Organization of cytoskeleton during the tentacle contraction and cytostome movement in the dinoflagellate Noctiluca scintillans McCartney

Summary Electron microscopy of Noctiluca scintillans reveals that the cytoskeleton of the tentacle involved in the motor action of the prey capture consists of three characteristic elements: a deformable peripheral fibrillo-granular ectosarc, abundant underlying microtubules organized in several rows on the convex side, and helicoid filaments about 8 nm in diameter organized into striated myonemes. Microtubules of the external row are crossed-linked with each other by fibrous elements 5 nm in diameter and 10–15 nm long, their links with the second row result in a Y-shaped binding. Bonds of the other rows are linked to each other irregularly between those of the same row. Striated myonemes are regularly inserted between the rows of microtubules on the ectosarc and between its pleats, joining together in a knot of disarrayed filaments with multidirectional orientation in the central axis of the tentacle. Striation of myonemes is based on an alternation of thick striae (TS) 40 nm wide with a periodicity of about 200 nm, and of some intermediary fine striae (FS) 10 nm wide. The events during tentacle contraction are: (1) Rotation of the tentacle, bringing the convex side to the inner side of it. Here, large numbers of microtubules have been visualized by optical immunocytochemistry after labelling with Paramecium antitubulin antiserum. (2) Increase of pleat amplitude (200–300 nm to 600 nm) in concomitance with a decrease of its period (500–700 nm to 250 nm). (3) Apparent modification of the microtubule orientation. (4) Transformation of some TS in several FS without modification of the striation periodicity.Near the cytostome, the cytoskeleton consists of a number quantity of microtubules underlying a non-pleated ectosarc and long tracts of contractile myonemes formed by 6-nm helicoid filaments linking the internal side of the cytostome of the supporting rod. Semirelaxed myonemes show an alternation of fine striae (FS) 35 nm wide between two clear areas (CA) with a periodicity of about 300 nm, plus an incipient dark area (DA) lying between them; together they are transformed into a thick stria (TS) during maximal contraction; the striation periodicity thus decreases by one half. These two systems are compared with one another and with other motile systems.     

THE CONTRACTILE PROCESS IN THE CILIATE, STENTOR COERULEUS : I. The Role of Microtubules and Filaments

The structural basis for the function of microtubules and filaments in cell body contractility in the ciliate Stentor coeruleus was investigated. Cells in the extended state were obtained for ultrastructural analysis by treatment before fixation with a solution containing 10 mM EGTA, 50–80 mM Tris, 3 mM MgSO₄, 7.5 mM NH₄Cl, 10 mM phosphate buffer (pH 7.1). The response of Stentor to changes in the divalent cation concentrations in this solution suggests that Ca⁺² and Mg⁺² are physiologically important in the regulation of ciliate contractility. The generation of motive force for changes in cell length in Stentor resides in two distinct longitudinal cortical fiber systems, the km fibers and myonemes. Cyclic changes in cell length are associated with (a) the relative sliding of parallel, overlapping microtubule ribbons in the km fibers, and (b) a distinct alteration in the structure of the contractile filaments constituting the myonemes. The microtubule and filament systems are distinguished functionally as antagonistic contractile elements. The development of motive force for cell extension is accomplished by active microtubule-to-microtubule sliding generated by specific intertubule bridges. Evidence is presented which suggests that active shortening of contractile filaments, reflected in a reversible structural transformation of dense 4-nm filaments to tubular 10–12-nm filaments, provides the basis for rapid cell contraction.     

Electron microscope investigation of the evolutionary stages of the trophozoite of Didymophyes gigantea (Sporozoa, Gregarinida). III. The fine structure of the epicyte with emphasis on the contractile elements (author's transl)

