The ultrastructure of nuclear division in a suctorian,Tokophrya infusionum

Summary Ultrastructural changes in the micro- and macronucleus throughout division were followed in synchronized cultures of the suctorian, Tokophrya infusionum. After an initial swelling, the micronucleus elongates enormously; microtubules within the micronucleus proliferate and lengthen as the micronucleus elongates. Changes in the macronucleus become visible only after micronuclear division is well underway. The chromatin bodies fuse into long chromatin strands, and the large bundles of microtubules present in the resting macronucleus break up into small groups which parallel the chromatin strands. Colchicine, which prevents reproduction in Tokophrya, seems to block division at a very early stage. The macronucleus appears the same as the resting nucleus of untreated organisms, with numerous microtubules and distinct chromatin bodies. The chromatin in the micronucleus aggregates into large clumps, however, and proliferation of microtubules does not occur.Supported by a Graduate Fellowship at The Rockefeller University.Supported by Grant A1-01407-12 USPHS and Grant A1-08989-01 USPHS.     

A New Type of Manchette Structure in Spermatids of Culex tigripes(Culicidae)

Abstract In young spermatids of Culex tigripes, microtubules organize a manchette which surrounds the nucleus. When the nucleus elongates, 1–5 expansions appear on the wall of the microtubules. They grow and branch out while the nucleus elongates and chromatin condenses. Expansions are straight or curved in shape. They have the same thickness as the microtubule walls, but they rarely constitute links between microtubules. The manchette disappears naturally at the end of spermiogenesis. The action of colchicine on spermatids leads to the complete disappearance of the microtubules and expansions, and inhibits the lengthening of the nucleus.     

Nuclear morphogenesis during spermiogenesis in the nudibranch molluscHypselodoris tricolor (Gastropoda,opisthobranchia)

An electron microscope study was carried out on Hypselodoris tricolor spermatids to describe the development of the nuclear morphogenesis and investigate the possible cause(s) of the change in the shape of the spermatid nucleus during spermiogenesis. Three different stages may be distinguished in the course of the nuclear morphogenesis on the basis of the morphology and inner organization of the nucleus. Stage 1 spermatid nuclei are spherical or ovoid in shape and the nucleoplasm finely granular in appearance. Stage 2 nuclei exhibit a disc- or cup-shaped morphology, and the chromatin forms short, thin filaments. During stage 3, a progressive nuclear elongation takes place, accompanied by chromatin rearrangement, first into fibers and then into lamellae, both formations helically oriented. A row of microtubules attached to the nuclear envelope completely surrounds the nucleus. Interestingly, the microtubules always lie parallel to the chromatin fibers adjacent to them. Late stage 3 spermatids show the highest degree of chromatin condensation and lack the manchette at the end of spermiogenesis. Our findings indicate the existence of a clear influence exerted on the chromatin by the manchette microtubules, which appear to be involved in determining the specific pattern of chromatin condensation in Hypselodoris tricolor.     

Chromatin condensation involving lamellar strands in spermiogenesis of Goniobasis proxima

Young spermatids of the prosobranch mollusc Goniobasis have spherical nuclei with diffuse centers and condensation of the chromatin only at their peripheries. At later stages, this condensation becomes uniform for the entire nucleus, and has a lamellar appearance in sectioned material. In specimens prepared using freeze-etch techniques, these lamellae are resolvable into chromatin strands, each of which has a helical substructure, with a period of ca. 100 Å and a pitch angle of 35°. The strands are ca. 130–140 Å in diameter (comparable to measurements made on micrographs of sectioned material). Most of the strands are oriented in the long axis of the elongating nucleus, but a few are oblique, suggesting that they might serve some sort of binding function. In the mature spermatozoon the chromatin is very compact and dense, and all evidence of the lamellar or stranded appearance is absent, in both sectioned and freeze-etch preparations.     

