To investigate the mechanisms involved in expression of the Drosophila melanogaster engrailed gene, we purified GAGA protein, one of several putative transcriptional activator proteins that binds to the proximal region of the engrailed promoter. Antibodies raised against GAGA protein were used to demonstrate that the protein is present in all nuclei of young embryos. We isolated cDNA clones encoding GAGA protein in which a putative 519-codon open reading frame contains general sequence motifs characteristic of other transcription factors. These include stretches of polyglutamine, a 60-amino-acid region with 18 (30%o) lysine or arginine residues, and a single putative zinc finger motif. In addition, a 120-residue N-terminal region shares significant sequence homology with several other known Drosophila transcription factors, including those encoded by Broad Complex and tramtrack. Up to 35-fold GAGA protein-dependent stimulation of transcription in Schneider line 2 tissue culture cells was observed after transfection of GAGA protein-encoding sequences. The GAGA gene is present in one copy in the Drosophila genome, at cytological location 70EF, and it encodes RNAs which vary in size between 2.4 and 4.4 kb.Many of the gene products that organize the Drosophila melanogaster embryo are expressed in restricted domains, and their accurate deployment is critical to normal development. Among these is engrailed, a homeodomain-containing protein that is expressed in a subset of the ectoderm and neuroectoderm. In gastrulating embryos, cells containing engrailed protein are in 15 concentric, single-cell-wide rings (15,19,29), and the presence of functional engrailed protein in these cells and in the posterior compartments that are populated by their descendants contributes to processes that form and maintain the segments and compartments.Genetic analysis has implicated the pair-rule segmentation genes even-skipped (eve) and fushi tarazu (ftz) in activating engrailed transcription in the gastrulating embryo (reviewed by Lawrence [31]). Genes that have been implicated in its subsequent regulation include engrailed itself (16), Polycomb (9,39), and wingless (3,16,38). It is not known whether the action of the protein products of any of these genes on engrailed regulation is direct, although logic might suggest that eve and ftz proteins, both of which are homeodomain-containing transcription factors, directly activate engrailed transcription in the gastrulating embryo. However, there is little direct evidence to suggest that these or other transcription factors act directly on the engrailed promoter. In vitro studies have identified sequences in the engrailed 5' upstream region that bind eve and ftz proteins (23), and engrailed is activated in a pattern that corresponds precisely with the anterior borders of the eve and ftz stripes (32). However, functional studies of the engrailed promoter failed to identify the eve and ftz binding sites in the engrailed upstream region as important sequences for regulation (10), and the respons...
To investigate the mechanisms involved in expression of the Drosophila melanogaster engrailed gene, we purified GAGA protein, one of several putative transcriptional activator proteins that binds to the proximal region of the engrailed promoter. Antibodies raised against GAGA protein were used to demonstrate that the protein is present in all nuclei of young embryos. We isolated cDNA clones encoding GAGA protein in which a putative 519-codon open reading frame contains general sequence motifs characteristic of other transcription factors. These include stretches of polyglutamine, a 60-amino-acid region with 18 (30%) lysine or arginine residues, and a single putative zinc finger motif. In addition, a 120-residue N-terminal region shares significant sequence homology with several other known Drosophila transcription factors, including those encoded by Broad Complex and tramtrack. Up to 35-fold GAGA protein-dependent stimulation of transcription in Schneider line 2 tissue culture cells was observed after transfection of GAGA protein-encoding sequences. The GAGA gene is present in one copy in the Drosophila genome, at cytological location 70EF, and it encodes RNAs which vary in size between 2.4 and 4.4 kb.
Transposon mutagenesis was used to isolate nonpathogenic mutants of Xanthomonas campestris pv. glycines 8ra, which causes bacterial pustule disease in soybean. A 6.1-kb DNA region in which a mutation gave loss of pathogenicity was isolated and found to carry six open reading frames (ORFs). Four ORFs had homology with hrcU, hrcV, hrcR, and hrcS genes of Ralstonia solanacearum and X. campestris pv. vesicatoria. One nonpathogenic mutant, X. campestris pv. glycines H80, lost pathogenicity on soybean but was able to elicit the hypersensitive response (HR) on nonhost pepper and tomato plants. This mutant still multiplied as well as the wild type in the leaves or cotyledons of soybean. Although the DNA and amino acid sequences showed high homology with known hrp genes, the hrcU-homolog ORF is not required for HR induction on nonhost plants, pepper and tomato, or for the multiplication of bacteria in the host plant. This gene was only required for the pathogenic symptoms of X. campestris pv. glycines 8ra on soybean.
Recently, outbreaks of food-borne diseases linked to fresh produce have been an emerging public health concern worldwide. Previous research has shown that when human pathogens co-exist with plant pathogens, they have improved growth and survival rates. In this study, we have assessed whether Escherichia coli O157:H7 benefits from the existence of a phytopathogenic bacterium and the underlying mechanisms were further investigated. When Pseudomonas syringae pv. tomato DC3000 (Pst DC3000) and E. coli O157:H7 were co-inoculated by either dipping or infiltration methods, the populations of E. coli O157:H7 increased; however, no effect was observed when type three secretion system (T3SS) mutants were used instead, suggesting that E. coli O157:H7 benefits from the presence of Pst DC3000. In addition, this study confirmed that the E. coli O157:H7 populations increased when they occupied the tomato leaf intercellular space; this colonization of the interior of the leaves was possible due to the suppression of the PAMP-triggered immunity (PTI) by Pst DC3000, in particular with the AvrPto effector. In conclusion, our data support a plausible model that E. coli O157:H7 benefits from the presence of Pst DC3000 via AvrPto suppression of the PTI resistance.
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