Actin in human colon adenocarcinoma cells with different metastatic potential

Four human colon adenocarcinoma cell line variants with different metastatic potential were used to examine whether a correlation exists between actin level, state of actin polymerization and invasiveness of tumour cells. Monomeric (G), total (T) and filamentous (F) actin were determined in the cytosolic fraction of these cells. A statistically significant decrease in G actin level and increase in the state of actin polymerization (measured by F:G actin ratio) were found in the cytosol of three cell variants with higher metastatic potential and invasiveness (EB3, 3LNLN, 5W) compared with the parental cell line (LS180). Our experimental data lead to the conclusion that there is a correlation between the metastatic capacity of human colon adenocarcinoma cells and the state of actin polymerization.     

Fate of microfilaments in vero cells infected with measles virus and herpes simplex virus type 1.

In herpes simplex virus type 1-infected Vero cells, reorganization of microfilaments was observed approximately 4 h postinfection. Conversion of F (filamentous) actin to G (globular) actin, as assessed by a DNase I inhibition assay, was continuous over the next 12 to 16 h, at which time a level of G actin of about twice that observed in uninfected cells was measured. Fluorescent localization of F actin, using 7-nitrobenz-2-oxa-1,3-diazole (NBD)-phallacidin, demonstrated that microfilament fibers began to diminish at about 16 to 18 h postinfection, roughly corresponding to the time that G actin levels peaked and virus-induced cytopathology was first observable. In measles virus-infected cells, no such disassembly of microfilaments occurred. Rather, there was a modest decrease in G actin levels. Fluorescent localization of F actin showed that measles virus-infected Vero cells maintained a complex microfilament network characterized by fibers which spanned the entire length of the newly formed giant cells. Disruption of microfilaments with cytochalasin B, which inhibits measles virus-specific cytopathology, was not inhibitory to measles virus production at high multiplicities of infection (MOI) but was progressively inhibitory as the MOI was lowered. The carbobenzoxy tripeptide SV-4814, which inhibits the ability of Vero cells to fuse after measles virus infection, like cytochalasin B, inhibited measles virus production at low MOI but not at high MOI. Thus, it appears that agents which affect the ability of Vero cells to fuse after measles virus infection may be inhibitory to virus production and that the actin network is essential to this process.     

Actin ADP‐ribosylation at Threonine148 by Photorhabdus luminescens toxin TccC3 induces aggregation of intracellular F‐actin

Intoxication of eukaryotic cells by Photorhabdus luminescens toxin TccC3 induces cell rounding and detachment from the substratum within a few hours and compromises a number of cell functions like phagocytosis. Here, we used morphological and biochemical procedures to analyse the mechanism of TccC3 intoxication. Life imaging of TccC3‐intoxicated HeLa cells transfected with AcGFP‐actin shows condensation of F‐actin into large aggregates. Life cell total internal reflection fluorescence (TIRF) microscopy of identically treated HeLa cells confirmed the formation of actin aggregates but also disassembly of F‐actin stress fibres. Recombinant TccC3 toxin ADP‐ribosylates purified skeletal and non‐muscle actin at threonine148 leading to a strong propensity to polymerize and F‐actin bundle formation as shown by TIRF and electron microscopy. Native gel electrophoresis shows strongly reduced binding of Thr148‐ADP‐ribosylated actin to the severing proteins gelsolin and its fragments G1 and G1–3, and to ADF/cofilin. Complexation of actin with these proteins inhibits its ADP‐ribosylation. TIRF microscopy demonstrates rapid polymerization of Thr148‐ADP‐ribosylated actin to curled F‐actin bundles even in the presence of thymosin β4, gelsolin or G1–3. Thr148‐ADP‐ribosylated F‐actin cannot be depolymerized by gelsolin or G1–3 as verified by TIRF, co‐sedimentation and electron microscopy and shows reduced treadmilling as indicated by a lack of stimulation of its ATPase activity after addition of cofilin‐1.     

