Phosphatidylinositol 4-kinase III Beta Promotes Oncogenic Signaling In Breast Cancer by Controlling Endocytosis

MacDonald, Spencer

January 2017

Endosomes are now recognized as important sites for regulating signal transduction. Here we show that the lipid kinase phosphatidylinositol 4-kinase III beta (PI4KIIIβ) regulates both endocytic kinetics and receptor signaling in breast cancer cells. PI4KIIIβ generates phosphatidylinositol 4-phosphate from phosphatidylinositol and is highly expressed in a subset of breast cancers. However, the molecular mechanism by which PI4KIIIβ promotes breast cancer is unclear. We demonstrate that ectopic PI4KIIIβ expression increases the rates of both endocytic internalization and recycling. Furthermore, PI4KIIIβ deletion reduces endocytic kinetics. Regulation of endocytic function by PI4KIIIβ is independent of its kinase activity but requires interaction with the Rab11a GTPase. Additionally, we find that PI4KIIIβ activates IGF-IRβ signaling, dependent on endosome function. Finally, we observe that PI4KIIIβ deletion decreases the growth rate of mammary tumours in mice. Our work suggests a novel regulatory role for PI4KIIIβ in endosome function and plasma membrane receptor signaling, providing a mechanism by which increased PI4KIIIβ expression could promote breast cancer oncogenesis.

Breast cancer

Rab11a

Phosphatidylinositol 4-phosphate

Recycling

Endocytosis

Signaling

Mécanismes du transport lipidique par les protéines ORP/Osh / Mechanisms of lipid transport by the ORP/Osh proteins

Moser von Filseck, Joachim

16 December 2014

Une distribution lipidique hétérogène est essentielle à l’identité et fonction des organelles, mais l’échange par trafic vésiculaire tend à annuler cette distribution. Il existe donc des mécanismes qui assurent l’homéostasie des lipides. Les protéines Osh (S. cerevisiae) et les OSBP-Related Proteins (ORP, H. sapiens), sont des transporteurs de lipides. Osh4 est capable d’échanger de l’ergostérol contre le phosphatidylinositol-4-phosphate (PI4P), présent sur l’appareil de Golgi. Utilisant des outils fluorescents mesurant avec une précision inégalée le transport de stérol et de PI4P, nous démontrons qu’Osh4 transporte du stérol contre son gradient de concentration en utilisant l’énergie d’un gradient de PI4P. Un couplage au métabolisme du PI4P permettrait à Osh4 d’alimenter le Golgi avec du stérol, ainsi créant le gradient de stérol entre ces organelles. La protéine OSBP participe, via sa capacité à connecter la membrane du RE à celle du trans-Golgi, à la création de jonctions entre ces organelles. Nous avons montré qu’OSBP, par échange stérol/PI4P, utilise le PI4P pour transférer du cholestérol au Golgi, mais également pour autoréguler sa capacité à former les jonctions. Osh6 lie la phosphatidylsérine, nous permettant d’étudier un nouveau mécanisme d’échange. Nous avons résolu la structure cristallographique d’un complexe Osh6/PI4P et avons pu observer l’échange de ces deux ligands par Osh6 entre deux membranes. Cette étude nous permet de suggérer que l’échange de PI4P avec divers lipides, via les protéines Osh/ORP, serait un mécanisme général permettant aux cellules de maintenir le gradient lipidique entre le RE et les membranes tardives de la voie sécrétoire. / An uneven lipid distribution is essential for the function of eukaryotic organelles. However, exchange of material by vesicular trafficking has a tendency to perturb this distribution; mechanisms must though exist to ensure lipid homeostasis. Osh proteins (S. cerevisiae) and OSBP-Related Proteins (ORPs, H. sapiens), are lipid transfer proteins (LTPs). Osh4 is capable of exchanging ergosterol for phosphatidylinositol 4-phosphate (PI4P), found on the Golgi. Using novel fluorescent tools to measure with unprecedented precision the transport of sterol and PI4P, we find that Osh4 can transport sterol against its concentration gradient using the energy of a PI4P gradient. Coupled to phosphoinositide metabolism, this allows Osh4 to transport sterol to the trans-Golgi and create the sterol gradients observed between these organelles. OSBP participates in the creation of membrane contact sites (MCSs) via its capacity to connect ER membranes to those of the trans-Golgi. We have shown that it uses PI4P for transporting cholesterol from the ER to the trans-Golgi by sterol/PI4P counterexchange, hence also autoregulating its tethering activity. Finally, the identification of phosphatidylserine as a ligand for Osh6 allowed us to analyze the possible extrapolation of the PI4P counterexchange mechanism. We have solved the crystal structure of Osh6 in complex with PI4P and have been able to follow counterexchange of PI(4)P and PS in vitro. Concluding, our studies allow us to suggest a general mechanism for ORP/Osh-mediated counterexchange of PI4P for other lipids to maintain lipid gradients between the ER and late membranes of the secretory pathway.

