Synergistic activation and repression of transcription by Drosophila homeobox proteins

Isolation of coactivators associated with the TATA-binding protein that mediate transcriptional activation

A key step in the regulation of transcription involves interactions between promoter-selective factors and various components of the transcriptional apparatus. Here we report the requirements for transcriptional activation directed by NTF-1, a developmentally regulated transcription factor in Drosophila. Reconstituted transcription with fractionated Drosophila basal factors reveals that activation by NTF-1 requires factors present in the endogenous TFIID fraction that are distinct from the purified TATA-binding protein (TBP). Glycerol gradient sedimentation and immunoprecipitation analyses indicate that TFIID is a multiprotein complex containing TBP and at least six tightly bound TBP-associated factors (TAFs). Preparations of TBP lacking TAFs after fractionation with denaturants no longer support activation by NTF-1 but retain basal level activity. Addition of immunopurified and renatured TAFs to free TBP restores the ability of NTF-1 to activate transcription without influencing basal transcription. These results suggest that one or more of the TAF polypeptides confer coactivator function.

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.

Alteration of homeobox gene expression by N-ras transformation of PA-1 human teratocarcinoma cells

We used a series of cell clones from a human teratocarcinoma cell line, PA-1, to study the effect of transformation by an activated N-ras oncogene on the expression of genes involved in retinoic acid (RA)-induced differentiation and growth regulation. Recently, it has been shown that expression of human HOX 2 genes is sequentially activated by RA beginning from Hox 2.9 at the 3' end of the HOX 2 cluster (A. Simeone, D. Acampora, L. Arcioni, P. W. Andrews, E. Boncinelli, and F. Mavilio, Nature [London] 346:763-766, 1990). We now report that six different genes of the cluster HOX 1 are sequentially induced by RA in a similar temporal pattern, beginning with genes at the 3' end of the cluster. However, in N-ras-transformed cell clones, RA-induced expression of these homeobox genes is delayed. Hox 1.4 and Hox 1.3, genes abundantly induced in nontransformed clones after 3 days of RA treatment, are expressed in N-ras-transformed cells only after 10 days of RA treatment. At this time, the cells' growth is arrested at very high density, and no differentiated morphologic characteristics are observed. Constitutive expression of a transfected Hox 1.4 gene under the control of a simian virus 40 promotor leads to differentiated cell morphology similar to that of the RA-induced phenotype and restores the growth-inhibitory effects of RA in N-ras-transformed cells. These observations provide evidence that enhanced proliferation in N-ras-transformed cells compromises teratocarcinoma cell differentiation by a mechanism that transiently suppresses homeobox gene induction and implies a central role for homeobox genes in RA-induced cell differentiation. We conclude that stimulation of a putative growth factor signal pathway, associated with ras-induced proliferation, transiently suppresses the induction of transcription factors functionally involved in cell growth and differentiation.

DNA-binding specificity of the fushi tarazu homeodomain

The fushi tarazu (ftz) gene of Drosophila melanogaster encodes a homeodomain-containing transcription factor that functions in the formation of body segments. Here we report an analysis of the DNA-binding properties of the ftz homeodomain in vitro. We provide evidence that the homeodomain binds to DNA as a monomer, with an equilibrium dissociation constant of 2.5 x 10(-11) M for binding to a consensus binding site. A single ftz binding site occupies 10 to 12 bp, as judged by the ability of protein bound at one site to interfere with binding to an adjacent site. These experiments also demonstrated a lack of cooperative binding between ftz homeodomains. Analysis of single-nucleotide substitutions over an 11-bp sequence shows that a stretch of 6 bp is critical for binding, with an optimal sequence of 5'CTAATTA3'. These data correlate well with recent structural evidence for base-specific contact at these positions. In addition, we found that sequences flanking the region of direct contact have effects on DNA binding that could be of biological significance.

Coordinate regulation of HOX genes in human hematopoietic cells

Hematopoiesis is a continuous process in which precursor cells proliferate and differentiate throughout life. However, the molecular mechanisms that govern this process are not clearly defined. Homeobox-containing genes, encoding DNA-binding homeodomains, are a network of genes highly conserved throughout evolution. They are organized in clusters expressed in the developing embryo with a positional hierarchy. We have analyzed expression of the four human HOX loci in erythroleukemic, promyelocytic, and monocytic cell lines to investigate whether the physical organization of human HOX genes reflects a regulatory hierarchy involved in the differentiation process of hematopoietic cells. Our results demonstrate that cells representing various stages of hematopoietic differentiation display differential patterns of HOX gene expression and that HOX genes are coordinately switched on or off in blocks that may include entire loci. The entire HOX4 locus is silent in all lines analyzed and almost all the HOX2 genes are active in erythroleukemic cells and turned off in myeloid-restricted cells. Our observations provide information about the regulation of HOX genes and suggest that the coordinate regulation of these genes may play an important role in lineage determination during early steps of hematopoiesis.

DNA-binding specificity of the fushi tarazu homeodomain

The fushi tarazu (ftz) gene of Drosophila melanogaster encodes a homeodomain-containing transcription factor that functions in the formation of body segments. Here we report an analysis of the DNA-binding properties of the ftz homeodomain in vitro. We provide evidence that the homeodomain binds to DNA as a monomer, with an equilibrium dissociation constant of 2.5 x 10(-11) M for binding to a consensus binding site. A single ftz binding site occupies 10 to 12 bp, as judged by the ability of protein bound at one site to interfere with binding to an adjacent site. These experiments also demonstrated a lack of cooperative binding between ftz homeodomains. Analysis of single-nucleotide substitutions over an 11-bp sequence shows that a stretch of 6 bp is critical for binding, with an optimal sequence of 5'CTAATTA3'. These data correlate well with recent structural evidence for base-specific contact at these positions. In addition, we found that sequences flanking the region of direct contact have effects on DNA binding that could be of biological significance.

