Interactions between metaphase and interphase factors in heterokaryons produced by fusion of mouse oocytes and zygotes

The cytoplasmic factor responsible for chromosome condensation was introduced into mouse zygotes at different times after fertilization by fusion of the zygotes with metaphase I oocytes. In 72% of heterokaryons obtained after fusion of early zygotes (14-18 hr post-human chorionic gonadotrophin (HCG) with oocytes, the male and female pronuclei of the zygote decondensed. At the same time, the oocyte chromosomes became enclosed in a nuclear envelope and decondensed to an interphase state. However, in the rest of the heterokaryons, the chromatin of the pronuclei condensed to metaphase chromosomes, thus resulting in three sets of chromosomes. Fusion of zygotes that had begun DNA synthesis (20-22 hr post-HCG) with oocytes induced chromosome condensation of the pronuclei in 76% of the cases. In some heterokaryons, however, the oocyte chromosome decondensed to an interphase state similar to the zygote pronuclei. Fusion between late zygotes (27-29 hr post-HCG) with oocytes resulted in chromosome condensation of the pronuclei in all heterokaryons. On the basis of these results, the formation of the pronuclei and their progression toward mitosis in the zygote may be explained by changing levels of a metaphase factor in the cell, or by a balance between interphase and metaphase factors.     

Membrane-mediated changes in the structure of chromosomes

In the present paper the interaction of metaphase chromosomes and chromatin with model and natural lipid membranes was studied. It was shown that chromatin and chromosomes are able to form complexes with membranes in the presence of divalent cations. In such complexes, the typical structure of chromosomes is altered. The character of this alteration in chromosomal structure was investigated with the use of electron microscopy and chemical modification with dimethylsulphate (DMS). The latter is possible because, according to the presented data, the condensation of chromatin into chromosomes is associated with a decrease in accessibility of N-3 in adenine (the protection of the minor groove of DNA) to modifications, and with an increased methylation of N-1 in adenine (the disarrangement of the secondary structure of DNA). It was shown that the interaction of chromosomes with liposomes provides various levels of unfolding up to the appearance of chromatin-like structures. The secondary DNA structure of decondensed chromosomes coincides with the secondary structure of chromosomal but not chromatin DNA, whereas the extent of shielding of the minor groove of DNA in such decondensed structures typical for chromatin DNA. It is possible to suggest that the chromosomal decondensation in telophase of mitosis is initiated by the action of a membrane component of the developing nuclear envelope.     

Chromatin and microtubule organisation in maturing and pre-activated porcine oocytes following intracytoplasmic sperm injection

Chromatin and microtubule organisation was determined in maturing and activated porcine oocytes following intracytoplasmic sperm injection in order to obtain insights into the nature of sperm chromatin decondensation and microtubule nucleation activity. Sperm chromatin was slightly decondensed at 8 h following injection into germinal vesicle stage oocytes. Sperm-derived microtubules were not seen in these oocytes. Following injection into metaphase I (MI)-stage oocytes, sperm chromatin went to metaphase in most cases. A meiotic-like spindle was seen in the sperm metaphase chromatin. In a few MI-stage oocytes, sperm chromatin decondensed at 8 h after injection, and a small sperm aster was seen. Sperm injection into oocytes at 5 h following activation failed to yield pronuclear formation. Maternally derived microtubules were organised near the female chromatin in these oocytes, and seemed to move condensed male chromatin closer to the female pronucleus. At 18 h after sperm injection into pre-activated oocytes, a condensed sperm nucleus was located in close proximity to the female pronucleus. These results suggest that the sperm nuclear decondensing activity and microtubule nucleation abilities of the male centrosome are cell cycle dependent. In the absence of a functional male centrosome, microtubules of female origin take over the role of microtubule nucleation for nuclear movement.     

