Comparative study of axopodial microtubule patterns and possible mechanisms of pattern control in the centrohelidian heliozoa Acanthocystis, Raphidiophrys and Heterophrys

1977 ◽  
Vol 25 (1) ◽  
pp. 205-232
Author(s):  
C.F. Bardele
Keyword(s):  
Fine Structure ◽  
Conformational Changes ◽  
Basal Body ◽  
Basic Unit ◽  
Lateral Growth ◽  
Secondary Nucleation ◽  
Body Formation ◽  
Pattern Control ◽  
Nucleation Sites ◽  
Equilateral Triangles

The axopodial microtubule pattern of 9 centrohelidians belonging to the genera Acanthocystis, Raphidiophrys and Heterophrys, as well as the fine structure of their microtubule organizing centre, the centroplast, was studied to determine the rules which govern their patterns. Microtubules capable of binding a xamimum of 4 linkers are arranged in regularly distorted hexagons and equilateral triangles. The number of microtubules present in each axoneme ranges from some 140 in Acanthocystis turfacea to as few as 6 in Heterophrys marina (Stock I). In the later species each axoneme contains a single hexagon of microtubules only. In other Heterophrys species, the central hexagon is surrounded by closely packed microtubules or by microtubules arranged in pentagons; only the central hexagon is anchored in the centroplast shell, whereas additional microtubules seem to originate from secondary nucleation sites somewhat distal to the centroplast. It is argued that the distortion of the basic unit hexagon (with alternate angles close to 134 degrees and 106 degrees) indicates that the microtubules are composed of 13 protofilaments. While in the larger Acanthocystis and Raphidiophrys species, the pattern may result from self-linkage, the arrays found in the Heterophrys species seem to favour a template-determined linkage. To explain the formation of the central hexagon in Heterophrys and balanced lateral growth in the larger microtubule arrays, a ‘linker-nucleation hypothesis’ is proposed. The assumption is made that graded conformational changes in the microtubule subunits not only specify the position where the next linker will bind, but that this linker, through linkage, becomes able to induce secondary microtubule nucleation, which will result in balanced lateral growth of the array. The application of this hypothesis to other microtubule systems, e.g. basal body formation, is discussed.

Timing of nuclear and kinetoplast DNA replication and early morphological events in the cell cycle of Trypanosoma brucei

1990 ◽  
Vol 95 (1) ◽  
pp. 49-57 ◽  
Author(s):  
R. Woodward ◽  
K. Gull
Keyword(s):  
Cell Cycle ◽  
Dna Replication ◽  
Trypanosoma Brucei ◽  
Basal Body ◽  
Unit Cell ◽  
Kinetoplast Dna ◽  
Interphase Cell ◽  
Body Formation ◽  
Timing Of Initiation ◽  
Single Mitochondrion

We have used immunofluorescent detection of 5-bromo-2-deoxyuridine-substituted DNA in order to determine the timing of initiation and the duration of nuclear and kinetoplast S-phases within the procyclic stage of the Trypanosoma brucei cell cycle. Both nuclear and kinetoplast S-phases were shown to be periodic, occupying 0.18 and 0.12 of the unit cell cycle, respectively. In addition, initiation of both of these S-phases were in approximate synchrony, differing by only 0.03 of the unit cell cycle. We have also used a monoclonal antibody that recognises the basal bodies of T. brucei in order to visualise cells possessing a new pro-basal body and hence determine the time of pro-basal body formation within the cell cycle. Pro-basal body formation occurred within a few minutes of the initiation of nuclear S-phase, at 0.41 of the unit cell cycle. This provides detection of the earliest known cell cycle event in T. brucei at the level of the light microscope. Cell cycle events including initiation of nuclear and kinetoplast DNA replication and pro-basal body formation may be strictly coordinated in T. brucei in order to maintain the precise single-mitochondrion (kinetoplast), singleflagellum status of the interphase cell.

