Expression of CSF-1 receptor on TRAP-positive multinuclear cells around the erupting molars in rats

Bone resorption overlying a developing tooth is a necessary event in the creation of an eruption pathway. The formation and function of osteoclasts, which play a major role in bone resorption, are controlled by several factors. Although CSF-1 and its mRNA are expressed in dental follicle cells required for eruption, little is known about the contribution of CSF-1 to osteoclast formation on the bony crypt around the tooth germ. The receptor protein of the CSF-1 encoded proto-oncogene c-fms was identified on multinucleated cells adjacent to the dental follicle, in conjunction with TRAP staining as a marker enzyme for osteoclasts in rat. c-Fms was highly expressed in TRAP-positive multinuclear cells at 3 days postnatal and the number of c-Fms-expressing cells was reduced thereafter. Administration of IL-1alpha, which enhances formation and function of osteoclasts, caused an increase in the number of c-Fms and TRAP-positive cells in rat. On the contrary, injection of calcitonin, which depresses osteoclast formation, caused a decrease in the number. It is obvious that the receptor of CSF-1 is expressed on the surface of osteoclasts around the tooth germ, on the dental follicle. These findings suggested that CSF-1 directly enhances the influx of osteoclasts adjacent to the erupting tooth, resulting in the formation of an eruption pathway.     

Localization of Myosin,Actin, α-Actinin,Tropomyosin and Vinculin in Surface-Activated,Spreading Human Platelets

We observed the localization of the contractile proteins myosin, filamentous actin, α-actinin, tropomyosin, and vinculin in surface-activated, spreading human platelets using a single fluorescence staining procedure and conventional fluorescence microscopy. Myosin was distributed in a speckled pattern that extended radially from the granulomere. F-actin demonstrated cable-networks. Tropomyosin and α-actinin occurred in a punctuate distribution, and vinculin was localized at adhesion sites. Although myosin, F-actin, α-actinin, tropomyosin, and vinculin were not studied in resting platelets, our data support the idea that these contractile proteins are reorganized and reassembled in activated platelets during platelet function.     

Interleukin 1 induces multinucleation and bone-resorbing activity of osteoclasts in the absence of osteoblasts/stromal cells

Interleukin-1 (IL-1) is one of the most potent bone-resorbing factors involved in bone loss associated with inflammation. We previously reported that IL-1 prolonged the survival of multinucleated osteoclast-like cells (OCLs) formed in cocultures of murine osteoblasts/stromal cells and bone marrow cells via the prevention of spontaneously occurring apoptosis. It was reported that macrophage colony-stimulating factor (M-CSF/CSF-1) prolongs the survival of OCLs without the help of osteoblasts/stromal cells. The present study was conducted to determine whether IL-1 also directly induces the multinucleation and activation of OCLs. Mononuclear osteoclast-like cells (prefusion osteoclasts; pOCs) were purified using the "disintegrin" echistatin from cocultures of murine osteoblastic cells (MB 1.8 cells) and bone marrow cells. Both IL-1 and M-CSF prolonged the survival and induced the multinucleation of pOCs through their respective receptors. However, actin ring formation (a functional marker of osteoclasts) by multinucleated cells was observed in the pOC cultures treated with IL-1, but not those treated with M-CSF. We previously reported that enriched multinucleated OCLs as well as pOCs placed on bone/dentine slices formed few resorption pits, but their pit-forming activity was greatly increased by the addition of osteoblasts/stromal cells. Here, pit-forming activity of both pOCs and enriched OCLs placed on dentine slices was induced by adding IL-1, even in the absence of osteoblasts/stromal cells. M-CSF failed to induce pit-forming activity in pOC and enriched OCL cultures. These results indicate that IL-1 induces the multinucleation and bone-resorbing activity of osteoclasts even in the absence of osteoblasts/stromal cells.     

