Ultrastructure of Draparnaldia glomerata (Chaetophorales, Chlorophyceae) II. Mitosis and cytokinesis

The mitosis and cytokinesis of Draparnaldia glomerata as examined here by transmission electron microscopy are in many aspects similar to those described earlier for other chaetophoralean algae. The standard chaetophoralean model of the mechanism of mitosis/cytokinesis is described in detail. Characteristic in this pattern is the movement of sets of centrioles towards the nuclear poles followed by a proliferation of extranuclear microtubules at prophase, the (partial) fusion of centrioles with the spindle poles at metaphase and anaphase, the simultaneous separation of chromosomes apparently caused by both spindle elongation and shortening of the chromosomal microtubules at anaphase, the expulsion of the centrioles by daughter nuclei and finally the non–persistent spindle at telophase. Cytokinesis takes place by formation of a cell plate associated with phycoplast microtubules. The possible function of the phycoplast in cytokinesis in Draparnaldia is discussed.     

INDEPENDENCE OF CENTRIOLE FORMATION AND DNA SYNTHESIS

The temporal relationship between cell cycle events and centriole duplication was investigated electron microscopically in L cells synchronized by mechanically selecting mitotic cells. The two mature centrioles which each cell received at telophase migrated together from the side of the telophase nucleus distal to the stem body around to a region of the cytoplasm near the stem body and then into a groovelike indention in the early G₁ nucleus, where they were found throughout interphase. Procentrioles appeared in association with each mature centriole at times varying from 4 to 12 h after mitosis. Since S phase was found to begin on the average about 9 h after mitotic selection, it appeared that cells generated procentrioles late in G₁ or early in S. During prophase, the two centriolar duplexes migrated to opposite sides of the nucleus and the daughter centrioles elongated to the mature length. To ascertain whether any aspect of centriolar duplication was contingent upon nuclear DNA synthesis, arabinosyl cytosine was added to mitotic cells at a concentration which inhibited cellular DNA synthesis by more than 99%. Though cells were thus prevented from entering S phase, the course of procentriole formation was not detectibly affected. However, cells were inhibited from proceeding to the next mitosis, and the centriolar elongation and migration normally associated with prophase did not occur.     

The centriole cycle in the amoebae of the myxomycetePhysarum polycephalum

Summary In the amoebae of the myxomycetePhysarum polycephalum, procentrioles are formed on the anterior and posterior centrioles in early prophase. Although the relative position of the parental and procentrioles is fixed, all relative positions of the daughter and parental centrioles were observed. During the different stages of mitosis daughter centrioles elongate and acquire anterior satellites, one of the characteristic features of the anterior centrioles. All other anterior morphological characteristics appear only in telophase and early reconstruction stages. In contrast to the parental posterior centrioles, which do not change morphologically during the successive mitotic stages, the parental anterior centrioles lose their morphological characteristics in late prophase and early prometaphase and then acquire the morphological features characteristic of the posterior centrioles. Thus, the following maturation scheme is suggested: a procentriole becomes an anterior centriole during the first mitosis and a posterior centriole during the second mitosis. Since posterior features are maintained during mitosis, the posterior centriole corresponds to the final state of centriole maturation.     

Control of daughter centriole formation by the pericentriolar material

Controlling the number of its centrioles is vital for the cell, as supernumerary centrioles cause multipolar mitosis and genomic instability. Normally, one daughter centriole forms on each mature (mother) centriole; however, a mother centriole can produce multiple daughters within a single cell cycle. The mechanisms that prevent centriole 'overduplication' are poorly understood. Here we use laser microsurgery to test the hypothesis that attachment of the daughter centriole to the wall of the mother inhibits formation of additional daughters. We show that physical removal of the daughter induces reduplication of the mother in S-phase-arrested cells. Under conditions when multiple daughters form simultaneously on a single mother, all of these daughters must be removed to induce reduplication. The number of daughter centrioles that form during reduplication does not always match the number of ablated daughter centrioles. We also find that exaggeration of the pericentriolar material (PCM) by overexpression of the PCM protein pericentrin in S-phase-arrested CHO cells induces formation of numerous daughter centrioles. We propose that that the size of the PCM cloud associated with the mother centriole restricts the number of daughters that can form simultaneously.     

