Regulated nuclear export of the homeodomain transcription factor Prospero.

Subcellular distribution of the Prospero protein is dynamically regulated during Drosophila embryonic nervous system development. Prospero is first detected in neuroblasts where it becomes cortically localized and tethered by the adapter protein, Miranda. After division, Prospero enters the nucleus of daughter ganglion mother cells where it functions as a transcription factor. We have isolated a mutation that removes the C-terminal 30 amino acids from the highly conserved 100 amino acid Prospero domain. Molecular dissection of the homeo- and Prospero domains, and expression of chimeric Prospero proteins in mammalian and insect cultured cells indicates that Prospero contains a nuclear export signal that is masked by the Prospero domain. Nuclear export of Prospero, which is sensitive to the drug leptomycin B, is mediated by Exportin. Mutation of the nuclear export signal-mask in Drosophila embryos prevents Prospero nuclear localization in ganglion mother cells. We propose that a combination of cortical tethering and regulated nuclear export controls Prospero subcellular distribution and function in all higher eukaryotes.

decapentaplegic is a direct target of dTcf repression in the Drosophila visceral mesoderm.

Drosophila T cell factor (dTcf) mediates transcriptional activation in the presence of Wingless signalling and repression in its absence. Wingless signalling is required for the correct expression of decapentaplegic (dpp), a Transforming Growth Factor (beta) family member, in parasegments 3 and 7 of the Drosophila visceral mesoderm. Here we demonstrate that a dpp enhancer element, which directs expression of a reporter gene in the visceral mesoderm in a pattern indistinguishable from dpp, has two functional dTcf binding sites. Mutations that reduce or eliminate Wingless signalling abolish dpp reporter gene expression in parasegment 3 and reduce it in parasegment 7 while ectopic expression of Wingless signalling components expand reporter gene expression anteriorly in the visceral mesoderm. However, mutation of the dTcf binding sites in the dpp enhancer results in ectopic expression of reporter gene expression throughout the visceral mesoderm, with no diminution of expression in the endogenous sites of expression. These results demonstrate that the primary function of dTcf binding to the dpp enhancer is repression throughout the visceral mesoderm and that activation by Wingless signalling is probably not mediated via these dTcf binding sites to facilitate correct dpp expression in the visceral mesoderm.

Identification of the Drosophila melanogaster homologue of the mammalian signal transducer protein, Vav.

Mammalian Vav signal transducer protein couples tyrosine kinase signals with the activation of the Rho/Rac GTPases, thus leading to cell differentiation and/or proliferation. We have isolated and characterized the DroVav gene, the homologue of hVav in Drosophila melanogaster. DroVav encodes a protein (793 residues) whose similarity with hVav is 47% and with hVav2 and hVav3 is 45%. DroVav preserves the unique, complex structure of hVav proteins, including the 'calponin homology', dbl homology, pleckstrin homology; SH2 and SH3 domains in addition to regions that are acidic rich, proline rich and cysteine rich. DroVav is located on the X chromosome in polytene interval 18A5;18B and is expressed in all stages of development and in all tissues. In mammalian cells, DroVav is tyrosine-phosphorylated in response to epidermal growth factor receptor (EGFR) induction; in vitro, the DroVav SH2 region is associated with tyrosine-phosphorylated EGFR. Thus, DroVav probably plays a pivotal role as a signal transducer protein during fruit fly development.

Selection and analysis of rare second-site suppressors of Drosophila RNA polymerase II mutations.

We used a mutagenesis and selection procedure in Drosophila melanogaster to recover rare allele-specific suppressor mutations. More than 11 million flies mutant for one of five recessive-lethal mutations in the two largest subunits of RNA polymerase II were selected for additional mutations that restored viability. Forty-one suppressor mutations were recovered. At least 16 are extragenic, identifying a minimum of three loci, two of which do not map near genes known to encode subunits of RNA polymerase II. At most, 25 are intragenic, 4 reverting the initial altered nucleotide back to wild type. Sequence analysis of interacting mutations in the two largest subunits identified a discrete domain in each subunit. These domains might be contact points for the subunits. Finally, our selections were large enough to allow recovery of multiple independent changes in the same nucleotides yet mutations in other equally likely targets were not recovered. The mutations recovered are not random and might provide insights into possible mechanisms for mutagenesis in eukaryotes.

