TY  - THES
A1  - Putzler, Sascha
T1  - Molekulare Charakterisierung des Centrosom-assoziierten Proteins CP91 in Dictyostelium discoideum
T1  - Molecular characterization of the centrosome-associated protein CP91 in Dictyostelium discoideum
N2  - Das Dictyostelium-Centrosom ist ein Modell für acentrioläre Centrosomen. Es besteht aus einer dreischichtigen Kernstruktur und ist von einer Corona umgeben, welche Nukleationskomplexe für Mikrotubuli beinhaltet. Die Verdoppelung der Kernstruktur wird einmal pro Zellzyklus am Übergang der G2 zur M-Phase gestartet. Durch eine Proteomanalyse isolierter Centrosomen konnte CP91 identifiziert werden, ein 91 kDa großes Coiled-Coil Protein, das in der centrosomalen Kernstruktur lokalisiert. GFP-CP91 zeigte fast keine Mobilität in FRAP-Experimenten während der Interphase, was darauf hindeutet, dass es sich bei CP91 um eine Strukturkomponente des Centrosoms handelt. In der Mitose hingegen dissoziieren das GFP-CP91 als auch das endogene CP91 ab und fehlen an den Spindelpolen von der späten Prophase bis zur Anaphase. Dieses Verhalten korreliert mit dem Verschwinden der zentralen Schicht der Kernstruktur zu Beginn der Centrosomenverdopplung. Somit ist CP91 mit großer Wahrscheinlichkeit ein Bestandteil dieser Schicht. CP91-Fragmente der N-terminalen bzw. C-terminalen Domäne (GFP-CP91 N-Terminus, GFP-CP91 C-Terminus) lokalisieren als GFP-Fusionsproteine exprimiert auch am Centrosom, zeigen aber nicht die gleiche mitotische Verteilung des Volllängenproteins. Das CP91-Fragment der zentralen Coiled-Coil Domäne (GFP-CP91cc) lokalisiert als GFP-Fusionsprotein exprimiert, als ein diffuser cytosolische Cluster, in der Nähe des Centrosoms. Es zeigt eine partiell ähnliche mitotische Verteilung wie das Volllängenprotein. Dies lässt eine regulatorische Domäne innerhalb der Coiled-Coil Domäne vermuten. Die Expression der GFP-Fusionsproteine unterdrückt die Expression des endogenen CP91 und bringt überzählige Centrosomen hervor. Dies war auch eine markante Eigenschaft nach der Unterexpression von CP91 durch RNAi. Zusätzlich zeigte sich in CP91-RNAi Zellen eine stark erhöhte Ploidie verursacht durch schwere Defekte in der Chromosomensegregation verbunden mit einer erhöhten Zellgröße und Defekten im Abschnürungsprozess während der Cytokinese. Die Unterexpression von CP91 durch RNAi hatte auch einen direkten Einfluss auf die Menge an den centrosomalen Proteinen CP39, CP55 und CEP192 und dem Centromerprotein Cenp68 in der Interphase. Die Ergebnisse deuten darauf hin, dass CP91 eine zentrale centrosomale Kernkomponente ist und für den Zusammenhalt der beiden äußeren Schichten der Kernstruktur benötigt wird. Zudem spielt CP91 eine wichtige Rolle für eine ordnungsgemäße Centrosomenbiogenese und, unabhängig davon, bei dem Abschnürungsprozess der Tochterzellen während der Cytokinese.
