The cell-surface-expressed nucleolin is associated with the actin cytoskeleton

Nucleolin is a RNA- and protein-binding multifunctional protein. Mainly characterized as a nucleolar protein, nucleolin is continuously expressed on the surface of different types of cells along with its intracellular pool within the nucleus and cytoplasm. By confocal and electron microscopy using specific antibodies against nucleolin, we show that cytoplasmic nucleolin is found in small vesicles that appear to translocate nucleolin to the cell surface. Translocation of nucleolin is markedly reduced at low temperature or in serum-free medium, whereas conventional inhibitors of intracellular glycoprotein transport have no effect. Thus, translocation of nucleolin is the consequence of an active transport by a pathway which is independent of the endoplasmic reticulum-Golgi complex. The cell-surface-expressed nucleolin becomes clustered at the external side of the plasma membrane when cross-linked by the nucleolin-specific monoclonal antibody mAb D3. This clustering, occurring at 20 degrees C and in a well-organized pattern, is dependent on the existence of an intact actin cytoskeleton. At 37 degrees C, mAb D3 becomes internalized, thus illustrating that surface nucleolin can mediate intracellular import of specific ligands. Our results point out that nucleolin should also be considered a component of the cell surface where it could be functional as a cell surface receptor for various ligands reported before.     

Identification of novel adhesion proteins in mouse peritoneal macrophages.

When mouse peritoneal macrophages were made to adhere firmly on glass surface and then removed by sequential treatment with hypotonic triethanolamine and Nonidet P-40, a set of proteins were found to be left behind at the sites of adherent cells. Such glass-adherent proteins were detected as round or ellipsoidal patches of autofluorescence under a confocal laser microscope, and visualized ultrastructurally as aggregates of narrow threads of unique loop structures which were composed of linearly aligned particles of 22 +/- 2 nm in diameter. Lithium dodecylsulfate-polyacrylamide gel electrophoresis of the glass-adherent proteins showed two major bands, 12 kDa and 14 kDa, which always co-existed in any different sample. The polyclonal antibody raised against these two proteins specifically stained the glass-adherent proteins in situ. The adhesion of macrophages to glass was significantly blocked with Fab fragments of the antibody. The in situ cross-linking experiment suggested that these two proteins might be closely associated with each other to form complexes. Hence, these proteins can be reasonably considered to be responsible for non-specific adhesion of macrophages to glass.     

ADF/cofilin use an intrinsic mode of F-actin instability to disrupt actin filaments

Proteins in the ADF/cofilin (AC) family are essential for rapid rearrangements of cellular actin structures. They have been shown to be active in both the severing and depolymerization of actin filaments in vitro, but the detailed mechanism of action is not known. Under in vitro conditions, subunits in the actin filament can treadmill; with the hydrolysis of ATP driving the addition of subunits at one end of the filament and loss of subunits from the opposite end. We have used electron microscopy and image analysis to show that AC molecules effectively disrupt one of the longitudinal contacts between protomers within one helical strand of F-actin. We show that in the absence of any AC proteins, this same longitudinal contact between actin protomers is disrupted at the depolymerizing (pointed) end of actin filaments but is prominent at the polymerizing (barbed) end. We suggest that AC proteins use an intrinsic mechanism of F-actin's internal instability to depolymerize/sever actin filaments in the cell.     

Structural basis for the slow dynamics of the actin filament pointed end

The actin filament has clear polarity where one end, the pointed end, has a much slower polymerization and depolymerization rate than the other end, the barbed end. This intrinsic difference of the ends significantly affects all actin dynamics in the cell, which has central roles in a wide spectrum of cellular functions. The detailed mechanism underlying this difference has remained elusive, because high-resolution structures of the filament ends have not been available. Here, we present the structure of the actin filament pointed end obtained using a single particle analysis of cryo-electron micrographs. We determined that the terminal pointed end subunit is tilted towards the penultimate subunit, allowing specific and extra loop-to-loop inter-strand contacts between the two end subunits, which is not possible in other parts of the filament. These specific contacts prevent the end subunit from dissociating. For elongation, the loop-to-loop contacts also inhibit the incorporation of another actin monomer at the pointed end. These observations are likely to account for the less dynamic pointed end.     

