A Role for Integrin-linked Kinase In Oligodendrocyte Mediated Myelination of the Central Nervous System

Michalski, John-Paul

January 2014

The interplay between oligodendrocyte (OL) and extracellular matrix (ECM) is critical to the proper maturation of this unique cell type. Recent work has established the β1 integrin-signaling pathway, a mediator for ECM/OL interactions, as an essential component of myelin sheath formation in the central nervous system (CNS). A major downstream effector of β1 integrin is integrin-linked kinase (ILK), an adaptor and structural platform protein. Herein, we (1) generated a model system to study ILK in vivo and (2) employed the model to elucidate ILK’s role in regulating OL biology. To assess the importance of ILK in OL-mediated myelination, we ablated ILK in primary OLs. ILK loss delayed morphological maturation and led to filamentous actin accumulation in the processes and cell body. Further, we noted an upregulation in RhoA activity, with pathway inhibition rescuing an OL subset. We next moved our studies in vivo. First, we assessed the proteolipid protein promoter’s utility as OL-specific Cre driver. Protocols established, we generated an ILK conditional knockout line (Ilk cKO). Ultrastructural analysis of Ilk cKO optic nerves revealed increased number of amyelinated nerve fibers at P14 with subsequent recovery by P28. The observed transient defects were due neither to a loss nor a gain in total number of mature or progenitor OLs. To rationalize recovery, we grew ILK-depleted OLs on an “inert” substrate. Here, while morphology improved, ILK-depleted OLs were characterized by enlarged and sluggish growth cones as well as microtubule disorganization. Taken together, our data suggests a role for ILK in regulating the morphological maturation of OLs both in vitro and in vivo, the loss of which results in defective OL branching and membrane formation with phenotype and subsequent recovery dependent upon niche complexity.

Oligodendrocyte

Integrin-linked kinase

Myelin

Cytoskeleton

Integrin

Aging Actin' Up: A novel aging determinant regulates the actin cytoskeleton, nutrient sensing, and lifespan in Saccharomyces cerevisiae

Sing, Cierra Nicole

January 2021

The aging process is unforgiving, targeting a decline in cellular function. Originally, the actin cytoskeleton has not been defined as a hallmark of aging biology, however, numerous studies provide evidence that actin cytoskeleton integrity is declining with age. Mammalian cells express an aged-linked decline in their actin dynamics, consequently defecting their migratory movements, immunological synapse formation, and phagocytosis. Overall, suggesting actin integrity is specifically targeted by aging. Despite the substantial evidence, the underlying mechanism remains elusive, however, current research indicates actin stability as a possible mechanistic aging target. Therefore, our research goal is to further elucidate the mechanism for actin cytoskeleton aging biology in a streamlined model organism, budding yeast, Saccharomyces cerevisiae. Here, we use aging enrichment protocols, streptavidin affinity purification, to isolate a population of older cells to examine any changes in the actin cytoskeleton with age. With an isolated aging population, we analyzed the actin cytoskeleton by testing its stability against a destabilizing drug, Lat-A, and morphology with imaging analysis. We find significant age-associated changes in the actin cytoskeleton, which we later conclude may be a consequence of the age-linked decline in the actin stability that we identified in an aging cell. Additionally, we uncovered a perplexing finding that there is an age-linked decline in actin cable bundling. How actin stability effects actin cable bundling, remains to be determined. However, our actin stability model was further supported by our research characterizing an open reading frame, YKL075C, as a novel actin cable regulatory protein whose deletion: increased actin cable stability, abundance, and mitochondrial quality to extend the replicative lifespan. Upon further insight into YKL075C underlying mechanism, we find YKL075C effects on actin stability and morphology is dependent on alterations in branched-chain amino acid (BCAA) metabolism. Overall, our research discovered a novel actin regulatory protein, Ykl075cp, whose actin function is dependent on BCAA homeostasis, and deleting specifically YKL075C reduces BCAA levels that subsequently increases actin cable stability and abundance to enhance mitochondrial quality and extends longevity.

