Sexual diploids of Aspergillus nidulans do not form by random fusion of nuclei in the heterokaryon

The sexual stage of Aspergillus (Emericella) nidulans consists of cleistothecia containing asci, each with eight ascospores. The fungus completes the sexual cycle in a homokaryotic or a heterokaryotic mycelium, respectively. The common assumption for the last 50 years was that different nuclear types are not distinguishable when sexual development is initiated. When cultured on a medium limited for glucose supplemented with 2% sorbitol, sexual development of A. nidulans is slowed and intact tetrads can be isolated. Through tetrad analysis we found that unlike haploid nuclei fuse preferentially to the prezygotic diploid nucleus. When heterokaryons are formed between nuclei of different genetic backgrounds, then recombinant asci derived from opposite nuclei are formed exclusively. Strains in the same heterokaryon compatibility group with moderate differences in their genetic backgrounds can discriminate between the nuclei of a heterokaryon and preferentially form a hybrid diploid nucleus, resulting in 85% recombinant tetrads. A. nidulans strains that differ at only a single genetic marker fuse the haploid nuclei at random for formation of diploid nuclei during meiosis. These results argue for a genetically determined "relative heterothallism" of nuclear recognition within a heterokaryon and a specific recruitment of different nuclei for karyogamy when available.     

Trikaryon formation and nuclear selection in pairings between heterokaryons and homokaryons of the root rot pathogen Heterobasidion parviporum

Pairings between heterokaryons and homokaryons of Agaricomycete fungi (he-ho pairings) can lead to either heterokaryotization of the homokaryon or displacement of the homokaryotic nucleus through migration of nuclei from the heterokaryon into the homokaryon. In species of Agaricomycetes with multinucleate cells (>2 nuclei per cell), he-ho pairings could result in the stable or transient formation of a hypha with three genetically different nuclei (trikaryons). In this study, he-ho pairings were conducted using the multinucleate Agaricomycete Heterobasidion parviporum to determine whether trikaryons can be formed in the laboratory and whether nuclear genotype affects migration and heterokaryon formation. Nuclei were tracked by genotyping the heterokaryotic mycelium using nucleus-specific microsatellite markers. The data indicated that certain nuclear combinations were favored, and that nuclei from some strains had a higher rate of migration. A high percentage of trikaryons (19 %) displaying three microsatellite alleles per locus were identified among subcultures of the he-ho pairings. Using hyphal tip and conidial isolation, we verified that nuclei of three different mating types can inhabit the same mycelium, and one of the trikaryotic strains was judged to be semi-stable over multiple sub-culturing steps, with some hyphal tips that retained three alleles and others that reduced to two alleles per locus. These results demonstrate that nuclear competition and selection are possible outcomes of heterokaryon-homokaryon interactions in H. parviporum and confirm that ratios of component nuclei in heterokaryons are not strictly 1:1. The high rate of trikaryon formation in this study suggests that fungi with multinucleate cells may have the potential for greater genetic diversity and recombination relative to dikaryotic fungi.     

Influence of different cell extraction methods on cytometric features.

The purpose of this study was to investigate the influence of different cell extraction procedures on relative nuclear DNA content (IOD), nuclear area, and texture features of Feulgen-stained nuclei. In imprints and smears of fine-needle aspirates and suspensions from one human liver specimen, 50 diploid, 50 tetraploid, and 25 octaploid nuclei were measured from each slide. In addition, for DNA measurements, the progressive mean of IOD and tetraploid/diploid and octaploid/diploid ratios was calculated. The results show that the progressive mean of the IOD is constant after measuring 25-30 nuclei. For the three types of specimens, the IOD of diploid nuclei varied slightly. The average coefficient of variation was about 5% for the fine-needle aspirates, imprints, and suspensions. For all tissue sampling methods, the 99% confidence limits of the tetraploid/diploid ratio and octaploid/diploid ratio were within the range of 1.9-2.1 and 3.7-4.3, respectively. The nuclear area and most of the texture features showed a significant difference (p less than 0.01) between the three sampling methods in all nuclear populations. In conclusion, different tissue sampling methods have little or no effect on DNA-related IOD measurements, whereas the outcome of nuclear area and texture features is very dependent of the cell extraction procedure.     

