Stability of mRNA influences osteoporotic bone mass via CNOT3.

Osteoclastogenesis is under the control of posttranscriptional and transcriptional events. However, posttranscriptional regulation of osteoclastogenesis is incompletely understood. CNOT3 is a component of the CCR4 family that regulates mRNA stability, but its function in bone is not known. Here, we show that Cnot3 deficiency by deletion of a single allele induces osteoporosis. Cnot3 deficiency causes an enhancement in bone resorption in association with an elevation in bone formation, resulting in high-turnover type bone loss. At the cellular level, Cnot3 deficiency enhances receptor activator of NF-κB ligand (RANKL) effects on osteoclastogenesis in a cell-autonomous manner. Conversely, Cnot3 deficiency does not affect osteoblasts directly. Cnot3 deficiency does not alter RANKL expression but enhances receptor activator of NF-κB (RANK) mRNA expression in bone in vivo. Cnot3 deficiency promotes RANK mRNA stability about twofold in bone marrow cells of mice. Cnot3 knockdown also increases RANK mRNA expression in the precursor cell line for osteoclasts. Anti-CNOT3 antibody immunoprecipitates RANK mRNA. Cnot3 deficiency stabilizes luciferase reporter expression linked to the 3'-UTR fragment of RANK mRNA. In contrast, Cnot3 overexpression destabilizes the luciferase reporter linked to RANK 3'-UTR. In aged mice that exhibit severe osteoporosis, Cnot3 expression levels in bone are reduced about threefold in vivo. Surprisingly, Cnot3 deficiency in these aged mice further exacerbates osteoporosis, which also occurs via enhancement of osteoclastic activity. Our results reveal that CNOT3 is a critical regulator of bone mass acting on bone resorption through posttranscriptional down-regulation of RANK mRNA stability, at least in part, even in aging-induced osteoporosis.

Mice Deficient in CIZ/NMP4 Develop an Attenuated Form of K/BxN-Serum Induced Arthritis.

CIZ/NMP4 (Cas interacting zinc finger protein, Nmp4, Zfp384) is a transcription factor that is known to regulate matrix related-proteins. To explore the possible pathophysiological role of CIZ/NMP4 in arthritis, we examined CIZ/NMP4 expression in articular cartilage in arthritis model. CIZ/NMP4 was expressed in the articular chondrocytes of mice at low levels while its expression was enhanced when arthritis was induced. Arthritis induction increased clinical score in wild type mice. In contrast, CIZ/NMP4 deficiency suppressed such rise in the levels of arthritis score and swelling of soft tissue. CIZ/NMP4 deficiency also reduced invasion of inflammatory cells in joint tissue. Quantitative PCR analyses of mRNA from joints revealed that arthritis-induced increase in expressions of IL-1ß was suppressed by CIZ/NMP4 deficiency. CIZ/NMP4 bound to IL-1ß promoter and activated its transcription. The increase in CIZ/NMP4 in arthritis was also associated with enhancement in bone resorption and cartilage matrix degradation. In fact, RANKL, a signaling molecule prerequisite for osteoclastogenesis and, MMP-3, a clinical marker for arthritis were increased in joints upon arthritis induction. In contrast, CIZ/NMP4 deficiency suppressed the arthritis-induced increase in bone resorption, expression of RANKL and MMP-3 mRNA. Thus, CIZ/NMP4 plays a role in the development of arthritis at least in part through regulation of key molecules related to the arthritis.

Anabolic action of parathyroid hormone regulated by the ß2-adrenergic receptor.

