Actomyosin interactions with insulin-storage granules in vitro.

Interactions between actomyosin and insulin storage granules isolated from rat islets of Langerhans have been examined in a simple system in vitro, which allows comparison of the sedimentation of the granules in the presence of absence of actomyosin in various conditions. Actomyosin altered granule-sedimentation rates in a manner consistent with the binding of the granules of actomyosin filaments. This interaction was enhanced by addition of ATP (1.5 mM) but unaltered by addition of CaCl2, by calmodulin or by calmodulin in the presence of 10 microM-CaCl2. Addition of EGTA (0.1 mM), cyclic AMP (10 microM) of cytochalasin B (10 microgram/ml) were also without effects in these conditions. Pre-incubation of granules with phospholipase c did not affect granule-actomyosin interaction. Ultrastructural studies showed close contacts between the membranes of the granules and actomyosin filaments. The results indicate the possibility that actomyosin might provide the motile force for granule translocation during the insulin secretory process.     

Heat-induced Gelation of Myosin Filaments at a Low Salt Concentration

The heat-induced gelation properties of myosin in low salt concentration were studied. Freshly prepared myosin formed gels with an extremely high rigidity in 0.1 to 0.3 m KC1 at pH 6.0 on heating. This high heat-induced gel formability of myosin filaments diminished during storage, concomitant with the loss of the filament formability inherent in the native myosin. Presumably intermolecular aggregation was the cause of this loss during storage. The difference in the heat-induced gelation of myosin filaments at a low salt concentration (0.2 m KC1) and that of myosin monomers at a high salt concentration (0.6 m KC1) was clearly.distinguishable from their gelling behavior. The high gelation ability of freshly prepared myosin filaments upon heating seems to develop through the interfilamental head-head aggregation on the surface of the filaments without involving the tail portion of the molecule.     

Freeze denaturation of enzymes and its prevention with additives

Freeze inactivation of LDH, MDH, ADH, G-6-PDH, and PK and its prevention with additives such as sodium glutamate and albumin were studied. LDH, MDH, ADH, G-6-PDH, and PK, each lost their activity during frozen storage at -20 degrees C. The speed of the inactivation differed in each. The stability of the enzymes increased with the increase of the enzyme concentration. Sodium glutamate and albumin prevented the freeze inactivation. While the activity of the LDH solution frozen without additives was almost lost during a day of frozen storage, those frozen with either glutamate (0.2 M) or albumin (0.1%) added decreased less quickly. The residual activity after 1 day was 50% the initial prefreeze value for the former and 10% for the latter, respectively. Combined use of glutamate and albumin prevented the inactivation the best and maintained the initial activity almost completely over 6 weeks. The enzymes tested lost some part of their activity when their solutions were diluted by the media. This inactivation was prevented to a significant extent by the addition of sodium glutamate and/or albumin to the diluting media.     

ELECTRON MICROSCOPIC INVESTIGATIONS OF ACTOMYOSIN AS A FUNCTION OF IONIC STRENGTH

Natural actomyosin at µ = 0.6 appears in various forms, including the regular arrowhead structures originally reported by Huxley (1), when it has been stained negatively with 1% uranyl acetate. In addition to the arrowheads, thin whiskers, 700–1200 A in length and 20 A in width, attached to the arm of the arrowheads have been demonstrated. The dimensions of the whiskers and arms of the arrowheads are practically the same as those of the light meromyosin (LMM) and the heavy meromyosin (HMM) moieties of the single myosin molecule, respectively. Changes in the electron microscopically distinguishable elements during aggregation of natural actomyosin on reduction of the ionic strength have been observed. At µ = 0.4, partial aggregation of the LMM whiskers begins to result in some parallel alignment of the arrowhead-bearing filaments (acto-HMM). In the range of µ = 0.3–0.1, the LMM whiskers merge into smooth filaments which are arranged alternatingly with arrowhead-bearing filaments. Thus, lateral aggregation of composite actomyosin filaments (acto-HMM + LMM whiskers) results with the LMM moieties as links. This view is supported by the following facts: (a) acto-HMM is devoid of whiskers and does not show lateral aggregation at µ = 0.1; (b) natural actomyosin digested with trypsin at µ = 0.6, which was followed by removal of LMM aggregates at low ionic strength, is essentially the same as acto-HMM at µ = 0.1; and (c) digestion with trypsin of natural actomyosin at µ = 0.2 for varying periods of time leads to a separation of arrowhead-bearing filaments from LMM aggregates.     

