The involvement of ARF6 in rapid membrane recycling during Drosophila spermatocyte cytokinesis

Foster, Naomi

14 February 2007

Cytokinesis involves constriction of the cell at the equator. Without decreasing in volume, a spherical cell requires a net increase in the surface area during this constriction. The constriction is driven by formation of an actomyosin contractile ring, and the surface increase by addition of membrane during the formation of the cleavage furrow. Both events depend on the central spindle microtubules at the midzone of the spindle and, in particular, on the centralspindlin protein complex. The communication between the central spindle microtubules and the actomyosin ring involves binding of a GAP and a GEF for RhoA to the centralspindlin kinesin Pavarotti/MKLP1. However, it is still unclear which molecular machinery connects the mitotic spindle to membrane trafficking during cleavage furrow ingression. ARF6 is a member of the ARF family of small GTPases, and previous studies suggest that it is an important regulator of membrane trafficking through the endocytic pathway, and cortical Actin remodelling. I generated an arf6 null mutant in Drosophila. arf6 null mutants survive to adulthood without obvious morphological defects, indicating that ARF6 is not required for Drosophila somatic development. However, ARF6 is required for cytokinesis in Drosophila spermatocytes. The centralspindlin kinesin Pavarotti, identified as an ARF6 interactor in a Yeast-2-Hybrid assay, binds ARF6 in GST pulldowns, and interacts genetically with the arf6 mutant. ARF6 localizes to the plasma membrane and a population of early and recycling endosomes. During cytokinesis, ARF6 is enriched on recycling endosomes at the central spindle. arf6 mutants form a cleavage furrow during cytokinesis, which later regresses. Cytokinesis in arf6 mutant spermatocytes lacks the rapid plasma membrane expansion observed during normal divisions. The results of this study suggest that ARF6 might promote rapid recycling of endosomal membrane stores at the central spindle to the plasma membrane during cytokinesis. ARF6 might be recruited to the central spindle via its interaction with Pavarotti, and act as part of the molecular link between the central spindle cytoskeleton and the rapid plasma membrane addition necessary for cytokinesis. Für die Ansicht der quick-time-Movies mit der Endung "avi" ist die Installation des "Apple QuickTime-Players" erforderlich.

info:eu-repo/classification/ddc/570

ddc:570

Zellteilung; Drosophila

Engagement of T cells with Antigen Presenting Cells is Dependent on Clathrin-Independent Endocytic Trafficking: The Role of Arf6 and Rab22

Johnson, Debra L.

January 2016

The clathrin-independent endosomal system is required for cellular homeostasis and specialized modifications of the plasma membrane such as cell spreading and polarization. Clathrin-independent endocytosis (CIE) has been demonstrated in adherent cells including fibroblasts and epithelial cells. However, non-adherent cells also have highly dynamic clathrin-independent pathways, which have not been well described. Here, I have characterized Arf6-associated clathrin-independent endocytosis (CIE) in the human T cell line Jurkat and identified it's importance in immunological synapse formation. Our findings indicate that the CIE pathway is similar in Jurkat cells as compared to other cell types including rates of endocytosis and sorting after internalization. Two GTPases, Arf6 and Rab22, have been shown to regulate the clathrin-independent endosomal system and play a role in cell spreading. We found that wild type and constitutively active Arf6 co-localized with CIE cargo in resting T cells. Arf6 constitutively active mutant inhibited CIE cargo internalization but not internalization of CME cargo. Rab22 co-localized with CIE cargo at the endocytic-recycling compartment. Expression of the dominant negative Rab22 mutant also inhibited internalization of MHCI indicating it plays a direct role in CIE cargo internalization. T cells must modify their membranes to specifically interact with antigen presenting cells. To establish the role of CIE in this process, we then examined the role of Arf6 and Rab22 in T cell/antigen presenting cell conjugate formation. Both expression of dominant negative or constitutively active mutants of Arf6 reduced T cell conjugate formation while expression of only the Rab22 dominant negative mutant inhibited T cell/APC conjugate formation. Furthermore, T cells expressing the dominant negative mutant of Rab22 were not able to spread on antibody-coated coverslips that normally cause T cell activation. These results indicate that the clathrin independent endosomal system is required for membrane remodeling events necessary for T cell conjugate formation and T cell spreading during activation. I also conducted a proteomics screen to identify binding partners of CIE cargo proteins. I identified multiple proteins that could possibly play a role in CIE internalization and discovered a subset of proteins that specifically interact with A cargo proteins and not B cargo proteins. It is possible they could play a role in cargo retention at the plasma membrane or sorting after internalization. Three proteins of interest that interact with A cargo include NHERF-1 and ezrin, which participate in actin arrangements, and Dlg-1, a known scaffolding protein for synaptic vesicles. Ezrin and Dlg-1 co-localize with the CIE cargo protein CD98 in HeLa cells indicating that they could be interacting in cells.

