Synergistic activation and repression of transcription by Drosophila homeobox proteins

Single-minded regulation of genes in the embryonic midline of the Drosophila central nervous system

Proper development of the midline cells within the Drosophila central nervous system is controlled by the single-minded (sim) gene. The sim protein defines a new subclass of bHLH transcription factors and as such, is predicted to function as a transcriptional regulator of other genes important for midline development. Here we identify two potential targets of sim regulation: the sim gene itself, and the 47F gene, which is expressed specifically in the sim-expressing midline cells. Using a transgene containing sim regulatory sequences fused to beta-galactosidase, we show that the sim gene uses two distinct promoters with overlapping temporal specificities, and that expression from the late promoter is autoregulated by sim itself. By expressing sim protein in salivary gland nuclei using the heat-shock inducible Hsp70 gene promoter, we show that sim protein associates with the sim late promoter on polytene chromosomes. In addition, sim protein binds to a small number of additional chromosomal sites, among which are the sites of the 47F gene, and two other genes, Tl and cdi, whose expression also depend on sim function.

Interaction between a transcriptional activator and transcription factor IIB in vivo

Transcription of messenger RNA-encoding genes in vitro requires many protein factors. Transcription factor IID, possibly with the cooperation of TFIIA, binds to the TATA element of the promoter, forming a complex that can bind TFIIB (refs 6, 7) followed by RNA polymerase II (refs 6, 8) and other factors. One or more of these steps is thought to be facilitated by gene-specific transcriptional activation proteins; this seems to require TFIID-associated auxiliary factors and may involve direct contact between the activator and TFIID and/or TFIIB. If such contact is necessary in vivo, activation might conceivably be blocked by a TFIIB derivative containing the sequences necessary for this interaction, but lacking those necessary for binding to the rest of the transcriptional apparatus, an effect similar to that referred to as squelching or transcriptional interference. Here we show that the activity of the glutamine-rich fushi tarazu activation domain is indeed blocked by truncated TFIIB derivatives in Drosophila Schneider L2 cells, suggesting that it is mediated by interactions with TFIIB.

Rough genes with Deformed homeobox substitutions exhibit rough regulatory specificity during Drosophila eye development

In certain cases, homeobox genes with different in vivo roles encode proteins with similar in vitro DNA binding specificities. To test the role of the homeobox in the regulatory specificity of such genes, rough homeobox sequences were changed in part or entirely to those of the Deformed gene, and the modified rough genes tested for their ability to rescue the rough mutant phenotype. Surprisingly, the chimaeric genes retained levels of rough regulatory specificity but acquired no novel functions. These results suggest that factors other than the DNA binding specificity of the homeodomain play crucial roles in determining the target, and thus the regulatory specificity, of such proteins.

Synergistic activation of transcription is mediated by the N-terminal domain of Drosophila fushi tarazu homeoprotein and can occur without DNA binding by the protein

Synergistic activation of transcription by Drosophila segmentation genes in tissue culture cells provides a model with which to study combinatorial regulation. We examined the synergistic activation of an engrailed-derived promoter by the pair-rule proteins paired (PRD) and fushi tarazu (FTZ). Synergistic activation by PRD requires regions of the homeodomain or adjacent sequences, and that by FTZ requires the first 171 residues. Surprisingly, deletion of the FTZ homeodomain does not reduce the capacity of the protein for synergistic activation, although this mutation abolishes any detectable DNA-binding activity. This finding suggests that FTZ can function through protein-protein interactions with PRD or other components of the homeoprotein transcription complex, adding a new layer of mechanisms that could underlie the functional specificities and combinatorial regulation of homeoproteins.

Transcriptional repression by the Drosophila even-skipped protein: definition of a minimal repression domain

We have used a transient expression assay employing Drosophila tissue culture cells to study the transcriptional repression activity of the homeo domain protein Even-skipped (Eve). Eve was found to repress all promoters that contained Eve-binding sites, including both TATA-containing and TATA-lacking minimal promoters, as well as promoters activated by several different classes of activator proteins. These findings suggest that the general transcription machinery can be a target of Eve. By analyzing properties of a variety of Eve mutants and chimeric fusion proteins, we have identified several features important for efficient repression. In addition to the DNA-binding domain, a potent repressor requires a repression domain, which can be as small as 27 residues. The minimal 57-residue Eve repression domain, as well as several others studied here, were all found to be proline rich and to contain a high percentage of hydrophobic residues. An intriguing feature of the strong repressors was that their DNA-binding activities, measured by gel retention assays with nuclear extracts, were significantly less than those of derivatives inactive in repression.

