Angus J.M. Cameron

PKC and the control of localized signal dynamics

Networks of signal transducers determine the conversion of environmental cues into cellular actions. Among the main players in these networks are protein kinases, which can acutely and reversibly modify protein functions to influence cellular events. One group of kinases, the protein kinase C (PKC) family, have been increasingly implicated in the organization of signal propagation, particularly in the spatial distribution of signals. Examples of where and how various PKC isoforms direct this tier of signal organization are becoming more evident.

PKC maturation is promoted by nucleotide pocket occupation independently of intrinsic kinase activity

The protein kinase C (PKC) Ser/Thr kinases account for ∼2% of the human kinome and regulate diverse cellular behaviors. PKC catalytic activity requires priming phosphorylations at three conserved sites within the kinase domain. Here we demonstrate that priming of PKC is dependent on the conformation of the nucleotide binding pocket but not on its intrinsic kinase activity. Inactive ATP binding site mutants are unprimed, but they become phosphorylated upon occupancy of the ATP binding pocket with inhibitors of PKC. We have exploited this property to screen for PKC inhibitors in vivo. Further, we generated a distinct class of kinase-inactive mutants that maintain the integrity of the ATP binding pocket; such mutants are constitutively primed and functionally distinct from ATP binding site mutants. These data demonstrate that autophosphorylation is not required for PKC priming and show how ATP pocket occupation can enable a kinase to mature as well as function.

The regulated assembly of a PKC|[epsiv]| complex controls the completion of cytokinesis

The cell cycle is exquisitely controlled by multiple sequential regulatory inputs to ensure fidelity. Here we demonstrate that the final step in division, the physical separation of daughter cells, is controlled by a member of the PKC gene superfamily. Specifically, we have identified three phosphorylation sites within PKCɛ that control its association with 14-3-3. These phosphorylations are executed by p38 MAP kinase (Ser 350), GSK3 (Ser 346) and PKC itself (Ser 368). Integration of these signals is essential during mitosis because mutations that prevent phosphorylation of PKCɛ and/or PKCɛ binding to 14-3-3 also cause defects in the completion of cytokinesis. Using chemical genetic and dominant-negative approaches it is shown that selective inhibition of PKCɛ halts cells at the final stages of separation. This arrest is associated with persistent RhoA activation at the midbody and a delay in actomyosin ring dissociation. This study therefore identifies a new regulatory mechanism that controls exit from cytokinesis, which has implications for carcinogenesis.

A molecular switch changes the signalling pathway used by the FcγRI antibody receptor to mobilise calcium

BACKGROUND Leukocytes express Fc gamma receptors, which are specific for the constant region of immunoglobulin G. Aggregation of these receptors activates a repertoire of responses that can lead to targeted cell killing by antibody-directed cellular cytotoxicity. The nature of the myeloid response to Fc gamma receptor aggregation is highly variable and depends on the maturation state of the cell, but little is known about the signalling mechanisms underlying this variability. RESULTS We show here that differentiation of a monocytic cell line, U937, to a more macrophage phenotype resulted in an absolute and fundamental switch in the nature of the phospholipid signalling pathway recruited following Fc gamma receptor aggregation. In cytokine-primed monocytes, aggregation of the high-affinity receptor Fc gamma RI resulted in the activation of phospholipase D and sphingosine kinase, which in turn led to the transient release of stored calcium; these effects were mediated by the gamma chain, an Fc gamma RI accessory protein. In contrast, in cells differentiated to a more macrophage type, aggregation of Fc gamma RI resulted in the Fc gamma RIIa-mediated activation of phospholipase C, and the resulting calcium response was prolonged as calcium entry was stimulated. CONCLUSIONS The switch in Fc gamma RI signalling pathways upon monocyte differentiation is mediated by a switch in the accessory molecule recruited by Fc gamma RI, which lacks its own intrinsic signal transduction motif. As many immune receptors have separate polypeptide chains for ligand binding and signal transduction (allowing a similar switch in signalling pathways), the mechanism described here is likely to be widely used.

PKC alpha protein but not kinase activity is critical for glioma cell proliferation and survival

Protein kinase C alpha (PKCα) has been implicated in tumor development with high levels of PKCα expression being associated with various malignancies including glioblastomas and tumors of the breast and prostate. To account for its upregulation in these cancers, studies have suggested that PKCα plays a role in promoting cell survival. Here we show by siRNA depletion in U87MG glioma cells that a critical threshold level of PKCα protein expression is essential for their growth in the presence of serum and for their survival following serum deprivation. Derivation of PKCα wt and KO mouse embryo fibroblast cell lines confirms a role for PKCα in protecting cells from apoptosis induced by serum deprivation. Notably, PKCα was found to mediate chemo‐protection in these fibroblastic cell lines. In U87MG cells PKCα does not confer chemoprotection though this likely reflects growth arrest associated with its depletion. To determine the requirements for catalytic function, comparison was made between distinct classes of PKC inhibitors. In contrast to loss of PKCα protein, inhibition of PKC kinase activity in glioma cell lines does not significantly inhibit growth or survival. Conversely, inhibition with calphostin C, which targets the regulatory domain of PKC, potently inhibits proliferation and induces apoptosis. Evidence is presented that it is the fully phosphorylated, folded form of PKCα that confers this activity‐independent behaviour. These results indicate an essential pro‐proliferative and pro‐survival role for PKCα in glioma but question the use of ATP competitive inhibitors as therapeutics, either alone, or in combination with chemotoxic agents.