Cytology

Aging

Cells--Aging

Saccharomyces cerevisiae

Cytoskeleton

Fundamental techniques for cell membrane studies at sub-micrometer scale / サブマイクロメートルスケール細胞膜研究の基盤技術

Genjo, Takuya

23 March 2020

京都大学 / 0048 / 新制・課程博士 / 博士(工学) / 甲第22464号 / 工博第4725号 / 新制||工||1738(附属図書館) / 京都大学大学院工学研究科分子工学専攻 / (主査)教授 梅田 眞郷, 教授 水落 憲和, 准教授 菅瀬 謙治 / 学位規則第4条第1項該当 / Doctor of Philosophy (Engineering) / Kyoto University / DGAM

Nanodiscs

Nanodiamonds

cell membrane

actin

cytoskeleton

500

Ischemic Loss of Sarcolemmal Dystrophin and Spectrin: Correlation With Myocardial Injury

Armstrong, Stephen C., Latham, Carole A., Shivell, Christine L., Ganote, Charles E.

01 January 2001

Sarcolemmal blebbing and rupture are prominent features of irreversible ischemic myocardial injury. Dystrophin and spectrin are sarcolemmal structural proteins. Dystrophin finks the transmembrane dystroglycan complex and extracellular laminin receptors to intracellular F-actin. Spectrin forms the backbone of the membrane skeleton confering an elastic modulus to the sarcolemmal membrane. An ischemic loss of membrane dystrophin and spectrin, in ischemically pelleted rabbit cardiomyocytes or in vivo 30-45 rain permanently ischemic. LAD-ligated hearts, was detected by immunofluorescence with monoclonal antibodies. Western blots of light and heavy microsomal vesicles and Triton-extracted membrane fractions from ischemic myocytes demonstrated a rapid loss of dystrophin coincident with sub-sarcolemmal bleb formation, subsequent to a hypotonic challenge. The loss of spectrin from purified sarcolemma of autolysed rabbit heart, and both isolated membrane vesicles and Triton solubilized membrane fractions of ischemic cardiomyocytes correlated linearly with the onset of osmotic fragility as assessed by membrane rupture, subsequent to a hypotonic challenge. In contrast to the ischemic loss of dystrophin and spectrin from the membrane, the dystrophin-associated proteins. α-sarcoglycan and β-dystroglycan and the integral membrane protein, sodium-calcium exchanger, were maintained in the membrane fraction of ischemic cells as compared to oxygenated cells. Preconditioning protected cells, but did not significantly alter ischemic dystrophin or spectrin translocation. This previously unrecognized loss of sarcolemmal dystrophin and spectrin may be the molecular basis for sub-sarcolemmal bleb formation and membrane fragility during the transition from reversible to irreversible ischemic myocardial injury.

cardiomyocytes

cytoskeleton

ischemia

ischemic preconditioning

sarcolemma

Deletion of Core Septin Gene aspB in Aspergillus fumigatus Results in Fungicidal Activity of Caspofungin

Busch, Rebecca Jean

01 December 2023

Septins are a family of GTP-binding proteins, and although highly conserved throughout many eukaryotes, their functions vary across species. In Aspergillus fumigatus, the etiological agent of invasive aspergillosis, septins participate in a variety of roles such as cell wall organization of conidia, septation, and response to anti-cell wall stress. Previous studies determined that the ∆aspB strain had a greater sensitivity to anti-cell wall drugs, especially the echinocandin caspofungin, yet mechanisms behind this augmented sensitivity are unknown. We performed cell viability staining post-caspofungin exposure and found that the ∆aspA, ∆aspB, and ∆aspC strains showed significant reduction in cell viability. Concomitant with the reduced viability, deletion strains are more susceptible to caspofungin on solid media. These results indicate that the septin cytoskeleton is important for A. fumigatus survival in the presence of caspofungin. Due to the potential of improved therapeutic outcome, we followed up using a neutropenic murine model of invasive aspergillosis. Deletion of the aspB gene resulted in improved survival when treated with caspofungin when compared to the akuBKU80 wild-type or untreated ∆aspB strains. Quantitative proteomics analyses were used to find proteins involved in the septin-dependent adaptation to caspofungin. We identified four candidates with roles in cell wall integrity. Deletion of these candidate genes resulted in increase in susceptibility to caspofungin and moderate reduction in viability post drug exposure. Taken together, these data suggest that septin AspB is essential in mediating the fungistatic response to caspofungin.

