The condensin complex is essential for amitotic segregation of bulk chromosomes, but not nucleoli, in the ciliate Tetrahymena thermophila

The macronucleus of the binucleate ciliate Tetrahymena thermophila contains fragmented and amplified chromosomes that do not have centromeres, eliminating the possibility of mitotic nuclear division. Instead, the macronucleus divides by amitosis with random segregation of these chromosomes without detectable chromatin condensation. This amitotic division provides a special opportunity for studying the roles of mitotic proteins in segregating acentric chromatin. The Smc4 protein is a core component of the condensin complex that plays a role in chromatin condensation and has also been associated with nucleolar segregation, DNA repair, and maintenance of the chromatin scaffold. Mutants of Tetrahymena SMC4 have remarkable characteristics during amitosis. They do not form microtubules inside the macronucleus as normal cells do, and there is little or no bulk DNA segregation during cell division. Nevertheless, segregation of nucleoli to daughter cells still occurs, indicating the independence of this process and bulk DNA segregation in ciliate amitosis.     

Ultrastructure of the nuclear apparatus of the infusorian Loxodes magnus. I. The macronuclei, macronuclear anlagen and the interphasic micronuclei]

The nuclear apparatus of Loxodes magnus Stokes (Holotricha) consists of numerous macronuclei which belong to the diploid type and never divide, and of numerous micronuclei. No nuclear groups exist; individual nuclei often lie in cytoplasmic islets surrounded by large lacunae of the smooth endoplasmic reticulum. Interphasic micronuclei have two-membraned envelopes with numerous pores, usually lined at the cytoplasmic side with a layer of vacuoles, channels, or flattened vesicles of the smooth endoplasmic reticulum. The chromatin of the micronuclei consists of anastomosing threads, 0.1--0.2 mum wide, between which several nucleolus-like bodies of microfibrillar structure occur. Adult macronuclei have a similar nuclear envelope and a similar system of vacuoles, channels, and flattened agranular cisternae outside it. The macronucleus contains a single large composite nucleolus with 3 or 4 fibrillar cores inside the common granular cortex. The fibrillar cores are pierced by channels containing nucleolar organizers in the form of strands of condensed chromatin. The peripheral zone of the macronucleus is filled with decondensed chromatin fibrils and contains a number of small chromocenters and several aggregates of RNP granules. No protein inclusions (spheres) have been observed in Loxodes macronuclei. The macronuclear anlagen, developing in the cycle of every cell division, show progressive decondensation of the chromosomes and formation of several nucleoli, each with its own organizer. Later on, the nucleoli fuse into a single nucleolus. The small chromocentres are the last to form.     

Amitotic division of the macronucleus in Tetrahymena thermophila: DNA distribution by genomic unit

The macronucleus of the ciliate Tetrahymena cell contains euchromatin and numerous heterochromatins called chromatin bodies. During cell division, a chromatin aggregate larger than chromatin body appears in the macronucleus. We observed chromatin aggregates in the dividing macronucleus in a living T. thermophila cell, and found that these were globular in morphology and homogeneous in size. To observe globular chromatin clearly, optimal conditions for making it compact were studied. Addition of Mg ion, benomyl and oryzalin, microtubule inhibitors, to cell suspension was effective. Globular chromatin appeared when the micronuclear anaphase began at the cell cortex, and disappeared long after cell separation. Using living cells with a small macronucleus at early log phase, we counted the number of globular chromatin per nucleus and measured the DNA content of globular chromatin in the macronucleus which was stained with Hoechst 33342 by using ImageJ. The number of globular chromatin per nucleus was reduced by half after division, indicating the globular chromatin is a distribution unit of DNA. A globular chromatin contained similar DNA content as that of the macronuclear genome. We developed methods for inducing and isolating a cell with an extremely small macronucleus with a DNA amount of one globular chromatin. These cells grew, divided, and give clones, suggesting that the macronuclear genome is not dispersed within the macronucleus and the globular chromatin may be a macronuclear genome. We named this globular chromatin "macronuclear genome unit" (MGU).     