Clathrin-independent

endocytosis

membrane trafficking

Rab22

T cells

Cellular and Molecular Medicine

Arf6

The Role of Phosphatidylinositol-3 Kinases and Phosphatidylinositol Phosphatases in T Cell Intracellular Homeostasis and Autophagy

McLeod, Ian Alexander

January 2013

<p>The homeostasis of naïve T lymphocytes is maintained by several mechanisms involving basal TCR and cytokine signaling, and nutrient factors. One of the common net results of these input signals is the production and stabilization of anti-apoptotic Bcl-2 family members. A second result of these processes is the induction of autophagy, an intracellular, catabolic, lysosomal targeting pathway. Autophagy induction in most systems involves the class III phosphatidylinositol-3 kinase (PI3K), Vps34, to produce phosphatidylinositol-3-phosphate (PI(3)P). To test this in T lymphocytes, I generated mice specifically lacking Vps34 in T cells (Vps34f/fLck-cre mice). However, Vps34-deficient T lymphocytes have normal levels of basal autophagy, and upregulate autophagy normally in response to cytokine or nutrient withdrawal, or TCR stimulation. Therefore I conclude that Vps34 activity is not required for autophagy induction in T lymphocytes. T lymphocytes lacking Vps34 do have enhanced rates of apoptosis, but this is due to defects in intracellular trafficking, specifically of the Interleukin-7 receptor alpha subunit (IL-7R&#945;). Additionally, multivesicular body (MVB) maturation is impaired in T cells lacking Vps34 such that extracellular ligands are not efficiently targeted to the lysosome. </p><p>Autophagy induction in Vps34-deficient T lymphocytes is still sensitive to pan-PI3K inhibitors, such as wortmannin and 3-methyladenine (3MA). Therefore, I hypothesized that other classes of PI3K are necessary to induce autophagy in T lymphocytes through the production of PI(3)P. Autophagy induction is sensitive to specific class I PI3K (PI3KI) inhibitors, such as PIK75. Additionally, T cells lacking the p85 regulatory subunit of PI3KI also have severe defects in T cell receptor (TCR) mediated autophagy induction. PI3KI activity results in the production of PI(3,4,5)P3, though, and not PI(3)P. Because of this specificity, I hypothesize that additional inositol polyphosphatases (Inpp) are required for autophagy induction downstream of PI3KI activity. Indeed, utilizing both inhibitors of pharmacological inhibition and siRNA-mediated knockdown of two classes of phosphatidylinositol phosphatases, inositol polyphosphate-4-phosphatase (Inpp4) and SH2 containing inositol phosphatase (SHIP), had dramatic impacts on autophagy induction. Furthermore, exogenous addition of PI(3,4)P2, a hypothesized intermediate in this pathway, positively regulates autophagy induction and leads to enhanced progression of autophagy. These observations indicate that PI3KI activity, linked to Inpp activity, are necessary and positive regulators of autophagy through the production of PI(3)P.</p> / Dissertation

