Reconstitution of contractile actomyosin rings in vesicles.

One of the grand challenges of bottom-up synthetic biology is the development of minimal machineries for cell division. The mechanical transformation of large-scale compartments, such as Giant Unilamellar Vesicles (GUVs), requires the geometry-specific coordination of active elements, several orders of magnitude larger than the molecular scale. Of all cytoskeletal structures, large-scale actomyosin rings appear to be the most promising cellular elements to accomplish this task. Here, we have adopted advanced encapsulation methods to study bundled actin filaments in GUVs and compare our results with theoretical modeling. By changing few key parameters, actin polymerization can be differentiated to resemble various types of networks in living cells. Importantly, we find membrane binding to be crucial for the robust condensation into a single actin ring in spherical vesicles, as predicted by theoretical considerations. Upon force generation by ATP-driven myosin motors, these ring-like actin structures contract and locally constrict the vesicle, forming furrow-like deformations. On the other hand, cortex-like actin networks are shown to induce and stabilize deformations from spherical shapes.

Talin dissociates from RIAM and associates to vinculin sequentially in response to the actomyosin force.

Cells reinforce adhesion strength and cytoskeleton anchoring in response to the actomyosin force. The mechanical stretching of talin, which exposes cryptic vinculin-binding sites, triggers this process. The binding of RIAM to talin could regulate this mechanism. However, the mechanosensitivity of the talin-RIAM complex has never been tested. It is also not known whether RIAM controls the mechanosensitivity of the talin-vinculin complex. To address these issues, we designed an in vitro microscopy assay with purified proteins in which the actomyosin force controls RIAM and vinculin-binding to talin. We demonstrate that actomyosin triggers RIAM dissociation from several talin domains. Actomyosin also provokes the sequential exchange of RIAM for vinculin on talin. The effect of RIAM on this force-dependent binding of vinculin to talin varies from one talin domain to another. This mechanism could allow talin to biochemically code a wide range of forces by selecting different combinations of partners.

The immunohistopathology of glomerular antigens. The glomerular basement membrane, collagen, and actomyosin antigens in normal and diseased kidneys.

The immunofluorescent localization of antisera to human glomerular basement membrane (GBM), collagen, and smooth muscle actomyosin was examined in 15 specimens of normal renal tissue and 98 specimens from patients with renal disease. The anti-GBM and anticollagen antisera normally localize to GBM, while antiactomyosin localizes to the mesangium. Diabetic nephropathy revealed a striking expansion of mesangial material reacting with antiactomyosin. In contrast, the expanded mesangium in membranoproliferative glomerulonephritis did not react with antiactomyosin, and the GBM localization of anti-GBM and anticollagen sera was similarly lost. The thickened GBM in diabetes mellitus and membranous nephropathy reacted with anti-GBM and anticollagen, but with accentuation of staining on the inner aspect of the GBM. In proliferative glomerulonephritis there was a moderate increase in the distribution of actomyosin. Glomerular sclerosis and hyalinization in all diseases studied was accompanied by a loss of immunofluorescent staining for all glomerular antigens, including collagen.

Effects of l-arginine on the physicochemical and gel properties of chicken actomyosin.

The objective of this study is to investigate the effects of l-arginine (Arg) on the physicochemical and gel properties of chicken actomyosin. The results showed that Arg increased the content of surface hydrophobicity and reactive sulfhydryl group of chicken actomyosin, but decreased storage modulus (G0). Also, Arg enhanced the first thermal transition temperature (TM1) but decreased the second thermal transition temperature (TM2). The addition of Arg favored to form a dense and uniform gel with the increased water holding capacity (WHC), strength and transverse relaxation time (T2). These results suggested that Arg may result in the formation of a uniform and continuous gel by changing the structural and thermal behavior of actomyosin in turn, ultimately contributing to the elevated WHC and strength. The results may provide new insight into the effects of Arg on the WHC and texture of meat products in the previous literatures.

Isolation of Cytokinetic Actomyosin Rings from Saccharomyces cerevisiae and Schizosaccharomyces pombe.

