THE MITOTIC APPARATUS IN FUNGI, CERATOCYSTIS FAGACEARUM AND FUSARIUM OXYSPORUM

Vegetative nuclei of fungi Ceratocystis fagacearum and Fusarium oxysporum were studied both in the living condition with phase-contrast microscopy and after fixation and staining by HCl-Giemsa, aceto-orcein, and acid fuchsin techniques. Nucleoli, chromosomes, centrioles, spindles, and nuclear envelopes were seen in living hyphae of both fungi. The entire division process occurred within an intact nuclear envelope. Spindles were produced between separating daughter centrioles. At metaphase the chromosomes became attached to the spindle at different points. In F. oxysporum the metaphase chromosomes were clear enough to allow counts to be made, and longitudinal splitting of the chromosomes into chromatids was observed. Anaphase was characterized in both fungi by separation of chromosomes to poles established by the centrioles, and in F. oxysporum anaphase separation of chromosomes was observed in vivo. Continued elongation of the spindles further separated the daughter nuclei. Maturing daughter nuclei of both fungi were quite motile; and in C. fagacearum the centriole preceded the bulk of the nucleus during migration. The above observations on living cells were corroborated by observations on fixed and stained material.     

THE ELECTRON MICROSCOPY OF THE HUMAN HAIR FOLLICLE : PART 1. INTRODUCTION AND THE HAIR CORTEX

1. The presumptive cortical cells of hair in the undifferentiated matrix of the bulb contain mitochondria, agranular vesicles, and many small dense R.N.P. particles, but no keratin, pigment granules, or endoplasmic reticulum. 2. In the mid-bulb region intercellular adhesion is limited to small localised areas. Intercellular gaps are common and the cell surfaces are irregularly convoluted. The melanocyte processes penetrate the cell gaps. The relation between their pigment-bearing tips and the involutions of the cell membranes suggests an active phagocytosis of the tips. 3. Fibrous keratin first appears in loose parallel strands of fine filaments (ca. 60 A diameter) in the mid-bulb. The filaments, the long mitochondria, and elongated nucleus are all parallel to the long axis of the cell and the axis of the follicle. 4. At the level of the constriction of the bulb and above, a dense amorphous substance appears between the fine filaments and apparently acts as adhesive cement. The bundles of filaments now form well defined fibrils. The packing of the filaments within the fibrils is in places hexagonal and elsewhere in the form of "whorls." 5. At higher levels further filaments and interfilamentous cement are added together and the whole cytoplasmic space becomes packed with fibrils which finally condense to massive blocks of keratin. The residual cellular material occupies the interstices. 6. The addition of the interfilamentous substance is regarded as an essential factor in keratinisation. Keratin is considered to be a complex made of fine filaments (α-filaments) embedded in an amorphous substance (γ-keratin) which has the higher cystine content. 7. The wide-angle fibre-type x-ray pattern is thought to be due to scattering by the fine α-filaments and some low angle lateral spacings to the filament-plus-cement structure.     

Ultrastructure of mitosis inAmoeba proteus

Summary The fine structure ofAmoeba proteus nuclei has been studied during interphase and mitosis. The interphase nucleus is discoidal, the nuclear envelope is provided with a honeycomb layer on the inside. There are numerous nucleoli at the periphery and many chromatin filaments and nuclear helices in the central part of nucleus.In prophase the nucleus becomes spherical, the numerous chromosomes are condensed, and the number of nucleoli decreases. The mitotic apparatus forms inside the nucleus in form of an acentric spindle. In metaphase the nuclear envelope loses its pore complexes and transforms into a system of rough endoplasmic reticulum cisternae (ERC) which separates the mitotic apparatus from the surrounding cytoplasm; the nucleoli and the honeycomb layer disappear completely. In anaphase the half-spindles become conical, and the system of ERC around the mitotic spindle persists. Electron dense material (possibly microtubule organizing centers—MTOCs) appears at the spindle pole regions during this stage. The spindle includes kinetochore microtubules attached to the chromosomes, and non-kinetochore ones which pierce the anaphase plate. In telophase the spindle disappears, the chromosomes decondense, and the nuclear envelope becomes reconstructed from the ERC. At this stage, nucleoli can already be revealed with the light microscope by silver staining; they are visible in ultrathin sections as numerous electron dense bodies at the periphery of the nucleus.The mitotic chromosomes consist of 10 nm fibers and have threelayered kinetochores. Single nuclear helices still occur at early stages of mitosis in the spindle region.     

