Stomatogenesis during sexual and asexual reproduction in an amicronucleate strain of Paramecium caudatum.

Amicronucleate cells of Paramecium caudatum, whose micronuclei have been artifically removed by micropipetting, are characterized by the appearance of a deciliated area at the posterior part of the buccal opening. These cells form food vacuoles at a slightly lower rate than micronucleate cells. Their mean interfission time is longer than that in micronucleates. The exconjugants of amicronucleate cells can not form food vacuoles and eventually die witout fission, though conjugation proceeds normally in them as well as in their micronucleate mate. The oral apparatus of amicronucleate exconjugants seems to be shallower than that of micronucleates. The membranellar cilia, therefore, can be seen through the buccal overture by scanning electron microscope. The results obtained from the cross of micronucleate and amicronucleate strains and from the induction of autogamy in amicronucleate strains suggest that the micronucleus has a primary role in developing the normal oral apparatus after nuclear reorganization.     

The somatic function of the micronucleus in asexual reproduction of Paramecium: thermosensitivity of amicronucleates

It has been established that following removal of the micronucleus in Paramecium tetraurelia, the amicronucleate cell line enters a depression period, characterized by slow growth rate and oral abnormalities, at normal growth temperature (27°C). Such cell lines gradually recover in growth rate and stomatogenesis. In the present study, 4 recovered amicronucleate cell lines were challenged with high temperatures (35°C, 36°C, and 36.5°C). They exhibited growth rate reduction and abortive cytokinesis at 35°C and 36°C, and died at 36.5°C. In addition, they demonstrated oral defects similar to those observed in the depression period: disruption of the regular oral membranellar pattern, reduction in the length of the oral apparatus, and impaired phagocytosis (food vacuole formation). These high temperature-induced abnormalities were largely restricted to amicronucleates, and were rare or seen to a much lesser extent in sister micronucleate cell lines. This study demonstrates the participation of the micronucleus in conferring thermotolerance on the cells. It is hypothesized that the micronucleus specifies heat-shock proteins to maintain the integrity of oral and somatic cytoskeletal elements at high temperature.     

Analysis of germinal aging in Paramecium caudatum by micronuclear transplantation

The role of the micronucleus in the age-dependent increase in mortality after conjugation in Paramecium has been investigated using micronuclear transplantation. The clone of Paramecium caudatum used for this study had a lifespan of about 750 fissions. In this clone, the fission rate began to decrease about 450 fissions after conjugation. Mortality after selfing conjugation also began to appear at about 450 fissions and gradually increased with clonal age. Cells at about 650 fissions showed 10–70% survival after selfing conjugation but when their micronuclei were transplanted into amicronucleate cells of about 450 fissions, the progeny survival increased to 70–90%. When micronuclei from cells 700–750 fissions old were transplanted into amicronucleate cells of 100–150 fissions, however, increase in progeny survival was very rare. The results indicate that micronuclei in cells up to the age of 650 fissions can function normally if the cytoplasmic environment is young.     

Nuclear functions in postconjugational development of Paramecium caudatum: Ability to form food vacuoles analyzed by nuclear elimination and implantation

Paramecium caudatum loses the ability to form food vacuoles at the crescent stage of the micronucleus from 5 to 6 hr after the initiation of conjugation and regains it immediately after the third division of the zygotic nucleus. To assess the micronuclear function in the development of the oral apparatus after coniugation, prezygotic micronuclei was removed from cells at various stages of conjugation, and their ability to form food vacuoles were examined. (1) When all of the prezygotic micronuclear derivatives were eliminated before the stage of formation of the zygotic nucleus, the exconjugant did not regain its ability. (2) When a zygotic nucleus or postzygotic nuclei were removed, in some cases the cell formed as many food vacuoles as did nonoperated cells after conjugation, while in other operated cells the number of food vacuoles was subnormal. (3) When a micronucleus from a cell at vegetative phase (G1) was transplanted into a cell of an amicronucleate mating pair at the stage between 8 and 9 hr after the initiation of conjugation, the implanted cell regained the ability to form food vacuoles. However, no cell regained the ability when the implantation was carried out within 1 hr after the separation of the mates. The results show that the micronucleus plays an indispensable role in the development of the oral apparatus at the stages of exchange of gametic nuclei and fertilization and that the micronucleus transplanted from asexual cells can fulfill this function. On the other hand, removal of the macronucleus from exconjugants showed that the maternal macronucleus also has an indispensable function in regaining the ability to form food Vacuoles. © 1992 Wiley-Liss, Inc.     