Alteration of homeobox gene expression by N-ras transformation of PA-1 human teratocarcinoma cells

We used a series of cell clones from a human teratocarcinoma cell line, PA-1, to study the effect of transformation by an activated N-ras oncogene on the expression of genes involved in retinoic acid (RA)-induced differentiation and growth regulation. Recently, it has been shown that expression of human HOX 2 genes is sequentially activated by RA beginning from Hox 2.9 at the 3' end of the HOX 2 cluster (A. Simeone, D. Acampora, L. Arcioni, P. W. Andrews, E. Boncinelli, and F. Mavilio, Nature [London] 346:763-766, 1990). We now report that six different genes of the cluster HOX 1 are sequentially induced by RA in a similar temporal pattern, beginning with genes at the 3' end of the cluster. However, in N-ras-transformed cell clones, RA-induced expression of these homeobox genes is delayed. Hox 1.4 and Hox 1.3, genes abundantly induced in nontransformed clones after 3 days of RA treatment, are expressed in N-ras-transformed cells only after 10 days of RA treatment. At this time, the cells' growth is arrested at very high density, and no differentiated morphologic characteristics are observed. Constitutive expression of a transfected Hox 1.4 gene under the control of a simian virus 40 promotor leads to differentiated cell morphology similar to that of the RA-induced phenotype and restores the growth-inhibitory effects of RA in N-ras-transformed cells. These observations provide evidence that enhanced proliferation in N-ras-transformed cells compromises teratocarcinoma cell differentiation by a mechanism that transiently suppresses homeobox gene induction and implies a central role for homeobox genes in RA-induced cell differentiation. We conclude that stimulation of a putative growth factor signal pathway, associated with ras-induced proliferation, transiently suppresses the induction of transcription factors functionally involved in cell growth and differentiation.

A human Hox 1 homeobox gene exhibits myeloid-specific expression of alternative transcripts in human hematopoietic cells

As part of a survey of the expression of homeobox-containing genes in human hematopoietic cells, we identified a novel gene (PL1) expressed only in cells of the myelomonocytic lineage (Shen et al., Proc. Natl. Acad. Sci, USA 86, 8536, 1989). On Northern gel analysis, major transcripts of 3.0 and 2.2 kb length are observed. Alternatively spliced homeobox-containing cDNAs, corresponding to the major transcripts, have been cloned from two myeloid leukemia cell libraries. The two cDNAs share the homeodomain and 3' flanking region but have unique 5' flanking regions. The longer transcript, would encode a 496 amino acid homeobox-containing protein, while the shorter message would encode a 94 amino acid homeobox-containing protein lacking the extended amino-terminal region. These two transcripts are differentially expressed in human leukemia cell lines. The larger transcript is exclusively expressed in cells with myelomonocytic features, while the smaller transcript is expressed in a variety of hematopoietic cell types. PL mRNA is also detectable in normal human bone marrow by RNAse protection. Neither transcript is expressed in uninduced teratocarcinoma cells or in the adult human tissues surveyed. The homeodomain is identical to the genomic sequence for Hox 1H, a newly identified member of the Hox 1 locus (Acampora et al. Nucl. Acids Res. 17, 10385, 1989). The PL1 gene was localized to chromosome 7 using chromosome specific blots and sublocalized to region pI4-21 by in situ hybridization of chromosomal spreads, confirming its location within the Hox 1 complex.

Synthetic oligonucleotides recreate Drosophila fushi tarazu zebra-stripe expression

A complex array of activator and repressor elements located within 669 bp proximal to the fushi tarazu (ftz) transcriptional start site is sufficient to generate the "zebra-stripe" expression pattern characteristic of the ftz gene. P-element-mediated transformation and ftz promoter/lacZ fusion genes were used to characterize, in detail, several of these transcriptional control elements. By reconstructing promoters with synthetic oligonucleotides containing cis-regulators of stripe expression, we show that these regulatory sites can function as independent units to direct position-specific transcription in the Drosophila embryo. In particular, we demonstrate that multiple copies of a positive regulatory site can mediate expression in both the odd- and even-numbered parasegments throughout most of the germ band and that negative regulatory sites can transform a continuous pattern of gene expression into discrete stripes. The reconstructed promoter system presented provides an effective means of studying molecular mechanisms governing spatially restricted transcription in the early embryo.

Identification and characterization of a novel repressor of beta-interferon gene expression

We have identified and characterized a novel repressor of human beta-interferon (beta-IFN) gene expression. This protein, designated PRDI-BF1, binds specifically to the PRDI element of the beta-IFN gene promoter and is distinct from previously reported proteins that bind to this sequence. PRDI-BF1 is an 88-kD protein containing five zinc-finger motifs. Cotransfection experiments in cultured mammalian cells revealed that PRDI-BF1 is a potent repressor of PRDI-dependent transcription. PRDI-BF1 blocks virus induction of the intact beta-IFN gene promoter and of synthetic promoters containing multiple PRDI sites. PRDI-BF1 can also block the SV40 enhancer when PRDI sites are located between the enhancer and the promoter. This repression is highly dependent on the location of the PRDI sites, however, indicating that PRDI-BF1 cannot act at a distance. On the basis of the properties of PRDI-BF1 and the observation that PRDI-BF1 mRNA accumulation is virus inducible, we propose that PRDI-BF1 may act as a postinduction repressor of the beta-IFN gene by displacing positive regulatory proteins from the PRDI site of the promoter.

Transcriptional regulation of a pair-rule stripe in Drosophila

The periodic, seven-stripe pattern of the primary pair-rule gene even-skipped (eve) is initiated by crude, overlapping gradients of maternal and gap gene proteins in the early Drosophila embryo. Previous genetic studies suggest that one of the stripes, stripe 2, is initiated by the maternal morphogen bicoid (bcd) and the gap protein hunchback (hb), while the borders of the stripe are formed by selective repression, involving the gap protein giant (gt) in anterior regions and the Krüppel (Kr) protein in posterior regions. Here, we present several lines of evidence that are consistent with this model for stripe 2 expression, including in vitro DNA-binding experiments and transient cotransfection assays in cultured cells. These experiments suggest that repression involves a competition or short-range quenching mechanism, whereby the binding of gt and Kr interferes with the binding or activity of bcd and hb activators at overlapping or neighboring sites within the eve stripe 2 promoter element. Such short-range repression could reflect a general property of promoters composed of multiple, but autonomous regulatory elements.