Centrioles in the cell cycle of L cells

The structure of centrosome in non-synchronous L-cells culture during the cell cycle has been studied. In mitosis, mother and daughter centrioles, which differ in their ultrastructure, are located perpendicularly in the pole of the spindle. Microtubules, meeting in the pole area terminate mainly in electron-dense clottings of fibrillar matter surrounding the diplosoma. In telophase, disjunction of mother and daughter centrioles begins. At the beginning of G1-period, centrioles move off from each other for several micron, and then draw together again without forming diplosome. Pericentriolar satellites form on mother centriole of some cells at this time, they disappear at the beginning of S-period, replication of centrioles begins; daughter centrioles reach the size of mother centrioles in anaphase. During growth and maturation, centrioles in L-cells undergo structural changes similar to those described for SPEV cells (Vorob'ev, Chentsov, 1982). Several types of meeting points for microtubules exist in L-cells during the whole interphase: surface of centrioles per se, pericentriolar satellites, free foci.     

CENTRIOLE REPLICATION : A Study of Spermatogenesis in the Snail Viviparus

This paper describes the replication of centrioles during spermatogenesis in the Prosobranch snail, Viviparus malleatus Reeve. Sections for electron microscopy were cut from pieces of testis fixed in OsO₄ and embedded in the polyester resin Vestopal W. Two kinds of spermatocytes are present. These give rise to typical uniflagellate sperm carrying the haploid number of 9 chromosomes, and atypical multiflagellate sperm with only one chromosome. Two centrioles are present in the youngest typical spermatocyte. Each is a hollow cylinder about 160 mµ in diameter and 330 mµ long. The wall consists of 9 sets of triplet fibers arranged in a characteristic pattern. Sometime before pachytene an immature centriole, or procentriole as it will be called, appears next to each of the mature centrioles. The procentriole resembles a mature centriole in most respects except length: it is more annular than tubular. The daughter procentriole lies with its axis perpendicular to that of its parent. It presumably grows to full size during the late prophase, although the maturation stages have not been observed with the electron microscope. It is suggested that centrioles possess a constant polarization. The distal end forms the flagellum or other centriole products, while the proximal end represents the procentriole and is concerned with replication. The four centrioles of prophase (two parents and two daughters) are distributed by the two meiotic divisions to the four typical spermatids, in which they function as the basal bodies of the flagella. Atypical spermatocytes at first contain two normal centrioles. Each of these becomes surrounded by a cluster of procentrioles, which progressively elongate during the late prophase. After two aberrant meiotic divisions the centriole clusters give rise to the basal bodies of the multiflagellate sperm. These facts are discussed in the light of the theory, first proposed by Pollister, that the supernumerary centrioles in the atypical cells are derived from the centromeres of degenerating chromosomes.     

MITOSIS IN THE AQUATIC FUNGUS RHIZOPHYDIUM SPHEROTHECA (CHYTRIDIALES)

The structure of centric, intranuclear mitosis and of organelles associated with nuclei are described in developing zoosporangia of the chytrid Rhizophydium spherotheca. Frequently dictyosomes partially encompass the sides of diplosomes (paired centrioles). A single, incomplete layer of endoplasmic reticulum with tubular connections to the nuclear envelope is found around dividing nuclei. The nuclear envelope remains intact during mitosis except for polar fenestrae which appear during spindle incursion. During prophase, when diplosomes first define the nuclear poles, secondary centrioles occur adjacent and at right angles to the sides of primary centrioles. By late metaphase the centrioles in a diplosome are positioned at a 40° angle to each other and are joined by an electron-dense band; by telophase the centrioles lie almost parallel to each other. Astral microtubules radiate into the cytoplasm from centrioles during interphase, but by metaphase few cytoplasmic microtubules are found. Cytoplasmic microtubules increase during late anaphase and telophase as spindle microtubules gradually disappear. The mitotic spindle, which contains chromosomal and interzonal microtubules, converges at the base of the primary centriole. Throughout mitosis the semipersistent nucleolus is adjacent to the nuclear envelope and remains in the interzonal region of the nucleus as chromosomes separate and the nucleus elongates. During telophase the nuclear envelope constricts around the chromosomal mass, and the daughter nuclei separate from each end of the interzonal region of the nucleus. The envelope of the interzonal region is relatively intact and encircles the nucleolus, but later the membranes of the interzonal region scatter and the nucleolus disperses. The structure of the mitotic apparatus is similar to that of the chytrid Phlyctochytrium irregulare.     

