Electron microscopic studies on the macronuclear development in the ciliate Chilodonella uncinata.

The development of macronuclear anlage in the ciliate Chilodonella uncinata has been studied through electron microscopy. The ultrastructure of macro- and micronuclei is described for comparison. During the first stage of development, when the DNA content of the macronuclear anage increases from 2 C to 32 C, chromosomes are visible as distinct osmiophilic bodies inside the anlage. At the end of the initial polyploidization phase, the chromosomes despiralize, giving rise to long filamentous structures 25 to 50 nm in diameter. The latter show a singular banding pattern, with dense bands 12 to 25 nm thick alternating regularly with less dense interbands. Such an organization has not yet been observed in any other type of nucleus. These filamentous structures have been interpreted as highly despiralized oligotenic chromosomes. During the final stage of macronuclear development, these structures condense into thin chromatin strands and small dense granules; the number of granules increases progressively as the chromatin strands disappear. These small granules very likely fuse amongst themselves to form the chromatin granules of the vegetative macronucleus. No evidence has yet been found for a fragmentation of chromatin in this ciliate, but this problem needs further study. The old macronucleus maintains a normal ultrastructure until a late stage of development of the macronuclear anlage, becoming pycnotic only towards the very end of the latter process.     

Nuclear differentiation and nucleic acid synthesis in well-fed exconjugants of Paramecium aurelia

Paramecium aurelia exconjugants contain new macronuclear anlagen and numerous fragments of the old pre-zygotic macronucleus. Macronuclear anlagen develop during the first two cell cycles after conjugation. During this time their volume increases from about 11 m³ to about 3700 m³ and more than 10 doublings of DNA content occur. The rate of DNA synthesis is between two and three times as great as in the vegetative macronucleus. — In macronuclear fragments, however, DNA synthesis is suppressed. The rate of DNA synthesis in macronuclear fragments during the extended first cell cycle after conjugation (11 1/2 hr. vs. 5 1/2 hr. for the vegetative cell cycle) is only about one-third of the rate in vegetative macronuclei and there is only a 65% increase in the mean DNA content of fragments. The rate of fragment DNA synthesis continues to decrease during each of the subsequent two cell cycles. — Unlike the rate of DNA synthesis, the rate of RNA synthesis per unit of DNA is similar in macronuclear anlagen, macronuclear fragments and fully developed macronuclei. Macronuclear fragments continue to synthesize RNA at the normal rate long after the new macronuclei are fully developed. Fragments contribute about 80% of all RNA synthesized during the first two cell cycles after conjugation. RNA synthesis begins very early in the development of macronuclear anlagen and nucleolar material appears during the first half-hour of anlage development. — Chromosome-like structures were never observed during anlage development and there was no evidence of two periods of DNA synthesis separated by a DNA poor stage as has been observed in several hypotrichous Ciliates.     

The development of the macronucleus in the ciliated protozoan Stylonychia mytilus

Ciliated protozoa are characterized by generative micronuclei and vegetative polyploid macronuclei. Micronuclei of Stylonychia mytilus contain 1 600 times as much DNA per haploid genome as E. coli. Most of this DNA is shown to be repetitive. The development of the macronucleus involves, as demonstrated by cytology, only 1/3 of the chromosomes which in a first replication phase are polytenized in probably 5 replication steps and appear as giant chromosomes. At this developmental stage considerable amounts of repetitive DNA are still present in the chromosomes. During the subsequent disintegration phase more than 90% of the DNA are eliminated from the macronucleus anlage. The remainder is further replicated five times and composes the final macronucleus. Since this DNA reassociates with a reaction rate almost identical to an ideal second order reaction its kinetic complexity can be determined by comparison with the kinetic complexity of E. coli DNA. Macronuclear DNA reassociates with a kinetic complexity of 26 times the kinetic complexity of E. coli DNA (corrected for GC content) which indicates that macronuclear DNA sequences exist at a ploidy level of 4 096 C. We assume that macronuclear DNA may be present only once per haploid genome. In this case it represents only 1.6% of the DNA in micronuclei or 10% of the DNA in the giant chromosome stage.     