Repression of hsp70 heat shock gene transcription by the suppressor of hairy-wing protein of Drosophila melanogaster

The suppressor of hairy-wing [su(Hw)] locus of Drosophila melanogaster encodes a zinc finger protein that binds a repeated motif in the gypsy retroposon. Mutations of su(Hw) suppress the phenotypes associated with mutations caused by gypsy insertions. To examine the mechanisms by which su(Hw) alters gene expression, a fragment of gypsy containing multiple su(Hw) protein-binding sites was inserted into various locations in the well-characterized Drosophila hsp70 heat shock gene promoter. We found no evidence for activation of basal hsp70 transcription by su(Hw) protein in cultured Drosophila cells but observed that it can repress heat shock-induced transcription. Repression occurred only when su(Hw) protein-binding sites were positioned between binding sites for proteins required for heat shock transcription. We propose that su(Hw) protein interferes nonspecifically with protein-protein interactions required for heat shock transcription, perhaps sterically, or by altering the ability of DNA to bend or twist.

Repression of hsp70 heat shock gene transcription by the suppressor of hairy-wing protein of Drosophila melanogaster

The suppressor of hairy-wing [su(Hw)] locus of Drosophila melanogaster encodes a zinc finger protein that binds a repeated motif in the gypsy retroposon. Mutations of su(Hw) suppress the phenotypes associated with mutations caused by gypsy insertions. To examine the mechanisms by which su(Hw) alters gene expression, a fragment of gypsy containing multiple su(Hw) protein-binding sites was inserted into various locations in the well-characterized Drosophila hsp70 heat shock gene promoter. We found no evidence for activation of basal hsp70 transcription by su(Hw) protein in cultured Drosophila cells but observed that it can repress heat shock-induced transcription. Repression occurred only when su(Hw) protein-binding sites were positioned between binding sites for proteins required for heat shock transcription. We propose that su(Hw) protein interferes nonspecifically with protein-protein interactions required for heat shock transcription, perhaps sterically, or by altering the ability of DNA to bend or twist.

wimp, a dominant maternal-effect mutation, reduces transcription of a specific subset of segmentation genes in Drosophila

wimp is a dominant maternal-effect mutation that interacts with a specific subset of early-acting maternal and zygotic Drosophila genes. We show that wimp is a change-of-function mutation, allelic to mutations of the 140-kD subunit of RNA polymerase, which causes reduced transcription of interacting genes. Loci that do not interact with wimp are expressed at normal levels. We discuss these results in terms of specific interactions between transcription factors and RNA polymerase. Embryos from wimp mothers show unaltered fate maps and develop normally, despite the reduction of transcript levels at least twofold. We suggest that spatial cues are determined by a balance of segmentation gene products rather than their absolute concentrations. We also demonstrate powerful genetic screens for otherwise undetected loci required for segmentation, sex determination, and other early functions.

An enhancer at the 3' end of the mouse immunoglobulin heavy chain locus

A tissue-specific enhancer (E mu) lies between the joining (JH) and mu constant region (C mu) gene segments of the immunoglobulin heavy chain (IgH) locus. Since mouse endogenous IgH genes are efficiently transcribed in its absence, the normal function of this enhancer remains ill-defined. Recently, another lymphoid-specific enhancer of equal strength has been identified 3' of the rat IgH locus. We have isolated an analogous sequence from mouse and have mapped it 12.5 kb 3' of the 3'-most constant region gene (C alpha-membrane) of the BALB/c mouse locus. The mouse and rat sequences are 82% homologous and share with other enhancers several DNA sequence motifs capable of binding protein. However, in transient transfection assays, the mouse sequence behaves as a weaker enhancer. The role of this distant element in the expression of endogenous IgH genes, both in E mu-deficient, Ig-producing cell lines and during normal B cell development, is discussed.

The oncogenic potential of an activated Hox-2.4 homeobox gene in mouse fibroblasts

The homeobox gene Hox-2.4 is transcriptionally activated in cells of the mouse myeloid leukemia WEHI-3B. The constitutive Hox-2.4 expression in WEHI-3B cells is due to insertion of a transposable element belonging to the family of intracisternal A particles. In this study, we demonstrated the oncogenic potential of this activated homeobox gene. NIH 3T3 fibroblast clones bearing the activated Hox-2.4 gene produced fibrosarcomas in nude mice.

Autoregulation of a segmentation gene in Drosophila: combinatorial interaction of the even-skipped homeo box protein with a distal enhancer element

Autoregulation has been implicated in the expression of many patterning genes in Drosophila, but the molecular details of this process are largely unknown. In the case of the segmentation gene even-skipped (eve), autoregulation is important for the specification of sharp stripes of gene expression at the onset of gastrulation. Here, we use a combination of DNA binding and P-transformation assays to characterize the cis- and trans-acting factors responsible for autoregulation. We show that eve autoregulation is mediated, at least in part, by a 100-bp minimal autoregulatory sequence (MAS) located approximately 5 kb upstream from the eve transcription start site. Multimerization of a 200-bp DNA fragment that encompasses the MAS drives optimal autoregulatory activity, comparable to that obtained with the native distal enhancer element located between -5.9 and -5.2 kb. The MAS contains two eve protein-binding sites, as well as binding sites for two nuclear factors present in early embryos. Directed mutagenesis of these binding sites suggests that both the eve protein and nuclear factors are essential for autoregulation. These results provide evidence that the eve protein acts combinatorially with other transcription factors to enhance its own expression.

Yolk polypeptide gene expression in cultured Drosophila cells

The transfer of chimaeric plasmids to Drosophila melanogaster cell lines has been examined as a system for investigation of the hormonal regulation of the genes coding for D. melanogaster yolk polypeptide 1 (YP1) and Locusta migratoria vitellogenin B (VgB). Constructs containing promoters and putative 5'-regulatory sequences from these genes, ligated to bacterial chloramphenicol acetyltransferase (CAT) coding DNA, were transfected into Drosophila Kc (Kc-H) and S3 cells, and transient expression of CAT was assayed. Activity was expressed both from the homologous promoter of pYP1CAT and from the heterologous locust promoter of pVgCAT at comparable levels. In S3 cells, with calcium phosphate-mediated transfer of pYP1CAT there was a twofold induction of CAT activity after the addition of 10(-6) M ecdysterone, but no hormonal stimulation was noted when the polycation polybrene was used to achieve transfection. For Kc cells, calcium phosphate was ineffective for transfection, and after transfection with polybrene neither pYP1CAT nor pVgCAT was induced by the juvenile hormone (JH) analog methoprene. It is concluded that S3 cells may be useful for investigating the molecular basis of gene regulation by ecdysteroids, but conditions suitable for the analysis of JH action have not yet been established.