M-CSF regulates the cytoskeleton via recruitment of a multimeric signaling complex to c-Fms Tyr-559/697/721

M-CSF is known to induce cytoskeletal reorganization in macrophages and osteoclasts by activation of phosphatidylinositol 3-kinase (PI3K) and c-Src, but the detailed mechanisms remain unclear. We find, unexpectedly, that tyrosine (Tyr) to phenylalanine (Phe) mutation of Tyr-721, the PI3K binding site in the M-CSF receptor c-Fms, fails to suppress cytoskeletal remodeling or actin ring formation. In contrast, mutation of c-Fms Tyr-559 to Phe blocks M-CSF-induced cytoskeletal reorganization by inhibiting formation of a Src Family Kinase SFK.c-Cbl.PI3K complex and the downstream activation of Vav3 and Rac, two key mediators of actin remodeling. Using an add-back approach in which specific Tyr residues are reinserted into c-Fms inactivated by the absence of all seven functionally important Tyr residues, we find that Tyr-559 is necessary but not sufficient to transduce M-CSF-dependent cytoskeletal reorganization. Furthermore, this same add-back approach identifies important roles for Tyr-697 and Tyr-721 in collaborating with Tyr-559 to recruit a multimeric signaling complex that can transduce signals from c-Fms to the actin cytoskeleton.     

Mutual effects of α-actinin,calponin and filamin on actin binding

The mutual effect of three actin-binding proteins (α-actinin, calponin and filamin) on the binding to actin was analyzed by means of differential centrifugation and electron microscopy. In the absence of actin α-actinin, calponin and filamin do not interact with each other. Calponin and filamin do not interfere with each other in the binding to actin bundles. Slight interference was observed in the binding of α-actinin and calponin to actin bundles. Higher ability of calponin to depress α-actinin binding can be due to the higher stoichiometry calponin/actin in the complexes formed. The largest interference was observed in the pair filamin–α-actinin. These proteins interfere with each other in the binding to the bundled actin filaments; however, neither of them completely displaced another protein from its complexes with actin. The structure of actin bundles formed in the presence of any one actin-binding protein was different from that observed in the presence of binary mixtures of two actin-binding proteins. In the case of calponin or its binary mixtures with α-actinin or filamin the total stoichiometry actin-binding protein/actin was larger than 0.5. This means that α-actinin, calponin and filamin may coexist on actin filaments and more than mol of any actin-binding protein is bound per two actin monomers. This may be important for formation of different elements of cytoskeleton.     

α-Actinin: Immunofluorescent localization of a muscle structural protein in nonmuscle cells

Antibodies specific for the skeletal muscle structural protein α-actinin are used to localize this protein by indirect immunofluorescence in nonmuscle cells. In cultured nonmuscle cells, α-actinin is localized along or between actin filament bundles producing an almost regular periodicity. The protein is also detected in the form of fluorescent plaques at some ends of actin filament bundles, as well as in a filamentous form in some overlap areas of cells. In spreading rat embryo cells, α-actinin assumes a focal distribution which corresponds to the vertices of a highly regular actin filament network. The results suggest that α-actinin may be involved in the organization of actin filament bundles, in the attachment of actin filaments to the plasma membrane, and in the assembly of actin filaments in areas of cell to cell contact.     

Effect of α-actinin on actin viscosity

As determined by analytical ultracentrifugation, purified α-actinin does not form stable complexes with G-actin, myosin, tropomyosin, or the tropomyosintroponin complex. However, α-actinin forms a stable complex with F-actin polymerized either in 100 mM KC1 or in 2mM MgCl₂ without KCl. Viscosity studies confirm that α-actinin interacts as strongly with Mg²⁺-polymerized actin as it does with KCl-polymerized actin.     

