Your search keyword '"Hotulainen, Pirta"' showing total 9 results

1. Actin polymerization and longitudinal actin fibers in axon initial segment plasticity.

Author

Micinski, David and Hotulainen, Pirta

Subjects

ACTIN, ACTION potentials, AXONS, CYTOSKELETON, FIBERS, DENDRITIC spines

Abstract

The location of the axon initial segment (AIS) at the junction between the soma and axon of neurons makes it instrumental in maintaining neural polarity and as the site for action potential generation. The AIS is also capable of largescale relocation in an activity-dependent manner. This represents a form of homeostatic plasticity in which neurons regulate their own excitability by changing the size and/or position of the AIS. While AIS plasticity is important for proper functionality of AIS-containing neurons, the cellular and molecular mechanisms of AIS plasticity are poorly understood. Here, we analyzed changes in the AIS actin cytoskeleton during AIS plasticity using 3D structured illumination microscopy (3D-SIM). We showed that the number of longitudinal actin fibers increased transiently 3 h after plasticity induction. We further showed that actin polymerization, especially formin mediated actin polymerization, is required for AIS plasticity and formation of longitudinal actin fibers. From the formin family of proteins, Daam1 localized to the ends of longitudinal actin fibers. These results indicate that active re-organization of the actin cytoskeleton is required for proper AIS plasticity. [ABSTRACT FROM AUTHOR]

Published

2024

2. ASD-Associated De Novo Mutations in Five Actin Regulators Show Both Shared and Distinct Defects in Dendritic Spines and Inhibitory Synapses in Cultured Hippocampal Neurons.

Author

Hlushchenko, Iryna, Khanal, Pushpa, Abouelezz, Amr, Paavilainen, Ville O., and Hotulainen, Pirta

Subjects

AUTISM spectrum disorders, ACTIN, SYNAPSES, HIPPOCAMPAL innervation, DENDRITIC spines

Abstract

Many actin cytoskeleton-regulating proteins control dendritic spine morphology and density, which are cellular features often altered in autism spectrum disorder (ASD). Recent studies using animal models show that autism-related behavior can be rescued by either manipulating actin regulators or by reversing dendritic spine density or morphology. Based on these studies, the actin cytoskeleton is a potential target pathway for developing new ASD treatments. Thus, it is important to understand how different ASD-associated actin regulators contribute to the regulation of dendritic spines and how ASD-associated mutations modulate this regulation. For this study, we selected five genes encoding different actin-regulating proteins and induced ASD-associated de novo missense mutations in these proteins. We assessed the functionality of the wild-type and mutated proteins by analyzing their subcellular localization, and by analyzing the dendritic spine phenotypes induced by the expression of these proteins. As the imbalance between excitation and inhibition has been suggested to have a central role in ASD, we additionally evaluated the density, size and subcellular localization of inhibitory synapses. Common for all the proteins studied was the enrichment in dendritic spines. ASD-associated mutations induced changes in the localization of a-actinin-4, which localized less to dendritic spines, and for SWAP-70 and SrGAP3, which localized more to dendritic spines. Among the wild-type proteins studied, only a-actinin-4 expression caused a significant change in dendritic spine morphology by increasing the mushroom spine density and decreasing thin spine density. We hypothesized that mutations associated with ASD shift dendritic spine morphology from mushroom to thin spines. An M554V mutation in a-actinin-4 (ACTN4) resulted in the expected shift in dendritic spine morphology by increasing the density of thin spines. In addition, we observed a trend toward higher thin spine density withmutations inmyosin IXb and SWAP-70. Myosin IIb and myosin IXb expression increased the proportion of inhibitory synapses in spines. The expression of mutated myosin IIb (Y265C), SrGAP3 (E469K), and SWAP-70 (L544F) induced variable changes in inhibitory synapses. [ABSTRACT FROM AUTHOR]

Published

2018

3. Actin in dendritic spines: connecting dynamics to function.

Author

Hotulainen, Pirta and Hoogenraad, Casper C.

