Macronuclear differentiation in conjugating pairs of Tetrahymena treated with the antitubulin drug nocodazole

During Tetrahymena conjugation gamic nuclei (pronuclei) are produced, reciprocally exchanged, and fused in each mate. The synkaryon divides twice; the two anterior nuclei develop into new macronuclei while the two posterior nuclei become micronuclei. The postzygotic divisions were blocked with the antitubulin drug nocodazole (ND). Then pronuclei (gamic nuclei) developed directly into macronuclear anlagen (primordial macronuclei), inducing amicronucleate cells with two anlagen, or, rarely, cells with one anlagen and one micronucleus. ND had a similar effect on cells that passed the first postzygotic division inducing amicronucleate cells with two anlagen, while cells treated with ND at the synkarya stage produced only one large anlage. Different intracytoplasmic positioning of the nuclei treated with ND (pronuclei, synkarya and two products of the first division) shows that most of cell cytoplasm is competent for inducing macronuclear development. Only posteriorly positioned nuclei--products of the second postzygotic division--remain micronuclei. The total cell DNA content, measured cytophotometrically in control and in ND-induced amicronucleate conjugant cells with one and two anlagen, was similar in all three samples at 12 h of conjugation. Eventually, at 24 h this content was about 2 pg (8 C) per anlagen both in nonrefed control and in amicronucleate exconjugants. Therefore "large" nuclei developing in the presence of ND were true macronuclear anlagen.     

冠突伪尾柱虫(Pseudourostyla cristata)接合生殖的研究 Ⅰ.核器演化

在25℃条件下,冠突伪尾柱虫接合生殖全程历时10天左右。接合生殖过程中的核器演化包括:①数十枚老的大核逐步瓦解。电镜观察表明,老的大核是以一种类似于食物泡消化的方式被吸收的,并在此过程中伴有大量溶酶体出现。②仅8枚左右小核中的一枚参与新核器的发生。首先,位于胞口后部的一枚小核膨大并进行一次预备分裂,接着发生三次成熟分裂。每一接合体内形成一枚雄原核和一枚雌原核。雄原核互向对方迁移并与其雌原核融合成为合子核。合子核分裂两次,四枚子核之一发育为大核原基,另一枚发育为小核原基,其余两枚退化。预备分裂和前两次成熟分裂各自产生的两枚子核中,仅一枚进入下一次分裂,另一枚解体消失。在第一次成熟分裂前期,“降落伞”的形成和发展经历着复杂的结构变化,持续一小时以上。③大核原基经过长时间的发育,伴有多线染色体的形成和解体等一系列变化,方达成熟状态。成熟的大核原基以伸长断裂、分叉断裂和哑铃形缢缩三种方式进行分裂,小核原基亦随之分裂,逐步形成具60枚左右大核、8枚左右小核的正常营养体。其后,大核融合,开始配后第一次无性分裂。值得注意的是,大核原基发育到将成熟时,最初的迹象是染色质向大核原基中央集结成团,染色质团与核膜之间充满着匀质的核液。当中央染色质团伸长时,又将     

Scheduled and unscheduled DNA synthesis during development in conjugating Tetrahymena