Nuclear magnetic resonance investigation of the state of water in protein solution.

The line width of the NMR signal of water protons in solutions of native actomyosin and actomyosin denatured by heat, acetone or urea was measured over the temperature range from -10 degrees to below the freezing point. The line widths of the water band which increased exponentially with decreasing temperature were compared with each other and also with those of the corresponding control solution without actomyosin. The line broadening observed for native actomyosin solution on lowering the temperature was significantly smaller than that for heat-denatured actomyosin solution. This difference implies that this signal is sensitive to conformational perturbations of the protein. In addition, the temperature dependence of the line width for heat-, acetone-, or urea-denatured actomyosin solution was similar to that for the corresponding control solution. These phenomena can be interpreted in terms of the state of water associated with the hydrophobic and hydrophilic residues. Similar NMR studies of actomyosin solution containing dimethyl sulfoxide (DMSO) or dimethylformamide (DMF) showed that DMSO and DMF prevent the formation of ice crystals until about -70 degrees, suggesting that the cryoprotective effects of DMSO and DMF are due to the change in the state of water described above. These differences in temperature dependence between the sample and control solutions are well-correlated with the viscosity of the solution. This correlation is useful for elucidation of the mechanism of the protein denaturation.     

Membrane structure of nonactivated and activated human blood platelets as revealed by freeze-fracture: evidence for particle redistribution during platelet contraction

The distribution of intramembrane particles of nonactivated and activated human blood platelets was studied by freeze-fracture under various experimental conditions to see whether morphological evidence for a structural coupling between the platelet actomyosin system and the fibrin network in a retracting clot could be established. Membrane particles were evenly distributed in nonactivated platelets; the total number (E + P faces) was approximately 1,500/micrometers 2 of membrane, and there were two to three times more particles present on the E face than on the P face. Transformation of discoid platelets to "spiny spheres" by cooling did not change the particle distribution. Platelet activation and aggregation by serum or ADP caused no change in membrane particle density or distribution. Particle distribution was not changed in Ca2+-activated platelets fixed immediately before fibrin formation, but after fibrin formation and during clot retraction, particles were sometimes most frequent on the P face and tended to form distinct clusters, and aggregates of E face pits were observed. Blood platelets contain contractile proteins that are distinct as filaments in platelets in retracting clots. We suggest that the redistribution of particles seen in activated platelets during clot retraction reflects the esablishment of mechanical transmembrane links between the platelet actomyosin system and the fibrin net. The P-face particle clusters may represent sites of force transmission between actin filaments bonded to the inside of the membrane and the fibrin network at the outside. Thus, whereas membrane particles may not be directly involved in the attachment of actin filaments to membranes, the transmission of the force of the contractile system to an exterior substrate apparently involves the intramembrane particles.     

ELECTRON MICROSCOPE OBSERVATIONS ON MYOSIN FROM PHYSARUM POLYCEPHALUM

Myosin has been separated from Physarum polycephalum actomyosin in confirmation of the results of Hatano and Tazawa. In an intermediate step, myosin-enriched actomyosin has also been obtained. The mean yield of free myosin was 4.4 mg from 100 g of mold. It was obtained as water-clear solutions at µ = 0.055 with calcium ATPase activity of up to 0.5 µM P_i/min per mg. Negatively stained preparations were examined by electron microscopy. Physarum myosin in 0.5 M KCl interacted with actin from rabbit skeletal muscle to form polarized arrowhead complexes similar to but less regular than those of natural actomyosin from muscle or myosin-enriched Physarum actomyosin. The Physarum myosin-enriched actomyosin at low ionic strength displayed evidence of head-to-tail and tail-to-tail aggregation attributable to the myosin component. Yet Physarum myosin alone did not produce detectable filaments at µ = 0.055 at pH 7, 6.5, or 5.8, nor when dialyzed against 0.01 M ammonium acetate, nor when the dielectric constant of the medium was reduced. However, aggregation approaching the extent of ‘thick filaments’ up to 0.3 µ long was found in some preparations of myosin-enriched actomyosin put into solutions containing adenosine triphosphate. Myosin alone in such solutions did not form filaments. The results are compatible with the idea that head-to-tail aggregations are favored by actin-myosin interactions in Physarum, possibly due to alignment of the extended or tail portions of this myosin molecule.     

