Identification of lysophosphatidic acid in serum as a factor that promotes epithelial apical junctional complex organization.

The apical junctional complex (AJC) consists of adherens junctions (AJs) and tight junctions and regulates epithelial integrity and remodeling. However, it is unclear how AJC organization is regulated based on environmental cues. We found here using cultured EpH4 mouse mammary epithelial cells that fetal bovine serum (FBS) in a culture medium showed an activity to promote AJC organization and that FBS showed an activity to promote tight junction formation even in the absence of AJ proteins, such as E-cadherin, αE-catenin, and afadin. Furthermore, we purified the individual factor responsible for these functions from FBS and identified this molecule as lysophosphatidic acid (LPA). In validation experiments, purified LPA elicited the same activity as FBS. In addition, we found that the AJC organization-promoting activity of LPA was mediated through the LPA receptor 1/5 via diacylglycerol-novel PKC and Rho-ROCK pathway activation in a mutually independent, but complementary, manner. We demonstrated that the Rho-ROCK pathway activation-mediated AJC organization was independent of myosin II-induced actomyosin contraction, although this signaling pathway was previously shown to induce myosin II activation. These findings are in contrast to the literature, as previous results suggested an AJC organization-disrupting activity of LPA. The present results indicate that LPA in serum has an AJC organization-promoting activity in a manner dependent on or independent of AJ proteins.

Impairment of radial glial scaffold-dependent neuronal migration and formation of double cortex by genetic ablation of afadin.

Studies of human brain malformations, such as lissencephaly and double cortex, have revealed the importance of neuronal migration during cortical development. Afadin, a membrane scaffolding protein, regulates the formation of adherens junctions (AJs) and cell migration to form and maintain tissue structures. Here, we report that mice with dorsal telencephalon-specific ablation of afadin gene exhibited defects similar to human double cortex, in which the heterotopic cortex was located underneath the normotopic cortex. The normotopic cortex of the mutant mice was arranged in the pattern similar to the cortex of the control mice, while the heterotopic cortex was disorganized. As seen in human patients, double cortex in the mutant mice was formed by impaired neuronal migration during cortical development. Genetic ablation of afadin in the embryonic cerebral cortex disrupted AJs of radial glial cells, likely resulting in the retraction of the apical endfeet from the ventricular surface and the dispersion of radial glial cells from the ventricular zone to the subventricular and intermediate zones. These results indicate that afadin is required for the maintenance of AJs of radial glial cells and that the disruption of AJs might cause an abnormal radial scaffold for neuronal migration. In contrast, the proliferation or differentiation of radial glial cells was not significantly affected. Taken together, these findings indicate that afadin is required for the maintenance of the radial glial scaffold for neuronal migration and that the genetic ablation of afadin leads to the formation of double cortex.

Cre complementation with variable dimerizers for inducible expression in neurons.

Cre complementation is a process of reconstitution of the activity of DNA recombinase by noncovalent association of multiple segments of Cre recombinase, which are enzymatically inactive by themselves. Cre complementation is potentially useful in restriction of Cre activity in a specific subset of cells, with temporal regulation, by limiting overlap in expression of Cre fragments. We analyzed the efficiency of Cre complementation using three different dimerizing modules in the context of non-neuronal cells and found differential Cre complementation efficiency. We further tested the efficiency of Cre complementation in primary hippocampal neurons derived from transgenic mice harboring a reporter gene flanked by loxP sites and confirmed differential activity of dimerization modules in Cre-dependent recombination of the transgene. These results suggest possible application of dimerizer-based Cre complementation in inducible expression/inactivation of target genes in a specific subset of neurons in the complex environment of nervous tissue in vivo.