Epidermal tendon cells require Broad Complex function for correct attachment of the indirect flight muscles in Drosophila melanogaster.

Drosophila Broad Complex, a primary response gene in the ecdysone cascade, encodes a family of zinc-finger transcription factors essential for metamorphosis. Broad Complex mutations of the rbp complementation group disrupt attachment of the dorsoventral indirect flight muscles during pupal development. We previously demonstrated that isoform BRC-Z1 mediates the muscle attachment function of rbp(+) and is expressed in both developing muscle fibers and their epidermal attachment sites. We now report two complementary studies to determine the cellular site and mode of action of rbp(+) during maturation of the myotendinous junctions of dorsoventral indirect flight muscles. First, genetic mosaics, produced using the paternal loss method, revealed that the muscle attachment phenotype is determined primarily by the genotype of the dorsal epidermis, with the muscle fiber and the ventral epidermis exerting little or no influence. When the dorsal epidermis was mutant, the vast majority of muscles detached or chose ectopic attachment sites, regardless of the muscle genotype. Conversely, wild-type dorsal epidermis could support attachment of mutant muscles. Second, ultrastructural analysis corroborated and extended these results, revealing defective and delayed differentiation of rbp mutant epidermal tendon cells in the dorsal attachment sites. Tendon cell processes, the stress-bearing links between the epidermis and muscle, were reduced in number and showed delayed appearance of microtubule bundles. In contrast, mutant muscle and ventral epidermis resembled the wild type. In conclusion, BRC-Z1 acts in the dorsal epidermis to ensure differentiation of the myotendinous junction. By analogy with the cell-cell interaction essential for embryonic muscle attachment, we propose that BRC-Z1 regulates one or more components of the epidermal response to a signal from the developing muscle.

The steroid hormone 20-hydroxyecdysone enhances neurite growth of Drosophila mushroom body neurons isolated during metamorphosis.

Mushroom bodies (MBs) are symmetrically paired neuropils in the insect brain that are of critical importance for associative olfactory learning and memory. In Drosophila melanogaster, the MB intrinsic neurons (Kenyon cells) undergo extensive reorganization at the onset of metamorphosis. A phase of rapid axonal degeneration without cell death is followed by axonal regeneration. This re-elaboration occurs as levels of the steroid hormone 20-hydroxyecdysone (20E) are rising during the pupal stage. Based on the known role of 20E in directing many features of CNS remodeling during insect metamorphosis, we hypothesized that the outgrowth of MB axonal processes is promoted by 20E. Using a GAL4 enhancer trap line (201Y) that drives MB-restricted reporter gene expression, we identified Kenyon cells in primary cultures dissociated from early pupal CNS. Paired cultures derived from single brains isolated before the 20E pupal peak were incubated in medium with or without 20E for 2-4 d. Morphometric analysis demonstrated that MB neurons exposed to 20E had significantly greater total neurite length and branch number compared with that of MB neurons grown without hormone. The relationship between branch number and total neurite length remained constant regardless of hormone treatment in vitro, suggesting that 20E enhances the rate of outgrowth from pupal MB neurons in a proportionate manner and does not selectively increase neuritic branching. These results implicate 20E in enhancing axonal outgrowth of Kenyon cells to support MB remodeling during metamorphosis.

Parallel molecular genetic pathways operate during CNS metamorphosis in Drosophila.

Insect metamorphosis provides a valuable model for studying mechanisms of steroid hormone action on the nervous system during a dynamic phase of functional remodeling. The Drosophila Broad Complex (BRC) holds a pivotal position in the gene expression cascade triggered by the molting hormone 20-hydroxyecdysone (20E) at the onset of metamorphosis. We previously demonstrated that the BRC, which encodes a family of zinc-finger transcription factors, is essential for transducing 20E signals into the morphogenetic movements and cellular assembly that alter the CNS from juvenile to adult form and function. We set out to examine the relationship of BRC to two other genes, IMP-E1 and Deformed (Dfd), involved in the metamorphic transition of the CNS. Representatives of the whole family of BRC transcript isoforms accumulate in the CNS during the larval-to-pupal transition and respond directly to 20E in vitro. IMP-E1 is also directly regulated by 20E, but its induction is independent of BRC, revealing that 20E works through at least two pathways in the CNS. DFD expression is also independent of BRC function. Surprisingly, BRC and DFD proteins are expressed in distinct, nonoverlapping subsets of neuronal nuclei of the subesophageal ganglion even though both are required for its migration into the head capsule. This suggests that the segment identity and ecdysone cascades operate in parallel to control region-specific reorganization during metamorphosis.

