Morphological apoptotic characteristics of the post-meiotic micronuclei in Paramecium caudatum

In a previous study, the apoptotic degeneration of meiotic products outside the paroral region of Paramecium caudatum was indirectly demonstrated by means of “apofluor” staining. In this experiment, conjugating pairs and exconjugants of P. caudatum were stained with either “apofluor” or carbol fuchsin or both to find some direct evidence to demonstrate the apoptotic characteristics of this process. As a result, asynchronous meiotic nuclear degeneration was observed. Furthermore, a number of additional meiotic nuclei were found. Disintegrating/dividing meiotic nuclei outside the paroral region were observed, which might be the origin of these additional meiotic nuclei. Condensed chromatin and disintegrated chromatin attached to the nuclear membrane were also observed in degenerating nuclei, which are the typical morphological characteristics of apoptosis. Comparison of the cells stained by the above two methods indicated that “apofluor”-stained meiotic nuclei could not be detected by carbol fuchsin in some cells, which suggests a time lag between meiotic nuclear DNA degradation and their eventual disappearance. In this study, some direct evidence was found to show that the meiotic nuclear degeneration in P. caudatum is of apoptotic nature, which further confirmed our previous study (Yang et al. 2007) and indicated that morphological apoptotic characteristics discovered in multicellular organisms do exist in unicellular eukaryotic ciliate protozoa.     

第四双小核草履虫减数分裂产物的退化特征分析

通过吖啶橙和Hoechst 33342两种活体荧光染料双染的方法对第四双小核草履虫(Paramecium tetraurelia)接合生殖过程中小核减数分裂产物进行观察,结果发现位于口旁锥外的小核分裂产物呈蓝绿色或黄绿色,表明它们以凋亡的方式发生退化.     

Mouse zygotes with one diploid pronucleus formed as a result of ICSI can develop normally beyond birth

A mouse spermatozoon was injected into mouse secondary oocytes (ICSI) in the vicinity of the metaphase spindle. In 22% of oocytes injected successfully, the maternal chromatin (the haploid chromatids formed after the second meiotic division) and paternal chromatin (from the sperm nucleus) were surrounded by a common nuclear envelope to form one diploid bi-parental pronucleus. However, the use of spermatozoa in which BrdU had been incorporated into DNA during spermatogenesis revealed, that maternal and paternal chromatin occupied two separate compartments within the one pronucleus. In the living state, the diploid pronucleus could be distinguished from a haploid one by its distinctly larger size and by a greater number of "nucleolus-like bodies"-criteria confirmed karylogically at the 1st cleavage division. Such zygotes with one diploid pronucleus were able to develop in vitro into blastocysts as often as those with two haploid pronuclei [11/29 (38%) vs. 14/35 (40%)]. Seventy nine 2-cell embryos developing in vitro from zygotes with one diploid pronucleus were transplanted to the oviducts of pseudopregnant recipients: two females had six foetuses when killed on the 17th day, and two females gave birth to nine young, eight of which survived and developed into normal fertile animals.     

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.     

Microtubules mediate germ-nuclear behavior after meiosis in conjugation of Paramecium caudatum

Microtubule dynamics in Paramecium caudatum were investigated with an anti-alpha-tubulin antibody and a microinjection technique to determine the function of microtubules on micronuclear behavior during conjugation. After meiosis, all four haploid micronuclei were connected by microtubular filaments to the paroral region and moved close to this region. This nuclear movement was micronucleus-specific, because some small macronuclear fragments transplanted from exconjugants never moved to the region. Only one of the four germ nuclei moved into the paroral cone and was covered by microtubule assembly (the so-called first assembly of microtubules, AM-I). This nucleus survived there, while the other three not in this region degenerated. The movement of germ nucleus was inhibited by the injection of the anti-alpha-tubulin antibody. The surviving germ nucleus divided once and produced a migratory pronucleus and a stationary pronucleus. Prior to the reciprocal exchange of the migratory nuclei, microtubules assembled around the migratory pronuclei again (the so-called second assembly of microtubules, AM-II). Then, the migratory pronucleus moved into the partner cell and fused with the stationary pronucleus. Thus, microtubules appear to be indispensable for nuclear behavior: they enable migration of postmeiotic nuclei to the paroral region and they permit the survival of the nucleus at the paroral cone.     