Fine structure and cytochemistry of the nuclei of the primitive ciliateTracheloraphis crassus (Karyorelictida)

Summary The nuclei ofTracheloraphis crassus were studied using light and electron microscopy combined with Bernhard's RNP staining and pronase digestion. The nuclear apparatus of this species consists of a longitudinal row of 11–43 macronuclei and 4–16 micronuclei. Like in all karyorelictids, the macronuclei are unable to divide and become segregated during cytokinesis; their number is supplemented in every cell cycle by differentiation of several new macronuclei from micronuclei.Each adult macronucleus contains a single compact endonuclear aggregate of several large chromocenters, readily destained with EDTA, and several RNP containing nucleoli. There is continuity between the material of the chromocenters and the decondensed DNP fibrils in the nuclear matrix. The nucleoli contain NORs in the form of fibrillar centers. The endonuclear aggregate includes also groups of RNP granules which are especially resistant to EDTA destaining. A microfibrillar sphere, usually localized at the periphery of the aggregate, contacts one or several nucleoli. The sphere is not bleached with EDTA, and only its periphery becomes digested with pronase. The macronuclear matrix consists of both protein fibrils and pronase-resistant fibrils, the latter being localized at the nuclear periphery.Developing macronuclear primordia contain loose strands of decondensed chromatin; only later they form chromocenters and nucleoli.The micronuclei reproduce by mitosis with typical chromosomes (2n=66). During interphase, they are filled with condensed chromatin which can be bleached with EDTA; they form no nucleoli. Ring-like lamellae, existing in the cavities of the chromatin mass, stain for RNA (after Bernhard) and are pronase-sensitive. These lamellae resemble the kinetochore material conserved during interphase in another karyorelictid ciliate,Trachelocerca geopetiti.     

Reorganization of microtubules in the amitotically dividing macronucleus of tetrahymena

We developed a modified immunofluorescence protocol that permitted visualization of microtubules inside the macronucleus of the ciliate Tetrahymena. Although the amitotically dividing macronucleus lacks a spindle, an elaborate system of microtubules is assembled inside the macronucleus and between the macronucleus and the cortex. Microtubules could not be detected inside the interphase macronuclei. The early stage of macronuclear division was associated with the assembly of short macronuclear microtubules that localized randomly. The intramacronuclear microtubules were subsequently organized in a radial manner. During elongation of the macronucleus, the distribution of macronuclear microtubules changed from radial to parallel. During constriction of the macronucleus, dense and tangled macronuclear microtubules were detected at the region of nuclear constriction. In the cytosol, microtubules were linking the macronucleus and cell cortex. During recovery after drug-induced depolymerization, microtubules reassembled at multiple foci inside the macronucleus in close proximity to the chromatin. We propose that these microtubules play roles in chromatin partitioning, macronuclear constriction, and positioning of the macronucleus in relation to the cell cortex.     

MACRONUCLEAR EVENTS IN SYNCHRONOUSLY DIVIDING TETRAHYMENA PYRIFORMIS

The macronuclei of synchronously dividing mass cultures of Tetrahymena pyriformis (strain WH₆) were examined with the electron microscope for changes during two division cycles. Samples were prepared at 30-minute intervals for a period of 8½ hours which included the time required to induce synchrony by five heat shocks (4½ hours). The interphase macronucleus contains peripheral, crescent-shaped nucleoli and evenly distributed chromatin bodies. Centrally located RNA bodies, composed of fibers, appear 1 to 2 hours following the initial heat shock. They are completely destroyed with ribonuclease whereas the nucleoli are only partially so. Following the third heat shock the RNA bodies move to the periphery and disintegrate; the nucleoli aggregate and form blebs which protrude into the cytoplasm where they appear to pinch off and may contribute to the cytoplasmic ribonucleic acid. Cytokinesis does not occur at this time. Instead the nuclear events are repeated during the 4th and 5th hours, even though the heat shocks are terminated at 4½ hours. Cytokinesis takes place at about 6 hours. The second division occurs about 2½ hours later during which all the macronuclear events noted above are repeated.     

Electron Microscopy of the Nuclear Events During Binary Fission in Paramecium multimicronucleatum

SYNOPSIS. From the interphase to the early stage of binary fission in Paramecium multimicronucleatum , when the micro-nuclei are situated close to the macronucleus, the microtubules in the cytoplasm seem to connect the nuclear pores of macro- and micronuclei. During the 1st half of macronuclear division, the microtubules are formed outside the macronucleus, while during the latter half of division, numerous microtubules appear inside it. Chromatin bodies and nucleoli remain unchanged during macro-nuclear division, but the latter show temporory irregularity in shape. In late prophase of micronuclear division, spindle micro-tubules are formed, and a polar structure, composed of randomly dispersed twisting filaments, is formed at each pole of the micro-nucleus at anaphase. Spindle microtubules terminate on the surface of this structure. The nuclear envolope of the macro-and micronuclei remains intact thruout division. The envelope of the daughter micronuclei is derived from the pre-existing one.     