A juvenile hormone agonist reveals distinct developmental pathways mediated by ecdysone-inducible broad complex transcription factors.

Juvenile hormone (JH) is an important regulator of insect development that, by unknown mechanisms, modifies molecular, cellular, and organismal responses to the molting hormone, 20-hydroxyecdysone (20E). In dipteran insects such as Drosophila, JH or JH agonists, administered at times near the onset of metamorphosis, cause lethality. We tested the hypothesis that the JH agonist methoprene acts by interfering with function of the Broad Complex (BRC), a 20E-regulated locus encoding BTB/POZ-zinc finger transcription factors essential for metamorphosis of many tissues. We found that methoprene, administered by feeding or by topical application, disrupts the metamorphic reorganization of the central nervous system, salivary glands, and musculature in a dose-dependent manner. As we predicted, methoprene phenocopies a subset of previously described BRC defects; it also phenocopies Deformed and produces abnormalities not associated with known mutations. Interestingly, methoprene specifically disrupts those metamorphic events dependent on the combined action of all BRC isoforms, while sparing those that require specific isoform subsets. Thus, our data provide independent pharmacological evidence for the model, originally based on genetic studies, that BRC proteins function in two developmental pathways. Mutations of Methoprene-tolerant (Met), a gene involved in the action of JH, protect against all features of the "methoprene syndrome." These findings have allowed us to propose novel alternative models linking BRC, juvenile hormone, and MET.

Identification of a broad complex-regulated enhancer in the developing visual system of Drosophila.

During metamorphosis, the central nervous system (CNS) is reconstructed through the concerted action of cell birth, death, and remodeling, so that it can serve the novel and complex behavioral needs of the adult insect. In Drosophila, Broad Complex (BRC) zinc-finger transcription factors are essential for many aspects of metamorphosis, including reorganization of the CNS. In particular, we showed previously that some mutant alleles disrupt the assembly of visual system synaptic neuropils. Using an enhancer-detector screen, we have now identified a candidate BRC target gene, H217, that is normally expressed in visual system neural precursor cells of the inner proliferative center. Moreover, the P-element insertion in the H217 line has caused a hypomorphic mutation in an essential gene, with an optic lobe disorganization phenotype very similar to that seen in BRC mutants. In BRC mutants of the br complementation group (but not in rbp or 2Bc mutants), the H217 enhancer is ectopically expressed in lamina precursor cells (LPCs) whose proliferation is regulated by signals from photoreceptor axons. As predicted by the current model of BRC structure-function relationships, we demonstrated that BRC-Z2 isoforms, when induced during the third larval instar, can repress H217 enhancer activity in the LPCs, whereas BRC-Z3 cannot. Taken together, the data suggest that the H217 P element has tagged an essential gene repressed by BRC-Z2 in LPCs and required for the normal architecture of the retinotopically connected visual system neuropils.

Broad-complex transcription factors regulate thoracic muscle attachment in Drosophila.

The Broad-Complex, a 20-hydroxyecdysone-regulated gene, is essential for the development of many tissues during metamorphosis. In Broad-Complex mutants of the rbp complementation group, dorsoventral indirect flight muscles (DVM) are largely absent, and the dorsal longitudinal indirect flight muscles, tergotrochanteral muscles, and remaining DVM often select incorrect attachment sites. The Broad-Complex encodes a family of zinc-finger-containing transcription factors, and it is hypothesized that Broad Complex proteins containing the Z1 zinc-finger pair (BRC-Z1) mediate rbp+ function. We provide additional strong support for this hypothesis by showing that heat-shock-induced BRC-Z1 expression rescues the thoracic muscle defects of rbp mutants completely. BRC-Z4 induction can also rescue the thoracic musculature, but BRC-Z2 and -Z3 can not. Thus, the effect is specific to BRC-Z1 and its closest relative, BRC-Z4. Formation of muscle primordia from imaginal myoblasts appears normal in rbp mutants. However, the myotendinous junctions linking the DVM to the dorsal epidermis are weak, and the muscles detach during pupal life and subsequently degenerate. The data indicate that rbp mutations disrupt the cell-cell interactions between developing muscles and epidermal tendon cells as they recognize and attach to one another. Using a BRC-Z1-specific monoclonal antibody, we show that both the developing muscles and epidermal tendon cells express BRC-Z1 at the time of pupation, before mutant muscles begin to detach. We conclude that 20-hydroxyecdysone acts through the Broad-Complex to control the development of thoracic myotendinous junctions.