Cytokinesis is the final stage of cell division, through which cellular constituents of mother cells are partitioned into two daughter cells resulting in the increase in cell number. In animal and fungal cells cytokinesis is mediated by an actomyosin contractile ring, which is attached to the overlying cell membrane. Contraction of this ring after chromosome segregation physically severs the mother cell into two daughters. Here we describe methods for the isolation and partial purification of the actomyosin ring from the fission yeast Schizosaccharomyces pombe and the budding yeast Saccharomyces cerevisiae, which can serve as in vitro systems to facilitate biochemical and ultrastructural analysis of cytokinesis in these genetically tractable model systems.

Some properties of Physarum actinin. A regulatory protein of actin polymerization.

A factor termed Physarum actinin was isolated and partially purified from plasmodia of a myxomycete, Physarum polycephalum. When Physarum actinin was mixed with purified Physarum or rabbit striated muscle G-actin in a weight ratio of about 1 actinin to 9 actin and then the polymerization of G-actin induced, G-actin polymerized to the ordinary F-actin on addition of 0.1 M KCl. However, it polymerized to Mg-polymer on addition of 2 mM MgCl2. The reduced viscosity (etasp/C) of the Mg-polymer was 1.2 dl/g, about one-seventh of that of the F-actin (7.4 dl/g). The sedimentation coefficient of the Mg-polymer was 22.8 S, almost the same as that of the F-actin (29.4 S). The Mg-polymer showed the specific ATPase activity of the order of 1 . 10(-3) mumol ATP/mg actin per min. It was shown that Physarum actinin copolymerized with G-actin to form Mg-polymer on addition of 2 mM MgCl2. The molecular weights of Physarum actinin were about 90 000 in salt-free or slat solutions and 43 000 in a dodecyl sulfate solution. The range of salting out with ammonium sulfate was 50--65% saturation, which was different from that of Physarum actin (15--35% saturation). Physarum actinin did not interact with Physarum myosin or muscle heavy meromyosin. When the weight ratio of actinin to actin increased, the flow birefringence of the formed Mg-polymer decreased, and it became almost zero at the weight ratio of 1 actinin to 5 actin. ATPase activity reached the maximum level (2.2 . 10(-3) mumol ATP/mg actin per min) at the same ratio. On the addition of Physarum actinin to purified Physarum F-actin which had been polymerized on addition of 2 mM MgCl2 the viscosity decreased rapidly, suggesting that the F-actin filaments were broken in the smaller fragments or that they transformed to Mg-polymers. A factor with properties similar to Physarum actinin was isolated from acetone powder of sea urchin eggs.

Observations on the kinetics, subunit composition, and sulfhydryl reactivity of myosin from Physarum polycephalum.

A highly purified preparation of myosin from Physarum polycephalum has been shown by sodium dodecyl sulfate polyacrylamide gel electrophoresis to contain heavy chains and only one molecular weight class of light chains, of approx. 15 000 daltons. Kinetic investigations of the Ca2+-ATPase and Mg2+-ATPase (ATP phosphohydrolases, EC 3.6.1.3) at pH 8.0 gave Km and V values of 17.3 muM and 1.25 mumol Pi/min per mg, and 2.4 muM and 0.12 mumol Pi/min per mg, respectively. Adenylyl imidodiphosphate, a beta-gamma-imido ATP analog, inhibited the ATPase activity of Physarum myosin competitively with Ki values equal to 350 and 12 muM in the presence of Ca2+ and Mg2+, respectively. The ATPase activity of Physarum myosin was inhibited at a very low rate (t1/2 = 24 h) by the ATP analog, 6,6'-dithiobis(inosinyl imidodiphosphate), with concentrations of inhibitor previously shown to inactivate (t1/2 approximately 10 min) skeletal and cardiac myosins rapidly by reacting with key cysteines.

Myosin from arterial smooth muscle: isolation following actin depolymerization.

