A blast without power - cell death induced by the tuberculosis-necrotizing toxin fails to elicit adequate immune responses.

In this study, we deploy a doxycycline-dependent suicide switch integrated in a tumor challenge model. With this experimental setup, we characterized the immunological consequences of cells dying by four distinct cell death stimuli in vivo. We observed that apoptotic cell death induced by expression of the truncated form of BH3 interacting-domain death agonist (tBid) and a constitutively active form of caspase 3 (revC3), respectively, showed higher immunogenicity than cell death induced by expression of the tuberculosis-necrotizing toxin (TNT). Our data indicate that the early release of ATP induces the silent clearance of dying cells, whereas the simultaneous presence of 'find me' signals and danger-associated molecular patterns (DAMPs) promotes inflammatory reactions and increased immunogenicity. This proposed model is supported by findings showing that the production and release of high concentrations of IL-27 by bone-marrow-derived macrophages (BMDM) is limited to BMDM exposed to those forms of death that simultaneously released ATP and the DAMPs heat-shock protein 90 (HSP90) and high-mobility group box-1 protein (HMGB1). These results demonstrate that the tissue microenvironment generated by dying cells may determine the subsequent immune response.

Dying autologous cells as instructors of the immune system.

In an organism, cell death occurs at many different sites and in many different forms. It is frequently part of normal development or serves to maintain cell homeostasis. In other cases, cell death not only occurs due to injury, disease or infection, but also as a consequence of various therapeutic interventions. However, in all of these scenarios, the immune system has to react to the dying and dead cells and decide whether to mount an immune response, to remain quiet or to initiate healing and repopulation. This is essential for the organism, testified by many diseases that are associated with malfunctioning in the cell death process, the corpse removal, or the ensuing immune responsiveness. Therefore, dying cells generally have to be considered as instructors of the immune system. How this happens and which signals and pathways contribute to modulate or shape the immune response is still elusive in many conditions. The articles presented in this Special Issue address such open questions. They highlight that the context in which cell death occurs will not only influence the cell death process itself, but also affect the surrounding cellular milieu, how the generation and presence of 'eat me' signals can have an impact on cell clearance, and that the exact nature of the residual 'debris' and how it is processed are fundamental to determining the immunological consequences. Hopefully, these articles initiate new approaches and new experiments to complete our understanding of how cell death and the immune system interact with each other.

No increased bleeding risk for oral surgery in patients with severe congenital bleeding disorders due to intense perioperative management.

PURPOSE: In order to evaluate complication rates of dentoalveolar surgery in patients with congenital bleeding disorders, a retrospective case-control study was performed. METHODS: A collective of patients with congenital bleeding disorders (n = 69), who received common oral surgery procedures in combination with intense perioperative monitoring and coagulation factor substitution at the University Hospital of Bonn between 1992 and 2011, was matched with patients without bleeding disorders by age, sex, and type of surgery. In addition to the rates of perioperative bleeding and other complications, the duration of surgery and the use of local hemostatic agents were compared between both cohorts. RESULTS: There were no significant differences between the two groups regarding the rate of postoperative bleeding (2.9 vs. 1.4%, patients with congenital bleeding disorders vs controls) and the rate of other complications (7.2 vs. 21.7%). Furthermore, no significant difference in operation time (54 min in patients with congenital bleeding disorders vs 45 min in controls) was observed. However, there was a significant difference (p < 0.001) regarding the use of local hemostatic measures, which were applied in all patients with hereditary bleeding disorders but in only one of the controls. All patients with bleeding disorders were inpatients, while all controls were treated in an outpatient setting. CONCLUSIONS: If adequate measures are taken, the complication rate following oral surgery in patients with hereditary bleeding disorders can be reduced to that of patients without bleeding disorders. However, these results are reached at significant costs due to coagulation factor replacement and inpatient treatment.

A tetracycline-binding RNA aptamer.