Spermatogenesis and sperm ultrastructure in three species of polydora and in streblospio benedicti (Polychaeta: Spionidae)

Summary Spermatogenesis was studied at the ultrastructural level in Polydora ligni, P. websteri, P. socialis and Streblospio benedicti. Spermatogonia, spermatocytes, spermatids and mature sperm are described. In all four species, meiosis occurs in the coelom following release of spermatogonia from the gonad. In Polydora spp., chromatin condensation is lamellar with no microtubules present during nuclear elongation. In S. benedicti, chromatin condensation is fibrous with a manchette of microtubules present around the nucleus. In all four species, the acrosome forms from a Golgi-derived vesicle situated at the base of spermatids. The acrosome in Polydora spp. is conical with a distinctive substructure whereas the S. benedicti acrosome is long and spiral. The implantation fossa is short in all species except P. ligni. All four species have elongated sperm heads. The middlepiece as well as the nucleus is elongated in Polydora spp. whereas S. benedicti has a long nucleus but a short middlepiece. Platelet-shaped electron-dense bodies are present throughout the nuclear region and middlepiece of Polydora spp. and the nuclear region of S. benedicti. These membrane-bounded bodies may be energy storage organelles. The use of ultrastructural data in analysis of sibling species complexes is discussed.Contribution Number 203 from Harbor Branch Foundation, Inc.     

Development of the sperm head in the caddis fly Potamophylax rotundipennis (Insecta,Trichoptera)

The restructuring of the sperm head has been examined in a caddis fly, Potamophylax rotundipennis (Limnephilidae), using light and electron microscopy. The roughly spherical nuclei of young spermatids are transformed into needle-shaped elements in advanced spermatids. During this process, the nuclei transiently become sickle-shaped. Prominent structural changes occur within the nucleus during spermiogenesis. The chromatin of spherical and slightly elongated nuclei has an amorphous appearance, then coarse granules become apparent, chromatin threads are visible in fully elongated nuclei and finally lamellar elements appear. During the changes in chromatin texture, a dense layer, the chromatin rim, develops transiently. This feature of the chromatin surface is interpreted as the structural expression of exchanges between nucleus and cytoplasm. A microtubular manchette is formed at the cytoplasmic face of the nuclear envelope. Whereas the manchette covers the full perimeter of the nucleus in early stages of elongation, gaps in the palisade of microtubules appear before the nuclear diameter decreases and needle-shaped nuclei develop. It is possible that the intermittent deployment of manchette microtubules is involved in reducing the nuclear diameter towards the end of nuclear elongation. The delayed detachment of the chromatin from the posterior pole of the nucleus, observed at the onset of nuclear clongation, points to local modifications of the nuclear envelope responsible for the connection of the centriole adjunct and the flagellum with the posterior pole of the nucleus.     

TRANSFORMATION OF THE NUCLEUS IN MARCHANTIA SPERMATIDS: MORPHOGENESIS

It is proposed that elongation of the nucleus in spermatids of Marchantia results from interaction between its membranous envelope and microtubules of the spermatid's cytoskeleton. The nucleus may be drawn out in two directions along microtubules until forces attracting the nucleus to them are balanced by forces resisting envelope distortion. Condensation of nuclear chromatin into fibrils of uniform diameter and probable shaping of the nucleus by blebbing of its envelope occur together before elongation is complete. The nucleus becomes crescent shaped and it is prolonged distally into a chromatin-free diverticulum. In accord with their distribution along the axis of the nucleus, chromatin fibrils are compacted together forming a cone-like rod of chromatin which narrows anteriorly and extends distally to the tip of the preexisting diverticulum. Elongation and shaping of the nucleus influence the distribution of its chromatin and thus its ultimate morphology. Coiling of the nucleus is related to a reduction of spermatid cytoplasm during maturation.     

Ultrastructure of the testes and spermatogenesis in the mite Anystis baccarum

The epithelial lining of testes in Anystis baccarum is glandular and produces a secretory product necessary to form spermatophores. The main stages of spermatogenesis occur in the lumen of the testis in groups of synchronously developing sister cells. Spermatogonia and late spermatids are encircled by glandular cells. Reorganization of developing spermatids is typical of the trombidiform mites and includes formation of the acrosomal complex, cytoplasm elimination, disappearance of the nuclear envelope and formation of invaginations of plasmalemma. The chromatin material condensation is not followed by the entire chromatin body formation. In mature spermatoza, dense chromatin strands (80b nm in diameter) lie along the cell in the peripheral layer of the cytoplasm. Mature spermatozoa lack axonema or any protrusions. A layer of microtubules, visible underneath the outer membrane, may serve for sperm movement in the female genital duct. The acrosomal complex consists of acromal granule, acrosomal filament and subacrosomal substance. This, as well as two aggregates of typical mitochondria, looks plesiomorphic.     

