Katherine A. Hinchliffe

PIPkins1, their substrates and their products: new functions for old enzymes.

The phosphatidylinositolphosphate kinases (PIPkins) are a unique family of enzymes that catalyse the production of phosphorylated inositol lipids. Recent advances have revealed that, due to their ability to utilise a number of different lipid substrates (at least in vitro), this family is potentially able to generate several distinct, physiologically important inositol lipids. Despite their importance, however, our understanding of the regulation of the PIPkins and of their physiological role in cellular signalling and regulation is still poor. Here we describe in turn the diverse physiological functions of the known substrates and major products of the PIPkins. We then examine what is known about the members of the PIPkin family themselves, and their characteristics and regulation.

Thrombin stimulation of platelets causes an increase in phosphatidylinositol 5-phosphate revealed by mass assay

Phosphatidylinositol 5‐phosphate (PtdIns5P), a novel inositol lipid, has been shown to be the major substrate for the type II PtdInsP kinases (PIPkins) [Rameh et al. (1997) Nature 390, 192–196]. A PtdInsP fraction was prepared from cell extracts by neomycin chromatography, using a protocol devised to eliminate the interaction of acidic solvents with plasticware, since this was found to inhibit the enzyme. The PtdIns5P in this fraction was measured by incubating with [γ‐32P]ATP and recombinant PIPkin IIα, and quantifying the radiolabelled PtdInsP2 formed. This assay was used on platelets to show that during 10 min stimulation with thrombin, the mass level of PtdIns5P increases, implying the existence of an agonist‐stimulated synthetic mechanism.

Aggregation-dependent, integrin-mediated increases in cytoskeletally associated PtdInsP2 (4,5) levels in human platelets are controlled by translocation of PtdIns 4-P 5-kinase C to the cytoskeleton.

Thrombin‐stimulated aggregation of human platelets promotes an increase in the phosphatidylinositol 4‐phosphate (PtdIns 4‐P) 5‐kinase (PIPkin) activity in the cytoskeleton. This phenomenon is associated with translocation of PIPkin isoform C to the cytoskeleton and with an increase in the amount of phosphatidylinositol bisphosphate (PtdInsP2) bound to the cytoskeletal pellet. All three of these effects are prevented if the platelets are not stirred or if RGD‐containing peptides are present, demonstrating that they require integrin activation. All three are also abolished by pretreatment with okadaic acid, which also prevents the aggregation‐dependent translocation of pp60(c‐src) to the cytoskeleton. The results point to the existence of a cytoskeletally associated PtdInsP2 pool under the control of integrin‐mediated signals that act via PIPkin C and suggest that a common, okadaic acid‐sensitive mechanism may underlie the aggregation‐dependent translocation of certain signalling molecules to the platelet cytoskeleton.

Activation of extracellular signal-regulated protein kinase 5 downregulates FasL upon osmotic stress.

Extracellular signal-regulated protein kinase (ERK) 5 is a mitogen-activated protein kinase (MAPK) that is activated by dual phosphorylation via a unique MAPK/ERK kinase 5, MEK5. The physiological importance of this signaling cascade is underscored by the early embryonic death caused by the targeted deletion of the erk5 or the mek5 genes in mice. Here, we have found that ERK5 is required for mediating the survival of fibroblasts under basal conditions and in response to sorbitol treatment. Increased Fas ligand (FasL) expression acts as a positive feedback loop to enhance apoptosis of ERK5- or MEK5-deficient cells under conditions of osmotic stress. Compared to wild-type cells, erk5−/− and mek5−/− fibroblasts treated with sorbitol display a reduced protein kinase B (PKB) activity associated with increased Forkhead box O3a (Foxo3a) activity. Based on these results, we conclude that the ERK5 signaling pathway promotes cell survival by downregulating FasL expression via a mechanism that implicates PKB-dependent inhibition of Foxo3a downstream of phosphoinositide 3 kinase.

Effects of lipid kinase expression and cellular stimuli on phosphatidylinositol 5-phosphate levels in mammalian cell lines

Phosphatidylinositol 5‐phosphate (PtdIns5P) is a relatively recently discovered inositol lipid whose metabolism and functions are not yet clearly understood. We have transfected cells with a number of enzymes that are potentially implicated in the synthesis or metabolism of PtdIns5P, or subjected cells to a variety of stimuli, and then measured cellular PtdIns5P levels by a specific mass assay. Stable or transient overexpression of Type IIα PtdInsP kinase, or transient overexpression of Type Iα or IIβ PtdInsP kinases caused no significant change in cellular PtdIns5P levels. Similarly, subjecting cells to oxidative stress or EGF stimulation had no significant effect on PtdIns5P, but stimulation of HeLa cells with a phosphoinositide‐specific PLC‐coupled agonist, histamine, caused a 40% decrease within 1 min. Our data question the degree to which inositide kinases regulate PtdIns5P levels in cells, and we discuss the possibility that a significant part of both the synthesis and removal of this lipid may be regulated by phosphatases and possibly phospholipases.