Spermatogenesis and spermiogenesis in Ascaris lumbricoides Var. suum

Reorganization of the prophase I nucleus marks the beginning of the first meiotic division. A pair of centrioles is present at each pole at metaphase I and mitochondria are not observed in the spindle area. A chromosomal pellicle, which resembles a kinetochore plate but has no apparent association with microtubules, surrounds each autosome at metaphase I and II. The sex body lags behind the autosomes at anaphase I and segregates differentially to one daughter cell. Mitochondria and a pair of centrioles are present in the spindle during the second meiotic division. Localized condensation of chromatin and fusion of the condensed chromatin of the secondary spermatocyte telophase nucleus results in a compact spermatid nucleus. Loss of spermatid cytoplasm is effected by the ejection of a cytophore vesicle.     

Light and electron microscopy of Rat kangaroo cells in mitosis

Rat kangaroo (PtK₂) cells were fixed and embedded in situ. Cells in mitosis were studied with the light microscope and thin sections examined with the electron microscope. Pericentriolar, osmiophilic material, rather than the centrioles, is probably involved in the formation of astral microtubules during prophase. Centriole migration occurs during prophase and early prometaphase. The nuclear envelope ruptures first in the vicinity of the asters. Nuclear pore complexes disintegrate as envelope fragments are dispersed to the periphery of the mitotic spindle. Microtubules invade the nucleus through gaps of the fragmented envelope. The number of microtubules and the degree of spindle organization increase during prometaphase and are maximal at metaphase. At this stage, chromosomes are aligned on the spindle equator, sister kinetochores facing opposite poles. Cytoplasmic organelles are excluded from the spindle. Prominent bundles of kinetochore microtubules converge towards the poles. Spindles in cold-treated cells consist almost exclusively of kinetochore tubules. Separating daughter chromosomes in early anaphase are connected by chromatin strands, possibly reflecting the rupturing of fibrous connections occasionally observed between sister chromatids in prometaphase. Breakdown of the spindle progresses from late anaphase to telophase, except for the stem bodies. Chromosomes decondense to form two masses. Nuclear envelope reconstruction, probably involving endoplasmic reticulum, begins on the lateral faces. Nuclear pores reappear on membrane segments in contact with chromatin. Microtubules are absent from reconstructed daughter nuclei.This report is to a large part based on a dissertation submitted by the author to the Graduate Council of the University of Florida in partial fulfillment of the requirements for the degree of Doctor of Philosophy.     

Dynamic distribution of Ser-10 phosphorylated histone H3 in cytoplasm of MCF-7 and CHO cells during mitosis

The dynamic distribution of phosphorylated Histone H3 on Serl 0 (phospho-H3) in cells was investigated to determine its function during mitosis. Human breast adenocarcinoma cells MCF-7, and Chinese hamster cells CHO were analyzed by indirect immunofluorescence staining with an antibody against phospho-H3. We found that the phosphorylation begins at early prophase, and spreads throughout the chromosomes at late prophase. At metaphase, most of the phospho-H3 aggregates at the end of the condensed entity of chromosomes at equatorial plate. During anaphase and telophase,the fluorescent signal of phospho-H3 is detached from chromosomes into cytoplasm. At early anaphase, phospho-H3 shows ladder bands between two sets of separated chromosome, and forms “sandwich-like structure” when the chromosomes condensed. With the cleavage progressing, the “ladders” of the histone contract into a bigger bright dot. Then the histone aggregates and some of compacted microtubules in the midbody region are composed into a “bar-like”complex to separate daughter cells. The daughter cells seal their plasma membrane along with the ends of the “bar”,inside which locates microtubules and modified histones, to finish the cytokinesis and keep the “bar complex” out of the cells. The specific distribution and kinetics of phospho-H3 in cytoplasm suggest that the modified histones may take part in the formation of midbody and play a crucial role in cytokinesis.     

Fine structure of Bacillus subtilis. I. Fixation

The fine structure of Bacillus subtilis has been studied by observing sections fixed in KMnO(4), OsO(4), or a combination of both. The majority of examinations were made in samples fixed in 2.0 per cent KMnO(4) in tap water. Samples were embedded in butyl methacrylate for sectioning. In general, KMnO(4) fixation appeared to provide much better definition of the boundaries of various structures than did OsO(4). With either type of fixation, however, the surface structure of the cell appeared to consist of two components: cell wall and cytoplasmic membrane. Each of these, in turn, was observed to have a double aspect. The cell wall appeared to be composed of an outer part, broad and light, and an inner part, thin and dense. The cytoplasmic membrane appeared (at times, under KMnO(4) fixation) as two thin lines. In cells fixed first with OsO(4) solution, and then refixed with a mixture of KMnO(4) and OsO(4) solutions, the features revealed were more or less a mixture of those revealed by each fixation alone. A homogeneous, smooth structure, lacking a vacuole-like space, was identified as the nuclear structure in a form relatively free of artifacts. Two unidentified structures were observed in the cytoplasm when B. subtilis was fixed with KMnO(4). One a tortuous, fine filamentous element associated with a narrow light space, was often found near the ends of cells, or attached to one end of the pre-spore. The other showed a special inner structure somewhat similar to cristae mitochondriales.     