Activation and repression of transcription by the gap proteins hunchback and Krüppel in cultured Drosophila cells

We have studied the ability of the Drosophila gap proteins Krüppel and hunchback to function as transcriptional regulators in cultured cells. Both proteins bind to specific sites in a 100-bp DNA fragment located upstream of the segment polarity gene engrailed, which also contains functional binding sites for a number of homeo box proteins. The hunchback protein is a strikingly concentration-dependent activator of transcription, capable of functioning both by itself and also synergistically with the pair-rule proteins fushi tarazu and paired. In contrast, Krüppel is a transcriptional repressor that can block transcription induced either by hunchback or by several different homeo box proteins. While repression of the homeo box protein activators requires a Krüppel-binding site on the DNA, repression of hunchback can occur efficiently in the absence of a Krüppel-binding site. We discuss the possible molecular mechanisms underlying these activities, as well as the potential significance of these results with respect to segmentation in Drosophila.

High-affinity binding sites for the Deformed protein are required for the function of an autoregulatory enhancer of the Deformed gene

The homeotic selector gene Deformed (Dfd) is required to specify the identity of head segments during Drosophila development. Previous experiments have shown that for the Dfd segmental identity function to operate in epidermal cells, the Dfd gene must be persistently expressed. One mechanism that provides persistent embryonic expression of Dfd is an autoregulatory circuit. Here, we show that the control of this autoregulatory circuit is likely to be directly mediated by the binding of Dfd protein to an upstream enhancer in Dfd locus DNA. In a 25-kb region around the Dfd transcription unit, restriction fragments with the highest binding affinity for Dfd protein map within the limits of the upstream autoregulatory element at approximately -5 kb. A minimal autoregulatory element, within a 920-bp segment of upstream DNA, has four moderate- to high-affinity binding sites for Dfd protein, with the two highest affinity sites sharing an ATCATTA consensus sequence. Site-specific mutagenesis of these four sites results in an element that has low affinity for Dfd protein when assayed in vitro and is nonfunctional when assayed in embryos.

Positive and negative regulatory elements mediating transcription from the Drosophila melanogaster actin 5C distal promoter

The major cytoskeletal actin gene of Drosophila melanogaster, the actin 5C gene, has two promoters, the distal one of which controls synthesis of actin in a tissue- and developmental stage-specific manner. This very strong promoter has widely been used for expression of heterologous genes in cultured cells. To locate functional regulatory elements in this distal promoter, mutants of the promoter were fused to the bacterial chloramphenicol acetyltransferase gene and assayed for transient expression activity in cultured Drosophila embryonic Schneider line 2 cells. The results showed that the upstream end of the promoter extends to 522 bp from the transcription start site. In addition, there are two remote activating regions about 2 kb upstream. Between -522 and -379 are two regions that exert a strong negative effect. Downstream from these negative regions are at least six positive regions and a TATA element. The strongest positive determinant of the promoter was identified at -320 as AAAATGTG by footprinting and by a replacement experiment. When the relevant region was replaced by a synthetic sequence containing this element in a random context, the transient expression activity was restored. The sequence TGTATG located at -355 was also identified as a positive element by a similar replacement approach. Apparently the very high activity of this promoter is the result of the combined activities of multiple factors.

The oncogenic potential of an activated Hox-2.4 homeobox gene in mouse fibroblasts

The homeobox gene Hox-2.4 is transcriptionally activated in cells of the mouse myeloid leukemia WEHI-3B. The constitutive Hox-2.4 expression in WEHI-3B cells is due to insertion of a transposable element belonging to the family of intracisternal A particles. In this study, we demonstrated the oncogenic potential of this activated homeobox gene. NIH 3T3 fibroblast clones bearing the activated Hox-2.4 gene produced fibrosarcomas in nude mice.

Modulation of the IgH enhancer's cell type specificity through a genetic switch

Using defined regions of the immunoglobulin heavy-chain enhancer linked to minimal promoters and cDNAs that encode the two helix-loop-helix transcription factors ITF-1 and TFE3, we demonstrate that activity of an otherwise repressed enhancer can be stimulated in nonlymphoid cells. Repression in non-B cells is mediated by the microE5 motif. Derepression occurs at two levels. First, overexpression of ITF-1, and E12/E47-related protein that binds the microE5 motif, leads to transcriptional activation itself. Second, binding of ITF-1 physically displaces a repressor that normally blocks the stimulatory activity of TFE3, which binds the neighboring microE3 motif. TFE3 can only stimulate enhancer activity in the presence of ITF-1 or in the absence of a microE5 motif. Hence, one component of the enhancer's cell type specificity can be artificially modulated through a "genetic switch" in which activity is dictated by the relative levels of ITF-1 and a competing repressor.

Network of interactions among pair-rule genes regulating paired expression during primordial segmentation of Drosophila

A model of the trans-regulation of the Drosophila pair-rule segmentation gene, paired (prd), has been derived from the observed alterations in the distribution of prd transcripts during early embryogenesis in single and double pair-rule mutants. Important aspects of the model include the following features and implications: (i) The regulation of prd is subject to a regulatory hierarchy among pair-rule genes. In particular, it shows that prd is at the bottom of this hierarchy, mediating the transition from pair-rule to segment-polarity genes. The transition of the early 'pair-rule' to the 'segment-polarity' pattern of prd expression is regulated by the secondary pair-rule genes opa and odd. The model predicts the distributions of pair-rule gene products regulating prd at late syncytial blastoderm, e.g., that of opa. (ii) The initial activation of prd is independent of pair-rule genes. (iii) The regulation of prd is combinatorial and hence probably cooperative. Combination of one pair-rule gene product with different pair-rule proteins may lead to opposite regulatory effects on prd. Furthermore, we discuss a two-step conversion of the initial analogue specification of position along the anteroposterior axis into a digital code specified by combinations of active segment-polarity and homeotic genes.