Parathyroid hormone (PTH), the major calcium-regulating hormone, and norepinephrine (NE), the principal neurotransmitter of sympathetic nerves, regulate bone remodeling by activating distinct cell-surface G protein-coupled receptors in osteoblasts: the parathyroid hormone type 1 receptor (PTHR) and the ß(2)-adrenergic receptor (ß(2)AR), respectively. These receptors activate a common cAMP/PKA signal transduction pathway mediated through the stimulatory heterotrimeric G protein. Activation of ß(2)AR via the sympathetic nervous system decreases bone formation and increases bone resorption. Conversely, daily injection of PTH (1-34), a regimen known as intermittent (i)PTH treatment, increases bone mass through the stimulation of trabecular and cortical bone formation and decreases fracture incidences in severe cases of osteoporosis. Here, we show that iPTH has no osteoanabolic activity in mice lacking the ß(2)AR. ß(2)AR deficiency suppressed both iPTH-induced increase in bone formation and resorption. We showed that the lack of ß(2)AR blocks expression of iPTH-target genes involved in bone formation and resorption that are regulated by the cAMP/PKA pathway. These data implicate an unexpected functional interaction between PTHR and ß(2)AR, two G protein-coupled receptors from distinct families, which control bone formation and PTH anabolism.

Migration linked to FUCCI-indicated cell cycle is controlled by PTH and mechanical stress.

Bone metabolism is maintained via balanced repetition of bone resorption by osteoclasts and bone formation by osteoblasts. Osteoblastic cells are capable of conducting self-renewal and differentiation that are basically associated with cell-cycle transition to enable cell specification and bone formation. Osteoblasts are also migrating to fill the resorption cavity curved by osteoclasts during bone remodeling to maintain homeostasis of bone mass whose imbalance leads to osteoporosis. However, technical difficulties have hampered the research on the dynamic relationship between cell cycle and migration in osteoblasts. In this report, we overcome these problems by introducing fluorescent ubiquitination-based cell cycle indicator (FUCCI) reporter system in calvarial osteoblastic cells and reveal that the cells in G1 as well as S/G2 /M phase are migrating. Furthermore, the osteoblastic cells in S/G2 /M phase migrate faster than those in G1 phase. Interestingly, parathyroid hormone (PTH) as an anabolic agent enhances migration velocity of the cells. Mechanical stress, another anabolic signal, also enhances migration velocity. In contrast, in the presence of both PTH and mechanical stress, the migration velocity returns to the base line levels revealing the interaction between the two anabolic stimuli in the regulation of cell migration. Importantly, PTH and mechanical stress also interact when they regulate the transition of cell cycle. These data demonstrate that osteoblastic migration is linked to cell cycle and it is under the control of mechanical and chemical stimuli that coordinate to regulate bone mass.

Sympathetic control of bone mass regulated by osteopontin.

The sympathetic nervous system suppresses bone mass by mechanisms that remain incompletely elucidated. Using cell-based and murine genetics approaches, we show that this activity of the sympathetic nervous system requires osteopontin (OPN), a cytokine and one of the major members of the noncollagenous extracellular matrix proteins of bone. In this work, we found that the stimulation of the sympathetic tone by isoproterenol increased the level of OPN expression in the plasma and bone and that mice lacking OPN (OPN-KO) suppressed the isoproterenol-induced bone loss by preventing reduced osteoblastic and enhanced osteoclastic activities. In addition, we found that OPN is necessary for changes in the expression of genes related to bone resorption and bone formation that are induced by activation of the sympathetic tone. At the cellular level, we showed that intracellular OPN modulated the capacity of the ß2-adrenergic receptor to generate cAMP with a corresponding modulation of cAMP-response element binding (CREB) phosphorylation and associated transcriptional events inside the cell. Our results indicate that OPN plays a critical role in sympathetic tone regulation of bone mass and that this OPN regulation is taking place through modulation of the ß2-adrenergic receptor/cAMP signaling system.

Profilin1 regulates sternum development and endochondral bone formation.