TRANSIENT LOCALIZATION OF γ-TUBULIN AROUND THE CENTRIOLES IN THE NUCLEAR DIVISION OF BOERGESENIA FORBESII (SIPHONOCLADALES, CHLOROPHYTA)

Mitosis in Boergesenia forbesii (Harvey) Feldman was studied by immunofluorescence microscopy using anti-β–tubulin, anti-γ–tubulin, and anti-centrin antibodies. In the interphase nucleus, one, two, or rarely three anti-centrin staining spots were located around the nucleus, indicating the existence of centrioles. Microtubules (MTs) elongated randomly from the circumference of the nuclear envelope, but distinct microtubule organizing centers could not be observed. In prophase, MTs located around the interphase nuclei became fragmented and eventually disappeared. Instead, numerous MTs elongated along the nuclear envelope from the discrete anti-centrin staining spots. Anti-centrin staining spots duplicated and migrated to the two mitotic poles. γ–Tubulin was not detected at the centrioles during interphase but began to localize there from prophase onward. The mitotic spindle in B. forbesii was a typical closed type, the nuclear envelope remaining intact during nuclear division. From late prophase, accompanying the chromosome condensation, spindle MTs could be observed within the nuclear envelope. A bipolar mitotic spindle was formed at metaphase, when the most intense staining of γ-tubulin around the centrioles could also be seen. Both spindle MT poles were formed inside the nuclear envelope, independent of the position of the centrioles outside. In early anaphase, MTs between separating daughter chromosomes were not detected. Afterward, characteristic interzonal spindle MTs developed and separated both sets of the daughter chromosomes. From late anaphase to telophase, γ-tubulin could not be detected around the centrioles and MT radiation from the centrioles became diminished at both poles. γ-Tubulin was not detected at the ends of the interzonal spindle fibers. When MTs were depolymerized with amiprophos methyl during mitosis, γ-tubulin localization around the centrioles was clearly confirmed. Moreover, an influx of tubulin molecules into the nucleus for the mitotic spindle occurred at chromosome condensation in mitosis.     

THE FINE STRUCTURE OF THE NUCLEOLUS IN MITOTIC DIVISIONS OF CHINESE HAMSTER CELLS IN VITRO

The nucleolus of Chinese hamster tissue culture cells (strain Dede) was studied in each stage of mitosis with the electron microscope. Mitotic cells were selectively removed from the cultures with 0.2 per cent trypsin and fixed in either osmium tetroxide or glutaraldehyde followed by osmium tetroxide. The cells were embedded in both prepolymerized methacrylate and Epon 812. Thin sections of interphase nucleoli revealed two consistent components; dense 150-A granules and fine fibrils which measured 50 A or less in diameter. During prophase, distinct zones which were observed in some interphase nucleoli (i.e. nucleolonema and pars amorpha) were lost and the nucleoli were observed to disperse into smaller masses. By late prophase or prometaphase, the nucleoli appeared as loosely wound, predominantly fibrous structures with widely dispersed granules. Such structures persisted throughout mitosis either free in the cytoplasm or associated with the chromosomes. At telophase, those nucleolar bodies associated with the chromosomes became included in the daughter nuclei, resumed their compact granular appearance, and reorganized into an interphase-type structure.     

Centrioles: some self-assembly required

Centrioles play an important role in organizing microtubules and are precisely duplicated once per cell cycle. New (daughter) centrioles typically arise in association with existing (mother) centrioles (canonical assembly), suggesting that mother centrioles direct the formation of daughter centrioles. However, under certain circumstances, centrioles can also selfassemble free of an existing centriole (de novo assembly). Recent work indicates that the canonical and de novo pathways utilize a common mechanism and that a mother centriole spatially constrains the self-assembly process to occur within its immediate vicinity. Other recently identified mechanisms further regulate canonical assembly so that during each cell cycle, one and only one daughter centriole is assembled per mother centriole.     