Protéines de transfert lipidique

Protéines Osh

OSBP

Stérol

Phosphatidylinositol-4-phosphate

Phosphatidylsérine

Lipid transfer protein

Osh proteins

OSBP

OSBP-related proteins

Sterol

Phosphatidylinositol 4-phosphate

Phosphatidylserine

The Role of lysine Acetylation on the Regulation of Phospholipid Homeostasis in Yeast

Dacquay, Louis

January 2017

Actively proliferating cells constantly monitor and re-adjust their metabolic pathways to ensure the replenishment of phospholipids necessary for membrane biogenesis and intracellular trafficking. In Saccharomyces cerevisiae, multiple studies have suggested that lysine acetylation has a role in coordinating phospholipid metabolism, yet its contribution towards phospholipid homeostasis remains uncharacterized. In this study we undertook a genetic screen to explore the connection between lysine acetylation and phospholipid homeostasis. We found that mutants of the lysine acetyltransferase complex, NuA4, shared a negative genetic interaction with a mutant of Sec14, a lipid-binding protein that regulates Golgi phospholipid composition. Through transcriptome, genetic, cell biology, and chemical analysis, we discovered that the growth defects between NuA4 and Sec14 mutants is likely derived from impaired fatty acid biosynthesis suggesting a role for NuA4 as a positive regulator of fatty acid biosynthesis. Secondly, we discovered that acetylation on the conserved lysine residue K109 inhibits the localization and function of the Oxysterol-Binding Protein Osh4- a lipid-binding protein that antagonizes the function of Sec14 at the Golgi. Furthermore, regulation of Oxysterol-Binding Proteins by acetylation may be a conserved mechanism as we found that Osh1, a homologue of Osh4, was also acetylated on the equivalent lysine residue. Altogether, we have demonstrated that lysine acetylation can target multiple different phospholipid metabolic pathways which implies that it has a very important role for the regulation of phospholipid homeostasis.

Lysine acetylation

NuA4

Phospholipids

Phospholipid-Binding Proteins

Lipid droplet formation

Inositol/choline responsive elements

Phosphatidylinositol-4-phosphate

Oxysterol-Binding Proteins

The localisation and regulation of phosphatidylinositol-4-phosphate 5-Kinase gamma splice variants and the discovery of a new mammalian splice variant, PIP5KIγ_v6