N2  - The Dictyostelium centrosome is a model for acentriolar centrosomes and it consists of a three-layered core structure surrounded by a corona harboring microtubule nucleation complexes. Its core structure duplicates once per cell cycle at the G2/M transition. Through proteomic analysis of isolated centrosomes we have identified CP91, a 91-kDa coiled coil protein that was localized at the centrosomal core structure. While GFP-CP91 showed almost no mobility in FRAP experiments during interphase, both GFP-CP91 and endogenous CP91 dissociated during mitosis and were absent from spindle poles from late prophase to anaphase. Since this behavior correlates with the disappearance of the central layer upon centrosome duplication, CP91 is a putative component of this layer. When expressed as GFP-fusions, CP91 fragments corresponding to the N-terminal and C-terminal domain (GFP-CP91N, and GFP-CP91C respectively) also localized to the centrosome but did not show the mitotic redistribution of the full length protein. The CP91 fragment corresponding to the central coiled coil domain (GFP-CP91cc) localized as a diffuse cluster close to the centrosome and did show a partially similar mitotic redistribution of the full length protein suggesting a regulatory role of the coiled coil domain. Expression of all GFP-fusion proteins suppressed expression of endogenous CP91 and elicited supernumerary centrosomes. This was also very prominent upon depletion of CP91 by RNAi. CP91-RNAi cells exhibited heavily increased ploidy due to severe defects in chromosome segregation along with increased cell size and defects in the abscission process during cytokinesis. Additionally, depletion of CP91 by RNAi had an immediate impact on the amount of the centrosomal core components CP39, CP55 and CEP192 and the centromere protein Cenp68 in interphase cells. Our results indicate that CP91 is a central centrosomal core component required for centrosomal integrity, proper centrosome biogenesis and, independently, for abscission during cytokinesis.
KW  - Centrosom
KW  - Dictyostelium
KW  - Mikrotubuli
KW  - Mitose
KW  - Zellkern
KW  - centrosome
KW  - dictyostelium
KW  - microtubules
KW  - mitosis
KW  - nucleus
Y1  - 2016
U6  - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:kobv:517-opus4-394689
ER  - 
TY  - THES
A1  - Bringmann, Martin
T1  - Identification of novel components that connect cellulose synthases to the cytoskeleton
T1  - Identifikation neuer Proteine als Bindeglieder zwischen den Zellulosesynthasen und dem Zytoskelett
N2  - Cellulose is the most abundant biopolymer on earth and the main load-bearing structure in plant cell walls. Cellulose microfibrils are laid down in a tight parallel array, surrounding plant cells like a corset. Orientation of microfibrils determines the direction of growth by directing turgor pressure to points of expansion (Somerville et al., 2004). Hence, cellulose deficient mutants usually show cell and organ swelling due to disturbed anisotropic cell expansion (reviewed in Endler and Persson, 2011). How do cellulose microfibrils gain their parallel orientation? First experiments in the 1960s suggested, that cortical microtubules aid the cellulose synthases on their way around the cell (Green, 1962; Ledbetter and Porter, 1963). This was proofed in 2006 through life cell imaging (Paredez et al., 2006). However, how this guidance was facilitated, remained unknown. Through a combinatory approach, including forward and reverse genetics together with advanced co-expression analysis, we identified pom2 as a cellulose deficient mutant. Map- based cloning revealed that the gene locus of POM2 corresponded to CELLULOSE SYNTHASE INTERACTING 1 (CSI1). Intriguingly, we previously found the CSI1 protein to interact with the putative cytosolic part of the primary cellulose synthases in a yeast-two-hybrid screen (Gu et al., 2010). Exhaustive cell biological analysis of the POM2/CSI1 protein allowed to determine its cellular function. Using spinning disc confocal microscopy, we could show that in the absence of POM2/CSI1, cellulose synthase complexes lose their microtubule-dependent trajectories in the plasma membrane. The loss of POM2/CSI1, however does not influence microtubule- dependent delivery of cellulose synthases (Bringmann et al., 2012). Consequently, POM2/CSI1 acts as a bridging protein between active cellulose synthases and cortical microtubules. This thesis summarizes three publications of the author, regarding the identification of proteins that connect cellulose synthases to the cytoskeleton. This involves the development of bioinformatics tools allowing candidate gene prediction through co-expression studies (Mutwil et al., 2009), identification of candidate genes through interaction studies (Gu et al., 2010), and determination of the cellular function of the candidate gene (Bringmann et al., 2012).