Inhibition of rabbit liver fructose 1,6-biphosphatase by AMP: effect of temperature and physiological concentrations of cations and anions

Turkey gizzard smooth muscle myofibrils, the actin of which is composed of 75% smooth muscle γ-isoactin and 25% nonmuscle β-isoactin, were separated into an actomyosin and a cytoskeletal fraction. Isoelectric focusing analysis of the actomyosin actin showed it was 80% γ-isoactin and 20% β-isoactin. It thus appears that the major actin in the tissue is also the major form involved in force generation. When the cytoskeletal material was extracted with low-ionic-strength solution for 18 h at 4 °C, the actin released was 95% γ and 5% β compared with the 75:25 ratio found in the original cytoskeletal material. The extracted material revealed the presence of F-actin filaments and high-molecular-weight aggregates. Little of the material was in a low-molecular-weight form. On the other hand, extraction of the cytoskeletal material with 0.6 m KI resulted in the two isoactins being extracted in the same proportions in which they were found in the original cytoskeletal material. However, when this KI-extracted material was subsequently chromatographed on Bio-Gel A-5m equilibrated with 0.6 m KCl, the γ-isoactin migrated predominantly as a very high molecular weight form while the β-isomer moved in the lower-molecular-weight range of the elution profile. This aggregation behavior displayed by the γ-isoactin was not observed with the γ-isoactin in the actomyosin fraction. These results show that the two gizzard isoactins in the cytoskeletal residue behave very differently in response to various extraction media, and are consistent with possible differential isoactin utilization in gizzard smooth muscle.     

Micron-scale supramolecular myosin arrays help mediate cytoskeletal assembly at mature adherens junctions

Epithelial cells assemble specialized actomyosin structures at E-Cadherin–based cell–cell junctions, and the force exerted drives cell shape change during morphogenesis. The mechanisms that build this supramolecular actomyosin structure remain unclear. We used ZO-knockdown MDCK cells, which assemble a robust, polarized, and highly organized actomyosin cytoskeleton at the zonula adherens, combining genetic and pharmacologic approaches with superresolution microscopy to define molecular machines required. To our surprise, inhibiting individual actin assembly pathways (Arp2/3, formins, or Ena/VASP) did not prevent or delay assembly of this polarized actomyosin structure. Instead, as junctions matured, micron-scale supramolecular myosin arrays assembled, with aligned stacks of myosin filaments adjacent to the apical membrane, overlying disorganized actin filaments. This suggested that myosin arrays might bundle actin at mature junctions. Consistent with this idea, inhibiting ROCK or myosin ATPase disrupted myosin localization/organization and prevented actin bundling and polarization. We obtained similar results in Caco-2 cells. These results suggest a novel role for myosin self-assembly, helping drive actin organization to facilitate cell shape change.     

Calcium ion-dependent myosin from decapod-crustacean muscles.

Ca2+ regulation of arthropod actomyosin adenosine triphosphatase is associated with both the thin filaments, as in vertebrates, and with the myosin, as in molluscs. The actomyosin of decapod-crustacean fast muscles was previously considered to be an exception, displaying only a Ca2+-regulatory system linked to the thin filaments and not a myosin-linked regulatory system. In the present study, myosin regulation is demonstrated in a variety of decapod muscles when they are tested under more physiological ionic conditions. Myosin regulation is shown by using mixtures of pure rabbit actin with myofibrils, with actomyosin and with purified myosin, and in each case the adenosine triphosphatase is Ca2+ dependent. Myosin regulation may also occur in vertebrate striated muscle, but seemingly is lost during purification of the myosin.     