Immunology

Cellular biology

Biochemistry

Autophagy

IL-7R

inositol phosphatase

Membrane Trafficking

PI3K

Mutational analysis of membrane traffic in Arabidopsis thaliana

Au, Kin Cheong Kenneth

January 2012

To identify novel and essential components of the plant membrane trafficking mechanisms, Arabidopsis membrane trafficking mutants from fluorescent protein-based forward genetic screens were characterized. First, four novel glutathione synthase (GSH2) mutant alleles featured swollen endoplasmic reticulum (ER)-derived bodies that accumulated a soluble secretory marker. Consistent with the role of GSH2 in glutathione biosynthesis, the loss-of-function mutant alleles exhibited gamma-glutamylcysteine (γ-EC) hyperaccumulation and glutathione deficiency. The aberrant ER morphology was ascribed to the γ-EC accumulation. Redox-sensitive fluorescent protein revealed that gsh2 seedlings maintained a reduced cytoplasm at steady state but were more sensitive to oxidative challenge. Second, Mut 21 was a conditional mutant that accumulated a secretory marker in the alkalized apoplast at restrictive temperature (31˚C). The mutant was identified as carrying a mutant allele of tuftelin-interacting protein 11 (TFIP11), which has been implicated in regulating redifferentiation and cell proliferation through a cytokinin signalling pathway. Hence, it was postulated that the changes in response to cytokinin affect auxin-mediated acidification of the apoplast. Third, Mut 43 was a conditional mutant that accumulated a soluble secretory marker in the ER and unidentified punctate structures at restrictive temperature, and exhibited perturbations in ER export of a soluble protein marker. Moreover, the mutant showed severe growth defects and abnormal radial root swelling in the apical elongation zone. A mutation identification method through deep-sequencing of the wild-type siblings in outcrossed heterozygous mutant families was developed and tested in Mut 43. At the time when this thesis was prepared, bioinformatic analysis has assigned Mut 43 to the bottom arm of chromosome two and predicted a 300kb mapping interval based on the observed bias in single nucleotide polymorphism ratios. This work demonstrates the feasibility of using forward genetics to study plant-specific aspects of membrane trafficking mechanisms and incorporates new technology to streamline the process of gene identification.

581.35

Viral subversion of host cell membrane trafficking

Muenzner, Julia

January 2017

Enveloped viruses acquire their membrane coat from the plasma membrane or intracellular organelles and rely on cellular machinery to facilitate envelopment and egress of virus progeny. This thesis examines egress-related interactions between host cell factors and proteins of two different enveloped viruses: hepatitis D virus (HDV) and herpes simplex virus 1 (HSV-1). HDV is a small RNA virus causing fulminant hepatitis or severely aggravating cirrhosis and hepatocellular carcinoma. HSV-1 is a large DNA virus infecting epithelial and neuronal cells. Infection with HSV-1 not only triggers the development of recurring sores on oral or genital mucosa, but can also cause severe disease in neonates and immunocompromised patients. The interaction between the large antigen of HDV (HDAg-L) and the N-terminal domain (NTD) of clathrin, a protein crucial for endocytosis and intracellular vesicular trafficking, was examined by structural, biochemical and biophysical techniques. Co-crystal structures of NTD bound to HDAg-L peptides derived from different HDV genotypes revealed that HDV interacts with multiple binding sites on NTD promiscuously, prompting re-evaluation of the binding between cellular peptides and NTD. Surprisingly, co-crystal structures and pull-down capture assays showed that cellular peptides containing clathrin-binding motifs can also bind multiple sites on the surface of NTD simultaneously. In addition, the structures of viral and cellular peptides bound to NTD enabled the molecular characterization of the fourth peptide binding site on NTD, the “Royle box”, and led to the identification of a novel binding mode at the “arrestin box” peptide binding site on NTD. The work in this thesis therefore not only identifies the molecular basis of HDV:clathrin interactions, but also furthers our understanding of basic clathrin biology. Even though many HSV-1 proteins have been implicated in the envelopment and egress of viral particles, only few interactions between HSV-1 and cellular proteins promoting these processes have been described. Therefore, the HSV-1 proteins gE, UL21 and UL56 were selected and characterized bioinformatically and/or biochemically. Cellular proteins interacting with UL56 were identified by yeast two-hybrid screening and quantitative mass spectrometry. Co-immunoprecipitation and pull-down experiments confirmed the Golgi-trafficking protein GOPC, components of the mammalian trafficking protein particle complex, and the ubiquitin ligase NEDD4 as novel binding partners of UL56, thereby suggesting exciting new avenues for the investigation of cellular mechanisms contributing to HSV-1 envelopment and egress.

