Phosphoinositide 3-kinase beta controls replication factor C assembly and function.

Genomic integrity is preserved by the action of protein complexes that control DNA homeostasis. These include the sliding clamps, trimeric protein rings that are arranged around DNA by clamp loaders. Replication factor C (RFC) is the clamp loader for proliferating cell nuclear antigen, which acts on DNA replication. Other processes that require mobile contact of proteins with DNA use alternative RFC complexes that exchange RFC1 for CTF18 or RAD17. Phosphoinositide 3-kinases (PI3K) are lipid kinases that generate 3-poly-phosphorylated-phosphoinositides at the plasma membrane following receptor stimulation. The two ubiquitous isoforms, PI3Kalpha and PI3Kbeta, have been extensively studied due to their involvement in cancer and nuclear PI3Kbeta has been found to regulate DNA replication and repair, processes controlled by molecular clamps. We studied here whether PI3Kbeta directly controls the process of molecular clamps loading. We show that PI3Kbeta associated with RFC1 and RFC1-like subunits. Only when in complex with PI3Kbeta, RFC1 bound to Ran GTPase and localized to the nucleus, suggesting that PI3Kbeta regulates RFC1 nuclear import. PI3Kbeta controlled not only RFC1- and RFC-RAD17 complexes, but also RFC-CTF18, in turn affecting CTF18-mediated chromatid cohesion. PI3Kbeta thus has a general function in genomic stability by controlling the localization and function of RFC complexes.

KNL1-Bubs and RZZ Provide Two Separable Pathways for Checkpoint Activation at Human Kinetochores.

The spindle assembly checkpoint (SAC) ensures the accurate segregation of sister chromatids during mitosis. Activation of the SAC occurs through a series of ordered molecular events that result in recruitment of Mad1:Mad2 complexes to improperly attached kinetochores. The current model involves sequential phospho-dependent recruitment of Bub3:Bub1 to KNL1 followed by binding of Mad1:Mad2 to Bub1. Here, we show in non-transformed diploid human cells that the KNL1-Bub3-Bub1 (KBB) pathway is required during normal mitotic progression when kinetochores are misaligned but is nonessential for SAC activation and Mad2 loading when kinetochores are unattached from microtubules. We provide evidence that the Rod-ZW10-Zwilch (RZZ) complex is necessary to recruit Mad1:Mad2 to, and delay anaphase onset in response to, unattached kinetochores independently of the KBB pathway. These data suggest that the KBB and RZZ complexes provide two distinct kinetochore receptors for Mad1:Mad2 and reveal mechanistic differences between SAC activation by unattached and improperly attached kinetochores.

Phosphoinositide 3-kinase ß regulates chromosome segregation in mitosis.

Class I(A) phosphoinositide 3-kinases (PI3K) are enzymes composed of a p85 regulatory and a p110 catalytic subunit that control formation of 3-poly-phosphoinositides (PIP(3)). The PI3K pathway regulates cell survival, migration, and division, and is mutated in approximately half of human tumors. For this reason, it is important to define the function of the ubiquitous PI3K subunits, p110α and p110ß. Whereas p110α is activated at G1-phase entry and promotes protein synthesis and gene expression, p110ß activity peaks in S phase and regulates DNA synthesis. PI3K activity also increases at the onset of mitosis, but the isoform activated is unknown; we have examined p110α and p110ß function in mitosis. p110α was activated at mitosis entry and regulated early mitotic events, such as PIP(3) generation, prometaphase progression, and spindle orientation. In contrast, p110ß was activated near metaphase and controlled dynein/dynactin and Aurora B activities in kinetochores, chromosome segregation, and optimal function of the spindle checkpoint. These results reveal a p110ß function in preserving genomic stability during mitosis.

SADB phosphorylation of gamma-tubulin regulates centrosome duplication.

Symmetrical cell division requires duplication of DNA and protein content to generate two daughter cells. Centrosomes also duplicate during cell division, but the mechanism controlling this process is incompletely understood. We describe an alternative splice form of SadB encoding a short SADB Ser/Thr kinase whose activity fluctuates during the cell cycle, localizes to centrosomes, and controls centrosome duplication. Reduction of endogenous SADB levels diminished centrosome numbers, whereas enhanced SADB expression induced centrosome amplification. SADB exerted this action through phosphorylation of gamma-tubulin on Ser 131, as expression of a phosphomimetic Ser 131-to-Asp gamma-tubulin mutant alone increased centrosome numbers, whereas non-phosphorylatable Ala 131-gamma-tubulin impaired centrosome duplication. We propose that SADB kinase activity controls centrosome homeostasis by regulating phosphorylation of gamma-tubulin.

A PI3K activity-independent function of p85 regulatory subunit in control of mammalian cytokinesis.

Cytosolic division in mitotic cells involves the function of a number of cytoskeletal proteins, whose coordination in the spatio-temporal control of cytokinesis is poorly defined. We studied the role of p85/p110 phosphoinositide kinase (PI3K) in mammalian cytokinesis. Deletion of the p85alpha regulatory subunit induced cell accumulation in telophase and appearance of binucleated cells, whereas inhibition of PI3K activity did not affect cytokinesis. Moreover, reconstitution of p85alpha-deficient cells with a Deltap85alpha mutant, which does not bind the catalytic subunit, corrected the cytokinesis defects of p85alpha(-/-) cells. We analyzed the mechanism by which p85alpha regulates cytokinesis; p85alpha deletion reduced Cdc42 activation in the cleavage furrow and septin 2 accumulation at this site. As Cdc42 deletion also triggered septin 2 and cytokinesis defects, a mechanism by which p85 controls cytokinesis is by regulating the local activation of Cdc42 in the cleavage furrow and in turn septin 2 localization. We show that p85 acts as a scaffold to bind Cdc42 and septin 2 simultaneously. p85 is thus involved in the spatial control of cytosolic division through regulation of Cdc42 and septin 2, in a PI3K-activity independent manner.