Haploid maternal genome derived from early diplotene oocytes can substitute for the female pronucleus in preimplantation mouse development

We describe the preimplantation development of mouse embryos that have received the haploid maternal genome derived from early diplotene nuclei of primordial oocytes (PO). Two generations of recipient egg-cells were used. Induction of two meiotic divisions of the PO nucleus and the reduction of the number of chromosomes to the haploid level were achieved in preovulatory oocytes (primary recipients). The developmental potential of the obtained haploid genome was examined in zygotes (secondary recipients). The nuclei of PO obtained from newborn mice were transferred by cell electrofusion to in vitro maturing (IVM) and enucleated preovulatory mouse oocytes. The reconstructed oocytes which had completed maturation, i.e., reached metaphase II, were artificially activated (8% ethanol + CHX). Activated oocytes were used as donors of haploid pronuclei of PO origin which were transferred (by karyoplast fusion) to partially enucleated zygotes containing only the male pronucleus. Thus, reconstituted zygotes were transplanted to the ligated oviducts of the cycling mice and 27% of them developed to the blastocyst stage. Our experiments demonstrate that 1) the nucleus of PO can be induced to premature meiotic divisions in an IVM enucleated preovulatory oocyte; 2) in the presence of a normal male pronucleus, the haploid pronucleus of PO origin can substitute for a female pronucleus during preimplantation development. Mol. Reprod. Dev. 48:488–495, 1997. © 1997 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.     

Naegleria fowleri: Light and electron microscopy study of mitosis

DAPI and Feulgen stains were used as specific DNA markers for studying the mitosis process in Naegleria fowleri. Both DAPI and Feulgen stains reacted with DNA in the nuclei of the amoebae. Representative figures of N. fowleri mitotic nuclei with a defined arrangement according to the phase of the cell cycle were observed. A notable characteristic is that the nucleolus is present throughout the stages of mitosis. During metaphase, several deeply stained DNA condensations following an elongated pattern were observed, corresponding almost certainly to tightly grouped chromosomes. Ultrastructural observations demonstrated that the nucleus divides by cryptomitosis, a process in which the nuclear membrane does not disappear during the mitosis. Centrioles were not found, and a spindle of microtubules was observed running the length of the nucleus from pole to pole however, they did not come to a focal point.     

DNA synthesis in the fertilizing hamster sperm nucleus: sperm template availability and egg cytoplasmic control

To assess the role of the availability of sperm nuclear templates in the regulation of DNA synthesis, we correlated the morphological status of the fertilizing hamster sperm nucleus with its ability to synthesize DNA after in vivo and in vitro fertilization. Fertilized hamster eggs were incubated in 3H-thymidine for varying periods before autoradiography. None of the decondensed sperm nuclei nor early (Stage I) male pronuclei present after in vivo or in vitro fertilization showed incorporation of label, even in polyspermic eggs in which more advanced pronuclei were labeled. In contrast, medium-to-large pronuclei (mature Stage II pronuclei) consistently incorporated 3H-thymidine. To investigate the contribution of egg cytoplasmic factors to the regulation of DNA synthesis, we examined the timing of DNA synthesis by microinjected sperm nuclei in eggs in which sperm nuclear decondensation and male pronucleus formation were accelerated experimentally by manipulation of sperm nuclear disulfide bond content. Although sperm nuclei with few or no disulfide bonds decondense and form male pronuclei faster than nuclei rich in disulfide bonds, the onset of DNA synthesis was not advanced. We conclude the the fertilizing sperm nucleus does not become available to serve as a template for DNA synthesis until it has developed into a mature Stage II pronucleus, and that, as with decondensation and pronucleus formation, DNA synthesis also depends upon egg cytoplasmic factors.     

