplification. Standard chromosome walking using a cosmid bank in conjunction with a "reverse-blot" procedure enabled us to construct a contiguous genomic BamHI map of the unstable region exceeding 900 kb. The unstable genes and the amplifiable region (AUD locus) are physically linked within a 600 kb segment of the chromosome. The previously characterized deletions which affect these loci are merely components of much larger deletions ranging from 270 to over 800 kb which are polar in nature, effecting the sequential loss of the strS and melC loci. The more extensive deletions terminate either adjacent to, or in the vicinity of DNA reiterations at the AUD locus. Additionally, a deletion junction fragment and the corresponding deletion ends were cloned and analysed at the sequence level.

Characterisation of the hydroxystreptomycin phosphotransferase gene (sph) of Streptomyces glaucescens: nucleotide sequence and promoter analysis.

The nucleotide sequence of a 1384 bp fragment containing the coding and promoter sequences of the streptomycin phosphotransferase gene (sph) of the hydroxystreptomycin-producing Streptomyces glaucescens was determined. Evidence for an ATG as translation start codon for sph was derived from a comparison with the amino-terminal amino acid sequence of an aminoglycoside phosphotransferase (aphD gene product) of S. griseus, exhibiting a high degree of amino acid homology to the deduced amino acid sequence of the S. glaucescens sph gene product. Transcriptional start and termination sites for the sph gene were identified by primer extension and/or nuclease S1 mapping experiments. The promoter region of the sph gene appears to be complex since tandemly arranged promoters (orfIp1, orfIp2) initiating transcription of a likely coding region (ORFI) in the opposite direction overlap sph promoter sequences. The presumptive sphp and orfIp1 promoters show considerable sequence similarities in the -10 region to Escherichia coli consensus promoter sequences but no homology to E. coli or Streptomyces -35 regions.

Streptomycin-sensitivity in Streptomyces glaucescens is due to deletions comprising the structural gene coding for a specific phosphotransferase.

The wild type strain of Streptomyces glaucescens produces hydroxystreptomycin and has a natural resistance towards the streptomycin group aminoglycoside antibiotics. The inherent resistance is a genetically unstable character and mutant strains sensitive to streptomycins arise spontaneously at unusually high frequencies. The gene conferring streptomycin resistance was cloned and characterised as a streptomycin specific phosphotransferase. Hybridisation experiments show that the mutational event leading to sensitivity is due to large deletions, most likely on the chromosome, comprehending the structural gene coding for a streptomycin phosphotransferase and its flanking regions. Interspecific expression of the S. glaucescens phosphotransferase was found in Streptomyces lividans as well as in Escherichia coli.