Natascha Blaudeck scite author profile

Background-Cardiac troponins in blood are the most preferred markers of myocardial damage. The fact that they are normally not found in the circulation provides a high level of clinical sensitivity and specificity even when cardiac lesions are small. After myocardial injury, the troponins enter the circulation, where they can be used for diagnosis of acute coronary syndromes. Thus, the cardiac troponins are paramount for disease classification and risk stratification. However, little is known about the long-term effects of the released troponins on cardiac function. Methods and Results-In this study we prepared recombinant murine cardiac troponin I (mc-TnI) and murine cardiac troponin T and used them to immunize mice. We report that A/J mice immunized with mc-TnI developed severe inflammation of the myocardium with increased expression of inflammatory chemokines RANTES (regulated on activation normal T cell expressed and secreted), monocyte chemoattractant protein-1, macrophage inflammatory protein (MIP)-1␣, MIP-1␤, MIP-2, T-cell activation gene 3, and eotaxin and chemokine receptors CCR1, CCR2, and CCR5. The inflammation was followed by cardiomegaly, fibrosis, reduced fractional shortening, and 30% mortality over 270 days. In contrast, mice immunized with murine cardiac troponin T or with the control buffer showed little or no inflammation and no death. Furthermore, we demonstrate that mice preimmunized with mc-TnI before left anterior descending coronary artery ligation showed greater infarct size, more fibrosis, higher inflammation score, and reduced fractional shortening. Conclusions-Overall, our results show for the first time that provocation of an autoimmune response to mc-TnI induces severe inflammation in the myocardium followed by fibrosis and heart failure with increased mortality in mice.

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Escherichia coli Twin Arginine (Tat) Mutant Translocases Possessing Relaxed Signal Peptide Recognition Specificities

Kreutzenbeck

Kröger

Lausberg

et al. 2007

Journal of Biological Chemistry

112

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The twin arginine (Tat) secretion pathway allows the translocation of folded proteins across the cytoplasmic membrane of bacteria. Tat-specific signal peptides contain a characteristic amino acid motif ((S/T)RRXFLK) including two highly conserved consecutive arginine residues that are thought to be involved in the recognition of the signal peptides by the Tat translocase. Here, we have analyzed the specificity of Tat signal peptide recognition by using a genetic approach. Replacement of the two arginine residues in a Tat-specific precursor protein by lysine-glutamine resulted in an export-defective mutant precursor that was no longer accepted by the wild-type translocase. Selection for restored export allowed for the isolation of Tat translocases possessing single mutations in either the aminoterminal domain of TatB or the first cytosolic domain of TatC. The mutant Tat translocases still efficiently accepted the unaltered precursor protein, indicating that the substrate specificity of the translocases was not strictly changed; rather, the translocases showed an increased tolerance toward variations of the amino acids occupying the positions of the twin arginine residues in the consensus motif of a Tat signal peptide.

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The efficient export of NADP‐containing glucose‐fructose oxidoreductase to the periplasm of Zymomonas mobilis depends both on an intact twin‐arginine motif in the signal peptide and on the generation of a structural export signal induced by cofactor binding

Halbig

Wiegert

Blaudeck

et al. 1999

European Journal of Biochemistry

100

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The periplasmic, NADP-containing glucose-fructose oxidoreductase of the gram-negative bacterium Zymomonas mobilis belongs to a class of redox cofactor-dependent enzymes which are exported with the aid of a signal peptide containing a so-called twin-arginine motif. In this paper we show that the replacement of one or both arginine residues results in drastically reduced translocation of glucose-fructose oxidoreductase to the periplasm, showing that this motif is essential. Mutant proteins which, in contrast to wild-type glucose-fructose oxidoreductase, bind NADP in a looser and dissociable manner, were severely affected in the kinetics of plasma membrane translocation. These results strongly suggest that the translocation of glucose-fructose oxidoreductase into the periplasm uses a Sec-independent apparatus which recognizes, as an additional signal, a conformational change in the structure of the protein, most likely triggered by cofactor binding. Furthermore, these results suggest that glucose-fructose oxidoreductase is exported in a folded form. A glucose-fructose oxidoreductase:b-galactosidase fusion protein is not lethal to Z. mobilis cells and leads to the accumulation of the cytosolic preform of wild-type glucose-fructose oxidoreductase expressed in trans but not of a typical Sec-substrate (OmpA), indicating that the glucose-fructose oxidoreductase translocation apparatus can be blocked without interfering with the export of essential proteins via the Sec pathway.

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Isolation and Characterization of Bifunctional Escherichia coli TatA Mutant Proteins That Allow Efficient Tat-dependent Protein Translocation in the Absence of TatB

Blaudeck

Kreutzenbeck

Müller

et al. 2005

Journal of Biological Chemistry

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In Escherichia coli, the Tat system promotes the membrane translocation of a subset of exported proteins across the cytoplasmic membrane. Four genes (tatA, tatB, tatC, and tatE) have been identified that encode the components of the E. coli Tat translocation apparatus. Whereas TatA and TatE can functionally substitute for each other, the TatB and the TatC proteins have been shown to perform distinct functions. In contrast to Tat systems of the ABC(E) type found in E. coli and many other bacteria, some microorganisms possess a TatACtype translocase that consists of TatA and TatC only, suggesting that, in these systems, TatB is not required or that one of the remaining components (TatA or TatC) additionally takes over the TatB function. We have addressed the molecular basis for the difference in subunit composition between TatABC(E) and TatAC-type systems by using a genetic approach. A plasmid-encoded E. coli minimal Tat translocase consisting solely of TatA and TatC was shown to mediate a low level translocation of a sensitive Tat-dependent reporter protein. Suppressor mutations in the minimal Tat translocase were isolated that compensate for the absence of TatB and that showed substantial increases in translocation activities. All of the mutations mapped to the extreme amino-terminal domain of TatA. No mutations affecting TatC were identified. These results suggest that in TatAC-type systems, the TatA protein represents a bifunctional component fulfilling both the TatA and TatB functions. Furthermore, our results indicate that the structure of the amino-terminal domain of TatA is decisive for whether or not TatB is required.Transport of proteins across biological membranes is a crucial process in all living cells. In eubacteria, the translocation of the vast majority of proteins across the plasma membrane is mediated by the general protein secretion (Sec) system, consisting of a protein-conducting channel (SecYEG) and a translocation motor (SecA). Sec-dependent proteins are threaded through the SecYEG pore in a more or less unfolded state and only fold after their release on the trans-side of the membrane (for a recent review, see Ref. 1).In addition to the Sec machinery, many bacteria possess a second protein export system, the so-called Tat (twin arginine translocation) system, for the translocation of a subset of proteins. In marked contrast to the Sec system, the Tat machinery translocates its substrates in a fully folded or even oligomeric state (for reviews, see Refs. 2-5). The Tat export machinery consists of a surprisingly low number of components. In Escherichia coli, four genes (tatA, tatB, tatC, and tatE) have been identified that encode components of the Tat translocation apparatus (6, 7). TatA, TatB, and TatE are sequence-related proteins. TatA and TatE show more than 50% sequence identity and can partially substitute for each other functionally (7). However, because the tatA gene is expressed about 100 times higher than tatE, the latter gene is currently regarded as a cryptic gene duplication of ta...

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