Synergistic activation of transcription is mediated by the N-terminal domain of Drosophila fushi tarazu homeoprotein and can occur without DNA binding by the protein

Synergistic activation of transcription by Drosophila segmentation genes in tissue culture cells provides a model with which to study combinatorial regulation. We examined the synergistic activation of an engrailed-derived promoter by the pair-rule proteins paired (PRD) and fushi tarazu (FTZ). Synergistic activation by PRD requires regions of the homeodomain or adjacent sequences, and that by FTZ requires the first 171 residues. Surprisingly, deletion of the FTZ homeodomain does not reduce the capacity of the protein for synergistic activation, although this mutation abolishes any detectable DNA-binding activity. This finding suggests that FTZ can function through protein-protein interactions with PRD or other components of the homeoprotein transcription complex, adding a new layer of mechanisms that could underlie the functional specificities and combinatorial regulation of homeoproteins.

Synergism in transcriptional activation: a kinetic view

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Expression of homeobox-containing genes in primary and metastatic colorectal cancer

Homeobox genes are a network of genes encoding nuclear proteins functioning as transcriptional regulators. Human and murine homeobox genes of the HOX family are organised in four clusters on different chromosomes. Gene order within each cluster is highly conserved, perhaps in direct relation to their expression. Homeobox genes have recently been involved in normal development and oncogenesis. We have analysed HOX gene expression in normal human colon and in primary and metastatic colorectal carcinomas. The majority of HOX genes are active in normal adult colon and their overall expression pattern is characteristic of this organ. Furthermore, the expression of some HOX genes is identical in normal and neoplastic colon indicating that these genes may exert an organ-specific function. In contrast, other HOX genes exhibit altered expression in primary colon cancers and their hepatic metastases which may suggest an association with colon cancer progression.

Control of tailless expression by bicoid, dorsal and synergistically interacting terminal system regulatory elements

Three different maternal morphogen gradients regulate expression of the gap gene tailless (tll), which is required to establish the acron and telson of the Drosophila embryo. To identify elements in the tll promoter that respond to these different maternal systems, we have generated promoter-lacZ fusions and transformed them into the germline. Expression of these constructs in both wild type and mutant embryos revealed the presence of at least two separate but synergistically interacting regions that mediate tll expression by the terminal system. This functional synergism between regulatory elements may play a role in the translation of the torso (tor) morphogen gradient into the sharp boundary of tll gene activity. In addition to regions mediating activation by the terminal system, regions mediating both activation and repression by bicoid (bcd), and repression by dorsal (dl) were identified. Binding sites of bcd protein in a 0.5 kb region, revealed by DNaseI footprinting, could be crucial for the bcd-dependent activation of tll expression in the anterior stripe.

Differential regulation of transcription preinitiation complex assembly by activator and repressor homeo domain proteins

Different eukaryotic transcription factors can act through the same upstream binding site to differentially regulate target gene expression, but little is known of the underlying mechanisms. Here, we show that Ultrabithorax and even-skipped homeo domain proteins (UBX and EVE) of Drosophila melanogaster exert active and opposite effects on in vitro transcription when bound to a common site upstream of a core promoter. Both the activator UBX and the repressor EVE affect the extent but not the rate constant of preinitiation complex (preIC) formation. Both regulators act early in preIC assembly and are dispensable later. Assembling complexes become resistant to regulation by the bound proteins, but activation by UBX is restored upon ATP or dATP addition, and regulation by both proteins is restored after the addition of all four nucleoside triphosphates and transcription initiation. The results establish that upstream activators and repressors can function by fundamentally similar mechanisms, by differentially regulating an early step in preIC assembly, leading to formation of functionally distinct transcription complexes. A subsequent step renders mature complexes transiently refractory to activation and repression. Implications for the mechanism of transcription complex assembly and turnover and its regulation are discussed, including a new role for ATP in turnover.