Genomic organization of the segment polarity gene pan in Drosophila melanogaster.

We previously described the molecular cloning of a mammalian T cell factor 1 (TCF-1)-like protein from Drosophila melanogaster, encoded by the pangolin (pan) locus, and demonstrated that it consists of a DNA binding domain similar to that of other high mobility group proteins and a protein-protein interaction domain that binds beta-catenin (Armadillo in Drosophila) but that it lacks a transcriptional activation domain. Here we show that the pan locus spans approximately 50 kb and the mRNA results from the splicing of 13 exons. We note remarkable conservation of the exon/intron boundaries between the human and D. melanogaster genes, suggesting that they share a common ancestor. Chromosomal in situ hybridization locates pan to the base of chromosome 4, near the cubitus interruptus locus. Restriction map and sequence analyses confirm their close proximity. The small fourth chromosome undergoes little or no recombination and was previously reported to lack DNA polymorphisms; however, we note two DNA polymorphisms occurring in three combinations within the pan locus, demonstrating the presence of synonymous substitutions and the past occurrence of recombination. We present evidence suggesting that the protein encoded by pan is more similar to mammalian TCF-1 and Caenorhabditis elegans POP-1 than to mammalian LEF-1.

Multiple functions of Drosophila heat shock transcription factor in vivo.

Heat shock transcription factor (HSF) is a transcriptional activator of heat shock protein (hsp) genes in eukaryotes. In order to elucidate the physiological functions of HSF in Drosophila, we have isolated lethal mutations in the hsf gene. Using a conditional allele, we show that HSF has an essential role in the ability of the organism to survive extreme heat stress. In contrast to previous results obtained with yeast HSF, the Drosophila protein is dispensable for general cell growth or viability. However, it is required under normal growth conditions for oogenesis and early larval development. These two developmental functions of Drosophila HSF are genetically separable and appear not to be mediated through the induction of HSPs, implicating a novel action of HSF that may be unrelated to its characteristic function as a stress-responsive transcriptional activator.

Transcriptional competition and homeosis in Drosophila.

Interference between different classes of RNA polymerase II alleles causes a mutant phenotype called the "Ubx effect" that resembles one seen in flies haploinsufficient for the transcription factor, Ultrabithorax (Ubx). Flies carrying the mutation in the largest subunit of Drosophila RNA polymerase II, RpII215(4), display the Ubx effect when heterozygous as in RpII215(4)/+ but not when homozygous mutant or wild type. In this report we demonstrate that the interaction between alleles in different classes of polymerase occurs even in the absence of transcription by the wild-type polymerase. We utilized the resistance to the transcriptional inhibitor alpha-amanitin conferred by RpII215(4) to show that RpII215(4)/+ flies raised on alpha-amanitin-containing food still show the Ubx effect and are indistinguishable from flies raised on normal food. We demonstrate using HPLC that the intracellular concentration of alpha-amanitin in the developing larvae is sufficient to inhibit transcription by alpha-amanitin-sensitive polymerase. Furthermore, fluorescein-labeled alpha-amanitin accumulates in imaginal discs, which are the precursor cells for the tissue showing the homeotic transformation in adults. We conclude that the interaction between different classes of RNA polymerase II alleles resulting in the Ubx effect occurs prior to the block in transcription caused by alpha-amanitin.

Molecular cloning of cDNA encoding the small subunit of Drosophila transcription initiation factor TFIIF.