The fine structure of the epicyte of D. gigantea was investigated. The motility of the gregarine and the contractile elements are described. Four essential types of movements can be observed in this gregarine: (1) rolling up and pendular movements, (2) locomotion by gliding forward, (3) cytoplasmic streaming (Fig. 1), (4) peristaltic contractions (Fig. 2) which seem to be accompanied by the contraction of annular myonemes (Fig. 2). The epicyte is formed by the folding of the parasitic cell wall which is made from three membranes (Figs. 3 and 4). At the top of each fold one can see apical struts between the outer and middle membrane and apical filaments under the inner membrane (Fig. 3). In addition, the epicytic folds are covered by a cell coat which is made from tubular structures (Fig. 5). At the base of the epicytic folds can be observed the basal lamina (Fig. 3) composed of very fine fibrillar material with an average thickness of 2.5 nm (Fig. 6). These fibrils are oriented in the longitudinal axis of the gregarine. Beneath the epicytic fold in the ectoplasm are found the annular myonemes with a width of up to 0.5 micrometers (Fig. 7). They are composed of many fine fibrils with an average thickness of 5 nm. In young trophozoites, the myonemes also contain microtubuli (Fig. 8). Between the epicytic folds, the cell wall is interrupted by three different types of vesicles: the vesicles with an electrondense content (Fig. 9), the three-membranous vesicles (Fig. 10), and the hose-shaped vesicles (Fig. 11). Glycerol-extraction of the parasites was performed in order to define the contractile structures. After extraction the annular myonemes are difficult to recognize (Fig. 13). When ATP is added, the gregarine does not contract but the myonemes reappear after 3 to 4 min (Fig. 14). Differences can also be observed in the myoneme structure using electron microscopy: After extraction, the myonemes are composed of a very limp fibrillar network (Fig. 15) which becomes very dense after the action of ATP (Fig. 16). Glycerol extraction does not disturb either the apical struts and apical filaments or the fibrils of the basal lamina (Figs. 15--17). In addition, cytoplasmic fibrillar structures appear after glycerol extraction (Figs. 15 and 16). The experimental and electron microscope results indicate that the motility of the gregarine depends upon four different systems: (1) the ectoplasmic annular myonemes, (2) the apical structures in the undulating epicytic folds, (3) the cytoplasmic fibrils, and (4) the basal lamina.     

Analysis of the contraction of an organelle using its birefringency: the R-fibre of the Ceratium (Dinoflagellate) flagellum

Some organelles responsible for contraction consist of bundles of 2-4 nm filaments called nanofilaments. Such organelles are present in the longitudinal flagellum of Ceratium (Dinoflagellate): the R-fibre is the motor system for contraction and parallels the axoneme, which is responsible for wave generation. We used a highly sensitive polarization microscope developed by one of the authors to measure the birefringence of these nanofilament bundles during contraction in vivo. Our results show that the R-fibre gives a highly birefringent signal, retarding the polarization to much the same extent irrespective of the direction of polarization. By rotating the axis of the microscope compensator we confirmed that the birefringence is positive, suggesting that the bundles run parallel to the longitudinal axis of the flagellum. Conversely, when the compensator was rotated contrary to the direction of retardation, the bundle appeared dark (except when the organelle was in a fully contracted state). Experiments performed on detergent-treated and ATP-reactivated flagella show that a portion of the flagella regained activity with the addition of ATP in the presence of low Ca(2+) concentrations. This demonstrates the ability to reactivate flagellar motility after permeabilization and that axonemal microtubules were not responsible for the strong flagellar birefringence. Combined with complementary data from DIC microscopy of demembranated flagella and electron microscopy, these findings have led to the development of a model of the R-fibre and a comparison with other types of birefringent nanofilament bundles, such as the myoneme of Acantharia.     

Fine structure of the M fibres in Stentor before and after shortening

The fine structure of the filamentous M fibres of Stentor coeruleus was examined in contracted specimens and in stentors relaxed in a solution of raised ionic strength with a high monovalent/divalent ion ratio, prior to fixation. In both, the microfilaments constituting the fibres were of two types, the great majority being about 8 nm in diameter, and a smaller proportion of microfilaments measuring 3–5 nm. The microfilaments of contracted M fibres were closely aggregated whereas those of uncontracted M fibres were more widely spaced. No appreciable change in size appeared to have occurred in the diameter of the filaments. These results were taken to indicate that the microfilaments do not undergo an internal conformational change, but rather shorten the M fibre by aggregating laterally and longitudinally.     