Repetitive Micronuclear Divisions in the Absence of the Macronucleus During Conjugation of Paramecium caudatum

ABSTRACT. The germinal micronucleus divides six times during conjugation of Paramecium caudatum : this includes two meiotic divisions and one mitosis of haploid nuclei during mating, and three mitoses of a fertilization nucleus (synkaryon). Microsurgical removal of the macronucleus showed that micronuclei were able to divide repeatedly in the absence of the macronucleus, after metaphase of meiosis I of the micronucleus and also after synkaryon formation. When the macronucleus was removed after the first division of synkaryon, in an extreme case the synkaryon divided five times and produced 32 nuclei, compared to three divisions and eight nuclei produced in the presence of the macronucleus. Treatment with actinomycin D (100 μ /ml) inhibited the morphological changes of the macronucleus during conjugation and induced a multimicronucleate state in exconjugants. However, in other cells, it induced production of a few giant micronuclei. We conclude that the micronucleus is able to undergo repeated divisions at any stage of conjugation in the absence of the macronucleus once the factor(s) for induction of the micronuclear division has been produced by the macronucleus. The macronucleus may also produce a regulatory factor required to stop micronucler division.     

Persistence of Oral Structures in the Sexual Process of Amicronucleate Paramecium tetraurelia

ABSTRACT In the sexual process, amicronucleate Paramecium tetraurelia , unlike micronucleates, fail to produce an oral apparatus, but resorb the pre-existing one. Exceptions were found in some amicronucleate cell lines in which about 1% of the cells possessed oral structures, including pieces of oral membranelles, sometimes complete with buccal cavity, after autogamy or conjugation. By following oral development in the sexual process in some detail, the present study supports the view that these oral structures are derived from the pre-existing oral apparatus and not newly developed from the oral primordium. The possible involvement of the micronucleus and the pre-existing oral apparatus in oral resorption is discussed. The possession of a functional oral apparatus after the sexual process may open up a new evolutionary avenue to the amicronucleates.     

The Somatic Function of the Germ Nucleus in Pseudourostyla cris tat a: Asexual Reproduction and Stomatogenesis

The micronuclei of the ciliated protozoan Pseudourostyla cristata were eliminated by amputation shortly before binary fusion. The amicronucleate cell lines derived from regenerants were maintained for more than a year. They exhibited a lower viability and reduced vigor in asexual propagation. There was some improvement in the growth of the cell lines 1 mo after operation, but the growth rate remained subnormal even up to 1 yr of culture. The exact cause of the poor growth and survival in the first 3 wk after operation, whether the loss of the micronucleus or operational damage, remains to be determined. It is nevertheless clear that the micronucleus is important for subsequent asexual propagation. The amicronucleate cell lines were permanently crippled in morphogenesis, unlike the situation in Paramecium amicronucleates in which stomatogenesis returned to near-normal during asexual propagation. They always included some cells with a characteristically defective adoral zone of membranelles, reduced number of frontal-ventral-transverse cirri, and reduced body length. They were also reluctant to encyst. It is evident that the micronucleus is important for maintaining normality of the oral apparatus. It is postulated that the permanent stomatogenic crippling of amicronucleates might be related to genomic reduction in the developing macronucleus in sexual reproduction, as exhibited by other hypotrichs. The morphological defects associated with the adoral zone of membranelles may be rationalized as arising from the spreading of a zone of degeneration in the cortex affecting the left edge of the membranelles.     

Genetic Analysis of Mating Type Differentiation in PARAMECIUM TETRAURELIA. II. Role of the Micronuclei in Mating-Type Determination

The two complementary mating types, O and E, of Paramecium tetraurelia are normally inherited cytoplasmically. This property has generally been interpreted to indicate the presence of cytoplasmic factors that determine macronuclear differentiation towards O or E. In these macronuclear-cytoplasmic interactions, the micronuclei were held to be unbiased and the determination to be established in the course of macronuclear development. In order to ascertain whether the micronuclei were actually neutral, amicronucleate clones were needed and a method to produce them was developed. In crosses between amicronucleate clones and normal micronucleate clones, we have observed regular deviations from cytoplasmic inheritance: the commonest deviation is that most O amicronucleate cells become E when they receive a micronucleus from an E partner. The data can be interpreted by assuming that the micronuclei are predetermined and that the apparent "cytoplasmic" inheritance of the two mating types is due, in E cells, to E-determining factors present in the cytoplasm and in the nucleus; and, in O cells, to O-determining factors present only or mainly in the nucleus.     