Plant villins:Versatile actin regulatory proteins

Regulation of actin dynamics is a central theme in cell biology that is important for different aspects of cell physiology.Villin, a member of the villin/gelsolin/fragmin superfamily of proteins, is an important regulator of actin. Villins contain six gelsolin homology domains(G1–G6) and an extra headpiece domain. In contrast to their mammalian counterparts, plant villins are expressed widely, implying that plant villins play a more general role in regulating actin dynamics. Some plant villins have a de fined role in modifying actin dynamics in the pollen Invitube; most of their in vivo activities remain to be ascertained.Recently, our understanding of the functions and mechanisms of action for plant villins has progressed rapidly, primarily due to the advent of Arabidopsis thaliana genetic approaches and imaging capabilities that can visualize actin dynamics at the single filament level in vitro and in living plant cells. In this review,we focus on discussing the biochemical activities and modes of regulation of plant villins. Here, we present current understanding of the functions of plant villins. Finally, we highlight some of the key unanswered questions regarding the functions and regulation of plant villins for future research.     

Caspase-dependent cleavage of tensin induces disruption of actin cytoskeleton during apoptosis

Members of both calpain and caspase protease families can degrade several components of focal adhesions, leading to disassembly of these complexes. In this report, we investigated the disappearance of tensin from cell adhesion sites of chicken embryonic fibroblast cells (CEFs) exposed to etoposide and demonstrated that loss of tensin from cell adhesions during etoposide-induced apoptosis may be due to degradation of tensin by caspase-3. Tensin cleavage by caspase-3 at the sequence DYPD(1226)G separates the amino-terminal region containing the actin binding domain and the carboxyl-terminal region containing the SH2 domain. The resultant carboxyl-terminal fragment of tensin is unable to bind phosphoinositide 3-kinase (PI3-kinase) transducing cell survival signaling. We also demonstrated that overexpression of the amino-terminal tensin fragment induced disruption of actin cytoskeleton in chicken embryonic fibroblasts. Therefore, caspase-mediated cleavage of tensin contributes to the disruption of actin organization and interrupts ECM-mediated survival signals through phosphatidylinositol 3-kinase.     

Cell adhesion dynamics and actin cytoskeleton reorganization in HepG2 cell aggregates

The temporal dependence of cytoskeletal remodelling on cell-cell contact in HepG2 cells has been established here. Cell-cell contact occurred in an ultrasound standing wave trap designed to form and levitate a 2-D cell aggregate, allowing intercellular adhesive interactions to proceed, free from the influences of solid substrata. Membrane spreading at the point of contact and change in cell circularity reached 50% of their final values within 2.2 min of contact. Junctional F-actin increased at the interface but lagged behind membrane spreading, reaching 50% of its final value in 4.4 min. Aggregates had good mechanical stability after 15 min in the trap. The implication of this temporal dependence on the sequential progress of adhesion processes is discussed. These results provide insight into how biomimetic cell aggregates with some liver cell functions might be assembled in a systematic, controlled manner in a 3-D ultrasound trap.     

Response of cytoskeleton of murine osteoblast cultures to two-step freezing

Understanding the ultrastructural response of cells to the freezing process is important for designing cryopreservation strategies for cells and tissues. The cellular structures of attached cells are targets of cryopreservation-induced damage. Specific fluorescence staining was used to assess the status of the actin filaments （F-actin） of murine osteoblasts attached to hydroxyapatite discs and plastic coverslips for a two-step freezing process. The F-actin of dead cells was depolymerized and distorted in the freezing process, whereas that of live cells had little change. The results suggest that the cytoskeleton may support the robustness of cells during cryopreservation. The present study helps to investigate the damage mechanism of attached cells during the freezing process.     