mTORC2 targets AGC kinases through Sin1-dependent recruitment

The protein kinase TOR (target of rapamycin) is a key regulator of cell growth and metabolism with significant clinical relevance. In mammals, TOR signals through two distinct multi-protein complexes, mTORC1 and mTORC2 (mammalian TOR complex 1 and 2 respectively), the subunits of which appear to define the operational pathways. Rapamycin selectively targets mTORC1 function, and the emergence of specific ATP-competitive kinase inhibitors has enabled assessment of dual mTORC1 and mTORC2 blockade. Little is known, however, of the molecular action of mTORC2 components or the relative importance of targeting this pathway. In the present study, we have identified the mTORC2 subunit Sin1 as a direct binding partner of the PKC (protein kinase C) ε kinase domain and map the interaction to the central highly conserved region of Sin1. Exploiting the conformational dependence for PKC phosphorylation, we demonstrate that mTORC2 is essential for acute priming of PKC. Inducible expression of Sin1 mutants, lacking the PKC-interaction domain, displaces endogenous Sin1 from mTORC2 and disrupts PKC phosphorylation. PKB (protein kinase B)/Akt phosphorylation is also suppressed by these Sin1 mutants, but not the mTORC1 substrate p70(S6K) (S6 kinase), providing evidence that Sin1 serves as a selectivity adaptor for the recruitment of mTORC2 targets. This inducible selective mTORC2 intervention is used to demonstrate a key role for mTORC2 in cell proliferation in three-dimensional culture.

Inhibition Of Proliferation And Signalling Mechanisms In Human Lymphocytes By Fluvastatin

1. Inhibitors of 3‐hydroxy‐3‐methylglutaryl coenzyme A (HMG‐CoA) reductase (statins) reduce serum cholesterol and have proven benefits in the treatment of cardiovascular disease. However, recent work suggests that statins may exert immunosuppressive effects in isolated lymphocytes and in solid organ transplant recipients. Fluvastatin does not interfere with the metabolism of commonly used immunosuppressive agents and, therefore, may have benefits in transplant recipients.

Protein kinases, from B to C.

The PKB (protein kinase B) and PKC (protein kinase C) families display highly related catalytic domains that require a largely conserved series of phosphorylations for the expression of their optimum activities. However, in cells, the dynamics of these modifications are quite distinct. Based on experimental evidence, it is argued that the underlying mechanisms determining these divergent behaviours relate to the very different manner in which their variant regulatory domains interact with their respective catalytic domains. It is concluded that the distinct behaviours of PKB and PKC proteins are defined by the typical ground states of these proteins.

Genomic Subtypes of Non-invasive Bladder Cancer with Distinct Metabolic Profile and Female Gender Bias in KDM6A Mutation Frequency.

Bladder cancer incurs a higher lifetime treatment cost than other cancers due to frequent recurrence of non-invasive disease. Improved prognostic biomarkers and localized therapy are needed for this large patient group. We defined two major genomic subtypes of primary stage Ta tumors. One of these was characterized by loss of 9q including TSC1, increased KI67 labeling index, upregulated glycolysis, DNA repair, mTORC1 signaling, features of the unfolded protein response, and altered cholesterol homeostasis. Comparison with muscle-invasive bladder cancer mutation profiles revealed lower overall mutation rates and more frequent mutations in RHOB and chromatin modifier genes. More mutations in the histone lysine demethylase KDM6A were present in non-invasive tumors from females than males.

A Cancer-Associated Mutation in Atypical Protein Kinase Cι Occurs in a Substrate-Specific Recruitment Motif

A cancer-associated mutation in protein kinase Cι selectively disrupts epithelial polarity by inhibiting the binding of specific substrates. Impairing Cell Polarity Epithelial cells simultaneously interact with both the external and internal environment. To perform their function as barriers, epithelial cells are polarized, meaning that they are asymmetric in shape and in the distribution of intracellular components. Epithelial cells in tumors often show loss of polarity. Linch et al. identified a 4–amino acid motif in the ι isoform of atypical protein kinase C (PKC), a kinase that promotes cell polarity through phosphorylation of various substrates. Mutations in this motif impaired the binding of PKCι to two substrates that are involved in cell polarization, and an epithelial cell line expressing a form of PKCι with mutations in this motif formed improperly polarized epithelial structures. Somatic mutations in this motif were detected in human cancers of various types. Thus, this study provides a mechanism by which these mutations contribute to the disease. Atypical protein kinase Cι (PKCι) has roles in cell growth, cellular polarity, and migration, and its abundance is frequently increased in cancer. We identified a protein interaction surface containing a dibasic motif (RIPR) that bound a distinct subset of PKCι substrates including lethal giant larvae 2 (LLGL2) and myosin X, but not other substrates such as Par3. Further characterization demonstrated that Arg471 in this motif was important for binding to LLGL2, whereas Arg474 was critical for interaction with myosin X, indicating that multiple complexes could be formed through this motif. A somatic mutation of the dibasic motif (R471C) was the most frequent mutation of PKCι in human cancer, and the intact dibasic motif was required for normal polarized epithelial morphogenesis in three-dimensional cysts. Thus, the R471C substitution is a change-of-function mutation acting at this substrate-specific recruitment site to selectively disrupt the polarizing activity of PKCι.