Concentration-dependent activities of the even-skipped protein in Drosophila embryos

The Drosophila pair-rule gene even-skipped (eve) encodes a homeo-domain-containing protein (Eve) that is required for the development of both odd- and even-numbered parasegments. We have used a heat shock-inducible eve transgene to study the regulatory functions of Eve in vivo. Transcripts encoded by eight other segmentation genes were monitored for changes in distribution and abundance following short pulses of ectopic Eve expression. Two tiers of response times appeared to distinguish between genes that were direct [fushi tarazu (ftz), odd-skipped (odd), runt (run), paired, and wingless] and indirect [eve, hairy, and engrailed (en)] targets of Eve. Genes that appeared to be directly regulated by Eve were differentially repressed in a concentration-dependent fashion. Interestingly, the run and ftz genes could also be activated by Eve during a brief 20- to 30-min stage in development. The delayed actions upon the eve and en genes appeared to be mediated by run and odd. As in eve- embryos, these effects on segmentation gene expression patterns caused defects in both odd- and even-numbered parasegments. Four sequential phenotypes could be induced, each of which was attributable to the altered expression of a unique subset of target genes.

Selective nuclear transport of the Drosophila morphogen dorsal can be established by a signaling pathway involving the transmembrane protein Toll and protein kinase A

Establishment of dorsal-ventral polarity in the early Drosophila embryo requires a concentration gradient of the maternal morphogen dorsal (dl). This concentration gradient is established by selective nuclear transport of dl so that dl protein is present only in ventral nuclei. The activity of 11 genes is required for dl nuclear localization. One of these genes, Toll, encodes a transmembrane protein that appears to play the most direct role in regulating dl localization. We have examined the effects of Toll on dl in cotransfected Schneider cells to gain insight into the nature of the interaction between these proteins. We have found that Toll can enhance the nuclear localization of dl and, independently, the ability of dl to activate transcription once in the nucleus. We present evidence that the signaling pathway from Toll to dl involves protein kinase A (PKA) and that nuclear transport and activation of dl results from phosphorylation of dl by PKA. We discuss the significance of these results with respect both to Drosophila embryogenesis and to the regulation of the mammalian transcription factor NF-kappa B.

Apterous is a Drosophila LIM domain gene required for the development of a subset of embryonic muscles

The recently discovered LIM motif is found in a set of homeodomain-containing proteins thought to mediate the generation of particular cell types. Of the four LIM domain family members described to date, mec-3 and lin-11 determine cell lineages in C. elegans. Isl-1 and Xlim-1 may play similar roles in vertebrates. We have identified a Drosophila member of this class, the product of the apterous (ap) gene. During embryogenesis, ap is expressed in a small subset of fusing mesodermal precursors that give rise to 6 muscles in each abdominal hemisegment and in 5 neurons within each corresponding CNS hemisegment. Lack of ap function results in loss of ap-expressing muscles, while misexpression of ap using a heterologous promoter produces ectopic muscles.

Cell-surface changes induced by ectopic expression of the murine homeo☐ gene Hox-3.3

Murine homeobox-containing genes (Hox genes) are postulated as playing key roles in the establishment of the anterior-posterior embryonic body axis, possibly providing cells with positional cues. Little is known, however, concerning how cells might respond to homeobox gene expression to interpret these cues. Since changes in the cell-surface are central to many processes in early development we reasoned that cells expressing different complements of Hox genes might have different surface properties. In order to investigate this we have used the sensitive, non-disruptive technique of multiple two-phase aqueous partition, which is able to detect small differences on the surface of intact cells. Using this technique we have found that ectopic expression of the murine Hox-3.3 gene in cultured cells induces reproducible changes in the cell surface. Changes only occurred above a threshold level of gene expression, but above this level a correlation between surface change and gene expression was seen. The implications for the establishment of a 'Hox' code of homeobox genes acting to specifically change cell-surface properties are discussed.

Dr1, a TATA-binding protein-associated phosphoprotein and inhibitor of class II gene transcription

We have discovered a protein termed Dr1 that interacts with the TATA-binding protein, TBP. The association of Dr1 with TBP results in repression of both basal and activated levels of transcription. The interaction of Dr1 with TBP precludes the formation of a transcription-competent complex by inhibiting the association of TFIIA and/or TFIIB with TBP. Dr1 activity is associated with a 19 kd protein. A cDNA clone encoding Dr1 was isolated. Dr1 is phosphorylated in vivo and phosphorylation of Dr1 affected its interaction with TBP. Our results suggest a regulatory role for Dr1 in repression of transcription mediated via phosphorylation.

