Assembly and fate of basal bodies in the colourless phytoflagellate Polytoma papillatum

Summary— The morphogenesis of basal bodies is described in the phytoflagellate Polytoma papillatum. The observations are based on the analysis of ultrathin serial sections through the flagellar apparatus of interphase, mitotic, and postmitotic cells using transmission electron microscopy. Formation of new basal bodies starts in prometaphase. Individual A-subfibres develop orthogonally to the long axis of mature basal bodies. The microtubules assemble at the surface of an annulus of amorphous material. By telophase, a complete cylinder of A-subfibres with a length of approximately 300 nm has formed. Although the proximal ends of these new probasal bodies are detached from the mature basal bodies, prominent reorientation of the probasal bodies does not occur. They remain with their proximal ends in the vicinity of mature basal bodies. In daughter cells with probasal bodies around 400 nm long, the assembly of microtubular triplets is initiated. B- and C-subfibres first show up distal from the mature basal bodies and may elongate towards them. Thus, A-subfibres on the one side and B- and C-subfibres on the other appear to growt with opposite polarity. If A-subfibres grow at their plus ends, B- and C-subfibres elongate at their minus ends. The latter is unusual in comparison with individual cytoplasmic and spindle microtubules. Possible the presence of a lateral template in the form of the A-subfibres is responsible for the deviating growth characteristics of the incomplete B- and C-subfibres. In interphase cells, the mature basal bodies extend into long flagella. The new basal bodies remain devoid of flagella and are less than 85 nm long. Thus, they have shortened relative to their precursors in mitotic and postmitotic cells. At the onset of a new division cycle, the flagellate basal badies shed their flagella. The breaking point is at the triplet-doublet transition of the flagellum.     

Transformation of the flagella and associated flagellar components during cell division in the coccolithophoridPleurochrysis carterae

Summary Immunofluorescence microscopy, conventional and high voltage transmission electron microscopy were used to describe changes in the flagellar apparatus during cell division in the motile, coccolithbearing cells ofPleurochrysis carterae (Braarud and Fagerlund) Christensen. New basal bodies appear alongside the parental basal bodies before mitosis and at prophase the large microtubular (crystalline) roots disassemble as their component microtubules migrate to the future spindle poles. By prometaphase the crystalline roots have disappeared; the flagellar axonemes shorten and the two pairs of basal bodies (each consisting of one parental and one daughter basal body) separate so that each pair is distal to a spindle pole. By late prometaphase the pairs of basal bodies bear diminutive flagellar roots for the future daughter cells. The long flagellum of each daughter cell is derived from the parental basal bodies; thus, the basal body that produces a short flagellum in the parent produces a long flagellum in the daughter cell. We conclude that each basal body in these cells is inherently identical but that a first generation basal body generates a short flagellum and in succeeding generations it produces a long flagellum. At metaphase a fibrous band connecting the basal bodies appears and the roots and basal bodies reorient to their interphase configuration. By telophase the crystalline roots have begun to reform and the rootlet microtubules have assumed their interphase appearance by early cytokinesis.Abbreviations CR1, CR2 crystalline roots 1 and 2 - CT cytoplasmic tongue microtubules - DIC differential interference contrast light microscopy - H haptonema - HVEM high voltage transmission electron microscopy - IMF immunofluorescence microscopy - L left flagellum/basal body - M metaphase plate - MT microtubule - N nucleus - R right flagellum/basal body - R1, R2, R3 roots 1, 2, and 3 - TEM transmission electron microscopy     

Rootletin interacts with C-Nap1 and may function as a physical linker between the pair of centrioles/basal bodies in cells

Rootletin, a major structural component of the ciliary rootlet, is located at the basal bodies and centrosomes in ciliated and nonciliated cells, respectively. Here we investigated its potential role in the linkage of basal bodies/centrioles and the mechanism involved in such linkages. We show that rootletin interacts with C-Nap1, a protein restricted at the ends of centrioles and functioning in centrosome cohesion in interphase cells. Their interaction in vivo is supported by their colocalization at the basal bodies/centrioles and coordinated association with the centrioles during the cell cycle. Ultrastructural examinations demonstrate that rootletin fibers connect the basal bodies in ciliated cells and are present both at the ends of and in between the pair of centrioles in nonciliated cells. The latter finding stands in contrast with C-Nap1, which is present only at the ends of the centrioles. Transient expression of C-Nap1 fragments dissociated rootletin fibers from the centrioles, resulting in centrosome separation in interphase. Overexpression of rootletin in cells caused multinucleation, micronucleation, and irregularity of nuclear shape and size, indicative of defects in chromosome separation. These data suggest that rootletin may function as a physical linker between the pair of basal bodies/centrioles by binding to C-Nap1.     