Differential Effects of Lysophosphatidic Acid and Phosphatidylinositol 4,5-Bisphosphate on Actin Dynamics by Direct Association with the Actin-binding Protein Villin

We have previously reported that the epithelial cell-specific actin-binding protein villin directly associates with phosphatidylinositol 4,5-bisphosphate (PIP₂) through three binding sites that overlap with actin-binding sites in villin. As a result, association of villin with PIP₂ in hibits actin depolymerization and enhances actin cross-linking by villin. In this study, we demonstrate that these three PIP₂-binding sites also bind the more hydrophilic phospholipid, lysophosphatidic acid (LPA) but with a higher affinity than PIP₂ (dissociation constant (K_d) of 22 μm versus 39.5 μm for PIP₂). More interestingly, unlike PIP₂, the association of villin with LPA inhibits all actin regulatory functions of villin. In addition, unlike PIP₂, LPA dramatically stimulates the tyrosine phosphorylation of villin by c-Src kinase. These studies suggest that in cells, selective interaction of villin with either PIP₂ or LPA could have dramatically different outcomes on actin reorganization as well as phospholipid-regulated cell signaling. These studies provide a novel regulatory mechanism for phospholipid-induced changes in the microfilament structure and cell function and suggest that LPA could be an intracellular regulator of the actin cytoskeleton.     

Actin crosslinking proteins at the leading edge

The lamellar membrane at the leading edge of motile cells participates in a series of complex movements that involve the assembly and reorganization of actin bundles and networks, both structures formed by actin crosslinking proteins. Immunofluorescence miscroscopy localizes within lamellipodia and filopodia several crosslinking proteins including fascin, fimbrin, α-actinin and filamin. While these proteins may organize actin into bundles and networks, fimbrin and α-actinin may play an additional role of linking the cytoskeleton to cell-substratum adhesion sites.     

Giardia spp.: Distribution of contractile proteins in the attachment organelle

Giardia spp. trophozoites isolated from rat small intestine were examined by light microscopy, electron microscopy, SDS-gel electrophoresis, and immunocytochemistry. In SDS-gels of protein extracts of isolated Giardia spp. trophozoites protein bands corresponding to myosin, α-actinin, and actin were identified by comigration with avian myofibril proteins and molecular weight standards. Actin was specifically identified in SDS-gels by immunoautoradiography. Immunostaining for actin, α-actinin, myosin, and tropomyosin in trophozoites was demonstrated in the periphery of the ventral disc in an area corresponding to the lateral crest. Electron-dense fibrillar was observed in the lateral crest of the ventral disc by electron microscopy. Immunostaining for actin and α-actinin was also observed in the area of the median body, a microtubular organelle, and in electron-dense fibrillar material associated with the intracellular axonemes of the posterior-lateral flagella. The localization of these contractile proteins in the ventral disc suggests that they may play an important role in the mechanism of trophozoite attachment.     

α-Actinin 1 and α-actinin 4: Contrasting roles in the survival, motility, and RhoA signaling of astrocytoma cells

α-Actinin is a prominent actin filament associated protein for which different isoforms exist. Here, we have examined whether the two highly homologous non-muscle α-actinin isoforms 1 and 4 exhibit functional differences in astrocytoma cells. The protein levels of these isoforms were differentially regulated during the development and progression of astrocytomas, as α-actinin 1 was higher in astrocytomas compared to normal brains whereas α-actinin 4 was elevated in high-grade astrocytomas compared to normal brains and low grade astrocytomas. RNAi demonstrated contrasted contributions of α-actinin 1 and 4 to the malignant behavior of U-373, U-87 and A172 astrocytoma cells. While α-actinin 1 appeared to favor the expansion of U-373, U-87 and A172 astrocytoma cell populations, α-actinin 4 played this role only for U-373 cells. On the other hand, downregulation of α-actinin 4, but not 1, reduced cell motility, adhesion, cortical actin, and RhoA levels. Finally, in the three astrocytoma cell lines examined, α-actinin 1 and 4 had contrasted biochemical properties as α-actinin 4 was significantly more abundant in the actin cytoskeleton than α-actinin 1. Collectively, these findings suggest that α-actinin 1 and 4 are differentially regulated during the development and progression of astrocytomas because each of these isoforms uniquely contributes to distinct malignant properties of astrocytoma cells.     

