Dentine sialophosphoprotein signal in dentineogenesis and dentine regeneration

Dentineogenesis starts on odontoblasts, which synthesise and secrete non-collagenous proteins (NCPs) and collagen. When dentine is injured, dental pulp progenitors/mesenchymal stem cells (MSCs) can migrate to the injured area, differentiate into odontoblasts and facilitate formation of reactionary dentine. Dental pulp progenitor cell/MSC differentiation is controlled at given niches. Among dental NCPs, dentine sialophosphoprotein (DSPP) is a member of the small integrin-binding ligand N-linked glycoprotein (SIBLING) family, whose members share common biochemical characteristics such as an Arg-Gly-Asp (RGD) motif. DSPP expression is cell- and tissue-specific and highly seen in odontoblasts and dentine. DSPP mutations cause hereditary dentine diseases. DSPP is catalysed into dentine glycoprotein (DGP)/sialoprotein (DSP) and phosphoprotein (DPP) by proteolysis. DSP is further processed towards active molecules. DPP contains an RGD motif and abundant Ser-Asp/Asp-Ser repeat regions. DPP-RGD motif binds to integrin αVβ3 and activates intracellular signalling via mitogen-activated protein kinase (MAPK) and focal adhesion kinase (FAK)-ERK pathways. Unlike other SIBLING proteins, DPP lacks the RGD motif in some species. However, DPP Ser-Asp/Asp-Ser repeat regions bind to calcium-phosphate deposits and promote hydroxyapatite crystal growth and mineralisation via calmodulin-dependent protein kinase II (CaMKII) cascades. DSP lacks the RGD site but contains signal peptides. The tripeptides of the signal domains interact with cargo receptors within the endoplasmic reticulum that facilitate transport of DSPP from the endoplasmic reticulum to the extracellular matrix. Furthermore, the middle- and COOH-terminal regions of DSP bind to cellular membrane receptors, integrin β6 and occludin, inducing cell differentiation. The present review may shed light on DSPP roles during odontogenesis.

Participation of Integrinα5β1 in the Fibronectin-Mediated Adherence of EnteroaggregativeEscherichia colito Intestinal Cells

Adherence to the intestinal epithelia is a key feature in enteroaggregativeEscherichia coli(EAEC) infection. The aggregative adherence fimbriae (AAFs) are involved in EAEC interaction with receptors at the surface of intestinal cells. We and others have demonstrated that fibronectin is a receptor for AAF/II fimbriae. Considering that the major cellular receptor of fibronectin is integrinα5β1, in this study we evaluated the participation of this receptor in the fibronectin-mediated adherence of EAEC strain 042 to intestinal cells. We found that EAEC strain 042 has the ability to bind directly and indirectly to integrinα5β1; direct binding was not mediated by AAF/II fimbriae and indirect binding was mediated by AAF/II and fibronectin. Coimmunoprecipitation assays confirmed the formation of the complex AafA/fibronectin/integrinα5β1. To evaluate EAEC adherence to intestinal cells, T84 cells were incubated with fibronectin and an antibody that blocks the interaction region of integrinα5β1to fibronectin, the RGD site. Under these conditions, we found the number of adherent bacteria to epithelial cells significantly reduced. Additionally, fibronectin-mediated adherence of EAEC strain 042 was abolished in HEp-2 cells transfected with integrinα5shRNA. Altogether, our data support the involvement of integrinα5β1in the fibronectin-mediated EAEC binding to intestinal cells.

RGD Motif of Lipoprotein T, Involved in Adhesion of Mycoplasma conjunctivae to Lamb Synovial Tissue Cells

ABSTRACT Lipoprotein T (LppT), a membrane-located 105-kDa lipoprotein of Mycoplasma conjunctivae, the etiological agent of infectious keratoconjunctivitis (IKC) of domestic sheep and wild Caprinae, was characterized. LppT was shown to promote cell attachment to LSM 192 primary lamb joint synovial cells. Adhesion of M. conjunctivae to LSM 192 cells is inhibited by antibodies directed against LppT. The RGD (Arg-Gly-Asp) motif of LppT was found to be a specific site for binding of M. conjunctivae to these eukaryotic host cells. Recombinant LppT fixed to polymethylmethacrylate slides binds LSM 192 cells, whereas LppT lacking the RGD site is deprived of binding capacity to LSM 192, and LppT containing RGE rather than RGD shows reduced binding. Synthetic nonapeptides derived from LppT containing RGD competitively inhibit binding of LSM 192 cells to LppT-coated slides, whereas nonapeptides containing RAD rather than RGD do not inhibit. RGD-containing, LppT-derived nonapeptides are able to directly inhibit binding of M. conjunctivae to LSM 192 cells by competitive inhibition, whereas the analogous nonapeptide containing RAD rather than RGD or the fibronectin-derived RGD hexapeptide has no inhibitory effect. These results reveal LppT as the first candidate of a RGD lectin in Mycoplasma species that is assumed to bind to β integrins.