Bone development is a dynamic process that requires cell motility and morphological adaptation under the control of actin cytoskeleton. This actin cytoskeleton system is regulated by critical modulators including actin-binding proteins. Among them, profilin1 (Pfn1) is a key player to control actin fiber structure, and it is involved in a number of cellular activities such as migration. During the early phase of body development, skeletal stem cells and osteoblastic progenitor cells migrate to form initial rudiments for future skeletons. During this migration, these cells extend their process based on actin cytoskeletal rearrangement to locate themselves in an appropriate location within microenvironment. However, the role of Pfn1 in regulation of mesenchymal progenitor cells (MPCs) during skeletal development is incompletely understood. Here we examined the role of Pfn1 in skeletal development using a genetic ablation of Pfn1 in MPCs by using Prx1-Cre recombinase. We found that Pfn1 deficiency in MPCs caused complete cleft sternum. Notably, Pfn1-deficient mice exhibited an absence of trabecular bone in the marrow space of appendicular long bone. This phenotype is location-specific, as Pfn1 deficiency did not largely affect osteoblasts in cortical bone. Pfn1 deficiency also suppressed longitudinal growth of long bone. In vitro, Pfn1 deficiency induced retardation of osteoblastic cell migration. These observations revealed that Pfn1 is a critical molecule for the skeletal development, and this could be at least in part associated with the retardation of cell migration.

Nck1 deficiency accelerates unloading-induced bone loss.

Mechanical stress is an important signal to determine the levels of bone mass. Unloading-induced osteoporosis is a critical issue in bed-ridden patients and astronauts. Many molecules have been suggested to be involved in sensing mechanical stress in bone, though the mechanisms involved in this phenomenon are not fully understood. Nck1 is an adaptor protein known to mediate signaling from plasma membrane-activated receptors to cytosolic effectors regulating actin cytoskeleton remodeling. Nck1 has also been implicated in cellular responses to endoplasmic reticulum stress. In vitro, in case of cell stress the actin cytoskeleton is disrupted and in such cases Nck1 has been reported to enter the nucleus of the cells to mediate the nuclear actin polymerization. However, the role of Nck1 in vivo during the bone response to mechanical stimuli is unknown. The purpose of this study is to examine the role of Nck1 in unloading-induced bone loss in vivo. Sciatic and femoral nerve resection was conducted. Neurectomy-based unloading enhanced Nck1 gene expression in bone about twofold. Using the Nck1 deficient mice and control Nck1+/+, effects of neurectomy-based unloading on bone structure were examined. Unloading reduced bone volume in wild type mice by 30% whereas the levels in bone loss were exacerbated to 50% in Nck1 deficient mice due to neurectomy after 4 weeks. These data demonstrate that Nck1 gene deficiency accelerates the mechanical unloading-induced bone loss suggesting Nck1 to be a crucial molecule in mechanical stress mediated regulation in bone metabolism.

Non-sebaceous lymphadenoma of the salivary gland with serous acinic cell differentiation, a first case report in the literature.

We report an atypical case of non-sebaceous lymphadenoma (NSL) of the parotid gland showing serous acinic cell differentiation. NSL is a rare benign salivary gland tumor with intermingled lymphoid and epithelial tissues without sebaceous differentiation. Since the first description of a case designated by Auclair et al. as 'non-sebaceous lymphadenoma' in 1991, to our best knowledge, only 37 cases have been reported, and no differentiation of tumor cells into serous acinic cell lineage has been described so far. In this paper, we present a case of NSL with serous acinic cell differentiation. The patient was a 78-year-old female with the complaint of a painless mass in the left parotid gland. The surgically resected tumor was encapsulated and measured 13 × 9 × 9 mm. Histologically, the tumor had the features of NSL, and an unusual finding of this case was the presence of epithelial cells with serous acinic cell differentiation. Dense cytoplasm packed with basophilic granules in those cells was positive in periodic acid Schiff reaction after diastase digestion (D-PAS), which was compatible with the feature of serous acinic cell differentiation. Possible differentiation of the epithelial component into serous acinic cell in this rare entity is warranted to avoid confusion in the diagnosis.

CIZ/NMP4 is expressed in B16 melanoma and forms a positive feedback loop with RANKL to promote migration of the melanoma cells.