Cytoskeletal and contractile structures in bovine lens cell differentiation

Bovine lenses from animals of different ages were separated into two epithelial sections, a cortical region and the lens nucleus. Both the 10000 g supernatant fraction and pellet of these sections were analysed by electrophoresis in SDS-containing polyacrylamide gels. When comparing total protein patterns of the cytoskeletal preparations from the different parts of lenses of different ages a decrease in the amount of vimentin, the protein subunit of lens intermediate-sized filaments (IF), was observed upon lens cell differentiation and aging. Amounts of monomeric (G) and filamentous (F) actin in the different stages of lens cell differentiation were quantitated using the DNase I inhibition technique. A significant increase in the relative amount of F-actin was observed upon fibre cell formation. A slight, but significant increase in the total amount of actin relative to the total amount of cellular protein was observed when passing from the central part of the lens epithelium to the epithelial cells in the elongation zone. In the fibre cells the amount of total actin decreased from cortex to nucleus. A possible function of microfilament-assembly in the process of lens cell differentiation is suggested.     

Interaction of diphtheria toxin (fragment A) with actin

It was shown by gel filtration and viscosity measurements that N‐terminal fragment (FA) of diphtheria toxin (DT) can interact with both G‐ and F‐actin (filamentous actin). Elution profiles on Sephadex G‐100 indicated the formation of a binary complex of fragment A (FA) with globular actin monomer (G‐actin), which was inhibited by gelsolin. Deoxyribonuclease I (DNase I) in turn appeared to interact with this complex. Tritiated FA was found to bind to F‐actin stoichiometrically. This binding was inhibited again by gelsolin and G‐actin, but not by DNase I. The binding of FA inhibited polymerization of G‐actin and induced a time‐dependent breakdown of F‐actin under polymerization conditions. Inhibition of its ADP‐ribosyltransferase activity did not have any effect on the interactions of FA with actin. FA interacted with actin also in the cell. After treatment of human umbilical vein endothelial cells (HUVEC) with biotin‐labeled DT, Western blot analysis revealed predominantly the presence of actin in affinity‐isolated complexes of the labeled FA. Similarly, FA was found in immunoaffinity‐isolated complexes of actin. Copyright © 2009 John Wiley & Sons, Ltd.     

Levels of filamentous and globular actin in Chinese hamster ovary cells throughout the cell cycle

Synchronous Chinese hamster ovary (CHO) cells were obtained by mitotic selection and the levels of globular (G) actin, filamentous (F) actin, and cytoskeletal-associated F-actin were determined as cells progressed through the cell cycle. Total actin levels remained quite constant when expressed as a percent of the total protein. An increase in F-actin occurred upon plating the mitotic cells, but this increase was shown to be a result of attachment to the substratum, since cells which remained attached during the second mitosis failed to show these changes. No large variation in the levels of either F-actin or cytoskeletal-associated F-actin occurred throughout the cell cycle. Therefore, changes in the morphology of the CHO cells which are accompanied by a reorganization of actin-containing microfilaments during the cell cycle are not accompanied by significant changes in the size of the monomeric actin pool.     

Ecdysterone induction of actin synthesis and polymerization in a Drosophila melanogaster cultured cell line

Actin pools have been evaluated in Drosophila melanogaster Kc 0% cells, through an actin assay based on differential inhibition of DNase I by globular (G) and filamentous (F) actin. Total actin represents about 4 % of total proteins and 54 % is G-actin. In ecdysterone treated cells (0.1 μM), the total actin content increases up to 9 % of total proteins after 3 days of treatment. Ecdysterone induces increase of G-actin as well as F-actin. Increase of both actins, detectable after only 24 hrs of treatment, is roughly parallel during the first two days of treatment. For longer hormonal treatment, actin polymerization is more important than accumulation of G-actin. Indirect immunofluorescence microscopy with antibodies to exogeneous DNase I suggests that actin is widely distributed in the whole cytoplasm before and after ecdysterone treatment. These results suggest that ecdysterone induces actin synthesis and polymerization in Drosophila melanogaster cells.     