HETEROKARYOSIS AND PARASEXUALITY IN THE FUNGUS ASCOCHYTA IMPERFECTA

The object of this investigation was to discover whether heterokaryosis and parasexuality occur in the imperfect fungus Ascochyta imperfecta. Both phenomena have been observed. The wild type of A. imperfecta grows on a minimal medium containing only salts plus a carbon source. Auxotrophic and morphological mutants have been isolated after treatment with ultraviolet light. When 2 different mutant auxotrophs are inoculated together onto minimal medium, colonies are consistently formed. These colonies might be due, a priori, to back-mutation, diploidy, syntrophism or heterokaryosis. Back-mutation and diploidy have been eliminated, since no back-mutant nuclei have been isolated from any heterokaryon, and since the frequency of diploid nuclei is very low. The combination is primarily syntrophic (only 2% heterokaryotic hyphal tips) when the nicotinamide mutant is one component. The combination is primarily heterokaryotic (over 50% heterokaryotic hyphal tips) when both components are auxotrophs for amino acids. From the heterokaryotic hyphal tips, the 2 unaltered nuclear components have been isolated. Heterozygous diploid nuclei (4.2 X 10^−-7 per haploid nucleus) can be isolated from heterokaryons by plating, onto minimal medium, the primarily uninucleate conidia from a heterokaryon of 2 auxotrophs. The resulting colonies are isolated as potential diploids. Three properties of these isolates establish their diploid nature: (1) the isolates are wild type for nutrition and morphology; (2) their conidial length is uniformly greater than that of the haploids (1.21 times); (3) the isolates produce segregants with nonparental combinations of the marker genes. The diploid isolates are much more stable than heterokaryons. The recombinants from the diploids are still diploid, since (1) their conidial length falls in the diploid range, and (2) one of the recombinants has segregated a second-order recombinant. Many of the expected classes of recombinants have not been detected.     

Nuclear reassortment between vegetative mycelia in natural populations of the basidiomycete Heterobasidion annosum

Somatic incompatibility is not an absolute block to nuclear exchange between incompatible mycelia of the basidiomycete Heterobasidion annosum in vitro. Under laboratory conditions new heterokaryotic genotypes can be isolated from the gap between incompatible heterokaryons, and nuclear migration between pairs of heterokaryons grown in Petri dishes has been observed. In this study, we test the hypothesis of nuclear transfer and reassortment between heterokaryotic mycelia in natural populations of H. annosum. We developed six microsatellite markers to genotype nuclei populating 21 somatically incompatible mycelia of H. annosum isolated from a single stump of Picea abies, and found that the detected heterokaryons share nuclei; 10 of the nuclear haplotypes were found in more than one mycelium. In one isolate, four nuclear types were found in the same mycelium. These findings indicate that new heterokaryons can be formed as a result of nuclear reassortment between incompatible heterokaryotic mycelia in nature.     

On the evolution of the karyorelict ciliate life cycle: heterophasic ciliates and the origin of ciliate binary fission

Karyorelict ciliates have near diploid somatic nuclei (macronuclei) incapable of division. If selective pressure favors nuclear division, how could such macronuclei have evolved? I propose that they initially evolved in the context of a diplophase stage that consisted entirely of a non-dividing trophont that was terminated by the induction of meiosis. The diploid macronucleus then differentiated, functioned and was destroyed in the absence of cell division. Such a life cycle would necessarily be heterophasic, i.e. with alternating haploid and diploid generations. I call these ancestors heterophasic ciliates. I further propose that the ability of this diploid trophont to undergo binary fission arose de novo. Ciliate binary fission would then be a derived characteristic, which possibly evolved indepedently in more than one heterophasic ciliate lineage. A progression of steps, leading to the reduction of the haplophase and the generation of the karyorelict life cycle, is proposed. The shared possession of nuclear dimorphism with non-dividing macronuclei, conjugation, and a putative heterophasic ancestry invites further investigation of the phylogenetic relationship between heterokaryotic foraminifera and karyorelict ciliates.     