Suggestive Structural Evidence for Macronuclear "Subnuclei" in Tetrahymena pyriformis GL

SYNOPSIS Structural changes in the Feulgen-positive material of the Tetrahymena pyriformis GL macronucleus have been observed during the cell cycle. From the finely granulated appearance in the interphase cell it appears as small rods, often arranged in pairs (probably the endomitotic stage) during early morphogenesis and as larger (and fewer) aggregates of granules during the nuclear division. These latter aggregates are also visible in dividing nuclei in the electron microscope where groups of chromation granules are separated by fairly empty nucleoplasm. It is suggested that these Feulgen positive aggregates in dividing nuclei are macronuciear segregation units or "subnuclei." The number per dividing macronucleus may vary from one experiment to another, but the variation seems to be related to cell volume. The distribution of the aggregates among the daughter nuclei is almost equal. The total number per dividing macronucleus is about 80 which is close to the estimated number of "subnuclei" in the T. pyriformis macronucleus (Allen and Nanney, 1958).
Some calculations are made on the polyploidy of the T. pyriformis GL macronucleus. Using published electron micrographs of micronuclei of known age to calculate the total number of chromatin granules per haploid nucleus, the polyploidy of the strain GL macronucleus is about 40. This figure is half of that expected from Allen and Nanney's estimation, since they assumed that the "subnuclei" were diploid; however, it is in agreement with the reported haploid nature of the "subnuclei" as found by Woodard, Gorovsky & Kaneshiro, 1968. Further calculations suggest that each macronuclear "chromosome" is composed of about 40 chromatin granules; an indication of such a chain arrangement of the chromatin granules has been observed in the phase contrast and electron microscope during the earliest macronuclear events, i.e., at the macronuclear "prophase."     

冠突伪尾柱虫（Pseudourostyla cristata）实验再生研究

冠突伪尾柱虫(Pseudvurostyla cristata) 含约70枚大核。我们用显微手术横切G1期细胞,得前后两块相等断片;分别培养。60小时后,断片再生完成。在再生过程中,随细胞体积增大,大核数目也增加。大核的数目和细胞体积存在着一定的均衡关系。在细胞无性分裂过程中,许多大核改组后,融合成一个融合大核。这个融合大核具两个仔虫的大核数目和DNA量。我们用显微手术得到含融合大核的后断片。在后断片再生后恢复的虫体内,我们发现本应分配到两个仔虫中去的大核数目,被限制在一个虫体的大核数目上。这说明了细胞质可以影响和调节大核的数目。并还证明了这种虫体大核DNA量较正常虫的大核DNA量约多一倍。其中大部分虫体分裂时,大核不经改组就开始融合和分裂;从而使DNA量回复正常。同讨还发现小部分虫体通过排出大核多余核物质方式来调节大核DNA量。这些现象说明了细胞核质之间存在着一种调节相对平衡和相互协调的机制。     

Localization of microtubules during macronuclear division in Tetrahymena and possible involvement of macronuclear microtubules in 'amitotic' chromatin distribution

The ciliated protozoa Tetrahymena contains two nuclei, a micronucleus and a macronucleus. In the vegetatively growing cell, the macronucleus divides amitotic while the micronucleus divides by mitosis. It has been indicated that microtubules are involved in macronuclear division and microtubules are observed to exist in the dividing macronucleus. To clarify the localization and the organization of microtubules in the amitotic dividing macronuclei, we used immunofluorescent staining technique. The microtubules were observed in the cytoplasm and macronucleus. The microtubules were organized and dynamically changed their distribution throughout the macronuclear division. We suggest a possibility that these microtubules are involved in 'amitotic' distribution of chromatin throughout the macronuclear division.     

Macronuclear division and cytokinesis in Tetrahymena

Tetrahymena contains a micronucleus and a macronucleus. The micronucleus divides with typical mitosis, while the macronucleus divides amitotically. Although the mechanism responsible for macronuclear division was previously unknown, we clarified the organization of microtubules during macronuclear division. The macronuclear microtubules dynamically changed their distribution in an organized way throughout the macronuclear division. The macronuclear microtubules and the cytoplasmic microtubules cooperatively carried out the macronuclear division. When the micronuclear division was finished, p85 appeared at the presumptive division plane prior to the cytokinesis. The p85 directly interacted with calmodulin in a Ca(2+)-dependent manner, and p85 and CaM colocalized to the division furrow during cytokinesis. Moreover, the Ca(2+)/CaM inhibitor, W7, inhibited the direct interaction between p85 and CaM, the localization of both proteins to the division plane, and the formation of the division furrow. Thus, Ca(2+)/CaM and p85 have important roles in initiation and progression of cytokinesis in Tetrahymena.     

