Demonstration of actin in neurosecretory cells by treatment with nitrobenzoxadiazole-phallacidin

Serial sections containing neurosecretory cells from chicken hypothalamus were cut after fixation in formaldehyde and embedding in paraffin. Sections were exposed to NBD-Ph (nitrobenzoxadiazole-phallacidin) and showed evidence of containing actin. By using a medium with sodium borohydride, non-specific fluorescence could be excluded.     

In vivo visualization of actin dynamics and actin interactions by BiFC

The method of bimolecular fluorescence complementation (BiFC) enables selective visualization of protein interactions. While BiFC complex formation under in vitro conditions is considered to be essentially irreversible, there are hints that under in vivo conditions BiFC complex formation can be reversible. In the present study we used the BiFC method to visualize in vivo actin cytoskeleton dynamics. We demonstrate that in living cells formation of actin/actin BiFC complexes is reversible. Furthermore, we show heterologous binding between actin and protein kinase C delta (PKCdelta). Treatment with phorbol esters caused translocation of actin/PKCdelta complexes from the cytosol to the plasma membrane independent of an intact actin cytoskeleton. Our experiments demonstrate that the BiFC method might be a useful tool to investigate participation of the actin cytoskeleton in regulation of cell function.     

In vivo importance of actin nucleotide exchange catalyzed by profilin

The actin monomer-binding protein, profilin, influences the dynamics of actin filaments in vitro by suppressing nucleation, enhancing nucleotide exchange on actin, and promoting barbed-end assembly. Profilin may also link signaling pathways to actin cytoskeleton organization by binding to the phosphoinositide PIP(2) and to polyproline stretches on several proteins. Although activities of profilin have been studied extensively in vitro, the significance of each of these activities in vivo needs to be tested. To study profilin function, we extensively mutagenized the Saccharomyces cerevisiae profilin gene (PFY1) and examined the consequences of specific point mutations on growth and actin organization. The actin-binding region of profilin was shown to be critical in vivo. act1-157, an actin mutant with an increased intrinsic rate of nucleotide exchange, suppressed defects in actin organization, cell growth, and fluid-phase endocytosis of pfy1-4, a profilin mutant defective in actin binding. In reactions containing actin, profilin, and cofilin, profilin was required for fast rates of actin filament turnover. However, Act1-157p circumvented the requirement for profilin. Based on the results of these studies, we conclude that in living cells profilin promotes rapid actin dynamics by regenerating ATP actin from ADP actin-cofilin generated during filament disassembly.     

In vivo acylation of Dictyostelium actin with palmitic acid

Cells of Dictyostelium discoideum were incubated with [³H]palmitic acid during development, and recovery of the fatty acid label in soluble and membrane-associated proteins was investigated. One of the major labeled proteins was found exclusively in the soluble fraction. This protein, with an apparent mol. wt. of 44 kd, was identified as actin based on its labeling with a monoclonal anti-actin antibody, its coincidence with the major [³⁵S]methionine-labeled protein after two-dimensional electrophoresis and its binding to a DNase I affinity column. The ³H-label was resistant to chloroform-methanol extraction and boiling in SDS-containing buffer. After partial purification by preparative SDS-polyacrylamide gel electrophoresis, the 44-kd protein was treated with KOH, the fatty acids released were derivatized to methyl esters and palmitic acid methylester was identified by gas-liquid chromatography.     

In vivo covalent cross-linking of cellular actin by the Vibrio cholerae RTX toxin

Enteric pathogens often export toxins that elicit diarrhea as a part of the etiology of disease, including toxins that affect cytoskeletal structure. Recently, we discovered that the intestinal pathogen Vibrio cholerae elicits rounding of epithelial cells that is dependent upon a gene we designated rtxA. Here we investigate the association of rtxA with the cell-rounding effect. We find that V. cholerae exports a large toxin, RTX (repeats-in-toxin) toxin, to culture supernatant fluids and that this toxin is responsible for cell rounding. Furthermore, we find that cell rounding is not due to necrosis, suggesting that RTX toxin is not a typical member of the RTX family of pore-forming toxins. Rather, RTX toxin causes depolymerization of actin stress fibers and covalent cross-linking of cellular actin into dimers, trimers and higher multimers. This RTX toxin-specific cross-linking occurs in cells previously rounded with cytochalasin D, indicating that G-actin is the toxin target. Although several models explain our observations, our simultaneous detection of actin cross-linking and depolymerization points toward a novel mechanism of action for RTX toxin, distinguishing it from all other known toxins.     