Centriole maturation and transformation to basal body

Centrioles and basal bodies are fascinating and mysterious organelles. They interconvert and seem to be crucial for a wide range of crucial cellular processes. However, intense research over the last years suggested that centrioles/basal bodies are essential mainly for the generation of cilia. Although a neglected organelle over a long time, interest in the primary cilia was recently rekindled by the notion that they are affected in a number of human diseases. Cilia formation is an intricate process that starts with the transformation of centrioles to basal bodies and their docking to the apical plasma membrane. Disturbance of basal body formation thus might cause ciliopathies. This review focuses on the formation of basal bodies in mammalian cells with an emphasis on basal bodies sprouting a primary cilium.     

Ultrastructure and cell size-dependent regulation of the adoral zone of membranelles in the heterotrich ciliate Stentor coeruleus

The number and length of oral membranelles were determined for both large and small Stentor from well-fed, growing cultures and nutrient-deprived cultures, respectively. Small cells possess both significantly fewer and shorter membranelles than do large cells. For both large and small cells, each membranelle is composed of three rows of basal bodies. The membranelles closest to the gullet have a third row that is only slightly shorter than the other two. The third row becomes rapidly shorter as membranelles become increasingly distant from the gullet. A short distance from the gullet, and for the remainder of the band, the third row is composed ofonly one to four basal bodies. The first two rows consist of approximately 35 basal bodies each in large cells and approximately 26 basal bodies each in small cells. This indicates that Stentor regulates the number of basal bodies per row, but not the number of rows, in response to changes in cell size. © 1992 Wiley-Liss, Inc.     

Patterns of basal body addition in ciliary rows in Tetrahymena

Most naked basal bodies visualized in protargol stains on the surface of Tetrahymena are new basal bodies which have not yet developed cilia. The rarity of short cilia is explained by the rapid development of the ciliary shaft once it begins to grow. The high frequency of naked basal bodies (about 50 percent) in log cultures indicates that the interval between assembly of the basal body and the initiation of the cilium is long, approximately a full cell cycle. Naked basal bodies are more frequent in the mid and posterior parts of the cell and two or more naked basal bodies may be associated with one ciliated basal body in these regions. Daughter cells produced at division are apparently asymmetric with respect to their endowment of new and old organelles.     

Evidence for a direct role of nascent basal bodies during spindle pole initiation in the green alga Spermatozopsis similis.

Basal body replication in the naked biflagellate green alga Spermatozopsis similis was analyzed using standard electron microscopy and immunogold localization of centrin, an ubiquitous centrosomal protein, and p210, a recently characterized basal apparatus component of S. similis. Fibrous disks representing probasal bodies appear at the proximal end of parental basal bodies at the end of interphase and development proceeds via a ring of nine singlet microtubules. Nascent basal bodies dock early to the plasma membrane but p210, usually present in basal body-membrane-linkers of S. similis, was already present on the cytosolic basal body precursors. In addition to the distal connecting fiber and the nuclear basal body connectors (NBBC) of the parental basal bodies, centrin was present on the fibrous probasal bodies, in a linker between probasal bodies and the basal apparatus, in the connecting fiber between nascent basal bodies and their corresponding parent, and, finally, a fiber linking the nascent basal bodies to the nucleus. This NBBC probably is present only in mitotic cells. During elongation a cartwheel of up to seven layers is formed, protruding from the proximal end of nascent basal bodies. Microtubules develop on the cartwheel indicating that it temporarily functions as a microtubule organizing center (MTOC). These microtubules and probably the cartwheels, touch the nuclear envelope at both sides of a nuclear projection. We propose that spindle assembly is initiated at these attachment sites. During metaphase, the spindle poles were close to thylakoid-free lobes of the chloroplast, and the basal bodies were not in the spindle axis. The role of nascent basal bodies during the initial steps of spindle assembly is discussed.     

Formation of flagella lacking outer rings by flaM, flaU, and flaY mutants of Escherichia coli.