N2  - Zellulose ist das abundanteste Biopolymer der Erde und verleiht pflanzlichen Zellwänden ihre enorme Tragkraft. Mit der Reißfestigkeit von Stahl umwickeln Zellulosefibrillen pflanzliche Zellwände wie ein Korsett. Die Orientierung der Zellulosefibrillen bestimmt zugleich die Wachstumsrichtung, indem sie den Zellinnendruck (Turgor) in die entsprechende Ausdehnungsrichtung dirigiert (Somerville et al.,2004).Folglich zeigen Mutanten mit gestörter Zellulosesynthese oft geschwollene Organe und Zellen, die sich nicht mehr gerichtet ausdehnen können (zusammengefasst von Endler und Persson,2011). Wie aber erhalten die Zellulosefibrillen ihre parallele Orientierung? Erste Experimente aus den1960ern führten zur Vermutung, kortikale Mikrotubuli leiten die Zellulosesynthasen auf ringförmigen Bahnen um die Zellen herum (Green, 1962; Ledbetter and Porter, 1963). Diese Theorie wurde 2006 mit Hilfe moderner mikroskopischer Methoden bestätigt (Paredez et al., 2006). Wie jedoch dieser Leitmechanismus funktioniert, blieb bisher unentdeckt. Durch die Kombination verschiedener genetischer und bioinformatischer Methoden, konnten wir pom2 als Zellulose defiziente Mutante identifizieren. Die Ermittlung des Genlocus durch Map-based cloning zeigte, dass es sich bei POM2 um CELLULOSE SYNTHASE INTERACTING 1 (CSI1) handelt, ein Gen, dessen korrespondierendes Protein, wie vorher von uns gezeigt, mit dem zytosolischen Teil der primären Zellulosesynthasen interagiert (Gu et al., 2010). Durch ausführliche zellbiologische Charakterisierung von POM2/CSI1 konnten wir seine zelluläre Funktion entschlüsseln. Mit Hilfe konfokaler Spinning- Disc-Mikroskopie konnten wir zeigen, dass in Abwesenheit von POM2/CSI1, Zellulosesynthasen von den Mikrotubuli- Bahnen abweichen. Der ebenfalls von den Mikrotubuli abhängige Transport der Zellulosesynthasen zur Zellmembran hingegen, war nicht beeinflusst (Bringmann et al., 2012). Demzufolge ist POM2/CSI1 das gesuchte Bindeglied zwischen aktiven Zellulosesynthasen und Mikrotubuli. In dieser Dissertationsschrift werden drei Publikationen des Autors zusammengefasst, die wa ̈hrend der Arbeit an der Dissertiation entstanden sind. Sie beinhalten die Entwicklung bioinformatischer Methoden zur Ko- Expressionsanalyse, um Kandidatengene zu ermitteln (Mutwil et al., 2009), die Identifikaton des Kandidatengens POM2/CSI1 in einer Interaktionsstudie (Gu et al., 2010), sowie die Bestimmung der zellula ̈ren Funktion des korrespondieren- den Proteins POM2/CSI1 (Bringmann et al., 2012).
KW  - Zellwand
KW  - Zytoskelett
KW  - Mikrotubuli
KW  - CESA Komplex
KW  - Polysaccharide
KW  - cell wall
KW  - cytoskeleton
KW  - microtubules
KW  - cesa complex
KW  - polysaccharides
Y1  - 2012
U6  - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:kobv:517-opus-61478
ER  - 
TY  - GEN
A1  - Gräf, Ralph
T1  - Comparative Biology of Centrosomal Structures in Eukaryotes
T2  - Cells
N2  - The centrosome is not only the largest and most sophisticated protein complex within a eukaryotic cell, in the light of evolution, it is also one of its most ancient organelles. This special issue of "Cells" features representatives of three main, structurally divergent centrosome types, i.e., centriole-containing centrosomes, yeast spindle pole bodies (SPBs), and amoebozoan nucleus-associated bodies (NABs). Here, I discuss their evolution and their key-functions in microtubule organization, mitosis, and cytokinesis. Furthermore, I provide a brief history of centrosome research and highlight recently emerged topics, such as the role of centrioles in ciliogenesis, the relationship of centrosomes and centriolar satellites, the integration of centrosomal structures into the nuclear envelope and the involvement of centrosomal components in non-centrosomal microtubule organization.
