Specific local histone-DNA sequence contacts facilitate high-affinity, non-cooperative nucleosome binding of both adf-1 and GAGA factor.

Sequence-specific transcription factors need to gain access to regulatory sequences in chromatin. Previous studies utilizing model systems have suggested many mechanisms involved in this process. It is unclear however how these findings relate to natural promoters. The Drosophila alcohol dehydrogenase ( Adh ) gene distal promoter is organized into an ordered nucleosome array before multiple transcription factors recognize their sites within this nucleosomal context and activate transcription. Here we used a purified in vitro system to study the binding of the ubiquitous Drosophila transcription factors Adf-1 and GAGA factor to the Adh distal promoter in chromatin. Several nucleosome core particles were assembled on 150 bp DNA fragments containing the Adh distal cis -acting elements in the natural promoter context but different DNA-histone environments. We found that the Adh distal promoter regulatory sequences can position nucleosomes in the same rotational setting as observed in vivo. In one particular nucleosome position, the wrapping of the Adf-1 and adjacent GAGA factor binding sitesaround the histone octamer creates a unique local DNA conformation. High-affinity but non-cooperative nucleosome binding of Adf-1 and GAGA factortherefore occurs, in contrast to the inhibition of Adf-1 and GAGA factor binding in other nucleosome positions. Thus, local histone-DNA sequence contact giving rise to a specific asymmetric nucleosome structure may play important roles in modulating the affinities of transcription factors for their nucleosomal sites.

Multiple isoforms of GAGA factor, a critical component of chromatin structure.

The GAGA transcription factor of Drosophila melanogaster is ubiquitous and plays multiple roles. Characterization of cDNA clones and detection by domain- specific antibodies has revealed that the 70-90 kDa major GAGA species are encoded by two open reading frames producing GAGA factor proteins of 519 amino acids (GAGA-519) and 581 amino acids (GAGA-581), which share a common N-terminal region that is linked to two different glutamine-rich C-termini. Purified recombinant GAGA-519 and GAGA-581 proteins can form homomeric complexes that bind specifically to a single GAGA sequence in vitro. The two GAGA isoforms also function similarly in transient transactivation assays in tissue culture cells and in chromatin remodeling experiments in vitro . Only GAGA-519 protein accumulates during the first 6 h of embryogenesis. Thereafter, both GAGA proteins are present in nearly equal amounts throughout development; in larval salivary gland nuclei they colocalize completely to specific regions along the euchromatic arms of the polytene chromosomes. Coimmunoprecipitation of GAGA-519 and GAGA-581 from crude nuclear extracts and from mixtures of purified recombinant proteins, indicates direct interactions. We suggest that homomeric complexes of GAGA-519 may function during early embryogenesis; both homomeric and heteromeric complexes of GAGA-519 and GAGA-581 may function later.

Management of cobra bite by artificial respiration and supportive therapy.

During the period when the hospital ran out of cobra antivenom, 4 patients bitten by cobra with neuromuscular symptoms and respiratory depression were treated with artificial respiration. Complete recovery was noted within 36 to 72 hours. The data are interpreted to indicate the reversible binding of the venom to receptors. Artificial ventilation appears to be another alternative to specific antivenom treatment and may be used when the antivenom is not available or if there is antivenom hypersensitivity.

Activation and repression of Drosophila alcohol dehydrogenase distal transcription by two steroid hormone receptor superfamily members binding to a common response element.