Common pathway of chromosome condensation in Mammalian cells

Chromatin folding in the interphase nucleus is not known. We compared the pattern of chromatin condensation in Indian muntjac, Chinese hamster ovary, murine pre B, and K562 human erythroleukemia cells during the cell cycle. Fluorescent microscopy showed that chromosome condensation follows a general pathway. Synchronized cells were reversibly permeabilized and used to isolate interphase chromatin structures. Based on their structures two major categories of intermediates were distinguished: (1) decondensed chromatin and (2) condensed chromosomal forms. (1) Chromatin forms were found between the G1 and mid-S phase involving veil-like, supercoiled, fibrous, ribboned structures; (2) condensing chromosomal forms appeared in the late-S, G2, and M phase, including strings, chromatin bodies, elongated pre-chromosomes, pre-condensed chromosomes, and metaphase chromosomes. Results demonstrate that interphase chromosomes are clustered in domains; condensing interphase chromosomes are linearly arranged. Our results raise questions related to telomer sequences and to the chemical nature of chromosome connectivity.     

Interphase chromosome structures of human cells

Major intermediates of chromosome condensation in erythroleukemia K562 cells are presented. Interphase chromatin structures became visible after reversal of permeabilization. Large-scale chromatin structures and the development of individual interphase chromosomes were observed by fluorescence microscopy. In the linear arrangement the following major intermediates of K562 chromatin condensation could be distinguished: (1) the most decondensed chromatin veil, (2) chromatin ribbon, (3) chromatin funnel, a new intermediate regarded as the earliest visible form of interphase chromosomes, (4) chromatin body, (5) 300 nm chromatin fiber, (6) u, v, or s forms of chromosomes, and (7) linear chromosomes. The observations made in nuclei of K562 cells conform to the model of helical coil chromosome condensation.     

Correlation between centromere and chromosome length in human male pronuclear chromosomes: ultrastructural analysis

Ultrastructural and morphometric analyses of centromeric regions by scanning and transmission electron microscopy have been performed in chromosomes from male pronuclei obtained by heterologous fertilisation of hamster oocytes with human spermatozoa. In 1308 of 1323 chromosomes analysed, the primary constriction showed a defined biconcave constriction of variable length (0.56-1.34 microns) and constant width (0.64-0.7 micron). A positive correlation was observed between centromeric length and chromosome length. In some chromosomes, the primary constriction appears as decondensed regions of variable length (1.6-2.51 microns) composed of chromatin fibres with a minimum diameter of 30 nm.     

Germinal vesicle materials are requisite for male pronucleus formation but not for change in the activities of CDK1 and MAP kinase during maturation and fertilization of pig oocytes

In amphibian oocytes, it is known that germinal vesicle (GV) materials are essential for sperm head decondensation but not for activation of MPF (CDK1 and cyclin B). However, in large animals, the role of GV materials in maturation and fertilization is not defined. In this study, we prepared enucleated pig oocytes at the GV stage and cultured them to examine the activation and inactivation of CDK1 and MAP kinase during maturation and after electro-activation. Moreover, enucleated GV-oocytes after maturation culture were inseminated or injected intracytoplasmically with spermatozoa to examine their ability to decondense the sperm chromatin. Enucleated oocytes showed similar activation/inactivation patterns of CDK1 and MAP kinase as sham-operated oocytes during maturation and after electro-stimulation or intracytoplasmic sperm injection. During the time corresponding to MI/MII transition of sham-operated oocytes, enucleated oocytes inactivated CDK1. However, penetrating sperm heads in enucleated oocytes did not decondense enough to form male pronuclei. To determine whether the factor(s) involved in sperm head decondensation remains associated with the chromatin after GV breakdown (GVBD), we did enucleation soon after GVBD (corresponding to pro-metaphase I, pMI) to remove only chromosomes. The injected sperm heads in pMI-enucleated oocytes decondensed and formed the male pronuclei. These results suggest that in pig oocytes, GV materials are not required for activation/inactivation of CDK1 and MAP kinase, but they are essential for male pronucleus formation.     