616.9

An investigation of the function of adaptor protein complex 4 (AP-4)

Davies, Alexandra Katherine

January 2019

Vesicle trafficking provides the solution to the 'sorting problem' - how the eukaryotic cell maintains the distinct identities, and thus functional properties, of its membrane-bound organelles. During vesicle trafficking, proteins are selectively sorted into membrane bound transport intermediates by vesicle adaptors, which include those of the highly conserved adaptor protein (AP) complex family. Each AP complex has a distinct subcellular localisation and functions in the sorting of a specific subset of transmembrane cargo proteins. Adaptor protein complex 4 (AP-4) is one of the more recently identified AP complexes, whose function has largely remained elusive. In humans, AP-4 deficiency causes a severe neurological disorder, suggesting an important role in neuronal development and homeostasis. However, the pathomechanisms that underly the neuronal pathology in AP-4 deficiency are currently unknown. AP-4 is proposed to function in protein sorting at the trans-Golgi network (TGN), so AP-4 deficiency can be thought of as a disease of missorting. The aim of this study was to apply unbiased global proteomic approaches to define the composition of AP-4 vesicles and to identify physiological cargo proteins of the AP-4 pathway. Using 'Dynamic Organellar Maps' and comparative analysis of vesicle-enriched fractions from wild-type and AP-4-depleted cells, three ubiquitously expressed transmembrane cargo proteins, ATG9A, SERINC1 and SERINC3, were found to be mislocalised in AP-4-deficient cells. Two novel cytosolic AP-4 accessory proteins, RUSC1 and RUSC2, were also identified. Further proteomic analyses confirmed the interactions between these proteins. AP-4 deficiency was found to cause missorting of ATG9A in diverse cell types, including patient derived cells, as well as dysregulation of autophagy. RUSC2 facilitates the transport of AP-4-derived, ATG9A and SERINC-positive vesicles from the TGN to the cell periphery. These vesicles cluster in close association with autophagosomes, suggesting they are the 'ATG9 reservoir' required for autophagosome biogenesis. This study uncovers ATG9A trafficking as a ubiquitous function of the AP-4 pathway. Furthermore, it provides a potential molecular pathomechanism of AP-4 deficiency, through dysregulated spatial control of autophagy.

Clathrin Independent Carriers: Molecular characterisation of a novel clathrin-independent endocytic pathway

Mark Howes

Unknown Date

Endocytosis effectuates a critical interface between the eukaryotic cell and its apposing environment. It is, subsequently, paramount for many physiologically important processes and encompasses a diverse array of mechanisms and pathways. The classical endocytic routes mediated by clathrin and caveolin are the best understood and the molecular roles of their major regulators, such as dynamin, adaptor proteins and various lipid species, are the most comprehensively described. Recent identification of an assortment of constitutive, noncaveolar, clathrin-independent endocytic (CIE) pathways has expanded the endocytic system. Unlike the classical endocytic pathways, little is known about the guiding parameters of CIE routes. Consequently, it is not possible to understand the important cellular roles these pathways may be fulfilling. This study has begun to characterise the very basic parameters governing the morphologically striking Clathrin-Independent Carrier (CLIC) pathway. Development of a diverse molecular toolkit has now allowed the quantitation of endocytic capacity provided by CLICs, the visualisation of subtle sorting components of the CLIC pathway, the isolation of novel CLIC cargo and regulators, and has linked this mechanism to the critical cellular processes of cellular migration and membrane repair. Calculation of the individual capacity of endocytic routes provides important information about the contribution of each pathway to total plasma membrane (PM) uptake and turnover. Quantitation of the volume, surface area and number of structures forming per minute in this study shows that CLICs provide the vast majority of constitutive endocytosis, up to four times the capacity of the clathrin mediated endocytic (CME) pathway. As the equivalent of the entire PM area could pass through the CLIC pathway within 12 minutes it is evident that CLICs are fundamental housekeepers of bulk membrane internalisation. Thus, they are likely to be central regulators of PM homeostasis and turnover. High-resolution tomography, in conjunction with analysis of CLIC cargo trafficking, identifies these carriers as complex, pleiomorphic structures that sort the bulk of membrane to early endosomes and recycle cargo back to the cell surface. Such vast internalisation combined with an ability to rapidly recycle components quickly attributes the CLIC pathway as a complex sorting station. Isolation of novel cargo and regulators has identified a striking array of proteins now associated with the CLIC pathway for the first time. A significant proportion of identified targets localise to lipid-rafts and recycle from the PM, facets consistent with association to the CLIC pathway. Numerous targets have also been directly implicated in clathrin-independent endocytosis by independent groups. Verification of selected cargo, such as CD44, Thy-1 and myoferlin, showing specific internalisation through the CLIC pathway, has provided insight into the sorting ability of the CLIC pathway and links to adhesion turnover and membrane recycling. Consistent with a role in cellular adhesion turnover, it was found that CLICs become polarised within migrating cells. This has shown the first instance of spatial separation between three major endocytic routes, CLICs, caveolae and CME and highlights the important and coordinated roles of multiple endocytic pathways during physiologically significant processes. The specific internalisation of paxillin, Thy-1 and CD44 through CLICs at the leading edge of migrating cells suggests that CLICs rapidly turnover adhesion components for dynamic extracellular sensation during directional cell migration. Indeed, specific ablation of the CLIC pathway significantly impedes cellular migration, implying coordination with CME at the leading edge. This study has defined numerous parameters of the CLIC pathway, developing the current understanding of this poorly defined route and places the CLIC pathway as a unique player during critical cellular processes.