Developmental activation of the Drosophila alcohol dehydrogenase (Adh) distal promoter is controlled by the Adh adult enhancer (AAE). Within this 150 bp, complex enhancer is a small (12 bp) positive cis-acting element that is required for high levels of distal transcription in adult flies and ADH-expressing tissue culture cells. We previously reported that the steroid receptor superfamily member FTZ-F1 binds to this site. We have identified a second steroid receptor superfamily member, DHR39, which also binds to this site. DHR39 is expressed throughout development in transcripts of several sizes. In situ hybridization to embryos has shown that DHR39 RNA is found primarily in the central nervous system, and not in embryonic tissues that express ADH. FTZ-F1 RNA, however, shows temporal-specific patterns similar to those of the distal promoter. FTZ-F1 and DHR39 have identical amino acids in the 'P-box' of the DNA binding domain, suggesting that they have identical DNA recognition characteristics. By electrophoretic mobility shift analysis we show that a DHR39 fusion protein binds specifically to two FTZ-F1 binding sites. By over expressing the full length DHR39 protein in a transient co-transfection assay we have shown that it represses distal Adh expression in a dosage- and binding site-dependent manner. Over expression of an alternative DHR39 open reading frame that lacks part of the putative ligand binding domain does not alter Adh expression. In contrast, over expression of FTZ-F1 specifically activates distal Adh expression.

DNA-histone interactions are sufficient to position a single nucleosome juxtaposing Drosophila Adh adult enhancer and distal promoter.

The alcohol dehydrogenase gene (Adh) of Drosophila melanogaster is transcribed from two tandem promoters in distinct developmental and tissue-specific patterns. Both promoters are regulated by separate upstream enhancer regions. In its wild-type context the adult enhancer specifically stimulates only the distal promoter, approximately 400 bp downstream, and not the proximal promoter, which is approximately 700 bp further downstream. Genomic footprinting and micrococcal nuclease analyses have revealed a specifically positioned nucleosome between the distal promoter and adult enhancer. In vitro reconstitution of this nucleosome demonstrated that DNA-core histone interactions alone are sufficient to position the nucleosome. Based on this observation and sequence periodicities in the underlying DNA, the mechanism of positioning appears to involve specific DNA structural features (ie flexibility or curvature). We have observed this nucleosome positioned early during development, before tissue differentiation, and before non-histone protein-DNA interactions are established at the distal promoter or adult enhancer. This nucleosome positioning element in the Adh regulatory region could be involved in establishing a specific tertiary nucleoprotein structure that facilitates specific cis-element accessibility and/or distal promoter-adult enhancer interactions.

In vivo stage- and tissue-specific DNA-protein interactions at the D. melanogaster alcohol dehydrogenase distal promoter and adult enhancer.

We performed a high resolution analysis of the chromatin structure within the regions required for distal transcription of the Drosophila melanogaster alcohol dehydrogenase gene (Adh). Using dimethyl sulfate, DNase I, and micrococcal nuclease as structural probes, and comparing chromatin structure in tissues isolated from several developmental stages, we have identified several sites of stage- and tissue-specific DNA-protein interactions that correlate with distal transcription initiation. Most were within previously identified cis-acting elements and/or in vitro protein binding sites of the adult enhancer (AAE) and distal promoter, including the TATA box. We also detected a novel stage-specific DNA-protein interaction at the Adf-2a binding site where a non-histone protein was bound to the DNA on the surface of a positioned nucleosome previously identified between the distal promoter and adult enhancer. In addition to footprints, we have also revealed stage- and tissue-specific DNA helix deformations between many of the non-histone protein binding sites. These helix distortions suggest there are interactions among the adjacently bound proteins that result in bending or kinking of the intervening DNA. The distal promoter and AAE have an accessible chromatin conformation in fat body prior to the third larval instar and many of the regulatory proteins that bind in these regions are also available before distal transcription begins. Nevertheless, the timing of DNA-protein interactions in the distal promoter and AAE suggest these proteins do not bind individually or assemble progressively as they and their binding sites become available. Instead, there appears to be a coordinated assembly of a large cooperative complex of proteins interacting with the distal promoter, the positioned nucleosome, the enhancer of the distal promoter (the AAE), and each other.

Characterization and purification of Adh distal promoter factor 2, Adf-2, a cell-specific and promoter-specific repressor in Drosophila.