Histological and ultrastructural studies of the basal disk of Hydra

Summary The glandulomuscular cells of Hydra are located exclusively in the basal disk. They are derived from epithelio-muscular cells which have been forced proximally. Light and electron microscopical studies show that prior to their destruction and elimination, the transformed epithelio-muscular cells (i.e. the glandulomuscular cells) undergo certain striking morphological and physiological changes. Golgi complexes and elements of rough E. R. increase remarkably in activity, and individually or jointly produce at least six types of morphologically different droplets. One additional type of droplet is thought to originate from neighboring digestive cells. Although the chemical nature of the individual droplets is uncertain, it is known that some are Alcian blue and PAS positive and contain hyaluronic acid. These evidences suggest the presence of an acid mucopolysaccharide material, the adhesive agent which attaches the animal to a substrate. The myonemes contain thick (200 Å in diameter) and thin (60 Å in diameter) filaments as in epithelio-muscular cells. There are also filaments of intermediate sizes and large fibers (770 Å in diameter). The myonemes are oriented radially with respect to the aboral pore and therefore in addition to contributing to the contraction and relaxation of the body column, they apparently regulate the opening and closing of the aboral pore. Although there is no evidence to substantiate the mechanism for transformation of epithelio-muscular cells to glandulomuscular cells as well as cell death of the latter cell types, these problems are discussed briefly.This investigation was supported by The National Science Foundation, Grant Number GB-27395.With the technical assistance of Linda M. Bookman.     

Contractility and its Control in Peritrich Ciliates*†

A review of the recent literature on the structure and physico-chemical properties of the myoneme and its specialization, the spasmoneme, of peritrich ciliates was made. Myonemes are composed of tightly packed bundles of 3–5 nm microfibrils which parallel, more or less, the long axis of the bundle and are of indefinite length. The presence of contractility in these ciliates is correlated with the presence of myonemes. Associated with the microfibrils is a system of membrane-bound tubules and saccules continuous with the endoplasmic reticulum (ER). This system is known to accumulate calcium. Myonemes differ from muscles in their structure, solubility properties, birefringence pattern, and in the time during the contraction-relaxation cycle at which they require energy. They may be related more closely to the cytochalasin B-sensitive microfibrils of higher organisms than to muscles. Contraction of extracted stalks can be induced solely by raising the calcium ion concentration above a certain threshold. Thus the calcium-accumulating myoneme-associated ER would appear to play an important role in the control of myoneme contractility. A specialization at the interface between the myoneme and the ER membranes is described as it appears in Vorticella and Opercularia. This structure, called a linkage complex, is found both in the body myonemes and the spasmoneme and links the membranes of the ER to the microfibrils. It also has microfilaments that pass from the ER-myoneme interface to the surface membranes. The uniqueness of this structure and its location suggests that it may play a role in controlling the movements of calcium between the ER and myoneme and also in transmission of messages from the pellicular membranes, possibly the alveolar sacs, to the ER.     

The Contractile Proteins and Calcium Mediated Gelation and Contraction of Pollen Tube Extracts

The crude extracts of pollen tubes, like other nonmuscle ceils, showed gelation at Iow Ga2+ concentrations and ATP-dependent contraction at higher Ga2+ concentrations. The contracted cytoplasmic clots contained a lot of filaments which were mainly composed of actin, myosin, 105 kD, 67 kD, 48 kD, 38 kD, 34 kD and 28 kD proteins. It is likely that Ca2+ are able to mediate tranformation of acfin from a less ordered state to a more oriented filaments, which interact with actin-binding proteins to form the filamentous network, thus to induce the gel formation of cytoplasm, to regulate the interaction of actin and myosin which transform the chemical energy of ATP into mechanical work of contractile movement of cytoplasm.     

Modeling myosin Va liposome transport through actin filament networks reveals a percolation threshold that modulates transport properties

Myosin Va (myoVa) motors transport membrane-bound cargo through three-dimensional, intracellular actin filament networks. We developed a coarse-grained, in silico model to predict how actin filament density (3-800 filaments) within a randomly oriented actin network affects fluid-like liposome (350 nm vs. 1750 nm) transport by myoVa motors. Five thousand simulated liposomes transported within each network adopted one of three states: transport, tug-of-war, or diffusion. Diffusion due to liposome detachment from actin rarely occurred given at least 10 motors on the liposome surface. However, with increased actin density, liposomes transitioned from primarily directed transport on single actin filaments to an apparent random walk, resulting from a mixture of transport and tug-of-wars as the probability of encountering additional actin filaments increased. This phase transition arises from a percolation phase transition at a critical number of accessible actin filaments, N_c. N_c is a geometric property of the actin network that depends only on the position and polarity of the actin filaments, transport distance, and the liposome diameter, as evidenced by a fivefold increase in liposome diameter resulting in a fivefold decrease in N_c. Thus in cells, actin network density and cargo size may be regulated to match cargo delivery to the cell’s physiological demands.     

