The influence of contact-inhibited growth and of agents which alter cell morphology on the levels of G- and F-actin in cultured cells

The amounts of G-actin and F-actin were measured in cultured cells grown under various conditions. The percent of total actin as F-actin in monolayer cultures of asynchronous cells was 72.4% in Chinese hamster ovary (CHO) cells, 57.7% in HeLa cells, 69.8% in V79 cells, and 79.5% in 1080 cells. Actin comprises 2.4–3.1% of the total protein in these cell lines. Treatment of cells with 20 μM cytochalasin B (CB) caused different cytological effects from treatment with 10 μM colchicine, but the effects characteristic of each drug were observed throughout the range of cell lines used. Of the five cell lines treated with CB only the V79 and CHO cells showed a decrease (5–8%) in the level of F-actin. Colchicine treatment of HeLa cells resulted in a 13% increase in the percent F-actin, but similar treatment of CHO cells caused no significant change in F-actin. Therefore, a change in the steady state level of F-actin is not necessary for the observed cell shape change. The F-actin levels in CHO cells treated with 7 mM procaine decreased from 72 to 65% over the first 15 min of exposure, a time during which the cells rounded. After continuous exposure of the cells to procaine for 1 h, the F-actin percentage returned to control levels and the cells, though abnormal in appearance, flattened on the culture dish. The relationship between the level of F-actin and cell density was studied in the 10T_1/2 cells, a cell line which demonstrates density-dependent growth regulation. While contact inhibition was accompanied by a decrease in the F-actin percentage (from >95% to about 60%) in one strain of 10T_1/2 cells, two other strains of the same cells progressed from log phase growth (highly motile) to late plateau phase (non-motile, contact-inhibited) with a constant level of F-actin (about 60%). A spontaneous transformant of this cell line, which no longer demonstrated contact-inhibited cell growth, also maintained the same constant F-actin (60%). Thus, the maintenance of contact-inhibited growth control does not appear to depend upon the net distribution of actin between the globular and filamentous forms.     

State of actin in gastric parietal cells

Remodeling of theapical membrane-cytoskeleton has been suggested to occur when gastricparietal cells are stimulated to secrete HCl. The present experimentsassayed the relative amounts of F-actin and G-actin in gastric glandsand parietal cells, as well as the changes in the state of actin onstimulation. Glands and cells were treated with a Nonidet P-40extraction buffer for separation into detergent-soluble (supernatant)and detergent-insoluble (pellet) pools. Two actin assays were used toquantitate actin: the deoxyribonuclease I binding assay to measureG-actin and F-actin content in the two pools and a simple Western blotassay to quantitate the relative amounts of actin in the pools.Functional secretory responsiveness was assayed by aminopyrineaccumulation. About 5% of the total parietal cell protein is actin,with about 90% of the actin present as F-actin. Stimulation of acidsecretion resulted in no measurable change in the relative amounts ofG-actin and cytoskeletal F-actin. Treatment of gastric glands withcytochalasin D inhibited acid secretion and resulted in a decrease inF-actin and an increase in G-actin. No inhibition of parietal cellsecretion was observed when phalloidin was used to stabilize actinfilaments. These data are consistent with the hypothesis thatmicrofilamentous actin is essential for membrane recruitment underlyingparietal cell secretion. Although the experiments do not eliminate theimportance of rapid exchange between G- and F-actin for the secretoryprocess, the parietal cell maintains actin in a highly polymerizedstate, and no measurable changes in the steady-state ratio of G-actin to F-actin are associated with stimulation to secrete acid.

     

Effect of Hypothyroidism on Different Forms of Actin in Rat Cerebral Neuronal Cultures Studied by an Improved DNase I Inhibition Assay