Nuclear Behavior of Euplotes woodruffi During Conjugation

SYNOPSIS. During conjugation of E. woodruffi , the micro-nucleus divides repeatedly four times prior to synkaryon formation and twice thereafter. The first division resembles an ordinary somatic mitosis, resulting in the formation of two daughter nuclei in each conjugant. Both products of this division enter the second division which corresponds to the heterotypic division of other ciliates, characterized by a parachute stage. Following this stage sixteen bivalents appear and separate into dyads and pass to the poles. During the following divisions individualized chromosomes do not appear but only certain chromatin elements comparable to those seen in the somatic and preliminary divisions. These divide and pass to the poles. All daughter nuclei of the second division enter and complete the third division. Only two of the products of the third division enter the final pregamic division while the rest degenerate. Exchange of pronuclei and their fusion leads to synkaryon formation. The conjugants then separate and in each exconjugant the synkaryon divides twice in rapid succession. Of the four products one condenses to become the functional micronucleus, another enlarges rapidly to become the macronuclear anlage while the remaining two degenerate and disintegrate. The old macronucleus breaks into irregular and polymorphic bodies. As the macronuclear anlage enlarges the remnants of the old macronucleus reorganize and fuse with the macronuclear anlage to form a characteristic vegetative macronucleus.     

Internuclear control of DNA synthesis in exconjugant cells of Paramecium caudatum

An exconjugant cell of Paramecium caudatum has two kinds of macronuclei, fragmented prezygotic macronuclei and postzygotic new macronuclei (anlagen). Although the DNA synthesis in the fragmented prezygotic macronucleus continues until the third cell cycle after conjugation, selective suppression of the DNA synthesis in the prezygotic macronucleus takes place at the fourth cell cycle. The inhibition of DNA synthesis in prezygotic fragmented macronuclei is due to the presence of a postzygotic macronucleus (anlage) in the same cytoplasm because the inhibition does not occur when the postzygotic macronucleus (anlage) is removed by micromanipulation during the third or fourth cell cycle. Well-developed postzygotic macronuclei (anlagen) with full ability to divide have the ability to depress the DNA synthesis of prezygotic macronuclear fragments. The suppression of DNA synthesis in prezygotic macronuclear fragments seems to be irreversible. Competition for the limited amount of DNA precursors also plays an important role in the onset of the selective suppression of the DNA synthesis.     

伍氏游仆虫接合过程中老大核后碎块的去向

在伍氏游仆虫(Euplotes woodruffi)接合后体发育过程中,已呈退化状态的老大核后碎块,在细胞第二次形态发生时,逐渐恢复其正常形态结构。T形新大核原基向后延伸而与恢复正常形态的老大核后碎块紧密靠拢。此时在光镜下观察,很容易误认为二者已融合为一。但在接合后体分裂之前,老大核后碎块再次瓦解,T形大核原基缩短成棒状而与老大核后碎块分开,此时二者界限分明。细胞分裂后,残存的老大核后碎块停留于后子虫中,最后被吸收。几个关键时期大核原基和老大核后碎块DNA含量的测定,也证明新老大核不融合。本文还讨论了老大核后碎块在有性过程中的功能。     

Nuclear Roles in the Post-Conjugant Development of the Ciliate Euplotes aediculatus. III. Roles of Old Macronuclear Fragments in Nuclear and Cortical Development1