Structural organization and distribution of the symbiotic bacteria <Emphasis Type="Italic">Wolbachia</Emphasis> during spermatogenesis of <Emphasis Type="Italic">Drosophila simulans</Emphasis>

Electron microscopy and morphometric analysis have shown that the symbiotic bacteria Wolbachia occur the testis cells D. simulans during spermatogenesis and are absent in mature spermatids. Bacteria did not affect the structural organization of testis cells, which have a typical morphology during morphogenesis. Bacteria were distributed along the meiotic spindle microtubules near the mitochondria. They increased in number in spermatids at the stage of elongation. Endosymbionts aggregated at the spermatid distal end and contained many vacuoles but were absent at the spermatid proximal end near the nuclei. It was shown for the first time that the diameter of spermatids in a strongly infected line was two of three times that in a noninfected line. We hypothesize that the increase in the number of endosymbionts during spermatid elongation can affect the chromatin condensation in the spermatozoon.Translated from Ontogenez, Vol. 36, No. 1, 2005, pp. 41–50.Original Russian Text Copyright © 2005 by Dudkina, Kiseleva.     

Spermiogenesis in Odontophrynus cultripes (Amphibia,Anura, Leptodactylidae): Ultrastructural and cytochemical studies of proteins using E-PTA

Spermiogenesis in the South American leptodactylid frog Odontophrynus cultripes was analyzed ultrastructurally. The spermatids undergo morphological modification while still enclosed in microtubule-rich processes of Sertoli cells. Electron-dense plates resembling junctional structures appear in regions at which the spermatids lie in close contact with the surface of Sertoli cell processes. Spermatid differentiation can be divided into five distinct stages based mainly on chromatin condensation. In the late stages, the densely compacted chromatin loses reactivity to ethanolic phosphotungstic acid (E-PTA). Helical arrangements of microtubules appear in the cytoplasm that surrounds the spermatid nucleus after the second stage. The acrosomal vesicle differentiates into a cone-shaped acrosome that caps the anterior region of the nucleus. The connecting piece, located in the flagellum implantation zone, has transverse striations, and is continuous with the axial rod. The tail is formed by a 9 + 2 axoneme, an undulating membrane, and an axial rod that is rich in basic proteins as demonstrated by E-PTA staining.     

Fine structure of spermiogenesis with special reference to the spermatid morulae of the freshwater mussel Prisodon alatus (Bivalvia,Unionoidea)

Within the testicular cysts of the mussel Prisodon alatus are numerous somatic host cells described as Sertoli cells (SC), each containing a variable number of young spermatid morulae. Among them, several free spermatid morulae, spermatids, and spermatozoa were observed. Each free spermatid morula is surrounded by an external membrane. The early spermatids enclosed within the morulae have dense and homogeneous chromatin, and the cytoplasm occupies little space around the nucleus. Later, during spermiogenesis, the SC show lysis and disrupt to liberate the spermatid morulae. The membrane of the free morula is then disrupted, releasing the young spermatids. The SC disappear just after the appearance in the testis of a large number of free young spermatids. The nucleus of each free spermatid becomes gradually smaller and denser by the appearance of a granular pattern of condensed chromatin. During the maturation phase of the spermatids, the cytoplasm becomes more voluminous, and mitochondria and centrioles are more evident. Then, flagellogenesis occurs, and the nucleus gradually condenses into thicker strands. In the mature sperm, the apical zone has a disc-shaped acrosomal vesicle and the midpiece contains five mitochondria and two centrioles located at the same level. The flagellum has the common 9+2 microtubular pattern. The results are discussed with particular reference to Sertoli cells and clusters of spermatid morulae with those of species of closely related taxa in the bivalves. J. Morphol. 238:63–70, 1998. © 1998 Wiley-Liss, Inc.     