Arterial smooth muscle cells in vivo: relationship between actin isoform expression and mitogenesis and their modulation by heparin

Quiescent smooth muscle cells (SMC) in normal artery express a pattern of actin isoforms with alpha-smooth muscle (alpha SM) predominance that switches to beta predominance when the cells are proliferating. We have examined the relationship between the change in actin isoforms and entry of SMC into the growth cycle in an in vivo model of SMC proliferation (balloon injured rat carotid artery). alpha SM actin mRNA declined and cytoplasmic (beta + gamma) actin mRNAs increased in early G0/G1 (between 1 and 8 h after injury). In vivo synthesis and in vitro translation experiments demonstrated that functional alpha SM mRNA is decreased 24 h after injury and is proportional to the amount of mRNA present. At 36 h after injury, SMC prepared by enzymatic digestion were sorted into G0/G1 and S/G2 populations; only the SMC committed to proliferate (S/G2 fraction) showed a relative slight decrease in alpha SM actin and, more importantly, a large decrease in alpha SM actin mRNA. A switch from alpha SM predominance to beta predominance was present in the whole SMC population 5 d after injury. To determine if the change in actin isoforms was associated with proliferation, we inhibited SMC proliferation by approximately 80% with heparin, which has previously been shown to block SMC in late G0/G1 and to reduce the growth fraction. The switch in actin mRNAs and synthesis at 24 h was not prevented; however, alpha SM mRNA and protein were reinduced at 5 d in the heparin-treated animals compared to saline-treated controls. These results suggest that in vivo the synthesis of actin isoforms in arterial SMC depends on the mRNA levels and changes after injury in early G0/G1 whether or not the cells subsequently proliferate. The early changes in actin isoforms are not prevented by heparin, but they are eventually reversed if the SMC are kept in the resting state by the heparin treatment.     

Quantitative analysis of cytoskeletal proteins throughout the cell cycle of the MRC-5 fibroblastic cell line

Fluorescent dyes were used to stain actin, vimentin, tubulin and DNA in the same MRC-5 fibroblastic cells. Cytofluorometry and image analysis were then used to quantitatively evaluate the F actin, vimentin and tubulin content throughout the cell cycle. The results showed that different cells can have the same DNA content while their cytoskeletal protein content is variable. The data also showed that cytoskeletal protein content variations exist throughout the cell cycle of the fibroblastic cell line. The F actin content increased during the cell cycle from G1 to G2 phases and decreased in M phase. The amount of tubulin in the G2 was about twice as much as that in the G1 phase, before decreasing in the M phase; there was a threshold of tubulin content for G2 cells entering S phase.     

Differences in the G/total actin ratio and microfilament stability between normal and malignant human keratinocytes

The state of polymerization of actin and the organization of actin filaments is widely believed to be related to cellular transformation. Since the intracellular monomer (G) and filamentous (F) actin content reflects the state of microfilament polymerization, we measured the G/total actin ratio in primary cultures of normal and malignant human keratinocytes. In normal keratinocytes the mean value of this ratio was 0·30 ± 0·03 (mean ± SE, n = 15), while in basal cell carcinoma (BCC) keratinocytes it was 0·49 ± 0·03 (n = 8) and in squamous cell carcinoma keratinocytes (SCC) 0·5 ± 0·07 (n = 4), indicating a 1·7-fold increase of the G/total actin ratio in malignant cells. These results imply that the proportion of polymerized actin is decreased markedly in malignant keratinocytes, suggesting alterations of microfilament structures which probably occur during the transformation process. This was supported by the morphological changes of microfilament structures as assessed by fluorescence microscopy. A different distribution of actin filaments in normal and malignant cells became evident; stress-fibres were converging in patches at several points in SCC cells, when compared to normal keratinocytes. Furthermore, incubation of normal and malignant keratinocytes with cytochalasin B indicated differences in the resistance of their microfilament networks. After 1 h exposure to 10^?6 and 10^?5 M cytochalasin B, microfilaments in normal cells appeared to be less affected than their counterparts in neoplastic cells. Even in a high excess of cytochalasin B (10^?4 M ), normal keratinocytes preserved their shape, while both basal cell and SCC were totally disrupted. We concluded that the G/total actin ratio was significantly increased in malignant keratinocytes. This seems to be correlated with altered microfilament morphology and resistance to cytochalasin B treatment. Our results suggest that the process of malignant transformation may be characterized by changes in the state of the polymerization of actin and in the stability of the microfilament network indicating that both features could potentially serve as markers determine the transformed state of keratinocytes.     

