Actin' like actin?

The most biologically significant property of actin is its ability to self-associate and form two-stranded polymeric microfilaments. In living cells, these micro filaments form the actin cytoskeleton, essential for maintenance of the shape, passive mechanical properties and active motility of eukaryotic cells. Recently discovered actin-related proteins (ARPs) appear to share a common ancestor with conventional actin. At present, six classes of ARPs have been discovered, three of which have representatives in diverse species across eukaryotic phyla and may share functional characteristics with conventional actin. The three most ubiquitous ARPs are predicted to share a common core structure with actin and contain all the residues required for ATP binding. Surface residues involved in protein protein interactions, however, have diverged. Models of these proteins based on the atomic structure of actin provide some clues about how ARPs interact with each other, with conventional actin and with conventional actin-binding proteins.     

What initiates actin polymerization?

For those working on the actin cytoskeleton, a major theme of the 39th annual meeting of the American Society for Cell Biology [] (Washington DC, December 11-15, 1999) was the elucidation of how actin polymerization is initiated. The emphasis was on the regulation and localization of the Arp2/3 complex, which over the last two years has been shown to stimulate actin nucleation, and on the identification of additional proteins that interact with actin and Arp2/3 in a variety of organisms.     

Effect of α-actinin on actin viscosity

As determined by analytical ultracentrifugation, purified α-actinin does not form stable complexes with G-actin, myosin, tropomyosin, or the tropomyosintroponin complex. However, α-actinin forms a stable complex with F-actin polymerized either in 100 mM KC1 or in 2mM MgCl₂ without KCl. Viscosity studies confirm that α-actinin interacts as strongly with Mg²⁺-polymerized actin as it does with KCl-polymerized actin.     

An intracellular actin motor in bacteria?

Actin performs structural as well as motor-like functions in eukaryotic cells. Orthologues of actin have also been identified in bacteria, where they perform an essential function during cell growth. Bacterial actins are implicated in the maintenance of rod-shaped cell morphology, and appear to form a cytoskeletal structure, localising as helical filaments underneath the cell membrane. Recently, a plasmid-borne actin orthologue has been shown to perform a mitotic-like function during segregation of a plasmid, and chromosomally encoded actin proteins were found to play an important role in chromosome segregation. Based on the findings that actin filaments are dynamic structures in two bacterial species, we propose that actins perform motor functions rather than a purely structural role in bacteria. We suggest that an intracellular motor exists in bacteria that could be derived from an ancestral actin motor that was present in cells early in evolution.     

How is actin polymerization nucleated in vivo?

Actin polymerization in vivo is dependent on free barbed ends that act as nuclei. Free barbed ends can arise in vivo by nucleation from the Arp2/3 complex, uncapping of barbed ends on pre-existing filaments or severing of filaments by cofilin. There is evidence that each mechanism operates in cells. However, different cell types use different combinations of these processes to generate barbed ends during stimulated cell motility. Here, I describe recent attempts to define the relative contributions of these three mechanisms to actin nucleation in vivo. The rapid increase in the number of barbed ends during stimulation is not due to any single mechanism. Cooperation between capping proteins, cofilin and the Arp2/3 complex is necessary for the development of protrusive force at the leading edge of the cell: uncapping and cofilin severing contributing barbed ends, whereas activity of the Arp2/3 complex is necessary, but not sufficient, for lamellipod extension. These results highlight the need for new methods that enable the direct observation of actin nucleation and so define precisely the relative contributions of the three processes to stimulated cell motility.     

How does doxorubicin interfere with actin polymerization?

It is well known that doxorubicin (adriamycin), an antibiotic with an antitumoral action, has some undesirable side effects. Among these, the most serious is, undoubtedly, damage to myocardial tissue (progressive cardiomyopathy). We have for some time focused our attention on the effect of this drug on cellular contractile systems and, more specifically, on the process of actin polymerization, which we consider to be an extremely delicate key point for the economy of most cellular motor manifestations. In the present study, using capillary viscometry, spectrofluorometry and electron microscopy, we have shown a negative action of doxorubicin on various important chemical events which contribute to the transformation of G-actin into F-actin. Specifically, we found that the drug mainly acts by reducing the polymer size. A possible action mechanism of the antibiotic is proposed and a plausible correlation among the events described in vitro and those observed in vivo is advanced.     

Vinculin–actin interaction couples actin retrograde flow to focal adhesions,but is dispensable for focal adhesion growth

In migrating cells, integrin-based focal adhesions (FAs) assemble in protruding lamellipodia in association with rapid filamentous actin (F-actin) assembly and retrograde flow. How dynamic F-actin is coupled to FA is not known. We analyzed the role of vinculin in integrating F-actin and FA dynamics by vinculin gene disruption in primary fibroblasts. Vinculin slowed F-actin flow in maturing FA to establish a lamellipodium–lamellum border and generate high extracellular matrix (ECM) traction forces. In addition, vinculin promoted nascent FA formation and turnover in lamellipodia and inhibited the frequency and rate of FA maturation. Characterization of a vinculin point mutant that specifically disrupts F-actin binding showed that vinculin–F-actin interaction is critical for these functions. However, FA growth rate correlated with F-actin flow speed independently of vinculin. Thus, vinculin functions as a molecular clutch, organizing leading edge F-actin, generating ECM traction, and promoting FA formation and turnover, but vinculin is dispensible for FA growth.     