Acineta tuberosa

Zusammenfassung Die Veränderungen im Feinbau des Makronucleus während der ungeschlechtlichen Fortpflanzung von Acineta tuberosa (Suctoria) werden beschrieben. Bei Zeitrafferaufnahmen von Tokophrya lemnarum ist kurz vor der Teilung des Makronucleus eine um mehrere Zentren kreisende Bewegung chromosomaler Fäden beobachtet worden (Heckmann, 1966). Die entsprechenden Stadien bei Acineta wurden nun im elektronenmikroskopischen Bild identifiziert. Von besonderem Interesse ist die Verteilung der Mikrotubuli. Während im Makronucleus älterer Wachstumsstadien und adulter Tiere zahlreiche Bündel von 8 bis 20 Mikrotubuli vorhanden sind, wurden kurz vor und während der Teilung des Makronucleus nur wenige, einzeln liegende Mikrotubuli beobachtet.Wenn auch diese wenigen, einzelnen Mikrotubuli kinetische Strukturen sein mögen, die den kontinuierlichen Fasern der Mitosespindel entsprechen könnten, so zeigen die zahlreichen Tubulibündel vegetativer Zellen keine Beziehung zur Bewegung der chromosomalen Fäden oder zur Streckung des Makronucleus. Es muß angenommen werden, daß die Tubulibündel, die möglicherweise Ausdruck einer besonderen Stoffwechselleistung des somatischen Makronucleus sind, vor der Kernteilung teilweise wieder abgebaut werden.

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Acineta tuberosaII. The distribution of microtubules in the macronucleus during asexual reproduction

Summary Ultrastructural changes in the macronucleus during the complete cycle of asexual reproduction of Acineta tuberosa (Suctoria) are described. Using time-lapse photography Heckmann (1966) demonstrated that in Tokophrya lemnarum just prior to macronuclear division thread-like chromatin strands rotate around several centres. Corresponding stages have now been identified in electron micrographs of Acineta.Of considerable interest is the distribution of microtubules during cell cycle. Numerous straight bundles of 8 to 20 microtubules are present in the macronucleus of more advanced metamorphosing stages and adult suctorian animals. On the other hand only a very few separate microtubules were observed in predivisional and divisional stages. Although these few microtubules may represent kinetic elements, similar to continuous fibers of the mitotic spindle the numerous bundles of microtubules of non-reproducing cells show no relation to the movement of chromatin strands or to the macronuclear elongation prior to division. It is assumed that these masses of microtubules might be the expression of a special physiological activity of the somatic macronucleus, and that at least part of them become depolymerized before macronuclear division starts.

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Über einen Teil der Ergebnisse wurde auf der 150. Konferenz der British Society for Experimental Biology, Bristol, 26. 3.–29. 3. 68, berichtet (Bardele, 1968 b).

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Mit Unterstützung durch die Deutsche Forschungsgemeinschaft.     

Spermiogenesis and sperm structure in the crabUca tangeri (Crustacea,Brachyura), with special reference to the acrosome differentiation

Summary Early spermatids of the crabUca tangeri consists of the nucleus of granular chromatin and the cytoplasm, which contains a proacrosomal vesicle in close association with membrane lamellae. In the mid spermatids an invagination of the acrosomal vesicle membrane gives rise to the formation of the perforatorium, a spindle-shaped tubule which encloses tubular membranous structures. The pair of centrioles located at the base of the acrosome is not directly involved in perforatorial differentiation. The acrosomal vesicle shows a heterogeneous content composed of the operculum, the thickened ring, and three layers of different materials concentrically arranged around the perforatorium. During the late spermatid stage the nuclear profile differentiates numerous slender arms and the chromatin arranges into fibers. Membranous tubules from the cytoplasm become incorporated into the tubular structures of the perforatorium. The mature spermatozoon has the typical structure of the branchyuran sperm, with a complex acrosome, cupped by the nucleus, and a thin cytoplasmic band intervening between the former main elements. The centrioles are degenerate. The nuclear arms are unusually numerous (more than 20) and lack microtubules or microtubular derivatives.     

The occurrence of a multilayered structure in the sperm of a pteridophyte

Summary A multilayered structure, previously recorded only in bryophytes, is reported in spermatids of three species of Equisetum. It is interpreted as comprising four layers, recalling the Vierergruppe of Marchantia spermatids. Unlike the multilayered structure of bryophyte spermatids, a rather compact organelle, that of Equisetum forms a thin strip extending almost the whole diameter of the cell. As in bryophytes the upper layer of the Equisetum multilayered structure is composed of parallel microtubules, extending far beyond the underlying layers. The microtubular band is considered equivalent to the similar structure seen in a variety of plant spermatozoids, but in Equisetum it is much longer and composed of many more microtubules than reported from any other plant spermatozoid. The morphology of the multilayered structure is related to the large size and short, broad form of Equisetum spermatozoids.     