Following conjugation of the hypotrichous ciliate Euplotes aediculatus, the posterior fragments of the old (prezygotic) macronucleus persist until after the first vegetative division. These fragments remain viable during exconjugant development as shown by their ability to regenerate should the cell's new macronucleus be damaged. It thus seemed possible that these parental nuclear fragments might participate in the development of the new macronucleus and/or the crucial post-conjugant cortical reorganization that restores the exconjugant cell's ability to feed. This idea was tested by damaging the posterior fragments with various doses of microbeam ultraviolet (UV) light and assessing the results of such treatment on subsequent cortical and nuclear development. When the posterior fragments of the macronucleus were irradiated at the beginning of cortical morphogenesis, the new macronucleus in 1/3 to 1/2 of the cells assumed a “folded” appearance but did not mature. These cells did not undergo cortical reorganization. Cells irradiated at earlier stages did not detectably develop an oral apparatus; their new macronucleus remained arrested at the spherical anlage stage. The results show that the posterior fragments of the parental macronucleus are necessary for normal nuclear and cortical development. These old nuclear fragments appear to influence the growing macronuclear anlage directly and probably the cortex as well. There also appears to be an information flow from the non-irradiated partner of a persistently joined exconjugant doublet to its irradiated counterpart, enabling normal anlage and cortex development in the irradiated cell.     

Mitosis-like macronuclear division in a ciliate

The macronucleus of a small marine ciliate of the genus Protocrucia consists of a cluster of ten vesicles which give rise to 20 distinct chromosomal elements in the course of prophase-like condensation stages. Size differences of vesicles and chromosomes are cytological indications of their genetic individuality. In an anaphase-like stage, the chromosomal elements are separated in two daughter groups which re-form 10 vesicles each. The micronucleus divides simultaneously. The existence of a precisely functioning mode of chromosome distribution is also indicated by DNA measurements. Since the macronucleus contains much more DNA than the micronucleus, the macronuclear chromosomes are thought to be oligotenic. This hypothesis is supported by the much larger size of the macronuclear chromosomes. In contrast to other modes of macronuclear division known so far, this ciliate has retained some essential features of mitosis.     

Analysis of mating type determination by transplantation of O macronuclear karyoplasm in Paramecium tetraurelia

The odd (O) or even (E) mating type in Paramecium tetraurelia is determined during the first cell cycle after new macronuclear development. The present paper demonstrates that mating type E is irreversibly determined at the end of the first cell cycle. Direct evidence comes from transplanting O macronuclear karyoplasm containing O-determining factor into E autogamous cells during a new postzygotic macronuclear development. Transplantation of O macronuclear karyoplasm into E autogamous cells at 7–8 hr after the origin of the macronucleus from a product of the synkaryon produces nearly 100% O mating type among the exautogamous cell lines but almost none 10–11 hr after the origin of the macronucleus (around the end of the first cell cycle). The macronuclear anlagen at the stage at which mating type E seems to be fixed contains about 20 times as much DNA as the vegetative G1 micronucleus. The O-determining factor shifting E cells toward O mating type by transplanting O macronuclear karyoplasm is also produced by the newly developed macronucleus in an effective concentration at 10–11 hr after the sensitive period and produced at full levels by the third cell cycle. The level of O factor in the macronucleus then gradually declines with subsequent repeated rounds of DNA synthesis and is finally lost by the eighth cell cycle.     

The processing of macronuclear-destined DNA sequences microinjected into the macronuclear anlagen of the hypotrichous ciliate Stylonchia lemnae.

We describe the construction of a vector carrying the micronuclear versions of two macronuclear DNA molecules, one of which was modified by the insertion of a polylinker sequence. This vector was injected into the polytene chromosomes of the developing macronucleus of Stylonychia and its processing during further macronuclear development and its fate in the mature macronucleus were analyzed. In up to 30% of injected cells the modified macronuclear DNA sequence could be detected. While the internal eliminated sequences (IES) present in the macronuclear precursor DNA sequence are still retained in the mature macronucleus, the modified macronuclear DNA sequence is correctly cut out from the vector, telomeres are added de novo and it is stably retained in the macronucleus during vegetative growth of the cells. This vector system represents an experimental system that allows the identification of DNA sequences involved in the processing of macronuclear DNA sequences during macronuclear development.     

