Tetsuya Nakamoto

Cardiovascular anomaly, impaired actin bundling and resistance to src-induced transformation in mice lacking p130Cas

p130Cas (Cas), the protein encoded by the Crkas gene (also known as Cas), is an adaptor molecule with a unique structure that contains a Src homology (SH)-3 domain followed by multiple YXXP motifs and a proline-rich region. Cas was originally cloned as a highly tyrosine-phosphorylated protein in cells transformed by v-Src (refs 2,3) or v-Crk (ref. 4) and has subsequently been implicated in a variety of biological processes including cell adhesion, cell migration, growth factor stimulation, cytokine receptor engagement and bacterial infection. To determine its role in vivo, we generated mice lacking Cas. Cas-deficient embryos died in utero showing marked systemic congestion and growth retardation. Histologically, the heart was poorly developed and blood vessels were prominently dilated. Electron microscopic analysis of the heart revealed disorganization of myofibrils and disruption of Z-disks. In addition, actin stress fiber formation was severely impaired in Cas-deficient primary fibroblasts. Moreover, expression of activated Src in Cas-deficient primary fibroblasts did not induce a fully transformed phenotype, possibly owing to insufficient accumulation of actin cytoskeleton in podosomes. These findings have defined Cas function in cardiovascular development, actin filament assembly and Src-induced transformation.

Direct binding of C-terminal region of p130Cas to SH2 and SH3 domains of Src kinase.

p130 is a major tyrosine-phosphorylated protein that tightly binds v-Crk in v-crk-transformed cells and v-Src in v-src-transformed cells. The “substrate domain” of p130 contains 15 possible Src homology (SH) 2-binding motifs, most of which conform to the binding motif for the Crk SH2 domain. Another region near its C terminus contains possible binding motifs for the Src SH2 domain and proline-rich sequences that are candidates for SH3-binding sites. Using GST fusion proteins, we revealed that both SH2 and SH3 domains of Src bind p130, whereas v-Crk binds p130 through its SH2 domain. We located the binding site of p130 for the Src SH3 domain at the sequence RPLPSPP in the region near its C terminus. Mutations within this sequence or at Tyr of p130 caused a significant reduction in the association of p130 with Src, and no association was detected when both of them were deleted. The kinase activity in v-Crk-transformed cells was also associated with p130 through this region. On the other hand, the deletion of the substrate domain abolished the binding with v-Crk. The association through the C-terminal region of p130 with Src kinase may facilitate effective hyperphosphorylation of tyrosine residues in the substrate domain of p130, resulting in the binding of SH2-containing molecules to p130.

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.

EphrinA1-induced cytoskeletal re-organization requires FAK and p130cas

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 p130cas were identified as the major ephrin-dependent phosphotyrosyl proteins during the ephrin-induced morphological changes. Mouse embryonic fibroblasts (MEFs) derived from FAK−/− and p130cas−/− mice had severe defects in ephrinA1-induced cell spreading, which were reversed after re-expression of FAK or p130cas, 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 p130cas-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.

Requirements for localization of p130cas to focal adhesions.

p130cas (Cas) is an adapter protein that has an SH3 domain followed by multiple SH2 binding motifs in the substrate domain. It also contains a tyrosine residue and a proline-rich sequence near the C terminus, which are the binding sites for the SH2 and SH3 domains of Src kinase, respectively. Cas was originally identified as a major tyrosine-phosphorylated protein in v-Crk- and v-Src-transformed cells. Subsequently, Cas was shown to be inducibly tyrosine phosphorylated upon integrin stimulation; it is therefore regarded as one of the focal adhesion proteins. Using an immunofluorescence study, we examined the subcellular localization of Cas and determined the regions required for its localization to focal adhesions. In nontransformed cells, Cas was localized predominantly to the cytoplasm and partially to focal adhesions. However, in 527F-c-Src-transformed cells, Cas was localized mainly to podosomes, where the focal adhesion proteins are assembled. The localization of Cas to focal adhesions was also observed in cells expressing the kinase-negative 527F/295M-c-Src. A series of analyses with deletion mutants expressed in various cells revealed that the SH3 domain of Cas is necessary for its localization to focal adhesions in nontransformed cells while both the SH3 domain and the C-terminal Src binding domain of Cas are required in 527F-c-Src-transformed cells and fibronectin-stimulated cells. In addition, the localization of Cas to focal adhesions was abolished in Src-negative cells. These results demonstrate that the SH3 domain of Cas and the association of Cas with Src kinase play a pivotal role in the localization of Cas to focal adhesions.