Stretch-induced growth of blowfly muscle

The expansion of the adult blowfly after it has emerged from the puparium was accompanied by an increase in the length of the longitudinal and tergo-sternal flight muscles by 26% and of the tergo-trochanteral leg muscle by 30%. The increases in muscle length were accompanied by similar increases in sarcomere length. Over the 2 hr between emergence and expansion the activity of the actomyosin ATPase increased by over 3 fold and the amount of actomyosin per thorax increased by 3 fold. Ligaturing the proboscis of the newly-emerged fly prevented the expansion of the fly, prevented the increase in the length of the muscles and sarcomeres and the increase in actomyosin activity and quantity. Stretching is proposed as the stimulus inducing increases in the length of the thick and thin filaments.     

The status within,an Autobiography by Francois Jacob; Basic Book Inc., New York, 1988, 326 pp. $22.95

The interactions of ram spermatozoa with exogenous liposomes of varying composition were studied, with the aim of examining the mechanisms by which some lipids protect against cold-induced damage during cryostorage. Liposomes containing various preparations of phosphatidylcholine and cholesterol enhanced sperm survival during storage at 5°C, both in terms of motility and acrosomal integrity. A membrane-fluidizing agent, A₂C, was slightly deleterious in this respect. Cholesterol-containing liposomes were not superior in their effects to those prepared without cholesterol. Thus stabilization of the plasma membrane by cholesterol loading may be unimportant. When sodium vanadate was used as a functional probe of membrane integrity, the cryoprotective effects of lipids were apparent despite increased plasma membrane permeability. Incubation of spermatozoa with positively charged liposomes, containing stearyl-amine, caused considerable loss of motility and acrosomal damage, coupled with cellular aggregation. There was also some evidence that the presence of calcium lessened the effectiveness of liposomes in protecting spermatozoa against damage during cooling.     

Actin cross-linking and inhibition of the actomyosin motor.

Intrastrand cross-linking of actin filaments by ANP, N-(4-azido-2-nitrophenyl) putrescine, between Gln-41 in subdomain 2 and Cys-374 at the C-terminus, was shown to inhibit force generation with myosin in the in vitro motility assays [Kim et al. (1998) Biochemistry 37, 17801-17809]. To clarify the immobilization of which of these two sites inhibits the actomyosin motor, the properties of actins with partially overlapping cross-linked sites were examined. pPDM (N,N'-p-phenylenedimaleimide) and ABP [N-(4-azidobenzoyl) putrescine] were used to obtain actin filaments cross-linked ( approximately 50%) between Cys-374 and Lys-191 (interstrand) and Gln-41 and Lys-113 (intrastrand), respectively. ANP, ABP, and pPDM cross-linked filaments showed similar inhibition of their sliding speeds and force generation with myosin ( approximately 25%) in the in vitro motility assays. In analogy to ANP cross-linking of actin, pPDM and ABP cross-linkings did not change the strong S1 binding to actin and the V(max) and K(m) parameters of actomyosin ATPase. The similar effects of these three cross-linkings reveal the tight coupling between structural elements of the subdomain 2/subdomain 1 interface and show the importance of its dynamic flexibility to force generation with myosin. The possibility that actin cross-linkings inhibit rate-limiting steps in motion and force generation during myosin cross-bridge cycle was tested in stopped-flow experiments. Measurements of the rates of mantADP release from actoS1 and ATP-induced dissociation of actoS1 did not reveal any differences between un-cross-linked and ANP cross-linked actin in these complexes. These findings are discussed in terms of the uncoupling between force generation and other aspects of actomyosin interactions due to a constrained dynamic flexibility of the subdomain 2/subdomain 1 interface in cross-linked actin filaments.     

Proteinase Enzyme System of Lactic Streptococci II. Role of Membrane Proteinase in Cellular Function

The effect of several environmental conditions on the structure and activity of a membrane-associated proteinase from Streptococcus lactis was investigated. The activity of the enzyme varied with pH. Before storage at 3 C, maximal activity occurred at pH 6.0, but was minimal at this pH after storage. At all pH values tested, the enzyme was inactivated after storage. After storage at 3 C, the enzyme showed gross structural alterations with a concomitant loss of activity. Gel filtration and sedimentation velocity data indicated that inactivation of the enzyme was the result of aggregation to higher molecular weight forms. p-Hydroxymercuribenzoate prevented inactivation of the enzyme during storage by preventing aggregation. Activity was correlated with disaggregation of polymer forms of the enzyme to an active monomer. The storage-inactivated enzyme could be reactivated by treatment of the enzyme with cysteine, glutathione, or ferrous ion. Glutathione enabled stored cells to produce acid at their original rate when subcultured in milk. This was attributed to the effect of glutathione on the membrane proteinase. The data suggested that the biological activity of stored cells may be dependent upon the activity of the membrane proteinase.     