Fine structure of the dendritic junction body region of the antennal sensory cone in a larval elaterid (Coleoptera)

1971 ◽  
Vol 49 (6) ◽  
pp. 817-821 ◽  
Author(s):  
David A. Scott ◽  
R. Y. Zacharuk
Keyword(s):  
Fine Structure ◽  
Basal Body ◽  
Sense Organ ◽  
Body Region ◽  
Ultrastructural Evidence ◽  
Primary Function ◽  
Secretory Products

The component ciliary collar, basal body, ciliary rootlets, trichogen–dendrite secretory junctions and secretory inclusions of the junction body region of dendrites in the wireworm antennal sensory cone are described. The primary function ascribed to the junction body region, based on the ultrastructural evidence presented, is one of secretion. The hypothesis that the secretory products produced in the junction body region are transported to the dendritic terminations in the sense organ is discussed and supported.

scholarly journals THE FORMATION OF BASAL BODIES (CENTRIOLES) IN THE RHESUS MONKEY OVIDUCT

1971 ◽  
Vol 50 (1) ◽  
pp. 10-34 ◽  
Author(s):  
Richard G. W. Anderson ◽  
Robert M. Brenner
Keyword(s):  
Rhesus Monkey ◽  
Basal Body ◽  
Wall Material ◽  
Basal Bodies ◽  
Major Pathway ◽  
Tubule Formation ◽  
Body Formation ◽  
Body Production ◽  
Basal Foot ◽  
Section Analysis

Basal body replication during estrogen-driven ciliogenesis in the rhesus monkey (Macaca mulatta) oviduct has been studied by stereomicroscopy, rotation photography, and serial section analysis. Two pathways for basal body production are described: acentriolar basal body formation (major pathway) where procentrioles are generated from a spherical aggregate of fibers; and centriolar basal body formation, where procentrioles are generated by the diplosomal centrioles. In both pathways, the first step in procentriole formation is the arrangement of a fibrous granule precursor into an annulus. A cartwheel structure, present within the lumen of the annulus, is composed of a central cylinder with a core, spoke components, and anchor filaments. Tubule formation consists of an initiation and a growth phase. The A tubule of each triplet set first forms within the wall material of the annulus in juxtaposition to a spoke of the cartwheel. After all nine A tubules are initiated, B and C tubules begin to form. The initiation of all three tubules occurs sequentially around the procentriole. Simultaneous with tubule initiation is a nonsequential growth of each tubule. The tubules lengthen and the procentriole is complete when it is about 200 mµ long. The procentriole increases in length and diameter during its maturation into a basal body. The addition of a basal foot, nine alar sheets, and a rootlet completes the maturation process. Fibrous granules are also closely associated with the formation of these basal body accessory structures.

Structural Organization of Detergent-Extracted Cells

1980 ◽  
Vol 38 ◽  
pp. 814-817
Author(s):  
Manfred Schliwa
Keyword(s):  
Electron Microscopy ◽  
Fine Structure ◽  
Conformational Changes ◽  
Structural Organization ◽  
Three Dimensional ◽  
High Voltage Electron Microscopy ◽  
Dimensional Lattice ◽  
Voltage Electron ◽  
Cell Architecture ◽  
Critical Point Drying

Adequate visualization of the three-dimensional organization has always been a major problem in studies of cell architecture. Efforts of numerous investigators weredevoted to the question of how best information can be collected from specimens prepared with different procedures. In recent years, the potential of high voltage electron microscopy has been combined with a technique for sample preparation that circumvents embedding, namely critical point-drying from CO2, to study the three-dimensional fine structure of cells in culture. This approach has revealed new insights into the structural organization of the cytoplasm (1-4). A system of slender strands or microtrabeculae has been described to form an elaborate three-dimensional lattice in which other organelles are embedded. This system has been shown in some cells to undergo rapid conformational changes (3,5) and in general is believed to be an important component of the cytoskeleton, being responsible for the gelatious properties of the cytoplasm.