Endocytosis

Endosome

Clathrin-independent Endocytosis

Lipid Rafts

Membrane Trafficking

The role of the tail of fungal kinesin-3 in binding to early endosomes and their role in plant pathogenicity

Bielska, Ewa

January 2013

The dimorphic fungus Ustilago maydis is a pathogen of maize and it was used for decades to understand the molecular basis of plant pathogenicity aspects. Recently, much effort went into understanding the cell biology that underlies the virulence of U. maydis. It was shown previously that early endosomes (EEs) move bidirectionally within fungal hyphal cells. Although it was shown that the motility of EEs facilitates growth of the infectious hypha and mutants defective for kinesin-3 (Kin3), the major EE transporter, exhibit impaired polarized growth, the importance of EEs and their motility in plant colonization is not known. The first part of this thesis is focused on the role of EE motility during plant infection. In collaboration with Natalie Steinberg, who performed the plant infection assays, I used a synthetic molecular anchor, K1rPX, to block the motility of EEs at early and late stages during the host plant infection and I found that EE motility is essential during the first two days of pathogenic development, when infectious hyphae exhibit most prominent elongation, whereas blockage of EE motility after 3 days post infection does not inhibit plant colonization. Moreover, I documented that the blockage of EE motility during early stages of the infection causes high plant defence response, which means that the pathogen becomes recognized by the host plant defence system. These results indicate that EE motility is crucial during initial stages of the plant host infection and enables colonization by U. maydis and additionally suggests involvement of EEs in some defence response machinery. The second part of the thesis addresses the relationship between Kin3, the major motor for EE motility, and the microtubule (MT) array. I demonstrate here that Kin3 uses all MT tracks available in the cell, which is in contrast to published results in other systems. In the third part I focused on the interaction between Kin3 and the EEs. I found that the pleckstrin homology (PH) domain localized at the distal part of the Kin3 tail is of minor importance for EE association. This conclusion is supported by in vivo experiments, showing that truncated Kin3PH, which lacks the PH domain, was still able to bind to the organelles. By systematic truncation of parts of the Kin3 tail I found two adjacent regions, a DUF3694 domain and a "linker" region, that are important for binding of Kin3 to EEs. By using a synthetic anchor composed of Kin1 rigor domain and selected Kin3 domains I proved that both domains anchor the EEs to MTs and inhibit EE motility. I also showed that the PH domain is not able to block EE motility. In collaboration with Dr. Nicholas Harmer, who performed structural modelling of selected PH domains, I demonstrated that the PH domain is likely to interact with the motor domain of Kin3. This result was confirmed by using a yeast-two hybrid approach and a protein affinity assay. This indicates a globular organization of the Kin3 motor, which was confirmed by a split-YFP assay in living cells. Deletion of the PH domain and most probably lack of intramolecular interaction between the tail and motor domain reduces Kin3 motility parameters like velocity, frequency and run length indicating that the interaction of the PH domain with the motor domain has a role in the control of Kin3 motility.