A shift in nuclear state as the result of natural interspecific hybridization between two North American taxa of the basidiomycete complex Heterobasidion

A natural first generation hybrid fungus shows interspecific heterozygosity. The nuclear condition of a rare natural hybrid between two taxa of the Heterobasidion complex is investigated. Heterobasidion species are known to be either homokaryotic (haploid) or heterokaryotic (n+n), but heterokaryons are made up of both homokaryotic and heterokaryotic sectors. The natural hybrid appears to be either a heterokaryon undergoing a primary homothallic phase or a diploid with limited ability to exchange nuclei when mated with homokaryons. The natural hybrid is stable and long lived, suggesting hybridization may play an important role in the evolutionary history of this fungal complex.     

Comparative microphotometric studies of DNA and arginine in plant nuclei

Summary Photometric measurements have been made of the amounts of stain formed in the Feulgen (DNA) and Sakaguchi (arginine) reactions in plant nuclei of differing ploidy.In nuclei of diploid and tetraploid plants of Tradescantia ohioensis and of diploid, triploid and tetraploid plants of Ranunculus ficaria, both Feulgen and Sakaguchi values gave ratios which agreed closely with the ratios of the number of chromatids known to be present. The Feulgen/ Sakaguchi ratio for each of the different types of nuclei measured was very similar both within and between these two species.In the interphase nuclei of five different species, both Feulgen and Sakaguchi values gave bimodal distributions. In the nuclei of differentiating cells, the proportions of values falling into each of the 2C, 4C or 8C classes were the same for both stains.Measurements of the amounts of both stains were made in sequence on the same individual nuclei and a positive correlation found between the two sets of values.In nuclei from differentiating cells of Vicia faba primary roots, the Feulgen/Sakaguchi ratio decreased with increasing distance from the apex.The following suggestions were made from the results: (a) that there is some degree of quantitative constancy of nuclear arginine which parallels that of DNA; (b) that the amount of nuclear arginine, like that of DNA, is doubled during synthesis in interphase; (c) that the syntheses of DNA and arginine in interphase, if not simultaneous, at least occur within the same relatively short period; (d) that there may be a difference in the DNA/arginine ratio between the nuclei of meristematic and differentiating cells.     

Nuclear differentiation and nuclear heteromorphism in the protozoa]

This is a review based upon a lecture given at the Developmental Biology School near Moscow in November 1991. Cases of successive and simultaneous nuclear differentiation are defined, and examples from various groups of protozoa are considered. Three cases of simultaneous nuclear differentiation, leading to the nuclear dualism phenomenon (heteromorphism) are analysed in detail. In heterokaryotic agamonts of some Foraminifera, nuclear differentiation occurs at the diploid level, proved to be irreversible and caused by either deletion or stable repression of some genes. In the Karyorelictid ciliates, the somatic nuclei (macronuclei) are paradiploid, metabolically active but unable to divide. They are irreversibly differentiated due to deletion of part of the initial (micronuclear) genome. Differentiation occurs in every cell cycle from the generative nuclei (micronuclei), which retain omnipotency and reproduce by mitosis. In most (higher) ciliates the differentiation of macronuclei occurs at an early stage of replication and involves a more or less drastic reorganization of the micronuclear genome, including both deletions and transpositions. Thereafter, the reorganized (and generally reduced) genome is strongly amplified to provide a high dose of active genes. The chromosomes of the majority of ciliates are fragmented in their macronuclei into either subchromosome-sized or gene-sized molecules, both being acentric. Systems regulating the differential replication of these molecules are likely to exist in macronuclei to keep the respective gene doses within certain limits.     