Regulation of Mitosis in Living Cells. I. Mitosis under Controlled Conditions

A quantitative method has been devised to study mitosis in vitro by phase contrast and polarization microscopy. Mitosis in cell-wall-free endosperm cells of Haemanthus kathrinar Baker (the African blood lily) has been divided into 18 arbitrary stages or events. The time course for the various stapes, as well as the percentage of cells that proceed from one stage to another during a four hour observation period, are presented. Cells that were in prophase when selected for study proceeded from nuclear membrane breakdown to melaphase in 60 minutes and remained in melaphase for 30 minutes. Only 13 minutes was required to proceed from onset of anaphase to mid-anaphasc. Mid-anaphase provides a clear and precise baseline for determining the time required for succeeding stages to appear. The cell plate made its appearance 40 minutes after mid-anaphase and was completely formed 20 minutes later. The nuclear membranes also became evident at this latter time and nucleoli were visible 30 minutes later. Thus, the average time for a cell observed initially in prophase to proceed from nuclear membrane breakdown to formation of two daughter cells was just over three hours. A high percentage of cells that were in late prophase or later stages of mitosis at the time of initial observation completed mitosis during the observation period. The effect of the length of time a cell is subjected to experimental conditions upon its subsequent behaviour is assessed. These results form the basis for future studies of the effects of chemicals, particularly herbicides, upon cells in mitosis as observed in vitro by phase contrast and polarization microscopy.     

Zoosporulation in Labyrinthula sp.; an Electron Microscope Study1

SYNOPSIS. Zoosporulation in Labyrinthula sp. in monoxenic culture was initiated by aggregation of spindle cells into reticulate sori. The spindle cells then changed into rounded or oval cells and formed, de novo, 2 pairs of centrioles at opposite sides of each nucleus. A pair of granular aggregates (protocentrioles) ～ 240 mμ in diameter served as precursor bodies during centriole formation. Spindle microtubules around the prophase nucleus connected the pairs of centrioles but were not found in the nucleoplasm until nuclear envelope fragmentation occurred. Prophase nuclei of uninucleated sporangia contained synaptinemal complexes; therefore, meiosis is presumed to occur. The envelope fragments moved toward the centrioles and regrouped to form the nuclear membranes of the daughter cells. Alternating nuclear and cytoplasmic divisions subdivided the preparation into 8 cells which differentiated into laterally biflagellated zoospores. Flagellar development involved growth of the kinetosome microtubules into a bud which formed over the kinetosome tangential to the cell surface. Kinetosomes were derived directly from centrioles with little differentiation other than addition of an electron-dense core to the lumen of the centriole. Zoospore ultrastructure included a stigma comprised of a row of electron-dense granules located slightly under the plasmalemma and posterior to the pair of kinetosomes. A single row of 17–21 microtubules lay parallel to the stigma granules, one or more being connected to the anterior kinetosome. A striated fiber apparatus similar to that found in some phytoflagellates connected the midregions of the kinetosomes. Fibers 1.0–1.2 μ long were attached to the plasmalemma around the base of the anterior flagellum. Zoospores settled on the substrate and differentiated directly into spindle cells. Since synaptinemal complexes were observed the planonts are probably haploid zoospores and probably not gametes since planogametic copulation was not observed.     

Centriole distribution during tripolar mitosis in Chinese hamster ovary cells

During bipolar mitosis a pair of centrioles is distributed to each cell but the activities of the two centrioles within the pair are not equivalent. The parent is normally surrounded by a cloud of pericentriolar material that serves as a microtubule-organizing center. The daughter does not become associated with pericentriolar material until it becomes a parent in the next cell cycle (Rieder, C.L., and G. G. Borisy , 1982, Biol. Cell., 44:117-132). We asked whether the microtubule-organizing activity associated with a centriole was dependent on its becoming a parent. We induced multipolar mitosis in Chinese hamster ovary cells by treatment with 0.04 micrograms/ml colcemid for 4 h. After recovery from this colcemid block, the majority of cells divided into two, but 40% divided into three and 2% divided into four. The tripolar mitotic cells were examined by antitubulin immunofluorescence and by high voltage electron microscopy of serial thick (0.25-micron) sections. The electron microscope analysis showed that centriole number was conserved and that the centrioles were distributed among the three spindle poles, generally in a 2:1:1 or 2:2:0 pattern. The first pattern shows that centriole parenting is not prerequisite for association with pole function; the second pattern indicates that centrioles per se are not required at all. However, the frequency of midbody formation and successful division was higher when centrioles were present in the 2:1:1 pattern. We suggest that the centrioles may help the proper distribution and organization of the pericentriolar cloud, which is needed for the formation of a functional spindle pole.     