Among flagellar mutants of Escherichia coli, flaM or flaU mutants form basal bodies lacking the outer P and L rings, whereas flaY mutants predominantly form basal bodies lacking the L ring. In these mutants, hooks and filaments are occasionally assembled onto these incomplete basal bodies. When the hook protein gene, flaFV, of Salmonella typhimurium was cloned on the multicopy plasmid pBR322 and introduced into these mutants, the efficiency with which cells assembled hooks and filaments onto the incomplete basal bodies increased significantly. Such cells formed characteristic dotted swarms on semisolid plates, indicating that cells carrying flagella without the outer rings are weakly motile because of poor function of their flagella, a low flagellar number per cell, or both of these defects. FlaV mutants also produced incomplete basal bodies lacking the outer rings, but assembly of hooks and filaments did not occur in these mutants even after introduction of the plasmid carrying flaFV of S. typhimurium. The failure in the case of flaV mutants was attributed to their inability to modify the rod tip to the structure competent for assembly of hook protein.     

The structure of epidermal feet during their development

Epidermal cells in Calpodes and other insects form basal processes or feet that at first extend axially and later shorten at the same time as the larval segment shortens to the pupal shape. The feet grow into spaces at the surfaces of other cells to make a basal interlacing meshwork of cellular extensions that are combined mechanically by their desmosomal attachments to cell bodies above and to the basal lamina below. Microtubules and microfilaments are linked to these junctions by a reticular fibrous matrix. Gap junctions on the feet may couple cells that are several cell bodies removed from one another. The meshwork is also a sieve separating the hemolymph from the spaces between cells to form an intercellular compartment. Entry to the intercellular compartment is through the sieve made by the negatively charged basolateral cell surfaces that can prevent the entry of positively charged molecules such as cationic ferritin. As the cells become columnar, coincident with the metamorphic change in segment shape, the feet shorten and pack more densely together. At this time the basal lamina buckles axially as if responding to contraction of the feet. Segment shape change involves cell rearrangement and relative cell movement, necessitating the transient loss of plasma membrane plaque attachments to the cuticle apically and the loss of junctions laterally. Gap junctions involute in characteristic vacuoles. The metamorphic reduction in cell surface area coincides with the loss of basolateral membrane in smooth tubes and vesicles and the turnover of the apical surface in multivesicular bodies. New apical plasma membrane plaques and new lateral and basal junctions stabilize the cells in their pupal positions.     

COMPARATIVE ANALYSIS OF THE FINE STRUCTURE OF YOUNG AND ADULT INDIVIDUALS OF DUNALIELLA SALINA (POLYBLEPHARIDACEAE,CHLOROPHYCEAE) WITH EMPHASIS ON THE FLAGELLAR APPARATUS1

Individuals of Dunaliella salina (Dunal.) Teod. change their shape during ontogenesis. Here we describe the fine structure of this species with emphasis on distinctions between young and adult individuals. The cell coat is present at early stages of cell development and may be synthesized by vesicles of nuclear membrane-associated endoplasmic reticulum. Scanning electron microscopical observations show differences in the surface pattern of the cell coat in young and adult cells. The nucleus of young cells is more or less spherical, whereas that of adult cells is pyriform. The Golgi apparatus is positioned immediately under the basal bodies and consists of three dictyosomes in young cells and six to eight dictyosomes in adult cells. The flagellar apparatuses of young and adult cells have a 1/7 o'clock (i.e. clockwise) displacement of basal bodies and are grossly similar, but there are subtle differences between specific components. Two non-axonemic basal bodies (1′, 2′) appear in a plane perpendicular to that determined by the flagella-bearing basal bodies (1, 2). The cruciate microtubular rootlet system has a 4–2–4–2 alternation pattern. In adult cells, rhizoplasts emerge from each terminal body and run parallel to the four rootlets.     

Immunocytochemical localization of myosin during ciliogenesis of quail oviduct

Myosin has been localized during ciliogenesis of quail oviduct by immunocytochemistry (immunofluorescence, immunoperoxidase, immunogold labeling) using a previously characterized monoclonal antibody. In ovariectomized quail oviduct many undifferentiated epithelial cells present a primary cilium arising from one of the diplosome centrioles. Myosin is associated with material located between the two centrioles. In contrast, in estrogen-stimulated quail oviduct, the material preceding the procentioles is never labeled. Basal bodies become labeled just before their migration toward the apical plasma membrane. During the anchoring phase, the labeling is mainly associated with the basal feet. In mature ciliated cells, myosin appears associated with an apical network embedding the basal bodies. This network is connected to a myosin-rich belt associated with the apical junctional complex which differentiates at the beginning of centriologenesis. The association of myosin with migrating basal bodies suggests that myosin could be involved in basal body movements.     