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.     

The spermatogenesis of ichthyophis glutinosus (Linn.)

Summary The primary spermatocytes which are the products of division of the spermatogonia embark on the prophase of the first division after a brief period of rest. The leptotene filaments are formed soon after and the polar orientation of the filaments results in a leptotene bouquet. Parallel conjugation of the leptotene filaments gives rise to the thicker pachytene threads, the conjugation beginning at the proximal pole. When the fusion between the apposing filaments is more or less intimate, the polarisation is lost and immediately after, splits appear along the threads at intervals, giving rise to the diplotene stage. The diplotene is followed by a pronounced and conspicuous diffuse stage where all individuality of the chromosomes is temporarily lost, the nucleus itself becoming a faintly staining reticulum, in its greatest development. Soon, the chromosomes emerge from the diffuse mass and the bivalents which now appear more or less clear, twist about each other giving rise to the strepsinema. A condensation and contraction of the chromosomes give rise to the diakinesis where 21 deeply staining tetrads of different forms are seen arranged peripherally inside the nuclear membrane. The spindle is formed between the centrioles, the nuclear membrane is lost and the tetrads take their place on the spindle. 21 tetrads can be clearly seen in the metaphase plates of the division, the four components of each tetrad being seen clearly for the first time in anaphase. A conspicuous interkinesis separates the first and second divisions, when the nucleus resumes the appearance of a faintly staining network. The second division follows quickly separating each dyad into two monads. 21 dyads are seen in the metaphase plates of this division while 21 monads can be counted in the anaphase plates. The resulting cells are the spermatids.     

ULTRASTRUCTURAL STUDIES ON THE LYMPHATIC ANCHORING FILAMENTS

The fine structure of the lymphatic capillary and the surrounding tissue areas was investigated. Instead of a continuous basal lamina (basement membrane) surrounding the capillary wall, these observations revealed the occurrence of numerous fine filaments that insert on the outer leaflet of the trilaminar unit membrane of the lymphatic endothelium. These filaments appear as individual units, or they are aggregated into bundles that are disposed parallel to the long axis of the lymphatic capillary wall and extend for long distances into the adjoining connective tissue area among the collagen fibers and connective tissue cells. The filaments measure about 100 A in width and have a hollow profile. They exhibit an irregular beaded pattern along their long axis and are densely stained with uranyl and lead. These filaments are similar to the microfibrils of the extracellular space and the filaments observed in the peripheral mantle of the elastic fibers. Infrequently, connections between these various elements are observed, suggesting that the lymphatic anchoring filaments may also contribute to the filamentous units of the extracellular space. It is suggested that these lymphatic anchoring filaments connect the small lymphatics to the surrounding tissues and represent the binding mechansim that is responsible for maintaining the firm attachment of the lymphatic capillary wall to the adjoining collagen fibers and cells of the connective tissue area.     

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.     

Cell Motility by Labile Association of Molecules : The nature of mitotic spindle fibers and their role in chromosome movement

This article summarizes our current views on the dynamic structure of the mitotic spindle and its relation to mitotic chromosome movements. The following statements are based on measurements of birefringence of spindle fibers in living cells, normally developing or experimentally modified by various physical and chemical agents, including high and low temperatures, antimitotic drugs, heavy water, and ultraviolet microbeam irradiation. Data were also obtained concomitantly with electron microscopy employing a new fixative and through measurements of isolated spindle protein. Spindle fibers in living cells are labile dynamic structures whose constituent filaments (microtubules) undergo cyclic breakdown and reformation. The dynamic state is maintained by an equilibrium between a pool of protein molecules and their linearly aggregated polymers, which constitute the microtubules or filaments. In living cells under physiological conditions, the association of the molecules into polymers is very weak (absolute value of ΔF_25°C < 1 kcal), and the equilibrium is readily shifted to dissociation by low temperature or by high hydrostatic pressure. The equilibrium is shifted toward formation of polymer by increase in temperature (with a large increase in entropy: ΔS_25°C 100 eu) or by the addition of heavy water. The spindle proteins tend to polymerize with orienting centers as their geometrical foci. The centrioles, kinetochores, and cell plate act as orienting centers successively during mitosis. Filaments are more concentrated adjacent to an orienting center and yield higher birefringence. Astral rays, continuous fibers, chromosomal fibers, and phragmoplast fibers are thus formed by successive reorganization of the same protein molecules. During late prophase and metaphase, polymerization takes place predominantly at the kinetochores; in metaphase and anaphase, depolymerization is prevalent near the spindle poles. When the concentration of spindle protein is high, fusiform bundles of polymer are precipitated out even in the absence of obvious orienting centers. The shift of equilibrium from free protein molecules to polymer increases the length and number of the spindle microtubules or filaments. Slow depolymerization of the polymers, which can be brought about by low concentrations of colchicine or by gradual cooling, allows the filaments to shorten and perform work. The dynamic equilibrium controlled by orienting centers and other factors provides a plasusible mechanism by which chromosomes and other organelles, as well as the cell surface, are deformed or moved by temporarily organized arrays of microtubules or filaments.     

