PTP-ER, a novel tyrosine phosphatase, functions downstream of Ras1 to downregulate MAP kinase during Drosophila eye development.

Activation of ERK/MAPK is a key event downstream of RAS. The duration, extent, and timing of MAPK activity is integral to signal specificity. Consequently, inactivation of MAPK by phosphatases has emerged as a critical element in the precise control of signal output. We have cloned and characterized a novel cytoplasmic protein tyrosine phosphatase, PTP-ER, which is related to mammalian PCPTP1, LC-PTP/HePTP, and STEP tyrosine phosphatases. PTP-ER mutants produce extra R7 cells and enhance activated Ras1 signaling. Ectopic expression of PTP-ER dramatically inhibits RAS1/MAPK signaling. PTP-ER binds to and inactivates Drosophila ERK/MAPK; however, it is unable to dephosphorylate and downregulate Drosophila MAPKSevenmaker. Resistance to PTP-ER activity partially accounts for the Sevenmaker mutant phenotype.

Ectopic expression of activated Ras1 induces hyperplastic growth and increased cell death in Drosophila imaginal tissues.

The Drosophila Ras1 gene is required for proper cell fate specification throughout development, and the loss-of-function phenotype of Ras1 suggests an additional role in cell proliferation or survival. A direct role for RAS1 in promoting cell proliferation, however, has not been established. We show that expression of an activated form of RAS1 (RAS1V12) during Drosophila imaginal disc development is sufficient to drive ectopic cell proliferation and hyperplastic tissue growth. In addition, expression of RAS1V12 induces widespread cell death in the imaginal discs, including cells not expressing the transgene, which results in ablation of adult structures. Loss-of-function mutations in the genes encoding RAF, MEK, MAPK and KSR dominantly suppress RAS1V12-induced cell proliferation. Furthermore, two RAS effector loop mutations (E37G and Y40C) that block the RAS-RAF interaction, also suppress RAS1V12-induced proliferation, consistent with a requirement for the MAPK cascade during the RAS1 mitogenic response. These two RAS effector loop mutants, however, retain some activity and can act synergistically with a MAPK gain-of-function mutation, suggesting that RAS1 may also act through signaling pathway(s) distinct from the MAPK cascade.

A screen for genes that function downstream of Ras1 during Drosophila eye development.

Cell-fate specification of the R7 photoreceptor cell is controlled by the sevenless receptor tyrosine kinase (SevRTK) and Ras1, the Drosophila homologue of mammalian H-ras, K-ras and N-ras oncogenes. An activated form of Ras1 expressed under control of the sevenless enhancer/promoter (sev-Ras1V12) induces production of supernumerary R7 photoreceptor cells, which causes the eye to become rough in appearance. To isolate mutations in genes functioning downstream of Ras1, we carried out a screen for dominant suppressors and enhancers of this rough eye phenotype. Approximately 850,000 mutagenized flies were screened, and 282 dominant suppressors and 577 dominant enhancers were isolated. Mutations in the Drosophila homologues of Raf, MEK, MAPK, type I Geranylgeranyl Transferase and Protein Phosphatase 2A were isolated, as were mutations in several novel signaling genes. Some of these mutant genes appear to be general signaling factors that function in other Ras1 pathways, while one seems to be more specific for photoreceptor development. At least two suppressors appear to function either between Ras1 and Raf or in parallel to Raf.

Protein phosphatase 2A positively and negatively regulates Ras1-mediated photoreceptor development in Drosophila.

Protein phosphatase 2A (PP2A), a heterotrimeric serine/threonine phosphatase present in most tissues and cell types, has been implicated in the regulation of cell cycle progression, DNA replication, transcription, and translation. Here we present genetic evidence suggesting that PP2A functions downstream of Ras1 in the Sevenless receptor tyrosine kinase (RTK) signal transduction pathway that specifies R7 photoreceptor cell fate in the developing Drosophila eye. Ras1 and downstream cytoplasmic kinases, Raf, MEK, and MAPK, comprise an evolutionarily conserved cascade that mediates the transmission of signals from RTKs at the plasma membrane to specific factors in the nucleus. Using transgenic flies expressing constitutively activated Ras1 or Raf proteins that function independently of upstream signaling events, we show that a reduction in the dose of the gene encoding the catalytic subunit of PP2A stimulates signaling from Ras1 but impairs signaling from Raf. This suggests that PP2A both negatively and positively regulates the Ras1 cascade by dephosphorylating factors that function at different steps in the cascade.

KSR, a novel protein kinase required for RAS signal transduction.