KW  - centrosome
KW  - centriole
KW  - cilium
KW  - basal body
KW  - spindle pole body
KW  - SPB
KW  - nucleus-associated body
KW  - NAB
KW  - microtubules
Y1  - 2018
U6  - https://doi.org/10.3390/cells7110202
SN  - 2073-4409
VL  - 7
IS  - 11
PB  - MDPI
CY  - Basel
ER  - 
TY  - GEN
A1  - Gräf, Ralph
T1  - Comparative biology of centrosomal structures in eukaryotes
T2  - Postprints der Universität Potsdam : Mathematisch-Naturwissenschaftliche Reihe
N2  - The centrosome is not only the largest and most sophisticated protein complex within a eukaryotic cell, in the light of evolution, it is also one of its most ancient organelles. This special issue of "Cells" features representatives of three main, structurally divergent centrosome types, i.e., centriole-containing centrosomes, yeast spindle pole bodies (SPBs), and amoebozoan nucleus-associated bodies (NABs). Here, I discuss their evolution and their key-functions in microtubule organization, mitosis, and cytokinesis. Furthermore, I provide a brief history of centrosome research and highlight recently emerged topics, such as the role of centrioles in ciliogenesis, the relationship of centrosomes and centriolar satellites, the integration of centrosomal structures into the nuclear envelope and the involvement of centrosomal components in non-centrosomal microtubule organization.
T3  - Zweitveröffentlichungen der Universität Potsdam : Mathematisch-Naturwissenschaftliche Reihe - 1063 
KW  - centrosome
KW  - centriole
KW  - cilium
KW  - basal body
KW  - spindle pole body
KW  - SPB
KW  - nucleus-associated body
KW  - NAB
KW  - microtubules
Y1  - 2020
U6  - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:kobv:517-opus4-472294
SN  - 1866-8372
IS  - 1063
ER  - 
TY  - JOUR
A1  - Pitzen, Valentin
A1  - Askarzada, Sophie
A1  - Gräf, Ralph
A1  - Meyer, Irene
T1  - CDK5RAP2 Is an Essential Scaffolding Protein of the Corona of the Dictyostelium Centrosome
JF  - Cells
N2  - Dictyostelium centrosomes consist of a nucleus-associated cylindrical, three-layered core structure surrounded by a corona consisting of microtubule-nucleation complexes embedded in a scaffold of large coiled-coil proteins. One of them is the conserved CDK5RAP2 protein. Here we focus on the role of Dictyostelium CDK5RAP2 for maintenance of centrosome integrity, its interaction partners and its dynamic behavior during interphase and mitosis. GFP-CDK5RAP2 is present at the centrosome during the entire cell cycle except from a short period during prophase, correlating with the normal dissociation of the corona at this stage. RNAi depletion of CDK5RAP2 results in complete disorganization of centrosomes and microtubules suggesting that CDK5RAP2 is required for organization of the corona and its association to the core structure. This is in line with the observation that overexpressed GFP-CDK5RAP2 elicited supernumerary cytosolic MTOCs. The phenotype of CDK5RAP2 depletion was very reminiscent of that observed upon depletion of CP148, another scaffolding protein of the corona. BioID interaction assays revealed an interaction of CDK5RAP2 not only with the corona markers CP148, gamma-tubulin, and CP248, but also with the core components Cep192, CP75, and CP91. Furthermore, protein localization studies in both depletion strains revealed that CP148 and CDK5RAP2 cooperate in corona organization.