Modulation of microfilament protein composition by transfected cytoskeletal actin genes.

HuT-14T is a highly tumorigenic fibroblast cell line which exhibits a reduced steady-state level of beta-actin due to coding mutations in one of two beta-actin alleles. The normal rate of total actin synthesis could be restored in some clones of cells following transfection of the functional beta-actin gene but not following transfection of the functional gamma-actin gene. In gamma-actin gene-transfected substrains that have increased rates of gamma-actin synthesis, beta-actin synthesis is further reduced in a manner consistent with an autoregulatory mechanism, resulting in abnormal ratios of actin isoforms. Thus, both beta- and gamma-actin proteins can apparently regulate the synthesis of their coexpressed isoforms. In addition, decreased synthesis of normal beta-actin seems to correlate with a concomitant down-regulation of tropomyosin isoforms.     

Identification of a functional switch for actin severing by cytoskeletal proteins

Actin severing is vital for the organization of the actin cytoskeleton during cell motility. Severing of F-actin by the homologous proteins villin and gelsolin requires unphysiologically high calcium concentrations (20-200 microM). Here we demonstrate that high calcium releases an autoinhibited conformation in villin that is maintained by two low affinity calcium binding sites (aspartic acids 467 and 715) that interact with a cluster of basic residues in the S2 domain of villin. Mutation of either of these sites as well as tyrosine phosphorylation alters the conformation of villin resulting in a protein that can sever actin in nanomolar calcium. These results suggest that tyrosine phosphorylation rather than high calcium may be the mechanism by which villin and other related proteins sever actin in vivo.     

Signalling for increased cytoskeletal actin in neutrophils

The addition of fMet-Leu-Phe, platelet-activating factor, leukotriene B4 or sodium propionate to rabbit neutrophils causes an increase in the amount of actin associated with the cytoskeletal actin. The increase is rapid, transient and inhibitable by pertussis toxin. On the other hand, the addition of phorbol 12-myristate 13-acetate or NH4Cl causes a pertussis toxin-insensitive increase in cytoskeletal actin. The effects of the phorbol ester and fMet-Leu-Phe are additive, and in the presence of the phorbol ester, the fMet-Leu-Phe induced effect declines to the level produced by the phorbol ester. These results suggest that: one of the signalling pathways for actin polymerization involves a guanine-nucleotide binding protein; actin polymerization mediated through this pathway is rapid, transient and inhibitable by pertussis toxin, and a second signalling pathway is independent of this guanine-nucleotide binding protein; actin polymerization, mediated by this second pathway, is somewhat slower, sustained and insensitive to pertussis toxin. These results are discussed in terms of a model which includes gelsolin, profilin and the pertussis toxin-sensitive guanine-nucleotide binding protein.     

In vivo identification of Tetrahymena actin probed by DMSO induction of nuclear bundles