Acetylation of GATA‐3 affects T‐cell survival and homing to secondary lymphoid organs

Acetylation of a transcription factor has recently been shown to play a significant role in gene regulation. Here we show that GATA‐3 is acetylated in T cells and that a mutation introduced into amino acids 305–307 (KRR‐GATA3) creates local hypoacetylation in GATA‐3. Remarkably, KRR‐GATA3 possesses the most potent suppressive effect when compared with other mutants that are disrupted in putative acetylation targets. Expressing this mutant in peripheral T cells results in defective T‐cell homing to systemic lymphnodes, and prolonged T‐cell survival after activation. These findings have significant implications in that the acetylation state of GATA‐3 affects its physiological function in the immune system and, more importantly, provides evidence for the novel role of GATA‐3 in T‐cell survival and homing to secondary lymphoid organs.

MICAL, a Novel CasL Interacting Molecule, Associates with Vimentin

CasL/HEF1 belongs to the p130Cas family. It is tyrosine-phosphorylated following β1 integrin and/or T cell receptor stimulation and is thus considered to be important for immunological reactions. CasL has several structural motifs such as an SH3 domain and a substrate domain and interacts with many molecules through these motifs. To obtain more insights on the CasL-mediated signal transduction, we sought proteins that interact with the CasL SH3 domain by far Western screening, and we identified a novel human molecule, MICAL (a Molecule Interacting withCasL). MICAL is a protein of 118 kDa and is expressed in the thymus, lung, spleen, kidney, testis, and hematopoietic cells. MICAL has a calponin homology domain, a LIM domain, a putative leucine zipper motif, and a proline-rich PPKPP sequence. MICAL associates with CasL through this PPKPP sequence. MICAL is a cytoplasmic protein and colocalizes with CasL at the perinuclear area. Through the COOH-terminal region, MICAL also associates with vimentin that is a major component of intermediate filaments. Immunostaining revealed that MICAL localizes along with vimentin intermediate filaments. These results suggest that MICAL may be a cytoskeletal regulator that connects CasL to intermediate filaments.

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.

Reverse seroconversion of Hepatitis B virus after hematopoietic stem cell transplantation

Hepatitis B virus (HBV) reactivation in patients previously positive for hepatitis B surface antibody (HBsAb), so-called reverse seroconversion, has been considered to be a rare complication after hematopoietic stem cell transplantation (HSCT). We experienced two patients who developed reverse seroconversion among nine who were HBsAb positive and Hepatitis B core antibody (HBcAb) positive before HSCT; one after autologous bone marrow transplantation (BMT) and another after allogeneic peripheral blood stem cell transplantation (PBSCT). We reviewed the literature and considered that reverse seroconversion of HBV after HSCT is not uncommon among HBsAb positive recipients. The use of corticosteroids, the lack of HBsAb in donor, and a decrease in serum HBsAb and HBcAb levels may predict reverse seroconversion after HSCT.

Integrin-mediated signal transduction in cells lacking focal adhesion kinase p125FAK.

We have previously shown that integrin‐dependent tyrosine phosphorylation of p130Cas (Cas) could be induced in a mouse fibroblast cell line that does not express focal adhesion kinase p125FAK (FAK). By analyzing FAK‐deficient (FAK−/−) cells transiently expressing Cas mutant proteins, we demonstrate here that the Src homology 3 (SH3) domain of Cas is indispensable for adhesion‐mediated Cas phosphorylation in this mutant cell line. While the FAK directly binds to Cas‐SH3, our findings imply that SH3‐binding molecule(s) other than FAK might regulate Cas phosphorylation, at least in FAK−/− cells. In this regard, we observed that FAK−/− cells expressed cell adhesion kinase β (CAKβ), a protein tyrosine kinase of the FAK subfamily. CAKβ expressed by FAK−/− cells was associated in vivo with Cas in a Cas‐SH3‐dependent manner. Moreover, integrin stimulation induces tyrosine phosphorylation of CAKβ in FAK−/− cells. Thus, our results suggest that CAKβ contributes to integrin‐mediated signal transduction in place of FAK in FAK‐deficient cells.