Xia, Yang

January 2011

Type I PIP kinases (phosphatidylinositol 4-phosphate 5-kinases, PIP5Ks) catalyse the majority of cellular synthesis of PI(4,5)P2. To date, three mammalian isoforms (r1, r2, r3) have been found. PIP5KIr is subject to complex C-terminal splice variation, enhancing its transcriptional diversity through evolution and producing at least 5 known spliceoforms in the mammals. This study addresses several important questions. (1) Several remarkable differences have been discovered between the neuronal splice variant PIP5KIr_i3 and its close variant, Ir_i2, whose peptide lacks a 26-AA insert near its C-terminus. This study attempts to map these behavioural differences onto motifs within the peptide insert. Furthermore, a site of point mutation is identified near the activation loop, which amplifies the above differences. (2) This study documents properties of the more recently discovered PIP5KIr_i3, about which relatively little is known, for example, the regulation of its subcellular localisation, kinase activity and post-translational modifications. By site-directed mutagenesis and examining more closely several crucial motifs, insight is gained into the putative relationship between the enzyme’s phosphorylation state, cellular localisation, lipid kinase activity and autophosphorylation. (3) The discovery of a new PIP5KIr splice variant, Ir_v6, is described. First discovered in rodents, PIP5KIr_i6 encompasses the 26-AA insert of Ir_i3, but lacks the common C-terminus of Ir_i2 and Ir_i3 which contains peptide motifs that have several roles in vivo. A polyclonal antibody against the C-terminus of Ir_i6 was also developed. Preliminary characterisation of Ir_i6 demonstrates a similar subcellular localisation, but a wider expression profile than its close relative, Ir_i3, suggesting potentially differential functions across tissues and at various developmental stages. (4) The existence of Ir_v3 and Ir_v6 is also confirmed in humans. In light of recent findings of other novel human spliceoforms, this is shown to be a case of intra-exonic splicing producing “alternative 5’ splice site” exons in the human. Overall, this thesis should help to better understand the regulation and physiological roles of PIP5KIr and, specifically, its different splice variants.

615.1

Distinct roles of PI4P 5-kinase isoforms in polar tip growth of pollen tubes / Unterschiedliche Funktionen von PI4P 5-Kinasen in der Kontrolle des polaren Spitzenwachstums von Pollenschläuchen

Ischebeck, Till

29 October 2008

No description available.

570 Biowissenschaften, Biologie

Mathematics and Computer Science

Pollenschlauch

Phosphoinositide

Phosphatidylinositol-4-phosphat 5-Kinase

polares Wachstum

Pektinsekretion

pollen tube

phosphoinositides

polar growth

pectin secretion

42.15

42.42

Novel regulators of trafficking in the yeast Golgi-endosomal system

Gravert, Maike

09 October 2006

Over the past few years a large amount of work has provided growing insight into the molecular mechanisms that direct post-Golgi trafficking events in the budding yeast Saccharomyces cerevisae. However, a key event in this process, the formation of secretory vesicles at the Golgi and sorting of cargo into these transport carriers, remains poorly understood. It has been demonstrated that phosphatidylinositol 4-phosphate (PI(4)P) generated by the PI(4)-kinase Pik1p plays an essential role in maintenance of Golgi secretory function and morphology. Up to now relatively few targets of Pik1/PI(4)P signaling at the Golgi have been identified and it thus remains elusive how Pik1p mediates its essential function in Golgi secretion. During my thesis work, I used synthetic genetic array analysis (SGA) of a temperature-sensitive mutant allele of PIK1 (pik1-101) in order to gain better understanding of Pik1p function at the TGN and to isolate new regulators of post-Golgi transport in yeast. I identified a total of 85 genes, whose deletion resulted in a synthetic growth defect when combined with the pik1-101 mutation. 21 isolated deletion mutants were used for further analysis, several of which were found to share common trafficking phenotypes with the pik mutant. A striking result of the screen was the finding that Pik1p interacts genetically with several components of a potential post-translational modification pathway referred to as “urmylation pathway”. In addition, a novel, previously uncharacterized subunit of the Transport protein particle (TRAPP) complex was isolated as genetic interactor of Pik1p, suggesting a function for the TRAPP complex in a Pik1p dependent trafficking pathway. Using tandem affinity purification, I could also demonstrate that TRAPP shows previously unknown interactions with other regulators of post-Golgi transport. The second part of this thesis describes the development of a new visual screening approach. Recent work indicates that secretory cargo in yeast can be transported to the cell surface via at least two different exocytic branches. Upon block of one pathway cargo can be partially redistributed into the other pathway. This partial redundancy of exocytic pathways provides one explanation why genetic screens in the past were largely unsuccessful in identifying the molecular machinery that directs vesicle budding and cargo sorting at the TGN. I collaborated in the development of a novel screening method that was devised to circumvent this problem. The method took advantage of the systematic yeast knockout array and was based on the assumption that a defect in cargo sorting and cell surface transport could be detected as intracellular accumulation of a GFP-tagged model cargo. The suitability of our approach for identifying regulators of secretory transport has been demonstrated in a small-scale pilot study that will be presented in this thesis. The screening method proofed to be applicable on a genome-wide scale and can now be used for the screening of additional markers. This novel approach provides an entry point to the comprehensive study of TGN sorting.