Transcriptional repression by a novel member of the bZIP family of transcription factors

We describe here a novel member of the bZIP family of DNA-binding proteins, designated E4BP4, that displays an unusual DNA-binding specificity which overlaps that of the activating transcription factor family of factors. When expressed in a transient transfection assay with a suitable reporter plasmid, E4BP4 strongly repressed transcription in a DNA-binding-site-dependent manner. Examination of a series of deletion mutants revealed that sequences responsible for the repressing potential of E4BP4 lie within the carboxyl-terminal region of the protein. No similarity was found between this region and the repressing domains of other known eukaryotic transcriptional repressors.

The replication activation potential of selected RNA polymerase II promoter elements at the simian virus 40 origin

Binding sites for cellular transcription factors were placed near the simian virus 40 origin of replication, and their effect on replication and TATA-dependent transcription was measured in COS cells. The hierarchy of transcriptional stimulation changed when the plasmids replicated. Only one of seven inserted sequences, a moderately weak transcription element, stimulated replication detectably. However, when two nonstimulatory sites were present in multiple copies they did activate replication. Multiple sites for the chimeric activator GAL4-VP16 did not stimulate replication even though transcription was stimulated strongly. The results indicate that the ability of a binding site to stimulate replication from the simian virus 40 ori is not based on its transcriptional activation potential but is instead related to a separate replication activation potential that can be increased by having multiple sites.

HOX gene expression in normal and neoplastic human kidney

As a consequence of transformation, cancer cells generally lose some of their differentiative properties. Thus, alterations interfering with the genetic mechanisms required to maintain embryonic determination could lead to tumorigenesis. Homeobox genes are a network of genes encoding nuclear proteins containing DNA-binding homeodomains that are highly conserved throughout evolution. They are expressed in a stage-related fashion in the developing embryo and, in adult life, in normal tissues. In mice and humans, homeobox genes of the HOX family are organized in 4 clusters on different chromosomes which have presumably evolved by duplication of a primordial gene cluster. Strikingly, the order of genes within each cluster is also highly conserved throughout evolution, suggesting that the physical organization of HOX genes might be essential for their expression. Recent reports indicate that homeobox mutant mice display morphological abnormalities or show neoplastic alterations, and that growth factors can turn on homeobox genes. We have studied the expression of the Antennapedia-like HOX genes in normal human kidney and in renal carcinomas. The great majority of the HOX genes analyzed are expressed in a peculiar manner in normal kidney: blocks of genes, even entire HOX loci, are coordinately regulated. Alterations in HOX gene expression in renal carcinoma can be observed in 2 genes of the HOX-2 locus, HOX-2A and HOX-2E, which are actively expressed in normal kidney and silent in cancer biopsies. The HOX-3H gene is not expressed in normal kidney whereas the HOX-3H transcripts are present in renal carcinomas. Homeobox genes within the 4 HOX loci can be aligned on the basis of the maximal sequence homology of their homeodomains: this alignment defines 13 paralogous gene groups. In renal carcinomas, genes of group 10 (HOX-1D, 2F, 3E, 4B) display a marked difference in their transcript classes when compared to those of normal kidney. Our findings suggest an association between altered HOX gene expression and kidney cancer.

The replication activation potential of selected RNA polymerase II promoter elements at the simian virus 40 origin

Binding sites for cellular transcription factors were placed near the simian virus 40 origin of replication, and their effect on replication and TATA-dependent transcription was measured in COS cells. The hierarchy of transcriptional stimulation changed when the plasmids replicated. Only one of seven inserted sequences, a moderately weak transcription element, stimulated replication detectably. However, when two nonstimulatory sites were present in multiple copies they did activate replication. Multiple sites for the chimeric activator GAL4-VP16 did not stimulate replication even though transcription was stimulated strongly. The results indicate that the ability of a binding site to stimulate replication from the simian virus 40 ori is not based on its transcriptional activation potential but is instead related to a separate replication activation potential that can be increased by having multiple sites.

Transcriptional repression by a novel member of the bZIP family of transcription factors

We describe here a novel member of the bZIP family of DNA-binding proteins, designated E4BP4, that displays an unusual DNA-binding specificity which overlaps that of the activating transcription factor family of factors. When expressed in a transient transfection assay with a suitable reporter plasmid, E4BP4 strongly repressed transcription in a DNA-binding-site-dependent manner. Examination of a series of deletion mutants revealed that sequences responsible for the repressing potential of E4BP4 lie within the carboxyl-terminal region of the protein. No similarity was found between this region and the repressing domains of other known eukaryotic transcriptional repressors.