Chromatin footprinting in Drosophila tissue culture cells has detected the binding of a non-histone protein at +8 of the distal Adh RNA start site, on a 10-bp direct repeat motif abutting a nucleosome positioned over the inactive Adh distal promoter. Alternatively the active promoter is bound by a transcription initiation complex. We have characterized and purified a protein Adf-2 that binds specifically to this direct repeat motif 5'TCTCAGTGCA3', present at +8 and -202 of the distal RNA start site. DNase I footprinting, methylation interference, and UV-crosslinking analyses showed that both direct repeats interact in vitro with a nuclear protein of approximately 120 kilodaltons (kDa). We purified Adf-2 through multiple rounds of sequence-specific DNA affinity chromatography. Southwestern analysis showed that the purified 120 KDa polypeptide binds the Adf-2 motif efficiently as a monomer or homomultimer. In vivo titrations of Adf-2 activity with the Adf-2 motif by transient co-transfection competitions in different Drosophila cell lines suggested that Adf-2 is a cell-specific repressor. Adf-2 has been detected ubiquitously in vitro, but is functional in vivo as a sequence-specific DNA binding protein and repressor only in the cells that have the inactive distal promoter. We discuss the possibility that an activation process is required for Adf-2 protein to bind DNA and function in vivo.

The binding site of a steroid hormone receptor-like protein within the Drosophila Adh adult enhancer is required for high levels of tissue-specific alcohol dehydrogenase expression.

Developmental and tissue-specific transcription from the Adh distal promoter is regulated in part by the Adh adult enhancer, located 450 to 600 bp upstream from the distal RNA start site. We have characterized four proteins (DEP1 to DEP4), present in Drosophila tissue culture cell nuclear extracts, which bind to this enhancer. DEP1 and DEP2 bind to a positive cis-acting element (-492 to -481) and share nucleotide contacts. A small linker replacement deletion mutation, which disrupts the overlapping DEP1- and DEP2-binding sites, reduces Adh distal transcription in an alcohol dehydrogenase (ADH)-expressing cultured cell line, in the adult fat body (the major tissue of ADH expression), as well as in some but not all adult tissues where ADH is normally expressed. This enhancer element contains an imperfect palindromic sequence similar to steroid hormone receptor superfamily response elements. Binding-site screening of a lambda gt11 expression library has identified the steroid receptor superfamily member fushi tarazu factor 1 (FTZ-F1) as a protein that binds to this site. Anti-FTZ-F1 antibodies have identified DEP1 as FTZ-F1. DEP2 also binds to the FTZ-F1 site from the fushi tarazu zebra element, suggesting that DEP2 may also be a steroid receptor superfamily member. Our results raise the possibility that Adh regulation in certain adult tissues involves a hormone-mediated pathway. Because DEP1 (FTZ-F1) and DEP2 contact some of the same nucleotides within the positive cis element, it is unlikely that they can bind simultaneously. Such alternative binding may play a role in the tissue-specific and developmental transcription of Adh.

Molecular analysis of the responder satellite DNA in Drosophila melanogaster: DNA bending, nucleosome structure, and Rsp-binding proteins.

The Responder (Rsp) locus of Drosophila melanogaster, the target locus of segregation distortion, is a satellite DNA array. This repeat array imparts some fitness advantage to the chromosomes bearing it. In this paper, we report the following three related molecular properties of this satellite repeat: (1) Sequence-directed curvature--On a polyacrylamide gel, Rsp-containing fragments migrate slower than would be predicted on the basis of their physical sizes. The extent of migration retardation correlates with the size and position of the Rsp sequence in a DNA fragment, suggesting that Rsp DNA is bent. The bending is shown to be affected by a DNA-binding drug (Hoechst 33258). (2) Nucleosome structure--Nucleosomes associated with Rsp repeats have an unusual spacing pattern. Instead of being spaced at approximately 190-bp intervals as is the bulk chromatin, they are separated at approximately 240-bp intervals, roughly the size of a dimeric Rsp repeat. The nucleosomal structure in the Rsp region is preferentially disrupted by Hoechst 33258, whereas the bulk chromatin appears to be insensitive to the drug. (3) Rsp-DNA binding proteins--Gel mobility-shift assays using nuclear extracts from pupae and end-labeled Rsp repeat demonstrate the presence of three distinct DNA-protein complexes. Competition assays suggest that these complexes are specific to the Rsp sequence, and two of these nucleoprotein complexes seem to be influenced by the presence of Hoechst 33258. The observed complexes are formed by nonhistone proteins of somatic origin and may be related to the normal functions of Rsp, rather than to the germ-line segregation distortion activities.