An improved DNase I inhibition assay for the filamentous actin (F-actin) and monomeric actin (G-actin) in brain cells has been developed. Unlike other methods, the cell lysis conditions and postlysis treatments, established by us, inhibited the temporal inactivation of actin in the cell lysate and maintained a stable F-actin/G-actin ratio for at least 4-5 h after lysis. The new procedure allowed separate quantitation of the noncytoskeletal F-actin in the Triton-soluble fraction (12,000 g, 10 min supernatant) that did not readily sediment with the Triton-insoluble cytoskeletal F-actin (12,000 g, 10 min pellet). We have applied this modified assay system to study the effect of hypothyroidism on different forms of actin using primary cultures of neurons derived from cerebra of neonatal normal and hypothyroid rats. Our results showed a 20% increase in the Triton-insoluble cytoskeletal F-actin in cultures from hypothyroid brain relative to normal controls. In the Triton-soluble fraction, containing the G-actin and the noncytoskeletal F-actin, cultures from hypothyroid brain showed a 15% increase in G-actin, whereas the F-actin remained unaltered. The 10% increase in total actin observed in this fraction from hypothyroid brain could be totally accounted for by the enhancement of G-actin. The mean F-actin/G-actin ratio in this fraction was about 30% higher in the cultures from normal brain compared to that of the hypothyroid system, which indicates that hypothyroidism tends to decrease the proportion of noncytoskeletal F-actin relative to G-actin.     

Membrane-associated actin from the microvillar membranes of ascites tumor cells

A membrane fraction (MF2) has been purified from isolated microvilli of the MAT-C1 subline of the 13762 rat mammary ascites adenocarcinoma under conditions which cause F-actin depolymerization. This membrane preparation contains actin as a major component, although no filamentous structures are observed by transmission electron microscopy. Membranes were extracted with a Triton X-100-containing actin-stabilizing buffer (S buffer) or actin-destabilizing buffer (D buffer). In D buffer greater than 90% of metabolically labeled protein and glycoprotein was extracted, and 80-90% of these labeled species was extracted in S buffer. When S buffer extracts of MF2 were fractionated by either gel filtration on Sepharose 6 B or rate-zonal sucrose density gradient centrifugation, most of the actin was found to be intermediate in size between G- and F-actin. In D buffer most of the MF2 actin behaved as G-actin. Extraction and gel filtration of intact microvilli in S buffer also showed the presence of the intermediate form of actin, indicating that it did not arise during membrane preparation. When [35S]methionine-labeled G-actin from ascites cells was added to S buffer extracts of MF2 and chromatographed, all of the radioactivity chromatographed as G-actin, indicating that the intermediate form of actin did not result from an association of G-actin molecules during extraction or chromatography. The results of this study suggest that the microvillar membrane fraction is enriched in an intermediate form of actin smaller than F-actin and larger than G-actin.     

Regulation of actin dynamics is critical for endothelial barrier functions

We tested the hypothesis that the equilibrium between F- and G-actin in endothelial cells modulates the integrity of the actin cytoskeleton and is important for the maintenance of endothelial barrier functions in vivo and in vitro. We used the actin-depolymerizing agent cytochalasin D and jasplakinolide, an actin filament (F-actin) stabilizing and promoting substance, to modulate the actin cytoskeleton. Low doses of jasplakinolide (0.1 microM), which we have previously shown to reduce the permeability-increasing effect of cytochalasin D, had no influence on resting permeability of single-perfused mesenteric microvessels in vivo as well as on monolayer integrity. The F-actin content of cultured endothelial cells remained unchanged. In contrast, higher doses (10 microM) of jasplakinolide increased permeability (hydraulic conductivity) to the same extent as cytochalasin D and induced formation of intercellular gaps in cultured myocardial endothelial (MyEnd) cell monolayers. This was accompanied by a 34% increase of F-actin and pronounced disorganization of the actin cytoskeleton in MyEnd cells. Furthermore, we tested whether an increase of cAMP by forskolin and rolipram would prevent the cytochalasin D-induced barrier breakdown. Conditions that increase intracellular cAMP failed to block the cytochalasin D-induced permeability increase in vivo and the reduction of vascular endothelial cadherin-mediated adhesion in vitro. Taken together, these data support the hypothesis that the state of polymerization of the actin cytoskeleton is critical for maintenance of endothelial barrier functions and that both depolymerization by cytochalasin D and hyperpolymerization of actin by jasplakinolide resulted in an increase of microvessel permeability in vivo. However, cAMP, which is known to support endothelial barrier functions, seems to work by mechanisms other than stabilizing F-actin.     