Positive and negative regulatory elements mediating transcription from the Drosophila melanogaster actin 5C distal promoter

The major cytoskeletal actin gene of Drosophila melanogaster, the actin 5C gene, has two promoters, the distal one of which controls synthesis of actin in a tissue- and developmental stage-specific manner. This very strong promoter has widely been used for expression of heterologous genes in cultured cells. To locate functional regulatory elements in this distal promoter, mutants of the promoter were fused to the bacterial chloramphenicol acetyltransferase gene and assayed for transient expression activity in cultured Drosophila embryonic Schneider line 2 cells. The results showed that the upstream end of the promoter extends to 522 bp from the transcription start site. In addition, there are two remote activating regions about 2 kb upstream. Between -522 and -379 are two regions that exert a strong negative effect. Downstream from these negative regions are at least six positive regions and a TATA element. The strongest positive determinant of the promoter was identified at -320 as AAAATGTG by footprinting and by a replacement experiment. When the relevant region was replaced by a synthetic sequence containing this element in a random context, the transient expression activity was restored. The sequence TGTATG located at -355 was also identified as a positive element by a similar replacement approach. Apparently the very high activity of this promoter is the result of the combined activities of multiple factors.

Altering the regulatory targets of the Deformed protein in Drosophila embryos by substituting the Abdominal-B homeodomain

The homeotic selector genes of Drosophila melanogaster encode transcriptional regulatory proteins that control the determination of different segmental fates. Binding of selector proteins to regulatory DNA sequences is mediated by an evolutionary conserved protein domain, the homeodomain. Although homeodomains encoded by the selector genes are very similar in their amino acid sequence and in vitro DNA-binding properties, here we provide additional evidence that the homeodomain is responsible for most of the regulatory specificity of the entire protein. A heat-shock promoter/selector gene was constructed that encodes a Deformed/Abdominal-B chimera in which the Abdominal-B homeodomain is substituted for that of Deformed. Expression of this chimeric protein throughout the embryo causes morphological transformation of anterior segments toward more posterior identities. A number of other homeotic selector genes, all normally repressed by Abdominal-B, are ectopically activated by the chimeric protein. These results support the hypothesis that the target specificity of similar homeodomain proteins is largely determined by the amino acid sequence of the homeodomain.

Regulation of a human epidermal keratin gene: sequences and nuclear factors involved in keratinocyte-specific transcription

The keratinocyte is a major cell type of the body, and in epidermis, keratinocytes have potential for future gene targeting and drug therapy. Despite the importance of keratinocytes in cell biology and medicine, little is known about the molecular mechanisms underlying keratinocyte-specific gene expression. Here, we report the first detailed characterization of the sequences and factors controlling expression of a human gene expressed specifically in keratinocytes. Using 5' upstream sequence of the human K14 keratin gene coupled to one of two reporter genes, we examined sequences necessary and sufficient for expression of K14 in both cultured human keratinocytes and in mitotically active basal keratinocytes of transgenic mouse epidermis. We demonstrated the existence of distal and proximal elements located 5' from the transcription initiation site of the hK14 gene, which when combined with a TATA box element, appear to act in concert to drive keratinocyte-specific expression. We examined the proximal region in detail. After using CAT assays to narrow a transcriptional activation element to within 110 bp, we demonstrated the existence of a keratinocyte nuclear factor which binds to a 10-bp palindrome, 5'-GCCTGCAGGC-3', within this domain. Using methylation interference analysis, we identified the G residues important for factor binding, and showed that point mutations in these G residues not only blocked factor binding but also resulted in decreased transcriptional activity of an hK14-CAT gene. The factor was most abundant in keratinocytes, was expressed at lower levels in some simple epithelial cell lines, and was not detected in fibroblasts or lymphoma cells. Moreover, the 10-bp sequence was similar to sequences found in the 5' upstream sequences of several other genes expressed in keratinocytes, and at least one of these genes, the human K1 gene, contained a sequence that competed with the hK14 proximal element for binding factor. Collectively, our data suggest that both the sequence and the nuclear factor that we have identified may be involved in controlling keratinocyte-specific expression in vitro and in vivo.

Molecular interactions within the ecdysone regulatory hierarchy: DNA binding properties of the Drosophila ecdysone-inducible E74A protein

The E74 early ecdysone-inducible gene plays a key role in the regulatory hierarchy activated by ecdysone at the onset of Drosophila metamorphosis. We show here that E74A protein binds to three adjacent sites in the middle of the E74 gene. The consensus sequence for E74A protein binding, determined by random-sequence oligonucleotide selection, contains an invariant purine-rich core sequence, C/AGGAA. This sequence is also present in the binding sites of two mammalian proteins that, like E74A, are related to the ets oncoprotein. Antibody staining of larval salivary gland polytene chromosomes revealed that E74A protein binds to both early and late ecdysone-inducible puffs. This study supports Ashburner's proposal that the early puffs encode site-specific DNA binding proteins that directly interact with the early and late ecdysone-inducible puffs.

The specificities of Sex combs reduced and Antennapedia are defined by a distinct portion of each protein that includes the homeodomain

The sequence requirements for distinguishing the functional specificities of two homeodomain proteins, Antennapedia and Sex combs reduced, involved in the specification of segmental identities in Drosophila, have been determined. A series of deletions and hybrid proteins was generated and assayed for their function in vivo after heat shock-induced ectopic expression during development. A distinct portion of each protein, including the residues within and adjacent to both ends of the homeodomain, has been found to almost entirely determine its functional specificity as measured by diagnostic cuticular transformations of embryonic and adult head structures. The remaining sequences contribute to the potency with which the proteins act in different cells and are to a limited extent functionally transferable from one protein to the other.