SOME STRUCTURAL AND FUNCTIONAL ASPECTS OF THE MITOTIC APPARATUS IN SEA URCHIN EMBRYOS

The mitotic figures in dividing cells of sea urchin embryos, from first division to the onset of cilia formation, were studied with regard to the filament system and its relation to kinetochores, chromosomes, and poles, as well as to fixation conditions which would best preserve these structures. With regard to fixation, variations in the salt concentration and pH of the fixative indicated that an extraction effect on the chromosomes noted in earlier work was probably due to a combination of neutral pH and salt concentration equivalent to sea water. The presence of the 15 mµ filaments depended on the presence of either of two stabilizing conditions: pH 6.1 or presence of the salts of sea water, presumably the divalent cations of Ca and Mg. Kinetochores and centrioles were unaffected by the fixative variations. The 15 mµ filaments, reported earlier in the central spindle, are also found in great numbers in the asters of early cleavage divisions. However, with successive divisions and reduction in cell size, the aster disappears at about the 32 to 64 cell stage, and the 15 mµ filaments are entirely associated with the central spindle. This disappearance of the aster suggests that it may be, in fact, merely a specialization of large cells for cytokinesis.     

MULTIPLE CORE COMPLEXES IN GRASSHOPPER SPERMATOCYTES AND SPERMATIDS

At meiotic prophase, the grasshopper Chorthippus longicornis has normal synaptinemal complexes inside paired homologous chromosomes. Evidence is presented that short single cores and small multiple core complexes occur inside metaphase I chromosomes. At first anaphase, interphase, and early spermatid stage, large multiple core complexes are located in the cytoplasm. It is speculated that the multiple core complexes have some structural elements in common with the synaptinemal complexes, but that different forms of pairing behavior are exhibited by the different complexes.     

Surface and shape changes during cell division

Summary Rat kangaroo cells (PtK₂) were studied with scanning and transmission electron microscopy in order to correlate shape changes during the cell cycle with the presence or absence of microvilli and stress fibers. During interphase, bundles of actin are prominent in the cytoplasm, and microvilli are localized over and around the centrally positioned nucleus. As mitosis begins, the interphase bundles of actin and the microvilli disappear, but the mitotic cells maintain a flattened shape. At metaphase the cell is still so flat that both the chromosomes and spindle apparatus are visible through the intact cell membrane. Microvilli reappear in late anaphase above the chromosomes and poles. Before cleavage begins, microvilli increase in number until they cover the apical surface of the cell. At the same time, the cell increases in height so that the chromosomes and mitotic apparatus can no longer be detected through the cell membrane. During cleavage, microvilli continue to cover the cell in a uniform manner but become greatly diminished in number after cytokinesis is completed and the cells flatten and enter interphase. It is suggested that the microvilli organize a network of actin filaments which interact with cortical myosin to produce the cell rounding prior to cleavage.     