The ability of dehydrated hamster and human sperm nuclei to develop into pronuclei.

To determine whether the nuclei of mature mammalian spermatozoa are resistant to dehydrated conditions, nuclei of hamster and human spermatozoa were freeze-dried or treated with various dehydrating agents before injection into hamster oocytes. Freeze-dried nuclei remained capable of developing into pronuclei even after 12 mo of storage at 4 degrees C. The level of DNA synthetic activity in the sperm (male) pronucleus was comparable to that in the egg (female) pronucleus. Sperm nuclei that had been stored in 100% ethanol, 100% methanol, or chloroform-methanol (2:1) mixture for 20 days were also capable of developing into pronuclei. Even the nuclei that had been dehydrated ("fixed") with Carnoy's fluid could develop into morphologically normal pronuclei. However, the level of DNA synthesis in the pronuclei derived from these chemically dehydrated nuclei was generally lower than that in the female pronuclei. Although the genetic integrity of the dehydrated sperm nuclei is yet to be determined, nuclei of mature hamster and human spermatozoa appear to be fairly resistant to dehydrated conditions.     

Lysosomal enzymes in the macronucleus of Tetrahymena during its apoptosis-like degradation

A key characteristic of apoptosis is its regulated nuclear degradation. Apoptosis-like nuclear degradation also occurs in the ciliated unicellular organism, Tetrahymena thermophila. Chromatin of the macronucleus undergoes massive condensation, a process that can be blocked by caspase inhibitors. The nucleus becomes TUNEL-positive, and its DNA is cleaved into nucleosome-sized fragments. In a matter of hours the macronucleus is completely degraded, and disappears. The condensed nucleus sequesters acridine orange, which means that it might become an acidic compartment. We therefore asked whether lysosomal bodies fuse with the condensed macronucleus to form an autophagosome. We monitored acid phosphatase (AP) activity, which is associated with lysosomal bodies but is not found in normal nuclei. We find that after the macronucleus condenses AP activity is localized in cap-like structures at its cortex. Later, after the degrading macronucleus loses much of its DNA, acid phosphatase deposits appear deeper within the nucleus. We conclude that although macronuclear elimination is initiated by an apoptosis-like mechanism, its final degradation may be achieved through autophagosomy.     

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."     

The formation of the pronuclei and their associated perinuclear cytoplasm; the determination of the phases of the first cleavage cycles in Crepidula fornicata (Mollusca,Gastropoda)

Summary

The behaviour of the male and the female pronuclei in Crepidula fornicata is studied, beginning at the formation of the second polar body. Shortly after the extrusion of the second polar body the female pronucleus is formed, and then the male pronucleus enters the yolk-free cytoplasm near the animal pole. Both pronuclei are enveloped by a typical nuclear membrane, and increase in size until the prophase; a zygote nucleus is not formed (“Ascaris type” of fertilization). In the meantime, the chromatin of both pronuclei is arranged in a meshwork in the centre of the pronuclei.

Shortly after the formation of the second polar body a special cytoplasm, the “perinuclear cytoplasm”, is formed in the vicinity of each of the pronuclei. During the early stages of the first cleavage cycle this cytoplasm is composed of numerous Golgi complexes, small dense Golgi vesicles, smooth endoplasmic reticulum vesicles, mitochondria and rosettes of glycogen-like granules. At later stages, when the pronuclei have met and their plasms coalesced, the number of Golgi elements decreases; at the same time, the small dense Golgi vesicles increase in number and aggregate in clusters.

The phases of the first three cleavage cycles are determined by cytophotometry. The nuclear DNA of the male pronucleus and that in the nuclei of the blastomeres of the 2- and the 4-cell stage is reduplicated between 7 and 33% of the normalized cleavage cycles; the G₂-phase is between 33 and 57%, while the mitotic phase occupies the last part of each cleavage cycle and the first 7% of the next cleavage cycle. There is no G j-phase. Since the female pronucleus lies just beneath the polar bodies, its DNA content could not be measured separately.     