The Drosophila even-skipped promoter is transcribed in a stage-specific manner in vitro and contains multiple, overlapping factor-binding sites

To investigate the factors contributing to regulation of expression of the Drosophila segmentation gene even-skipped (eve), we have analyzed both the in vitro transcription and eve-promoter-binding proteins in embryo extracts. We show that the eve promoter is accurately and efficiently expressed in nuclear extracts derived from Drosophila embryos and that transcription is more efficient in extracts prepared from embryos at early stages of development than in those from older embryos, broadly reproducing the temporal pattern of expression observed in vivo. This stage-specific expression is dependent on sequences upstream of the eve transcription start site which contain multiple binding sites for at least two distinct proteins present in embryo nuclei. One of these proteins, the binding sites for which correspond to the sequences required for stage-specific expression, appears to be the previously described GAGA factor. Although the binding activity of the GAGA factor remains constant, the level of the binding activity of the other protein, which we have called the TCCT factor, changes during the course of embryogenesis. Activity is first detected 3 to 5 h after fertilization and decreases during later stages of embryogenesis. We discuss the possibility that the TCCT factor plays a role in the maintenance or refinement of the eve expression pattern.

Ig/EBP-1: a ubiquitously expressed immunoglobulin enhancer binding protein that is similar to C/EBP and heterodimerizes with C/EBP

We report the isolation and characterization of cDNA clones that encode a protein with the same DNA binding specificity as the immunoglobulin heavy chain enhancer binding protein E (muEBP-E). We call the gene encoding this protein Ig/EBP-1. A fusion protein encoded by the cDNA binds specifically to muEBP-E-binding sites (E sites) in both the IgH enhancer and the VH1 promoter. Sequence analysis reveals that Ig/EBP-1 is a member of the "basic-zipper" family of DNA-binding proteins that are characterized by basic regions and heptad repeats of leucine residues. Among known family members, Ig/EBP-1 demonstrates highest homology to C/EBP throughout the DNA-binding domain and leucine repeat region. Ig/EBP-1 and C/EBP have highly overlapping binding specificities; both cloned proteins bind to the IgH enhancer and the VH1 promoter E sites, and Ig/EBP-1 binds to previously characterized C/EBP binding sites in the Rous sarcoma virus (RSV) LTR and the murine albumin promoter. Consistent with their homology in the leucine repeat region, Ig/EBP-1 and C/EBP form heterodimers; Ig/EBP-1 is the first member of this family that has been found to heterodimerize with the well-characterized C/EBP. Ig/EBP-1 mRNA is present in all tissues and cell lines examined, although its levels vary almost 20-fold from different sources, with highest levels in early B cells. In tissues where Ig/EBP-1 and C/EBP are both present, heterodimers may be functionally important. The presence of Ig/EBP-1 in fibroblasts and other tissues where C/EBP is not expressed suggests that Ig/EBP-1 may be functionally important for the activity of the RSV enhancer in these cell types. Finally, elevated expression of Ig/EBP-1 in early B cells may explain in part the enhancer-independent activity of VH promoters early in B-cell development.

The Drosophila even-skipped promoter is transcribed in a stage-specific manner in vitro and contains multiple, overlapping factor-binding sites

To investigate the factors contributing to regulation of expression of the Drosophila segmentation gene even-skipped (eve), we have analyzed both the in vitro transcription and eve-promoter-binding proteins in embryo extracts. We show that the eve promoter is accurately and efficiently expressed in nuclear extracts derived from Drosophila embryos and that transcription is more efficient in extracts prepared from embryos at early stages of development than in those from older embryos, broadly reproducing the temporal pattern of expression observed in vivo. This stage-specific expression is dependent on sequences upstream of the eve transcription start site which contain multiple binding sites for at least two distinct proteins present in embryo nuclei. One of these proteins, the binding sites for which correspond to the sequences required for stage-specific expression, appears to be the previously described GAGA factor. Although the binding activity of the GAGA factor remains constant, the level of the binding activity of the other protein, which we have called the TCCT factor, changes during the course of embryogenesis. Activity is first detected 3 to 5 h after fertilization and decreases during later stages of embryogenesis. We discuss the possibility that the TCCT factor plays a role in the maintenance or refinement of the eve expression pattern.

The c-ets proto-oncogenes encode transcription factors that cooperate with c-Fos and c-Jun for transcriptional activation

Cell transformation by oncogenes leads to changes in gene expression. A key event in this process seems to be activation of the transcription factors AP-1 and PEA 3. Their synergistic activities are required for efficient activation of transcription from different promoters by many different oncogenes, serum growth factors and the tumour promoter TPA. We show here that the products of the ets-1 and -2 proto-oncogenes, whose biological function was previously unknown, are transcription factors that activate transcription through the PEA 3 motif. The p68c-ets-1 protein specifically binds to DNA and contains a transcriptional activation domain. The ets-like gene family therefore seems to encode a new family of transcription factors, apparently unrelated to other transcription factors. The p68c-ets-1 protein cooperates with c-Fos and c-Jun (components of AP-1) for activation of transcription from the oncogene-responsive domain of the polyoma enhancer, indicating that combined activity of all three oncoproteins could be involved in the response of cells to growth stimuli.

Drosophila Krüppel protein is a transcriptional repressor

Krüppel (Kr), one of the zygotically active Drosophila segmentation genes, is expressed in a restricted domain during the blastoderm stage of embryogenesis and is involved in the control of development of the thoracic and abdominal segments of the fly. Kr encodes a polypeptide containing DNA-binding zinc-finger motifs, disruptions of which yield Kr mutants. We have assayed the transcriptional activities of wild-type Kr protein as well as Lac repressor/Kr fusion proteins in HeLa and CV-1 cells. Wild-type Kr and a Lac-Kr chimaeric protein repressed transcription from reporter promoters in which a consensus Kr binding site derived from sequences within the even-skipped promoter had been inserted in an upstream position. We mapped the repression function of Kr to an alanine-rich amino-terminal region of the protein, as a Lac/Kr fusion protein containing only amino acids 26-110 of Kr repressed transcription from a reporter promoter containing upstream lac operators. This demonstrates that the DNA-binding and repression activities of the Kr protein are distinct. These data are consistent with genetic evidence that Kr represses even-skipped and hunchback expression, and suggest that Kr is a negative regulator of transcription in Drosophila.