500

The Role Of The Small GTPASE RAB14 In Apical ProteinTraffic And Maintenance Of Cell Polarity

Jacobson, Noelle C

January 2005

The establishment and maintenance of cell polarity during development is an active process that requires specific protein sorting and targeting to apical and basolateral regions of the cell. Our lab has identified an apical early endosomal marker, endotubin, in developing rat intestine, which we have used to label specialized apical endosomal tubules, and to probe for components of the apical sorting machinery. Studies with endotubin have implicated the small GTPase Rab14 as part of the sorting machinery for apical targeting. The current work pursues further study of the interaction between Rab14 and endotubin, as well as the role for Rab14 in the establishment of cell asymmetry. Interestingly, even nonpolarized cells may utilize polarized trafficking components for proper sorting and dynamics of endotubin.

protein trafficking

cell polarity

apical protein sorting

membrane trafficking

epithelial polarity

Clathrin Independent Carriers: Molecular characterisation of a novel clathrin-independent endocytic pathway

Mark Howes

Unknown Date

Endocytosis effectuates a critical interface between the eukaryotic cell and its apposing environment. It is, subsequently, paramount for many physiologically important processes and encompasses a diverse array of mechanisms and pathways. The classical endocytic routes mediated by clathrin and caveolin are the best understood and the molecular roles of their major regulators, such as dynamin, adaptor proteins and various lipid species, are the most comprehensively described. Recent identification of an assortment of constitutive, noncaveolar, clathrin-independent endocytic (CIE) pathways has expanded the endocytic system. Unlike the classical endocytic pathways, little is known about the guiding parameters of CIE routes. Consequently, it is not possible to understand the important cellular roles these pathways may be fulfilling. This study has begun to characterise the very basic parameters governing the morphologically striking Clathrin-Independent Carrier (CLIC) pathway. Development of a diverse molecular toolkit has now allowed the quantitation of endocytic capacity provided by CLICs, the visualisation of subtle sorting components of the CLIC pathway, the isolation of novel CLIC cargo and regulators, and has linked this mechanism to the critical cellular processes of cellular migration and membrane repair. Calculation of the individual capacity of endocytic routes provides important information about the contribution of each pathway to total plasma membrane (PM) uptake and turnover. Quantitation of the volume, surface area and number of structures forming per minute in this study shows that CLICs provide the vast majority of constitutive endocytosis, up to four times the capacity of the clathrin mediated endocytic (CME) pathway. As the equivalent of the entire PM area could pass through the CLIC pathway within 12 minutes it is evident that CLICs are fundamental housekeepers of bulk membrane internalisation. Thus, they are likely to be central regulators of PM homeostasis and turnover. High-resolution tomography, in conjunction with analysis of CLIC cargo trafficking, identifies these carriers as complex, pleiomorphic structures that sort the bulk of membrane to early endosomes and recycle cargo back to the cell surface. Such vast internalisation combined with an ability to rapidly recycle components quickly attributes the CLIC pathway as a complex sorting station. Isolation of novel cargo and regulators has identified a striking array of proteins now associated with the CLIC pathway for the first time. A significant proportion of identified targets localise to lipid-rafts and recycle from the PM, facets consistent with association to the CLIC pathway. Numerous targets have also been directly implicated in clathrin-independent endocytosis by independent groups. Verification of selected cargo, such as CD44, Thy-1 and myoferlin, showing specific internalisation through the CLIC pathway, has provided insight into the sorting ability of the CLIC pathway and links to adhesion turnover and membrane recycling. Consistent with a role in cellular adhesion turnover, it was found that CLICs become polarised within migrating cells. This has shown the first instance of spatial separation between three major endocytic routes, CLICs, caveolae and CME and highlights the important and coordinated roles of multiple endocytic pathways during physiologically significant processes. The specific internalisation of paxillin, Thy-1 and CD44 through CLICs at the leading edge of migrating cells suggests that CLICs rapidly turnover adhesion components for dynamic extracellular sensation during directional cell migration. Indeed, specific ablation of the CLIC pathway significantly impedes cellular migration, implying coordination with CME at the leading edge. This study has defined numerous parameters of the CLIC pathway, developing the current understanding of this poorly defined route and places the CLIC pathway as a unique player during critical cellular processes.

Endocytosis

Endosome

Clathrin-independent Endocytosis

Lipid Rafts

Membrane Trafficking