Cytoskeleton Locomotion Kohidai Laszlo MD Ph D Med
- Slides: 71
Cytoskeleton - Locomotion Kohidai, Laszlo MD, Ph. D Med. habil. , Assoc. Professor Dept. Genetics, Cell & Immunobiology, Semmelweis University Ecelctive Course / 2017 www. dgci. sote. hu
Main functions of cytoskeleton • • Determines the shape of the cell Anchores organelles Movement of organelles Tensile strength Movement of chromosomes Polarity Motility
Cytoskeleton Microfilaments (actin) l Microtubuli (tubulin) l Intermedier filaments l l Microtubule associated proteins (MAP-s) Motor proteins
Microfilaments Microtubuli Intermedier filaments
SLIDING Globular proteins Ca 2+ ATP Fibrillar proteins Motor proteins
Microfilaments
Polymerization of actin ADP + ATP Depolymerization ADP ATP cytochalasin – inh. phalloidin - stabilizer Pi Polymerization - slow
Actin - still in Prokaryots ! ((Ent et al. Nature 2001, 413, 39)
Cyclosis Moving cytoplasm Stationary (cortical) cytoplasm Plasma membrane Cell-wall Actin filaments Chloroplasts l Transitional connections between actin and myosin l Ca 2+, temperature- and p. H-dependent (Lodish, H. et al. Mol. Cell Biol. 2000, 767)
„Fountain” mechanism Ca 2+-dep. requires ATP Formation of pseudopodium stress-fibrillums integrins Mono. Poly. Lobo- podial Filo. Reticulo-
Cross-linking proteins of actin contractile bundle a actinin – in stress fibr. gel-like network filamin - cortex „tight” parallel bundle fimbrin – in filopodium
Migrating keratinocyte 15 mm/sec Formation of lobopodium actin-network microtubuli
Regulator proteins of actin polymerisation g. CAP 39 Tropomodulin + - Cofilin Severin Gelsolin Villin Cap. Z
Actin polymerisation – acrosomal-reaction (Lodish, H. et al. Mol. Cell Biol. 2000, 767)
Listeria monocytogenes • local actin polymerization • speed: 10 mm/min • high ability to transmit in tissues actin (Fred Soo & Julie Theriot Laboratory)
Model of actin nucleation WASP = Wiscott-Aldrich syndr. prot.
Structure of cortical region (Svitkina, TM, Borisy GG J. Cell Biol. 1999, 145, 1009)
Actin – membrane links membrane Myozin I. Arp 2/3 F-Actin Profilin - G-aktin Filamin Integrin
Profilin-mechanism Tb 4 = timozin b 4 Proline-rich protein (Lodish, H. et al. Mol. Cell Biol. 2000, 767)
Filamin – Membrane link filamin actin
Structure of focal contact actin filament a actinin vinculin + integrin paxillin talin fibronectin
A plasma membrane – cortex links Thrombocyte Glycophorin Ankyrin Spectrin tetramer Muscle Epithel ((Lux SE, 1979 Nature 281: 426)
E Electromagnetic field induces the transformation of cytoskeleton and formation of pseudopodia - Adhesion plaque ++ + -
head Myosin Ca 2+-dependent phosphorylation and its effect on the 3 D strcture light chain heavy chain a helix ATP - ADP Pi myosin I. 150 k. D monomer myosin I I. 260 k. D dimer Head: - ATP-ase - motor
Distribution of myosines in the migrating Dyctiostelium and in dividing cell myozin I. (green) myozin II. (red) (Fukui, Y. Mol. Cell Biol 2000, 785))
- + Main types of interactions between the globular and fibrillar components of cytoskeleton membrane
Non-treated F-actin blocked MT-blocked
Microtubules
Tubulin – still in Prokaryotes ! Fts. Z Tubulin (Margolin Laboratory, University of Texas)
Polymerization of tubulin GTP GTP Polymerization - fast Protofilament (strait) GDP GDP Protofilament (curved) GDP Depolymerization
Dynamics of microtubule-assembly Nucleation Elongation + incorporation balanced release -
Role of g-tubulin in nucleation (Wiease et al. Curr. Opin. Struct. Biol. 1999, 9, 250)
Microtubular systems in the cells Interphase cell centrosome Cilla Basal body - Centrosome Dividing cell spindle - Cilia / flagellum - Mitotic system - Vesicular transport Neuron centrosome axon
MTOC = Mikrotubul organizing center g-tubulin specialized region of the cortex ((Brinkley, B. R. Encyclop. Neurosci. 1987, 665)
Network of microtubuli 24 nm ab dimer Protofilaments a tubulin b tubulin Fibroblast
Cilia cilia flagellum Paramecium
tubulin (13 ill. 11 protofilaments) B A dynein-arms nexin
Composition of dynein-arms ATP-independent binding ATP-dependent hydrolisis The arm moves toward the - pole
The role of dynein arms in beating of cilia Bending „Telescoping” Proteolysis
Molecules composing the cilia more than 250 types of molecules 70% a and b tubulin l dynein arms outer - 9 polypeptides - ATP-ase inner – composition varies l radial spokes - 17 polypeptides l
Microtubules of mitotic spindle and kinetochore
Arrangement of actin during cell-division
Intermedier filaments
Mechanical characterization of cytoskeleton components intermedier filament i. e. vimentin deformation microtubule = rupture actin filament force
Role of intermedier filaments Buffer against external mechanical stress Tissue specificity Nucleus – lamines (lamina fibrosa) Epithel – keratin Connective tissue Muscles Neuroglia } vimentin Neurones - neurofilaments
Structure of intermedier filamentums (Lodish, H. et al. Mol. Cell Biol. 2000, 767)
Domain structures of intermedier filamentums H 2 N- a helical domain keratins vimentin neurofilam. prot. nuclear prot -COOH
Intermedier filaments Keratin filaments Vimentin-like filaments ! They DO NOT co-polymerise !