Region-specific recombination and expression are directed by portions of the Drosophila engrailed promoter

The Drosophila engrailed gene is expressed in the cells of the posterior developmental compartments. To investigate how the engrailed gene is regulated, chimeric genes consisting of fragments of the engrailed promoter and Escherichia coli lacZ were incorporated into the Drosophila germ line by P-element-mediated recombination. Fusion constructs with 7.5 kb of 5'-flanking sequence contain sufficient information to promote expression in most of the embryonic, larval, and imaginal posterior compartments; transformants with smaller fragments of the 5' region do not. Remarkably, of 20 independent transformants with constructs containing more than 1 kb of 5'-flanking DNA, 7 integrated in or around the engrailed locus. These strains inactivate engrailed function to varying degrees, and some express lacZ with a position- and temporal-specific program that is indistinguishable from the normal engrailed gene. Presumably, in these strains, lacZ is expressed in the context of the engrailed promoter.

Analysis of the ftz upstream element: germ layer-specific enhancers are independently autoregulated

The Drosophila fushi tarazu (ftz) upstream element is an enhancer-like element that is required for the correct expression of ftz in developing embryos and that directs transcription from a minimal promoter in a ftz-like seven-striped pattern. Using a deletion analysis, we have identified several independent cis-regulatory elements in the upstream element. A distal enhancer directs fusion gene expression in seven stripes primarily in the mesoderm. A more complex proximal enhancer contains a mesodermally active element and a second element with which it interacts to generate seven stripes in the ectoderm. Striped expression directed by each enhancer is ftz-dependent, and each contains binding sites for purified ftz homeo domain. We suggest that ftz protein acts in combination with germ layer-restricted transcription factors directly and positively to regulate the transcription of its own gene.

Mutations in the Drosophila gene extradenticle affect the way specific homeo domain proteins regulate segmental identity

We characterized a gene, extradenticle, which seems to interact with a specific subset of Drosophila homeo domain proteins, possibly affecting their target specificity. This interpretation is based on an examination of the zygotic and maternal effect phenotypes of extradenticle mutations. In embryos with reduced levels of extradenticle gene product, anterior and posterior segmental transformations occur. Segmental identity in Drosophila is mediated by the products of the Antennapedia and bithorax complexes. These homeo domain proteins are thought to regulate different target genes specifically in each segment, resulting in different morphologies. extradenticle alters segmental identity without affecting the pattern of expression of homeotic genes. Genetic tests demonstrate that in extradenticle mutants, the homeotic proteins are functional and act in their normal segmental domains, yet segmental identities are altered. Even when homeotic proteins are ectopically expressed under the control of a heterologous promoter, extradenticle mutations affect their consequences. Thus, in the absence of sufficient extradenticle product, altered segmental morphology results from alteration of the functional consequences of specific homeo domain proteins, possibly through alterations in their target gene specificity. extradenticle is also expressed maternally. Complete removal of extradenticle, maternally and zygotically, leads to specific alterations in segmentation, many of which result from failure to maintain the expression of the homeo domain protein engrailed.

Fibroin gene promoter contains a cluster of homeodomain binding sites that interact with three silk gland factors

By nuclease protection and mobility shift assays, we have shown that the 5' flanking sequence of the Bombyx mori fibroin gene, which is known to be required for a maximal level of transcription in vitro, contains five regions (A to E) that bind protein factors from the posterior silk gland extract. A silk gland-specific factor (SGF-1) and a ubiquitous factor (FBF-A1) were found to interact with the proximal A region, while the related B region can only bind SGF-1. The three distal regions (C, D and E) bind one posterior silk gland-specific factor (SGF-2) and two ubiquitous factors (SGF-3 and -4). SGF-1 might play an important role in the expression of silk protein genes because it also binds to a similar site in the sericin-1 gene and potential SGF-1 binding sites can be found in two other silk protein genes of Bombyx mori and the fibroin gene of Antheraea yamamai. The three distal regions for SGF-2, -3 and -4 contain ten base-pairs of A + T-rich repeats that resemble the consensus binding site (TCAATTAAAT) of a number of homeodomain proteins. The TAAT motif in the core of these regions is shown to be important for the binding of these three proteins and, as described elsewhere, two Drosophila homeodomain proteins, ZEN (zerknüllt) and EVE (even-skipped). Interestingly, SGF-3 appears to be a Bombyx octamer binding protein and may also be involved in the regulation of the sericin-1 gene. The possibility that the fibroin gene and other silk protein genes may be a group of target genes for some members of the homeobox gene family is discussed.

Stimulation of transcription by an Ultrabithorax protein in vitro

The Ultrabithorax (Ubx) gene of Drosophila melanogaster encodes a family of UBX proteins that are thought to specify the developmental fates of segments in the posterior thorax and anterior abdomen by controlling the expression of a set of target genes. UBX proteins bind DNA in vitro, and they activate or repress different natural and synthetic target promoters in cultured cells. Here it is shown that a purified UBX protein can stimulate transcription of a synthetic target gene in extracts of cultured D. melanogaster cells. Stimulation is dependent on the presence of upstream, promoter-region binding sites but is independent of binding site orientation. A naturally occurring binding site cluster and a binding site consensus sequence consisting of TAA trinucleotide repeats can mediate this activation. A minimal promoter fused to such sites is activated by UBX, suggesting that transcriptional stimulation could result from an interaction between the promoter-bound protein and the general transcriptional machinery.

