The distribution of cofilin and DNase I in vivo

Actin is the principal component of the cytoskeleton, a structure that can be disassembled and reassembled in a matter of seconds in vivo. The state of assembly of actin in vivo is primarily regulated by one or more actin binding proteins (ABPs). Typically, the actions of ABPs have been studied one by one, however, we propose that multiple ABPs, acting cooperatively, may be involved in the control of actin filament length. Cofilin and DNase I are two ABPs that have previously been demonstrated to form a ternary complex with actin in vitro. This is the first report to demonstrate their co-localisation in vivo, and differences in their distributions. Our observations strongly suggest a physiological role for higher order complexes of actin in regulation of cytoskeletal assembly during processes such as cell division.     

The distribution of cofilin and DNase I in vivo

Actin is the principal component of the cytoskeleton, a structure that can be disassembled and reassembled in a matter of seconds in vivo. The state of assembly of actin in vivo is primarily regulated by one or more actin binding proteins (ABPs). Typically, the actions of ABPs have been studied one by one, however, we propose that multiple ABPs, acting cooperatively, may be involved in the control of actin filament length. Cofilin and DNase I are two ABPs that have previously been demonstrated to form a ternary complex with actin in vitro. This is the first report to demonstrate their co-localisation in vivo, and differences in their distributions. Our observations strongly suggest a physiological role for higher order complexes of actin in regulation of cytoskeletal assembly during processes such as cell division.     

The distribution of cofilin and Dnase I in vivo

Actin is the principal component of the cytoskeleton, a structure that can be disassembled and reassem-bled in a matter of seconds in vivo. The state of assembly of actin in vivo is primarily regulated by one ormore actin binding proteins (ABPs). Typically, the actions of ABPs have been studied one by one, however,we propose that multiple ABPs, acting cooperatively, may be involved in the control of actin filament length.Cofilin and DNase I are two ABPs that have previously been demonstrated to form a ternary complex withactin in vitro. This is the first report to demonstrate their co-localisation in vivo, and differences in theirdistributions. Our observations strongly suggest a physiological role for higher order complexes of actin inregulation of cytoskeletal assembly during processes such as cell division.     

A review of actin binding proteins: new perspectives

Actin binding proteins (ABPs) have been considered components of the cytoskeleton, which gives structure and allows mobility of the cell. The complex dynamic properties of the actin cytoskeleton are regulated at multiple levels by a variety of proteins that control actin polymerization, severing of actin filaments and cross-linking of actin filaments into networks, which may be used by molecular motors. Proteins that cross-link F-actin are important for the maintenance of the viscoelastic properties of the cytoplasm and for the integrity of plasma membrane-associated macromolecules. Most of these F-actin cross-linking proteins have an actin-binding domain homologous to calponin. In addition, some of them have been considered scaffolds. Through the years, several research groups have found different proteins that interact with ABPs; however, the effect of these interactions on ABPs remains mostly unknown. In addition to organize the cytoskeletal structure, recent data indicate that ABPs can also migrate to the nucleus. This fact is in agreement and could be relevant to the recently found role that actin might play in nuclear function. Recent data and analysis of published results have also indicated that scaffold proteins like filamin A (FLNa) may be processed by proteolysis and that the degradation products generated by this reaction may play a role as signaling molecules, integrating nuclear and cytosolic pathways. Some of the relevant information in this area is reviewed here.     

Microscopy basics and the study of actin–actin-binding protein interactions

Actin is a multifunctional eukaryotic protein with a globular monomer form that polymerizes into a thin, linear microfilament in cells. Through interactions with various actin-binding proteins (ABPs), actin plays an active role in many cellular processes, such as cell motility and structure. Microscopy techniques are powerful tools for determining the role and mechanism of actin–ABP interactions in these processes. In this article, we describe the basic concepts of fluorescent speckle microscopy, total internal reflection fluorescence microscopy, atomic force microscopy, and cryoelectron microscopy and review recent studies that utilize these techniques to visualize the binding of actin with ABPs.     

Actin-binding proteins--a unifying hypothesis

Actin participates in more protein-protein interactions than any other known protein, including the interaction of actin with itself to form the helical polymer F-actin. The vast majority of actin-binding proteins (ABPs) can be grouped into conserved families. Only a handful of structures of complexes of actin with ABPs have been determined so far. These structures are starting to reveal how certain ABPs, including gelsolin, vitamin D-binding protein and Wiskott-Aldrich syndrome protein (WASP)-homology domain-2-related proteins, share a common actin-binding motif. It is proposed here that other ABPs, including actin itself, might share this motif, providing a mechanism whereby ABPs and actin compete for a common binding site. Of particular interest is a hydrophobic pocket that mediates important interactions in five of the existing structures of actin complexes. As the pocket remains accessible in F-actin, it is proposed that this pocket represents a primary target for F-actin-binding proteins, such as calponin-homology-related proteins and myosin.     