aspergillosis

Aspergillus

caspofungin

cytoskeleton

fungi

septin

Understanding virulence factors of Mycoplasma penetrans: attachment organelle organization and gene expression

Distelhorst, Steven Lindau

28 March 2017

No description available.

Microbiology

Bacteria

Mycoplasma

attachment organelle

cytoskeleton

Regulation of Growth Cone Mitochondria by Intrinsic and Extrinsic Factors

Xu, Zhuxuan

January 2017

The activity of the growth cone is necessary for neuron axon elongation during neuron development and regeneration. This is a highly dynamic process of cytoskeletal recorganization that requires a significant amount of energy provided by the mitochondria. The localization of a sufficient number of mitochondria at the growth cone is essential to support its activity during neuron development and regeneration. Both promotion and inhibition of the motility of growth cones can be induced by intrinsic factors of neuron itself such as cytoskeleton dynamics and motor protein activity, as well as extracellular molecules in the vicinity of the neuron such as nerve growth factor (NGF) and components of the extracellular matrix. The proposed hypothesis is that some of these factors have an impact on the localization and morphology of mitochondria. My work in this project is aimed to determine which of these factors have the greatest impact on mitochondria in neurons. Using sensory neurons isolate / Biomedical Sciences

Neurosciences

Cytoskeleton

Growth Cone

Mitochondria

Ngf

Characterization of the hollow fiber assay for the determination of microtubule disruption in vivo.

Suggitt, Marie, Swaine, David J., Pettit, G.R., Bibby, Michael C.

January 2004

No / Purpose: The hollow fiber assay is used successfully as a routine in vivo screening model to quantitatively define anticancer activity by the National Cancer Institute. This study investigates whether the hollow fiber assay can be used as a short-term in vivo model to demonstrate specific pharmacodynamic end points, namely microtubule and cell cycle disruption. Experimental Design: The growth of A549 cells was characterized within hollow fibers over 5 days in vivo at both subcutaneous (s.c.) and intraperitoneal (i.p.) sites. Drugs were administered on day 4 (i.p.). Results: At 24 hours, cells were retrieved from fibers at both i.p. and s.c. sites of paclitaxel-treated (20 mg/kg) and combretastatin A1 phosphate¿treated (150 mg/kg) mice. Cell cycle analysis after paclitaxel treatment revealed a mean G2-M phase population of 48.04% (i.p.) and 25.76% (s.c.) compared with vehicle group mice (6.78 and 5.56%, respectively; P = <0.001 and 0.005, respectively). Tumor cells retrieved from combretastatin A1 phosphate¿treated mice had a mean G2-M phase population of 36.3% (i.p.) and 29.36% (s.c.) compared with cells retrieved from vehicle group mice (5.58 and 5.49%, respectively; P = <0.001). Using fluorescence and laser-confocal microscopy, paclitaxel was revealed to induce the formation of spindle asters and tubulin polymerization. Combretastatin A1 phosphate was shown to hold cells in mitosis. Changes in nuclear morphology were also observed. Conclusion: These data demonstrate that the hollow fiber assay can be used as a short-term in vivo model for studying the pharmacodynamic effects of both standard and novel compounds on microtubules. Evidence has also been provided to support the routine use of the in vivo hollow fiber assay for demonstrating the mechanism of action of a drug.