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.     

Holospora elegans-Infected Micronuclei of Paramecium caudatum Still Serve a Function During Vegetative Life1

The fission rate of Paramecium caudatum cells infected with the micronucleus-specific bacterium Holospora elegans was examined before and after elimination of the micronucleus. Uninfected cells, micronucleate and amicronucleate, were used as controls. Emicronucleation of Holospora elegans-infected cells causes a decrease of fission rates, as is observed after emicronucleation of uninfected cells. This is taken as an argument that infected micronuclei still serve a function for the vegetative life of P. caudatum.     

Selection of the germinal micronucleus in Paramecium caudatum: nuclear division and nuclear death

Each cell of Paramecium caudatum has a germinal micronucleus. When a bi-micronucleate state was created artificially by micronuclear transplantation, both micronuclei divided for at least 2 cell cycles after nuclear transplantation. However, this bi-micronucleate state was unstable and reduced to a uni-micronucleate state after several fissions. Although the number of micronuclei was usually 1 during the vegetative phase, 4 presumptive micronuclei differentiated after conjugation. At the first post-conjugational fission, only 1 of the 4 micronuclei divided, indicating that there is tight regulation of micronuclear number in exconjugants. Micronuclei that did not divide at the first post-conjugational fission may persist through the first and second post-conjugational cell cycles. The decision to divide appears to be separate from the decision to degenerate, as evidenced by division of a remaining micronucleus upon removal of the dividing micronucleus at the first division. Degeneration of micronuclei in exconjugants differs from that of haploid nuclei after meiosis. Nutritional state affected micronuclear degeneration. Under well-fed conditions, the micronuclei destined to degenerate lost the ability to divide earlier than after starvation treatment, suggesting that micronuclear degeneration is an "apoptotic" phenomenon, probably under the control of the new macronuclei (macronuclear anlagen).     

Nuclear transplant studies of the determination of mating type in germ nuclei of Paramecium tetraurelia

The micronucleus from vegetative cells of one mating type (O or E) in Paramecium tetraurelia was transplanted by micropipet into amicronucleate cells of opposite mating type (E or O). When autogamy was induced in the recipient cells, they developed new macronuclei and micronuclei derived from the transplanted micronucleus and usually expressed the same mating type as the recipients. The results indicate that micronuclei in the asexual phase may be undetermined for mating type. Recipient E cells in which the macronucleus had been previously removed were transplanted with a whole macronucleus from an O cell. Their mating type was soon transformed E to O before the occurrence of autogamy, and remained O after autogamy. This demonstrates that the transplanted macronucleus determined the O cytoplasmic state to determine the developing zygotic macronucleus for mating type O. It is unlikely that the micronucleus is determined for mating type in O or E cell during the asexual cycle.     

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.     

Interactions between newly developed macronuclei and maternal macronuclei in sexually immature multinucleate exconjugants of Paramecium caudatum

The macronucleus of Paramecium caudatum controls most cellular activities, including sexual immaturity after conjugation. Exconjugant cells have two macronuclear forms: (1) fragments of the maternal macronucleus, and (2) the new macronuclei that develop from the division products of a fertilization micronucleus. The fragments are distributed into daughter cells without nuclear division and persist for at least eight cell cycles after conjugation. Conjugation between heterokaryons revealed that the fragmented maternal macronuclei continued to express genetic information for up to eight cell cycles. When the newly developed macronucleus was removed artificially within four cell cycles after conjugation, the clones regenerated the macronuclear fragments (macronuclear regeneration; MR) and showed mating reactivity, because they were sexually mature. However, when the new macronucleus was removed during later stages, many MR clones did not show mating reactivity. In some extreme cases, immaturity continued for more than 50 fissions after conjugation, as seen with normal clones that had new macronuclei derived from a fertilization micronucleus. These results indicate that the immaturity determined by the new macronucleus is not annulled by the regenerated maternal macronucleus. Mature macronuclear fragments may be "reprogrammed" in the presence of the new macronucleus, resulting in their expression of "immaturity."     