Modeling the Drosophila pair-rule pattern by reaction-diffusion: gap input and pattern control in a 4-morphogen system

Various reaction-diffusion models will produce striped patterns, but the most effective models so far devised to do this require two matched pairs of interacting morphogens, i.e. four substances in all. This paper examines the behavior of one such model, of a fairly generalized type, and its application to the process of pair-rule pattern formation during Drosophila embryogenesis. It is assumed that the two self-activating morphogens required by the model, expressed in complementary out-of-phase stripes, are products of early-acting pair-rule genes. Possible candidates include the primary pair-rule genes, hairy and runt. The conditions under which regular stripes are generated by the model are then examined, with emphasis on the way pre-existing patterns act to control stripe formation via their effect on rates of reaction within the pair-rule system, specifically rates of pair-rule gene transcription, to show how gap gene products may act during pattern formation. A fully symmetrical set of reactions, in which rates of formation, self- and cross-activation are exactly matched, gives unaligned stripes. Pronounced asymmetries in this regard, e.g. differential rates of formation or self-activation, destabilize stripes or produce local interruptions in the pattern like those seen in gap mutants. A limited degree of asymmetry, coupled with a gradient in the value of one or more parameters will give a correctly aligned, well-controlled pattern of stripes. The experimental evidence indicates that gap genes could be responsible for both of these effects: they activate the pair-rule system asymmetrically and, when first expressed, generate a sufficiently complex landscape of concentration peaks and gradations to provide the local cues needed to correctly position and align the pair-rule stripes. In this respect, the pair-rule system can be viewed as having an intrinsic pattern-forming capability, but it depends on the input of gap genes for pattern control. Gradients are involved, but from this analysis, it is the graded distribution of gap products that is important, not the overall antero-posterior gradient. The uniform spacing of stripes, despite underlying peaks and troughs of gap gene expression, shows that pattern wavelength is relatively insensitive to parameter change, also a property of the model.(ABSTRACT TRUNCATED AT 400 WORDS)

Binding site-dependent direct activation and repression of in vitro transcription by Drosophila homeodomain proteins

Fushi tarazu and engrailed are two of the genes required for proper segmentation of the Drosophila embryo. Their protein products Fushi tarazu and Engrailed (Ftz and En) each contain a homeodomain and have been shown to act as transcriptional regulators in transient expression experiments in a Drosophila cell culture system. We used an in vitro transcription system to test whether the effects of Ftz and En on transcription were direct or indirect. Purified Ftz directly activates in vitro transcription by binding to homeodomain binding sites inserted upstream of the TATA box of the Drosophila hsp70 promoter. Equimolar amounts of purified En repress this activation by competition with Ftz for binding to these sites. These results indicate that Ftz and En act directly as transcription factors and suggest that such homeodomain proteins regulate development by combinatorial transcriptional control.

Specific DNA binding of the two chicken Deformed family homeodomain proteins, Chox-1.4 and Chox-a

The cDNA clones encoding two chicken Deformed (Dfd) family homeobox containing genes Chox-1.4 and Chox-a were isolated. Comparison of their amino acid sequences with another chicken Dfd family homeodomain protein and with those of mouse homologues revealed that strong homologies are located in the amino terminal regions and around the homeodomains. Although homologies in other regions were relatively low, some short conserved sequences were also identified. E. coli-made full length proteins were purified and used for the production of specific antibodies and for DNA binding studies. The binding profiles of these proteins to the 5'-leader and 5'-upstream sequences of Chox-1.4 and Chox-a coding regions were analyzed by immunoprecipitation and DNase I footprint assays. These two Chox proteins bound to the same sites in the 5'-flanking sequences of their coding regions with various affinities and their binding affinities to each site were nearly the same. The consensus sequences of the high and low affinity binding sites were TAATGA(C/G) and CTAATTTT, respectively. A clustered binding site was identified in the 5'-upstream of the Chox-a gene, suggesting that this clustered binding site works as a cis-regulatory element for auto- and/or cross-regulation of Chox-a gene expression.

A sequence-specific DNA-binding protein that activates fushi tarazu segmentation gene expression

The Drosophila segmentation gene fushi tarazu (ftz) is expressed at the cellular blastoderm stage in a pattern of seven transverse stripes; the stripes lie out of register with the segmental primordia, spanning alternate segmental boundaries. The zebra element, a 740-bp DNA sequence upstream of the ftz translational start, directs striped expression of lacZ when introduced into the fly genome. We have purified to homogeneity a sequence-specific DNA-binding factor, FTZ-F1, that binds to two sites located within the zebra element and to two sites within the ftz protein-coding sequence. FTZ-F1 DNA-binding activity is first detected in extracts of 1.5- to 4-hr embryos, coincident with the time of ftz expression in stripes; the activity then diminishes before reappearing during late embryo, larval, and adult stages. When one of the FTZ-F1-binding sequences in the zebra element is mutated by 2- or 4-base substitutions, the binding to FTZ-F1 is disrupted in vitro, and the intensity of lacZ expression is reduced in transformed embryos, especially in stripes 1, 2, 3, and 6. The results suggest that FTZ-F1 is a transcriptional activator necessary for the proper expression of the ftz gene.

Engrailed, a homeodomain protein, can repress in vitro transcription by competition with the TATA box-binding protein transcription factor IID

Engrailed (En) is a homeodomain protein that binds to a consensus sequence (NP) and plays an important role during Drosophila development. Purified En, which is produced in Escherichia coli, binds not only to this consensus sequence but also to the TATA box of the Drosophila Hsp70 promoter and of other eukaryotic promoters. Interestingly, En represses transcription of these promoters in an in vitro-reconstituted mammalian transcription system and footprint analyses show that En competes with the TATA box-binding protein transcription factor IID for binding to the TATA box. In contrast, a stable template-committed complex formed by preincubation of transcription factor IID with the promoter is not disrupted by addition of En, and in this case transcription is not repressed. These in vitro studies suggest a transcriptional repression mechanism, involving competition between En and transcription factor IID for TATA box binding, that may be involved in En-mediated repression in vivo.

Spatial and temporal control elements of the Drosophila engrailed gene

engrailed (en) is a segmentation gene expressed in a series of stripes throughout embryonic development. Here, I show that regulatory sequences for striped expression are present within the first intron of en. The 1-kb intron is able to confer striped expression early, but not late, in development. This shows that different regulatory sequences are required for en stripes at different times in development. Furthermore, stripes generated by the intron are coincident with en stripes in a wild-type background but behave differently from endogenous engrailed stripes in some segmentation mutant backgrounds. Thus, although the intron can induce apparently normal stripes, it lacks some of the regulatory sequences present within the endogenous gene. These experiments suggest that multiple regulatory programs control an expression in stripes, and each may be able to confer "normal" spatial regulation independently.