Analysis of formaldehyde-induced Adh mutations in Drosophila by RNA structure mapping and direct sequencing of PCR-amplified genomic DNA.

Two formaldehyde-induced mutations at the Drosophila Adh locus (Adhfn45 and Adhfn46) were analyzed by determining RNA structures at different developmental stages, polymerase chain reaction (PCR) amplification of the affected genomic regions, and direct sequencing of the resulting double-stranded DNA fragments. Adhfn46 adults and larvae accumulate abundant ADH-like distal (adult) and proximal (larval) transcripts that are shorter than transcripts in wild-type flies by a lesion located in the second ADH protein-coding exon. Direct sequencing of the amplified DNA region showed that Adhfn46 contains a 69-bp in-frame deletion that removes 23 amino acids near one border of the second exon. Consistent with these findings, we observed a shorter ADHfn46 protein present at only 3% of wild-type levels. In contrast, Adhfn45 adults and larvae accumulate much smaller amounts of ADH-like distal and proximal transcripts. Both RNAs have an identical aberration in RNA splicing of the 65-base intron sequence. Direct sequencing of the amplified mutated DNA region showed that Adhfn45 contains a 21-bp deletion that removed and rearranged DNA at the 5' splice junction of the 65-bp intron. No ADH cross-reacting material is detected in Adhfn45 flies. Direct-repeat sequences (3-11 bp) are present flanking and within the mutated DNA regions. The patterns of DNA deletion and deletion accompanied by sequence addition at the mutant sites suggest a slipped mispairing mechanism during DNA replication or repair that involves local DNA homology.

Conserved enhancer and silencer elements responsible for differential Adh transcription in Drosophila cell lines.

The distal promoter of Adh is differentially expressed in Drosophila tissue culture cell lines. After transfection with an exogenous Adh gene, there was a specific increase in distal alcohol dehydrogenase (ADH) transcripts in ADH-expressing (ADH+) cells above the levels observed in transfected ADH-nonexpressing (ADH-) cells. We used deletion mutations and a comparative transient-expression assay to identify the cis-acting elements responsible for enhanced Adh distal transcription in ADH+ cells. DNA sequences controlling high levels of distal transcription were localized to a 15-base-pair (bp) region nearly 500 bp upstream of the distal RNA start site. In addition, a 61-bp negative cis-acting element was found upstream from and adjacent to the enhancer. When this silencer element was deleted, distal transcription increased only in the ADH+ cell line. These distant upstream elements must interact with the promoter elements, the Adf-1-binding site and the TATA box, as they only influenced transcription when at least one of these two positive distal promoter elements was present. Internal deletions targeted to the Adf-1-binding site or the TATA box reduced transcription in both cell types but did not affect the transcription initiation site. Distal transcription in transfected ADH- cells appears to be controlled primarily through these promoter elements and does not involve the upstream regulatory elements. Evolutionary conservation in distantly related Drosophila species suggests the importance of these upstream elements in correct developmental and tissue-specific expression of ADH.

Alternative DNA-protein interactions in variable-length internucleosomal regions associated with Drosophila Adh distal promoter expression.