Some Aspects of the Cytology of Polycelis nigra

1961 ◽  
Vol s3-102 (59) ◽  
pp. 295-317
Author(s):  
R. J. SKAER
Keyword(s):  
Fine Structure ◽  
Epithelial Cells ◽  
Basement Membrane ◽  
Muscle Fibre ◽  
Cell Body ◽  
Basal Body ◽  
Sense Organs ◽  
Gland Cells ◽  
Secretion Granules ◽  
Undifferentiated Cells

The triclad, Polycelis nigra, has been found to be fully cellular. Gland-cells, undifferentiated cells, and the cell-bodies of muscle-cells, make up the parenchyma. The fine structure of the component cells of the parenchyma, nervous, and excretory systems, testis, pharynx, and epidermis is described. Acidophil secretion granules, produced by certain parenchymatous gland-cells, have a characteristic, doubly-banded ultrastructure which is not invariably associated with the property of adhesiveness. The parenchymatous cell-body of the muscles is often up to 10 µ. from the musclefibre, to which it is joined by tenuous cytoplasmic connexions. The muscle-fibre itself consists of coarse and fine sets of hexagonally arranged myofilaments, but is unhanded. The basement membrane of the epidermis is composed of fine, banded fibrils, apparently randomly arranged in the plane of the membrane. Permeating the epidermis at a level just above the basement membrane is a system of extracellular spaces, which may have a hydrostatic function and assist in the extrusion of secretion granules. Epidermal sense organs, whose fine structure resembles the basal body of the cilia, are considered to have a functionally significant distribution on the surface of the animal. The rhabdites have been shown to develop in special cells of the parenchyma. Such rhabdite-forming cells, together with their contained rhabdites, have been found apparently passing through the basement membrane of the epidermis. As all the epidermal epithelial cells contain rhabdites, it is suggested that the epidermis as a whole is renewed by centrifugal migration of rhabdite-forming cells. The rhabdites themselves appear to consist of arginine and some tyrosine, together with a purine, probably adenine. They may be an excretory product.

scholarly journals THE RELATIONSHIP BETWEEN THE FINE STRUCTURE AND DIRECTION OF BEAT IN GILL CILIA OF A LAMELLIBRANCH MOLLUSC

1961 ◽  
Vol 11 (1) ◽  
pp. 179-205 ◽  
Author(s):  
I. R. Gibbons
Keyword(s):  
Fine Structure ◽  
Cell Surface ◽  
Basal Body ◽  
Transitional Region ◽  
Basal Bodies ◽  
Conical Structure ◽  
The Relationship ◽  
Basal Foot ◽  
Different Levels ◽  
Outer Fiber

This paper describes the fine structure and its relationship to the direction of beat in four types of cilia on the gill of the fresh-water mussel Anodonta cataracta. The cilia contain nine outer, nine secondary, and two central fibers, such as have been described previously in other material. Each outer fiber is a doublet with one subfiber bearing arms. One particular pair of outer fibers (numbers 5 and 6) are joined together by a bridge. The two central fibers are enclosed by a central sheath; also present in this region is a single, small mid-fiber. The different groups of fibers are connected together by radial links that extend from the outer to the secondary fibers, and from the secondary fibers to the central sheath. The basal body consists of a cylinder of nine triplet fibers. Projecting from it on one side is a dense conical structure called the basal foot. The cylinder of outer fibers continues from the basal body into the cilium, passing through a complex transitional region in which five distinct changes of structure occur at different levels. There are two sets of fibers associated with the basal bodies: a pair of striated rootlets that extends from each basal body down into the cell, and a system of fine tubular fibers that runs parallel to the cell surface. The relationship between fine structure and direction of beat is the same in all four types of cilia examined. The plane of beat is perpendicular to the plane of the central fibers, with the effective stroke toward the bridge between outer fibers 5 and 6, and toward the foot on the basal body.

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