We have identified and characterized two genes in Drosophila whose products are required for activated RAS to signal with normal efficiency, but do not appear to effect signaling by activated RAF. One encodes the beta subunit of type I geranylgeranyl transferase, a prenylation enzyme essential for targeting RAS to the plasma membrane. The other encodes a protein kinase that we have named kinase suppressor of ras (ksr). By genetic criteria, we show that KSR functions in multiple receptor tyrosine kinase pathways. We have isolated mammalian homologs of KSR that, together with the Drosophila gene, define a novel class of kinases. Our results suggest that KSR is a general and evolutionarily conserved component of the RAS signaling pathway that acts between RAS and RAF.

phyllopod functions in the fate determination of a subset of photoreceptors in Drosophila.

phyllopod (phyl) encodes a novel protein required for fate determination of photoreceptors R1, R6, and R7, the last three photoreceptors to be recruited into the ommatidia of the developing Drosophila eye. Genetic data suggests that phyl acts downstream of Ras1, raf, and yan to promote neuronal differentiation in this subset of photoreceptors. Ectopic expression of phyl in the cone cell precursors mimics the effect of ectopic activation of Ras1, suggesting that phyl expression is regulated by Ras1. phyl is also required for embryonic nervous system and sensory bristle development.

Molecular analysis of the initiation of insect metamorphosis: a comparative study of Drosophila ecdysteroid-regulated transcription.

More than 50 ecdysteroid-regulated Drosophila genes have been described in the literature. These genes were identified using several different ecdysteroid-responsive systems and characterized under a variety of experimental conditions. The diversity of these approaches has made it difficult to compare results and identify common responses to the hormone. As a first step toward characterizing the temporal regulation of these genes by ecdysteroids, we have examined their transcriptional activity throughout third instar larval and prepupal development using a single collection of staged animals. We see four coordinate changes in ecdysteroid-regulated gene activity during third instar larval development, at 78-88 hr, approximately 100 hr, 106-108 hr, and approximately 114 hr after egg laying. A dramatic transition in gene expression occurs at puparium formation, after which the prepupal ecdysteroid pulse induces successive waves of transcription. Our results suggest that several increases in the ecdysteroid titer during third instar larval and prepupal development program a precise temporal progression of gene activity that could direct the appropriate behavioral and developmental changes at the onset of metamorphosis.

The Drosophila Broad-Complex plays a key role in controlling ecdysone-regulated gene expression at the onset of metamorphosis.

During Drosophila third instar larval development, one or more pulses of the steroid hormone ecdysone activate three temporally distinct sets of genes in the salivary glands, represented by puffs in the polytene chromosomes. The intermolt genes are induced first, in mid-third instar larvae; these genes encode a protein glue used by the animal to adhere itself to a solid substrate for metamorphosis. The intermolt genes are repressed at puparium formation as a high titer ecdysone pulse directly induces a small set of early regulatory genes. The early genes both repress their own expression and activate more than 100 late secondary-response genes. The Broad-Complex (BR-C) is an early ecdysone-inducible gene that encodes a family of DNA binding proteins defined by at least three lethal complementation groups: br, rbp, and l(1)2Bc. We have found that the BR-C is critical for the appropriate regulation of all three classes of ecdysone-inducible genes. Both rbp and l(1)2Bc are required for glue gene induction in mid-third instar larvae. In addition, the l(1)2Bc function is required for glue gene repression in prepupae; in l(1)2Bc mutants the glue genes are re-induced by the late prepupal ecdysone pulse, recapitulating a mid-third instar regulatory response at an inappropriate stage in development. The l(1)2Bc function is also required for the complete ecdysone induction of some early mRNAs (E74A, E75A, and BR-C) and efficient repression of most early mRNAs in prepupae. Like the intermolt secondary-response genes, the late secondary-response genes are absolutely dependent on rbp for their induction. An effect of l(1)2Bc mutations on late gene activity can also be detected, but is most likely a secondary consequence of the submaximal ecdysone-induction of a subset of early regulatory products. Our results indicate that the BR-C plays a key role in dictating the stage-specificity of the ecdysone response. In addition, the ecdysone-receptor protein complex alone is not sufficient for appropriate induction of the early primary-response genes, but requires the prior expression of BR-C proteins. These studies define the BR-C as a key regulator of gene activity at the onset of metamorphosis in Drosophila.

Potential role for a FTZ-F1 steroid receptor superfamily member in the control of Drosophila metamorphosis.

FTZ-F1, a member of the steroid receptor superfamily, has been implicated in the activation of the homeobox segmentation gene fushi tarazu early in Drosophila embryogenesis. We have cloned a developmental isoform of FTZ-F1 and found that it is expressed as a product of the previously identified, midprepupal chromosome puff at 75CD. The 75CD puff occurs in the midst of a period of intense puffing activity that is triggered in response to the steroid hormone ecdysone at the onset of metamorphosis. Indirect immunofluorescent staining for FTZ-F1 on Drosophila polytene chromosomes reveals binding to over 150 chromosomal targets, which include 75CD itself and prominent late prepupal puffs that are predicted to be regulated by midprepupal puff proteins. These results suggest a role for FTZ-F1 as a regulator of insect metamorphosis and underscore the repeated utilization of a regulatory protein for widely separate developmental pathways.

Temporal coordination of regulatory gene expression by the steroid hormone ecdysone.