Platelet‐rich plasma inhibits osteoblast apoptosis and actin cytoskeleton disruption induced by gingipains through upregulating integrin β1

The aim of this study was to explore the effects of platelet‐rich plasma on gingipain‐caused changes in cell morphology and apoptosis of osteoblasts. Mouse osteoblasts MC3T3‐E1 cells were treated with gingipain extracts from Porphyromonas gingivalis in the presence or absence of platelet‐rich plasma. Apoptosis was detected with terminal deoxynucleotidyl transferase‐mediated dUTP nick‐end labeling staining. F‐actin was determined by phalloidin‐fluorescent staining and observed under confocal microscopy. Western blot analysis was used to detect integrin β1, F‐actin, and G‐actin protein expressions. A knocking down approach was used to determine the role of integrin β1. The platelet‐rich plasma protected osteoblasts from gingipain‐induced apoptosis in a dose‐dependent manner, accompanied by upregulation of integrin β1. Platelet‐rich plasma reversed the loss of F‐actin integrity and decrease of F‐actin/G‐actin ratio in osteoblasts in the presence of gingipains. By contrast, the effects of platelet‐rich plasma were abrogated by knockdown of integrin β1. The platelet‐rich plasma failed to reduce cell apoptosis and reorganize the cytoskeleton after knockdown of integrin β1. In conclusion, platelet‐rich plasma inhibits gingipain‐induced osteoblast apoptosis and actin cytoskeleton disruption by upregulating integrin β1 expression.     

Overexpression of the rabies virus glycoprotein results in enhancement of apoptosis and antiviral immune response

A recombinant rabies virus (RV) carrying two identical glycoprotein (G) genes (SPBNGA-GA) was constructed and used to determine the effect of RV G overexpression on cell viability and immunity. Immunoprecipitation analysis and flow cytometry showed that tissue culture cells infected with SPBNGA-GA produced, on average, twice as much RV G as cells infected with RV carrying only a single RV G gene (SPBNGA). The overexpression of RV G in SPBNGA-GA-infected NA cells was paralleled by a significant increase in caspase 3 activity followed by a marked decrease in mitochondrial respiration, neither of which was observed in SPBNGA-infected cells. Furthermore, fluorescence staining and confocal microscopy revealed an increased extent of apoptosis and markedly reduced neurofilament and F actin in SPBNGA-GA-infected primary neuron cultures compared with neuronal cells infected with SPBNGA, supporting the concept that RV G or motifs of the RV G gene trigger the apoptosis cascade. Mice immunized with SPBNGA-GA showed substantially higher antibody titers against the RV G and against the nucleoprotein than SPBNGA-immunized mice, suggesting that the speed or extent of apoptosis directly determines the magnitude of the antibody response.     

Autoregulation of actin synthesis responds to monomeric actin levels

Regulation of the assembly and expression of actin is of major importance in diverse cellular functions such as motility and adhesion and in defining cellular and tissue architecture. These biological processes are controlled by changing the balance between polymerized (F) and soluble (G) actin. Previous studies have indicated the existence of an autoregulatory pathway that links the state of assembly and expression of actin, resulting in the reduction of actin synthesis after actin filaments are depolymerized. We have employed the marine toxins swinholide A and latrunculin A, both disrupting the organization of the actin-cytoskeleton, to determine whether this autoregulatory response is activated by a decrease in the level of polymerized actin or by an increase in monomeric actin concentrations in the cell. We showed that in cells treated with swinholide A the level of filamentous actin is decreased, and using a reversible cross-linking reagent, we found that actin dimers are formed. Latrunculin A also disassembled actin filaments, but produced monomeric actin, followed by a reduction in actin and vinculin expression, while swinholide A treatment elevated the synthesis of these proteins. In cells treated with both latrunculin A and swinholide A, dimeric actin was formed, and actin and vinculin synthesis were higher than in control cells. These results suggest that the substrate that confers an autoregulated reduction in actin expression is monomeric actin, and when its level is decreased by dimeric actin formation, actin synthesis is increased. J. Cell. Biochem. 65:469–478. © 1997 Wiley-Liss Inc.     