RhoD regulates cytoskeletal dynamics via the actin nucleation–promoting factor WASp homologue associated with actin Golgi membranes and microtubules

The Rho GTPases have mainly been studied in association with their roles in the regulation of actin filament organization. These studies have shown that the Rho GTPases are essential for basic cellular processes, such as cell migration, contraction, and division. In this paper, we report that RhoD has a role in the organization of actin dynamics that is distinct from the roles of the better-studied Rho members Cdc42, RhoA, and Rac1. We found that RhoD binds the actin nucleation–promoting factor WASp homologue associated with actin Golgi membranes and microtubules (WHAMM), as well as the related filamin A–binding protein FILIP1. Of these two RhoD-binding proteins, WHAMM was found to bind to the Arp2/3 complex, while FILIP1 bound filamin A. WHAMM was found to act downstream of RhoD in regulating cytoskeletal dynamics. In addition, cells treated with small interfering RNAs for RhoD and WHAMM showed increased cell attachment and decreased cell migration. These major effects on cytoskeletal dynamics indicate that RhoD and its effectors control vital cytoskeleton-driven cellular processes. In agreement with this notion, our data suggest that RhoD coordinates Arp2/3-dependent and FLNa-dependent mechanisms to control the actin filament system, cell adhesion, and cell migration.     

Crystalline actin tubes. I. Is the conformation of the lanthanide-induced actin tube monomer more like F-actin than G-actin?

Actin, isolated from rabbit skeletal muscle, forms highly-ordered aggregates when it binds six moles of the lanthanide ion, Gd3+. In the presence of 0.1 M KCl, these aggregates are referred to as actin tubes. The monomer contained in the repeating subunit of these tubes possess a number of functional characteristics which include: (i) binding to myosin or subfragment-1 of myosin; (ii) rapid conversion into filamentous Gd-actin which can activate myosin ATPase activity; (iii) a slow rate of exchange of the bound nucleotide; (iv) a slow rate of exchange of the metal cation; (v) a resistance to digestion by proteolytic enzymes. Additionally, the monomer of the Gd-actin tube structures appears to stoichiometrically bind ATP and exhibit a lower minimum protein concentration for tube formation than is needed for the formation of F-actin. The properties listed above suggest that the actin monomer, which comprises the Gd-actin tubes, bears little resemblance to either the G-actin monomer or the recently-described actin monomer conformation that exists under conditions that favour polymerization. The data suggest that the actin molecules which comprise the Gd-actin tube structures contain sites which bind myosin, nucleotide and metal cations and that these sites are similar to the sites on F-actin.     

The interaction of spectrin · actin and synthetic phospholipids

Using differential scanning calorimetry and freeze fracture electron microscopy interactions were studied between lipids and a spectrin · action complex isolated from human erythrocyte membranes. With dispersions of $\text{1,2-}\text{dimyristoyl}\text{-sn-}\text{glycero}\text{-3-}\text{phosphocholine}$, $\text{1,2-}\text{dimyristoyl}\text{-sn-}\text{glycero}\text{-3-}\text{phosphoglycerol}$ and mixtures of these two compounds, which for experimental reasons were chosen as the lipid counterpart, such an interaction could clearly be deduced from changes in the temperature and the enthalpy of the phase transition. Furthermore it was demonstrated that the interaction with this membrane protein protects the bilayer against the action of Ca²⁺ and Mg²⁺ and prevents fusion of lipid vesicles which easily occurs in some of the systems when divalent ions were added to the pure lipid vesicles.     

DNAse I—actin complex: An immunological study

DNAse I - actin complex formation is studied in the presence of different anti actin antibody populations. The binding of DNAse I to actin is shown to be affected by antibodies specific to a central region in actin sequence (168–226). The C- and N-extremities of actin are shown to be in spatial proximity at the surface of the actin monomer and far from the binding area of DNAse I.     

Polymerization of β-like actin from scallop adductor muscle

Scallop adductor muscle β-like isoactin differs from rabbit skeletal muscle α-actin in the rate, extent and critical concentration of polymerization. The difference is temperature- and [KCl]-dependent. In the presence of DNase I scallop actin was shown to be depolymerized more rapidly than rabbit actin. It was suggested that the polymers formed by β-actin are less stable than those formed by α-actin.     