Antibodies against Z DNA react with the macronucleus but not the micronucleus of the hypotrichous ciliate stylonychia mytilus

Using indirect immunofluorescence, we studied the reaction of antibodies specific for left-handed Z DNA with the nuclei of the hypotrichous ciliate Stylonychia mytilus. In the vegetative cell, the macronucleus reacts strongly with these antibodies, but no reaction can be detected with micronuclei. However, an antibody that binds to denatured and right-handed B DNA reacts with both types of nuclei. No reaction of the anti-Z DNA antibody is seen in the macronuclear replication band. Digestion of macronuclei with DNAase I leads to a decrease in the anti-Z DNA antibody reaction. Some stages of the developing macronucleus were also investigated. No reaction is seen at the polytene chromosome stage, but following DNA elimination the nucleus is seen to react with the antibody.     

Polytene chromosomes and nucleic acid metabolism during macronuclear development in Euplotes

Polytene chromosomes in two species of Euplotes, E. woodruffi and E. eurystomus, have been described during the macronuclear development following conjugation. In these two species, the giant chromosomes appear briefly in the macronuclear anlagen and disappear completely later. DNA synthesis begins concomitantly with the appearance of the giant chromosomes and reaches a peak at the maximum stage of polyteny. Shortly thereafter DNA begins to break down and the breakdown products leave the macronuclear anlagen, reducing the DNA content in the anlagen to the amount present at the earlier stages of the polytene development of the chromosomes. A later phase of DNA synthesis occurs in the anlagen with the appearance of replication bands comparable to the bands which double the DNA in the somatic macronucleus. These replication bands initiate several rounds of DNA synthesis which finally lead to the development of the vegetative macronucleus. RNA synthesis occurs uniformly on the giant chromosomes and no special RNA producing puffs or other regions are noticed on them.Research supported by American Cancer Society grant E 434 to David M. Prescott and by the Deutsche Forschungsgemeinschaft to Dieter Ammermann.     

Observations on the Life-cycle of a New Race of Blepharisma undulans from India

SYNOPSIS. A full account of the nuclear changes during binary fission and conjugation in a local race of Blepharisma is presented in this paper. The macronucleus consists of 2 nodes connected by a strand. Number of micronuclei varies from 6 to 18. During binary fission, condensation of macronucleus is followed by elongation and thinning of the middle region which finally breaks. Daughter nuclei later attain the typical vegetative form. Notably, during binary fission some micronuclei appear to complete their mitoses by the time the macronucleus attains the condensed form, while others lag behind and exhibit practically every stage of mitosis.
During conjugation, from 6 to 10 micronuclei undergo the first pregamic division, the same number through the second division, and two products of the second division take part in the third division. The rest degenerate. Division products of the nuclei in the paraoral region take part in synkaryon formation. The synkaryon undergoes either 2 or 3 divisions. In the former case, of the 4 products, 2 become the macronuclear anlagen, one the micronucleus and the fourth degenerates. In the latter case, of the 8 products, 3 to 4 become the macronuclear anlagen and the rest become micronuclei. Chromatin elimination has been observed during the division of the macronuclear anlage, followed by an extra metagamic fission of the cell.
Comparison with two other races from India and an American race indicates considerable diversity in the structure and behaviour of the nuclear apparatus in different races of Blepharisma undulans.     

Effects of Nullisomic Chromosome Deficiencies on Conjugation Events in Tetrahymena Thermophila: Insufficiency of the Parental Macronucleus to Direct Postzygotic Development

Conjugation fails postzygotically after mating of Tetrahymena cells that have wild-type parental macronuclei but harbor noncomplementing nullisomic parental germline deficiencies. Failures begin shortly after formation of the new macronuclear precursor (anlage) and completion of the first step in elimination of the parental macronucleus (pycnosis). Conjugants fail to complete pair separation, to eliminate one new micronucleus, and to amplify anlage DNA, and they eventually die. Some deficiencies block resorption of the pycnotic parental macronucleus, but we find no evidence for its regeneration. Some deficiencies cause aberrant anlage DNA loss. Those that do not cause DNA loss are epistatic to those that do, indicating that normal anlage development requires the dependent function of at least two types of genes. The possibility that these genes are involved in developmentally regulated anlage DNA rearrangements is discussed. Each observed conjugation defect indicates insufficiency of the parental macronucleus to direct postzygotic development and can be explained by the deficiency of essential conjugation genes that are expressed from the anlage. The failure of nullisomic conjugants to complete pair separation indicates a requirement for gene products, expressed from the early anlage or its precursors, soon after anlage first differentiate.     