Kinetic analysis of F-actin depolymerization in polymorphonuclear leukocyte lysates indicates that chemoattractant stimulation increases actin filament number without altering the filament length distribution

The rate of filamentous actin (F-actin) depolymerization is proportional to the number of filaments depolarizing and changes in the rate are proportional to changes in filament number. To determine the number and length of actin filaments in polymorphonuclear leukocytes and the change in filament number and length that occurs during the increase in F-actin upon chemoattractant stimulation, the time course of cellular F-actin depolymerization in lysates of control and peptide-stimulated cells was examined. F-actin was quantified by the TRITC-labeled phalloidin staining of pelletable actin. Lysis in 1.2 M KCl and 10 microM DNase I minimized the effects of F-actin binding proteins and G-actin, respectively, on the kinetics of depolymerization. To determine filament number and length from a depolymerization time course, depolymerization kinetics must be limited by the actin monomer dissociation rate. Comparison of time courses of depolymerization in the presence (pointed ends free) or absence (barbed and pointed ends free) of cytochalasin suggested depolymerization occurred from both ends of the filament and that monomer dissociation was rate limiting. Control cells had 1.7 +/- 0.4 x 10(5) filaments with an average length of 0.29 +/- 0.09 microns. Chemo-attractant stimulation for 90 s at room temperature with 0.02 microM N-formylnorleucylleucylphenylalanine caused a twofold increase in F-actin and about a two-fold increase in the total number of actin filaments to 4.0 +/- 0.5 x 10(5) filaments with an average length of 0.27 +/- 0.07 microns. In both cases, most (approximately 80%) of the filaments were quite short (less than or equal to 0.18 micron). The length distributions of actin filaments in stimulated and control cells were similar.     

Isolation and characterization of covalently cross-linked actin dimer

Covalently cross-linked actin dimer was isolated from rabbit skeletal muscle F-actin reacted with phenylenebismaleimide (Knight, P., and Offer, G. (1978) Biochem. J. 175, 1023-1032). The UV spectrum of the purified cross-linked actin dimer, in a nonpolymerizing buffer, was very similar to that of native F-actin and not to the spectrum of G-actin. Cross-linked actin dimer polymerized to filaments that were indistinguishable in the electron microscope from F-actin made from native G-actin and that were similar to native F-actin in their ability to activate the Mg2+-ATPase of myosin subfragment-1. The critical concentrations of polymerization of cross-linked actin dimer in 0.5 mM and 2.0 mM MgCl2, 2 to 4 microM, and 1 to 2 microM, respectively, were similar to the values for native G-actin. Cross-linked actin dimer contained 2 mol of bound nucleotide/mol of dimer. One bound nucleotide exchanged with ATP in solution with a t 1/2 of 55 min and with ADP with a t 1/2 of 5 h. The second bound nucleotide exchanged much more slowly. The more rapidly exchangeable site contained 10 to 15% bound ADP.Pi and 85 to 90% bound ATP while the second site contained much less, if any, bound ADP.Pi. Cross-linked actin dimer had an ATPase activity in 0.5 mM MgCl2 that was 7 times greater than the ATPase activity of native G-actin and that was also stimulated by cytochalasin D. These data are discussed in relation to the possible role of ATP in actin polymerization and function with the speculation that the cross-linked actin dimer may serve simultaneously as a useful model for each of the two different ends of native F-actin.     

Localization of thymosin β10 in breast cancer cells: relationship to actin cytoskeletal remodeling and cell motility

Beta-thymosins are polypeptides involved in the regulation of actin polymerization and thymosin β10 and β4 have been implicated in sequestration of monomeric (G-) actin. Additionally, experimental overexpression of thymosin β10 has been found to result in increases in F-actin bundles as well as in cell motility and spreading. We have studied the distribution of endogenously expressed thymosin β10 in cultured human breast cancer cell lines. Both unperturbed monolayer cultures and wound-healing models were examined using double-staining for thymosin β10 and polymerized (F-) actin. Our findings show that thymosin β10 is expressed in all three-cancer cell lines (SK-BR-3, MCF-7 and MDA-MB-231) studied. No or little staining was detected in confluent cells, whereas strong staining occurred in semiconfluent cells and in cells populating monolayer wounds. Importantly, the distribution of staining for thymosin β10 was inverse of staining for F-actin. These data support a physiological role for thymosin β10 in sequestration of G-actin as well as in cancer cell motility.     