Diverse soybean actin transcripts contain a large intron in the 5′ untranslated leader: structural similarity to vertebrate muscle actin genes

Plant actins are encoded by complex and highly divergent multigene families. Despite the general lack of intron conservation in animal, fungal and protist actin genes, evidence is presented which indicates that higher plant actin genes have an untranslated leader exon with structural similarity to that found in vertebrate actin genes. All functional higher plant actin genes sequenced to date contain a potential intron acceptor site in the 5 untranslated region 10 to 13 nucleotides upstream of the initiator ATG. A leader specific cDNA probe hybridized to sequences over 1.0 kbp upstream from the coding region confirming the presence of an upstream exon. Primer extension of mRNA with gene-specific oligonucleotides was used to analyze the 5 untranslated exon and leader intron from four divergent soybean actin genes, SAc3, 4, 6 and 7. The 5 ends of all four mRNAs are heterogeneous. The consensus promoter elements of the SAc7 actin promoter were identified. Gene specific primer extension sequencing of actin mRNAs indicated that splicing of the 5 leader intron occured at the predicted acceptor site in SAc6 and SAc7. The SAc6 and SAc7 5 untranslated exons are small (88–111 nt) and the leader introns are relatively large (844–1496 nt). The presence of an intron within the 5 RNA leader and an intron which splits a glycine codon at position 152 in all plant actin genes and all vertebrate muscle actin genes suggests that these structures may have been conserved due to a functional role in actin expression. The 5 regions of these two soybean actin genes contain many unusual features including (CT) repeats and long stretches of pyrimidine-rich DNA. The possible roles of the upstream exon/intron and the C + T-rich regions are discussed.     

Alpha smooth muscle actin (α-SM actin) in normal human ovaries,in ovarian stromal hyperplasia and in ovarian neoplasms

An immunohistochemical investigation of alpha-smooth muscle actin (alpha-SM actin) using the monoclonal anti-alpha-SM-1 antibody was carried out in 15 normal ovaries, in three ovaries with stromal hyperplasia and in 27 neoplastic ovaries. In selected cases the pattern of actin isoforms was examined by means of 2 D-gel electrophoresis. In addition, the tissues were stained for vimentin and desmin. In normal ovaries alpha-SM actin was found in the inner cortex and in the theca externa. In ovarian stromal hyperplasia expression of alpha-SM actin was minimal or absent. In primary and metastatic epithelial tumors there was positive stromal staining for alpha-SM actin, especially in the vicinity of epithelial elements. This tended to be more widespread in malignant neoplasms. Thecomas did not express alpha-SM-actin and could thus be differentiated from leiomyomas which stained intensely for alpha-SM actin. Only focal stromal staining of alpha-SM actin was observed in granulosa and germ cell tumors. In all the tissues studied blood vessels were strongly positive for alpha-SM actin. Desmin, although present in the stroma of most of the specimens, was less abundant than alpha-SM actin. We concluded that alpha-SM actin is a component of the normal human ovary where it may contribute to the contractility of its stroma. Its absence in the normal outer cortex and theca interna, and in stromal hyperplasia and thecoma implies that sex hormones do not constitute a stimulus for alpha-SM actin production in the ovary. Among neoplasms it is most widely represented in the stroma of epithelial tumors in which it may reflect stromal stimulation mediated by neoplastic epithelium.     

Is there a role for actin in virus budding?

Electrophoretic data from both sodium dodecyl sulfate-polyacrylamide gels (SDS-PAGE) and acid-urea gels reveal a protein in purified murine mammary tumor virus (MuMTV) which co-migrates with purified chick skeletal muscle actin. 125I-labeling of intact and disrupted virus preparations shows that the actin-like protein is not artifactually adsorbed to the outside of virions during isolation. Quantitative SDS- PAGE and examination of negatively stained preparations show that the actin cannot be accounted for by a contaminating population of virus- free vesicles. The ultrastructure of mammary epithelial cells and of Rous sarcoma virus-transformed chick embryo fibroblasts shows that virus extrusion is associated with filament-containing cellular processes. In particular, MuMTV is released from the ends of long microvilli which contain a bundle of 6-8-nm microfilaments and share other structural features with intestinal microvilli. We suggest that virus nucleoids require an interaction with host cell contractile proteins for their extrusion from the cell.     

登革病毒感染后ECV304细胞骨架actin变化的研究

登革病毒属于黄病毒属 ,它以蚊虫为传播媒介 ,引起登革热 (DF)或死亡率较高的登革出血热 (DHF)。DHF主要特点是血管通透性增加引起血浆渗漏 ,继发休克。DHF发生机理尚不明了。临床研究提示 :登革病毒感染后 ,血管内皮细胞 (VEC)无明显器质性变化 ,推测血管渗透性增加可能与VEC功能失调有关。由于细胞骨架系统与VEC功能及微血管的完整性密切相关 ,所以实验以血管内皮细胞株ECV30 4为细胞模型 ,研究登革病毒感染与细胞骨架微丝变化的关系 ;并通过药物干扰微丝的聚合与解聚 ,探讨微丝在DHF发病过程中的可能作用。实验用 2型登革病毒…