THE EVOLUTION OF PARASITISM IN RED ALGAE: CELLULAR INTERACTIONS OF ADELPHOPARASITES AND THEIR HOSTS1

In the initial stages of cell–cell interactions (spore germination and host penetration), the adelphoparasites Gardneriella tuberifera Kyl. and Gracilariophila oryzoides Setch. & Wilson form infection rhizoids that fuse directly with underlying host epidermal or cortical cells. In so doing, parasite nuclei and other organelles enter the cytoplasm of the host. The resulting heterokaryon may fuse with adjacent host cells either directly, via secondary pit connections, or by the dissolution or dislodgment of pit plugs from existing pit connections. The cell fusion events result in a heterokaryotic syncytium in which parasite nuclei replicate. In Gardneriella, formation of the syncytium induces surrounding host tissues to divide to form a photosynthetic callus. The internalized syncytium forms conjunctor and rhizoidal cells that fuse with host callus, eventually transforming the host callus into cells containing parasite nuclei. Gracilariophila does not induce surrounding host tissue to divide. Rather, division of the initial heterokaryotic tissue gives rise to the colorless mantle that protrudes from the host and forms reproductive structures. The heterokaryotic tissue also fuses with underlying host cells, thereby spreading parasite nuclei throughout adjacent host cells. In both these adelphoparasites, transformation of host cells by parasite nuclear invasion results in plastid dedifferentiation, an increase in mitochondria, autolysis of organelles, and accumulation of large amounts of floridean starch. The development and physiology of these parasites is similar to normal post-fertilization processes in the hosts that give rise to carposporophytes and suggests that these adelphoparasites may have originated from perturbations of developmental pathways involved in their host's post-fertilization development.     

Generation of fertile and diploid fish, medaka (Oryzias latipes), from nuclear transplantation of blastula and four-somite-stage embryonic cells into nonenucleated unfertilized eggs

In two experimental series of transplantation of embryonic cell nuclei into nonenucleated unfertilized eggs in medaka (Oryzias latipes), fertile and diploid nuclear transplants were successfully generated. In the first experiment, nuclei from blastula cells of a medaka stock with the wild-type body color were transplanted into 1722 eggs from the orange-red variety. Of 26 adult nuclear transplants with the wild-type body color, 22 were, as expected, triploid and sterile, but the other four were fertile. Three of the four were diploid, and the last one was tetraploid. They transmitted the wild-type body color to the F1 and F2 progenies in a Mendelian fashion. In the second experiment, cell nuclei from four-somite-stage embryos of the orangered variety carrying the green fluorescent protein (GFP) transgene were transplanted into 1688 recipients of the same strain. Three adult nuclear transplants expressing GFP were obtained. Two of them were triploid and sterile, but the remaining one was fertile and diploid. The transgene of the donor nuclei was transmitted to the F(1) and F(2) offspring in a Mendelian fashion. These observations that diploid and fertile nuclear transplants could be obtained without enucleation of the recipient eggs may have important implications for future nuclear transplantation in medaka.     

Detection of concealed "illegitimate" nuclei in tetrad analysis of the diploid progeny of heterokaryons in Saccharomyces cerevisiae

In this work, the studies on the previously detected phenomenon of concealed heterokaryosis in Saccharomyces cerevisiae were continued. In genetic and Southern blotting experiments, one of the nuclei in the heterokaryon was shown to be active (capable of division and ensuring the corresponding cell phenotype), whereas the other was not expressed until the heterokaryotic clone was transferred to the medium selective for this concealed nucleus. Moreover, the concealed nucleus was able to assume the active state after fusion with the second parental nucleus. It was analyzed whether the nuclei with new marker combinations occurring in meiosis can behave as exceptional nuclei. Tetrad analysis of hybrids carrying the kar1 mutation in their nuclei revealed the relatively high percentage of exceptional tetrads (more than 10%). One spore in these tetrads usually formed diploid cells capable of sporulation. The presented data of genetic and molecular biological studies testify in favor of the assumption that abnormal spores contain two nuclei, which form an "illegitimate" hybrid after fusion. An extraneous spore (termed x) has usually a genotype close to that of one of the spores in this tetrad. Thus, it was assumed that the additional DNA replication round occurs in the absence of cell division during one of meiotic divisions. Results of cytological analysis conducted by the method of specific DNA staining confirmed the existence of exceptional tetrads, one spore of which contains two nuclei.     