Tumor metastasis to bone is a serious pathological situation that causes severe pain, and deterioration in locomoter function. However, the mechanisms underlying tumor metastasis is still incompletely understood. CIZ/NMP4 is a nucleocytoplasmic shuttling protein and its roles in tumor cells have not been known. We, therefore, hypothesized the role of CIZ/NMP4 in B16 melanoma cells that metastasize to bone. CIZ/NMP4 is expressed in B16 cells. The CIZ/NMP4 expression levels are correlated to the metastatic activity in divergent types of melanoma cells. Overexpression of CIZ/NMP4 increased B16 cell migration in Trans-well assay. Conversely, siRNA-based knockdown of CIZ/NMP4 suppressed migratory activity of these cells. As RANKL promotes metastasis of tumor cells in bone, we tested its effect on CIZ in melanoma cells. RANKL treatment enhanced CIZ/NMP4 expression. This increase of CIZ by RANKL promoted migration. Conversely, we identified CIZ/NMP4 binding site in the promoter of RANKL. Furthermore, luciferase assay indicated that CIZ/NMP4 overexpression enhanced RANKL promoter activities, revealing a positive feedback loop of CIZ/NMP4 and RANKL in melanoma. These observations indicate that CIZ/NMP4 is critical regulator of metastasis of melanoma cells.

Nanogel-based scaffold delivery of prostaglandin E(2) receptor-specific agonist in combination with a low dose of growth factor heals critical-size bone defects in mice.

OBJECTIVE: Regeneration of bone requires the combination of appropriate drugs and an appropriate delivery system to control cell behavior. However, the delivery of multiple drugs to heal bone is complicated by the availability of carriers. The aim of this study was to explore a new system for delivery of a selective EP4 receptor agonist (EP4A) in combination with low-dose bone morphogenetic protein 2 (BMP-2). METHODS: Combined delivery of EP4A and BMP-2 was carried out with a nanogel-based scaffold in the shape of a disc, to repair critical-size circle-shaped bone defects in calvariae that otherwise did not heal spontaneously. RESULTS: Combination treatment with EP4A and low-dose BMP-2 in nanogel efficiently activated bone cells to regenerate calvarial bone by forming both outer and inner cortical plates as well as bone marrow tissue to regenerate a structure similar to that of intact calvaria. EP4A enhanced low-dose BMP-2-induced cell differentiation and activation of transcription events in osteoblasts. CONCLUSION: These data indicate that combined delivery of EP4A and low-dose BMP-2 via nanogel-based hydrogel provides a new system for bone repair.

Schnurri-2 deficiency counteracts against bone loss induced by ovariectomy.

Schnurri (Shn)-2 is a transcriptional modulator of bone formation and bone resorption and its deficiency causes low turnover state with higher cancellous bone mass due to the defects in osteoclasts that exceeds the defects in osteoblasts in mice. We addressed whether such low turnover of bone remodeling in Shn2 deficiency may be modulated in the absence of estrogen that induces high turnover state in vivo. Ovariectomy reduced bone mass in wild type compared to sham operated control mice and such reduction in bone mass was also observed in Shn2 deficient mice. However, due to the high levels of basal bone mass in Shn2 deficient mice, the bone mass levels after ovariectomy were still comparable to sham operated wild-type mice. Analysis indicated that estrogen depletion increased bone resorption at similar levels in wild type and Shn2 deficient mice though the basal levels of osteoclast number was slightly lower in Shn2-deficient mice. In contrast, basal levels of bone marrow cell mineralization in cultures were low in Shn2-deficeint mice while estrogen depletion increased the mineralization levels to those that were comparable to sham wild type. This indicates that Shn2-deficient mice maintain bone mass at the levels comparable to wild-type sham mice even after ovariectomy-induced bone loss and this correlates with the high levels of mineralization activity in bone marrow cells after ovariectomy.

MURF1 deficiency suppresses unloading-induced effects on osteoblasts and osteoclasts to lead to bone loss.