Transcription initiation factor TFIIF is a tetramer consisting of two large subunits (TFIIF alpha or RAP74) and two small subunits (TFIIF beta or RAP30). We report here the molecular cloning of a Drosophila cDNA encoding TFIIF beta. The cDNA clone contains an open-reading frame encoding a 277 amino acid polypeptide having a calculated molecular mass of 32,107 Da. Comparison of the deduced amino acid sequence with the corresponding sequences from vertebrates showed only 50% identity, with four insertion/deletion points. For transcription activity in a TFIIF-depleted Drosophila nuclear extract, both TFIIF alpha and TFIIF beta are essential. Moreover, Drosophila TFIIF beta interacts with both Drosophila and human TFIIF alpha in vitro. Thus we conclude that isolated cDNA encodes bona fide TFIIF beta. The structural domains of TFIIF beta and its sequence similarity to bacterial delta factors are discussed.

Molecular modeling of RNA polymerase II mutations onto DNA polymerase I.

Genetic and molecular analysis in Drosophila melanogaster identifies eight suppressor mutations in the second largest subunit of RNA polymerase II. The suppressor mutations fall into two classes: five are strong, result from the same serine to cysteine amino acid residue substitution and rescue one conditional lethal allele in the largest subunit of RNA polymerase II; three are mild, result from a change in the same methionine residue to either isoleucine or valine, are located seven amino acid residues away from the strong suppressors and rescue two conditional lethal alleles in the largest subunit. Sequence analysis of the three regions around these mutations demonstrates that they are located within highly conserved domains but fails to explain the observed genetic interactions. One of the conditional lethal alleles maps within a region previously reported to share sequence similarity to Escherichia coli DNA polymerase I. As the gross structure of RNA polymerase II and DNA polymerase I is similar, even though their primary sequence is not, we predict that more similarities exist but may be too highly divergent to be detected by normal homology searches. We identify the most similar regions between each of the three conserved domains of RNA polymerase II, identified as functionally important because of the mutations we isolated, and DNA polymerase I. Molecular modeling these regions of RNA polymerase II onto the tertiary structure of DNA polymerase I predicts that all lie adjacent to the DNA binding cleft in positions such that they could interact with the phosphate backbone of DNA. This juxtaposition of mutations in the two largest subunits of RNA polymerase II suggest a mechanism for their genetic interactions.

Mapping mutations in genes encoding the two large subunits of Drosophila RNA polymerase II defines domains essential for basic transcription functions and for proper expression of developmental genes.

We have mapped a number of mutations at the DNA sequence level in genes encoding the largest (RpII215) and second-largest (RpII140) subunits of Drosophila melanogaster RNA polymerase II. Using polymerase chain reaction (PCR) amplification and single-strand conformation polymorphism (SSCP) analysis, we detected 12 mutations from 14 mutant alleles (86%) as mobility shifts in nondenaturing gel electrophoresis, thus localizing the mutations to the corresponding PCR fragments of about 350 bp. We then determined the mutations at the DNA sequence level by directly subcloning the PCR fragments and sequencing them. The five mapped RpII140 mutations clustered in a C-terminal portion of the second-largest subunit, indicating the functional importance of this region of the subunit. The RpII215 mutations were distributed more broadly, although six of eight clustered in a central region of the subunit. One notable mutation that we localized to this region was the alpha-amanitin-resistant mutation RpII215C4, which also affects RNA chain elongation in vitro. RpII215C4 mapped to a position near the sites of corresponding mutations in mouse and in Caenorhabditis elegans genes, reinforcing the idea that this region is involved in amatoxin binding and transcript elongation. We also mapped mutations in both RpII215 and RpII140 that cause a developmental defect known as the Ubx effect. The clustering of these mutations in each gene suggests that they define functional domains in each subunit whose alteration induces the mutant phenotype.

Reverse genetics of Drosophila RNA polymerase II: identification and characterization of RpII140, the genomic locus for the second-largest subunit.