Aptamers are perfect tools to study the interaction of small ligands with RNA. To study the mode of interaction of tetracycline with RNA, we isolated aptamers with high affinity to this antibiotic via in vitro selection. One of the selected aptamers, cb28, which has a comparable affinity to tetracycline as the small ribosomal subunit, was characterised in more detail. Cb28 binds only to typical tetracyclines, while atypical tetracyclines are not recognised. The hydroxyl group at position 6 is an essential determinant for recognition, while modifications at positions 4, 5 and 7 do not interfere with RNA binding. Binding of tetracycline to cb28 is magnesium dependent. The secondary structure of cb28 was determined by lead cleavage and DMS modification. Upon tetracycline binding, nucleotides in J2/3 and the P5 stem-loop are protected from cleavage by lead, indicating a conformational change in the RNA. This conformational change was confirmed by tetracycline dependent changes in the DMS modification pattern. Photo-induced affinity incorporation of tetracycline into cb28 resulted in a crosslink to position G76, a residue in L5. The mode of binding of tetracycline to the cb28 aptamer resembles its interaction with the primary binding site on the small ribosomal subunit.

Evaluation of uranyl photocleavage as a probe to monitor ion binding and flexibility in RNAs.

In order to evaluate uranyl photocleavage as a tool to identify and characterize structural and dynamic properties in RNA, we compared uranyl cleavage sites in five RNA molecules with known X-ray structures, namely the hammerhead and hepatitis delta virus ribozymes, the P4-P6 domain of the Tetrahymena group I intron, as well as tRNA(Phe) and tRNA(Asp) from yeast. Uranyl photocleavage was observed at specific positions in all molecules investigated. In order to characterize the sites, photocleavage was performed in the absence and in increasing amounts of MgCl(2). Uranyl photocleavage correlates well with sites of low calculated accessibility, suggesting that uranyl ions bind in tight RNA pockets formed by close approach of phosphate groups. RNA foldings require ion binding, usually magnesium ions. Thus, upon the adoption of the native structure, uranyl ions can no longer bind well except in flexible and open to the solvent regions that can undergo induced-fit without disrupting the native fold. Uranyl photocleavage was compared to N-ethyl-N-nitrosourea and lead-induced cleavages in the context of the three-dimensional X-ray structures. Overall, the regions protected from ENU attack are sites of uranyl cleavage, indicating sites of low accessibility which can form ion binding sites. On the contrary, lead cleavages occur at flexible and accessible sites and correlate with the unspecific cleavages prevalent in dynamic and open regions. Applied in a magnesium-dependent manner, and only in combination with other backbone probing agents such as N-ethyl-N-nitrosourea, lead and Fenton cleavage, uranyl probing has the potential to reveal high-affinity metal ion environments, as well as regions involved in conformational transitions.

Identification, purification and partial characterisation of an oligonucleotide receptor in membranes of HepG2 cells.

The low and unpredictable uptake and cytosolic transfer of oligonucleotides (ODN) is a major reason for their limited benefit. Improving the ODN potential for therapy and research requires a better understanding of their receptor-mediated endocytosis. We have undertaken to identify a membrane ODN receptor on HepG2 cells by ligand blotting of cell extracts with [(125)I]ODN and by photolabelling of living cells with a [(125)I]ODN-benzophenone conjugate. A major band at 66 kDa was identified by the two methods. Its labelling was saturable and competed for by unlabelled ODN of various sequences and irrespective of the presence of a phosphodiester or phosphoro-thioate backbone. This protein remained sedimentable after carbonate extraction, indicating strong membrane association. About half of the total cell amount resisted extensive surface proteolysis, suggesting a dual localisation at the plasma membrane and cytoplasmic vesicles. The protein was purified using a biotinylated ODN-benzophenone conjugate by photocrosslinking followed by streptavidin affinity purification. A sequence obtained by Edman degradation showed no homology with known proteins. Using anti-peptide antisera, labelling by western blotting revealed at 66 kDa a band with comparable properties as found by ligand blotting. Thus, a new membrane protein acting as an ODN receptor has been demonstrated.