POLARIZATION AND ELECTRON MICROSCOPE STUDY OF FROG NERVE AXOPLASM

1. The submicroscopic organization of nerve axons from R. pipiens and R. catesbiana has been studied by means of polarizing and electron microscopes. 2. In measurements on a series of 85 fresh myelinated axons from which the sheaths had been removed average values were obtained for the total birefringence, +2.5 x 10^–4, the form birefringence, +1.4 x 10^–4, and the refractive index of the oriented component, 1.523. The average partial volume occupied by axially oriented filaments was computed to be 0.69 per cent. 3. Electron micrographs of fixed myelinated axons demonstrate an average of 93 axially oriented neuroprotofibrils per square micron of cross-section. The neuroprotofibrils are approximately 90 A in diameter, of indefinite length, and occupy a computed partial volume of 0.59 per cent. 4. Mitochondria, neuroprotofibrils, endoplasmic reticulum, and dense particles are seen in electron micrographs of both myelinated and unmyelinated nerve axons. 5. It is concluded that the neuroprotofibrils are present in the living nerve, that they play an important but undetermined role in nerve function, and that these structures are not an artifact of osmium tetroxide fixation.     

THE STRUCTURE AND ORGANIZATION OF, AND THE RELATIONSHIP BETWEEN THE ORGANIC MATRIX AND THE INORGANIC CRYSTALS OF EMBRYONIC BOVINE ENAMEL

Electron microscope and electron diffraction studies of developing embryonic bovine enamel have revealed the organization of the organic matrix and the inorganic crystals. The most recently deposited inorganic crystals located at the ameloblast-enamel junction are thin plates, approximately 1300 A long, 400 A wide, and 19 A thick. During maturation of the enamel, crystal growth occurs primarily by an increase in crystal thickness. Statistical analyses failed to show a significant change in either the width or the length of the crystals during the period of maturation studied. Even in the earliest stages of calcification, the crystals are organized within the prisms so that their long axes (c-axes) are oriented parallel to the long axes of the prisms but randomly distributed about their long axes. With maturation of the enamel, the crystals become more densely packed and more highly oriented within the prisms. The organic matrix in decalcified sections of enamel is strikingly similar in its over-all organization to that of the fully mineralized tissue. When viewed in longitudinal prism profiles, the intraprismatic organic matrix is composed of relatively thin dense lines, approximately 48 A wide, which are relatively parallel to each other and have their fiber axes parallel to the long axes of the prisms within which they are located. Many of these dense lines, which have the appearance of thin filaments, are organized into doublets, the individual 48 A wide filaments of the doublets being separated by approximately 120 A. When observed in oblique prism profiles, the intraprismatic organic matrix is likewise remarkably similar in general orientation and organization to that of the fully mineralized tissue. Moreover, the spaces between adjacent doublets or between single filaments have the appearance of compartments. These compartments, more clearly visualized in cross- or near cross-sectional prism profiles, are oval or near oval in shape. Therefore, the appearance of the intraprismatic organic matrix (in longitudinal, oblique, and cross-sectional prism profiles) indicates that it is organized into tubular sheaths which are oriented with their long axes parallel to the long axes of the prisms in which they are located, but randomly oriented about their own long axes, an orientation again remarkably "blue printing" that of the inorganic crystals. The predominant feature of the walls of the tubular sheaths, when viewed in cross- or near cross-section, is that of continuous sheets, although in many cases closely packed dot-like structures of approximately 48 A were also observed, suggesting that the wall of the sheaths consists of a series of closely packed filaments. The 48 A wide dense lines (filaments) representing the width of the sheath wall were resolved into two dense strands when viewed in longitudinal prism profiles. Each strand was 12 A wide and was separated by a less electron-dense space 17 A wide. The intraprismatic organic matrix is surrounded by a prism sheath which corresponds in mineralized sections to the electron-lucent uncalcified regions separating adjacent prisms. Structurally, the prism sheaths appear to consist of filaments arranged in basket-weave fashion.     

