Elisabeth Ferreira

The Ets Transcription Factors Interact with Each Other and with the c-Fos/c-Jun Complex via Distinct Protein Domains in a DNA-dependent and -independent Manner

The transcription factors Fos, Jun, and Ets regulate the expression of human stromelysin-1 and collagenase-1 genes. Recently, we found that ERG, an Ets family member, activates collagenase-1 gene but not stromelysin-1 by physically interacting with c-Fos/c-Jun. Interestingly, ERG binds to stromelysin-1 promoter and represses its activation by ETS2. Here, to investigate the molecular mechanism of this regulation, we have used an in vitroprotein-protein interaction assay and studied the transcription factor interactions of ETS2. We found that ETS2 could weakly associate within vitro synthesized ETS1, c-Fos, and c-Jun and strongly with c-Fos/c-Jun complex and ERG via several distinct ETS2 domains including the C-terminal region that contains the DNA-binding domain. Strikingly, these interactions were stabilized in vitro by DNA as they were inhibited by ethidium bromide. Both the N-terminal region, comprising the transactivation domain, and the C-terminal region of ETS2 associated with ERG and, interestingly, the interaction of ERG through the transactivation domain of ETS2 was DNA-independent. The DNA-dependent interaction of ETS2 with c-Fos/c-Jun was enhanced by specific DNA fragments requiring two Ets-binding sites of the stromelysin-1 promoter. Using the two hybrid system, we also demonstrated that ETS2 interacts with c-Jun or ERG in vivo.

Optimization of a gene electrotransfer method for mesenchymal stem cell transfection

Gene electrotransfer is an efficient and reproducible nonviral gene transfer technique useful for the nonpermanent expression of therapeutic transgenes. The present study established optimal conditions for the electrotransfer of reporter genes into mesenchymal stem cells (MSCs) isolated from rat bone marrow by their selective adherence to tissue-culture plasticware. The electrotransfer of the lacZ reporter gene was optimized by adjusting the pulse electric field intensity, electric pulse type, electropulsation buffer conductivity and electroporation temperature. LacZ electrotransfection into MSCs was optimal at 1500 V cm−1 with pre-incubation in Spinners minimum essential medium buffer at 22 °C. Under these conditions β-galactosidase expression was achieved in 29±3% of adherent cells 48 h post transfection. The kinetics of β-galactosidase activity revealed maintenance of β-galactosidase production for at least 10 days. Moreover, electroporation did not affect the MSC potential for multidifferentiation; electroporated MSCs differentiated into osteoblastic, adipogenic and chondrogenic lineages to the same extent as cells that were not exposed to electric pulses. Thus, this study demonstrates the feasibility of efficient transgene electrotransfer into MSCs while preserving cell viability and multipotency.

Inflammatory Cytokines Induce a Unique Mineralizing Phenotype in Mesenchymal Stem Cells Derived from Human Bone Marrow

Background: The effects of inflammation upon the biology of human mesenchymal stem cells are poorly understood. Results: IL-1β provoked massive hydroxyapatite deposition by inhibiting ectonucleotide pyrophosphatase. Cells did not express typical markers of osteoblasts or other mesenchymal lineages. Conclusion: Inflammation promotes mineralization by a novel mechanism. Significance: These data provide new insights into cytokine effects on mineralization of soft tissues. Bone marrow contains mesenchymal stem cells (MSCs) that can differentiate along multiple mesenchymal lineages. In this capacity they are thought to be important in the intrinsic turnover and repair of connective tissues while also serving as a basis for tissue engineering and regenerative medicine. However, little is known of the biological responses of human MSCs to inflammatory conditions. When cultured with IL-1β, marrow-derived MSCs from 8 of 10 human subjects deposited copious hydroxyapatite, in which authenticity was confirmed by Fourier transform infrared spectroscopy. Transmission electron microscopy revealed the production of fine needles of hydroxyapatite in conjunction with matrix vesicles. Alkaline phosphatase activity did not increase in response to inflammatory mediators, but PPi production fell, reflecting lower ectonucleotide pyrophosphatase activity in cells and matrix vesicles. Because PPi is the major physiological inhibitor of mineralization, its decline generated permissive conditions for hydroxyapatite formation. This is in contrast to MSCs treated with dexamethasone, where PPi levels did not fall and mineralization was fuelled by a large and rapid increase in alkaline phosphatase activity. Bone sialoprotein was the only osteoblast marker strongly induced by IL-1β; thus these cells do not become osteoblasts despite depositing abundant mineral. RT-PCR did not detect transcripts indicative of alternative mesenchymal lineages, including chondrocytes, myoblasts, adipocytes, ligament, tendon, or vascular smooth muscle cells. IL-1β phosphorylated multiple MAPKs and activated nuclear factor-κB (NF-κB). Certain inhibitors of MAPK and PI3K, but not NF-κB, prevented mineralization. The findings are of importance to soft tissue mineralization, tissue engineering, and regenerative medicine.