Regulation of endothelial nitric oxide synthase by the actin cytoskeleton

In the present study, the association ofendothelial nitric oxide synthase (eNOS) with the actin cytoskeleton inpulmonary artery endothelial cells (PAEC) was examined. We found thatthe protein contents of eNOS, actin, and caveolin-1 were significantly higher in the caveolar fraction of plasma membranes than in the noncaveolar fraction of plasma membranes in PAEC. Immunoprecipitation of eNOS from lysates of caveolar fractions of plasma membranes in PAECresulted in the coprecipitation of actin, and immunoprecipitation ofactin from lysates of caveolar fractions resulted in thecoprecipitation of eNOS. Confocal microscopy of PAEC, in which eNOS waslabeled with fluorescein, F-actin was labeled with Texasred-phalloidin, and G-actin was labeled with deoxyribonuclease Iconjugated with Texas red, also demonstrated an association betweeneNOS and F-actin or G-actin. Incubation of purified eNOS with purifiedF-actin and G-actin resulted in an increase in eNOS activity. Theincrease in eNOS activity caused by G-actin was much higher than thatcaused by F-actin. Incubation of PAEC with swinholide A, an actinfilament disruptor, resulted in an increase in eNOS activity, eNOSprotein content, and association of eNOS with G-actin and in a decrease in the association of eNOS with F-actin. The increase in eNOS activitywas higher than that in eNOS protein content in swinholide A-treatedcells. In contrast, exposure of PAEC to phalloidin, an actin filamentstabilizer, caused decreases in eNOS activity and association of eNOSwith G-actin and increases in association of eNOS with F-actin. Theseresults suggest that eNOS is associated with actin in PAEC and thatactin and its polymerization state play an important role in theregulation of eNOS activity.

     

Mechanisms responsible for F-actin stabilization after lysis of polymorphonuclear leukocytes

While actin polymerization and depolymerization are both essential for cell movement, few studies have focused on actin depolymerization. In vivo, depolymerization can occur exceedingly rapidly and in a spatially defined manner: the F-actin in the lamellipodia depolymerizes in 30 s after chemoattractant removal (Cassimeris, L., H. McNeill, and S. H. Zigmond. 1990. J. Cell Biol. 110:1067-1075). To begin to understand the regulation of F-actin depolymerization, we have examined F-actin depolymerization in lysates of polymorphonuclear leukocytes (PMNs). Surprisingly, much of the cell F-actin, measured with a TRITC-phalloidin-binding assay, was stable after lysis in a physiological salt buffer (0.15 M KCl): approximately 50% of the F-actin did not depolymerize even after 18 h. This stable F-actin included lamellar F-actin which could still be visualized one hour after lysis by staining with TRITC-phalloidin and by EM. We investigated the basis for this stability. In lysates with cell concentrations greater than 10(7) cells/ml, sufficient globular actin (G-actin) was present to result in a net increase in F-actin. However, the F-actin stability was not solely because of the presence of free G-actin since addition of DNase I to the lysate did not increase the F-actin loss. Nor did it appear to be because of barbed end capping factors since cell lysates provided sites for barbed end polymerization of exogenous added actin. The stable F-actin existed in a macromolecular complex that pelleted at low gravitational forces. Increasing the salt concentration of the lysis buffer decreased the amount of F-actin that pelleted at low gravitational forces and increased the amount of F-actin that depolymerized. Various actin-binding and cross-linking proteins such as tropomyosin, alpha-actinin, and actin-binding protein pelleted with the stable F-actin. In addition, we found that alpha-actinin, a filament cross-linking protein, inhibited the rate of pyrenyl F-actin depolymerization. These results suggested that actin cross-linking proteins may contribute to the stability of cellular actin after lysis. The activity of crosslinkers may be regulated in vivo to allow rapid turnover of lamellipodia F-actin.     

Nucleotide exchange between cytosolic ATP and F-actin-bound ADP may be a major energy-utilizing process in unstimulated platelets

About 40% of the cytosolic ADP of human platelets is tightly bound to protein and the complex is precipitated from the cells by 43% ethanol. We show here that this ADP is bound to F-actin by three criteria (a) copurification with F-actin, (b) specific extraction with water and (c) by specific interaction with DNase I. Platelets contain 0.3 mumol/10(11) cells of this F-actin--ADP complex compared to the total actin content of 0.8 mumol/10(11) cells, which is consistent with the view that actin is maintained in different pools (F-actin--ADP, profilactin, G-actin). In intact platelets the F-actin-bound ADP turns over rapidly and we have determined a turnover rate at 37 degrees C of 0.1 +/- 0.025 s-1 by using a double-labelling procedure. This rapid turnover indicates that F-actin in intact platelets is in a very dynamic state, which may be necessary for rapid responses to stimuli. If it is assumed that the source of the ADP bound to F-actin is cytosolic ATP, the turnover of F-actin ADP measured represents an ATP-consuming process that would account for up to 50% of total ATP consumption in resting platelets.     