An electron microscope study on the cytoplasmic and nuclear components of rat primary oocytes

Summary This paper reports on the structure of rat primary oocytes, as observed with the electron microscope. Four main components are described in the cytoplasm: Golgi apparatus, centrioles, mitochondria and multivesicular bodies.The components of the Golgi apparatus are forming a single mass confined to a limited region of the cytoplasm and the centrioles were found located in a clear zone sited in the middle of this mass. Mitochondria are scattered at random in the cytoplasm. Multivesicular bodies are elements integrated by an enveloping membrane containing a varied number of tiny vesicles. They are generally found associated with a short number of small free vesicles. Only one two groups of this kind are found per oocyte. This contrast with what has been observed previously in full-grown rat oocytes, where the groups are numerous and constituted by many units.Two components were described for the oocyte nucleus: nucleoli and chromosomes. Nucleoli are constituted by a tangled thread whose elemental component is a fine fibrous material of high electron density.At the age studied on this paper, primary oocytes are undergoing meiotic prophase, chromosomes have at this time the same components observed by different authors in primary spermatocytes. These are two thick ribbon-like threads helically twisted around a thinner medial filament. Each tripartite group is attached by one end to the nuclear membrane. It was actually seen tripartite groups incompletely organized; the images recorded of such groups suggest that the medial filament is the first to appear in the nucleoplasm. The possible significance of these filaments in respect to the meiotic phase called chromosome pairing is discussed.     

Unusual pattern of mitosis in the free-living flagellateDimastigella mimosa (Kinetoplastida)

Summary The three-dimensional ultrastructural organization of the mitotic apparatus ofDimastigella mimosa was studied by computer-aided, serial-section reconstruction. The nuclear envelope remains intact during nuclear division. During mitosis, chromosomes do not condense, whereas intranuclear microtubules are found in close association with six pairs of kinetochores. No discrete microtubule-organizing centers, except kinetochore pairs, could be found within the nucleus. The intranuclear microtubules form six separate bundles oriented at different angles to each other. Each bundle contains up to 8 tightly packed microtubules which push the daughter kinetochores apart. At late anaphase only, midzones of these bundles align along an extended interzonal spindle within the narrow isthmus between segregating progeny nuclei. The nuclear division inD. mimosa can be described as closed intranuclear mitosis with acentric and separate microtubular bundles and weakly condensed chromosomes.Abbreviation MTOC microtubule-organizing center     

Structural similarity between actin bundles from characean algal cells and sea urchin oocytes

The structure of actin bundles from internodal cells of Chara australis, an algal plant, was studied by electron microscopy of negatively stained specimens and optical diffraction. Gently prepared bundles revealed paracrystalline structures resembling the Mg²⁺-induced paracrystals of rabbit skeletal muscle actin (Hanson, 1968). In addition, the algal actin bundles sometimes had transverse striations at intervals of about 130 Å, as has been observed in actin bundles from sea urchin eggs (DeRosier et al., 1977; Spudich & Amos, 1979) and sea urchin coelomocytes (De Rosier & Edds, 1980; Otto & Bryan, 1981). This finding suggests that a common mechanism might be working in a variety of cells to organize actin filaments into functional bundles.     

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.     

The ultrastructural organization of the basement membrane of Bowman's capsule in the rat renal corpuscle

Summary The basement membrane of Bowman's capsule (BCBM) of the rat was studied by means of a modified tissue-preservation technique for transmission electron microscopy, which avoids the usual thorough fixation in OsO₄ and applies tannic acid and uranyl acetate for staining (Sakai et al. 1986). At most sites the BCBM is multilayered, consisting of one to seven dense layers separated by electron-lucent layers. The latter, which can be termed laminae rarae, contain fine filaments which connect the dense layers to each other and the innermost dense layer to the basal cell membrane of the parietal epithelium. The laminae densae are basically composed of fine filaments arranged in an anastomosing pattern. Individual filaments ranging from 5 to 15 nm in diameter, combine to form filament bundles up to 100 nm in thickness and 1 to 2 m in length. Within a dense layer, filaments and filamentous bundles are oriented mainly in the same direction. Often the inner dense layers do not form a continuous sheet, and the filamentous bundles are arranged in anastomosing or spiral patterns to form a ribbon-like structure that we call a microligament. These microligaments are often embedded in basal furrows of the parietal epithelium and are best developed around the vascular pole. Intracellular actin bundles of the parietal cells are regularly associated with these extracellular ribbon-like structures of the basement membrane. In conclusion, the BCBM has an unusual structure: the laminae densae are characterized by their filamentous nature and are arranged in different patterns, i.e. as a multilayered mat and as microligaments.Fellow of the Deutscher Akademischer Austauschdienst     