Alteration in the arrangement of the keratin-type intermediate filaments during mitosis in cultured human keratinocytes

The behavior of the keratin-type intermediate filaments (KIFs) during mitosis was characterized in cultured human keratinocytes by immunofluorescence microscopy using polyclonal antibodies to keratin. The structural relationship of KIFs with microtubules (MTs) was also studied at the same time using a monoclonal antibody to alpha-tubulin. The KIFs and MTs showed similar but different cytoskeletal networks and underwent structural rearrangements independently during the cell cycle. KIFs in keratinocytes formed two different arrangements during meta- and anaphase: a global aggregation of filaments around the spindle and a fibrous array radiating from the central, global aggregation of filaments to the cell periphery where they were connected with those of the adjacent cells at desmosomal sites. These radiating fibrous portions of KIFs appeared to play a role in retaining the cell in its correct relationship to the surrounding cells during mitosis. This behavior of KIFs in normal keratinocytes was different from the KIF-alterations which had been previously described in SV40-transformed keratinocytes and other cells which expressed two different IFs (keratin and vimentin).     

Rigor crossbridges are double-headed in fast muscle from crayfish

The structure of rigor crossbridges was examined by comparing rigor crossbridges in fast muscle fibers from glycerol-extracted abdominal flexor muscle of crayfish with those in "natively decorated" thin filaments from the same muscle. Natively decorated thin filaments were obtained by dissociating the backbone of the myosin filaments of rigor myofibrils in 0.6 M KCl. Intact fibers were freeze-fractured, deep-etched, and rotary shadowed; isolated filaments were either negatively stained or freeze dried and rotary shadowed. The crossbridges on the natively decorated actin maintain the original spacing and the disposition in chevrons and double chevrons for several hours, indicating that no rearrangement of the actomyosin interactions occurs. Thus the crossbridges of the natively decorated filaments were formed within the geometrical constraints of the intact myofibril. The majority of crossbridges in the intact muscle have a triangular shape indicative of double-headed crossbridge. The triangular shape is maintained in the isolated filaments and negative staining resolves two heads in a single crossbridge. In the isolated filaments, crossbridges are attached at uniform acute angles. Unlike those in insect flight muscle (Taylor et al., 1984), lead and rear elements of the double chevron may be both double-headed. Deep-etched images reveal a twisted arrangement of subfilaments in the backbone of the thick filament.     

Freeze-etching study on membrane ultrastructural changes caused by freezing: cooling rate-dependent intramembrane particle aggregation in erythrocyte stripped ghosts

The changes of membrane ultrastructures by freezing stresses were examined on stripped ghosts which were made by removing almost all peripheral membrane proteins from human erythrocyte membranes. By freezing these stripped ghost membranes showed cooling rate-dependent intramembrane particle (IMP) aggregation. With the cooling rates at and faster than 30,000 degrees C/min, their IMPs were evenly distributed on the fracture faces. However, cooling rates at and slower than 8000 degrees C/min resulted in IMP aggregation. The degree of IMP aggregation increased in parallel with decreasing cooling rates. Without freezing, the IMP aggregation in stripped ghosts could be induced by exposing these ghosts to hypertonic salt solutions, but lowering the temperature did not affect IMP aggregation. The cooling rate-dependent IMP aggregation during freezing was suppressed by adding cryoprotective agents which were known to reduce the salt concentration of the medium during freezing. It is suggested that the IMP aggregation in stripped ghosts by freezing occurs by exposure to concentrated salt solutions during freezing. This result indicates the possibility that IMP aggregation may arise during slow freezing of some biomembranes as a result of an increase in salt concentration rather than as a result of reduction in temperature.     