Inhibition by dibutyryl cyclic AMP of the transition to metaphase of mouse oocyte nuclei and its reversal by cell fusion to metaphase oocytes

Mouse oocytes at metaphase I of meiotic maturation were treated with puromycin, which caused the condensed chromosomes to become decondensed to form an interphase nucleus. The chromosomes returned to a metaphase state 6.3 hr after the oocytes were transferred to puromycin-free medium [H. J. Clarke and Y. Masui (1983) Dev. Biol. 97, 291-301]. In contrast, the chromosomes of the puromycin-treated oocytes remained decondensed within the nucleus if dibutyryl cyclic AMP (dbcAMP) was included in the puromycin-free medium. This implies that dbcAMP inhibited the development of conditions in the oocytes that were required for the transition to metaphase. The chromosomes of puromycin-treated oocytes that were incubated for 7.5 hr in dbcAMP-containing medium returned to metaphase just 1.9 hr after transfer to dbcAMP-free medium. Therefore, the protein synthesis-dependent process that is required for the transition to metaphase could occur in the presence of dbcAMP. Fusion to metaphase II oocytes, or to puromycin-treated oocytes that had returned to metaphase, rapidly induced transition of the nuclei of dbcAMP-inhibited oocytes to metaphase, despite the presence of the inhibitor. These results suggest that the transition of nuclei to metaphase can be induced by a cytoplasmic factor that is present in metaphase oocytes, and that dbcAMP inhibits the development of this factor.     

Teniposide, a topoisomerase II inhibitor, prevents chromosome condensation and separation but not decondensation in fertilized surf clam (Spisula solidissima) oocytes

DNA topoisomerase II has been implicated in regulating chromosome interactions. We investigated the effects of the specific DNA topoisomerase II inhibitor, teniposide on nuclear events during oocyte maturation, fertilization, and early embryonic development of fertilized Spisula solidissima oocytes using DNA fluorescence. Teniposide treatment before fertilization not only inhibited chromosome separation during meiosis, but also blocked chromosome condensation during mitosis; however, sperm nuclear decondensation was unaffected. Chromosome separation was selectively blocked in oocytes treated with teniposide during either meiotic metaphase I or II indicating that topoisomerase II activity may be required during oocyte maturation. Teniposide treatment during meiosis also disrupted mitotic chromosome condensation. Chromosome separation during anaphase was unaffected in embryos treated with teniposide when the chromosomes were already condensed in metaphase of either first or second mitosis; however, chromosome condensation during the next mitosis was blocked. When interphase two- and four-cell embryos were exposed to topoisomerase II inhibitor, the subsequent mitosis proceeded normally in that the chromosomes condensed, separated, and decondensed; in contrast, chromosome condensation of the next mitosis was blocked. These observations suggest that in Spisula oocytes, topoisomerase II activity is required for chromosome separation during meiosis and condensation during mitosis, but is not involved in decondensation of the sperm nucleus, maternal chromosomes, and somatic chromatin.     

Effects of Hoechst 33258 on human leukocytes in vitro.

The benzimidazole derivative Hoechst 33258 was added at various concentrations to human leukocyte cultures. After 16 or 24 h of treatment, with concentrations equal to or greater than 100 mug/ml of Hoechst 33258, a number of chromosomes showed regions in which the chromatin was undercontracted. The centromeric regions of chromosome 1 and, more rarely, of chromosomes 3 and 9 appeared to be decondensed. Short decondensed regions were also present on the long arms of chromosomes 1 and 2. The possible nature of these regions is discussed.     

Involvement of mouse nucleoplasmin 2 in the decondensation of sperm chromatin after fertilization

The tightly condensed chromatin of spermatozoa is rapidly decondensed after the spermatozoa enter oocytes. Although no factor involved in sperm chromatin decondensation (SCD) has been identified in mammals, it has been suggested that a factor related to SCD activity is present in the germinal vesicle (GV) of oocytes. Here, we found that the nucleolus-like body (NLB), which is a component of the GV, is involved in SCD in murine oocytes. When NLBs were microsurgically removed from GV-stage oocytes, SCD was significantly retarded in the paternal genome after fertilization following meiotic maturation. We found that the retardation of SCD in the NLB-removed oocytes was restored by the microinjection of mRNA encoding nucleoplasmin 2 (NPM2), a component of NLBs. Furthermore, SCD was retarded in the fertilized oocytes from Npm2-knockout females, and recombinant NPM2 alone could induce the SCD in vitro. These data provide evidence that NPM2 is involved in sperm chromatin remodeling in mammals.     