The homeodomain: a new face for the helix-turn-helix?

The discovery of conserved protein domains found in many Drosophila and mammalian developmental gene products suggests that fundamental developmental processes are conserved throughout evolution. Our understanding of development has been enhanced by the discovery of the widespread role of the homeodomain (HD). The action of HD-containing proteins as transcriptional regulators is mediated through a helix-turn-helix motif which confers sequence specific DNA binding. Unexpectedly, the well conserved structural homology between the HD and the prokaryotic helix-turn-helix proteins contrasts with their divergent types of physical interaction with DNA. A C-terminal extension of the HD recognition helix has assumed the role that the N-terminus of the prokaryotic helix plays for specification of DNA binding preference. However, the HD appears also capable of recognizing DNA in an alternative way and its specificity in vivo may be modified by regions outside the helix-turn-helix motif. We propose that this intrinsic complexity of the HD, as well as its frequent association with other DNA binding domains, explains the functional specificity achieved by genes encoding highly related HDs.

In vivo analysis of the helix-turn-helix motif of the fushi tarazu homeo domain of Drosophila melanogaster

We report a systematic mutational analysis of the helix-turn-helix motif (HTH) of the fushi tarazu (ftz) homeo domain (HD) of Drosophila. We started out by testing the function of chimeric ftz proteins containing either a part of the Sex combs reduced (Scr) or the muscle segment homeobox (msh) HDs. By complementation tests in transgenic flies, cotransfection assays in cultured Drosophila cells and in vitro DNA-binding assays, we have found that the ftz activity is retained in the ftz-Scr chimera but is lost in the ftz-msh chimera, which is defective in binding to an Antennapedia (Antp)-class target site. Further studies with a series of back-mutants of the ftz-msh chimera have revealed that a set of class-specific DNA backbone-contacting residues in the HTH, particularly Arg-28 and Arg-43, are required for efficient target site recognition and, hence, full ftz activity both in vitro and in vivo.

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.

Homeodomain-independent activity of the fushi tarazu polypeptide in Drosophila embryos

The Drosophila segmentation gene fushi tarazu (ftz) encodes a homeodomain-containing protein, ftz, that can act as a DNA-binding activator of transcription. In the developing embryo, ftz is expressed in seven stripes which correspond to the even-numbered parasegments. These parasegments are missing in ftz- embryos. When ftz is expressed throughout blastoderm embryos under the control of a heat-shock promoter, the odd-numbered parasegments are lost. This 'anti-ftz' phenotype has been attributed to autoactivation of the endogenous ftz gene by the ectopically expressed protein. Here we show that the same phenotype is induced by ectopic expression of a ftz polypeptide containing a deletion in the homeodomain. Thus, ftz can alter gene expression without binding directly to DNA.

Lineage and stage specific expression of HOX 1 genes in the human hematopoietic system

Recent observations have demonstrated the expression of several members of the homeobox-containing (HOX) gene complexes within the hematopoietic compartment. We have analyzed the expression pattern of the entire HOX 1 locus in a panel of leukemia-derived human cell lines representing various blood phenotypes. The expression of the eleven HOX 1 genes is lineage-restricted and these genes are predominantly detected within cells of myelomonocytic origin. This is in strong contrast with the erythro-megakaryocytic specific expression of HOX 2 genes. Furthermore, we have observed that the expression of three HOX 1 genes within B lymphoid lineages is stage-related and that the expression of several of them is switched off during TPA-induced differentiation of Kg1 and U937. These observations suggest that HOX 1 homeoproteins could be regulators of lineage determination during hematopoiesis.

A conserved regulatory unit implicated in tissue-specific gene expression in Drosophila and man

The Drosophila melanogaster alcohol dehydrogenase (Adh) gene is expressed in a specific set of tissues during larval development and in adults. Expression in the adult fat body is controlled by the Adh adult enhancer (AAE). Previous studies identified a negative regulatory element in the AAE and a protein that binds specifically to this sequence [adult enhancer factor-1 (AEF-1)]. Here, we show that the AEF-1-binding site in the AAE and in two other Drosophila fat body enhancers overlaps a sequence recognized by the mammalian transcription factor CCAAT/enhancer-binding protein (C/EBP). Remarkably, these two proteins also bind specifically to overlapping sites in a liver-specific regulatory element of the human Adh gene. Cotransfection experiments in mammalian cells reveal that C/EBP stimulates the activity of the AAE by 50-fold, and this activity can be suppressed by AEF-1. In addition, AEF-1 prevents C/EBP binding in vitro, and displaces prebound C/EBP. Thus, a tissue-specific regulatory unit consisting of one positive and one negative regulatory element has been conserved between Drosophila and man.