We report the first successful identification of actin, an ubiquitous contractile protein, in Tetrahymena pyriformis (strain W). We employed dimethyl sulfoxide (DMSO) as a probe to induce the formation of actin bundles in the cell nucleus [1, 2] through disruption of cytoplasmic microfilament organization [3, 4]. The cells were incubated for 30 min at 22 °C in the inorganic medium of Prescott & James [5] containing 10% DMSO, and observed under a transmission electron microscope (TEM). Microfilarment bundles were formed in interphase macronuclei, and these microfilaments, approx. 6 nm in diameter, could be decorated by rabbit skeletal muscle heavy meromyosin (HMM) in the glycerinated model. In many cases, the bundles formed closely parallel to natively existing bundles of microtubules. Interestingly, these microtubules had prominent striation with 15–16 nm periodicity. SDS-polyacrylamide gel electrophoresis was designed to show the low actin content of Tetrahymena cells in comparison with that of Dictyostelium. Actin was suggested to comprise less than 1.7% of the total protein in Tetrahymena, whereas as much as 6% was actin in Dictyostelium cells. In assessing the physiological significance of the bundle formation, we further performed HMM and myosin subfragment-1 (S1)-binding studies to clarify the organization process and the polarity of the DMSO-induced nuclear actin filaments by using the tannic acid staining technique [6]. Randomly oriented short filaments appeared in the nucleus treated with 10% DMSO for 10 min. These filaments became elongated and associated with each other to form loose bundles in the following 10 min. With 30-min treatment, the filaments were organized and large bundles with single axes developed. With these well-developed bundles, the Student's t-test was performed on 172 pairs of neighboring filaments and the probability (p) of the deviation from random polarity was 0.08, suggesting that the filaments were organized in an anti-parallel manner. The results show that the DMSO induction of nuclear actin is a powerful tool to demonstrate the existence of cellular actin in vivo and to study the mechanism of microfilament organization in relation to cell physiological activities.     

Cytoplasmic actin patterns in Physarum as revealed by NBD-phallacidin staining

Fluorescently labeled phallacidin, a F-actin specific drug, was used to demonstrate the morphological variety in the cytoskeletal actin pattern of thin-spread plasmodia of the acellular slime mould Physarum polycephalum. The patterns observed in phallacidin-stained specimens consisted of a polygonal network in the anterior region, and of longitudinal as well as helically twisted fibrils in plasmodial strands of the posterior region. These observations are in complete accordance with our recent results obtained on comparable plasmodia by immunofluorescence microscopy using specific antibodies against actin.     

Filling gaps in signaling to actin cytoskeletal remodeling

A recent publication in the April 4 issue of Cell advances our understanding of stimulus response coupling leading to actin remodeling. It describes the identification of a novel membrane component Mig-2 that engages filamin A through a new intermediary, migfilin, to stimulate actin assembly and cell spreading on a substrate of extracellular matrix.     

Studying the effects of actin cytoskeletal destabilization on cell cycle by cofilin overexpression

The significance of actin cytoskeleton on cell growth was historically studied using toxic drugs, such as cytochalasin. However, it is possible that unpredictable effects of these agents may have influenced the reported observations. In our study, we have established a drug-free system using cofilin overexpression to investigate the relationship between actin filaments and cell cycle progression. Cofilin is a member of the actin depolymerization factor (ADF)/cofilin family, cofilin cDNA was cloned to a tetracycline-inducible gene expression vector and stably transfected to human lung cancer H1299 epithelial cells. Destabilization of actin filaments and morphological change was detected in cofilin overexpressing cells by actin analysis and microscopy, respectively. Measurements of growth rates showed that cell proliferation was retarded in cells with overexpressed cofilin. Also, cell cycle analysis showed that approx 90% of cofilin overexpressing cells were arrested in G1 phase, which is consistent with previous reports that drug-mediated disruption of actin filaments can cause G1 phase arrest. Taken together, cofilin overexpression cell model provides evidence that the effects of actin cytoskeletal destabilization on cell cycle progression can be studied using molecular approach instead of drug.     

In vivo and in vitro phosphorylation and subcellular localization of trypanosomatid cytoskeletal giant proteins