Evidence for Micronuclear Function During Vegetative Growth and Reproduction of the Ciliate, Tetrahymena pyrijormis

An amicronucleate clone of Tetrahymena pyrijormis has been found among the asexual progeny of irradiated cells of strain EU 6000 (variety 6, mating type I). Log-phase cells of this clone, designated EU 6525, have a mean generation time (6.0 hr) longer than that of the micronucleate strain, EU 6000 (2.9 hr). Further irradiation studies of strain EU 6000 indicate that the recovery of viable amicronucleate populations is rare although many amicronucleate cells are found among surviving progeny.¹ Attempts to introduce micronuclei into amicronucleate cells of strain EU 6525 by conjugation have been made. Micronucleate lines are obtained from amicronu create pair members only in low frequency. These results, considered together with those of other workers, suggest that some change in the state of the cell, additional to the physical loss (or gain) of the micronucleus, must occur before viable amicronucleate clones can be obtained from micronucleate cells, or before amicronucleate cells can produce viable micronucleate lineages. An alteration in mean generation time may be a reflection of this change, or it may simply be a direct consequence of micronuclear removal. The results further imply that the ciliate micronucleus unquestionably contributes information to the cell during asexual growth and reproduction.     

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.     

Proliferation and differentiation of chick skeletal muscle cells cultured in a chemically defined medium

By using the technique of nuclear transplantation in Paramecium [1], amicronucleate and renucleate clones were prepared in P. caudatum. The major differences between amicronucleate and micronucleate cells in the vegetative stage are elongation of cell cycle time, decrease in food vacuole formation, and shortening of the buccal cavity in the amicronucleate cells. These characteristics of amicronucleate cells are closely related with the absence of micronucleus, because all of these abnormalities were cured when the micronucleus was transplanted again into the amicronucleate. It is evident that the germinal micronucleus plays an important role not only during the sexual cycle but also in vegetative growth. Elongation of the cell cycle time in amicronucleates was also observed in P. bursaria and P. jenningsi.     

Behavior of germinal micronuclei under control of the somatic macronucleus during conjugation in Paramecium caudatum.

In conjugating pairs of Paramecium caudatum, the micronuclear events occur synchronously in both members of the pair. To find out whether micronuclear behavior is controlled by the somatic macronucleus or by the germinal micronucleus, and whether or not synchronization of micronuclear behavior is due to intercellular communication between conjugating cells, the behavior of the micronucleus was examined after removal of the macronuclei from either or both cells of a mating pair at various stages of conjugation. When macronuclei were removed from both cells of a pair, micronuclear development was arrested 1 to 1.5 hr after macronuclear removal. When the macronucleus of a micronucleate cell mating with an amicronucleate cell was removed later than 3 to 3.5 hr of conjugation, that is, an early stage of meiotic prophase of the micronucleus, micronuclear events occurred normally in the operated cell. These results suggest that most micronuclear events are under the control of the macronucleus and that the gene products provided by the macronucleus are transferable between mating cells. One such product is required for induction of micronuclear division and is provided just before metaphase of the first meiotic division of the micronucleus. This factor is effective at a lower concentration in the cytoplasm and/or is more transferable between mating cells than the factors required for other stages. This factor, which seems to be present at least until the stage of micronuclear disintegration, is able to induce repeated micronuclear division as long as it remains active. The factor can act on a micronucleus which has not passed through a meiotic prophase. Moreover, the results suggest the existence of a second factor which is provided by the macronucleus after the first meiotic division that inhibits further micronuclear division.     

Nuclear Differentiation in Paramecium caudatum: Analysis by the Monoclonal Antibody against a Micronuclear Antigen

I obtained the monoclonal antibody 93A against a micronuclear antigen of the ciliate Paramecium caudatum . Immunocytochemical observations showed that the antigen 93A appeared in some portion of the micronucleus in every stage of life cycle. In dividing micronuclei, the antigen appeared mainly in their both poles and in fibrous structures between the poles. These results suggest that the micronuclear antigen 93A may be a component of microtubule organizing center and spindles. During nuclear differentiation in P. caudatum , four among eight postzygotic micronuclei differentiate new macronuclear anlagen and one becomes a new micronucleus and the remaining three degenerate. The micronuclear antigen 93A appeared in all of the eight nuclei in the early stage of macronuclear differentiation but then disappeared in the four macronuclear anlagen and eventually persisted only in the new micronucleus, showing that the newly developing macronuclear anlagen lose the micronuclear antigen 93A during their differentiation.