Actin as a cytoskeletal basis for cell architecture and a protein essential for ecdysis in Prorocentrum minimum (Dinophyceae,Prorocentrales)

The specific cell architecture of prorocentroid dinoflagellates is reflected in the internal cell structure, particularly, in cytoskeleton organization. Cytoskeleton arrangement in a Prorocentrum minimum cell was investigated using fluorescent labeling approaches, electron‐microscopy and immunocytochemical methods. The absence of cortical microtubules was confirmed. Phalloidin – tetramethylrhodamine isothiocyanate conjugate staining demonstrated that F‐actin forms a dense layer in the cortical region of the cell; besides, it was detected in the ‘archoplasmic sphere’ adjacent to the nucleus. In some cells the rest of the cytoplasm and the nucleus were also slightly stained. In dividing cells, F‐actin was mainly distributed in the cortical region and in the cleavage furrow. Fluorescent deoxyribonuclease I staining demonstrated more evenly distributed cytoplasmic non‐polymerized actin; the basis of the nuclear actin pool is monomeric actin. It concentrates in the nucleoplasm and forms a meshwork around chromosomes. The significant amount of G‐actin is apparently localized in the P. minimum nucleolus. Assumed involvement of F‐actin in the process of stress‐induced ecdysis – cell cover shedding – was examined. A sharp decrease in the level of ecdysis was observed after treatment with actin‐depolymerizing agent latrunculin B. The fluorescent staining of treated cells demonstrated disturbance of the actin cytoskeleton and disappearance of the cortical F‐actin layer. Our results support the recent data on the actin involvement in fundamental nuclear processes: cytoplasmic F‐actin appears to participate in cell shape determination, cell cover rearrangement and development. Actin may play a substitute role in the absence of cortical microtubules, representing the cytoskeletal basis of P. minimum cell architecture.     

Effect of methotrexate on the leukemic cell cycle in mouse ascitic leukemia L1210]

In cells of L1210 ascite leukemia cells, methotrexate inhibited H3-thymidine incorporation, blocked shortly (during 4 hours) the G1 leads to S transition, and did not affect cells in G2-phase or in the late S phase. Almost half a cell population was degenerated and cells in S- and G1-phases were affected in equal proportion. This may suggest that methotrexate is not S-phase specific for cells of leukemia L1210. A simultaneous administration of vinblastine increases the antitumour effect of methotrexate. Cells in G2-phase constitute, presumably, a significant proportion of cells recovered after methotrexate administration. A comparison of the data obtained with literature evidence shows that in the sensitive (leukemia L1210) and resistant (acute mieloid leukemia of man) forms of leukemia, methotrexate affects cells that are in S-phase, whereas cells being in G1-phase are affected only when the sensitive tumours are treated.     

Mutual regulation of plant phospholipase D and the actin cytoskeleton

Membrane lipids and cytoskeleton dynamics are intimately inter‐connected in the eukaryotic cell; however, only recently have the molecular mechanisms operating at this interface in plant cells been addressed experimentally. Phospholipase D (PLD) and its product phosphatidic acid (PA) were discovered to be important regulators in the membrane–cytoskeleton interface in eukaryotes. Here we report the mechanistic details of plant PLD–actin interactions. Inhibition of PLD by n‐butanol compromises pollen tube actin, and PA rescues the detrimental effect of n‐butanol on F‐actin, showing clearly the importance of the PLD–PA interaction for pollen tube F‐actin dynamics. From various candidate tobacco PLDs isoforms, we identified NtPLDβ1 as a regulatory partner of actin, by both activity and in vitro interaction assays. Similarly to published data, the activity of tobacco PIP₂‐dependent PLD (PLDβ) is specifically enhanced by F‐actin and inhibited by G‐actin. We then identified the NtPLDβ1 domain responsible for actin interactions. Using sequence‐ and structure‐based analysis, together with site‐directed mutagenesis, we identified Asn323 and Thr382 of NtPLDβ1 as the crucial amino acids in the actin‐interacting fold. The effect of antisense‐mediated suppression of NtPLDβ1 or NtPLDδ on pollen tube F‐actin dynamics shows that NtPLDβ1 is the active partner in PLD–actin interplay. The positive feedback loop created by activation of PLDβ by F‐actin and of F‐actin by PA provides an important mechanism to locally increase membrane–F‐actin dynamics in the cortex of plant cells.     