Loss of mechanical stress or unloading causes disuse osteoporosis that leads to fractures and deteriorates body function and affects mortality rate in aged population. This bone loss is due to reduction in osteoblastic bone formation and increase in osteoclastic bone resorption. MuRF1 is a muscle RING finger protein which is involved in muscle wasting and its expression is enhanced in the muscle of mice subjected to disuse condition such as hind limb unloading (HU). However, whether MuRF1 is involved in bone loss due to unloading is not known. We therefore examined the effects of MuRF1 deficiency on unloading-induced bone loss. We conducted hind limb unloading of MuRF1 KO mice and wild-type control mice. Unloading induced about 60% reduction in cancellous bone volume (BV/TV) in WT mice. In contrast, MuRF1 deficiency suppressed unloading-induced cancellous bone loss. The cortical bone mass was also reduced by unloading in WT mice. In contrast, MuRF1 deficiency suppressed this reduction in cortical bone mass. To understand whether the effects of MuRF1 deficiency suppress bone loss is on the side of bone formation or bone resorption, histomorphometry was conducted. Unloading reduced bone osteoblastic formation rate (BFR) in WT. In contrast, MuRF1 deficiency suppressed this reduction. Regarding bone resorption, unloading increased osteoclast number in WT. In contrast, MURF1 deficiency suppressed this osteoclast increase. These data indicated that the ring finger protein, MURF1 is involved in disuse-induced bone loss in both of the two major bone remodeling activities, osteoblastic bone formation and osteoclastic bone resorption.

Per-1 is a specific clock gene regulated by parathyroid hormone (PTH) signaling in osteoblasts and is functional for the transcriptional events induced by PTH.

Per-1 is one of the clock genes and is known to regulate various biological events including bone mass determination. Parathyroid hormone is anabolic to bone while the mechanism of its action is not fully understood. Here, we examined the role of PTH on Per-1 gene expression under osteoblast specific PTH signaling. Constitutively active PTH receptor (caPPR) expressed specifically in osteoblasts in transgenic mice activates Per-1 gene expression in bone. This is specific as expression of other clock gene Bmal-1 is not affected by caPPR over-expression. Per-1 is also expressed in osteoblastic cell line. Interestingly, Per-1 expression is required for PTH signaling-induced CRE dependent transcription. This is forming a positive feed back loop in the anabolic action of PTH signaling and Per-1 in bone. These data indicate that PTH singling in osteoblasts activates Per-1 gene expression in vivo in association with its anabolic action in bone at least in part through the regulation of transcriptional events.

The nucleocytoplasmic shuttling protein CIZ reduces adult bone mass by inhibiting bone morphogenetic protein-induced bone formation.

Osteoporosis is a major health problem; however, the mechanisms regulating adult bone mass are poorly understood. Cas-interacting zinc finger protein (CIZ) is a nucleocytoplasmic shuttling protein that localizes at cell adhesion plaques that form where osteoblasts attach to substrate. To investigate the potential role of CIZ in regulating adult bone mass, we examined the bones in CIZ-deficient mice. Bone volume was increased and the rates of bone formation were increased in CIZ-deficient mice, whereas bone resorption was not altered. CIZ deficiency enhanced the levels of mRNA expression of genes encoding proteins related to osteoblastic phenotypes, such as alkaline phosphatase (ALP) as well as osterix mRNA expression in whole long bones. Bone marrow cells obtained from the femora of CIZ-deficient mice revealed higher ALP activity in culture and formed more mineralized nodules than wild-type cells. CIZ deficiency enhanced bone morphogenetic protein (BMP)-induced osteoblastic differentiation in bone marrow cells in cultures, indicating that BMP is the target of CIZ action. CIZ deficiency increased newly formed bone mass after femoral bone marrow ablation in vivo. Finally, BMP-2-induced bone formation on adult mouse calvariae in vivo was enhanced by CIZ deficiency. These results establish that CIZ suppresses the levels of adult bone mass through inhibition of BMP-induced activation of osteoblasts.