Cytoskeleton

In vivo

Microtubule

Quantitative analysis

Hollow fiber

The identification of a new molecular tool to investigate the role of actin and microtubule cytoskeletons in the endocytosis pathway of the pathogenic fungus Ustilago maydis

Clark, Natalie

January 2014

Endocytosis is essential for the pathogenic development of Ustilago maydis. It has been shown that the initiation of pathogenicity relies upon the ability of the cell to recognize pheromone (a1 or a2) released from its mating partner and subsequently to form conjugated hyphae. The actin and microtubule cytoskeleton plays an essential role in all aspects of cell growth. A component of the actin cytoskeleton, the filamentous actin is required for cell-cell fusion, whereas the molecular motors, kinesin and dynein, move along microtubules and provide the long distance transport of many proteins and they are important in cell growth and pathogenicity. In this thesis, we investigated the role of the cytoskeleton in endocytosis and a1 pheromone transport, using a fluorescently labelled derivative of the a1 pheromone. We confirmed that uptake of the a1 pheromone is also receptormediated. In addition, we have shown that pheromone transport towards the cellular vacuole requires the actin and microtubule cytoskeletons. Furthermore, we revealed that the microtubule-dependent motors kinesin-1 and kinesin-3 and dynein were shown to be essential in the delivery of the pheromone to vacuoles. Moreover, a mutation in the early endosomal protein Yup1 gene causes a stop in delivery of the synthetic pheromone to the vacuole. This suggests that it travels with early endosomes. Within the actin cytoskeleton, we analysed the dynamics of actin patches in the presence of the synthetic pheromone and found that the dynamics of the patches increased significantly. Additionally, in the presence of an over-expression of the tail domain of the molecular motor myosin-5, the dynamics of the patches were significantly reduced and their intensity diminished.

570

Analysis of the novel Lyn-associated cytoskeletal modular protein, LACM

McCarthy, David James

January 2009

A yeast-two hybrid screen with Lyn identified a novel 130 kDa multidomain protein with a 36% identity to Actin Filament Associated Protein (AFAP) 110 and similar domains, including PH domains, potential sites of tyrosine and serine/threonine phosphorylation, a leucine-zipper domain, a potential actin binding site and multimerization site. AFAP110 has been shown to have a role in modulating actin filament integrity and induce lamellipodia formation, and is known to interact with Src family kinases. The aim of this thesis was to characterize this novel protein named Lyn-Associated Cytoskeletal Modulator (LACM) and determine any molecular interactions in order to attempt to elucidate a role for the protein in cell signaling through Lyn. LACM is encoded by a gene consisting of 18 exons and is located on human chromosome 5q33.1 and mouse chromosome 18 E1. LACM protein is expressed through a number of cell types including the R11 erythroid cell line, and mouse tissues including brain, lung, heart and embryos. LACM was shown to multimerize, and subcellular localization of the protein was observed to concentrate around the cell membrane at sites of filamentous actin in filopodia, lamellipodia and stress fibres. The carboxy-terminus of LACM was observed to localize the protein to sites at the cell membrane and through the cytoplasm. Removal of this terminal region resulted in all LACM protein localizing to the nucleus in punctuate spots. LACM protein was observed in heart muscle and potentially has a role at sites of nerve junctions on cardiac myocytes. LACM was shown to interact with the SH3 domain of Lyn at a polyproline motif on LACM. LACM was observed to co-localize and co-immunoprecipitate with Lyn and was tyrosine phosphorylated by the kinase domain of Lyn. Interestingly, the consititutively active Lyn and LACM caused transfected cells to

Cellular signal transduction

Cytoskeleton

Cytoskeletal proteins

Erythropoiesis

Protein-tyrosine kinase

Cell signalling

Cytoskeleton

LACM

Lyn