Ploidy levels and the number of nuclei in cardiomyocytes of the lamprey and fish

It is well known that polyploidization of cardiomyocytes (CMC) is an essential component of heart growth in the warm-blooded vertebrates. Using the Feulgen cytophotometry of alkali-dissociated cells, we determined the ploidy in CMC of the lower vertebrates: lamprey Lampetra fluviatilis (Cyclostomata), skate Bathyraja maculata (Chondrostei), sterlet Acipenser ruthenus, and Russian sturgeon Acipenser güldenst?dti (Ganoids), as well as paradise fish Macropodus opercularis, Amur sleeper Perccottus glehni, and Atlantic salmon Salmo solar (Teleostei). The data obtained have demonstrated a wide variety in CMC ploidy of both cyclostomata and fishes. About 85% of the lamprey CMC contain 2 or more (up to 17) nuclei per cell; with 90 and 10% of the nuclei being, respectively, diploid and tetraploid. Hearts of the skate and sturgeons contain mononucleated diploid CMC. In the perch-like fishes, mononucleated diploid and mononucleated tetraploid CMC make, respectively, 95 and 5%. The salmon heart contains near 50% of mononucleated diploid CMC, 13% of mononucleated tetra- and octaploid CMC, the rest CMC being multinucleated (up to 6 nuclei per cell). In all the examined species, the increased nuclear ploidy is accompanied with a significant increase in the nuclear volume. The number of nucleoli per nucleus does not correlate with the nuclear ploidy level. Evolutionary aspects of CMC polyploidy in chordates are discussed.     

Analysis of protein expression in pure cell nuclei populations isolated from human breast cancer tissue by DNA flow cytometric sorting

In this study, cell nuclei from aneuploid breast cancer samples were sorted with respect to DNA content into pure diploid and aneuploid fractions using flow cytometry. The nuclear proteins were then separated by one-dimensional gel electrophoresis (1D-PAGE) and differences in protein expression patterns, between diploid and aneuploid nuclei from the same tumours, were compared. Using a combination of peptide finger printing and peptide identification by MALDI-TOF mass spectrometry, we identified proteins and confirmed that the proteins were of nuclear origins. The results in this study add further information to the knowledge about the breast cancer disease complexity and heterogeneity at molecular level. For some of the tumours studied different nuclei protein patterns were obtained, in the diploid respective aneuploid nuclei populations, whilst other tumours did not show these differences.     

Microspectrophotometry of cell nuclei stained with the Feulgen reaction. IV. Formation of tetraploid nuclei in rat liver cells during postnatal growth