Autoradiography has been used to confirm and to extend previous microspectrophotometric studies (Doerder and DeBault, 1975) on the timing of DNA synthesis during conjugation in Tetrahymena thermophila. The majority of DNA synthesis occurs at the expected periods preceding gamete formation and the two postzygotic divisions and during macronuclear development. DNA in new macronuclei is endoreplicated in an extremely discontinuous fashion. Under starvation conditions, the first endoreplication (2C to 4C) occurs immediately after the second postzygotic division when both new macronuclei and new micronuclei replicate. The second endoreplication (4C to 8C) does not occur until after separation of conjugants. If mating cells are kept under prolonged starvation conditions (20-24 hr), refeeding induces a partially synchronous division, after which an unexpectedly high percentage of cells incorporate tritiated thymidine into both macro- and micronuclei. Two previously undescribed periods of DNA synthesis were observed in the micronuclei of conjugating Tetrahymena. The first occurs during the early stages of meiotic prophase, before full crescent elongation. The second takes place in an extended period corresponding to macronuclear anlagen development, before conjugants have separated. CsCl gradient analyses indicate that, in micronuclear fractions, only main band DNA is being synthesized in both of these periods. However, in macronuclear fractions from both stages, a significant fraction (approximately 20%) of the DNA being synthesized has the buoyant density of ribosomal DNA. The finding that macro- and micronuclear DNA can be synthesized simultaneously in a single cell, both during conjugation and after refeeding starved exconjugants, raises interesting questions of how macro- or micronuclear-specific histones are targeted to the appropriate nuclei.     

Nuclear Behavior of Spirostomum ambiguum During Conjugation with Special Reference to Macronuclear Development*

SYNOPSIS. During conjugation in Spirostomum ambiguum, the micronuclei divide thrice before synkaryon formation and 20 times thereafter. During the first meiotic division 18-24 bivalents, each about 0.5 μ or less appear on the spindle. They separate and pass to the poles. The details of the 2nd and 3rd prezygotic divisions and synkaryon formation by reciprocal exchange of gametic nuclei resemble those described for other ciliates in the literature. The synkaryon divides twice resulting in 4 nuclei; 2 of them become micronuclei and the remaining 2 macronuclear anlagen. The micronuclei enter into division, but this division is arrested in metaphase. The chromosomes in the macronuclear anlagen resemble those appearing in the Ist meiotic division in shape and size. In their maximum stage of development the macronuclear chromosomes are at least 3-4 times larger than those appearing in the arrested micronuclear metaphases in the same cell. There is no banding pattern of the chromosomes and therefore the possible extent of polyteny is difficult to evaluate. The chromosomes duplicate 3-4 times resulting in about 200–250 before they become indistinct as separate entities. Spirostomum is the only nonhypotrichous ciliate in which these cytologic features are described.     

Abortive conjugation induced by UV-B irradiation at meiotic prophase in Tetrahymena thermophila

Conjugating Tetrahymena were irradiated by ultraviolet-B (UV-B) at various stages of conjugation. When the conjugants were exposed to the UV-B at late meiotic prophase (the stage from pachytene to diplotene), abortive conjugation was induced at high frequencies. After completing meiosis, a significant number of the conjugants showed marked anomalies, i.e., failure of nuclear selection after meiosis, and abortion of the subsequent conjugation process such as a postmeiotic division to form gametic nuclei, nuclear exchange, synkaryon formation, and postzygotic development. The conjugating pairs retained the parental macronucleus and separated earlier as compared with a control. The resultant exconjugants degenerated meiotic products and became amicronucleates. These observations strongly suggest the presence of a UV-sensitive molecule that is expressed specifically at the meiotic prophase and that directs the subsequent development after meiosis. Dev. Genet. 23:151–157, 1998. © 1998 Wiley-Liss, Inc.     

Dynamic behaviour of stationary pronuclei during their positioning in Paramecium caudatum

During conjugation of Paramecium caudatum, there are two well-known stages when nuclear migration occurs. What happens to the nuclei is closely related to their localisations in cells. The first of these stages is the entrance of one meiotic product into the paroral region. This nucleus survives, while the remaining three outside this area degenerate. The second stage is the antero-posterior localisation of eight synkaryon division products. Four posterior nuclei are differentiated into macronuclear anlagen, whereas four anterior nuclei remain as the presumptive micronuclei. In this experiment, the process of the third prezygotic division of P. caudatum was studied with the help of protargol staining. Here, a third nuclear migration was discovered. By two spindle turnings and two spindle elongations, stationary pronuclei were positioned near migratory pronuclei. This positioning of stationary pronuclei could shorten the distance for transferred migratory pronuclei to recognise and reach the stationary pronuclei. This fosters the synkaryon formation of P. caudatum.     