THE EFFECTS OF NICOTINE ON FERTILIZATION IN THE SEA URCHIN, ARBACIA PUNCTULATA

The number of sperm incorporated into eggs made polyspermic with varying concentrations of nicotine (0.025–0.25%, v/v) appears to be directly related to the concentrations employed. The cortical response is morphologically equivalent to that observed in control preparations. Shortly after their incorporation all of the spermatozoa undergo structural events normally associated with the development of the male pronucleus in monospermic eggs. During the reorganization of the spermatozoa, sperm asters are formed. The number of male pronuclei that initially migrate to and encounter the female pronucleus is usually one to three. When pronuclei come into proximity to one another the surface of the female pronucleus proximal to the advancing male pronuclei flattens and becomes highly convoluted. Subsequently, the pronuclei contact each other and the outer and inner membranes of the pronuclear envelopes fuse, thereby producing the zygote nucleus. The male pronuclei remaining in the zygote after this initial series of pronuclear fusions continue to differentiate, i.e. they enlarge, form nucleolus-like bodies, and undergo further chromatin dispersion. In approximately 90% of the zygotes, all of the remaining male pronuclei progressively migrate to the zygote nucleus and fuse to form one large nucleus by 80 min postinsemination. Mitosis and cleavage of the polyspermic zygote occurs later than in monospermic eggs.     

Early Embryogenesis and Anterior-Posterior Axis Formation in the White-Tip Nematode Aphelenchoides besseyi (Nematoda: Aphelenchoididae)

We followed the early embryogenesis of Aphelenchoides besseyi from fertilization to the 4-cell stage under Nomarski optics and examined the chromosome number and structure by DAPI staining. After an oocyte is fertilized by a sperm, the eggshell forms and the male and female pronuclei are reconstructed. The male pronucleus moves toward the female pronucleus, which is located at the center of the egg. They meet, rotate 90°, and fuse. The embryo then divides unequally into a larger anterior AB cell and a smaller posterior P(1) cell. The site of sperm entry into the oocyte seems to become the future anterior pole of the embryo, and thus the formation of an anterior-posterior axis formation is the same as that for Bursaphelenchus xylophilus, but opposite to that for Caenorhabditis elegans. From immunostaining, the fertilizing sperm appears to bring the centrosome into the oocyte. The chromosome structure during the pronuclear meeting as observed by DAPI staining suggests that a haploid sperm (N = 3) fertilizes a haploid oocyte (N = 3) to form a diploid embryo (2N = 6) and that all chromosomes appear to be of a similar size. Unlike C. elegans does, the P(1) cell first divides anterior-posteriorly followed by the AB anterior-posteriorly. These divisions produced the 4-cell stage embryo with 4 cells arranged in a linear fashion, again in contrast to that for C. elegans or B. xylophilus configured in a rhomboid shape.     

Remodelling of thymocyte nuclei in activated mouse oocytes: an ultrastructural study

Oocyte-thymocyte mouse cell hybrids were produced using polyethylene glycol (PEG) and examined at the ultrastructural level. Fusion was accomplished either before or after activation of metaphase II oocytes. In both experimental variants thymocyte nuclei undergo remodelling which comprises the following sequence of events: nuclear envelope breakdown, initial chromatin condensation, and subsequent decondensation, nuclear envelope reformation and formation of nucleoli. In hybrids produced before oocyte activation but activated within a short time and cultured for several hours the thymocyte nuclei become identical to the female pronucleus. In the second variant (fusion with activated oocytes) the degree of remodeling of thymocyte nuclei is variable. Our observations demonstrate that between metaphase II, telophase of meiosis and early female pronuclear stages the mouse oocyte contains all "factors" necessary for remodelling of differentiated somatic nuclei and their development as if they were pronuclei.