Systematic analysis of phosphotyrosine antibodies recognizing single phosphorylated EPIYA-motifs in CagA of Western-type Helicobacter pylori strains.

The clinical outcome of Helicobacter pylori infections is determined by multiple host-pathogen interactions that may develop to chronic gastritis, and sometimes peptic ulcers or gastric cancer. Highly virulent strains encode a type IV secretion system (T4SS) that delivers the effector protein CagA into gastric epithelial cells. Translocated CagA undergoes tyrosine phosphorylation at EPIYA-sequence motifs, called A, B and C in Western-type strains, by members of the oncogenic Src and Abl host kinases. Phosphorylated EPIYA-motifs mediate interactions of CagA with host signaling factors--in particular various SH2-domain containing human proteins--thereby hijacking multiple downstream signaling cascades. Observations of tyrosine-phosphorylated CagA are mainly based on the use of commercial phosphotyrosine antibodies, which originally were selected to detect phosphotyrosines in mammalian proteins. Systematic studies of phosphorylated EPIYA-motif detection by the different antibodies would be very useful, but are not yet available. To address this issue, we synthesized phospho- and non-phosphopeptides representing each predominant Western CagA EPIYA-motif, and determined the recognition patterns of seven different phosphotyrosine antibodies in Western blots, and also performed infection studies with diverse representative Western H. pylori strains. Our results show that a total of 9-11 amino acids containing the phosphorylated EPIYA-motifs are necessary and sufficient for specific detection by these antibodies, but revealed great variability in sequence recognition. Three of the antibodies recognized phosphorylated EPIYA-motifs A, B and C similarly well; whereas preferential binding to phosphorylated motif A and motifs A and C was found with two and one antibodies, respectively, and the seventh anti-phosphotyrosine antibody did not recognize any phosphorylated EPIYA-motif. Controls showed that none of the antibodies recognized the corresponding non-phospho CagA peptides, and that all of them recognized phosphotyrosines in mammalian proteins. These data are valuable in judicious application of commercial anti-phosphotyrosine antibodies and in characterization of CagA phosphorylation during infection and disease development.

Functionally important residues of the Tet repressor inducing peptide TIP determined by a complete mutational analysis.

Tet repressor (TetR) is widely used to control gene expression in pro- and eukaryotes. The mechanism of induction by its natural inducer tetracycline is well characterized. A 16-mer oligopeptide, called TIP, fused to thioredoxin A (TrxA) of Escherichia coli is an artificial inducer of TetR. We analyzed the sequence requirements of TIP by directed and random single amino acid substitutions and identified residues important for TetR induction. An alanine scanning analysis of the first twelve residues showed that all except the ones at position eleven and twelve are important for induction. A randomization of residues at positions one to twelve of TIP revealed the properties of each residue necessary for induction. These further insights into the specificity of TIP-TetR interaction are discussed in the light of the X-ray structure of the [TetR-TIP] complex. The last four residues of TIP contribute indirectly to TetR induction by increasing the steady-state level of the fusion protein. TIP mutants fused N-terminally or C-terminally to TrxA in E. coli induce with the same efficiency indicating identical binding and induction mechanisms, and the lack of contribution from TrxA.

A gene regulation system with four distinct expression levels.

BACKGROUND: The amount of a particular protein, and not just its presence or absence, frequently determines the outcome of a developmental process or disease progression. These dosage effects can be studied by conditionally expressing such proteins at different levels. With typical gene regulation systems like the Tet-On system, intermediate expression levels can be obtained by varying the effector concentration. However, this strategy is limited to situations in which these concentrations can be precisely controlled and, thus, not suited for animal models or gene therapy approaches. Here, we present a Tet transregulator setup that allows establishment of four levels of promoter activity largely independent of effector concentration. METHODS: A newly introduced transsilencer is combined with a reverse transactivator. As the regulators respond differentially to tetracycline derivatives, four expression levels are obtained by adding different effectors. To facilitate integration of the components, we generated versatile all-in-one vectors. Apart from a cassette expressing the transregulators and a selection marker, these vectors encode a bidirectional, regulated promoter driving expression of GFP and the gene of interest. The features of this stepwise regulation system were analyzed by transient and stable transfections of human cell lines. RESULTS: We demonstrate in a variety of experimental settings that coexpression of these transregulators leads to robust stepwise regulation. Depending on the respective effectors, four expression levels are achieved with different responsive promoters, cell lines and target genes. CONCLUSIONS: This system shows that a promoter can be adjusted to different activities and provides an excellent strategy to investigate protein dosage effects.

Inducible DNA-loop formation blocks transcriptional activation by an SV40 enhancer.

It is well established that gene expression in eukaryotes is controlled by sequence-dependent binding of trans-acting proteins to regulatory elements like promoters, enhancers or silencers. A less well understood level of gene regulation is governed by the various structural and functional states of chromatin, which have been ascribed to changes in covalent modification of core histone proteins. And, much on how topological domains in the genome take part in establishing and maintaining distinct gene expression patterns is still unknown. Here we present a set of regulatory proteins that allow to reversibly alter the DNA structure in vivo and in vitro by adding low molecular weight effectors that control their oligomerization and DNA binding. Using this approach, we completely regulate the activity of an SV40 enhancer in HeLa cells by reversible loop formation to topologically separate it from the promoter. This result establishes a new mechanism for DNA-structure-dependent gene regulation in vivo and provides evidence supporting the structural model of insulator function.

A short autonomous repression motif is located within the N-terminal domain of CTCF.

The vertebrate transcription factor CTCF is not only involved in transcriptional activation, insulation and genomic imprinting, but also in transcriptional repression. Sequence motifs mediating these activities have not been identified so far. We have mapped a short repression motif to residues 150-170 within the N-terminal domain of CTCF. This motif is active in HeLa, HEK293 and COS-7 cell lines where it is both sufficient and necessary for silencing either an SV40-, or a CMV-enhancer. It also represses the basal activity of an SV40 core promoter. Since this autonomous repression motif displays no sequence similarity to any other regulatory protein, it represents a yet unknown co-repressor recruiting motif.

Tet repressor residues indirectly recognizing anhydrotetracycline.

Two tetracycline repressor (TetR) sequence variants sharing 63% identical amino acids were investigated in terms of their recognition specificity for tetracycline and anhydrotetracycline. Thermodynamic complex stabilities determined by urea-dependent unfolding reveal that tetracycline stabilizes both variants to a similar extent but that anhydrotetracycline discriminates between them significantly. Isofunctional TetR hybrid proteins of these sequence variants were constructed and their denaturation profiles identified residues 57 and 61 as the complex stability determinant. Association kinetics reveal different recognition of these TetR variants by anhydrotetracycline, but the binding constants indicate similar stabilization. The identified residues connect to an internal water network, which suggests that the discrepancy in the observed thermodynamics may be caused by an entropy effect. Exchange of these interacting residues between the two TetR variants appears to influence the flexibility of this water organization, demonstrating the importance of buried, structural water molecules for ligand recognition and protein function. Therefore, this structural module seems to be a key requisite for the plasticity of the multiple ligand binding protein TetR.