Solvent-exposed residues in the Tet repressor (TetR) four-helix bundle contribute to subunit recognition and dimer stability.

Dimerization specificity of Tet repressor (TetR) can be altered by changes in the core of the four-helix bundle that mediates protein-protein recognition. We demonstrate here that the affinity of subunit interaction depends also on the solvent-exposed residues at positions 128 and 179'-184', which interact across the dimerization surface. TetR(B) and (D), two naturally occurring sequence variants, differ at position 128 with respect to the monomer-monomer distances in the crystal structures and the charge of the amino acids, being glutamate in TetR(B) and arginine in TetR(D). In vivo analysis of chimeric TetR(B/D) variants revealed that the single E128R exchange does not alter the dimerization specificity of TetR(B) to the one of TetR(D). When combined with specificity mutations in alpha10, it is, however, able to increase dimerization efficiency of the TetR(B/D) chimera with TetR(D). A loss of contact analysis revealed a positive interaction between Arg-128 and residues located at positions 179'-184' of the second monomer. We constructed a hyperstable TetR(B) variant by replacing residues 128 and 179-184 by the respective TetR(D) sequence. These results establish that in addition to a region in the hydrophobic core residues at the solvent-exposed periphery of the dimerization surface participate in protein-protein recognition in the TetR four-helix bundle.

A fluorescent radioiodinated oligonucleotidic photoaffinity probe for protein labeling: synthesis and photolabeling of thrombin.

To study the interactions between oligonucleotides and proteins, an original photoaffinity radiolabeling probe has been synthesized. Starting with a 5'-pyridyldithio-3'-amino-oligonucleotide, the photophore benzophenone was first coupled to the 3' end, through acylation by an activated ester of benzoylbenzoic acid. A fluorescein molecule was grafted by alkylation of the free 5'-SH. This compound was finally radiolabeled with 125I using IodoBeads. The selective photolabeling of thrombin in a complex protein mixture by the radioiodinated probe validates this strategy to identify oligonucleotide-binding proteins.

Antibiotic inhibition of RNA catalysis: neomycin B binds to the catalytic core of the td group I intron displacing essential metal ions.

The aminoglycoside antibiotic neomycin B induces misreading of the genetic code during translation and inhibits several ribozymes. The self-splicing group I intron derived from the T4 phage thymidylate synthase (td) gene is one of these. Here we report how neomycin B binds to the intron RNA inhibiting splicing in vitro. Footprinting experiments identified two major regions of protection by neomycin B: one in the internal loop between the stems P4 and P5 and the other in the catalytic core close to the G-binding site. Mutational analyses defined the latter as the inhibitory site. Splicing inhibition is strongly dependent on pH and Mg2+ concentration, suggesting electrostatic interactions and competition with divalent metal ions. Fe2+-induced hydroxyl radical (Fe-OH.) cleavage of the RNA backbone was used to monitor neomycin-mediated changes in the proximity of the metal ions. Neomycin B protected several positions in the catalytic core from Fe-OH. cleavage, suggesting that metal ions are displaced in the presence of the antibiotic. Mutation of the bulged nucleotide in the P7 stem, a position which is strongly protected by neomycin B from Fe-OH. cleavage and which has been proposed to be involved in binding an essential metal ion, renders splicing resistant to neomycin. These results allowed the docking of neomycin to the core of the group I intron in the 3D model.

Visualizing metal-ion-binding sites in group I introns by iron(II)-mediated Fenton reactions.