1. DNA contents of the individual parenchymal nuclei of rat livers during postnatal growth were estimated by microspectrophotometric apparatus, and different ploidy classes of nuclei were classified by their DNA contents. With the same material the total number of parenchymal nuclei in the liver was counted microscopically. 2. If the DNA content of nuclei encountered most frequently in several tissues represents the diploid class, the ploidy classes of the rat liver cell nuclei correspond to di-, tri-, tetra-, and octoploid, with the di- and tetraploid ones predominating considerably. 3. In suckling rats (below 25 gm. of body weight) the liver parenchyma is composed almost exclusively of cells with diploid nuclei, whereas in young rats (above 80 gm.), of tetraploid nuclei. In the growth stage between 25 and 80 gm., there is a remarkable replacement of the diploid nuclei by the tetraploid ones. However, in the liver of adult rats weighing more than 150 gm., any increase or decrease in the frequency of diploid and tetraploid nuclei is hardly observable. In such rats, the nuclear population of the liver parenchyma seems to reach a cell-ecological equilibrium which is considered to be a stable one. 4. It is shown that such nuclear populations and the total number of nuclei in a liver are controlled by the growth state, and not by the age. 5. The decrease in the total number of diploid nuclei and the increase in tetraploid nuclei in the growing livers of rats weighing from 40 up to 130 gm. can both be explained by the hypothesis that the tetraploid nuclei originate from the interphase diploid nuclei without involving mitosis. This hypothesis implies that mitosis is confined to the reproduction of diploid cells alone. 6. It is suggested that, in general, the synthesis of DNA does not necessarily result in the formation of visible mitotic chromosomes. 7. Mitotic time and generation time of diploid nuclei and the percentage of the tetraploidization from diploid nuclei are calculated and discussed.     

Triallelic SNP-mediated genotyping of regenerated protoplasts of the heterokaryotic fungus Rhizoctonia solani

The aneuploid and heterokaryotic nuclear condition of the soil fungus Rhizoctonia solani have provided challenges in obtaining a complete genome sequence. To better aid in the assembly and annotation process, a protoplast and single nucleotide polymorphism (SNP)-based method was developed to identify regenerated protoplasts with a reduced nuclear genome. Protocol optimization experiments showed that enzymatic digestion of mycelium from a 24 h culture of R. solani increased the proportion of protoplasts with a diameter of ≤7.5 μm and 1-4 nuclei. To determine whether strains regenerated from protoplasts with a reduced number of nuclei were genetically different from the parental strain, triallelic SNPs identified from variance records of the genomic DNA sequence reads of R. solani were used in PCR-based genotyping assays. Results from 16 of the 24 SNP-based PCR assays provided evidence that one of the three alleles was missing in the 11 regenerated protoplast strains, suggesting that these strains represent a reduced genomic complement of the parental strain. The protoplast and triallelic SNP-based method used in this study may be useful in strain development and analysis of other basidiomycete fungi with complex nuclear genomes.     

Spatial topography of a pericentromeric region (1q12) in hemopoietic cells studied by in situ hybridization and confocal microscopy

A fluorescent in situ hybridization procedure with a chromosome 1-specific (1q12) repetitive satellite DNA probe was used to label the 1q12 regions of the chromosomes 1 in spherical and polymorphic hemopoietic cell nuclei. The entire procedure was performed in suspension to preserve nuclear morphology. The result was studied by three-dimensional analysis, as provided by a scanning laser confocal microscope. The 1q12 regions of chromosome 1 were measured to be closely associated with the nuclear envelope in isolated nuclei of unstimulated diploid human lymphocytes. The relative positions to each other in the periphery of these spherical nuclei could not be distinguished from a random distribution pattern. In the diploid and tetraploid polymorphic nuclei of cells of the promyelocytic leukemia cell line HL60 these pericentromeric sequences were also associated with the nuclear surface.     

The nuclear dry weight of liver cells from patients with virus hepatitis and from controls.

Interferometric investigations were performed at liver cell nuclei isolated in 70 per cent glycerol. In 11 patients with virus hepatitis and seven patients without liver disease the nuclear dry weight of liver cells obtained by liver biopsy was determined by interferometry. The average nuclear dry weight of diploid liver cells from controls was 39.9 pg while an average value of 45.4 pg was found for patients with hepatitis. The corresponding nuclear volumes were 241 and 274mu3 respectively. The dry mass and volume of tetraploid nuclei was twice as big as that of diploid nuclei in both materials. The nuclear water content was neither significantly different between diploid and tetraploid nuclei nor significantly different between nuclei from controls and patients with hepatitis.     