Chemotactic peptide modulation of actin assembly and locomotion in neutrophils

To determine the relationship between the state of actin polymerization in neutrophils and the formyl-methionyl-leucyl-phenylalanine (fMLP)-induced changes in the locomotive behavior of neutrophils, the mean rate of locomotion (mROL), the percent G-actin, and the relative F-actin content of neutrophils were determined. The mROL was quantified by analysis of the locomotion of individual cells; the percentage of total actin as G-actin was measured by DNase I inhibition; and the F-actin was determined by fluorescence-activated cell sorter (FACS) analysis of nitrobenzoxadiazol (NBD)-phallacidin-stained neutrophils. Neutrophils stimulated with fMLP exhibit a change in their mROL that is biphasic and dose dependent. The mROL of neutrophils exposed to 10(-8) M fMLP, the KD, is 11.9 +/- 2.0 micron/min (baseline control 6.2 +/- 1.0 micron/min). At 10(-6) M fMLP, the mROL returns to baseline levels. Stimulation of neutrophils with fMLP also induces action polymerization. Evidence for actin polymerization includes a 26.5% reduction in G-actin and a twofold increase in the amount of NBD-phallacidin staining of cells as determined by FACS analysis. The NBD-phallacidin staining is not due to phagocytosis, is inhibited by phalloidin, requires cell permeabilization, and is saturable at NBD-phallacidin concentrations greater than 10(-7)M. The fMLP-induced increase in NBD-phallacidin staining occurs rapidly (less than 2 min), is temperature dependent, and is not due to cell aggregation. Since NBD-phallacidin binds specifically to F-actin, the increase in fluorescent staining of cells likely reflects an increase in the F-actin content of fMLP-stimulated cells. FACS analysis of NBD-phallacidin-stained cells shows that the relative F-actin content of neutrophils stimulated with 10(-11)-10(-8)M fMLP increases twofold and remains increased at concentrations greater than 10(-8)M fMLP. Therefore, the fMLP-induced increase in F-actin content of neutrophils as determined by FACS analysis of NBD-phallacidin-stained cells coincides with a decrease in G-actin and correlates with increased mROL of neutrophils under some (10(-11)-10(-8)M fMLP) but not all (greater than 10(-8)M fMLP) conditions of stimulation. Quantification of the F-actin content of nonmuscle cells by FACS analysis of NBD-phallacidin-stained cells may allow rapid assessment of the state of actin polymerization and correlation of that state with the motile behavior of nonmuscle cells.     

Regulation of the microfilament system in normal and polyoma virus transformed cultured (BHK) cells

The content and state of actin in baby hamster kidney (BHK) cells before and after transformation with polyoma virus were examined by deoxyribonuclease assay and gel electrophoresis followed by dye elution. The actin content of the transformed cells, relative to total cell protein, was lower than that of the normal cells by 30-50%. In both the normal and transformed cells the greater part of the total actin was found on lysis to be in the monomeric state. Cytoplasmic and membrane fractions of the two cell lines were, in qualitative terms, very similar in their protein compositions. The plasma membrane isolated from the transformed cells was richer in actin than that from the untransformed, and both membrane fractions contained proteins corresponding to myosin, filamin and alpha-actinin on SDS-polyacrylamide gels. The cell extract from both the normal and transformed lines formed an actin-based gel on incubation at 30 degrees C, although the amount of the cross-linked actin was much smaller in the latter. This was a consequence not only of the lower concentration of total actin in the cell, but also, presumably, of a gross relative deficiency in the concentration or activity of filament cross-linking protein(s) in the cytoplasm. Thus, small aliquots of cytoplasmic fractions from transformed cells, when added to an excess of exogenous F-actin, were able to cross-link the filaments to a much smaller extent than those from the normal cells. A similar range of proteins was found to be associated with the actin gels formed from both cell extracts. One conspicuous difference was that a species migrating in SDS-gel electrophoresis as a doublet with a subunit molecular weight of about 58,000, and tentatively identified as intermediate filament protein, was replaced in the transformed cells by a single band. Filament cross-linking activity of the cytoplasmic fractions was enhanced by addition of Triton extracts of crude membranes, although the latter were not capable of cross-linking exogenous F-actin on their own. The effect of Triton extracts was much greater in the case of membranes from the transformed cells. The cytoplasmic fractions of BHK cells contain capping protein(s) and/or complexes of such proteins with actin; these reveal themselves by the propensity of the extracts to nucleate polymerization of exogenous G-actin. This activity was more abundant in transformed cells, despite their lower actin content. Their membranes were also more effective in nucleating G-actin polymerization, indicating the presence of a greater number of filament ends.(ABSTRACT TRUNCATED AT 400 WORDS)     