Fine structure of the macronucleus during the cell division cycle of Euplotes eurystomus,a Ciliate Protozoon

This paper reports new observations obtained from a study of macronuclear fine structure throughout various stages of the cell division cycle of Euplotes. Study of the ultrastructural organization of the macronuclear chromatin indicates that much of the chromatin is organized into continuous masses, portions of which appear to be attached to the nuclear envelope. The macronuclear envelope appears unchanged in the region of a replication band, and apparent attachments of the chromatin to the inner membrane of the nuclear envelope are maintained in the reticular and diffuse zones. Intranuclear helices were never observed in the diffuse zone. During macronuclear division, linear elements (fibrils or microtubules) were observed in close association with both chromatin bodies and nucleoli. The ultrastructural data suggest that the intranuclear linear fibrils have two functions: elongation of the dividing nucleus, and attachment of chromatin bodies and nucleoli to the envelope. The significance of these observations for macronuclear division and chromatin segregation is considered.     

Chromatin extrusion in resting encystment of Colpoda cucullus: a possible involvement of apoptosis-like nuclear death

The extrusion of macronuclear chromatin is a remarkable characteristic during encystment in Colpoda, but the biological significance of this phenomenon has not been fully elucidated. Here we demonstrate that chromatin extrusion occurs with high frequency when encystment was induced by increasing Ca(2+) in growing cells in various stages of the cell cycle. The Feulgen-DNA reaction revealed that vegetatively growing cells have more macronuclear DNA than cells in the stationary phase, suggesting an association of macronuclear DNA content with the execution of chromatin extrusion. Using 4',6-diamidino-2-phenylindole (DAPI), we found that the size of the macronuclear extrusion body was reduced with time and eventually disappeared approximately 24h after encystment induction. In addition, oligonucleosome-sized DNA cleavage was confirmed to occur concomitant with the size reduction, suggesting that the extrusion body is selectively degraded, while the normal macronucleus remains alive. Combined use of acridine orange and Hoechst 33342 demonstrated that the extruded body was increasingly acidified before final resorption. These features are reminiscent of the nuclear degradation process in conjugating Tetrahymena, and therefore we conclude that chromatin extrusion in Colpoda might occur to adjust the macronuclear DNA content prior to encystment. In this way, it is similar to the apoptotic-like nuclear death that occurs during the conjugation of other ciliates.     

DNA elimination and its relation to quantities in the macronucleus of Tetrahymena.

The macronucleus of Tetrahymena contains a large number of DNA molecules of subchromosomal size. They belong to about 270 species each one occurring at an average number of 45 copies. Macronuclei divide unequally and nothing is known of segregation control. This and the elimination and degradation of DNA during macronuclear amitosis make the clonal stability of macronuclei a problem of qualitative and quantitative control on a subchromosomal level. We studied the contribution of DNA elimination to the quantitative composition of the macronucleus cytophotometrically in single cells of different strains. This was done under standard conditions and under conditions known to influence the amount of macronuclear DNA. The following results were found: Elimination of DNA occurs at almost every division. The size of the elimination body is highly variable but still positively correlated with the macronuclear DNA content. In T. thermophila the amount of eliminated DNA is 2.5% of the G2 content and is not dependent on the growth state. It varies with species, amounting to as much as 8% in T. pigmentosa. During conditions which increase the macronuclear DNA content, very little DNA is eliminated. On the other hand, large amounts are eliminated under other conditions causing the macronuclear DNA content to decrease. DNA to be eliminated at division is synthesized at the same time as bulk DNA. We developed a computer program which helps us study the effects of DNA elimination and unequal divisions upon the copy numbers of subchromosomal DNA classes.(ABSTRACT TRUNCATED AT 250 WORDS)     

The DNA of ciliated protozoa.

Ciliates contain two types of nuclei: a micronucleus and a macronucleus. The micronucleus serves as the germ line nucleus but does not express its genes. The macronucleus provides the nuclear RNA for vegetative growth. Mating cells exchange haploid micronuclei, and a new macronucleus develops from a new diploid micronucleus. The old macronucleus is destroyed. This conversion consists of amplification, elimination, fragmentation, and splicing of DNA sequences on a massive scale. Fragmentation produces subchromosomal molecules in Tetrahymena and Paramecium cells and much smaller, gene-sized molecules in hypotrichous ciliates to which telomere sequences are added. These molecules are then amplified, some to higher copy numbers than others. rDNA is differentially amplified to thousands of copies per macronucleus. Eliminated sequences include transposonlike elements and sequences called internal eliminated sequences that interrupt gene coding regions in the micronuclear genome. Some, perhaps all, of these are excised as circular molecules and destroyed. In at least some hypotrichs, segments of some micronuclear genes are scrambled in a nonfunctional order and are recorded during macronuclear development. Vegetatively growing ciliates appear to possess a mechanism for adjusting copy numbers of individual genes, which corrects gene imbalances resulting from random distribution of DNA molecules during amitosis of the macronucleus. Other distinctive features of ciliate DNA include an altered use of the conventional stop codons.     