We have used a reverse genetics approach to isolate genes encoding two subunits of Drosophila melanogaster RNA polymerase II. RpII18 encodes the 18-kDa subunit and maps cytogenetically to polytene band region 83A. RpII140 encodes the 140-kDa subunit and maps to polytene band region 88A10:B1,2. Focusing on RpII140, we used in situ hybridization to map this gene to a small subinterval defined by the endpoints of a series of deficiencies impinging on the 88A/B region and showed that it does not represent a previously known genetic locus. Two recently defined complementation groups, A5 and Z6, reside in the same subinterval and thus were candidates for the RpII140 locus. Phenotypes of A5 mutants suggested that they affect RNA polymerase II, in that the lethal phase and the interaction with developmental loci such as Ubx resemble those of mutants in the gene for the largest subunit, RpII215. Indeed, we have achieved complete genetic rescue of representative recessive lethal mutations of A5 with a P-element construct containing a 9.1-kb genomic DNA fragment carrying RpII140. Interestingly, the initial construct also rescued lethal alleles in the neighboring complementation group, Z6, revealing that the 9.1-kb insert carries two genes. Deleting coding region sequences of RpII140, however, yielded a transformation vector that failed to rescue A5 alleles but continued to rescue Z6 alleles. These results strongly support the conclusion that the A5 complementation group is equivalent to the genomic RpII140 locus.

Mutations in the second-largest subunit of Drosophila RNA polymerase II interact with Ubx.

Specific mutations in the gene encoding the largest subunit of RNA polymerase II (RpII215) cause a partial transformation of a structure of the third thoracic segment, the capitellum, into the analogous structure of the second thoracic segment, the wing. This mutant phenotype is also caused by genetically reducing the cellular concentration of the transcription factor Ultrabithorax (Ubx). To recover mutations in the 140,000-D second-largest subunit of RNA polymerase II (RpII140) and determine whether any can cause a mutant phenotype similar to Ubx we attempted to identify all recessive-lethal mutable loci in a 340-kilobase deletion including this and other loci. One of the 13 complementation groups in this region encodes RpII140. Three RpII140 alleles cause a transformation of capitellum to wing but unlike RpII215 alleles, only when the concentration of Ubx protein is reduced by mutations in Ubx.

The RNA polymerase II 15-kilodalton subunit is essential for viability in Drosophila melanogaster.

A small, divergently transcribed gene is located 500 bp upstream of the suppressor of Hairy-wing locus of Drosophila melanogaster. Sequencing of a full-length cDNA clone of the predominant 850-nucleotide transcript reveals that this gene encodes a 15,100-Da protein with high homology to a subunit of RNA polymerase II. The RpII15 protein is 46% identical to the RPB9 protein of Saccharomyces cerevisiae, one of the smallest subunits of RNA polymerase II from that species. Among those identical residues are four pairs of cysteines whose spacing is suggestive of two metal-binding "finger" domains. The gene is expressed at all developmental stages and in all tissues. Two deletions within the RpII15 gene are multiphasic lethal deletions, with accumulation of dead animals commencing at the second larval instar. Ovary transplantation experiments indicate that survival of mutant animals to this stage is due to the persistence of maternal gene product throughout embryogenesis and early larval development. The RpII15 gene product is thus necessary for viability of D. melanogaster.

Use of second-site suppressor mutations in Drosophila to identify components of the transcriptional machinery.

Isolation of second-site suppressor mutations provides a powerful method for identifying (i) genes that encode proteins that interact and (ii) domains within the interacting proteins that contact each other. Flies conditionally lethal because they carry mutations in the largest subunit of RNA polymerase II were mutagenized; ten million progeny were then screened for compensatory mutations. Eight intragenic and 10 extragenic suppressor mutations were recovered. Both the conditional lethality and premature termination of transcription caused by one mutation in the largest subunit of RNA polymerase II are compensated by an allele-specific suppressor mutation in the second-largest subunit of the enzyme.

Antagonistic interactions between alleles of the RpII215 locus in Drosophila melanogaster.