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.     

Isolation of polymerization-competent cytoplasmic actin by affinity chromatography on immobilized DNAse I using formamide as eluant

Formamide dissociates the G-actin . DNAse-I complex and is therefore suitable as an alternative to the eluant containing 3 M guanidinium hydrochloride, suggested originally by Lazarides and Lindberg [Proc, Natl Acad. Sci. USA, 71, 4742--4746 (1974)], to elute actin from immobilized DNAse-I agarose. Formamide provides the advantage of being a much weaker denaturant than guanidinium hydrochloride and being a nonionic substance. In the concentration necessary for the dissociation of the G-actin . DNAse-I complex (approximately 10 M) formamide denatures actin only slowly (half-time approximately 150 min at 2 degrees C) and thus allows the recovery of a large fraction of actin in a polymerization-competent form from the affinity column. Based on these findings a rapid two-step procedure for the isolation of non-muscle G-actin from cultured cells is described. The actin obtained in high yield and purity (greater than 90%) and can readily polymerize to F-actin.     

Peroxynitrite induces F-actin depolymerization and blockade of myosin ATPase stimulation

Treatment of F-actin with the peroxynitrite-releasing agent 3-morpholinosydnonimine (SIN-1) produced a dose-dependent F-actin depolymerization. This is due to released peroxynitrite because it is not produced by 'decomposed SIN-1', and it is prevented by superoxide dismutase concentrations efficiently preventing peroxynitrite formation. F-actin depolymerization has been found to be very sensitive to peroxynitrite, as exposure to fluxes as low as 50-100nM peroxynitrite leads to nearly 50% depolymerization in about 1h. G-actin polymerization is also impaired by peroxynitrite although with nearly 2-fold lower sensitivity. Exposure of F-actin to submicromolar fluxes of peroxynitrite produced cysteine oxidation and also a blockade of the ability of actin to stimulate myosin ATPase activity. Our results suggest that an imbalance of the F-actin/G-actin equilibrium can account for the observed structural and functional impairment of myofibrils under the peroxynitrite-mediated oxidative stress reported for some pathophysiological conditions.     

Atomic force microscopy and light scattering of small unilamellar actin-containing liposomes

Three-dimensional networks of filamentous actin (F-actin) encapsulated inside phosphatidylcholine liposomes are currently being used in an effort to model the cytoskeleton and plasma membrane of eukaryotic cells. In this article, unilamellar lipid vesicles consisting of egg yolk-derived phosphatidylcholine encapsulating monomeric actin (G-actin) were made via extrusion in low ionic strength buffer (G-buffer). Vesicle shape and structure in these dispersions was studied using a combination of fluid-tapping atomic force microscopy, and multiangle static light scattering. After subjecting the liposome dispersion to high ionic strength polymerization buffer (F-buffer) containing K(+) ions, atomic force microscopy imaging and light scattering of these liposomes indicated the formation of specialized structures, including an overall liposome structure transformation from spherical to torus, disk-shaped geometries and tubular assemblies. Several atomic force microscopy control measurements were made to ascertain that the specialized structures formed were not due to free G-actin and F-actin self-assembling on the sample surface, plain liposomes exposed to G- and F-buffer, or liposomes encapsulating G-actin. Liposomes encapsulating G-actin assumed mostly thin disk shapes and some large irregularly shaped aggregates. In contrast, liposomes encapsulating polymerized actin assumed mostly torus or disk shapes along with some high aspect ratio tubular structures.     

A 133Cs nuclear magnetic resonance study of endothelial Na(+)-K(+)-ATPase activity: can actin regulate its activity?