MICROSPECTROPHOTOMETRY OF CELL NUCLEI STAINED WITH THE FEULGEN REACTION : IV. FORMATION OF TETRAPLOID NUCLEI IN RAT LIVER CELLS DURING POSTNATAL GROWTH

1. DNA contents of the individual parenchymal nuclei of rat livers during postnatal growth were estimated by microspectrophotometric apparatus, and different ploidy classes of nuclei were classified by their DNA contents. With the same material the total number of parenchymal nuclei in the liver was counted microscopically. 2. If the DNA content of nuclei encountered most frequently in several tissues represents the diploid class, the ploidy classes of the rat liver cell nuclei correspond to di-, tri-, tetra-, and octoploid, with the di- and tetraploid ones predominating considerably. 3. In suckling rats (below 25 gm. of body weight) the liver parenchyma is composed almost exclusively of cells with diploid nuclei, whereas in young rats (above 80 gm.), of tetraploid nuclei. In the growth stage between 25 and 80 gm., there is a remarkable replacement of the diploid nuclei by the tetraploid ones. However, in the liver of adult rats weighing more than 150 gm., any increase or decrease in the frequency of diploid and tetraploid nuclei is hardly observable. In such rats, the nuclear population of the liver parenchyma seems to reach a cell-ecological equilibrium which is considered to be a stable one. 4. It is shown that such nuclear populations and the total number of nuclei in a liver are controlled by the growth state, and not by the age. 5. The decrease in the total number of diploid nuclei and the increase in tetraploid nuclei in the growing livers of rats weighing from 40 up to 130 gm. can both be explained by the hypothesis that the tetraploid nuclei originate from the interphase diploid nuclei without involving mitosis. This hypothesis implies that mitosis is confined to the reproduction of diploid cells alone. 6. It is suggested that, in general, the synthesis of DNA does not necessarily result in the formation of visible mitotic chromosomes. 7. Mitotic time and generation time of diploid nuclei and the percentage of the tetraploidization from diploid nuclei are calculated and discussed.     

Occurrence of amitotic division of trophoblast cell nuclei in blastocysts of the western spotted skunk (Spilogale putorius latifrons)

A cytogenetic examination of spreaded cells of diapausing and early activated blastocysts obtained from 7 female western spotted skunks was performed. Mitosis was not observed in 1626 cells obtained from 9 diapausing blastocysts; however, 12 (1.5%) figures of diploid mitosis were seen in 851 cells from 5 early activated embryos. Diameter of the cell nuclei varied from 4 to 29 microm during diapause, and from 5 to 40 microm in activated blastocyst, and the heterogeneity in nuclear size was significantly different between diapausing and activated embryos (P<0.01). About 80% of nuclei from diapausing blastocysts measured 9 to 16 microm, whereas a similar percentage of nuclei from activated blastocysts ranged from 15 to 27 microm. Many enlarged nuclei exhibited morphological features characteristic of mammalian polytene (i.e. endopolyploid with polytenic organization of chromosomes) trophoblast cells. The number of silver stained nucleoli in all the nuclei did not exceed 2, which corresponds to the number of nucleolus organizers in the diploid karyotype in this species of skunk and suggests the polytene organization of chromosomes in enlarged nuclei. About 10% of large interphase nuclei were observed to undergo amitosis, i.e. direct division by constriction. The resulting nuclear fragments in diapausing blastocysts usually had normal morphology and active nucleoli. In activated embryos, nearly 15% of amitotically divided nuclei appeared to be dividing into fragments of unequal size, one of which had normal cell nuclear morphology and extremely large silver positive nucleoli, and the other fragment exhibited signs of cell death. We interpret these data as indicating that 1) amitotic division of trophoblast endopolyploid cell nuclei in the skunk blastocysts may generate new trophoblast cells which contribute to increased cell number during both diapause and activation stages, and 2) activation of blastocysts after diapause is related to the production of trophoblast cells with enhanced synthetic capabilities.