Cytoskeletal functions of cytoplasmic contractile proteins

This is a review of the evidence that the cytoplasmic contractile proteins function as a cytoskeletal system inthe cytoplasmic matrix. Biochemical experiments show that cycoplasmic actin filaments can form a solid gel under conditions likely to exist in living cells. The actin filaments are associated with other proteins which may stabilize the gel and which are involved with motile force generation like myosin. Ultrastructural studies show that actin filaments are difficult to preserve, but that under stabilizing conditions networks of actin filaments are found throughout the cytoplasmic matrix.     

Paraquat induces irreversible actin cytoskeleton disruption in cultured human lung cells

The herbicide paraquat (PQ) induces the selective necrosis of type I and type II alveolar pneumocytes. We investigated the effect of PQ on human lung A549 cells to determine the possible role of cytoskeleton in lung cytotoxicity. At 80 mol/L PQ, a concentration that did not affect cell viability, the organization of actin cytoskeleton network depended on incubation time with the herbicide. Microfilaments appeared less numerous in 30% of the cells treated for 1 h. After 24 h, all the treated cells displayed only short filaments in the periphery. The effect of PQ on actin cytoskeleton was irreversible. Moreover, no modification of microtubule network was observed in PQ-treated cells. Next, we studied the effect of PQ on Chang Liver, an epithelial cell line from human liver. These cells appeared less sensitive to the herbicide than A549, and no cytoskeletal alteration was observed. To verify whether actin filament modifications in A549 cells were related to intracellular alterations of ATP concentrations, nucleotide levels during incubation with PQ were determined. The intracellular levels of ATP were not different in control and treated cells. Our results indicate that PQ induces specifically an irreversible actin filament disorganization on A549 cells and that the observed effect is independent of intracellular concentration of ATP.Abbreviations BSA bovine serum albumin - IC₅₀ concentration that produces 50% inhibitiition - PBS phosphate-buffered saline - PQ paraquat, 1,1-dimethyl-4,4-bipyridinium dichloride - SE standard error of the mean     

Collective efforts to modulate the host actin cytoskeleton by Salmonella type III-secreted effector proteins

The hallmark of Salmonella entry into host cells is extensive rearrangements of the host actin cytoskeleton at the site of Salmonella contact with intestinal epithelial cells. SopE, SopE2 and SopB, three type III effectors of Salmonella pathogenicity island 1 (SPI-1), activate the Cdc42 and Rac1 signal transduction pathways to promote these rearrangements. SipA and SipC, two Salmonella type III-secreted actin-binding proteins, directly modulate host actin dynamics to facilitate bacterial uptake. Salmonella-induced actin cytoskeleton rearrangements are therefore the result of the coordinated action of a group of type III-secreted effector proteins.     

The actin cytoskeleton in presynaptic assembly

Dramatic morphogenetic processes underpin nearly every step of nervous system development, from initial neuronal migration and axon guidance to synaptogenesis. Underlying this morphogenesis are dynamic rearrangements of cytoskeletal architecture. Here we discuss the roles of the actin cytoskeleton in the development of presynaptic terminals, from the elaboration of terminal arbors to the recruitment of presynaptic vesicles and active zone components. The studies discussed here underscore the importance of actin regulation at every step in neuronal circuit assembly.     

LIM proteins: association with the actin cytoskeleton

The LIM domain is an evolutionary conserved double-zinc finger motif found in a variety of proteins exhibiting diverse biological roles. LIM domains have been observed to act as modular protein-binding interfaces mediating protein-protein interactions in the cytoplasm and the nucleus. Interaction of LIM domains with specific protein partners is now known to influence its subcellular localization and activity; however, no single binding motif has been identified as a common target for LIM domains. Several LIM domain-containing proteins associated with the actin cytoskeleton have been identified, playing a role in signal transduction and organization of the actin filaments during various cellular processes.     