BACKGROUND: Most catalytic RNAs depend on divalent metal ions for folding and catalysis. A thorough structure-function analysis of catalytic RNA therefore requires the identification of the metal-ion-binding sites. Here, we probed the binding sites using Fenton chemistry, which makes use of the ability of Fe2+ to functionally or structurally replace Mg2+ at ion-binding sites and to generate short-lived and highly reactive hydroxyl radicals that can cleave nucleic acid and protein backbones in spatial proximity of these ion-binding sites. RESULTS: Incubation of group I intron RNA with Fe2+, sodium ascorbate and hydrogen peroxide yields distinctly cleaved regions that occur only in the correctly folded RNA in the presence of Mg2+ and can be competed by additional Mg2+, suggesting that Fe2+ and Mg2+ interact with the same sites. Cleaved regions in the catalytic core are conserved for three different group I introns, and there is good correlation between metal-ion-binding sites determined using our method and those determined using other techniques. In a model of the T4 phage-derived td intron, cleaved regions separated in the secondary structure come together in three-dimensional space to form several metal-ion-binding pockets. CONCLUSIONS: In contrast to structural probing with Fe2+/EDTA, cleavage with Fe2+ detects metal-ion-binding sites located primarily in the inside of the RNA. Essentially all metal-ion-binding pockets detected are formed by tertiary structure elements. Using this method, we confirmed proposed metal-ion-binding sites and identified new ones in group I intron RNAs. This approach should allow the localization of metal-ion-binding sites in RNAs of interest.

Intragenic suppressors of induction-deficient TetR mutants: localization and potential mechanism of action.

Eight Tn10 Tet repressor mutants with an induction-deficient phenotype and with primary mutations located at or close to the dimer interface were mutagenized and screened for inducibility in the presence of tetracycline. The second-site suppressors with wild-type-like operator binding activity that were obtained act, except for one, at a distance, suggesting that they contribute to conformational changes in the Tet repressor. Many of these long-range suppressors occur along the dimer interface, indicating that interactions between the monomers play an important role in Tet repressor induction.

Combinations of the alpha-helix-turn-alpha-helix motif of TetR with respective residues from LacI or 434Cro: DNA recognition, inducer binding, and urea-dependent denaturation.

We constructed 10 different variants of TetR by substituting all or some of the residues in the alpha-helix-turn-alpha-helix (HTH) operator binding motif with the respective amino acids from LacI or 434Cro. The variants were soluble, negative transdominant over tetR in vivo, and as active as wild-type TetR in tetracycline binding in vitro. The urea-induced denaturation of the 10 variants occurs in single reversible transitions, which are centered around 4.3 M urea. Denaturation is concentration-dependent, supporting a simple two-state mechanism in which the folded dimeric protein is in equilibrium with unfolded monomers. An analysis according to the two-state model yields a Gibbs free energy of stabilization (at 0 M urea, 25 degrees C) of about 75 kJ/mol, typical for dimeric proteins of this size. Even a deletion of 24 residues from the reading head decreased the stability by only 2.7 kJ/mol. These results suggest that the DNA reading head of Tet repressor is a thermodynamically independent domain and that the thermodynamic stability of the Tet repressor dimer is determined by the association of the dimerization domains of the individual monomers. Variants containing replacements in the first alpha-helix of HTH did not show any DNA binding activity whatsoever. We attribute this to the alteration of the two N-terminal residues in this alpha-helix. TetR variants were active in nonspecific DNA binding, when either all or only the solvent-exposed residues in the recognition alpha-helix of HTH were exchanged to the respective LacI sequence. Replacement of the same residues by the respective amino acids from 434Cro yielded hybrid proteins that specifically recognize tetO in vitro. Taken together, these results establish that the similarity of operator recognition between 434Cro and TetR is greater than between TetR and LacI and confirm that prediction of the recognized DNA sequence is not obvious from the sequence of the respective HTH or recognition alpha-helix.

The role of the variable region in Tet repressor for inducibility by tetracycline.

A set of deletions and substitutions to alanine was introduced into the loop separating helices alpha8 and alpha9 of Tn10 Tet repressor (TetR). This region appears as an unstructured loop in the crystal structure of the TetR(D).([Mg-tc]+)2 complex and is the only internal segment of variable length in an alignment of Tet repressors from seven different resistance determinants. In vivo analysis of 10 mutants shows that this loop is important for inducibility by tetracycline (tc), whereas DNA binding is not or only marginally affected. All deletions have an induction-deficient TetRS phenotype, but the corresponding substitutions do not or only slightly affect inducibility. The purified mutant TetR proteins have a reduced affinity for tc in vitro that correlates with their lack of inducibility. The association rate of [Mg-tc]+ to the TetR mutants is enhanced. Since none of the mutated residues contacts tc directly in the crystal structure, we propose that the length of the loop is important for the structural transition between a closed, tc binding and an open, operator binding conformation of TetR. We propose that the deletions in the loop shift the equilibrium between both forms toward the open, operator binding conformation.