Macronuclear development in conjugants of Tetrahymena thermophila, which were artificially separated at meiotic prophase

Conjugant pairs of Tetrahymena thermophila were mechanically separated by vigorous pipetting at the early stages of meiotic prophase. The complete sequence of conjugational nuclear events including the appearance of pronuclei, development of the new macronuclei (postzygotic development), and resorption of the old macronuclei was observed in the separated cells, without pronuclear exchange. The pronuclei in the separated cells were recognised by the presence of components of the extranuclear cytoskeleton, which were labelled with anti-tubulin and anti-fenestrin antibodies in the same way as in undisturbed conjugants. The apical region of the separated conjugants (the post-junction area), corresponding to the junction area of conjugants was labelled with anti-fenestrin antibody and maintained the properties required for the nuclear development. The results of the genetic study were consistent with a hypothesis that cytogamy (pronuclear fusion) was induced in the separated conjugants. Therefore, the lasting cell contact is not necessary for the successful completion of conjugational nuclear events.     

Disturbance of the determination of germinal and somatic nuclei by heat shock in Paramecium caudatum

During conjugation of Paramecium caudatum, nuclear determination occurs soon after the third postzygotic division: one of the four anterior nuclei becomes the micronucleus and the remaining three degenerate, while four posterior nuclei differentiate into macronuclear anlagen. Macronuclear differentiation is supposed to be dependent on a cytoplasmic differentiation factor. In this study, postzygotic cells were subjected to heat shock for 30 min and nuclear changes were observed by staining with carbol fuchsin solution. When heat shock was initiated during the period from metaphase to telophase of the third postzygotic division, cells showed an excess of macronuclear anlagen and were typically amicronucleate. Abnormal nuclear localization around the end of the third (last) postzygotic division may explain the origin of these kinds of cells. A similar phenomenon appeared after treatment with actinomycin D or emetine. Since heat shock did not inhibit macronuclear differentiation but destroyed the formation of micronuclei, some factor(s) probably plays an essential role in nuclear determination, especially in the protection of the micronuclei.     

Analysis of nuclei from exponentially growing and conjugated Tetrahymena thermophila using the flow microfluorimeter

Isolated nuclei of Tetrahymena thermophila from both exponentially growing cultures and from cells following conjugation have been analysed using a flow microfluorimeter. The macronuclei from a culture in exponential growth display a single broad distribution of DNA contents, without bimodal character. The micronuclei are virtually all in G2 phase (4C). The mean of the macronuclear DNA distribution is about 12.4 times the micronuclear mean (50C). When cells are starved in preparation for conjugation, the macronuclei DNA content is decreased about 30%, but the distribution remains similar to that of nuclei from a culture in exponential growth. Following conjugation, the macronuclear anlagen develop through a set of relatively synchronous endoreplications. At 12 h after the initiation of conjugation the anlagen are at a 4C stage and at 18 h they are virtually all at a 8C stage. If the culture is refed, anlagen development progresses to a 16C and 32C, but the synchrony is poorly conserved. Cells that are not refed are arrested at the 8C stage and only a fraction of the population ever become mature macronuclei. In general we do not observe distinct peaks of anlagen with DNA contents in excess of 32C. The amitotic division of macronuclei may obscure any endoreplications producing anlagen stages with higher DNA content.     

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.     