Cilia-lacking respiratory cells in ciliary aplasia

This report describes the ultrastructural alterations observed in the nasal and bronchial mucosa of an 11-yr-old male suffering from immotile cilia syndrome (ICS). The morphological features observed in this patient are consistent with a ciliary aplasia. In fact, ciliated cells appeared to be replaced by columnar cells lacking cilia and basal bodies, and bearing on their surface cilium-like projections without any internal axonemal structure. In spite of the absence of basal bodies, centrioles, and kinocilia, these cells unexpectedly showed mature striated roots and centriolar precursor material scattered throughout the apical cytoplasm. These data suggest that control over basal body assembly is distinct from control over striated root formation. The presence of the above-reported structures in cells otherwise presenting many morphological features of normal ciliated cells is discussed on the basis of current knowledge of respiratory cilia biogenesis.     

Calcium-modulated contractile proteins associated with the eucaryotic centrosome

Affinity-purified antibodies that recognize the 20,000-dalton molecular weight (20 kd) striated flagellar root protein of Tetraselmis striata have been used to identify antigenic homologs in other eucaryotic organisms of diverse evolutionary origins. Among the green algae, Tetraselmis and Chlamydomonas, and their colorless relative, Polytomella, the 20-kd homologs appear associated with basal bodies. This occurs most prominently in the form of flagellar roots of both striated and microtubule subtended types. Among cultured mammalian cells (PtK2 and primary mouse macrophage cell lines), flagellar root protein homologs appear as basal feet, pericentriolar fibrils, and pericentriolar satellites. Mammalian sperm cells also show flagellar root protein homologs associated with their basal bodies. We envisage a functional role for these fibrous calcium-sensitive contractile proteins in altering the orientation of centrioles or basal bodies with their associated MTOCs by responding to topological calcium fluxes.     

The basal bodies of Chlamydomonas reinhardtii. Formation from probasal bodies, isolation, and partial characterization

The assembly and composition of basal bodies was investigated in the single-celled, biflagellate green alga, Chlamydomonas reinhardtii, using the cell wall-less strain, cw15. In the presence of EDTA, both flagellar axonemes remained attached to their basal bodies while the entire basal body-axoneme complex was separated from the cell body, without cell lysis, by treatment with polyethylene glycol-400. The axonemes were then removed from the basal bodies in the absence of EDTA, leaving intact basal body pairs, free from particulate contamination from other regions of the cell. The isolated organelles produced several bands on sodium dodecyl sulfate-urea polyacrylamide gels, including two tubilin bands which co-electrophoresed with flagellar tubulin. The formation of probasal bodies was observed by electron microscopy of whole mount preparations. Synchronous cells were lysed, centrifuged onto carbon-coated grids, and either negatively stained or shadowed with platinum. The two probasal bodies of each cell appeared shortly after mitosis as thin "annuli," not visible in thin sections, each consisting of nine rudimentary triplet microtubules. Each annulus remained attached to one of the mature basal bodies by several filaments about 60 in diameter, and persisted throughout interphase until just before the next cell division. It then elongated into a mature organelle. The results revive the possibility of the nucleated assembly of basal bodies.     

Three-dimensional organization of basal bodies from wild-type and delta-tubulin deletion strains of Chlamydomonas reinhardtii

Improved methods of specimen preparation and dual-axis electron tomography have been used to study the structure and organization of basal bodies in the unicellular alga Chlamydomonas reinhardtii. Novel structures have been found in both wild type and strains with mutations that affect specific tubulin isoforms. Previous studies have shown that strains lacking delta-tubulin fail to assemble the C-tubule of the basal body. Tomographic reconstructions of basal bodies from the delta-tubulin deletion mutant uni3-1 have confirmed that basal bodies contain mostly doublet microtubules. Our methods now show that the stellate fibers, which are present only in the transition zone of wild-type cells, repeat within the core of uni3-1 basal bodies. The distal striated fiber is incomplete in this mutant, rootlet microtubules can be misplaced, and multiflagellate cells have been observed. A suppressor of uni3-1, designated tua2-6, contains a mutation in alpha-tubulin. tua2-6; uni3-1 cells build both flagella, yet they retain defects in basal body structure and in rootlet microtubule positioning. These data suggest that the presence of specific tubulin isoforms in Chlamydomonas directly affects the assembly and function of both basal bodies and basal body-associated structures.     