The contractile proteins from arterial smooth muscle are highly soluble, and can be extracted at I = 0.05. However, they can be precipitated by a prolonged dialysis at pH 6 to give an actomyosin with a high, although variable, actin:myosin ratio. The sedimentation behavior of this actomyosin at high ionic strength was examined as a function of pH, protein concentration and composition by preparative ultracentrifugation. Comparisons with synthetic skeletal muscle actomyosins of similar composition demonstrated significant differences in the behaviors of these two systems. It was found that much smooth muscle actomyosin is not dissociated by normally relaxing conditions, and that it sediments at a slower rate than F-actin. The solubility of the supernatant protein (a myosin-enriched actomyosin) in 0.2 M K Cl (pH 7) depended on the pH during centrifugation. A lower solubility was associated only with a higher actin concentration in the supernatant, suggesting a dependence on actin repolymerization. Pure myosin was selectively precipitated from the supernatant by polyethylene glycol-6000, but only when the protein was soluble at low ionic strength. The solubility of purified myosin was similar to that of myosin from striated muscles. A relationship between the presence of depolymerized actin and the high solubility of smooth muscle contractile proteins is suggested.

Actomyosin extracted from bovine aortic intima.

Actomyosin extracted from bovine aortic intima with a KCl-ATP medium of low ionic strength, but not with a KCl medium of high ionic strength, exhibited Ca2+ sensitivity. Aortic medial actomyosin extracted with a medium of high ionic strength retained the Ca2+ sensitivity. These differences in extractability suggest that actomyosin of the aortic intima is different from that of the aortic media.

Superprecipitation of gizzard actomyosin, and tension in gizzard muscle skinned fibers in the presence of nucleotides other than ATP.

1. Nucleotides which are known to be poor substrates for myosin kinase (ITP, GTP, UTP and CTP) are poor relative to ATP at producing Ca2+-sensitive superprecipitation or tension in smooth-muscle-derived experimental systems. The ability of these nucleotides to support Ca2+-sensitive superprecipitation or tension in striated muscle fibers depends on fiber type, but ranges from poor for GTP to excellent for CTP. 2. Thiophosphate analogs of ITP and GTP (ITP gamma S and GTP gamma S) are poor at irreversibly activating superprecipitation in smooth muscle actomyosin relative to ATP gamma S. 3. [gamma-32P]ITP is poor relative to [gamma-32P]ATP as a substrate of the endogenous myosin light-chain kinase in gizzard actomyosin. 4. The results provide further independent evidence in both gizzard actomyosin and skinned fibers that the smooth muscle Ca2+-control system is based on myosin phosphorylation.

The influence of hydrogen ion concentration on calcium binding and release by skeletal muscle sarcoplasmic reticulum.

Calcium release and binding produced by alterations in pH were investigated in isolated sarcoplasmic reticulum (SR) from skeletal muscle. When the pH was abruptly increased from 6.46 to 7.82, after calcium loading for 30 sec, 80-90 nanomoles (nmole) of calcium/mg protein were released. When the pH was abruptly decreased from 7.56 to 6.46, after calcium loading for 30 sec, 25-30 nmole of calcium/mg protein were rebound. The calcium release process was shown to be a function of pH change: 57 nmole of calcium were released per 1 pH unit change per mg protein. The amount of adenosine triphosphate (ATP) bound to the SR was not altered by the pH changes. The release phenomenon was not due to alteration of ATP concentration by the increased pH. Native actomyosin was combined with SR in order to study the effectiveness of calcium release from the SR by pH change in inducing super-precipitation of actomyosin. It was found that SR, in an amount high enough to inhibit superprecipitation at pH 6.5, did not prevent the process when the pH was suddenly increased to 7.3, indicating that the affinity of SR for calcium depends specifically on pH. These data suggest the possible participation of hydrogen ion concentration in excitation-contraction coupling.

Activation of the adenosine triphosphatase of Limulus polyphemus actomyosin by tropomyosin.

