Phenotypic suppression of empty spiracles is prevented by buttonhead.

Unlike the trunk segments, the anterior head segments of Drosophila are formed in the absence of pair-rule and HOX-cluster gene expression, by the activities of the gap-like genes orthodenticle (otd), empty spiracles (ems) and buttonhead (btd). The products of these genes are transcription factors, but only EMS has a HOX-like homeodomain. Indeed, ems can confer identity to trunk segments when other HOX-cluster gene activities are absent. In trunk segments of wild-type embryos, however, ems activity is prevented by phenotypic suppression, in which more posterior HOX-cluster genes inactivate the more anterior without affecting transcription or translation. ems is suppressed by all other Hox-cluster genes and so is placed at the bottom of their hierarchy. Here we show that misexpression of EMS in the head transforms segment identity in a btd-dependent manner, that misexpression of BTD in the trunk causes ems-dependent structures to develop, and that EMS and BTD interact in vitro. The data indicate that this interaction may allow ems to escape from the bottom of the HOX-cluster gene hierarchy and cause a dominant switch of homeotic prevalence in the anterior-posterior direction.

Common and diverged functions of the Drosophila gene pair D-Sp1 and buttonhead.

The Drosophila gene buttonhead (btd) is required for the formation of the mandibular, the intercalary and the antennal head segments of the embryo. The btd protein (BTD) is functionally and structurally related to the human C(2)H(2) zinc finger transcription factor Sp1. A second Sp1-like Drosophila gene, termed Drosophila Sp1 (D-Sp1), had been identified on the basis of a partial sequence showing that the gene encodes a characteristic zinc finger domain, composed of three finger motifs similar to both Sp1 and btd. D-Sp1 is located in the same cytological location as btd in chromosome band 9A on the X-chromosome. It had been proposed that D-Sp1 and btd are likely to act as a gene pair and function in a at least partially redundant manner. Here we report the molecular analysis of D-Sp1 and its expression pattern during embryonic and larval development. We show that D-Sp1 acts as a transcriptional regulator. Lack-of-function analysis combined with rescue and gain-of-function studies indicates that btd and D-Sp1 play essential and redundant roles for mechanosensory organ development. However, D-Sp1 lacks the specific features of BTD required for embryonic intercalary and antennal segment formation.

Drosophila head segmentation factor buttonhead interacts with the same TATA box-binding protein-associated factors and in vivo DNA targets as human Sp1 but executes a different biological program.

The Drosophila gene buttonhead (btd) is required for the establishment of three embryonic head segments. It encodes a zinc-finger-type transcription factor expressed in the corresponding head segment anlagen in the blastoderm stage embryo. The DNA-binding properties of the btd protein (BTD) are indistinguishable from the human transcription factor Sp1. Furthermore, BTD and Sp1 are capable of activating transcription in transfected cultured cells through interaction with the same DNA target sites. Herein we show that BTD and Sp1 functionally interact with the same TATA box-binding protein-associated factors and support in vitro transcription activation through these contacts. Transgene expression of BTD results in the rescue of the head segments that fail to develop in btd mutant embryos, whereas Sp1 or Sp1 containing the zinc finger region of BTD rescues mandibular segment development. The results suggest that BTD contains functional domains other than an equivalent DNA-binding region and interaction sites of the TATA box-binding protein-associated factors, which are necessary to establish head segments that fail to develop in response to Sp1.

buttonhead and D-Sp1: a novel Drosophila gene pair.

The Drosophila gene buttonhead (btd) is a gap-like head segmentation gene which encodes a triple zinc finger protein structurally and functionally related to the human transcription factor Spl. Here we report the pattern of btd expression during embryogenesis. btd is not only expressed and required in the blastoderm anlagen of the antennal, intercalary and mandibular segments as reported previously, but both expression and requirement extend into the anlage of the maxillary segment. From gastrulation onwards, btd is expressed in distinct spatial and temporal patterns, suggesting that btd might be required for a number of developmental processes beyond head segmentation. In fact, analysis of btd mutant embryos revealed that btd participates in the formation of the peripheral nervous system. However, no other morphologically apparent phenotype was observed. We identified a btd-related gene, termed D-Sp1, which is expressed in temporal and spatial patterns similar to btd during postblastodermal development. No localized expression domains of D-Sp1, which is located in the same X-chromosomal band as btd, were seen during the blastoderm stage. The results suggest that D-Sp1 and btd represent a novel gene pair with partially redundant functions after the blastoderm stage.

TFIID sequence recognition of the initiator and sequences farther downstream in Drosophila class II genes.

Immunopurified TFIID produces a large DNase I footprint over the hsp70, hsp26, and histone H3 promoters of Drosophila. These footprints span from the TATA element to a position approximately 35 nucleotides downstream from the transcription start site. Using a "missing nucleoside" analysis, four regions within the three promoters have been found to be important for TFIID binding: the TATA element, the initiator, and two regions located approximately 18 and 28 nucleotides downstream of the transcription start site. On the basis of the missing nucleoside data, the initiator appears to contribute as much to the affinity as the TATA element. However, there is weak conservation of the sequence in this region. To determine whether a preferred binding sequence exists in the vicinity of the initiator, the nucleotide composition of this region within the hsp70 promoter was randomized and then subjected to selection by TFIID. After five rounds of selection, the preferred sequence motif--G/A/T C/TAT/GTG--emerged. This motif is a close match to consensus sequences that have been derived by comparing the initiator region of numerous insect promoters. Selection of this sequence demonstrates that sequence-specific interactions downstream of the TATA element contribute to the interaction of TFIID on a wide spectrum of promoters.

Contribution of sequences downstream of the TATA element to a protein-DNA complex containing the TATA-binding protein.

A TATA complex that forms on the hsp70 promoter has been found to depend on sequence-specific interactions that occur at the transcription start and regions further downstream. The complex was detected with a gel shift assay and further characterized with interference assays. Antibodies reveal that the TATA-binding protein is in the complex. Interference assays localize specific contacts in the TATA element, the start site, and in a region approximately 25 bp downstream of the start site that contribute to either the assembly or the maintenance of the complex. Contact at the TATA element is made in the minor groove, as has been reported for the recombinant TATA-binding protein. Mutation in the TATA element or the start site of hsp70 causes complex formation to be more strongly dependent on contacts in the +25 region than in the normal core promoter. Examination of the hsp26 and histone H4 genes indicates that similar contacts contribute to the TATA complexes that form on these promoters. The results suggest that specific contacts downstream of the TATA element could play a key role in establishing the transcriptional potential of a gene by contributing to the interaction of the TATA-binding protein.