Remodeling of the insect nervous system.

Our nervous systems and behavior are shaped by hormonally driven developmental changes that continue beyond the embryonic period. Key insights into this process have emerged from studies of the insect nervous system. During insect metamorphosis, the nervous system is remodeled through postembryonic neurogenesis, programmed cell death and the modification of persistent neurons. These changes are regulated to a large degree by gene cascades that are triggered by steroid hormones, the ecdysteroids. Current studies are attempting to reveal the molecular mechanisms involved in regulating these dramatic examples of developmental plasticity.

Two Drosophila regulatory genes, deformed and the Broad-Complex, share common functions in development of adult CNS, head, and salivary glands.

Deformed (Dfd), a homeotic selector gene required for segment identity in the head, and the Broad-Complex (BR-C), a steroid hormone-regulated locus required for metamorphosis of the epidermis and multiple internal tissues, are members of distinct genetic regulatory hierarchies. Their protein products contain DNA-binding domains (of the homeodomain and zinc-finger variety, respectively) and are believed to act by regulating the transcription of target genes. In this study we demonstrate that Dfd and BR-C mutants dying during metamorphosis share defects of CNS reorganization, ventral adult head development, and adult salivary gland morphogenesis. Specifically, the shared phenotypes are (i) failure to separate the subesophageal ganglion (SEG) from the thoracic ganglion (TG); (ii) structural and functional abnormalities of the proboscis and maxillary palps, innervated by the SEG; and (iii) failure of the adult salivary glands to extend into the thorax. Experiments performed with a conditional allele demonstrate that Dfd+ function during either larval life or metamorphosis is sufficient to rescue the SEG-TG separation phenotype. BR-C;Dfd double mutants show synergistic enhancement of the ventral head defects. This genetic interaction suggests that the segment identity and steroid hormone-sensitive regulatory hierarchies intersect during postembryonic development.

Mutations in a steroid hormone-regulated gene disrupt the metamorphosis of the central nervous system in Drosophila.

The actions of steroid hormones on vertebrate and invertebrate nervous systems include alterations in neuronal architecture, regulation of neuronal differentiation, and programmed cell death. In particular, central nervous system (CNS) metamorphosis in insects requires a precise pattern of exposure to the steroid molting hormone 20-hydroxyecdysone (ecdysterone). To test whether the effects of steroid hormones on the insect nervous system are due to changes in patterns of gene expression, we examined Drosophila mutants of the ecdysterone-regulated locus, the Broad Complex (BR-C). This report documents aspects of CNS reorganization which are dependent on BR-C function. During wild-type metamorphosis, CNS components undergo dramatic morphogenetic movements relative to each other and to the body wall. These movements, in particular, the separation of the subesophageal ganglion from the thoracic ganglion, the positioning of the developing visual system, and the fusion of right and left brain hemispheres, are deranged in BR-C mutants. In addition, a subset of mutants shows disorganization of optic lobe neuropil, both within and among optic lobe ganglia. Optic lobe disorganization is found in mutants of the br and l(1)2Bc complementation groups, but not in those of the rbp complementation group. This suggests that the three complementation groups of this complex locus represent distinct but overlapping functions necessary for normal CNS reorganization. This study demonstrates that ecdysterone-regulated gene expression is essential for CNS metamorphosis, illustrating the utility of Drosophila as a model system for investigating the genetic basis of steroid hormone action on the nervous system.

Poly(A) shortening of coregulated transcripts in Drosophila.

The 71E ecdysterone-regulated puff of Drosophila melanogaster contains a cluster of six coregulated "late" genes which are expressed in the prepupal salivary gland. The resulting transcripts exhibit a decrease in their length during the 12-hr period in which they accumulate. Using the enzyme ribonuclease H, we show that this size decrease is a result of a progressively shorter poly(A) tract and suggest that these transcripts undergo an active sequential shortening of their poly(A) tracts in prepupal salivary glands. It is interesting to note that this shortening precedes the complete loss of these transcripts from the RNA population.