Cell type dependent transcription regulation by chick homeodomain proteins

Five chick homeodomain proteins (CHOXs), CHOX-1.7, -1.1, -1.4, -4.2 and -2.6, had different transcription-regulating activities in a chick cultured cell line, LMH. In particular, CHOX-1.7 highly activated transcription when NP6 was used as the target site whereas CHOX-1.4 did not. This was mainly due to differences in the activation domains since both proteins bound to NP with almost the same affinities in vitro. In LMH cells, they competitively acted on target gene transcription. Moreover, the strength of the CHOX-1.4 activation domain depended on the cell type. These findings suggest that the effect on a target gene is determined by a combination of CHOXs and cell types.

Molecular characterization and silk gland expression of Bombyx engrailed and invected genes

Genetic analysis in Drosophila has shown that engrailed (en) plays an important role in segmentation and neurogenesis. A closely related gene, invected (in), is coexpressed with en in the posterior developmental compartments where en is known to specify cell state. We report here the isolation of two en-like cDNAs from the middle silk glands of Bombyx mori larvae. Sequence analysis revealed that they are the counterparts of Drosophila en and in. Four highly conserved domains, including the homeodomain, were identified in these En and In proteins from Bombyx and Drosophila. In addition, two en-specific and one in-specific domains could also be found. These structurally homologous genes might share a similar role in Bombyx development. They were found to be coexpressed in the middle silk gland but not in the posterior silk gland during the fourth molt/fifth intermolt period. We speculate that these Bombyx en-like genes might be involved in the compartmentalization of the silk gland.

TFIID can be rate limiting in vivo for TATA-containing, but not TATA-lacking, RNA polymerase II promoters

We have studied the effect of exogenous expression of the basal transcription factor TFIID on the activities of several different TATA-containing and TATA-lacking promoters. Overexpression of TFIID from a transfected plasmid in Drosophila Schneider cells resulted in substantial concentration-dependent increases in expression from a cotransfected minimal TATA-containing promoter. Overexpression of TFIID activated expression from all TATA-containing promoters tested, with the maximum level of activation being inversely proportional to the strength of the promoter. In contrast, expression from TATA-less promoters was not enhanced, and could in fact be reduced, by increased expression of TFIID. Consistent with these findings overexpression of TFIID had opposite effects on Sp1-mediated activation observed from minimal synthetic promoters consisting of Sp1-binding sites and either a TATA box or initiator element. We discuss the significance of these results in terms of the role of TFIID in the initiation of transcription and as a possible regulatory target for expression from TATA-containing promoters, as well as the role TFIID may play in expression from TATA-less promoters.

Stage- and adult tissue-specific expression of a homeobox gene in embryo and adult Parechinus angulosus sea urchins

We report the isolation of a gene (PaHbox6), encoding a homeobox-containing protein of the South African sea urchin, Parechinus angulosus. Sequencing identified an Antennapedia-class gene encoding a homeobox that is the homologue of the Hawaiian sea urchin Tripneustes gratilla homeobox gene. Extensive restriction-fragment length polymorphism surrounds the gene. RNase-protection analyses revealed expression of PaHbox6 in mesenchyme blastula embryos at maximal levels of 44 +/- 8 transcripts/embryo. Four adult tissues examined (testes, ovary, intestines, Aristotle's lantern) showed expression of PaHbox6, though at greatly differing levels, with testes highest at eleven transcripts/10 pg RNA. Two transcripts of 5.2 and 5.7 kb were identified in adult tissue.