Using (133)Cs+ NMR, we developed a technique to repetitively measure, in vivo, Na(+)-K(+)-ATPase activity in endothelial cells. The measurements were made without the use of an exogenous shift reagent, because of the large chemical shift of 1.36 +/- 0.13 ppm between intra- and extracellular Cs+. Intracellularly we obtained a spin lattice relaxation time (T1) of 2.0 +/- 0.3 s, and extracellular T1 was 7.9 +/- 0.4 s. Na(+)-K+ pump activity in endothelial cells was determined at 12 +/- 3 nmol Cs+ x min(-1) x (mg Prot)[-1] under control conditions. When intracellular ATP was depleted by the addition of 5 mM 2-deoxy-D-glucose (DOG) and NaCN to about 5% of control, the pump rate decreased by 33%. After 80 min of perfusion with 5 mM DOG and NaCN, reperfusion with control medium rapidly reestablished the endothelial membrane Cs+ gradient. Using (133)Cs+ NMR as a convenient tool, we further addressed the proposed role of actin as a regulator of Na(+)-K+ pump activity in intact cells. Two models of actin rearrangement were tested. DOG caused a rearrangement of F-actin and an increase in G-actin, with a simultaneous decrease in ATP concentration. Cytochalasin D, however, caused an F-actin rearrangement different from that observed for DOG and an increase in G-actin, and cellular ATP levels remained unchanged. In both models, the Na(+)-K(+)-pump activity remained unchanged, as measured with (133)Cs NMR. Our results demonstrate that (133)Cs NMR can be used to repetitively measure Na(+)-K(+)-ATPase activity in endothelial cells. No evidence for a regulatory role of actin on Na(+)-K(+)-ATPase was found.     

Comparisons of Endothelial Cell G- and F-Actin Distribution in Situ and in Vitro

Numerous studies have described the F-actin cytoskeleton; however, little information relevant to C-actin is available. The actin pools of bovine aortic endothelial cells were examined using in situ and in vitro conditions and fluorescent probes for G-(deoxyribonuclease I.0.3 μM) or F-actin (phalloidin, 0.2 μM). Cells in situ displayed a diffuse G-actin distribution, while F-actin was concentrated in the cell periphery and in fine stress fibers that traversed some cells. Cells of subconfluent or just confluent cultures demonstrated intense fluorescence, with many F-actin stress fibers. Postconfluent cultures resembled the condition in situ; peripheral F-actin was prominent, traversing actin stress fibers were greatly reduced and fluorescent intensity was diminished. Postconfluency had little influence on G-actin. with only an enhancement in the intensity of G-actin punctate fluorescence. When post-confluent cultures were incubated with cytochalasin D (15 min; 10^--⁴ M), F-actin networks were disrupted and actin punctate and diffuse fluorescence increased. G-actin fluorescence was not altered by the incubation. Although its unstructured nature may account for the minor changes observed, the stability of the G-actin pool in the presence of notable F-actin modulations suggested that filamentous actin was the key constituent involved in these actin cytoskeletal alterations. A separate finding illustrated that the concomitant use of actin probes with image enhancement and fluorescent microscopy could reveal simultaneously the G- and F-actin pools within the same cell.     

Hyper-mobility of water around actin filaments revealed using pulse-field gradient spin-echo 1H NMR and fluorescence spectroscopy

This paper reports that water molecules around F-actin, a polymerized form of actin, are more mobile than those around G-actin or in bulk water. A measurement using pulse-field gradient spin-echo (1)H NMR showed that the self-diffusion coefficient of water in aqueous F-actin solution increased with actin concentration by ～5%, whereas that in G-actin solution was close to that of pure water. This indicates that an F-actin/water interaction is responsible for the high self-diffusion of water. The local viscosity around actin was also investigated by fluorescence measurements of Cy3, a fluorescent dye, conjugated to Cys 374 of actin. The steady-state fluorescence anisotropy of Cy3 attached to F-actin was 0.270, which was lower than that for G-actin, 0.334. Taking into account the fluorescence lifetimes of the Cy3 bound to actin, their rotational correlation times were estimated to be 3.8 and 9.1ns for F- and G-actin, respectively. This indicates that Cy3 bound to F-actin rotates more freely than that bound to G-actin, and therefore the local water viscosity is lower around F-actin than around G-actin.