Maternal effect mutations affecting macronuclear determination and development in Paramecium tetraurelia

Gene mutations that interfere with macronuclear development in Paramecium were obtained by selecting lines that failed to produce normal macronuclear anlagen following the second autogamy after mutagenesis. The mutants fell into several complementation groups. There was one case of apparent intragenic noncomplementation among the eight mutants examined. In the stronger mutants, macronuclear anlagen were not formed, and all four mitotic products of the posfzygotic divisions of the synkaryon remained as micronuclei. Under semirestrictive conditions, cells often contained a single anlage, suggesting that determination of anlagen was a discrete event for each nucleus. The missing anlagen trait was recessive and associated with a strong maternal effect. The phenocritical period of one of the stronger alleles, aal^a, began at the second postzygotic division and ended with the first morphological differentiation of macronuclear anlagen. Nuclear migration in this mutant was abnormal. Under restrictive conditions, the posterior products of the second postzygotic division reached a posterior-most position, which was 8% of cell length more anterior than that of the most posterior nuclei in wild-type cells. Under permissive conditions, the pattern of migration was intermediate between that of wild-type cells and mutants under fully restrictive conditions. The patterns of nuclear migration were consistent with the nuclear growth kinetics.     

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.     

Spatio-temporal reorganization of intracytoplasmic microtubules is associated with nuclear selection and differentiation during the developmental process in the ciliateTetrahymena thermophila

Summary Indirect immunofluorescence has revealed various intracytoplasmic microtubular structures, which are transiently polymerized in specific subcellular locations during the developmental process of conjugation in the ciliateTetrahymena thermophila. These structures include: (1) micronuclear spindles, (2) perimicronuclear microtubules, (3) microtubular baskets surrounding migrating pronuclei, and (4) microtubules interconnecting the pronuclei with the conjugants' junctional zone. Furthermore, a peripheral network of intracytoplasmic microtubules related to the cell cortex is present in both vegetative cells and in conjugants. Comparative observations made on cells undergoing normal conjugation and defective conjugation (occurring either spontaneously or induced by taxol) has revealed some rules governing the pattern of deployment of conjugation-specific microtubules. The presence of perinuclear microtubular arrays during early postmeiotic stages of development is strictly limited to more anteriorly located nuclei which includes the selected haploid nucleus that further divides to form the stationary and migratory pronuclei. These perinuclear microtubules may be involved in the positional control of nuclear fates leading to effective nuclear selection. Microtubular bundles associated with pronuclei and connecting the junctional zone are only formed in the presence of functional pronuclei, and may be involved in the guidance of pronuclei leading to their fusion. The mechanism of cytoplasmic control of nuclear differentiation of derivatives of the zygotic nucleus appear to be associated with a coordinate action of two microtubular arrays: spindle microtubules of the second postzygotic division and the peripheral intracytoplasmic network of microtubules, leading to a proper subcortical positioning of the postzygotic nuclei at opposite poles of the cell.Abbreviations MTs Microtubules     

Macronuclear Regeneration and Cell Division in Paramecium caudatum

SYNOPSIS. In Paramecium caudatum , occurrence of macronuclear regeneration is closely related to the time of feeding after conjugation. Macronuclear regeneration is induced with a high frequency when conjugating pairs are transferred into fresh culture medium. Feeding immediately after conjugation induces early cell division and 3 or more fissions occur without macronuclear division because of the inability of the macronuclear anlagen to divide. In the cells lacking normal macronuclear anlagen, old macronuclear fragments undergo regeneration and form vegetative macronuclei.     

Nuclear Differentiation in Exconjugants of Paramecium caudatum: Role of Nuclear Division in Differetiation

It has been known that, immediately after the third division of fertilization nucleus (synkaryon), nuclei localized near the posterior region of exconjugant are to be macronuclear anlagen and those near the anterior region are to be presumptive micronuclei in Paramecium caudatum. One of such posterior nuclei was transplanted into amicronucleate cell at vegetative phase in this work. The implanted nuclei were able to divide at every fission. Their DNA content was nearly equal to or less than ordinary micronuclei during vegetative phase. When conjugation was induced between clones obtained and amicronucleates, macronuclear anlagen developed from the division products of implanted nuclei and thereafter derivative caryonides were true to the marker gene of implanted nuclei. The results indicate that there was no intrinsic difference between nuclei localized anteriorly and those situated posteriorly in exconjugant. Differentiation of nuclei into macronucleus may be irreversible at the stage of anteroposterior localization of the nuclei. The role of nuclear division in differentiation may be only to transport the daughter nuclei into the cytoplasm/cortex differentiated anteroposteriorly.     