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。     

De novo cytosine methylation in the differentiating macronucleus of the stichotrichous ciliate Stylonychia lemnae

Dramatic DNA reorganization and elimination processes occur during macronuclear differentiation in ciliates. In this study we analyzed whether cytosine methylation of specific sequences plays a functional role during DNA rearrangement. Three classes of sequences, macronuclear-destined sequences (MDSs, pCE7), members from a large family of transposon-like elements and micronuclear-specific sequences (pLJ01), differing in their structure and future destiny during nuclear differentiation, were studied in the micronucleus, the developing macronucleus and, when present, in the mature macronucleus. While the MDSs become processed to a 1.1 and 1.3 kb gene-sized macronuclear DNA molecule, the family of transposon-like elements represented by MaA81 becomes removed late in the course of polytene chromosome formation. The micronuclear-specific sequence pLJ01 is eliminated together with bulk micronuclear DNA during degradation of polytene chromosomes. No methylated cytosine could be detected in the vegetative macronucleus and no difference in methylation pattern was observed either between micronucleus and developing macronucleus in MDSs or in a micronuclear-specific sequence. However, a significant percentage of the cytosines contained in the transposon-like element becomes methylated de novo in the course of macronuclear differentiation. This is the first demonstration that cytosine methylation in specific sequences occurs during macronuclear differentiation and may provide a first step towards understanding epigenetic factors involved in DNA processing.     

Delayed degradation of parental macronuclear DNA in programmed nuclear death of Paramecium caudatum

In the ciliated protozoan Paramecium caudatum, a parental macronucleus that is fragmented into some 40-50 pieces during conjugation does not degenerate immediately, but persists until the eighth cell cycle after conjugation. Here we demonstrate that the initiation of the parental macronuclear degeneration occurs at about the fifth cell cycle. The size of parental macronuclear fragments continued to increase between the first and fourth cell cycle, but gradually decreased thereafter. By contrast, a new macronucleus grew and reached a maximum size by the fourth cell cycle, suggesting that the new macronucleus matured by that stage. Southern blot analysis revealed that parental macronuclear DNA was degraded at about the fifth cell cycle. The degradation was supported by acridine orange staining, indicating degeneration of the macronuclear fragments. Prior to the degradation, the fragments once attached to the new macronucleus were subsequently liberated from it. These observations lead us to conclude that once a new macronucleus has been fully formed by the fourth cell cycle, the parental macronuclear fragments are destined to degenerate, probably through direction by new macronucleus. Considering the long persistence of the parental macronucleus during the early cell cycles after conjugation, the macronuclear fragments might function in the maturation of the imperfect new macronucleus. Two possible functions, a gene dosage compensation and adjustment of ploidy level, are discussed.     

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."     

Cytology of an Indian Race of Blepharisma undulans (Stein)

SYNOPSIS. The Indian race of Blepharisma undulans described in this paper measures 150 μ in length. The macronucleus consists of 5–7 nodes, all of equal size. During binary fission, condensation of macronucleus is followed by its elongation and a thinning of the middle region which breaks with the division of the animal. It later attains the typical vegetative form.
During conjugation 7 or 8 micronuclei pass through the first pregamic division, 5 to 7 through the second pregamic division and one product of the second division takes part in the third division. The rest degenerate. At the same time, the macronucleus also starts degenerating. After the synkaryon has divided twice, the conjugating pairs separate. Of the 4 products, 3 become macronuclear anlagen and one, micronuclear anlage.
The micronuclei divide asynchronously both during binary fission and during conjugation. There is apparently considerable diversity in the structure and behaviour of the macronucleus and micronuclei in the different races of Blepharisma undulans.