Crk-associated substrate lymphocyte type regulates myeloid cell motility and suppresses the progression of leukemia induced by p210Bcr/Abl.

The p210Bcr/Abl and p190Bcr/Abl fusion oncoproteins are known to cause chronic myelogenous leukemia (CML) and acute lymphoblastic leukemia (ALL). Bcr/Abl phosphorylates several proteins that can lead to leukemogenesis. Crk-associated substrate lymphocyte type (Cas-L)/human enhancer of filamentation-1 (HEF1)/neural precursor cell expressed, developmentally down-regulated 9 (NEDD9) is an adapter protein at focal adhesions known to be associated with solid tumor metastasis. Crk-associated substrate lymphocyte type has also been reported to be tyrosine phosphorylated by p190Bcr/Abl. We demonstrated that Cas-L was expressed in murine granulocytes, as well as in lymphocytes, and that Cas-L-deficient (Cas-L(-/-) ) granulocytes had increased migratory activity and decreased adhesiveness. To examine whether Cas-L was involved in leukemogenesis by p210Bcr/Abl, we generated Cas-L(-/-) p210Bcr/Abl transgenic mice. The mice displayed early development of myeloproliferative neoplasm seen in the chronic phase of CML, which resulted in the early death of the mice. Pathologically, increased infiltration of myeloid cells into several tissues was detected in the absence of Cas-L. In a hematopoietic reconstitution assay, Cas-L(-/-) p210Bcr/Abl transgenic cells showed a low population in the spleen, although only their myeloid cell population was normal. Thus, Cas-L seems to regulate the progression of CML in a negative way, presumably by attenuating extramedullary hyperplasia.

EphrinA1-induced cytoskeletal re-organization requires FAK and p130(cas).

Ephrins and Eph receptors are involved in axon guidance and cellular morphogenesis. An interaction between ephrin and Eph receptors elicits neuronal growth-cone collapse through cytoskeletal disassembly. When NIH3T3 cells were plated onto an ephrinA1-coated surface, the cells both adhered and spread. Adhesion and spreading proceeded concomitantly with changes in both the actin and microtubule cytoskeleton. EphA2, focal adhesion kinase (FAK) and p130(cas) were identified as the major ephrin-dependent phosphotyrosyl proteins during the ephrin-induced morphological changes. Mouse embryonic fibroblasts (MEFs) derived from FAK(-/-) and p130(cas-/-) mice had severe defects in ephrinA1-induced cell spreading, which were reversed after re-expression of FAK or p130(cas), respectively. Expression of a constitutively active EphA2 induced NIH3T3 cells to undergo identical, but ligand-independent, morphological changes. These data show that ephrinA1 can induce cell adhesion and actin cytoskeletal changes in fibroblasts in a FAK- and p130(cas)-dependent manner, through activation of the EphA2 receptor. The finding that ephrin Eph signalling can result in actin cytoskeletal assembly, rather than disassembly, has many implications for ephrin Eph responses in other cell types.

[Control of bone remodeling by nervous system. Nervous system and bone].

The relationship between bone and nervous system has been considered based on clinical observations such as Reflex Sympathetic Dystrophy (RSD) or ectopic bone formation associated with spinal cord injury. Sympathtic nervous tone has been reported to control both bone formation and bone resorption. Unloading induces bone loss due to an increase in bone resorption and decrease in bone formation. Both of these two arms are shown to be influenced by sympathetic tone. In addition, cannabinoid receptor has been observed to be involved in regulation of bone mass. Psychiatric diseases such as depression has also been suggested to linked to the alteration in the levels of bone mass. These observations together point to importance of the relationship between bone mass and nervous system.