Repression of the Drosophila proliferating-cell nuclear antigen gene promoter by zerknüllt protein

A 631-bp fragment containing the 5'-flanking region of the Drosophila melanogaster proliferating-cell nuclear antigen (PCNA) gene was placed upstream of the chloramphenicol acetyltransferase (CAT) gene of a CAT vector. A transient expression assay of CAT activity in Drosophila Kc cells transfected with this plasmid and a set of 5'-deletion derivatives revealed that the promoter function resided within a 192-bp region (-168 to +24 with respect to the transcription initiation site). Cotransfection with a zerknüllt (zen)-expressing plasmid specifically repressed CAT expression. However, cotransfection with expression plasmids for a nonfunctional zen mutation, even-skipped, or bicoid showed no significant effect on CAT expression. RNase protection analysis revealed that the repression by zen was at the transcription step. The target sequence of zen was mapped within the 34-bp region (-119 to -86) of the PCNA gene promoter, even though it lacked zen protein-binding sites. Transgenic flies carrying the PCNA gene regulatory region (-607 to +137 or -168 to +137) fused with lacZ were established. When these flies were crossed with the zen mutant, ectopic expression of lacZ was observed in the dorsal region of gastrulating embryos carrying the transgene with either construct. These results indicate that zen indirectly represses PCNA gene expression, probably by regulating the expression of some transcription factor(s) that binds to the PCNA gene promoter.

The TATA-dependent and TATA-independent promoters of the Drosophila melanogaster actin 5C-encoding gene

The major cytoskeletal actin of Drosophila melanogaster, actin 5C, is encoded by a gene (act5C) that has two promoters which are differentially controlled and possess distinct sets of regulatory elements. The distal basal promoter has a TATA motif, but the proximal does not. The distal strong positive domain, centered at nucleotide -290, can be shifted and fused directly to the distal basal promoter without losing its activity. It can also activate heterologous basal promoters containing either TATAAAT or TATTTAA signal when directly fused to them, but cannot activate the basal proximal promoter, which is TATA-less. When the entire distal regulatory region, which includes a remote enhancer-like region, is fused to the proximal promoter, it does not increase the proximal promoter activity. Fusion of the distal strong negative domain to the proximal promoter does not inhibit activity. Thus, all the three major strong regulatory domains of the distal promoter are unable to act on the proximal promoter.

Concentration-dependent transcriptional activation or repression by Krüppel from a single binding site

One of the gap class of segmentation genes, Krüppel (Kr), is required for normal thorax and abdominal development of the Drosophila embryo. Its gene product, a zinc-finger type protein, forms a bell-shape concentration gradient in a central position of the blastoderm. Genetic and molecular studies suggested that the Kr protein (KR) may act both as a positive and as a negative regulator of transcription on several other genes of the zygotic segmentation hierarchy. We have examined the regulatory potential of Kr by a series of cotransfection experiments in the Drosophila Schneider cell line system. Different doses of Kr expression plasmid were tested for their ability to drive reporter gene expression mediated by a single 11-base pair KR in vitro binding site common to several putative Kr target genes. Our results show that low amounts of Kr expression plasmid lead to transcriptional activation, whereas high amounts result in repression. Distinct portions of KR other than the DNA-binding domain are required for gene activation and repression, suggesting that KR itself can act as a concentration-dependent positive and negative regulator of transcription.

Repression of the Drosophila proliferating-cell nuclear antigen gene promoter by zerknüllt protein

A 631-bp fragment containing the 5'-flanking region of the Drosophila melanogaster proliferating-cell nuclear antigen (PCNA) gene was placed upstream of the chloramphenicol acetyltransferase (CAT) gene of a CAT vector. A transient expression assay of CAT activity in Drosophila Kc cells transfected with this plasmid and a set of 5'-deletion derivatives revealed that the promoter function resided within a 192-bp region (-168 to +24 with respect to the transcription initiation site). Cotransfection with a zerknüllt (zen)-expressing plasmid specifically repressed CAT expression. However, cotransfection with expression plasmids for a nonfunctional zen mutation, even-skipped, or bicoid showed no significant effect on CAT expression. RNase protection analysis revealed that the repression by zen was at the transcription step. The target sequence of zen was mapped within the 34-bp region (-119 to -86) of the PCNA gene promoter, even though it lacked zen protein-binding sites. Transgenic flies carrying the PCNA gene regulatory region (-607 to +137 or -168 to +137) fused with lacZ were established. When these flies were crossed with the zen mutant, ectopic expression of lacZ was observed in the dorsal region of gastrulating embryos carrying the transgene with either construct. These results indicate that zen indirectly represses PCNA gene expression, probably by regulating the expression of some transcription factor(s) that binds to the PCNA gene promoter.