The RpII215 locus encodes the large subunit of RNA polymerase II (polII). Three of 22 RpII215 alleles cause a synergistic enhancement of the mutant phenotype elicited by mutations in the Ultrabithorax (Ubx) locus. We have recovered and analyzed three new mutations that suppress this enhancement. All three mutations map to the RpII215 locus. In addition to suppressing the Ubx enhancement of other RpII215 alleles, two of the new mutations, JH1 and WJK2, themselves enhance Ubx. RpII215 alleles can be placed into three classes based on their ability to enhance Ubx. Class I alleles, including Ubl, C4, C11, JH1, and WJK2, enhance Ubx when heterozygous with class II alleles, which include wild-type RpII215. Class III alleles, which include amorphic alleles, do not enhance Ubx. The third new mutation, WJK1, is a conditional amorphic allele, which behaves like a class III allele at 29 degrees but like a class II allele at 19 degrees. Another mutant phenotype is caused by certain RpII215 alleles, including all class I alleles. This phenotype is a synergistic enhancement of a mutant phenotype elicited by mutations at the Delta (Dl) locus. Unlike the enhancement of Ubx, the enhancement of Dl is not dependent upon antagonistic interactions between different classes of RpII215 alleles.

Genetic interactions of modifier genes and modifiable alleles in Drosophila melanogaster.

We have examined the effects of mutations in the six allele-specific modifier genes su(Hw), e(we), su(f), su(s), su(wa), and su(pr) on the expression of 18 modifiable alleles, situated at 11 loci. Ten of the modifiable alleles are associated with insertions of the gypsy retrotransposon and the others include alleles associated with insertions of copia and 412. We tested or retested 90 of the 108 possible combinations and examined the expression of modifiable alleles in flies mutant for pairs of modifier genes in various heterozygous and homozygous configurations. Our principal findings are: (1) a screen of 40,000 mutagenized X chromosomes yielded three new mutations in known modifier genes, but revealed no new modifier genes; (2) the modification effects of different mutations in a given modifier gene were qualitatively similar; (3) each of the six modifiers suppressed some modifiable alleles, enhanced others, and had no noticeable effect on still others; (4) the modifier genes could be placed in four classes, according to their effects on the gypsy-insertion alleles; and (5) the effects of mutations in different modifier genes combined additively. Implications of these results for models of modifier gene action are discussed.

Clonal analysis of two mutations in the large subunit of RNA polymerase II of Drosophila.

Two mutations in the gene, RpII215, were analyzed to determine their effects on cell differentiation and proliferation. The mutations differ in that one, RpII215ts (ts), only displays a conditional recessive lethality, while the other, RpII215Ubl (Ubl), is a recessive lethal mutation that also displays a dominant mutant phenotype similar to that caused by the mutation Ultrabithorax (Ubx). Ubl causes a partial transformation of the haltere into a wing; however, this transformation is more complete in flies carrying both Ubl and Ubx. The present study shows that patches of Ubl/-tissue in gynandromorphs are morphologically normal. cuticle that has lost the wild-type copy of the RpII215 locus fails to show a haltere to wing transformation, nor does it show the synergistic enhancement of Ubx by Ubl. We conclude that an interaction between the two RpII215 alleles, Ubl and RpII215+, is responsible for the mutant phenotype. Gynandromorphs carrying the ts allele, when raised at permissive temperature, display larger patches of ts/-cuticle than expected, possibly indicating that the proliferation of ts/+ cells is reduced. This might result from an antagonistic interaction between different RpII215 alleles. Classical negative complementation does not appear to be the cause of the antagonistic interactions described above, as only one RpII215 subunit is thought to be present in an active multimeric polymerase enzyme. We have therefore coined the term 'negative heterosis' to describe the aforementioned interactions. We also observed that the effects of mutationally altered RNA polymerase II on somatic cells are different from its effects on germ cells.(ABSTRACT TRUNCATED AT 250 WORDS)

The use of promoter fusions in Drosophila genetics: isolation of mutations affecting the heat shock response.