THE MORPHOGENESIS OF BASAL BODIES AND ACCESSORY STRUCTURES OF THE CORTEX OF THE CILIATED PROTOZOAN TETRAHYMENA PYRIFORMIS

Dividing cells of Tetrahymena pyriformis were observed by transmission electron microscopy for signs of morphogenesis of cortical structures. The earliest stage of basal body development observed was of a short cylinder of nine single tubules connected by an internal cartwheel structure. This is set perpendicular to the mature basal body at its anterior proximal surface under the transverse microtubules and next to the basal microtubules. Sequential stages show that the single tubules become triplet tubules and that the "probasal bodies" then elongate and tilt toward the organism's surface while maintaining a constant distance of 75–100 mµ with the "parent." The new basal body after it is fully extended contacts the pellicle, and then assumes a parallel orientation with and moves anterior to the parent basal body. The electron-opaque core in the lumen of the basal body and accessory structures around its outer proximal surface appear after the developing basal body has elongated. These accessory structures associating with their counterparts from other basal bodies and with the longitudinal microtubules may play a role in the final positioning of basal bodies and thus in the maintenance of cortical patterns. Observations on a second sequence of basal body formation suggest that the oral anlage arises by multiple duplication of somatic basal bodies.     

Ovariolar 'basal body' development and physiological age of the mosquito Aedes aegypti

Abstract. Dissection of the ovaries of the mosquito Aedes aegypti (Diptera: Culicidae) revealed, in each ovariole, a group of seven to nine specialized epithelial cells in a region of the calyx wall that is enclosed by the end of the ovariolar sheath. This group of cells is termed the basal body. During ovulation, the mature oocyte passes from the ovariole into the calyx lumen through the basal body. Subsequently, granulation occurs in the basal body cells. The granular basal bodies differ from all previously described ovarian structures. In multiparous females the size and optical density of the granular basal bodies increase after each ovulation. Examination of the granular basal bodies in intact ovaries, stained with neutral red, provides an easy method for distinguishing parous from nulliparous females, and has potential as a new method of age grading.     

Structure and Protein Composition of a Basal‐Body Scaffold (“Cage”) in the Hypotrich Ciliate Euplotes

Cilia on the ventral surface of the hypotrich ciliate Euplotes are clustered into polykinetids or compound ciliary organelles, such as cirri or oral membranelles, used in locomotion and prey capture. A single polykinetid may contain more than 150 individual cilia; these emerge from basal bodies held in a closely spaced array within a scaffold or framework structure that has been referred to as a basal‐body “cage”. Cage structures were isolated free of cilia and basal bodies; the predominant component of such cages was found on polyacrylamide gels to be a 45‐kDa polypeptide. Antisera were raised against this protein band and used for immunolocalizations at the light and electron microscope levels. Indirect immunofluorescence revealed the 45‐kDa polypeptide to be localized exclusively to the bases of the ventral polykinetids. Immunogold staining of thin sections of intact cells further localized this reactivity to filaments of a double‐layered dense lattice that appears to link adjoining basal bodies into ordered arrays within each polykinetid. Scanning electron microscopy of isolated cages reveals the lower or “basal” cage layer to be a fine lacey meshwork supporting the basal bodies at their proximal ends; adjoining basal bodies are held at their characteristic spacing by filaments of an upper or “medial” cage layer. The isolated cage thus resembles a miniature test‐tube rack, able to accommodate varying arrangements of basal‐body rows, depending on the particular type of polykinetid. Because of its clear and specific localization to the basal‐body cages in Euplotes, we have termed this novel 45‐kDa protein “cagein”.     

Possible biogenesis of the membrane-bound bodies of the thick basal laminae of the proximal convoluted tubule cells of the gerbil Meriones crassus.

The ultrastructural findings on the kidney cells of the gerbil Meriones crassus have shown the presence of finger-like projections emerging from the basal part of the epithelial cells of the proximal convoluted tubules into the matrix of the thick basal laminae and that structure like membrane-bound bodies are commonly seen in continuity with these processes. Such findings would give clues for the possible biogenesis of the membrane-bound bodies from the epithelial cells. Such an origin is consistent with the idea that either all or part of the population of membrane-bound bodies is produced by a process of budding off from the basal cell membrane rather than by extension of an intracytoplasmic precursor through the plasma membrane.     

Elucidation of basal body and centriole functions in Chlamydomonas reinhardtii

In eukaryotic cells, basal bodies and their structural equivalents, centrioles, play essential roles. They are needed for the assembly of flagella or cilia as well as for cell division. Chlamydomonas reinhardtii provides an excellent model organism for the study of the basal body and centrioles. Genes for two new members of the tubulin superfamily are needed for basal body/centriole duplication. In addition, other genes that play roles in the duplication and segregation of basal bodies are discussed.