Development of pronuclei from human spermatozoa injected microsurgically into frog (Xenopus) eggs

Human spermatozoa were demembranated with Triton X-100 (TX) and injected into the mature eggs of Xenopus laevis. The nuclei of these spermatozoa decondensed and developed into pronuclei. Chromosomes did not appear in the eggs until the end of a 5-hr incubation period. When the demembranated human spermatozoa were further treated with dithiothreitol (DTT) before they were injected into the eggs, the sperm nuclear decondensation and pronuclear development took place considerably faster than in spermatozoa treated with the detergent alone. By the end of the 5-hr incubation period, decondensed chromatin threads or chromosome-like structures appeared, but none of the eggs cleaved. When human spermatozoa were injected into full-grown ovarian oocytes with intact germinal vesicle (GV) or oocytes which had matured without GV, the nuclei of a proportion of TX-treated and all TX-DTT-treated sperm decondensed but showed no sign of developing into pronuclei. Sperm nuclei injected into maturing oocytes formed condensed chromatin fragments as long as the oocytes were not activated, but they transformed into pronuclei when the oocytes were stimulated with electric shock. These results indicate that the cytoplasmic factors responsible for the decondensation of human sperm nuclei are present in egg cytoplasm independent of GV-materials. We also suggest that the factors controlling development of decondensed sperm nuclei into pronuclei are dependent on GV materials.     

Condensation of interphase chromatin in nuclei of synchronized chinese hamster ovary (CHO-K1) cells

Reversibly permeabilized cells have been used to visualize interphase chromatin structures in the presence and absence of biotinylated nucleotides. By reversing permeabilization, it was possible to confirm the existence of a flexible chromatin folding pattern through a series of transient geometric forms such as supercoiled, circular forms, chromatin bodies, thin and thick fibers, and elongated chromosomes. Our results show that the incorporation of biotin-11-dUTP interferes with chromatin condensation, leading to the accumulation of decondensed chromatin structures. Chromatin condensation without nucleotide incorporation was also studied in cell populations synchronized by centrifugal elutriation. After reversal of permeabilization, nuclei were isolated and chromatin structures were visualized after DAPI staining by fluorescent microscopy. Decondensed veil-like structures were observed in the early S phase (at an average C-value of 2.21), supercoiled chromatin later in the early S (2, 55 C), fibrous structures in the early mid S phase (2, 76 C), ribboned structures in the mid-S phase (2, 98 C), continuous chromatin strings later in the mid-S phase (3,28), elongated prechromosomes in the late S-phase (3, 72 C), precondensed chromosomes at the end and after the S phase (3, 99 C). Fluorescent microscopy revealed that neither interphase nor metaphase chromosomes are separate entities but form a linear array arranged in a semicircle. Linear arrangement was confirmed by computer image analysis.     

Ability of in vitro maturing bovine oocytes to transform sperm nuclei to metaphase chromosomes.

Bovine oocytes at the germinal vesicle stage were inseminated in Brackett & Oliphant's medium with bovine serum albumin, caffeine and heparin. Eight hours after insemination, oocytes were transferred into tissue culture medium-199 containing 10% fetal calf serum and cultured for 5-40 h at 39 degrees C in 5% CO2 in air. The proportions of unpenetrated and penetrated oocytes reaching metaphase II increased as the time of examination increased, reaching 70 and 65% 40 h after transfer, respectively. When oocytes were penetrated by more than four spermatozoa, meiotic maturation was greatly retarded. Sperm nuclei were decondensed in most (81%) penetrated oocytes 5 h after transfer. The decondensed sperm nuclei were recondensed and then transformed to metaphase chromosomes which were morphologically compacted at first but became slightly dispersed later. The formation of the metaphase chromosomes was observed in 86% of penetrated oocytes examined 40 h after transfer, and occurred in all metaphase II oocytes at that time. In oocytes penetrated by more than nine spermatozoa, no such transformation of sperm nuclei was observed. Well-developed male and female pro-nuclei were observed in only three (6%) of 51 oocytes penetrated 40 h after transfer.     