Functional analysis of Src homology 3-encoding exon (exon 2) of p130Cas in primary fibroblasts derived from exon 2-specific knockout mice.

p130Cas (Cas, Crk-associated substrate) is an adaptor molecule composed of a Src homology 3 (SH3) domain, a substrate domain (SD) and a Src binding domain (SBD). The SH3 domain of Cas associates with focal adhesion kinase (FAK), but its role in cellular function has not fully been understood. To address this issue, we established and analyzed primary fibroblasts derived from mice expressing a truncated Cas lacking exon 2, which encodes the SH3 domain (Cas Deltaexon 2). In comparison to wild-type cells, Cas exon 2(Delta/Delta) cells showed reduced motility, which could be due to impaired tyrosine-phosphorylation of FAK and Cas, reduced FAK/Cas/Src/CrkII binding, and also impaired localization of Cas Deltaexon 2 to focal adhesions on fibronectin. In addition, to analyze downstream signaling pathways regulated by Cas exon 2, we performed microarray analyses. Interestingly, we found that a deficiency of Cas exon 2 up-regulated expression of CXC Chemokine Receptor-4 and CC Chemokine Receptor-5, which may be regulated by IkappaBalpha phosphorylation. These results indicate that the SH3-encoding exon of Cas participates in cell motility, tyrosine-phosphorylation of FAK and Cas, FAK/Cas/Src/CrkII complex formation, recruitment of Cas to focal adhesions and regulation of cell motility-associated gene expression in primary fibroblasts.

ROCK and mDia1 antagonize in Rho-dependent Rac activation in Swiss 3T3 fibroblasts.

The small GTPase Rho acts on two effectors, ROCK and mDia1, and induces stress fibers and focal adhesions. However, how ROCK and mDia1 individually regulate signals and dynamics of these structures remains unknown. We stimulated serum-starved Swiss 3T3 fibroblasts with LPA and compared the effects of C3 exoenzyme, a Rho inhibitor, with those of Y-27632, a ROCK inhibitor. Y-27632 treatment suppressed LPA-induced formation of stress fibers and focal adhesions as did C3 exoenzyme but induced membrane ruffles and focal complexes, which were absent in the C3 exoenzyme-treated cells. This phenotype was suppressed by expression of N17Rac. Consistently, the amount of GTP-Rac increased significantly by Y-27632 in LPA-stimulated cells. Biochemically, Y-27632 suppressed tyrosine phosphorylation of paxillin and focal adhesion kinase and not that of Cas. Inhibition of Cas phosphorylation with PP1 or expression of a dominant negative Cas mutant inhibited Y-27632-induced membrane ruffle formation. Moreover, Crk-II mutants lacking in binding to either phosphorylated Cas or DOCK180 suppressed the Y-27632-induced membrane ruffle formation. Finally, expression of a dominant negative mDia1 mutant also inhibited the membrane ruffle formation by Y-27632. Thus, these results have revealed the Rho-dependent Rac activation signaling that is mediated by mDia1 through Cas phosphorylation and antagonized by the action of ROCK.

Expression and tyrosine phosphorylation of Crk-associated substrate lymphocyte type (Cas-L) protein in human neutrophils.

Crk-associated substrate lymphocyte type (Cas-L) protein, also known as human enhancer of filamentation 1 (Hef1) or neural precursor cell-expressed, developmentally down-regulated gene 9 (Nedd9), belongs to the Cas family of adapter proteins, which are involved in integrin signaling. Previous reports showed that Cas-L is expressed preferentially in lymphocytes and epithelial cells. Cas-L mediates signals from integrins, T-cell receptors, B-cells receptors, and transforming growth factor beta, leading to cell movement and cell division. Here, we report the expression of Cas-L in neutrophils. Cas-L was tyrosine-phosphorylated when human neutrophils were stimulated by fMLP, tumor necrosis factor-alpha (TNF), or lipopolysaccharide. The tyrosine phosphorylation of Cas-L in fMLP- or TNF- stimulated neutrophils was further enhanced by adhesion of the cells to their substrates. Cas-L was found to be localized at focal adhesions in stimulated neutrophils based on immunofluorescence microscopy. These findings suggest that Cas-L is one of the targets of inflammatory cytokines and is also modulated by cell adhesion process in neutrophils.