The germinal centre kinase Don3 triggers the dynamic rearrangement of higher‐order septin structures during cytokinesis in Ustilago maydis

The dimorphic phytopathogenic fungus Ustilago maydis grows in its haploid phase by budding. Cytokinesis and separation of daughter cells are accomplished by the consecutive formation of two distinct septa. Here, we show that both septation events involve the dynamic rearrangement of septin assemblies from hourglass‐shaped collars into ring‐like structures. Using a chemical genetic approach we demonstrate that the germinal centre kinase Don3 triggers this septin reorganization during secondary septum formation. Although chemical inhibition of an analogue‐sensitive version of Don3 prevented septation, a stable septin collar was assembled at the presumptive septation site. Interestingly, the essential light chain of type II myosin, Cdc4, was already associated with this septin collar. Release of Don3 kinase inhibition triggered immediate dispersal of septin filaments and concomitant incorporation of Cdc4 into a contractile actomyosin ring, which also contained the F‐BAR domain protein Cdc15. Inhibition of actin polymerization or deletion of the cdc15 gene, did not affect assembly of the initial collar consisting of septin and myosin light chain. However, reassembly of septin filaments into a ring‐like structure was prevented in the absence of either F‐actin or Cdc15, indicating that septin ring formation in U. maydis depends on a functional contractile actomyosin ring.     

Unfixed cryosections of striated muscle to study dynamic molecular events.

The structures of the actin and myosin filaments of striated muscle have been studied extensively in the past by sectioning of fixed specimens. However, chemical fixation alters molecular details and prevents biochemically induced structural changes. To overcome these problems, we investigate here the potential of cryosectioning unfixed muscle. In cryosections of relaxed, unfixed specimens, individual myosin filaments displayed the characteristic helical organization of detached cross-bridges, but the filament lattice had disintegrated. To preserve both the filament lattice and the molecular structure of the filaments, we decided to section unfixed rigor muscle, stabilized by actomyosin cross-bridges. The best sections showed periodic, angled cross-bridges attached to actin and their Fourier transforms displayed layer lines similar to those in x-ray diffraction patterns of rigor muscle. To preserve relaxed filaments in their original lattice, unfixed sections of rigor muscle were picked up on a grid and relaxed before negative staining. The myosin and actin filaments showed the characteristic helical arrangements of detached cross-bridges and actin subunits, and Fourier transforms were similar to x-ray patterns of relaxed muscle. We conclude that the rigor structure of muscle and the ability of the filament lattice to undergo the rigor-relaxed transformation can be preserved in unfixed cryosections. In the future, it should be possible to carry out dynamic studies of active sacromeres by cryo-electron microscopy.     

Time-resolved electron microscopic analysis of the behavior of myosin heads on actin filaments after photolysis of caged ATP

The interaction between myosin subfragment 1 (S1) and actin filaments after the photolysis of P3-1-(2-nitrophenyl)ethyl ester of ATP (caged ATP) was analyzed with a newly developed freezing system using liquid helium. Actin and S1 (100 microM each) formed a ropelike double-helix characteristic of rigor in the presence of 5 mM caged ATP at room temperature. At 15 ms after photolysis, the ropelike double helix was partially disintegrated. The number of S1 attached to actin filaments gradually decreased up to 35 ms after photolysis, and no more changes were detected from 35 to 200 ms. After depletion of ATP, the ropelike double helix was reformed. Taking recent analyses of actomyosin kinetics into consideration, we concluded that most S1 observed on actin filaments at 35-200 ms are so called "weakly bound S1" (S1.ATP or S1.ADP.Pi) and that the weakly bound S1 under a rapid association- dissociation equilibrium with actin filaments can be captured by electron microscopy by means of our newly developed freezing system. This enabled us to directly compare the conformation of weakly and strongly bound S1. Within the resolution of deep-etch replica technique, there were no significant conformational differences between weakly and strongly bound S1, and neither types of S1 showed any positive cooperativity in their binding to actin filaments. Close comparison revealed that the weakly and strongly bound S1 have different angles of attachment to actin filaments. As compared to strongly bound S1, weakly bound S1 showed a significantly broader distribution of attachment angles. These results are discussed with special reference to the molecular mechanism of acto-myosin interaction in the presence of ATP.