Chromatin at the Drosophila Adh distal promoter displays an ordered but different conformation in different cell types as detected by a modified exonuclease protection assay and accessibility to endonucleases. In cells not transcribing Adh (ADH-) sequences between -40 to +30 of the distal RNA initiation site exist as a DNA linker between positioned nucleosomes, and appear to interact with a specific DNA-binding protein. In contrast, a longer linker DNA, from -140 to +30, is bound in a multi-protein transcription initiation complex in cells that specifically transcribe the distal (adult) ADH RNA (ADH+A). These DNA-protein interactions can account for a localized open chromatin structure at the distal promoter in ADH+A cells. The observed mutually exclusive patterns of DNA-protein interactions in the linkers of different ADH cell types between -40 to +30 suggest a model for organizing alternative chromatin structure associated with gene regulation. Two DNA binding proteins, one being a TATA box binding factor, compete for overlapping sites to allow either assembly of a transcription initiation complex and transcription, or positioning of nucleosomes for stable repression.

Molecular consequences of two formaldehyde-induced mutations in the alcohol dehydrogenase gene of Drosophila melanogaster.

Adhfn23 and Adhfn24 are two formaldehyde-induced, homozygous-viable, alcohol dehydrogenase-null mutants that bear lesions in the gene that codes for the alcohol dehydrogenase (ADH; EC 1.1.1.1) of Drosophila melanogaster. Adhfn23 contains a 34-base pair deletion in the C-terminal coding region of the alcohol dehydrogenase structural gene. By immunological and molecular analysis, we show that the deletion shifts the translation reading frame and results in a prematurely truncated polypeptide product (10 amino acids shorter than wild type) that cross-reacts with antibody raised against ADH. The steady-state level of alcohol dehydrogenase mRNA present in this mutant is close (97%) to that in the wild type, but the steady-state level of alcohol dehydrogenase-like protein is 50% lower. Moreover, the rate of alcohol dehydrogenase synthesis in Adhfn23 flies is reduced to 60% of that found in the wild type. Hence both the rate of synthesis and the rate of degradation of alcohol dehydrogenase are affected. In contrast, Adhfn24 which contains an 11-base pair deletion in the N-terminal coding region of the ADH gene, synthesizes no immunodetectable protein, and the amount of alcohol dehydrogenase mRNA is less than half that of wild-type flies. As with Adhfn23, the deletion in Adhfn24 results in a change in the reading frame. Unlike Adhfn23, however, nucleic acid sequence data indicate that polypeptide chain elongation can proceed for a considerable distance (over 130 amino acids) beyond the deletion. Based upon antigenic binding-site predictions, the resultant aberrant protein (projected 195 amino acids in length) would share few antigenic sites with the alcohol dehydrogenase from the wild type, which may account for the lack of immunoprecipitable material in this mutant. The contrasting effects these two deletions have on the Drosophila ADH mRNA levels and ADH protein levels are discussed.

Roles of cis-acting elements and chromatin structure in Drosophila alcohol dehydrogenase gene expression.

The alcohol dehydrogenase (Adh) gene of D. melanogaster is transcribed from two different promoters during fly development: the distal (adult) and the proximal (embryonic-larval). Certain aspects of Adh gene regulation are represented in Drosophila continuous cell lines. We have used Drosophila tissue culture cells in an in vivo transient expression assay to delimit cis-acting sequences affecting Adh expression, and to investigate the role of chromatin structure in Adh gene regulation. These studies show that positive cis-acting elements of the distal promoter can exist in at least 2 alternative chromatin configurations. There is a close correlation between specific transcriptional activity of the Adh distal promoter and a defined, localized chromatin structural change that indicates altered DNA-protein interactions. Thus, chromatin structure appears to play a role in regulating the accessibility of defined positive cis-acting regulatory sequences of Adh to transcription factors and the transcription machinery.

Analysis of human blood monocyte activation at the level of gene expression. Expression of alpha interferon genes during activation of human monocytes by poly IC/LC and muramyl dipeptide.