An ecdysterone-responsive puff site in Drosophila contains a cluster of seven differentially regulated genes.

We have determined the molecular organization of an ecdysterone-responsive puff site in Drosophila melanogaster. The 71E puff site contains a tightly linked cluster of at least seven genes within a neighborhood of 10 X 10(3) base-pairs. All the genes are expressed in a tissue-specific manner in either the larval or the prepupal salivary gland. However, these genes can be divided into two groups on the basis of their temporal pattern of transcription. Six of the genes are expressed only in prepupal salivary glands and are arranged as three divergently transcribed pairs. Nestled within this region is one gene expressed primarily in late third-instar salivary glands. We conclude that this developmentally complex puff site contains six members of the ecdysterone-induced "late"-gene set and one member of the ecdysterone-regulated "intermolt" -gene set. Additional complexity is found at the transcript level: a heterogeneously sized population of RNA molecules arises from each of the seven genes.

Effects of UV irradiation on the fate of 5-bromodeoxyuridine-substituted bacteriophage T4 DNA.

We have carried out a series of experiments designed to characterize the impact of UV irradiation (260 nm) on 5-bromodeoxyuridine-labeled (heavy) T4 bacteriophage, both before and after infection of Escherichia coli. In many respects, these effects differ greatly from those previously described for non-density-labeled (light) phage. Moreover, our results have led us to propose a model for a novel mechanism of host-mediated repair synthesis, in which excision of UV-damaged areas is followed by initiation of replication, strand displacement, and a considerable amount of DNA replication. UV irradiation of 5-bromodeoxyuridine-labeled phage results in single-stranded breaks in a linear, dose-dependent manner (1.3 to 1.5 breaks per genomic strand per lethal hit). This damage does not interfere with injection of the phage genome, but some of the UV-irradiated heavy phage DNA undergoes additional intracellular breakdown (also dose dependent). However, a minority (25%) of the injected parental DNA is protected, maintaining its preinjection size. This protected moiety is associated with a replicative complex of DNA and proteins, and is more efficiently replicated than is the parental DNA not so associated. Most of the progeny DNA is also found with the replicative complex. The 5-bromodeoxyuridine of heavy phage DNA is debrominated by UV irradiation, resulting in uracil which is removed by host uracil glycosylase. Unlike the simple gap-filling repair synthesis after infection with UV-irradiated light phage, the repair replication of UV-irradiated heavy phage is extensive as determined by density shift of the parental label in CsC1 gradients. The newly synthesized segments are covalently attached to the parental fragments. The repair replication takes place even in the presence of chloramphenicol, a protein synthesis inhibitor, suggesting it is host mediated. Furthermore, the extent of the repair replication is greater at higher doses of UV irradiation applied to the heavy phage. This abundant synthesis results ultimately in dispersion of the parental sequences as short stretches in the midst of long segments of newly synthesized progeny DNA. Together, the extensive replication and the resulting distribution pattern of parental sequences, without significant solubilization of parental label, are most consistent with a model of repair synthesis in which the leading strand displaces, rather than ligates to, the encountered 5' end.

Partial replication of UV-irradiated T4 bacteriophage DNA results in amplification of specific genetic areas.

Upon infection of Escherichia coli with bromodeoxyuridine-labeled t4 phage that had received 10 lethal hits of UV irradiation, a sizable amount of phage DNA was synthesized (approximately 36 phage equivalent units of DNA per infected bacterium), although very little multiplicity reactivation occurs. This progeny DNA was isolated and analyzed. This DNA was biased in its genetic representation, as shown by hybridization to cloned segments of the T4 genome immobilized on nitrocellulose filters. Preferentially amplified areas corresponded to regions containing origins of T4 DNA replication. The size of the progeny DNA increased with time after infection, possibly due to recombination between partial replicas and nonreplicated subunits or due to the gradual overcoming of the UV damage. As the size of the progeny DNA increased, all of the genes were more equally represented, resulting in a decrease in the genetic bias. Amplification of specific genetic areas was also observed upon infection with UV-irradiated, nonbromodeoxyuridine-substituted (light) phage. However, the genetic bias observed in this case was not as great as that observed with bromodeoxyuridine-substituted phage. This is most likely due to the higher efficiency of multiplicity reactivation of the light phage.