THE CONTRACTILE BASIS OF AMOEBOID MOVEMENT : I. The Chemical Control of Motility in Isolated Cytoplasm

Cytoplasm has been isolated from single amoeba (Chaos carolinensis) in physiological solutions similar to rigor, contraction, and relaxation solutions designed to control the contractile state of vertebrate striated muscle. Contractions of the isolated cytoplasm are elicited by free calcium ion concentrations above ca. 7.0 x 10^-7 M. Amoeba cytoplasmic contractility has been cycled repeatedly through stabilized (rigor), contracted, and relaxed states by manipulating the exogenous free calcium and ATP concentrations. The transition from stabilized state to relaxed state was characterized by a loss of viscoelasticity which was monitored as changes in the capacity of the cytoplasm to exhibit strain birefringence when stretched. When the stabilized cytoplasm was stretched, birefringent fibrils were observed. Thin sections of those fibrils showed thick (150–250 Å) and thin (70 Å) filaments aligned parallel to the long axis of fibrils visible with the light microscope. Negatively stained cytoplasm treated with relaxation solution showed dissociated thick and thin filaments morphologically identical with myosin aggregates and purified actin, respectively, from vertebrate striated muscle. In the presence of threshold buffered free calcium, ATP, and magnesium ions, controlled localized contractions caused membrane-less pseudopodia to extend into the solution from the cytoplasmic mass. These experiments shed new light on the contractile basis of cytoplasmic streaming and pseudopod extension, the chemical control of contractility in the amoeba cytoplasm, the site of application of the motive force for amoeboid movement, and the nature of the rheological transformations associated with the circulation of cytoplasm in intact amoeba.     

Constitutive aggregates of intermediate-sized filaments of the vimentin and cytokeratin type in cultured hepatoma cells and their dispersal by butyrate

Cloned hepatoma cells ($\text{72}\text{22}$) derived from the liver of a rat treated with the carcinogen, diethylnitrosamine, exhibit a genetically stable, large, acentric, juxtanuclear, hyaline aggregate of loosely packed intermediate-sized (7–11 nm) filaments, interspersed with variable but minor amounts of microtubules, polyribosomes and membranous structures. Immunofluorescence microscopy shows that the these filaments react specifically with antibodies to bovine prekeratin and to murine vimentin. The aggregates contain aster-like foci common to the arrangement of both tonofilament-like and vimentin-containing intermediate-sized filaments, although both filament systems show different fibrillar patterns in other cytoplasmic regions. While the cytokeratin filament system is not significantly altered during exposure to colcemid, the vimentin in the abnormal aggregate is rearranged during such treatment into extensive and complex perinuclear ‘whorls’ of filaments. Treatment of the cells with butyrate results in a markedly flattened, hepatocyte-like morphology, a reappearance of typical actin-containing ‘cables’, and a progressive disintegration of the filament aggregate concomitant with a normal display of filaments of both the cytokeratin and vimentin type. The results show that (i) some cells contain aggregates consisting of two different types of intermediate-sized filaments oriented onto a common focal center; (ii) such an abnormal filament arrangement is clonally stable; (iii) the vimentin-type filaments contained in such aggregates are still susceptible to the action of antimitotic drugs and can be rearranged into characteristic perinuclear whorls; and (iv) this abnormal aggregate of intermediate filaments can be reverted to normal patterns upon treatment of the cells with butyrate.     

ULTRASTRUCTURAL STUDIES ON THE CONTRACTILE MECHANISM OF SMOOTH MUSCLE

Fresh taenia coli and chicken gizzard smooth muscle were studied in the contracted and relaxed states. Thick and thin filaments were observed in certain (but not all) cells fixed in contraction. Relaxed smooth muscle contained only thin filaments. Several other morphological differences were observed between contracted and relaxed smooth muscle. The nuclear chromatin is clumped in contraction and evenly dispersed in the relaxed state. The sarcolemma is more highly vesiculated in contraction than in relaxation. In contraction, the sarcoplasm also appears more electron opaque. Over-all morphological differences between cells fixed in isometric and in unloaded contraction were also noticeable. The results suggest a sliding filament mechanism of smooth muscle contraction; however, in smooth muscle, unlike striated muscle, the thick filaments appear to be in a highly labile condition in the contractile process. The relation between contraction and a possible change in pH is also discussed.     