Differences between nucleus and cytoplasm in the degree of actin polymerization

For purposes of studying the degree of polymerization of actin in nuclei, nuclei from 35S-labeled amoebas (Amoeba proteus) were transplanted into unlabeled cells, which were immediately lysed and extracted under conditions considered to stabilize preexisting fibrous actin. The enucleated 35S-donor cells were similarly treated for analysis of cytoplasmic actin. The extraction conditions permitted separation of soluble (unpolymerized or G) actin from pelletable (polymerized or F) actin, and the radioactivity of each was determined after the actin was separated from other proteins by polyacrylamide gel electrophoresis. We found that about 2/3 of the actin within the nucleus is pelletable, whereas only about 1/3 of the cytoplasmic actin is pelletable. We speculate that polymerized actin in the nucleus is involved in the condensation of chromatin.     

Anisotropy decay of labelled actin. Evidence of the flexibility of the peptide chain in F-actin molecules.

G actin, labelled presumably on cysteine-373 with the fluorescent chromophore N-iodoacetyl-N'-(5 sulfo-1-napthyl)-ethylenediamine and purified by Sephacryl S-200 gel chromatography, migrated in one band on polyacrylamide gel electrophoresis and had the same polymerizability as unlabelled purified G actin. Anisotropy decays of labelled actin solutions have been studied at different ionic strengths and protein concentrations. It was found that these anisotropy decays could be fitted by a sum of two exponential functions. Under low ionic strength or below the critical concentrations the longer correlation time (45 ns at 3.5 degrees C) was independent of protein concentration and ionic strength. Above the critical concentration, the longer correlation time increased with ionic strength and protein concentration. In order to take into account that, under these conditions, the solutions contained a mixture of F and G actin at the critical concentration, the anisotropy decays were analysed as a sum of three exponential functions in which the longest correlation time characterized F actin. Since F actin correlation time also depended on actin concentration, an analysis with a sum of four exponential functions was performed, in which two fixed correlation times (100 ns and 900 ns at 3.5 degrees C) were introduced in order to characterize the F actin motions. The lower of these correlation times was attributed to regions where two actin filaments interact side by side, while the shorter one was attributed to filament regions free from intermolecular interactions. The small value of the free F actin correlation time indicates that the protomer peptide chain is very flexible around its C terminus, probably involving the motion of a molecular lobe. This flexibility might be an important factor in the interaction of actin with myosin during the muscular contraction.     

Stabilization of actin by phalloidin: a differential scanning calorimetric study.

We have used differential scanning calorimetry to study the effects of phalloidin on F and G actin stability. For F actin, saturating concentrations of phalloidin induced an important shift on the transition temperature, Tm, from 69.5 degrees C to 83.5 degrees C. However, the calorimetric enthalpy remained unchanged. Using lower phalloidin concentrations, monomers linked to phalloidin, as well as neighboring unlinked monomers, were both stabilized. Contrary to previous reports, phalloidin was also shown to affect G actin, shifting its Tm from 59.5 degrees C to 75 degrees C. Two mechanisms are proposed to explain this finding: first, it could indicate a real interaction of phalloidin with G actin, and second, heating of the specimen during the scan could have induced polymerization of some G actin to the F form. The resulting F polymer would then interact with phalloidin, thus shifting the equilibrium between G and F actin towards the polymeric form.