The actin cytoskeleton coordinates the signal transduction and antigen processing functions of the B cell antigen receptor

The B cell antigen receptor （BCR） is the sensor on the B cell surface that surveys foreign molecules （antigen） in our bodies and activates B cells to generate antibody responses upon encountering cognate antigen. The binding of antigen to the BCR induces signaling cascades in the cytoplasm, which provides the first signal for B cell activation. Subsequently, BCRs internalize and target bound antigen to endosomes, where antigen is processed into T cell recognizable forms. T helper cells generate the second activation signal upon binding to antigen presented by B cells. The optimal activation of B cells requires both signals, thereby depending on the coordination of BCR signaling and antigen transport functions. Antigen binding to the BCR also induces rapid remodeling of the cortical actin network of B cells. While being initiated and controlled by BCR signaling, recent studies reveal that this actin remodeling is critical for both the signaling and antigen processing functions of the BCR, indicating a role for actin in coordinating these two pathways. Here we will review previous and recent studies on actin reorganization during BCR activation and BCR- mediated antigen processing, and discuss how actin remodeling translates BCR signaling into rapid antigen uptake and processing while providing positive and negative feedback to BCR signaling.     

Electron microscopic visualization of the filament binding mode of actin-binding proteins

A large number of actin-binding proteins (ABPs) regulate various kinds of cellular events in which the superstructure of the actin cytoskeleton is dynamically changed. Thus, to understand the actin dynamics in the cell, the mechanisms of actin regulation by ABPs must be elucidated. Moreover, it is particularly important to identify the side, barbed-end or pointed-end ABP binding sites on the actin filament. However, a simple, reliable method to determine the ABP binding sites on the actin filament is missing. Here, a novel electron microscopic method for determining the ABP binding sites is presented. This approach uses a gold nanoparticle that recognizes a histidine tag on an ABP and an image analysis procedure that can determine the polarity of the actin filament. This method will facilitate future study of ABPs.     

Structure and properties of small heat shock proteins (sHsp) and their interaction with cytoskeleton proteins

The modern classification of small heat shock proteins (sHsp) is presented and peculiarities of their primary structure and the mechanism of formation of oligomeric complexes are described. Data on phosphorylation of sHsp by different protein kinases are presented and the effect of phosphorylation on oligomeric state and chaperone activity of sHsp is discussed. Intracellular location of sHsp under normal and stress conditions is described and it is emphasized that under certain condition sHsp interact with different elements of cytoskeleton. The literature concerning the effect of sHsp on polymerization of actin in vitro is analyzed. An attempt is made to compare effects of sHsp on polymerization of actin in vitro with the results obtained on living cells under normal conditions and after heat shock or hormone action. The literature concerning possible effects of sHsp on cell motility is also analyzed.     

Deletion mutagenesis of the amino-terminal head domain of vimentin reveals dispensability of large internal regions for intermediate filament assembly and stability

Previous studies have shown that the non-alpha-helical head domain of vimentin is required for polymerization of intermediate filaments (IFs) and, furthermore, a nonapeptide highly conserved among type III IF subunit proteins at their extreme amino-terminus is essential for this process. Recombinant DNA technology was employed to produce specific vimentin deletion mutant proteins (for in vitro studies) or vimentin protein expression plasmids (for in vivo studies), which were used to identify other regions of the vimentin head domain important for polymerization. Various vimentin proteins lacking either residues 25-38, 44-95, or 40-95 polymerized into wild-type or largely normal IFs, both in vitro and in vivo. Vimentin proteins lacking residues 44-69 or 25-63 failed to form IFs in vitro, but assembled into IFs in vivo. Vimentin proteins lacking residues 25-68, 44-103, or 88-103 failed to form IFs in vitro or in vivo. Taken together with previous results, these data demonstrate that the middle of the vimentin non-alpha-helical head domain, which is known to be the site of nucleic acid binding, is completely dispensable for IF formation, whereas both ends of the vimentin non-alpha-helical head domain are required for IF formation. The simplest explanation for these results is that the middle of the vimentin non-alpha-helical head domain loops out, thereby permitting the juxtaposition of the ends of the head domain and their productive interaction with other protein domains (probably the C-terminus of the rod domain) during IF polymerization. The ability of some of the mutant proteins to form IFs in vivo, but not in vitro, suggests that as-yet-unknown cellular proteins may interact with and, in some cases, enable polymerization of IFs, even though they are not absolutely required for IF formation by wild-type vimentin.