THE MICROFIBRILLAR STRUCTURE OF THE CELL WALLS OF THE FILAMENTOUS FUNGUS, Allomyces

Cell walls of the fungus, Allomyces, were isolated by chemical procedures, using either potassium permanganate oxidation or glacial acetic acid-hydrogen peroxide treatment followed by dilute mineral acid. The structure of the treated walls was investigated by means of electron microscopy and electron diffraction analysis which showed that rhizoidal walls were especially suitable for observation. Chitin microfibrils exist in the extreme tips of rhizoidal walls, and tend to lie in a preferred longitudinal orientation. Older rhizoidal wall segments show a crossed fibrillar structure under a thin layer of short randomly arranged microfibrils. In the possession of systems of crossed fibrils these walls are like the cell walls of certain green algae. Walls of branch rhizoidal filaments were observed in the early stages of development, in which case the observed microfibrillar orientations are such that it is possible to envisage their origin from pre-existing fibrils that have passively reoriented. With respect to the continued growth of the filaments, however, it is difficult to explain the observed microfibrillar arrangements in terms of the "multi-net" theory. Hyphal walls usually show two layers, the outer consisting of microfibrils arranged randomly, and the inner consisting of well oriented microfibrils running parallel with the longitudinal axis of the hypha. The oriented inner layer appears to be similar in structure to the secondary wall of the Phycomyces sporangiophore.     

Two-dimensional reconstruction of birefringence map of the skeletal muscle sarcomere in relaxed and rigor states studied by interference microscopy]

A new method of automatized quantitative interferometry of skeletal muscle fibers was developed for the investigation of birefringence. A device based on the Linnic microscope was constructed to obtain phase images, which are two-dimensional pictures of birefringence. For the first time, two-and-three-dimensional maps of both total birefringence and birefringence for individual sarcomeres in the central part of muscle fiber were visualized using large databases. It was shown that total birefringence of fibers at rest length in the rigor state was lower as compared with the relaxed. Birefringence values from individual sarcomere interferograms revealed also that normalized A-disk birefringence was lower in the rigor state. The results obtained could be explained by a decrease of thick filaments anisotropy, due to the moving away of myosin heads from the rod during transition into the rigor state.     

Reduction of density and anisotropic distribution of intermediate filaments occur during avian skeletal myogenesis

Chicken skeletal muscle taken from embryos in ovo was examined by thin-section electron microscopy. Measurements of filament diameters reveal three nonoverlapping groups of filaments: thin (actin myofibrillar) filaments with mean diameters of 5.3 +/- 0.6 nm (S.D.), thick (myosin myofibrillar) filaments with mean diameters of 15 +/- 1.4 nm, and intermediate filaments with mean diameters of 9.3 +/- 0.9 nm. During muscle development these diameters do not change. By counting the number of filaments observed in the sarcoplasm at different stages, we find that the spatial density of intermediate filaments decreases during avian myogenesis in ovo, from 91 intermediate filaments/micron 2 at 6 days to 43 intermediate filaments/micron 2 at 17 days in ovo. Initially randomly arranged, some intermediate filaments become associated with Z discs, sarcoplasmic reticulum, nuclear membrane, and the sarcolemma between 6 and 10 days in ovo. These associated intermediate filaments course both parallel and transverse to myofibrils, forming lateral connections between myofibrillar Z discs and longitudinal connections from Z disc to Z disc within myofibrils. Intermediate filaments also appear to connect Z discs with the nuclear membrane. The intermediate filament associations persist through day 17 of development, after which the presence of cytoskeletal filaments is obscured by the densely packed myofibrils and membranes. Intermediate filament distribution becomes anisotropic during development. A greater proportion of intermediate filaments in the immediate perimyofibrillar area are oriented parallel to myofibrils than in other areas, so that the majority of the intermediate filaments nearest the myofibrils course parallel to them. The longitudinal intramyofibrillar intermediate filaments persist throughout development, as shown by their existence in KI-extracted adult myofibrils.     

Electric birefringence of bacterial flagellar protein filaments: evidence for field-induced interactions.