Purified actin does not stimulate the adenosine triphosphatase (ATPase) activity of Limulus myosin greatly. The ATPase activity of such reconstituted preparations is only about one-fourth the ATPase of myofibrils or of natural actomyosin. Actin preparations containing tropomyosin, however, activate Limulus myosin fully. Both the tropomyosin and the actin preparations appear to be pure when tested by different techniques. Tropomyosin combines with actin but not with myosin and full activation is reached at a tropomyosin-to-actin ratio likely to be present in muscle. Tropomyosin and actin of several different animals stimulate the ATPase of Limulus myosin. Tropomyosin, however, is not required for the ATPases of scallop and rabbit myosin which are fully activated by pure actin alone. Evidence is presented that Limulus myosin, in the presence of ATP at low ionic strength, has a higher affinity for actin modified by tropomyosin than for pure actin.

Rates of synthesis of actomyosin in atria and ventricles of the perfused working rat heart.

Actomyosin from hearts perfused in vitro with [U-14C] phenylalanine and the remaining plasma amino acids was purified by standard techniques. The rate of actomyosin synthesis was expressed relative to actomyosin protein, to total protein and to total RNA. The rate of atrial total protein synthesis was twice the ventricular rate correlating with the RNA/protein ratios of the compartments. The actomyosin contents relative to total protein were not significantly different in atria and ventricles. The rate of actomyosin synthesis in atria was 2 to 3 times greater than in the ventricles when expressed relative to actomyosin or total protein. Synthesis rates of actomyosin expressed relative to total RNA were similar in the two compartments. These results suggest that the rate of turnover of actomyosin in the atria is 2 to 3 times the ventricular rate and that the greater rate of synthesis of total protein synthesis in atria is reflected in the rate of synthesis of specific intramyocytic proteins.

Alpha1-syntrophin has distinct binding sites for actin and calmodulin.

Overlay and co-sedimentation assays using recombinant alpha1-syntrophin proteins revealed that two regions of alpha1-syntrophin, i.e. aa 274-315 and 449-505, contain high-affinity binding sites for F-actin (Kd 0.16-0.45 microM), although only a single high-affinity site (Kd 0.35 microM) was detected in the recombinant full-length syntrophin. We also found that actomyosin fractions prepared from both cardiac and skeletal muscle contain proteins recognized by anti-syntrophin antibody. These data suggest a novel role for syntrophin as an actin binding protein, which may be important for the function of the dystrophin-glycoprotein complex or for other cell functions. We also found that alpha1-syntrophin binds calmodulin at two distinct sites with high (Kd 15 nM) and low (Kd 0.3 microM) affinity.

An activating factor (tropomyosin) for the superprecipitation of actomyosin prepared from scallop adductor muscles.

An activating factor for the superprecipitation of actomyosin reconstructed from scallop smooth muscle myosin and rabbit skeletal muscle F-actin was purified from thin filaments of scallop smooth and striated muscles. Two components were obtained from the smooth muscle and one from the striated muscle. All three components similarly affected the actomyosin ATPase activity. According to the results of analysis involving double reciprocal plotting of the ATPase activity versus F-actin concentration, the activating factor for superprecipitation decreased the apparent dissociation constants of actomyosin about 30 to 110 times. The activation of the superprecipitation by the factor, therefore, may be due to the enhancement of the affinity between F-actin and myosin in the presence of ATP. The activating factor was identified as tropomyosin based on it mobility on polyacrylamide gel electrophoresis and on the recovery of the Ca2+-sensitivity of purified rabbit skeletal actomyosin in the presence of troponin.

Non-polymerizable tropomyosin and control of the superprecipitation of actomyosin.

Non-polymerizable tropomyosin was prepared by the digestion of several C-terminal residues of tropomyosin with carboxypeptidase A [EC 3.4.12.2]. The intrinsic viscosity and molecular weight of the non-polymerizable tropomyosin were almost the same as those of untreated tropomyosin. Like untreated tropomyosin, the non-polymerizable tropomyosin in combination with troponin repressed the superprecipitation of actomyosin in the absence of calcium, while this repression was released by addition of calcium. However, the curve representing the superprecipitation rate as a function of pCa was less steep than that found with actomyosin containing untreated tropomyosin: in the former case, the rate increased to a plateau over about 2 pCa units, while in the latter case, it did so over about 1 pCa unit. These experimental results provide evidence that the "co-operation" in the regulation mechanism of skeletal muscle contraction, which is indicated by the steep curve of the contraction versus pCa relation, is mediated by tropomyosin-tropomyosin interaction along the thin filament.