Subjects

*ACTIN, *SKELETON, *DENDRITES, *SYNAPSES, *CYTOSKELETON, *LEARNING, *MEMORY

Abstract

Dendritic spines are small actin-rich protrusions from neuronal dendrites that form the postsynaptic part of most excitatory synapses and are major sites of information processing and storage in the brain. Changes in the shape and size of dendritic spines are correlated with the strength of excitatory synaptic connections and heavily depend on remodeling of its underlying actin cytoskeleton. Emerging evidence suggests that most signaling pathways linking synaptic activity to spine morphology influence local actin dynamics. Therefore, specific mechanisms of actin regulation are integral to the formation, maturation, and plasticity of dendritic spines and to learning and memory. [ABSTRACT FROM AUTHOR]

Published

2010

4. Defining mechanisms of actin polymerization and depolymerization during dendritic spine morphogenesis.

Author

Hotulainen, Pirta, Llano, Olaya, Smirnov, Sergei, Tanhuanpää, Kimmo, Faix, Jan, Rivera, Claudio, and Lappalainen, Pekka

Subjects

*DENDRITIC cells, *ACTIN, *POLYMERIZATION, *CYTOPLASMIC filaments, *GUANOSINE triphosphatase, *SPINE, *NEURAL transmission

Abstract

Dendritic spines are small protrusions along dendrites where the postsynaptic components of most excitatory synapses reside in the mature brain. Morphological changes in these actin-rich structures are associated with learning and memory formation. Despite the pivotal role of the actin cytoskeleton in spine morphogenesis, little is known about the mechanisms regulating actin filament polymerization and depolymerization in dendritic spines. We show that the filopodia-like precursors of dendritic spines elongate through actin polymerization at both the filopodia tip and root. The small GTPase Rif and its effector mDia2 formin play a central role in regulating actin dynamics during filopodia elongation. Actin filament nucleation through the Arp2/3 complex subsequently promotes spine head expansion, and ADF/cofilin-induced actin filament disassembly is required to maintain proper spine length and morphology. Finally, we show that perturbation of these key steps in actin dynamics results in altered synaptic transmission. [ABSTRACT FROM AUTHOR]

Published

2009

5. Characterization of the interaction between Actinin-Associated LIM Protein (ALP) and the rod domain of α-actinin.

Author

Klaavuniemi, Tuula, Alho, Nanna, Hotulainen, Pirta, Kelloniemi, Annina, Havukainen, Heli, Permi, Perttu, Mattila, Sampo, and Ylänne, Jari

Subjects

PROTEINS, ACTIN, CROSSLINKING (Polymerization), SURFACE plasmon resonance, NUCLEAR magnetic resonance

Abstract

Background: The PDZ-LIM proteins are a family of signalling adaptors that interact with the actin cross-linking protein, α-actinin, via their PDZ domains or via internal regions between the PDZ and LIM domains. Three of the PDZ-LIM proteins have a conserved 26-residue ZM motif in the internal region, but the structure of the internal region is unknown. Results: In this study, using circular dichroism and nuclear magnetic resonance (NMR), we showed that the ALP internal region (residues 107-273) was largely unfolded in solution, but was able to interact with the α-actinin rod domain in vitro, and to co-localize with α-actinin on stress fibres in vivo. NMR analysis revealed that the titration of ALP with the α-actinin rod domain induces stabilization of ALP. A synthetic peptide (residues 175-196) that contained the N-terminal half of the ZM motif was found to interact directly with the α-actinin rod domain in surface plasmon resonance (SPR) measurements. Short deletions at or before the ZM motif abrogated the localization of ALP to actin stress fibres. Conclusion: The internal region of ALP appeared to be largely unstructured but functional. The ZM motif defined part of the interaction surface between ALP and the α-actinin rod domain. [ABSTRACT FROM AUTHOR]

Published

2009

6. The Role of Protein Arginine Methylation as Post-Translational Modification on Actin Cytoskeletal Components in Neuronal Structure and Function.

Author

Qualmann, Britta, Kessels, Michael M., Rust, Marco, and Hotulainen, Pirta

Subjects

CYTOSKELETAL proteins, POST-translational modification, DENDRITIC spines, PROTEIN arginine methyltransferases, ACTIN, ARGININE, METHYLATION

Abstract

The brain encompasses a complex network of neurons with exceptionally elaborated morphologies of their axonal (signal-sending) and dendritic (signal-receiving) parts. De novo actin filament formation is one of the major driving and steering forces for the development and plasticity of the neuronal arbor. Actin filament assembly and dynamics thus require tight temporal and spatial control. Such control is particularly effective at the level of regulating actin nucleation-promoting factors, as these are key components for filament formation. Arginine methylation represents an important post-translational regulatory mechanism that had previously been mainly associated with controlling nuclear processes. We will review and discuss emerging evidence from inhibitor studies and loss-of-function models for protein arginine methyltransferases (PRMTs), both in cells and whole organisms, that unveil that protein arginine methylation mediated by PRMTs represents an important regulatory mechanism in neuritic arbor formation, as well as in dendritic spine induction, maturation and plasticity. Recent results furthermore demonstrated that arginine methylation regulates actin cytosolic cytoskeletal components not only as indirect targets through additional signaling cascades, but can also directly control an actin nucleation-promoting factor shaping neuronal cells—a key process for the formation of neuronal networks in vertebrate brains. [ABSTRACT FROM AUTHOR]