Human monocytes were activated to secrete alpha interferon (IFN-alpha) by poly IC/LC but not by other monocyte activators, such as muramyl dipeptide (MDP). In contrast, monocytes were activated to secrete fibroblast growth factor (FGF) release by MDP but not by poly IC/LC. The amount of total RNA present in unactivated and activated human monocytes was similar. Using two 32P-labeled cDNA probes (pLM001 and HuIFN-alpha 2) for human IFN-alpha genes in hybridization studies, we analyzed messenger RNA species from this gene family in activated human monocytes. After activation with poly IC/LC, two other mRNA species (2.8 and 5.5 kb) were detected in addition to the 1.0 kb mRNA normally associated with IFN-alpha secretion. Unexpectedly, monocytes activated with MDP also contained 2.8 kb IFN-alpha mRNA. There was associated with this 2.8 kb IFN-alpha mRNA, found in MDP-activated monocytes, appreciable levels of intracellular IFN-alpha activity in the absence of detectable secreted IFN-alpha. Thus the secretion of IFN-alpha in activated human monocytes can be correlated with the appearance of a 1.0 kb mRNA species after poly IC/LC exposure. Secretion appears to be defective in MDP-stimulated monocytes even though they contain active intracellular IFN-alpha apparently translated from the 2.8 kb mRNA.

Cloned Drosophila alcohol dehydrogenase genes are correctly expressed after transfection into Drosophila cells in culture.

We have obtained correct transcription of the cloned alcohol dehydrogenase (Adh) gene of Drosophila melanogaster after DNA-mediated gene transfer into Drosophila cells in culture. Supercoiled plasmids, each containing various regions of the Adh gene cloned in pBR327, were introduced into Schneider line 2 (SL2) cells by the calcium phosphate-DNA transfection technique. Although these cells do not normally express their endogenous Adh genes, they do express the exogenous genes as shown by primer extension and nuclease S1 analyses of RNA isolated 48 hr after transfection. The resulting alcohol dehydrogenase (ADH) transcripts, both the larval and adult types, have the correct 5' ends and are properly spliced. The transfected cells have also acquired ADH enzyme activity. The levels of enzyme activity and of ADH protein crossreacting material in cells transfected with different Adh plasmids correlate directly with the level of ADH transcripts. When a mutant Adh gene cloned from an ADH-negative mutant fly with a defect in the splicing of ADH RNA is transfected into the Schneider line 2 cells, the resulting ADH RNA is not spliced properly and there is no synthesis of ADH; thus, the mutant gene transfection into cell culture mimics the mutant phenotypes observed in the mutant fly.

Formaldehyde mutagenesis in Drosophila. Molecular analysis of ADH-negative mutants.

The Adh gene from 4 formaldehyde-generated ADH-negative mutants of Drosophila melanogaster has been cloned and sequenced. All 4 mutants bear small deletions within the gene, ranging in size from 6 to 34 base pairs. 2 of the deletions lie within a 65-base pair intervening sequence and are accompanied by other aberrations. The other two are within the protein coding region of the gene. Some of these aberrations may be explained by a slipped mispairing mechanism.

The messenger RNA for alcohol dehydrogenase in Drosophila melanogaster differs in its 5' end in different developmental stages.

Alcohol dehydrogenase (EC 1.1.1.1) of Drosophila melanogaster is coded by a single structural gene, active in both larvae and adults. The major larval and adult transcripts of Adh differ in their 5'-untranslated regions. The major larval mRNA is about 1100 bases long, some 50 bases shorter than the major adult transcript. The 5' end of the larval mRNA is colinear with the genomic sequence immediately adjacent to the coding region, starting 70 base pairs (bp) upstream of the initiation codon. By contrast, the adult mRNA shares only 36 of its 123 5'-untranslated bases with the larval mRNA; the remaining 87 are encoded by a sequence 654 bp upstream. Both initiation sites are preceded by a TATA box some 24 bp upstream. The developmental specificity of Adh expression is seen, therefore, to have a counterpart in the specificity of transcription initiation at the two separate promoter regions.