Gamma irradiation-induced apoptosis in murine pre-B cells prevents the condensation of fibrillar chromatin in early S phase

Local changes in chromatin structure leading to temporally distinct geometric forms were characterized in nuclei of reversibly permeabilized cells. Reversal of permeabilization was tested by 3H-thymidine incorporation and trypan blue dye exclusion. Apoptotic changes were visualized in a cell cycle dependent manner at the chromatin level by fluorescent microscopy in non-irradiated cells and after 400 rad Co60 irradiation. Fluorescent microscopy of chromatin structures belonging mainly to the interphase of the cell cycle confirmed the existence of specific geometric forms in nuclei of non-irradiated cells. In this control population, the following main transitory forms of condensing chromatin were distinguished: decondensed veil-like structures and fibrous structures in early and mid S phase (2.0-2.5 average C-value), chromatin bodies, semicircles later in mid S phase (3.0-3.5 C), precondensed chromosomes in late S (3.5-3.7 C) and metaphase chromosomes at the end and after S phase (3.7-4.0 C). Our results show that upon gamma-irradiation (a) the cellular and nuclear sizes were increased, (b) the DNA content was lower in each elutriated subpopulation of cells, (c) the progression of the cell cycle was arrested in the early S phase at 2.4 C value, (d) the chromatin condensation was blocked between the fibrillar chromatin and precondensed elongated chromosomal forms, and (e) the number and size of apoptotic bodies were inversely correlated with the progression of the cell cycle, with many small apoptotic bodies in early S phase and less and larger apoptotic bodies in late S phase.     

Microtubule and chromatin organization during the first cell-cycle following intracytoplasmic injection of round spermatid into porcine oocytes

The objective of this study was to determine microtubule assembly and chromatin configuration in porcine oocytes during the first cell cycle following round spermatid injection into matured porcine oocytes in the presence or absence of electrical stimulation. The oocytes with two large pronuclei and two polar bodies were classified as normal fertilization at 6 to 8 h following injection. The incidence of normal fertilization following round spermatid injection with electrical stimulation was significantly higher (21/45, 47%) than that following injection alone (6/39, 15%). Although a small microtubular aster was organized near the decondensed spermatid chromatin in some oocytes (2/6, 33%, spermatid injection alone; 9/21, 29%, spermatid injection and electrical stimulation), it did not enlarge nor fill the cytoplasm. Instead, a dense network of microtubules in the cytoplasm was organized from cortex. At 12 to 15 h after injection, we classified the oocytes with closely apposed pronuclei as normal fertilization. The electrical stimulation following spermatid injection enhanced (P < 0.05) the incidence of normal fertilization (18/54, 33%) compared with spermatid injection alone (7/52, 13%). During pronuclear movement, the maternally derived microtubules filled the whole cytoplasm, which appeared to move male and female chromatin. Mitosis and two-cell division were observed at 20 to 24 h after spermatid injection with electrical stimulation (12/41, 29%). At mitotic metaphase, the microtubular spindle had focused astral poles, and chromosomes were aligned on the spindle equator. During mitosis, asters were assembled at each spindle pole, and they filled the cytoplasm. These results suggested that round spermatid nuclei of the pig can develop into a morphologically normal pronucleus in matured porcine oocytes and are competent to participate in syngamy with the ootid chromatin. In addition, functional microtubules for complete fertilization with spermatid were not associated with male-derived centrosome but were organized solely from maternal stores. Mol. Reprod. Dev. 50:221–228, 1998. © 1998 Wiley-Liss, Inc.