Promastigote forms of Phytomonas serpens, Leptomonas samueli, and Leishmania tarentolae express cytoskeletal giant proteins with apparent molecular masses of 3,500 kDa (Ps 3500), 2,500 kDa (Ls 2500), and 1,200 kDa (Lt 1200), respectively. Polyclonal antibodies to Lt 1200 and to Ps 3500 specifically recognize similar polypeptides of the same genera of parasite. In addition to reacting with giant polypeptides of the Leptomonas species, anti-Ls 2500 also cross reacts with Ps 3500, and with a 500-kDa polypeptide of Leishmania. Confocal immunofluorescence and immunogold electron microscopy showed major differences in topological distribution of these three proteins, though they partially share a common localization at the anterior end of the cell body skeleton. Furthermore, Ps 3500, Ls 2500, and Lt 1200 are in vivo phosphorylated at serine and threonine residues, whereas, in vitro phosphorylation of cytoskeletal fractions reveal that only Ps 3500 and Ls 2500 are phosphorylated. Heat treatment (100 degrees C) of high salt cytoskeletal extracts demonstrates that Ps 3500 and Ls 2500 remain stable in solution, whereas Lt 1200 is denatured. Kinase assays with immunocomplexes of heat-treated giant proteins show that only Ps 3500 and Ls 2500 are phosphorylated. These results demonstrate the existence of a novel class of megadalton phosphoproteins in promastigote forms of trypanosomatids that appear to be genera specific with distinct cytoskeletal functions. In addition, there is also evidence that Ps 3500 and Ls 2500, in contrast to Lt 1200, seem to be autophosphorylating serine and threonine protein kinases, suggesting that they might play regulatory roles in the cytoskeletal organization.     

Beneficial role of amino acids in mitigating cytoskeletal actin glycation and improving F-actin content: In vitro

Aims: The actin filaments present in circulating leukocytes facilitate their passage through microvenules and capillaries by helping in their deformability. Decreased deformability of granulocytes is now known to cause occlusion of the retinal microcapillaries leading to hypoxia and the subsequent development of diabetic retinopathy. Structural and functional loss of proteins, due to non-enzymatic glycation and glycoxidation, has been reported to cause diabetic pathogenesis. As amino acids have been earlier reported to have antidiabetic properties, the present study involves the investigation of the susceptibility of the cytoskeletal actin to glycation and its mitigation by free amino acids. This study also involves quantifying F-actin in cultured mononuclear cells obtained from diabetic and normal healthy volunteers and on the effect of glucose and free amino acids on F-actin content. Methods: Commercial non-muscle actin and actin immuno-pre-cipitated from granulocytes obtained from (a) normal healthy human volunteers and (b) patients with type 2 diabetes mellitus were subjected to glycation studies using [U] ¹⁴C glucose. The effect of free amino acids, as antiglycating agents, was determined using various concentrations of lysine, arginine, alanine, aspartic acid and glutamic acid. F-actin content in cultured mononuclear cells was estimated by flow cytometry using fluorescein isothiocynate (FITC)-Phalloidin. Results: Commercial actin at physiological conditions of pH and temperature was found to undergo non-enzymatic glycation. The extent of in vitro glycation was significantly low (P<0.001) in actin isolated from patients with type2 diabetes when compared to the non-diabetic group, suggesting an increased in vitro structural modification of actin in patients with diabetes. All the free amino acids tested were found to have varying degrees of antiglycating effect. The F-actin content in the intact mononuclear cells obtained from diabetic patients was found to be low when compared with normal healthy volunteers (P<0.001). Similarly the F-actin content was significantly low when the normal mononuclear cells were incubated with glucose. This effect was reversed upon the addition of free amino acids to the incubation mixture. Conclusions: Free amino acids can play a positive role in improving leukocyte deformability by mitigating cytoskeletal actin glycation and improving F-actin content.     

In vivo imaging of the actin polymerization state with two-photon fluorescence anisotropy

Using two-photon fluorescence anisotropy imaging of actin-GFP, we have developed a method for imaging the actin polymerization state that is applicable to a broad range of experimental systems extending from fixed cells to live animals. The incorporation of expressed actin-GFP monomers into endogenous actin polymers enables energy migration FRET (emFRET, or homoFRET) between neighboring actin-GFPs. This energy migration reduces the normally high polarization of the GFP fluorescence. We derive a simple relationship between the actin-GFP fluorescence polarization anisotropy and the actin polymer fraction, thereby enabling a robust means of imaging the actin polymerization state with high spatiotemporal resolution and providing what to the best of our knowledge are the first direct images of the actin polymerization state in live, adult brain tissue and live, intact Drosophila larvae.