Microvilli actin myosin I. villin „terminal web” • a rigid bundle composed by 20 -30 actin mol. s • actin + on the apical part • villin is the linker molecule of actins • „terminal web” = intermed. fil. + spectrin • myosin I. and calmodulin anchore to the surface membrane
SEM structure of microvilli actin bundle linker molecules „terminal web”
Intermedier filaments Glial filaments Neuro-filaments – many cross-linkers – few cross-linkers The number of protein cross-links between the intermedier filaments varies in different tissues
Microtubuli associated proteins (MAP-s)
Groups of MAP-s • Structural MAP-s - MT-assembly - links to MF and to IF • Motor proteins - sliding on MT • Shape and polarity of the cell Membrane transports Enzymes, signal molecules - glycolytic enzymek - kinases Assembly of molecules
Motor-proteins
Structure of motor-proteins asszoc. motor domain polypeptides motor domain „stalk” asszoc. polypeptides Kinesin „stalk” asszoc. polypeptides Myozin Dynein
Motor proteins - + microtubule heavy chain light chain kinesin dynein
kinesin - + dynein c. AMP pigment cells c. AMP
Kinesin ADP ATP ADP-Pi
MT-motor proteins and the transported elements (Hirokawa, N. Science 1998, 279: 519
Dynein – membrane relations (Hirokawa, N. Science 1998, 279: 519)
There are other mechanisms over sliding …
Locomotion – with spasmoneme of Vorticella
Spasmoneme spring Contracts 40% in few msecs Velocity: 8 cm˛/sec Negative charges Neutralization with Ca 2+
Actin spring in sperm of horseshoe crab Limulus polyphemus acrosome actin bundle • The extension does not involve a myosin motor or actin polymerization • The bundle is crystalline in its coiled and uncoiled states !
Signalling mechanisms – In a nutshell –
Polymerization of microtubules Significance of motor proteins
Ameboid movement and microtubules
Complex effects of focal adhesion kinase (FAK)
LIM domains of proteins
Central role of vimentin in signalling mechanisms of cytoskeleton
Phosphatases and cell migration
- Kuranda tedvir ne demek
- Cytoskeleton look like
- Composition of cytoskeleton
- Commassie
- Prokaryotes and eukaryotes
- Cytoskeleton organelles
- Cytoskeleton analogy school
- Chloroplast function
- Analogy of rough endoplasmic reticulum
- Difference between prokaryote and eukaryotes
- Cytoskeleton look like
- Intermediate filament tetramer
- Cytoskeleton
- Cytoskeleton nickname
- Cytoskeleton
- Treadmilling microtubules
- Cytoskeleton prokaryotic or eukaryotic
- Structure and function of cytoskeleton
- Phylum apicomplexa characteristics
- Vorticella locomotion
- Locomotion and support
- Carl schissler
- Phylum porifera locomotion
- Balistiform
- Enumerate the locomotor and axial movement
- Locomotion by jacqueline woodson summary
- Characteristics of protists
- Locomotion
- Reptiles organs for locomotion
- Hirudinea locomotion
- Tarsier locomotion
- Types of locomotion in fish
- Fish locomotion types
- Eukaryotic cells
- Reptiles organs for locomotion
- Chapter 34 protection support and locomotion
- Autotroph
- Locomotion and support
- Locomotion of archaebacteria
- Reptiles organs for locomotion
- Wheeled locomotion
- Reptiles organs for locomotion
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- Laszlo systems
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