Genomic exclusion in Tetrahymena thermophila: A cytogenetic and cytofluorimetric study

Genomic exclusion is an aberrant form of conjugation of Tetrahymena thermophila in which the genome of a defective conjugant is excluded from the genotype of the exconjugant progeny. This paper is concerned with the cytogenetic and nucleocytoplasmic events of genomic exclusion in senescent clones A*III and C*. In crosses between A*III or C* and strain B, functional, haploid gametic nuclei are formed only in the strain B cell. In some instances one of the gametic nuclei divides prior to transfer of the migratory gametic nucleus, and both products then undergo DNA synthesis. Two alternative cytogenetic pathways are followed after transfer of the migratory nucleus. In the first, the conjugants separate without further micronuclear divisions. This pathway was most common in A*III genomic exclusion. In exconjugants the former gametic nuclei undergo both DNA synthesis and (presumably) intranuclear separation of centromeres to restore micronuclear diploidy. The old macronucleus of each exconjugant is retained without autolysis. This class of exconjugant survives and contributes genes to future sexual progeny. In the second cytogenetic pathway the gametic nuclei divide and macronuclear anlagen are formed, as in normal conjugation. This pathway was more common in C* genomic exclusion. The initial DNA content of the anlagen ranges from haploid to diploid. Following two to three rounds of DNA synthesis, further macronuclear development ceases and the anlagen appear to undergo autolysis. The old macronucleus condenses and also undergoes autolysis, as in normal conjugation. Except for rare C* exconjugants, in which macronuclear development is completed, anlagen-bearing genomic exclusion exconjugants die. Death may be caused by aneuploidy, errors in the timing or receptivity to signals for autolysis, or the inability of anlagen-bearing exconjugants to feed. Anlagenbearing conjugants are frequently abnormal with respect to the number of anlagen and micronuclei. Most of the anomalies can be explained by postulating errors in the timing of both developmental signals and nuclear divisions. Rare conjugants in which gametic nuclei divide but do not give rise to macronuclear anlagen are also observed. In these instances, the old macronuclei condense and undergo autolysis. Destruction of the old macronucleus therefore is independent of the presence of macronuclear anlagen and requires cell pairing in order to be initiated.     

Studies on Conjugation in Paramecium polycaryum

SYNOPSIS. The process of autogamy in unassociated individuals of Paramecium polycaryum was reported by the author in 1954. In May, 1955, conjugation was first seen in this species in cultures collected by me at Annamalainagar, South India, thus removing it from the list of non-conjugating species. This appears to be the first instance in which the process of autogamy was detected prior to observation of conjugation in the same species. Autogamy occurs in singles of the Indian race and appears to be similar, cytologically, to that of American races. The details of the micronuclear behavior in conjugation parallel those of autogamy in singles. In fact, the conjugation process seems to be one of double autogamy (cytogamy), rather than of reciprocal gametic interchange. Paroral cones, often of fair size, are formed but breakdown of the cones to permit micronuclear passage has not been observed. In conjugation there are the usual three pregamic divisions; the first shows four characteristic crescents. The resulting nuclei may all participate in the second division. Fertilization occurs in the paroral cone area. Frequently, separation of the conjugants takes place immediately after the first division of the synkaryon. The old macronucleus undergoes very little change prior to the last postzygotic micronuclear division in the ex-conjugant, when it goes into a skein condition. Four macronuclear and four micronuclear anlagen are formed in the ex-conjugants at the completion of reorganization. On occasion giant individuals of P. polycaryum were observed to have ingested numbers of Tetrahymena pyriformis. The presence of an unidentified rod-like organism in the cytoplasm of the paramecia (non-conjugating) was detected in one collection from Bangalore, India.