János Kovács scite author profile

Previously, we have demonstrated the presence of a protein factor [tubulin polymerization perturbing protein (TPPP)] in brain and neuroblastoma cell but not in muscle extract that uniquely influences the microtubule assembly. Here we describe a procedure for isolation of this protein from the cytosolic fraction of bovine brain and present evidence that this protein is a target of both tubulin and microtubules in vitro. The crucial step of the purification is the cationic exchange chromatography; the bound TPPP is eluted at high salt concentrations, indicating the basic character of the protein. By IDA-nanoLC-MS analysis of the peptides extracted from the gel-digested purified TPPP, we show the presence of a single protein in the purified fraction that corresponds to p25, a brain-specific protein the function of which has not been identified. Circular dichroism data have revealed that, on one hand, the alpha-helix content of p25 is very low (4%) with respect to the predicted values (30-43%), and its binding to tubulin induces remarkable alteration in the secondary structure of the protein(s). As shown by turbidimetry, pelleting experiments, and electron microscopy, p25 binds to paclitaxel-stabilized microtubules and bundles them. p25 induces formation of unusual (mainly double-walled) microtubules from tubulin in the absence of paclitaxel. The amount of aberrant tubules formed depends on the p25 concentration, and the process occurs at substoichiometric concentrations. Our in vitro data suggest that p25 could act as a unique MAP in vivo.

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Mesenchymal Stem Cells Cooperate with Bone Marrow Cells in Therapy of Diabetes

Urban¹,

Kiss²,

Kovács

et al. 2007

258

166

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Several recent studies have suggested that the adult bone marrow harbors cells that can influence ␤-cell regeneration in diabetic animals. Other reports, however, have contradicted these findings. To address this issue, we used an animal model of type 1 diabetes in which the disease was induced with streptozotocin in mice. Freshly prepared sexmismatched bone marrow cells (BMCs) and syngeneic or allogeneic mesenchymal stem cells (MSCs) were concomitantly administrated into sublethally irradiated diabetic mice. Blood glucose and serum insulin concentrations rapidly returned to normal levels, accompanied by efficient tissue regeneration after a single injection of a mixture of 10 6 BMCs per 10 5 MSCs. Neither BMC nor MSC transplantation was effective alone. Successful treatment of diabetic animals was not due to the reconstitution of the damaged islet cells from the transplant, since no donor-derived ␤-cells were found in the recovered animals, indicating a graftinitiated endogenous repair process. Moreover, MSC injection caused the disappearance of ␤-cell-specific T lymphocytes from diabetic pancreas. Therefore, we suggest that two aspects of this successful treatment regimen operate in parallel and synergistically in our model. First, BMCs and MSCs induce the regeneration of recipient-derived pancreatic insulin-secreting cells. Second, MSCs inhibit T-cell-mediated immune responses against newly formed ␤-cells, which, in turn, are able to survive in this altered immunological milieu. Thus, the application of this therapy in human patients suffering from diabetes and/or other tissue destructive autoimmune diseases may be feasible. STEM CELLS 2008;26:244 -253 Disclosure of potential conflicts of interest is found at the end of this article.

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János Kovács

Autophagy promotes T-cell survival through degradation of proteins of the cell death machinery

Natively unfolded tubulin polymerization promoting protein TPPP/p25 is a common marker of alpha-synucleinopathies

Brain-Specific p25 Protein Binds to Tubulin and Microtubules and Induces Aberrant Microtubule Assemblies at Substoichiometric Concentrations

Mesenchymal Stem Cells Cooperate with Bone Marrow Cells in Therapy of Diabetes

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