The time course for the build-up and decay of birefringence induced by a rectangular voltage pulse was measured on solutions of flagellar filaments from Salmonella equi-abortus (strain SJ25). These filaments are tubular polymers of protein (degree of polymerization ≈ 10³) constituted by non-covalent linkage of flagellin monomers of molecular weight 4 × 10⁴. The effect on electro-optical properties of solutions of filaments due to variations in temperature, concentration and mean length of protein filaments, and the duration and intensity of the applied electric field is described. Analysis of the field intensity dependence of the birefringence and comparison of the build-up and decay processes indicate that orientation in the field is due primarily to the existence of a permanent dipole moment in the filaments. At 18 °C the following values were obtained for a solution of filaments with mean length and standard deviation of 0.39 and 0.30 μm: specific Kerr constant (K_sp) = 6.14 × 10⁻³ electrostatic units; optical anisotropy factor (g₁ — g₂) = 5.66 × 10⁻³; dipole moment (μ) = 1.01 × 10⁵ Debye units; and mean relaxation time ($\text{}\text{̄}$gt) = 9.20 ms. At temperatures below 20 °C there is a marked increase in the optical anisotropy factor of the filaments which may be due to a change in their flexibility. The large values of K_sp obtained indicate the highly responsive nature of these filaments to an electric field. The birefringence decay curves were decomposed by computer into a specified number of exponential terms from which both the mean length and the size distribution of these polydisperse filaments were calculated. The results obtained were in substantial agreement with the values of these parameters observed by electron microscopy. A cumulative field effect dependent on field intensity and filament concentration was observed. Repeated pulsing of electric field, above threshold values of field intensity and filament concentration, produced decreases in the birefringence near 60% of its initial value. The effect was reversible with a time constant greater than two minutes. No appreciable change in the relaxation time for decay of birefringence was observed on multiple pulsing of these solutions. These results are interpreted consistently to arise from the sidewise aggregation of filaments induced by electrical impulses of sufficient intensity and duration. These properties appear relevant to bacterial motility: variations in electric potential along the membrane of the bacterium might serve first to orient these organelles and then to induce their coalescence to “bundles” of filaments. The latter structures are commonly observed in vivo. In this way the activity of flagella might be co-ordinated.     

Electric birefringence imaging of electrokinetic agarose orientation.

Time-resolved and steady-state electric birefringence imaging with a slow-scan video camera is used to study orientation during DNA agarose gel electrophoresis. The hydrodynamically induced gel distortion is shown to be the major source of birefringence under electrophoresis running conditions and to generate a birefringence image that approximates the image of the DNA concentration gradient in the electric field direction. A fluid kinematic model is presented to describe the spatial distribution of steady-state birefringence and is verified with fluorescence measurements of DNA distribution. The stress-optic coefficient of 1% agarose gel is measured by mechanical compression and used to evaluate the magnitude of the induced strain on the gel during electrophoresis.     

Near-UV Circular Dichroism Reveals Structural Transitions of Vimentin Subunits during Intermediate Filament Assembly

In vitro assembly of vimentin intermediate filaments (IFs) proceeds from soluble, reconstituted tetrameric complexes to mature filaments in three distinct stages: (1) within the first seconds after initiation of assembly, tetramers laterally associate into unit-length filaments (ULFs), on average 17 nm wide; (2) for the next few minutes, ULFs grow by longitudinal annealing into short, immature filaments; (3) almost concomitant with elongation, these immature filaments begin to radially compact, yielding ∼ 11-nm-wide IFs at around 15 min. The near-UV CD signal of soluble tetramers exhibits two main peaks at 285 and 278 nm, which do not change during ULF formation. In contrast, the CD signal of mature IFs exhibits two major changes: (1) the 278-nm band, denoting the transition of the tyrosines from the ground state to the first vibrational mode of the excited state, is lost; (2) a red-shifted band appears at 291 nm, indicating the emergence of a new electronic species. These changes take place independently and at different time scales. The 278-nm signal disappears within the first minute of assembly, compatible with increased rigidity of the tyrosines during elongation of the ULFs. The rise of the 291-nm band has a lifetime of ∼ 13 min and denotes the generation of phenolates by deprotonation of the tyrosines' hydroxyl group after they relocalize into a negatively charged environment. The appearance of such tyrosine-binding “pockets” in the assembling filaments highlights an essential part of the molecular rearrangements characterizing the later stages of the assembly process, including the radial compaction.