Fast large-scale purification of tetracycline repressor variants from overproducing Escherichia coli strains.

We constructed a plasmid for overexpression of Tn10 Tet repressor (TetR) by placing a synthetic tetR gene under control of the Pc promoter. Active TetR is expressed up to 30% of the total soluble cell protein. A protocol containing anion-exchange, cation-exchange, and size-exclusion chromatography steps is described for the large-scale purification of milligram amounts of TetR in three days. Cation-exchange chromatography already yields almost homogenous TetR. Purification of about fifty TetR mutants demonstrates that this protocol is generally applicable. No correlation between net charge of TetR variants and elution behaviour was detected for the anion-exchange column. On the other hand, TetR mutants with increased negative charge in their DNA binding domain eluted at lower NaCl concentration from the cation-exchange column. The applicability of this purification protocol to the wide variety of TetR variants suggests that it can be used for the rapid purification of other DNA binding proteins as well.

Deletion mutagenesis of Tn 10 Tet repressor--localization of regions important for dimerization and inducibility in vivo.

The gene for the Tn 10 Tet repressor (TetR) was subjected to deletion mutagenesis. Screening for a transdominant operator-binding negative phenotype yielded 10 mutants with internal deletions. Three deletions extend from residue D5 to residues L41, W75, or Q76, respectively, and two contain deletions of the alpha-helix-turn-alpha-helix DNA-binding motif. Five deletions range from residue K84 to residues between R87 and K98. Since residues from the N-terminus up to position 98 are not necessary for dimerization, this must take place in the C-terminal half of the protein. Ability to dimerize was probed by introducing ochre nonsense codons (oc) at residues G138, H151, E159, I174, or K202. Koc202 shows wild-type in vivo operator-binding and inducibility by tetracycline indicating that the six C-terminal residues of TetR are not important for activity. Mutants with longer C-terminal truncations are inactive and not transdominant. They show reduced steady-state protein levels and are probably impaired in folding and degraded in vivo. Two mutants (delta151-166, delta164-166) with deletions in a region variable in primary structure and length among Tet repressors from different resistance determinants bind tet operator efficiently, but are not inducible by tetracycline. This result indicates that these residues are not important for dimer formation in the operator-binding form.

Synthesis and pharmacological properties of 2-[S-acetylthiorphan]-1,3- diacylaminopropan-2-ol derivatives as chimeric lipid drug carriers containing an enkephalinase inhibitor.

The design of 1,3-dacylaminopropan-2-ols as CNS-directed carrier groups is based on their resemblance to endogenous lipids and the properties of pseudotriglyceride esters to facilitate the brain penetration of therapeutic agents. 2-[S-acetylthiorphan]-1,3-diacylaminopropan-2-ols, differing from the nature of 1,3-acyl chains, were synthesized and evaluated in vivo using the hot-plate jump test. The compounds exhibited naloxone reversible analgesic properties. The effects were superior to those of parent compounds thiorphan and S-acetylthiorphan. The palmitoyl derivative showed also activity at 0.8 mmol/kg after oral administration. Like acetorphan, a thiorphan prodrug, these compounds were poor substrates for brain enkephalinase, suggesting the release of the pharmacological active inhibitor at the site of action in the brain.

Proximity probing of Tet repressor to tet operator by dimethylsulfate reveals protected and accessible functions for each recognized base-pair in the major groove.

