Real-time TIRF observation of vinculin recruitment to stretched α-catenin by AFM.

Adherens junctions (AJs) adaptively change their intensities in response to intercellular tension; therefore, they integrate tension generated by individual cells to drive multicellular dynamics, such as morphogenetic change in embryos. Under intercellular tension, α-catenin, which is a component protein of AJs, acts as a mechano-chemical transducer to recruit vinculin to promote actin remodeling. Although in vivo and in vitro studies have suggested that α-catenin-mediated mechanotransduction is a dynamic molecular process, which involves a conformational change of α-catenin under tension to expose a cryptic vinculin binding site, there are no suitable experimental methods to directly explore the process. Therefore, in this study, we developed a novel system by combining atomic force microscopy (AFM) and total internal reflection fluorescence (TIRF). In this system, α-catenin molecules (residues 276-634; the mechano-sensitive M1-M3 domain), modified on coverslips, were stretched by AFM and their recruitment of Alexa-labeled full-length vinculin molecules, dissolved in solution, were observed simultaneously, in real time, using TIRF. We applied a physiologically possible range of tensions and extensions to α-catenin and directly observed its vinculin recruitment. Our new system could be used in the fields of mechanobiology and biophysics to explore functions of proteins under tension by coupling biomechanical and biochemical information.

Purification, crystallization and initial crystallographic analysis of the α-catenin homologue HMP-1 from Caenorhabditis elegans.

Adherens junctions transmit mechanical force between cells. In these junctions, ß-catenin binds to cadherins and to the N-terminal domain of α-catenin, which in turn binds to actin filaments via its C-terminal domain. The middle (M) domain of α-catenin plays an important role in responding to mechanical tension. The nematode Caenorhabditis elegans contains α- and ß-catenin homologues called HMP-1 and HMP-2, respectively, but HMP-1 behaves differently from its mammalian homologue. Thus, structural and biochemical studies of HMP-1 have been initiated to understand the mechanism of HMP-1 and the evolution of α-catenin. The N-terminal domain of HMP-1 in complex with the minimal HMP-1-binding region of HMP-2 was purified and crystallized. These crystals diffracted to 1.6 Å resolution and belonged to space group P3(1)21, with unit-cell parameters a = b = 57.1, c = 155.4 Å. The M domain of HMP-1 was also purified and crystallized. The M-domain crystals diffracted to 2.4 Å resolution and belonged to space group P2(1)2(1)2(1), with unit-cell parameters a = 72.8, b = 81.5, c = 151.4 Å. Diffraction data were collected and processed from each crystal, and the structures were solved by molecular replacement.

Molecular basis of actin reorganization promoted by binding of enterohaemorrhagic Escherichia coli EspB to alpha-catenin.

EspB is a multifunctional protein associated with the type III secretion system of enterohaemorrhagic Escherichia coli, and interacts with various biomolecules including alpha-catenin in the host cell. The binding of EspB to alpha-catenin is thought be involved in actin reorganization during bacterial infection, although the precise mechanism of this phenomenon is still unclear. Recent research shows that dimerization of alpha-catenin dissociates it from E-cadherin/beta-catenin/alpha-catenin complexes, and that the dimer suppresses Arp2/3-mediated actin branching or polymerization. These results inspired us to evaluate the effect of EspB on the functions of alpha-catenin. Based on a series of in vitro biochemical approaches, including pull-down, co-sedimentation and pyrene-actin polymerization assays combined with transmission electron microscopy, we conclude that EspB promotes all the functions of dimeric alpha-catenin described above. These results clarified the molecular basis of reorganization of actin filaments during infection with enterohaemorrhagic Escherichia coli.

Regulation of a novel alphaN-catenin splice variant in schizophrenic smokers.

The alphaN-catenin (CTNNA2) gene represents a promising candidate gene for schizophrenia based upon previous genetic linkage, expression, and mouse knockout studies. CTNNA2 is differentially regulated by smoking in schizophrenic patients. In this report, the genomic structure of a primate-specific alphaN-catenin splice variant (alphaN-catenin III) is described. A comparison of alphaN-catenin III mRNA expression across postmortem hippocampi from schizophrenic and non-mentally ill smokers and non-smokers revealed a significant decrease in expression among patient non-smokers compared to all other groups. The recent evolutionary divergence of this gene, as well as the differences in gene expression in postmortem brain of schizophrenic non-smokers, supports the role of alphaN-catenin III as a novel disease susceptibility gene.

Cooperative roles of Par-3 and afadin in the formation of adherens and tight junctions.

Par-3 is a cell-polarity protein that regulates the formation of tight junctions (TJs) in epithelial cells, where claudin is a major cell-cell adhesion molecule (CAM). TJs are formed at the apical side of adherens junctions (AJs), where E-cadherin and nectin are major CAMs. We have revealed that nectin first forms cell-cell adhesions, and then recruits cadherin to nectin-based cell-cell adhesion sites to form AJs and subsequently recruits claudin to the apical side of AJs to form TJs. The cytoplasmic tail of nectin binds afadin and Par-3. Afadin regulates the formation of AJs and TJs cooperatively with nectin. Here, we studied the role of Par-3 in the formation of these junctions by using Par-3-knockdown MDCK cells. Par-3 was necessary for the formation of AJs and TJs but was not necessary for nectin-based cell-cell adhesion. Par-3 promoted the association of afadin with nectin, whereas afadin was not necessary for the association of Par-3 with nectin. However, the association of afadin with nectin alone was not sufficient for the formation of AJs or TJs, and Par-3 and afadin cooperatively regulated it. We describe here these novel roles of Par-3 in the formation of junctional complexes.