yeast

post-Golgi sorting

phosphatidylinositol 4-phosphate

Pik1p

genetic screen

TRAPP complex

Hefe

post-Golgi Transport

Phosphatidylinositol 4-Phosphat

Pik1p

genetischer Screen

TRAPP-Komplex

ddc:570

rvk:WF 9500

Hefeartige Pilze

Dictyosom

Inositphosphatide

Novel regulators of trafficking in the yeast Golgi-endosomal system

Gravert, Maike

29 September 2006

Over the past few years a large amount of work has provided growing insight into the molecular mechanisms that direct post-Golgi trafficking events in the budding yeast Saccharomyces cerevisae. However, a key event in this process, the formation of secretory vesicles at the Golgi and sorting of cargo into these transport carriers, remains poorly understood. It has been demonstrated that phosphatidylinositol 4-phosphate (PI(4)P) generated by the PI(4)-kinase Pik1p plays an essential role in maintenance of Golgi secretory function and morphology. Up to now relatively few targets of Pik1/PI(4)P signaling at the Golgi have been identified and it thus remains elusive how Pik1p mediates its essential function in Golgi secretion. During my thesis work, I used synthetic genetic array analysis (SGA) of a temperature-sensitive mutant allele of PIK1 (pik1-101) in order to gain better understanding of Pik1p function at the TGN and to isolate new regulators of post-Golgi transport in yeast. I identified a total of 85 genes, whose deletion resulted in a synthetic growth defect when combined with the pik1-101 mutation. 21 isolated deletion mutants were used for further analysis, several of which were found to share common trafficking phenotypes with the pik mutant. A striking result of the screen was the finding that Pik1p interacts genetically with several components of a potential post-translational modification pathway referred to as “urmylation pathway”. In addition, a novel, previously uncharacterized subunit of the Transport protein particle (TRAPP) complex was isolated as genetic interactor of Pik1p, suggesting a function for the TRAPP complex in a Pik1p dependent trafficking pathway. Using tandem affinity purification, I could also demonstrate that TRAPP shows previously unknown interactions with other regulators of post-Golgi transport. The second part of this thesis describes the development of a new visual screening approach. Recent work indicates that secretory cargo in yeast can be transported to the cell surface via at least two different exocytic branches. Upon block of one pathway cargo can be partially redistributed into the other pathway. This partial redundancy of exocytic pathways provides one explanation why genetic screens in the past were largely unsuccessful in identifying the molecular machinery that directs vesicle budding and cargo sorting at the TGN. I collaborated in the development of a novel screening method that was devised to circumvent this problem. The method took advantage of the systematic yeast knockout array and was based on the assumption that a defect in cargo sorting and cell surface transport could be detected as intracellular accumulation of a GFP-tagged model cargo. The suitability of our approach for identifying regulators of secretory transport has been demonstrated in a small-scale pilot study that will be presented in this thesis. The screening method proofed to be applicable on a genome-wide scale and can now be used for the screening of additional markers. This novel approach provides an entry point to the comprehensive study of TGN sorting.

info:eu-repo/classification/ddc/570

ddc:570