Stimulation of tyrosine phosphorylation in lectin treated human lymphocytes

Large increases in tyrosine phosphorylation have been detected in subcellular matrixes isolated from lectin treated human lymphocytes. In lectin stimulated cells proteins of molecular weight 105, 75, 58 and 35 kDa contained phosphotyrosine (P-tyr) whereas non-stimulated cells had no 105 and low levels of P-tyr in proteins of 75, 58 and 35 kDa. In stimulated cells increased tyrosine kinase activity was also shown using gastrin as substrate. In both stimulated and non-stimulated cells the 58 kDa phosphoprotein was the most heavily labelled, after partial proteolysis of the 58 kDa different phosphopeptides were generated. A peptide with a sequence analogous to the autophosphorylated tyrosine site of pp60src inhibited tyrosine phosphorylation in stimulated cells. The lymphocyte system provides a useful tool to study normal tyrosine protein kinases and their role in cellular proliferation.     

c-Src links a RANK/αvβ3 integrin complex to the osteoclast cytoskeleton

RANK ligand (RANKL), by mechanisms unknown, directly activates osteoclasts to resorb bone. Because c-Src is key to organizing the cell's cytoskeleton, we asked if the tyrosine kinase also mediates RANKL-stimulated osteoclast activity. RANKL induces c-Src to associate with RANK(369-373) in an αvβ3-dependent manner. Furthermore, RANK(369-373) is the only one of six putative TRAF binding motifs sufficient to generate actin rings and activate the same cytoskeleton-organizing proteins as the integrin. While c-Src organizes the cell's cytoskeleton in response to the cytokine, it does not participate in RANKL-stimulated osteoclast formation. Attesting to their collaboration, αvβ3 and activated RANK coprecipitate, but only in the presence of c-Src. c-Src binds activated RANK via its Src homology 2 (SH2) domain and αvβ3 via its SH3 domain, suggesting the kinase links the two receptors. Supporting this hypothesis, deletion or inactivating point mutation of either the c-Src SH2 or SH3 domain obviates the RANK/αvβ3 association. Thus, activated RANK prompts two distinct signaling pathways; one promotes osteoclast formation, and the other, in collaboration with c-Src-mediated linkage to αvβ3, organizes the cell's cytoskeleton.     

Myofibril assembly visualized by imaging N-RAP, alpha-actinin, and actin in living cardiomyocytes

N-RAP is a striated muscle-specific scaffolding protein that organizes α-actinin and actin into symmetrical I-Z-I structures in developing myofibrils. Here we determined the order of events during myofibril assembly through time-lapse confocal microscopy of cultured embryonic chick cardiomyocytes coexpressing fluorescently tagged N-RAP and either α-actinin or actin. During de novo myofibril assembly, N-RAP assembled in fibrillar structures within the cell, with dots of α-actinin subsequently organizing along these structures. The initial fibrillar structures were reminiscent of actin fibrils, and coassembly of N-RAP and actin into newly formed fibrils supported this. The α-actinin dots subsequently broadened to Z-lines that were wider than the underlying N-RAP fibril, and N-RAP fluorescence intensity decreased. FRAP experiments showed that most of the α-actinin dynamically exchanged during all stages of myofibril assembly. In contrast, less than 20% of the N-RAP in premyofibrils was exchanged during 10-20 min after photobleaching, but this value increased to 70% during myofibril maturation. The results show that N-RAP assembles into an actin containing scaffold before α-actinin recruitment; that the N-RAP scaffold is much more stable than the assembling structural components; that N-RAP dynamics increase as assembly progresses; and that N-RAP leaves the structure after assembly is complete.     