We have constructed a gene fusion using the promoter of Drosophila hsp70 and the structural gene for Drosophila alcohol dehydrogenase (Adh) and used this construct to transform Adh-deficient flies. In these transformants, Adh is expressed only after heat shock. Like hsp70 itself, this heat-shock-inducible Adh (Adhhs) is induced in a wide variety of tissues. It fails to be induced in primary spermatocytes. Although the tissue distribution of Adh activity is very different from wild type, this does not appear to be deleterious. Indeed, the induction of Adhhs allows flies to survive exposure to ethanol. We have used this latter characteristic to select dominant, trans-acting mutations that alter the response of flies to heat shock.

Developmental effects of a temperature-sensitive RNA polymerase II mutation in Drosophila melanogaster.

Drosophila melanogaster possessing a temperature-sensitive (ts) mutation that maps to an X-linked locus ( RpII215 ) (the locus has also been called l(1)L5 and Ultrabithorax -like or Ubl ) encoding a subunit of RNA polymerase II are fertile at 22 degrees C but become sterile when shifted to 29 degrees C. Homozygous RpII215ts adult females shifted to 29 degrees C lay structurally normal eggs for 24 hr, after which increasing numbers of eggs are abnormal. Eggs left to develop at 29 degrees C die as morphologically normal late embryos or first instar larvae when produced by females maintained at 29 degrees C for less than 6 hr. However, eggs produced by females undergoing oogenesis at 29 degrees C for longer than 6 hr develop abnormally, displaying holes primarily in their ventral cuticle and possessing an abnormal pharyngeal apparatus. As exposure of females to 29 degrees C lengthens there is an increase in the severity of these defects. Some of the eggs can be rescued by either mating RpII215ts females to wild-type males or shifting the eggs to 22 degrees C. The percentage of eggs rescued decreases with increased length of oogenesis at 29 degrees C, up to 20 hr, at which point they are no longer rescuable. The terminal phenotype of eggs that fail to be rescued by the above procedure is less extreme than that of eggs for which no rescue attempt was made. Holes in the ventral cuticle are reduced or absent, but pattern formation is disrupted such that segments are often missing, incorrectly oriented or fused. Because the RpII215 locus encodes a subunit of RNA polymerase II, the developmental defects described above are most likely due to reduced or aberrant transcription during oogenesis and early embryogenesis. This postulated effect on transcription results, in part, from the maternal loading of a gene product(s) that is thermolabile in eggs.

Developmental genetics of a temperature-sensitive RNA polymerase II mutation in Drosophila melanogaster.

Purified RNA polymerase II (RNA nucleotidyl-transferase; EC 2.7.7.6) extracted from flies possessing lesions in the Ultrabithorax-like (Ubl) locus of Drosophila melanogaster has altered activity in vitro (Greenleaf et al. 1979, 1980; Coulter and Greenleaf 1982). This strongly suggests that the Ubl locus encodes a subunit of RNA polymerase II. Ethyl methanesulfonate was used to induce a temperature-sensitive mutation in this locus. Flies either homozygous or hemizygous for this new X-linked mutation (Ublts) display viability comparable to that of wild-type flies at 22 degrees C but are lethal at 29 degrees C. The temperature-sensitive period for Ublts flies is between gastrulation (6 h, 29 degrees C) and pupation (9-10 days, 22 degrees C). Zygotes shifted from 22 degrees C to 29 degrees C die at either the late embryonic or first larval instar stage while temperature shifts of second and third instar larvae result in the lethal phase occurring at the pupal stage. Most pupae shifted from 22 degrees C to 29 degrees C undergo metamorphosis and eclose as adults. Adults are viable if placed at 29 degrees C; however, all females and some males become sterile if maintained at this temperature. Somatic recombination was used to induce clones homozygous for a null allele of Ubl at different stages of development. Clones of this null allele appear to be cell lethal indicating that the Ubl+ gene product is required at all stages of development. The viability of Ublts pupae and adults at 29 degrees C may result from only a partial reduction in activity caused by the mutation at this nonpermissive temperature.