KW  - centrosome
KW  - centriole
KW  - Dictyostelium
KW  - microtubules
KW  - mitosis
Y1  - 2018
U6  - https://doi.org/10.3390/cells7040032
SN  - 2073-4409
VL  - 7
IS  - 4
PB  - MDPI
CY  - Basel
ER  - 
TY  - GEN
A1  - Krupinski, Pawel
A1  - Bozorg, Behruz
A1  - Larsson, André
A1  - Pietra, Stefano
A1  - Grebe, Markus
A1  - Jönsson, Henrik
T1  - A model analysis of mechanisms for radial microtubular patterns at root hair initiation sites
T2  - Frontiers in plant science
N2  - Plant cells have two main modes of growth generating anisotropic structures. Diffuse growth where whole cell walls extend in specific directions, guided by anisotropically positioned cellulose fibers, and tip growth, with inhomogeneous addition of new cell wall material at the tip of the structure. Cells are known to regulate these processes via molecular signals and the cytoskeleton. Mechanical stress has been proposed to provide an input to the positioning of the cellulose fibers via cortical microtubules in diffuse growth. In particular, a stress feedback model predicts a circumferential pattern of fibers surrounding apical tissues and growing primordia, guided by the anisotropic curvature in such tissues. In contrast, during the initiation of tip growing root hairs, a star-like radial pattern has recently been observed. Here, we use detailed finite element models to analyze how a change in mechanical properties at the root hair initiation site can lead to star-like stress patterns in order to understand whether a stress-based feedback model can also explain the microtubule patterns seen during root hair initiation. We show that two independent mechanisms, individually or combined, can be sufficient to generate radial patterns. In the first, new material is added locally at the position of the root hair. In the second, increased tension in the initiation area provides a mechanism. Finally, we describe how a molecular model of Rho-of-plant (ROP) GTPases activation driven by auxin can position a patch of activated ROP protein basally along a 2D root epidermal cell plasma membrane, paving the way for models where mechanical and molecular mechanisms cooperate in the initial placement and outgrowth of root hairs.
T3  - Zweitveröffentlichungen der Universität Potsdam : Mathematisch-Naturwissenschaftliche Reihe - 435 
KW  - plant cell wall
KW  - finite element modeling
KW  - computational morphodynamics
KW  - root hair initiation
KW  - microtubules
KW  - cellulose fibers
KW  - composite material
Y1  - 2018
U6  - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:kobv:517-opus4-407181
ER  - 
TY  - JOUR
A1  - Krupinski, Pawel
A1  - Bozorg, Behruz
A1  - Larsson, Andre
A1  - Pietra, Stefano
A1  - Grebe, Markus
A1  - Jönsson, Henrik
T1  - A Model Analysis of Mechanisms for Radial Microtubular Patterns at Root Hair Initiation Sites
JF  - Frontiers in plant science
N2  - Plant cells have two main modes of growth generating anisotropic structures. Diffuse growth where whole cell walls extend in specific directions, guided by anisotropically positioned cellulose fibers, and tip growth, with inhomogeneous addition of new cell wall material at the tip of the structure. Cells are known to regulate these processes via molecular signals and the cytoskeleton. Mechanical stress has been proposed to provide an input to the positioning of the cellulose fibers via cortical microtubules in diffuse growth. In particular, a stress feedback model predicts a circumferential pattern of fibers surrounding apical tissues and growing primordia, guided by the anisotropic curvature in such tissues. In contrast, during the initiation of tip growing root hairs, a star-like radial pattern has recently been observed. Here, we use detailed finite element models to analyze how a change in mechanical properties at the root hair initiation site can lead to star-like stress patterns in order to understand whether a stress-based feedback model can also explain the microtubule patterns seen during root hair initiation. We show that two independent mechanisms, individually or combined, can be sufficient to generate radial patterns. In the first, new material is added locally at the position of the root hair. In the second, increased tension in the initiation area provides a mechanism. Finally, we describe how a molecular model of Rho-of-plant (ROP) GTPases activation driven by auxin can position a patch of activated ROP protein basally along a 2D root epidermal cell plasma membrane, paving the way for models where mechanical and molecular mechanisms cooperate in the initial placement and outgrowth of root hairs.
KW  - plant cell wall
KW  - finite element modeling
KW  - computational morphodynamics
KW  - root hair initiation
KW  - microtubules
KW  - cellulose fibers
KW  - composite material
Y1  - 2016
U6  - https://doi.org/10.3389/fpls.2016.01560
SN  - 1664-462X
VL  - 7
PB  - Frontiers Research Foundation
CY  - Lausanne
ER  -