Functional Effects of Transforming Growth Factor β on Adhesive Properties of Porcine Trophectoderm

In pigs, expression and amounts of biologically active TGFβs at the conceptus-maternal interface increase significantly as conceptuses elongate and begin the implantation process. Before their activation, secreted TGFβs are noncovalently associated with their respective, isoform-specific latency-associated peptides (LAPs), which contain the Arg-Gly-Asp (RGD) amino acid sequence that serves as a ligand for numerous integrins. Objectives of this study were to determine whether TGFβ1 increases production of fibronectin by porcine trophectoderm, whether porcine trophectoderm adheres specifically to fibronectin and LAP, and whether functional interactions between porcine trophectoderm and the two TGFβ-associated proteins, fibronectin and LAP, are integrin mediated. Porcine trophectoderm cells (pTr2) were cultured in presence of TGFβ1, LAP, or pan-neutralizing anti-TGFβ antibody; TGFβ specifically increased (P < 0.05) fibronectin mRNA levels, as determined by Northern and slot blot analyses. Immunofluorescence microscopy demonstrated a TGFβ-induced increase in fibronectin in pTr2 cells. In dispersed cell adhesion assays, adhesion of pTr2 cells to fibronectin was inhibited by an RGD-containing peptide (P < 0.05) and pTr2 cells attached to recombinant LAP but not to an LAP mutant, which contained an RGE sequence rather than the RGD site (P < 0.05). Fibronectin- and LAP-coated microbeads induced integrin activation at apical surfaces of both trophectoderm and uterine luminal epithelial cells, as indicated by aggregation and transmembrane accumulation of talin detected with immunofluorescence microscopy. Cell surface biotinylation and immunoprecipitation revealed integrin subunits αv and β1 on apical membranes of pTr2 cells. These results suggest multiple effects of TGFβ at the porcine conceptus-maternal interface, including integrin-mediated conceptus-maternal communication through LAP.

Analyses of cellular multimerin 1 receptors: in vitro evidence of binding mediated by αΙΙbβ3 and αvβ3

SummaryMultimerin 1 (MMRN1) is a large, soluble, polymeric, factor V binding protein and member of the EMILIN protein family.In vivo, MMRN1 is found in platelets, megakaryocytes, endothelium and extracellular matrix fibers, but not in plasma. To address the mechanism of MMRN1 binding to activated platelets and endothelial cells, we investigated the identity of the major MMRN1 receptors on these cells using wild-type and RGE-forms of recombinant MMRN1. Ligand capture, cell adhesion, ELISA and flow cytometry analyses of platelet-MMRN1 binding, indicated that MMRN1 binds to integrins αIIbβ3 and αvβ3. Endothelial cell binding to MMRN1 was predominantly mediated by αvβ3 and did not require the MMRN1 RGD site or cellular activation. Like many other αvβ3 ligands, MMRN1 had the ability to support adhesion of additional cell types, including stimulated neutrophils. Expression studies, using a cell line capable of endothelial-like MMRN1 processing, indicated that MMRN1 adhesion to cellular receptors enhanced its extracellular matrix fiber assembly. These studies implicate integrin-mediated binding in MMRN1 attachment to cells and indicate that MMRN1 is a ligand for αIIbβ3 and αvβ3.

The Proadhesive Properties of Multimerin in Supporting Cellular Adhesion: Evidence for RGD and Non-RGD Dependent Adhesive Mechanisms.

Multimerin is a large soluble protein, with an uncertain function, found in platelets, megakaryocytes, endothelium and extracellular matrix fibers but not in plasma. The observation that multimerin contains structural features of an adhesive protein, including an Arg-Gly-Asp (RGD) sequence, led us to investigate its ability to support adhesion of platelets, megakaryocytes, endothelial cells and other cell types. Multimerin had the ability to support the adhesion of both platelets and megakaryocytes and this required cellular activation and the multimerin RGD site. Studies of normal and Glanzmann platelets indicated that multimerin interacted with the major platelet integrin receptor, αIIbβ3 and radioimmunoprecipitation analyses confirmed that multimerin bound to αIIbβ3. Multimerin also supported adhesion of endothelial cells, neutrophils and other cells including smooth muscle cells, fibroblast cells, human embryonic kidney (HEK293) and epithelial cells. Unlike platelets, these cells do not express αIIbβ3; this indicated that other integrin or non-integrin receptors could be involved in cellular adhesion to multimerin. Comparisons of cell adhesion to wild-type and RGE-multimerin indicated that unlike platelets and megakaryocytes, some other cell types (e.g. endothelial cells, smooth muscle cells and neutrophils) were capable of adhering to RGE-multimerin. This suggested that cellular adhesion to multimerin occurs by both RGD and non-RGD dependent mechanisms. Finally, unlike platelets, megakaryocytes and neutrophils, adhesion of other cell types to multimerin did not require cellular activation. In conclusion, our data indicate multimerin has fairly broad proadhesive properties, involving RGD and non-RGD dependent mechanisms, and that cellular receptors including αIIbβ3 interact with multimerin to mediate its binding to activated platelets, endothelial cells and potentially other cell types.