We have tracked the path of Tet repressor across the major groove in the complex with tet operator. This was done by a methylation protection analysis of nine tet operator mutants containing replacements by a G residue of each nucleotide in base-pairs important for Tet repressor recognition. We demonstrated sequence-specific binding of Tet repressor to these operator mutants using DNA retardation assays and the protection of the wild-type +2G residue from methylation. Hydroxyl radical cleavage protection analysis of the Tet repressor-tet operator complexes indicated identical, or at least very similar, locations of the DNA reading head across the major groove of wild-type and mutant operator DNA. Methylation protection occurred at the G residues in positions +3, +4, -5 and -6, whereas the G residues in the respective opposite strands showed enhanced methylation. These results show that most amino acid side-chains of Tet repressor are in close proximity to only one base of each base-pair in the major groove of tet operator. The Tet repressor mutant PS39 gave a changed methylation protection pattern at base-pair four of tet operator indicating that the residue at this position can contact either base at this base-pair depending on the amino acid side-chain present. Tet repressor mutants QA38 and TA40 with a loss of specificity phenotype gave the same methylation protection profile as wild-type TetR confirming that this experiment scores proximity rather than chemical interaction. The excellent agreement of these results with those obtained in genetic analyses demonstrates that this method yields a high-resolution proximity pattern of Tet repressor with tet operator and that it may be generally applicable for the analysis of protein-DNA complexes.

Mechanisms underlying expression of Tn10 encoded tetracycline resistance.

Tetracycline-resistance determinants encoding active efflux of the drug are widely distributed in gram-negative bacteria and unique with respect to genetic organization and regulation of expression. Each determinant consists of two genes called tetA and tetR, which are oriented with divergent polarity, and between them is a central regulatory region with overlapping promoters and operators. The amino acid sequences of the encoded proteins are 43-78% identical. The resistance protein TetA is a tetracycline/metal-proton antiporter located in the cytoplasmic membrane, while the regulatory protein TetR is a tetracycline inducible repressor. TetR binds via a helix-turn-helix motif to the two tet operators, resulting in repression of both genes. A detailed model of the repressor-operator complex has been proposed on the basis of biochemical and genetic data. The tet genes are differentially regulated so that repressor synthesis can occur before the resistance protein is expressed. This has been demonstrated for the Tn10-encoded tet genes and may be a common property of all tet determinants, as suggested by the similar locations of operators with respect to promoters. Induction is mediated by a tetracycline-metal complex and requires only nanomolar concentrations of the drug. This is the most sensitive effector-inducible system of transcriptional regulation known to date. The crystal structure of the TetR-tetracycline/metal complex shows the Tet repressor in the induced, non-DNA binding conformation. The structural interpretation of many noninducible TetR mutants has offered insight into the conformational changes associated with the switch between inducing and repressing structures of TetR. Tc is buried in the core of TetR, where it is held in place by multiple contacts to the protein.

The role of the N terminus in Tet repressor for tet operator binding determined by a mutational analysis.

The N-terminal residues preceding the alpha-helix-turn-alpha-helix motif on the Tn10 Tet repressor protein were probed by oligonucleotide-directed deletion mutagenesis for their role in protein activity. All deletion mutants showed decreased repression in vivo, emphasizing the importance of the N terminus for tet operator binding. Only two of the mutants, TetR delta 2-23 and TetR delta 3-8 displayed a reduced intracellular protein level. The remaining deletion mutants showed either reduced binding to tet operator and inducibility by tetracycline or transdominance. We conclude that these deletions do not affect stability and overall protein structure. DNA binding activities of residue-wise increasing deletions, TetR delta 9 through TetR delta 9-13, reveal a pattern consistent with an alpha-helical structure of the affected residues. This conclusion is supported by the helical wheel projection and the hydrophobic moment profile calculated for the protein segment ranging from residues S7-V20. We propose that these residues form an amphipathic alpha-helix which packs closely against the alpha-helix-turn-alpha-helix motif and is essential for Tet repressor activity. The residues preceding this putative alpha-helix contribute to DNA binding, but no direct interactions with base pairs of tet operator were revealed in a loss of contact analysis. Individual mutation of the 4 charged residues to alanine at the N terminus shows that no single residue can account for the reduction in repression observed for the deletion mutants.