Impaired lymphocyte trafficking in mice deficient in the kinase activity of PKN1.

Knock-in mice lacking PKN1 kinase activity were generated by introducing a T778A point mutation in the catalytic domain. PKN1[T778A] mutant mice developed to adulthood without apparent external abnormalities, but exhibited lower T and B lymphocyte counts in the peripheral blood than those of wild-type (WT) mice. T and B cell development proceeded in an apparently normal fashion in bone marrow and thymus of PKN1[T778A] mice, however, the number of T and B cell counts were significantly higher in the lymph nodes and spleen of mutant mice in those of WT mice. After transfusion into WT recipients, EGFP-labelled PKN1[T778A] donor lymphocytes were significantly less abundant in the peripheral circulation and more abundant in the spleen and lymph nodes of recipient mice compared with EGFP-labelled WT donor lymphocytes, likely reflecting lymphocyte sequestration in the spleen and lymph nodes in a cell-autonomous fashion. PKN1[T778A] lymphocytes showed significantly lower chemotaxis towards chemokines and sphingosine 1-phosphate (S1P) than WT cells in vitro. The biggest migration defect was observed in response to S1P, which is essential for lymphocyte egress from secondary lymphoid organs. These results reveal a novel role of PKN1 in lymphocyte migration and localization.

Involvement of a centrosomal protein kendrin in the maintenance of centrosome cohesion by modulating Nek2A kinase activity.

Centrosome cycle is strictly coordinated with chromosome duplication cycle to ensure the faithful segregation of chromosomes. Centrosome duplication occurs from the beginning of S phase, and the duplicated centrosomes are held together by centrosome cohesion to function as a single microtubule organizing center during interphase. At late G2 phase centrosome cohesion is disassembled by Nek2A kinase-mediated phosphorylation and, as a consequence, centrosomes are split and constitute spindle poles in mitosis. It has been reported that depletion of a centrosomal protein kendrin (also named pericentrin) induces premature centrosome splitting in interphase, however, it remains unknown how kendrin contributes to the maintenance of centrosome cohesion. Here we show that kendrin associates with Nek2A kinase, which exhibits considerably low activity. Nek2A kinase activity is inhibited in vitro by addition of the Nek2A-binding region of kendrin in a dose-dependent manner. Furthermore, ectopic expression of the same region decreases the number of the cells with split centrosomes at late G2 phase. Taken together, these results suggest that kendrin anchors Nek2A and suppresses its kinase activity at the centrosomes, and thus, is involved in the mechanism to prevent premature centrosome splitting during interphase.