Light chains of abalone myosin. UV absorption difference spectrum and resensitization of desensitized scallop myosin.

1. Abalone myosin consisted of one kind of heavy chain and two kinds of light chain according to SDS gel electrophoresis. The molecular weights of the light chains were estimated as 16,600 daltons (Light Chain-1: LC-1) and 14,500 daltons (Light Chain-2: LC-2). 2. The amino acid composition of LC-2 was not appreciably different from that of LC-1 except that the valine residue was 1 mol per mol of LC-2. 3. both LC-1 and LC-2 showed a calcium-induced UV absorption difference spectrum through the apparent binding constants for Ca2+ were low (2.5 x 10(-3) M for LC-1 and 3.2 x 10(-4) M for LC-2). 4. The modification of carboxyl groups of LC-2 by 1-ethyl-3(3-dimethylaminopropyl)carbodiimide caused the disappearance of the calcium-induced UV absorption difference spectrum. 5. Manganese ion could also induce a UV absorption difference spectrum with these light chains although the concentration of Mn2+ required to produce the difference spectrum was very high. 6. Abalone LC-2 bound to desensitized scallop myosin and restored the calcium sensitivity of the myosin but LC-1 did not.

ATPase characteristics of myosin from nematode Caenorhabditis elegans purified by an improved method. Formation of myosin-phosphate-ADP complex and ATP-induced fluorescence enhancement.

Myosin was purified rapidly from the nematode Caenorhabditis elegans by an improved method. Crude actomyosin was extracted from the worms at low ionic strength. Paramyosin was removed by repeating the precipitation of myosin filaments in the presence of Mg2+ and the dissolution of them in 0.6 M NaCl. Actin was removed by ultracentrifugation in the presence of Mg-ATP and finally by column chromatography on DEAE-cellulose. This method gave a good yield of myosin (20-30 mg from 50 g wet weight of worms), and its EDTA(K+)-ATPase activity was about 3-fold higher than that of myosin prepared by the method of Harris and Epstein (1979). ATP hydrolysis by nematode myosin showed an initial Pi-burst due to formation of the myosin-phosphate-ADP complex. Tryptophan fluorescence of myosin was enhanced about 8% by ATP. The relationship between the structure and function of myosin is discussed based on the above results and the amino acid sequences of myosins from rabbit skeletal muscle and Caenorhabditis elegans.

Determination of the protein components of native thin filaments isolated from natural actomyosin: nebulin and alpha-actinin are associated with actin filaments.

A new method was developed for extracting natural actomyosin with full length connectin (titin) and nebulin from rabbit skeletal muscle. To determine the protein components of native thin filaments, thin filaments were isolated from natural actomyosin by sedimentation in a H2O/D2O/sucrose density gradient. Both alpha-actinin and nebulin were cosedimented with actin filaments, while connectin was not. This shows that the native thin filaments contained alpha-actinin and nebulin. This indicates that the native thin filaments were more complicated than synthetic filaments reconstituted from actin, tropomyosin, and troponin. It is known that synthetic filaments are less Ca2+ sensitive than native thin filaments. This difference in Ca2+ sensitivity may be due to the differences in components and/or the different structures of native and synthetic filaments. The newly developed methods described here for extracting natural actomyosin and for isolating native thin filaments are useful for addressing these important problems related to the structure and function of native thin filaments.

Purification and characterization of an 'actomyosin' complex from Escherichia coli W3110.

An 'actomyosin' complex was purified from Escherichia coli W3110 using selective precipitation. The complex contains three major components of 19.5, 18.5 and 17 kDa. The 19.5- and 17-kDa proteins were purified by electroelution, peptide mapped and N-terminally sequenced. The structural gene for the 17-kDa protein was found to have been previously identified in an operon containing several other genes including the essential lpxA, lpxB and dnaE. The possible function of the 17-kDa protein and the other 'actomyosin' components is discussed.