M. Maillard scite author profile

Reprecipitated fibrils from collagen solutions assemble into aggregates often showing a remarkable twisted structure. We first observed these aggregates in collagen gels prepared to facilitate culture of epithelial cells. We verified that these structures form in the absence of cells and correspond to a process of self-assembly. Studies on reconstructed fibrils of collagen are generally based on the examination of thin specimens mounted onto coated grids prepared for electron microscopy. We rather applied the classical methods of fixation, embedding and ultramicrotomy, which allowed us to analyze the structure of these aggregates, several microns in diameter. Our gels were prepared from 2.5 mg/ml tropocollagen solutions usually chosen for cell and organ cultures. The time required to obtain twisted architectures, in these aggregates, depends on temperature and the presence of factors such as fetal calf serum proteins. Twist is observed at two different levels of organization. Microfibrils are gathered into twisted bundles which condense into cross-striated fibrils. These fibrils themselves aggregate and show a mutual twist whose orientation is left-handed as is the twist observed within each microfibril bundle. Several models of these architectures are presented. Planar twist, cylindrical twist and toroidal twist are described and their relation to the structure of certain liquid crystals is considered. Examples of orthogonal packing also have been observed. These structures obtained in vitro are very close to patterns already described in vivo in numerous collagen matrices.

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3D analysis of gelatin gel networks from transmission electron microscopy imaging

Djabourov

Bonnet

Kaplan

et al. 1993

J. Phys. II France

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This paper presents a quantitative analysis of the structural parameters of gelatin gel networks derived from transmission electron micrographs. The network gel replicas were obtained by a quick-freezing, deep-etching and rotary replication method adapted to the study of fragile physical networks by Favard P. et al. (Biol. Cell 67 (1989) 201-207). Stereo electron micrographs were taken by tilting the replicas at increasing angles between – 35 to + 30○. A 3D reconstruction of the filamentous network was performed by stereoscopic and tomographic procedures. These procedures allowed us to measure the thicknesses of the replicas. The average length of filaments (triple helices) per unit volume and the average distance between filaments (mesh sizes of the networks) were derived for two polymer concentrations ($c=2~\%$ and $c=10~\%$). The results are in full agreement with optical rotation and small-angle neutron scattering measurements

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A technique for labelling the sample surface for quick‐freeze, deep‐etch, rotary replication electron microscopy: application to the study of geletin gel structure

Favard¹,

Lechaire²,

Maillard³

et al. 1989

Biology of the Cell

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A method using magnesium oxide crystals to label the surface of physical gels, such as gelatin gel before quick-freezing is described and discussed. The quick-freeze, deep-etch, rotary replication technique is most adapted to 3-D visualization of physical gel structure. However, it is known that the depth which ultrarapid freezing may reach is limited by the growth of ice crystals as the distance from the surface of the specimen (rapidly cooled by smashing against a cooled metal plate) increases. Consequently, intact preservation of structures occurs only in superficial zones of the specimen.The MgO surface labelling technique provides a simple means for surface recognition. It enables the estimation of a given replicated area depth, taking into account the angle of specimen scraping before etching and replicating. By comparison of views of the same replica at different depths, freezing artifacts may be recognized even when they cause only slight deformations in the structure. This is particularly necessary for interpretation of gel network geometry: interpretation can be made with certainty only if a reliable surface reference marker exists.For gelatin gels, the depth of best freezing can be estimated tobe around S lzm from the frozen sample surface.surface marker ---gelatin gel --=.cha|ns network ---quick-freeze artifacts --MgO crystals

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3-D-electron microscopy configuration of TMOS wet silica gels prepared by the quick-freeze, deep-etching-rotary-replication technique

Favard¹,

Lechaire²,

Maillard³

et al. 1992

Colloid Polym Sci

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Wheat germ agglutinin (WGA) reduces ADH‐induced water flow and induces cell surface changes in epithelial cells of frog urinary bladder

Favard¹,

Favard²,

Zhu³

et al. 1989

Biology of the Cell

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The functional and structural changes induced by apical wheat germ agglutinin (WGA) 100 micrograms/ml exposure on frog urinary bladder have been investigated and the possible correlations between these effects discussed. Bladders, apically exposed to WGA for 30 min to 3 hr exhibit a marked reduction of their response to antidiuretic hormone (ADH) challenge and of their hydrosmotic reactivity. Structural changes triggered by WGA treatment are: 1. apical invaginations of the plasma membrane, interpreted as endocytotic in nature, taking into account the results of carbohydrate cytochemical detection and horseradish peroxidase (HRP) exposure: 2. cytoskeleton disorganization and microvilli collapse. These phenomena do not interfere with cortical granule traffic and are independent of ADH challenge: they occur in ADH-stimulated bladders as well as in bladders at rest. These findings could be interpreted as follows: binding of the divalent lectin WGA to its coat specific receptors would induce changes in the apical membrane structure which in turn could provoke disorganization and disruption of apical cytoskeletal elements associated with plasma membrane. Reduction of bladder response to ADH challenge could result from a reduced recycling of aggrephores, as they are associated with cytoskeletal elements in the subapical cytoplasm. Collapse of microvilli and endocytotic events also could result from apical cytoskeleton disruption, as microvilli are sustained by bundles of actin filaments interconnected with apical cytoskeletal filaments and as plasma membrane is associated with apical cytoskeleton. However, these two last events evidently occur in ADH-challenged or non-challenged bladders.

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M. Maillard

Twisted architectures in cell‐free assembled collagen gels: study of collagen substrates used for cultures

3D analysis of gelatin gel networks from transmission electron microscopy imaging

A technique for labelling the sample surface for quick‐freeze, deep‐etch, rotary replication electron microscopy: application to the study of geletin gel structure

3-D-electron microscopy configuration of TMOS wet silica gels prepared by the quick-freeze, deep-etching-rotary-replication technique

Wheat germ agglutinin (WGA) reduces ADH‐induced water flow and induces cell surface changes in epithelial cells of frog urinary bladder

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