The DNA of ciliated protozoa.

Ciliates contain two types of nuclei: a micronucleus and a macronucleus. The micronucleus serves as the germ line nucleus but does not express its genes. The macronucleus provides the nuclear RNA for vegetative growth. Mating cells exchange haploid micronuclei, and a new macronucleus develops from a new diploid micronucleus. The old macronucleus is destroyed. This conversion consists of amplification, elimination, fragmentation, and splicing of DNA sequences on a massive scale. Fragmentation produces subchromosomal molecules in Tetrahymena and Paramecium cells and much smaller, gene-sized molecules in hypotrichous ciliates to which telomere sequences are added. These molecules are then amplified, some to higher copy numbers than others. rDNA is differentially amplified to thousands of copies per macronucleus. Eliminated sequences include transposonlike elements and sequences called internal eliminated sequences that interrupt gene coding regions in the micronuclear genome. Some, perhaps all, of these are excised as circular molecules and destroyed. In at least some hypotrichs, segments of some micronuclear genes are scrambled in a nonfunctional order and are recorded during macronuclear development. Vegetatively growing ciliates appear to possess a mechanism for adjusting copy numbers of individual genes, which corrects gene imbalances resulting from random distribution of DNA molecules during amitosis of the macronucleus. Other distinctive features of ciliate DNA include an altered use of the conventional stop codons.     

DNA elimination in Tetrahymena: a developmental process involving extensive breakage and rejoining of DNA at defined sites

Elimination of specific DNA sequences occurs during macronuclear development in the ciliate Tetrahymena thermophila. Recombinant DNA clones containing a segment of micronuclear (germinal) DNA involved in elimination and the corresponding segment of macronuclear (somatic) DNA produced after elimination were isolated. Detailed comparisons of the cloned DNAs, as well as the genomic DNAs, by hybridization indicated that DNA elimination is accompanied by specific DNA rearrangements. In this 9.5 kb region three defined DNA segments are deleted and the remaining sequences are linked together as one contiguous piece in the macronucleus. Specific DNA rearrangement of this kind occurs widely in the genome. Analysis of 20 randomly selected DNA clones suggests that there are more than 5000 such rearrangement sites in the genome. Thus specific breakage and rejoining of DNA occurs extensively during development, and might play an essential role in nuclear differentiation.     

The perichromosomal layer

In addition to genetic information, mitotic chromosomes transmit essential components for nuclear assembly and function in a new cell cycle. A specialized chromosome domain, called the perichromosomal layer, perichromosomal sheath, chromosomal coat, or chromosome surface domain, contains proteins required for a variety of cellular processes, including the synthesis of messenger RNA, assembly of ribosomes, repair of DNA double-strand breaks, telomere maintenance, and apoptosis regulation. The layer also contains many proteins of unknown function and is a major target in autoimmune disease. Perichromosomal proteins are found along the entire length of chromosomes, excluding centromeres, where sister chromatids are paired and spindle microtubules attach. Targeting of proteins to the perichromosomal layer occurs primarily during prophase, and they generally remain associated until telophase. During interphase, perichromosomal proteins localize to nucleoli, the nuclear envelope, nucleoplasm, heterochromatin, centromeres, telomeres, and/or the cytoplasm. It has been suggested that the perichromosomal layer may contribute to chromosome structure, as several of the associated proteins have functions in chromatin remodeling during interphase. We review the identified proteins associated with this chromosome domain and briefly discuss their known functions during interphase and mitosis.     

Chromatin structure in somatic nucleus of ciliate <Emphasis Type="Italic">Didinium nasutum</Emphasis>

The structural organization of macronuclear chromatin of the ciliate Didinium nasutum was studied. The macronuclear genome of D. nasutum is represented by DNA molecules of subchromosomal size. At interphase, macronuclear chromatin is organized into chromatin of 100–200-nm clumps. Some of these clumps form short, thick fibers that consist of several chromatin clumps. Using the differential staining of nucleic acids on ultrathin sections, we revealed perichromatin fibers and granules on the surface of many chromatin clumps. A 3D model of the spatial distribution of chromatin clumps in the macronucleus was built based on serial ultrathin sections and peculiar features of chromatin spatial organization were studied.