ASK-1 (apoptosis signal-regulating kinase 1) is a direct E2F target gene

In the present study, we show that E2Fs (E2 promoter-binding factors) regulate the expression of ASK-1 (apoptosis signal-regulating kinase 1), which encodes a mitogen-activated protein kinase kinase kinase, also known as MAP3K5. Its mRNA expression is cell-cycle-regulated in human T98G cells released from serum starvation. Moreover, overexpression and RNA interference experiments support the requirement of endogenous E2F/DP (E2F dimerization partner) activity for ASK-1 expression. Characterization of the human ASK-1 promoter demonstrates that the -95/+11 region is critical for E2F-mediated up-regulation. Chromatin immunoprecipitation assays show that E2F1-E2F4 are bound in vivo to the ASK-1 promoter in cycling cells, probably through a non-consensus E2F-binding site located 12 bp upstream of the transcription start site. Mutation of this site completely abolishes the ASK-1 promoter response to E2Fs as well as the E2F1 binding in electrophoretic mobility-shift experiments. Our results indicate that E2Fs modulate the expression of ASK-1 and suggest that some of the cellular functions of ASK-1 may be under the control of E2F transcription factors. Moreover, the up-regulation of ASK-1 may also favour the p53-independent E2F1 apoptotic activity.

Desferrioxamine-driven upregulation of angiogenic factor expression by human bone marrow stromal cells

Bone marrow stromal cells (BMSCs) are the subject of intense research because of their biological properties and potential use for the repair of damaged tissues. Success of BMSC‐based therapies, however, relies on a number of methodological improvements, including the establishment of a vascular network providing nutrients and oxygen to the transplanted cells and ensuring their immediate survival and long‐term functionality. We described a method to enhance the autocrine expression of angiogenic factors by BMSCs. For this purpose, human BMSCs were treated with desferrioxamine (DFX). No PDGF‐BB, VEGF‐R1 or ‐R2 mRNA expression was detected under any of the conditions tested. mRNA and protein expression levels of TGFβ1 were similar in BMSCs, whether they were exposed to DFX (50 µM) or to control conditions under normoxia for 48 h. In comparison with the results obtained with control conditions under normoxia, exposure of BMSCs to DFX for 48 h resulted in upregulation of bFGF at the protein (26‐fold) but not at the mRNA levels and VEGF at both the mRNA (1.5‐fold) and protein levels (4.5‐fold). In comparison with the results obtained with control conditions under hypoxia, DFX induced a 50% increase in VEGF secretion but led to the same level of hypoxia inducible factor‐1α protein expression (a transduction factor involved in angiogenic factor expression and known to be activated by DFX). Exposure of BMSCs to DFX resulted in oversecretion of angiogenic factors, suggesting that DFX‐treated BMSCs could be used to supply angiogenic factors. Copyright

Interaction between living bone particles and rhBMP-2 in large segmental defect healing in the rat femur.

Orthopedic surgeons sometimes combine recombinant, human BMP‐2 with autograft bone when dealing with problematic osseous fractures. Although some case reports indicate success with this off‐label strategy, there have been no randomized controlled trials. Moreover, a literature search revealed only one pre‐clinical study and this was in a cranial defect model. The present project examined the consequences of combining BMP‐2 with particles of living bone in a rat femoral defect model. Human bone particles were recovered with a reamer‐irrigator‐aspirator (RIA). To allow acceptance of the xenograft as surrogate autograft, rats were administered an immunosuppressive cocktail that does not interfere with bone healing. Implantation of 200 µg living bone particles generated a small amount of new bone and defects did not heal. Graded amounts of BMP‐2 that alone provoked no healing (1.1 µg), borderline healing (5.5 µg), or full healing (11 µg) were added to this amount of bone particles. Addition of BMP‐2 (1.1 µg) increased osteogenesis, and produced bridging in 2 of 7 defects. The combination of BMP‐2 (5.5 µg) and bone particles made healing more reliable and advanced the maturation of the regenerate. Bone formation with BMP‐2 (11 µg) and bone particles showed improved maturation. Thus, the combination of autograft and BMP‐2 may be helpful clinically under conditions where the healing response is suboptimal.

Solution Structure of the N-Terminal Domain of Mediator Subunit MED26 and Molecular Characterization of Its Interaction with EAF1 and TAF7

MED26 is a subunit of Mediator, a large complex central to the regulation of gene transcription by RNA Polymerase II. MED26 plays a role in the switch between the initiation and elongation phases of RNA Polymerase II-mediated transcription process. Regulation of these steps requires successive binding of MED26 N-terminal domain (NTD) to TATA-binding protein-associated factor 7 (TAF7) and Eleven-nineteen lysine-rich in leukemia-Associated Factor 1 (EAF1). In order to investigate the mechanism of regulation by MED26, MED26-NTD structure was solved by NMR, revealing a 4-helix bundle. EAF1 (239-268) and TAF7 (205-235) peptide interactions were both mapped to the same groove formed by H3 and H4 helices of MED26-NTD. Both interactions are characterized by dissociation constants in the 10-μM range. Further experiments revealed a folding-upon-binding mechanism that leads to the formation of EAF1 (N247-S260) and TAF7 (L214-S227) helices. Chemical shift perturbations and nuclear Overhauser enhancement contacts support the involvement of residues I222/F223 in anchoring TAF7 helix to a hydrophobic pocket of MED26-NTD, including residues L48, W80 and I84. In addition, Ala mutations of charged residues located in the C-terminal disordered part of TAF7 and EAF1 peptides affected the binding, with a loss of affinity characterized by a 10-time increase of dissociation constants. A structural model of MED26-NTD/TAF7 complex shows bi-partite components, combining ordered and disordered segments, as well as hydrophobic and electrostatic contributions to the binding. This study provides molecular detail that will help to decipher the mechanistic basis for the initiation to elongation switch-function mediated by MED26-NTD.