THE STRUCTURE OF THE CENTRAL REGION IN THE SYNAPTONEMAL COMPLEXES OF HAMSTER AND CRICKET SPERMATOCYTES

The fine structure of bivalents from golden hamster and house cricket spermatocytes has been studied with a whole mount surface-spreading method combined with negative staining. The elements of the synaptonemal complex show detail of structure which is absent in other preparative procedures. The transverse filaments found in the central region of the synaptonemal complex from both species are straight and have a similar width, 1 6–1 8 nm These filaments occur mainly in bundles The central element differs in architecture in the two species In hamster bivalents it is formed of longitudinal stretches of filaments 1.6–1 8 nm wide and a small amount of an amorphous material similar to that of the lateral elements In the cricket, the central element contains transverse fibrils which are continuous with the transverse filaments of the central region, and an amorphous material lying mainly along the sides of the central element All of the components of the central region of the synaptonemal complex are resistant to pancreatic DNase. The overlapping ends of the transverse filaments, together with additional protein material, make up the central element The widespread occurrence and close morphological and histochemical interspecies similarities of the transverse filaments indicate that they serve an essential role, probably one concerned with holding synapsed bivalents together via the lateral elements. Restrictions placed by the observations reported here on current models of the synaptonemal complex are discussed.     

Centrioles and associated striated filamentous bundles in rabbit pulmonary lymphatic endothelial cells

Summary An electron microscopic study of the pulmonary lymphatic collecting channels and their valves in the rabbit revealed that the endothelial cells generally contain two centrioles which are almost invariably associated with one to several striated bundles of filaments. The structure of the centrioles corresponds well with that in other cell types. The filaments however were present only in endothelial cells and not in the perilymphatic connective tissue cells. The bundles consist of 2 to 6 filaments of about 40 Å diamenter and show a cross banding with a periodicity of 600 to 900 Å. They are attached at both ends or in the middle of the centriole. Their function is unknown, but they might be vestigial rootlets of rudimentary cilia of lymphatic endothelial cells.This study has been supported by a grant from The Council for Tobacco Research—U.S.A.. We thank R. Janssens for technical, G. Pison and St. Ons for photographic and R. Kell for secretarial assistance.     

The electron microscopy of the human hair follicle. I. Introduction and the hair cortex

1. The presumptive cortical cells of hair in the undifferentiated matrix of the bulb contain mitochondria, agranular vesicles, and many small dense R.N.P. particles, but no keratin, pigment granules, or endoplasmic reticulum. 2. In the mid-bulb region intercellular adhesion is limited to small localised areas. Intercellular gaps are common and the cell surfaces are irregularly convoluted. The melanocyte processes penetrate the cell gaps. The relation between their pigment-bearing tips and the involutions of the cell membranes suggests an active phagocytosis of the tips. 3. Fibrous keratin first appears in loose parallel strands of fine filaments (ca. 60 A diameter) in the mid-bulb. The filaments, the long mitochondria, and elongated nucleus are all parallel to the long axis of the cell and the axis of the follicle. 4. At the level of the constriction of the bulb and above, a dense amorphous substance appears between the fine filaments and apparently acts as adhesive cement. The bundles of filaments now form well defined fibrils. The packing of the filaments within the fibrils is in places hexagonal and elsewhere in the form of "whorls." 5. At higher levels further filaments and interfilamentous cement are added together and the whole cytoplasmic space becomes packed with fibrils which finally condense to massive blocks of keratin. The residual cellular material occupies the interstices. 6. The addition of the interfilamentous substance is regarded as an essential factor in keratinisation. Keratin is considered to be a complex made of fine filaments (alpha-filaments) embedded in an amorphous substance (gamma-keratin) which has the higher cystine content. 7. The wide-angle fibre-type x-ray pattern is thought to be due to scattering by the fine alpha-filaments and some low angle lateral spacings to the filament-plus-cement structure.     

Chromosome elimination in Heteropeza pygmaea

The ultrastructure of early cleavage divisions of the paedogenetic gall midge Heteropeza pygmaea (syn. Oligarces paradoxus) was analysed at different division stages determined by previous in vivo observation. The spindles are enclosed by a continuous layer of vesicles. Centrioles are absent. During anaphase the disassembling microtubules connected with normally segregating chromosomes become increasingly coated with electron-opaque material. The microtubules of eliminated chromosomes blocked in the interzone persist throughout anaphase and remain uncoated. During anaphase the spindles are considerably stretched and stem bodies are formed. The microtubules of the stem bodies are also associated with electronopaque material. These phenomena seem to be consistent with the explanation of chromosome segregation by cyclic assembly and disassembly of spindle microtubules.