Centrioles in the cell cycle. I. Epithelial cells

A study was made of the structure of the centrosome in the cell cycle in a nonsynchronous culture of pig kidney embryo (PE) cells. In the spindle pole of the metaphase cell there are two mutually perpendicular centrioles (mother and daughter) which differ in their ultrastructure. An electron-dense halo, which surrounds only the mother centriole and is the site where spindle microtubules converge, disappears at the end of telophase. In metaphase and anaphase, the mother centriole is situated perpendicular to the spindle axis. At the beginning of the G1 period, pericentriolar satellites are formed on the mother centriole with microtubules attached to them; the two centrioles diverge. The structures of the two centrioles differ throughout interphase; the mother centriole has appendages, the daughter does not. Replication of the centrioles occurs approximately in the middle of the S period. The structure of the procentrioles differs sharply from that of the mature centriole. Elongation of procentrioles is completed in prometaphase, and their structure undergoes a number of successive changes. In the G2 period, pericentriolar satellites disappear and some time later a fibrillar halo is formed on both mother centrioles, i.e., spindle poles begin to form. In the cells that have left the mitotic cycle (G0 period), replication of centrioles does not take place; in many cells, a cilium is formed on the mother centriole. In a small number of cells a cilium is formed in the S and G2 periods, but unlike the cilium in the G0 period it does not reach the surface of the cell. In all cases, it locates on the centriole with appendages. At the beginning of the G1 period, during the G2 period, and in nonciliated cells in the G0 period, one of the centrioles is situated perpendicular to the substrate. On the whole, it takes a mature centriole a cycle and a half to form in PE cells.     

Ultrastructure of the micronucleus of the infusorian Didinium nasutum during meiosis]

Six stages can be distinguished in the micronuclear first maturation division prophase of D. nasutum. Nucleolus-like structures of fibrillar nature, connected with micronuclear chromosomes seem to develop at the late leptotene. At zygotene-pachytene, the chromosomes condense, forming irregular loops. This coincides with formation of classically structured synaptinemal complexes in the micronuclei. At diplotene-diakinesis, chromosomal bivalents are uniformly scattered throughout the micronucleus. They aggregate into a net equatorial plate in the first division metaphase; chromosomes show prominent kinetochores with attached chromosomal microtubule bundles. The second maturation division starts immediately after the completion of the first division and is morphologically similar to agamic mitosis of the micronuclei of D. nasutum. During the 2th maturation division prophase, the compact chromosomes form a dense group and show no spreading inside the nucleus. They are interspaced by an amorphous material being possibly involved in the formation of spindle microtubules. The telophase spindle of the 2nd division likely as that of the Ist division divides into three parts, the two daughter nuclei and the separation spindle containing a material of depolymerized microtubules. Only one of the 2nd division derivatives enters the third maturation division. A short telophasic third division spindle is perpendicular to the surface of the contact between the conjugants and produces two pronuclei. The envelopes of the daughter micronuclei are formed from parts of the original nuclear envelope surrounding the entire spindle.     

Centriole modification in human aortic endothelial cells.

The structure of centrioles in endothelial cells of embryonic (22-24 weeks old) and definitive (2, 14-17, and 30-40 years) human aorta in situ and also in aortic endothelial cells dividing in organ and cell cultures (donor age 30-40 years) was studied. It was found that in the endothelial cells from definitive aorta the lengths of mother centrioles vary from 0.5 to 2 microns, whereas the length of daughter centrioles remains constant (0.4-0.5 microns). The distal part of the cylinder of long mother centrioles consists of microtubule doublets. In aorta of donors 30-40 years old in multinucleated cells and in one of 30 single-nucleated cells analyzed, C-shaped long centrioles were seen. These centrioles exhibit a doublet organization along all their length. Mitotic cells in organ and cell culture had a nonequal structure of spindle poles: at one pole, the long mother centriole was seen, while at the other a mother centriole of standard size was found. In such cells of organ culture long centrioles make contact with the remnant of primary cilia until the end of anaphase. In cell culture mitotic cells are also observed containing C-shaped centrioles. In these cells the number of mother centrioles is odd and their number is not equal to the number of daughter centrioles. The possible mechanism for transformation of endothelial centrioles and its role in the control of cell-cycle progression are discussed.