The association of α-actinin with the plasma membrane

The role of α-actinin in the attachment of actin to plasma membranes has been investigated. Specific antibody staining of SDS gels has indicated that α-actinin is a major component in isolated plasma membranes prepared from three different cell types by two different procedures. Using specific extraction conditions, most of the α-actinin can be selectively extracted from the membranes with relatively little parallel release of actin. This selective dissociation of α-actinin from the plasma membrane leads us to conclude that α-actinin is present in these membrane preparations, because it is bound to actin, and that α-actinin does not form a direct link between actin and the membrane.     

Structural characterization of the interactions between palladin and α-actinin

The interaction between α-actinin and palladin, two actin-cross-linking proteins, is essential for proper bidirectional targeting of these proteins. As a first step toward understanding the role of this complex in organizing cytoskeletal actin, we have characterized binding interactions between the EF-hand domain of α-actinin (Act-EF34) and peptides derived from palladin and generated an NMR-derived structural model for the Act-EF34/palladin peptide complex. The critical binding site residues are similar to an α-actinin binding motif previously suggested for the complex between Act-EF34 and titin Z-repeats. The structure-based model of the Act-EF34/palladin peptide complex expands our understanding of binding specificity between the scaffold protein α-actinin and various ligands, which appears to require an α-helical motif containing four hydrophobic residues, common to many α-actinin ligands. We also provide evidence that the Family X mutation in palladin, associated with a highly penetrant form of pancreatic cancer, does not interfere with α-actinin binding.     

A potential role for the Src-like adapter protein SLAP-2 in signaling by the colony stimulating factor-1 receptor

The development of macrophages from myeloid progenitor cells is primarily controlled by the growth factor colony stimulating factor-1 (CSF-1) and its cognate receptor, a transmembrane tyrosine kinase encoded by the c-Fms proto-oncogene. The CSF-1 receptor exerts its biological effects on cells via a range of signaling proteins including Erk1/2 and Akt. Here we have investigated the potential involvement of the Src-like adapter protein (SLAP-2) in signaling by the CSF-1 receptor in mouse bone marrow-derived macrophages. RT-PCR analysis revealed constitutive expression of the SLAP-2 gene in bone marrow macrophages. Surprisingly, co-immunoprecipitation and GST binding experiments demonstrated that the CSF-1 receptor could bind to SLAP-2 in a ligand-independent manner. Furthermore, the binding of SLAP-2 to the CSF-1 receptor involved multiple domains of SLAP-2. SLAP-2 also bound c-Cbl, with the interaction being mediated, at least in part, by the unique C-terminal domain of SLAP-2. Overexpression of SLAP-2 in bone marrow macrophages partially suppressed the CSF-1-induced tyrosine phosphorylation and/or expression level of a approximately 80 kDa protein without affecting CSF-1-induced global tyrosine phosphorylation, or activation of Akt or Erk1/2. Significantly, CSF-1 stimulation induced serine phosphorylation of SLAP-2. Pharmacologic inhibition of specific protein kinases revealed that CSF-1-induced phosphorylation of SLAP-2 was dependent on JNK activity. Taken together, our results suggest that SLAP-2 could potentially be involved in signaling by the CSF-1 receptor.     

Interaction of iodinated vinculin, metavinculin and α-actinin with cytoskeletal proteins

Iodinated vinculin, metavinculin and α-actinin were used to probe the interaction of these proteins with electrophoretically separated cytoskeletal proteins. Using the gel overlay technique, we detected strong binding of ¹²⁵I-vinculin and ¹²⁵I-metavinculin to α-actinin, 175 kDa polypeptide, talin, vinculin and metavinculin themselves, and moderate binding to actin.¹²⁵I-α-actinin was capable of interacting with vinculin and metavinculin. The specific binding of ¹²⁵-I-α-actinin to vinculin and metavinculin immobilized on a polysterene surface was also demonstrated. We suggest that the ability of vinculin and α-actinin to form a complex may be realized in microfilament-membrane linkages.