Ultrastructure of spermatogenesis and mature spermatozoa in the flatworm Prosthiostomum siphunculus (Polycladida,Cotylea)

This is the first study investigating spermatogenesis and spermatozoan ultrastructure in the polyclad flatworm Prosthiostomum siphunculus. The testes are numerous and scattered as follicles ventrally between the digestive ramifications. Each follicle contains the different stages of sperm differentiation. Spermatocytes and spermatids derive from a spermatogonium and the spermatids remain connected by intercellular bridges. Chromatoid bodies are present in the cytoplasm of spermatogonia up to spermatids. During early spermiogenesis, a differentiation zone appears in the distal part of spermatids. A ring of microtubules extends along the entire sperm shaft just beneath the cell membrane. An intercentriolar body is present and gives rise to two axonemes, each with a 9 + “1” micro‐tubular pattern. Development of the spermatid leads to cell elongation and formation of a filiform, mature spermatozoon with two free flagella and with cortical microtubules along the sperm shaft. The flagella exit the sperm shaft at different levels, a finding common for acotyleans, but so far unique for cotylean polyclads. The Golgi complex produces numerous electron‐dense bodies of two types and of different sizes. These bodies are located around a perinuclear row of mitochondria. The elongated nucleus extends almost along the entire sperm body. The nucleus is wide in the proximal part and becomes narrow going towards the distal end. Thread‐like chromatin mixed with electron‐dense intranuclear spindle‐shaped bodies are present throughout nucleus. The general sperm ultrastructure, the presence of intranuclear bodies and a second type of cytoplasmic electron‐dense bodies may provide characters useful for phylogenetic analysis.     

Spermiogenesis in the teleost Gambusia affinis with particular reference to the role played by microtubules

Summary During nuclear elongation in spermatids of Gambusia affinis, a deep fossa is formed at the base of the nucleus in which the centriolar complex and proximal portion of the flagellum reside. To stabilize the positional relationship between the nucleus and centriolar complex, while nuclear morphogenesis is taking place, a series of microtubules develop which emanate from the centriolar complex and extend to the nuclear envelope lining the fossa. Buttressing microtubules also develop within the nuclear fossa which both originate and insert along the nuclear envelope. These appear to stabilize nuclear shape prior to the time when chromatin condensation has proceeded to the stage where it could lend structural stability to nuclear form. Microtubules develop only after specific nuclear morphogenic events have taken place. It is therefore concluded that the spermatid nucleus is capable of self-assembly involving microtubules in a supportive role in addition to stabilizing the nuclear-flagellar relationship in G. affinis.The pattern of nuclear fossa-associated microtubules in G. affinis is significantly different from that observed in other poeciliid teleosts indicating a degree of species specificity with regard to both the timing of appearance and total number of microtubules.     

Contents Volume 14, 1988

Summary

Within the unpaired testis, spermatogonia, spermatocytes, spermatids and spermatozoa were found. In early spermatids, mitochondria take perinuclear positions and centrioles a diplosomal arrangement. Rootlet-like striated differentiations occur in slightly more advanced stages. Then a conical cytoplasmic projection develops, supported by a single row of closely spaced microtubules. At this stage of maturation, giant Golgi stacks occur within the cytoplasm of the cytophore which is rich in different elongate structures and oval dense bodies. With progressive differentiation, the nucleus elongates and its chromatin condenses into twisted lamellae. Two centrioles, which change their diplosomal configuration and come to lie in line to each other, and rootlet-like structures remain near the tip of the median cytoplasmic outgrowth. Mitochondria start to fuse into a single long cylindrical mitochondrial rod extending beside the lengthening nucleus. Bone-shaped rods, smaller dense sticks and dense bodies migrate into the outgrowth. Spermatozoa are totally ensheathed by cortical microtubules. These tubules show different arrangements along the cell body. The thread-like nucleus extends along the cell, the first quarter excepted, whereas the single mitochondrion extends over two thirds of the cell. Two strings with linearly arranged oval dense bodies run in the median to post-median cell segment; four rows of bone-shaped rods and two rows of smaller electron-dense sticks extend from the frontal end up to the beginning of the last third of the cell. All the different longitudinal cords run in the gaps between 4 sets of microtubules. Ciliary axonemes or lateral bristles were not observed. The present findings substantiate the hypotheses, that spermatozoa in the Macrostomida are aciliate and that Myozona takes an isolated position within the Macrostomidae. The occurrence of two centrioles, which come to lie in line to each other and which stay in the tip of the cytoplasmic outgrowth in spermatids, may indicate that biciliate spermatozoa are characteristic for the Rhabditophora (= Macrostomorpha+Trepaxonemata) and not an evolutionary novelty of the Trepaxonemata.     