In Drosophila, pulses of the steroid hormone ecdysone function as temporal signals that trigger the major postembryonic developmental transitions. The best characterized of these pulses activates a series of puffs in the polytene chromosomes as it triggers metamorphosis. A small set of early puffs is induced as a primary response to the hormone. These puffs encode regulatory proteins that both repress their own expression and activate a large set of late secondary response genes. We have used Northern blot analysis of RNA isolated from staged animals and cultured organs to study the transcription of three primary response regulatory genes, E75, BR-C and EcR. Remarkably, their patterns of transcription in late larvae can be defined in terms of two responses to different ecdysone concentrations. The class I transcripts (E74B and EcR) are induced in mid-third instar larvae in response to the low, but increasing, titer of ecdysone. As the hormone concentration peaks in late third instar larvae, these transcripts are repressed and the class II RNAs (E74A, E75A and E75B) are induced. The BR-C RNAs appear to have both class I and class II characteristics. These data demonstrate that the relatively simple profile of a hormone pulse contains critical temporal information that is transduced into waves of primary response regulatory gene activity.

Isolation and characterization of five Drosophila genes that encode an ets-related DNA binding domain.

The recent determination of the site-specific DNA binding properties of several proteins related to the ets oncoprotein has allowed the definition of a novel DNA binding domain, designated the ETS domain. In Drosophila, an ETS domain is present in the early ecdysone-induced E74A protein, which binds DNA in a site-specific manner and interacts with many ecdysone-induced polytene chromosome puffs at the onset of metamorphosis. As a first step toward determining the function of ETS-domain proteins during Drosophila development, we have used PCR amplification with degenerate oligonucleotides to isolate five other ets-related genes. Two of these genes, D-ets-2 and D-elg, have been previously identified. The proteins encoded by these genes are highly related to one another and to the seven identified vertebrate ETS-domain proteins, within the approximately 85-amino-acid DNA binding domain. In situ hybridization to polytene chromosomes revealed that these ets-related genes are not clustered in the genome and that only E74 corresponds to an ecdysone-inducible puff locus. These five ets-related genes are distinguished further from E74 in that they are transcribed through most of development, suggesting that they do not perform a stage-specific function. They are, however, expressed in a variety of patterns in early embryos, suggesting roles in the development of specific cell types. D-ets-2 is expressed in a complex pattern that changes dynamically during early embryogenesis. D-ets-3 and D-ets-6 are expressed in the ventral nervous system. The expression of D-ets-3 is higher in the three thoracic segments and lower in the abdominal segments. The high levels of expression in the thoracic segments are dependent on the presence of the bithorax complex. D-ets-4 and D-elg are expressed at their highest levels in the pole cells, suggesting a role in the development of the germline. This study represents the first effort in any organism to systematically isolate members of the ets gene family. The identification of six independent ets-related genes demonstrates that the ETS-domain proteins constitute a new family of potential transcriptional regulators encoded by the Drosophila genome.

Ecdysone coordinates the timing and amounts of E74A and E74B transcription in Drosophila.

Pulses of the steroid hormone ecdysone function as temporal signals to coordinate the development of both larval and adult tissues in Drosophila. Ecdysone acts by triggering a genetic regulatory hierarchy that can be visualized as puffs in the larval polytene chromosomes. In an effort to understand how the ecdysone signal is transduced to result in sequential gene activation, we are studying the transcriptional control of E74, an early gene that appears to play a regulatory role in the hierarchy. Northern blot analysis of RNA isolated from staged animals or cultured organs was used to characterize the effects of ecdysone on E74 transcription. Ecdysone directly activates both E74A and E74B promoters. E74B mRNA precedes that of E74A, each mRNA appearing with delay times that agree with their primary transcript lengths and our previous transcription elongation rate measurement of approximately 1.1 kb/min. The earlier appearance of E74B transcripts is enhanced by its activation at an approximately 25-fold lower ecdysone concentration than E74A. E74B is further distinguished from E74A by its repression at a significantly higher ecdysone concentration than that required for its induction, close to the concentration required for E74A activation. These regulatory properties lead to an ecdysone-induced switch in E74 expression, with an initial burst of E74B transcription followed by a burst of E74A transcription. We also show that the patterns of ecdysone-induced E74A and E74B transcription vary in four ecdysone target tissues. These studies provide a means to translate the profile of a hormone pulse into different amounts and times of regulatory gene expression that, in turn, could direct different developmental responses in a temporally and spatially regulated manner.

The Drosophila 74EF early puff contains E74, a complex ecdysone-inducible gene that encodes two ets-related proteins.

We have isolated an ecdysone-inducible gene, E74, from the early puff at position 74EF in the Drosophila polytene chromosomes. We show that E74 consists of three nested transcription units that derive from unique promoters but share a single polyadenylation site. The 60 kb E74A unit is directly induced by ecdysone and leads to the synthesis of a 6.0 kb mRNA that contains an unusually long 5' leader (1891 nucleotides) with 17 short ORFs. Within the fifth of the seven E74A introns are two E74B promoters that direct the synthesis of 4.8 and 5.1 kb mRNAs. The nested arrangement of these transcription units leads to the formation of two E74 proteins, each with a unique N-terminal domain joined to a common C-terminal domain. The unique N-terminal domains contain regions rich in acidic amino acids while the C-terminal domain is rich in basic amino acids and is very similar to proteins encoded by the ets proto-oncogene superfamily.