Recombinant gene expression in cultured Drosophila melanogaster cells

Cultured Drosophila Schneider line 2 cells provide a versatile and efficient system for the expression of recombinant gene products that retain authentic properties. An efficient method now exists for the expression of large amounts of recombinant protein from continuous cell lines. In addition, Schneider line 2 cells have proven reliable as a background for in vivo studies of gene regulation and protein function.

Comparison of several promoters and polyadenylation signals for use in heterologous gene expression in cultured Drosophila cells

We have directly compared the ability of four promoters and three polyadenylation (poly(A)) signals to direct heterologous gene expression in stably transfected Drosophila melanogaster S2 cells. We compared two constitutive Drosophila promoters, the actin 5C distal promoter and the alpha 1-tubulin promoter, with the tightly regulated Drosophila metallothionein (Mtn) promoter and the Bombyx mori fibroin promoter. We find that the actin 5C and induced Mtn promoters generate comparable high levels of RNA and protein in this system. The alpha 1-tubulin promoter generates about four-fold lower levels, and the fibroin promoter shows no detectable activity in S2 cells. Interestingly, genes expressed from the constitutive actin 5C and alpha 1-tubulin promoters are consistently present at three- to four-fold lower copy numbers than genes expressed from the inducible Mtn promoter or the inactive fibroin promoter. Poly(A) signals of both mammalian (SV40) and Drosophila (Mtn) origin efficiently directed stable RNA synthesis in S2 cells, and, as in mammalian cells, the SV40 late poly(A) signal was more efficient than the SV40 early poly(A) signal. Thus the process of polyadenylation appears to be conserved between mammalian and Drosophila cells.

A complex regulatory DNA element associated with a major histocompatibility complex class I gene consists of both a silencer and an enhancer

A novel regulatory element which contributes to the regulation of quantitative, tissue-specific differences in gene expression has been found between -771 and -676 bp upstream of the major histocompatibility complex (MHC) class I gene, PD1. Molecular dissection of this element reveals the presence of two overlapping functional activities: an enhancer and a silencer. Distinct nuclear factors bind to the overlapping enhancer and silencer DNA sequence elements within the regulatory domain. The levels of factors binding the silencer DNA sequence in different cell types are inversely related to levels of class I expression; in contrast, factors binding the enhancer DNA sequence can be detected in all cells. In cultured cell lines, inhibition of protein synthesis leads to the rapid loss of silencer complexes, with a concomitant increase in both enhancer complexes and MHC class I RNA. From these data, we conclude that a labile silencer factor competes with a constitutively expressed, stable enhancer factor for overlapping DNA-binding sites; the relative abundance of the silencer factor contributes to establishing steady-state levels of MHC class I gene expression.

A nuclear factor binds to the metal regulatory elements of the mouse gene encoding metallothionein-I

The ability of vertebrate metallothionein (MT) genes to be induced by heavy metals is controlled by metal regulatory elements (MREs) present in the promoter in multiple, non-identical copies. The binding specificity of the mouse L-cell nuclear factor(s) that interact with the element MREd of the mouse MT-I gene was analyzed by in vitro footprinting, protein blotting, and UV cross-linking assays. In vitro footprinting analyses revealed that synthetic oligodeoxynucleotides (oligomers) corresponding to the metal regulatory elements MREa, MREb, MREc, MREd and MREe of the mouse MT-I gene, as well as the MRE4 of the human MT-IIA gene and the MREa of the trout MT-B gene, all competed for the nuclear protein species binding to the MREd region of the mouse MT-I gene, the MREe oligomer being the weakest competitor. In addition, protein blotting experiments revealed that a nuclear protein of 108 kDa, termed metal element protein-1 (MEP-1), which specifically binds with high affinity to mouse MREd, binds with different affinities to the other mouse MRE elements, mimicking their relative transcriptional strength in vivo: MREd greater than or equal to MREa = MREc greater than MREb greater than MREe greater than MREf. Similarly, human MRE4 and trout MREa bind to MEP-1. A protein similar in size to MEP-1 was also detected in HeLa-cell nuclear extracts. In UV cross-linking experiments the major protein species, complexed with mouse MREd oligomers, migrated on a denaturating gel with an apparent Mr of 115,000 and was detected using each of the mouse MRE oligomers tested. These results show that a mouse nuclear factor can bind to multiple MREs in mouse, trout, and human MT genes.