Nuclear spectrin-like proteins are structural actin-binding proteins in plants

Background information. Although actin is a relevant component of the plant nucleus, only three nuclear ABPs (actin‐binding proteins) have been identified in plants to date: cofilin, profilin and nuclear myosin I. Although plants lack orthologues of the main structural nuclear ABPs in animals, such as lamins, lamin‐associated proteins and nesprins, their genome does contain sequences with spectrin repeats and N‐terminal calponin homology domains for actin binding that might be distant relatives of spectrin. We investigated here whether spectrin‐like proteins could act as structural nuclear ABPs in plants. Results. We have investigated the presence of spectrins in Allium cepa meristematic nuclei by Western blotting, confocal and electron microscopy, using antibodies against α‐ and β‐spectrin chains that cross‐react in plant nuclei. Their role as nuclear ABPs was analysed by co‐immunoprecipitation and IF (immunofluorescence) co‐localization and their association with the nuclear matrix was investigated by sequential extraction of nuclei with non‐ionic detergent, and in low‐ and high‐salt buffers after nuclease digestion. Our results demonstrate the existence of several spectrin‐like proteins in the nucleus of onion cells that have different intranuclear distributions in asynchronous meristematic populations and associate with the nuclear matrix. These nuclear proteins co‐immunoprecipitate and co‐localize with actin. Conclusions. These results reveal that the plant nucleus contains spectrin‐like proteins that are structural nuclear components and function as ABPs. Their intranuclear distribution suggests that plant nuclear spectrin‐like proteins could be involved in multiple nuclear functions.     

Actin-Binding Proteins in Plant Cells

Abstract: Actinoccurs in all plant cells, as monomers, filaments and filament assemblies. In interphase, actin filaments form a cortical network, co-align with cortical microtubules, and extend throughout the cytoplasm functioning in cytoplasmic streaming. During mitosis, they co-align with microtubules in the preprophase band and phragmoplast and are indispensa ble for cell division. Actin filaments continually polymerise and depolymerise from a pool of monomers, and signal transduction pathways affecting cell morphogenesis modify the actin cytoskeleton. The interactions of actin monomers and filaments with actin-binding proteins (ABP5) control actin dynamics. By binding to actin monomers, ABPs, such as profilin, regulate the pool of monomers available for polymerisation. By breaking filaments or capping filament ends, ABPs, such as actin depoly-merising factor (ADF), prevent actin filament elongation or loss of monomers from filament ends. By bivalent cross-linking to actin filaments, ABPs, such as fimbrin and other members of the spectrin family, produce a variety of higher order assemblies, from bundles to networks. The motor protein ABPs,. which are not covered in this review, move organelles along ac tin filaments. The large variety of ABPs share a number of functional modules. A plant representative of ABPs with particular modules, and therefore particular functions, is treated in this review.     

Molecular dynamics study of interactions between polymorphic actin filaments and gelsolin segment-1

The assembly of protein actin into double-helical filaments promotes many eukaryotic cellular processes that are regulated by actin-binding proteins (ABPs). Actin filaments can adopt multiple conformations, known as structural polymorphism, which possibly influences the interaction between filaments and ABPs. Gelsolin is a Ca²⁺-regulated ABP that severs and caps actin filaments. Gelsolin binding modulates filament structure; however, it is not known how polymorphic actin filament structures influence an interaction of gelsolin S1 with the barbed-end of filament. Herein, we investigated how polymorphic structures of actin filaments affect the interactions near interfaces between the gelsolin segment 1 (S1) domain and the filament barbed-end. Using all-atom molecular dynamics simulations, we demonstrate that different tilted states of subunits modulate gelsolin S1 interactions with the barbed-end of polymorphic filaments. Hydrogen bonding and interaction energy at the filament-gelsolin S1 interface indicate distinct conformations of filament barbed ends, resulting in different interactions of gelsolin S1. This study demonstrates that filament's structural multiplicity plays important roles in the interactions of actin with ABPs.     

Actin microfilaments in fungi

The cytoskeletal protein actin is among the most abundant proteins in nature. It is almost ubiquitous, occurring in all eukaryotes and in an ancestral form in prokaryotes. Actin monomers can polymerise to form microfilaments, structures that play a critical role in a number of fundamental cell processes in fungi such as morphogenesis, cytokinesis and the movement of organelles. Microfilaments are extremely dynamic structures and can be rapidly modified through their interactions with a number of actin binding proteins (ABPs). The purpose of the following review is to introduce actin and microfilaments in fungi to a general mycological audience and to provide a basic framework from which further study is possible.