The microtubular system and posttranslationally modified tubulin during spermatogenesis in a parasitic nematode with amoeboid and aflagellate spermatozoa

Using transmission electron microscopy and immunologic approaches with various antibodies against general tubulin and posttranslationally modified tubulin, we investigated microtubule organization during spermatogenesis in Heligmosomoides polygyrus, a species in which a conspicuous but transient microtubular system exists in several forms: a cytoplasmic network in the spermatocyte, the meiotic spindle, a perinuclear network and a longitudinal bundle of microtubules in the spermatid. This pattern differs from most nematodes including Caenorhabditis elegans, in which spermatids have not microtubules. In the spermatozoon of H. polygyrus, immunocytochemistry does not detect tubulin, but electron microscopy reveals two centrioles with a unique structure of 10 singlets. In male germ cells, microtubules are probably involved in cell shaping and positioning of organelles but not in cell motility. In all transient tubulin structures described in spermatocytes and spermatids of H. polygyrus, detyrosination, tyrosination, and polyglutamylation were detected, but acetylation and polyglycylation were not. The presence/absence of these posttranslational modifications is apparently not stage dependent. This is the first study of posttranslationally modified tubulin in nematode spermatogenesis. Mol. Reprod. Dev. 49:150–167, 1998. © 1998 Wiley-Liss, Inc.     

The ultrastructure of spermatid development during spermiogenesis within the rosebelly lizard,Sceloporus variabilis (Reptilia,Squamata, Phrynosomatidae)

Several recent studies have mapped out the characters of spermiogenesis within several species of squamates. Many of these data have shown both conserved and possibly apomorphic morphological traits that could be important in future phylogenetic analysis within Reptilia. There, however, has not been a recent study that compares spermiogenesis and its similarities or differences between two species of reptile that reside in the same genus. Thus, the present analysis details the changes to spermiogenesis in Sceloporus variabilis and then compares spermatid morphologies to that of Sceloporus bicanthalis. Many of the morphological changes that the spermatids undergo in these two species are similar or conserved, which is similar to what has been reported in other squamates. There are six main character differences that can be observed during the development of the spermatids between these two sceloporid lizards. They include the presence (S. variabilis) or absence (S. bicanthalis) of a mitochondrial/endoplasmic reticulum complex near the Golgi apparatus during acrosome development, a shallow (S. variabilis) or deep (S. bicanthalis) nuclear indentation that accommodates the acrosomal vesicle, filamentous (S. variabilis) or granular (S. bicanthalis) chromatin condensation, no spiraling (S. variabilis) or spiraling (S. bicanthalis) of chromatin during condensation, absence (S. variabilis) or presence (S. bicanthalis) of the longitudinal manchette microtubules, and the lack of (S. variabilis) or presence (S. bicanthalis) of nuclear lacunae. This is the first study that compares spermiogenic ultrastructural characters between species within the same genus. The significance of the six character differences between two distantly related species within Sceloporus is still unknown, but these data do suggest that spermiogenesis might be a good model to study the hypothesis that spermatid ontogeny is species specific. J. Morphol. 275:258–268, 2014. © 2013 Wiley Periodicals, Inc.     

A cytological study of micronuclear elongation during conjugation in Tetrahymena

Micronuclear elongation is the first major event in a series of nuclear changes occurring during the sexual stage of the life cycle of Tetrahymena. Beginning at about one hour after cells of complementary mating types have conjugated, the micronucleus leaves its recess in the macronucleus and swells slightly. This is accompanied by a reorganization of its chromatin from a reticular to a solid body. In the next stage the micronucleus assumes an egg shape, a development concomitant with the appearance of microtubules. While the chromatin spins out from the dense body, and microtubules increase in number, the nucleus assumes a spindle shape. During the elongation, which increases the length of the nucleus some fifty fold, microtubules are prominent in clusters just internal to the nuclear membrane, and parallel to the longitudinal axis of the nucleus. When elongation is completed the nucleus is curved around the macronucleus. Internally, partially condensed strands of chromatin are located off-center, towards the macronuclear side, and the density of the microtubules is diminished. At all the stages, DNA is located throughout the nucleus; neither discrete chromosomes nor synaptonemal complexes are seen. Occasionally cytoplasmic membrane systems are seen fused to the nuclear envelope which retains the typical appearance of a double membrane with pores.