Published

2021

7. The initiation of post-synaptic protrusions.

Author

Hotulainen, Pirta and Saarikangas, Juha

Subjects

*DENDRITES, *POLYMERIZATION, *FIBERS, *CELL membranes, *ACTIN

Abstract

The post-synaptic spines of neuronal dendrites are highly elaborate membrane protrusions. Their anatomy, stability and density are intimately linked to cognitive performance. The morphological transitions of spines are powered by coordinated polymerization of actin filaments against the plasma membrane, but how the membrane-associated polymerization is spatially and temporally regulated has remained ill defined. Here, we discuss our recent findings showing that dendritic spines can be initiated by direct membrane bending by the I-BAR protein MIM/Mtss1. This lipid phosphatidylinositol (PI(4,5)P2) signaling-activated membrane bending coordinated spatial actin assembly and promoted spine formation. From recent advances, we formulate a general model to discuss how spatially concentrated protein-lipid microdomains formed by multivalent interactions between lipids and actin/membrane regulatory proteins might launch cell protrusions. [ABSTRACT FROM PUBLISHER]

Published

2016

8. Contractility-dependent actin dynamics in cardiomyocyte sarcomeres.

Author

Skwarek-Maruszewska, Aneta, Hotulainen, Pirta, Mattila, Pieta K., and Lappalainen, Pekka

Subjects

*ACTIN, *HEART cells, *POLYMERIZATION, *CYTOSKELETON, *BIOMOLECULES, *CYTOPLASM, *MEDICAL research

Abstract

In contrast to the highly dynamic actin cytoskeleton in non-muscle cells, actin filaments in muscle sarcomeres are thought to be relatively stable and undergo dynamics only at their ends. However, many proteins that promote rapid actin dynamics are also expressed in striated muscles. We show that a subset of actin filaments in cardiomyocyte sarcomeres displays rapid turnover. Importantly, we found that turnover of these filaments depends on contractility of the cardiomyocytes. Studies using an actin-polymerization inhibitor suggest that the pool of dynamic actin filaments is composed of filaments that do not contribute to contractility. Furthermore, we provide evidence that ADF/cofilins, together with myosin-induced contractility, are required to disassemble non-productive filaments in developing cardiomyocytes. These data indicate that an excess of actin filaments is produced during sarcomere assembly, and that contractility is applied to recognize non-productive filaments that are subsequently destined for depolymerization. Consequently, contractility-induced actin dynamics plays an important role in sarcomere maturation. [ABSTRACT FROM AUTHOR]

Published

2009

9. A Molecular Pathway for Myosin II Recruitment to Stress Fibers

Author

Tojkander, Sari, Gateva, Gergana, Schevzov, Galina, Hotulainen, Pirta, Naumanen, Perttu, Martin, Claire, Gunning, Peter W., and Lappalainen, Pekka

Subjects

*MYOSIN, *CELL migration, *MORPHOGENESIS, *ACTIN, *CELL membranes, *TROPOMYOSINS

Abstract

Summary: Background: Cell migration and morphogenesis are driven by both protrusive and contractile actin filament structures. The assembly mechanisms of lamellipodial and filopodial actin filament arrays, which provide the force for plasma membrane protrusions through actin filament treadmilling, are relatively well understood. In contrast, the mechanisms by which contractile actomyosin arrays such as stress fibers are generated in cells, and how myosin II is specifically recruited to these structures, are not known. Results: We demonstrate that four functionally distinct tropomyosins are required for assembly of stress fibers in cultured osteosarcoma cells. Tm1, Tm2/3, and Tm5NM1/2 stabilize actin filaments at distinct stress fiber regions. In contrast, Tm4 promotes stress fiber assembly by recruiting myosin II to stress fiber precursors. Elimination of any one of the tropomyosins fatally compromises stress fiber formation. Importantly, Dia2 formin is critical to stress fiber assembly by nucleating Tm4-decorated actin filaments at the cell cortex. Myosin II is specifically recruited through a Tm4-dependent mechanism to the Dia2-nucleated filaments, which subsequently assemble endwise with Arp2/3-nucleated actin filament structures to yield contractile stress fibers. Conclusions: These experiments identified a pathway, involving Dia2- and Arp2/3-promoted actin filament nucleation and several functionally distinct tropomyosins, that is required for generation of contractile actomyosin arrays in cells. [ABSTRACT FROM AUTHOR]

Published

2011