Regulation of extranuclear PtdIns5P production by phosphatidylinositol phosphate 4-kinase 2α

Cellular levels of the phosphoinositide PtdIns5P are regulated by agonist stimulation, but the mechanisms controlling turnover of this lipid, and the subcellular location of the regulated PtdIns5P pool(s), remain poorly understood. Here we show that enhanced tyrosine phosphorylation robustly increases cellular PtdIns5P levels. Moreover, unlike PtdIns5P production enhanced by cell stress, we show that this pool of PtdIns5P is specifically regulated by the inositol lipid kinase PIP4K2a.

Type IIalpha phosphatidylinositol phosphate kinase associates with the plasma membrane via interaction with type I isoforms.

The phosphatidylinositol phosphate kinases (PIPkins) are a family of enzymes involved in regulating levels of several functionally important inositol phospholipids within cells. The PIPkin family is subdivided into three on the basis of substrate specificity, each subtype presumably regulating levels of different subsets of the inositol lipids. The physiological function of the type II isoforms, which exhibit a preference for phosphatidylinositol 5-phosphate, a lipid about which very little is known, is particularly poorly understood. In the present study, we demonstrate interaction between, and co-immunoprecipitation of, type IIalpha PIPkin with the related, but biochemically and immunologically distinct, type I PIPkin isoforms. Type IIalpha PIPkin interacts with all three known type I PIPkins (alpha, beta and gamma), and in each case co-expression of the type I isoform with type IIalpha results in recruitment of the latter from the cytosol to the plasma membrane of the cell. This change in subcellular localization could result in improved access of the type IIalpha PIPkin to its lipid substrates.

The Lowe Syndrome Protein OCRL1 Is Required for Endocytosis in the Zebrafish Pronephric Tubule

Lowe syndrome and Dent-2 disease are caused by mutation of the inositol 5-phosphatase OCRL1. Despite our increased understanding of the cellular functions of OCRL1, the underlying basis for the renal tubulopathy seen in both human disorders, of which a hallmark is low molecular weight proteinuria, is currently unknown. Here, we show that deficiency in OCRL1 causes a defect in endocytosis in the zebrafish pronephric tubule, a model for the mammalian renal tubule. This coincides with a reduction in levels of the scavenger receptor megalin and its accumulation in endocytic compartments, consistent with reduced recycling within the endocytic pathway. We also observe reduced numbers of early endocytic compartments and enlarged vacuolar endosomes in the sub-apical region of pronephric cells. Cell polarity within the pronephric tubule is unaffected in mutant embryos. The OCRL1-deficient embryos exhibit a mild ciliogenesis defect, but this cannot account for the observed impairment of endocytosis. Catalytic activity of OCRL1 is required for renal tubular endocytosis and the endocytic defect can be rescued by suppression of PIP5K. These results indicate for the first time that OCRL1 is required for endocytic trafficking in vivo, and strongly support the hypothesis that endocytic defects are responsible for the renal tubulopathy in Lowe syndrome and Dent-2 disease. Moreover, our results reveal PIP5K as a potential therapeutic target for Lowe syndrome and Dent-2 disease.

Regulation of type IIalpha phosphatidylinositol phosphate kinase localisation by the protein kinase CK2.

Inositol lipid synthesis is regulated by several distinct families of enzymes [1]. Members of one of these families, the type II phosphatidylinositol phosphate kinases (PIP kinases), are 4-kinases and are thought to catalyse a minor route of synthesis of the multifunctional phosphatidylinositol 4,5-bisphosphate (PI(4,5)P(2)) from the inositide PI(5)P [2]. Here, we demonstrate the partial purification of a protein kinase that phosphorylates the type IIalpha PIP kinase at a single site unique to that isoform - Ser304. This kinase was identified as protein kinase CK2 (formerly casein kinase 2). Mutation of Ser304 to aspartate to mimic its phosphorylation had no effect on PIP kinase activity, but promoted both redistribution of the green fluorescent protein (GFP)-tagged enzyme in HeLa cells from the cytosol to the plasma membrane, and membrane ruffling. This effect was mimicked by mutation of Ser304 to alanine, although not to threonine, suggesting a mechanism involving the unmasking of a latent membrane localisation sequence in response to phosphorylation.

Intracellular signalling: Is PIP2 a messenger too?

The phospholipid phosphatidylinositol (4,5) bisphosphate (PIP(2)) has recently been shown to act downstream of the small G proteins Rac and Arf. Different effectors may be employed in each case, suggesting that PIP(2) has multiple signalling roles.