Sea urchin sperm chromatin structure as probed by pancreatic DNase I: Evidence for a novel cutting periodicity

Chromatin from mature sea urchin spermatozoa is highly compacted and composed almost entirely of DNA and the five histones, although sperm H1, H2A, and H2b histones differ from those found in embryo or somatic cell nuclei. Release of acid-soluble DNA during pancreatic DNase I digestion is 20-fold slower from sperm nuclei than from embryonic nuclei. Following DNase I digestion, most sperm nuclear DNA remains at high molecular weight, although there appears to be some release of 10 base oligomer fragments. Size analysis of the higher molecular weight DNA reveals a series of fragments that indicate a cutting periodicity of approximately 500 base pairs. This pattern remains when electrophoretic separation is carried out under denaturing conditions. The 500 base pair cleavage pattern was not detected in digestions of embryonic nuclei. Nucleosomes reconstituted with fractionated core histones from sperm gave, upon digestion, a characteristic 10 base “ladder,” with no resistant high molecular weight DNA. Micrococcal nuclease and DNase II digested sperm nuclei to produce DNA fragments with a calculated repeat length of 248 ± 3 and 246 ± 6 base pairs, respectively. The structural basis for the 500 base pair cutting periodicity in sperm nuclei may reside in the unique sperm H1 histone.     

Transformation of sperm nuclei into male pronuclei in nucleate and anucleate fragments of parthenogenetic mouse eggs

Our objective was to examine the ability of nucleate and anucleate fragments of artificially activated mouse eggs to transform sperm nucleus into male pronucleus. To this end, zona-free oocytes in metaphase II were activated by ethanol and bisected into halves (one with the spindle, the other anucleate) either within 10 to 20 min (series A) or 3 or 5 hr later (series B). In series A, the fragments were inseminated 3,5, and 8 h after activation, and in series B. 3 and 5 h after activation. Both nucleate and anucleate fragments lose the capability of transforming sperm nucleus into fully formed pronucleus sometime between 3 and 5 h after activation. In 8 h old parthenogenetic fragments, the majority of sperm nuclei remain unchanged or begin decondensation but never reach the stage of an early pronucleus. In over 1/3 of anucleate fragments of this age group, sperm nuclei develop defectively: chromatin decondenses inside the persisting nuclear envelope. In other experimental groups, the incidence of these abnormal sperm nuclei varies between 0 and 10%. In general, the anuclcate fragments retain the capability to transform sperm nuclei (fully or partially) longer than their nuclear counterparts. This difference may be accounted for by a different level of substances required for pronuclcar growth (extrachromosomal constituents of the germinal vesicle and nuclear lamins): high and constant in the cytoplasm of anucleate egg halves and low and progressively decreasing in the nucleate halves because of their putative uptake by the female pronucleus. However, the cytoplasmic factors responsible for the initial stages of transformation (nuclear envelope breakdown, chromatin decondensation) become eventually inactivated both in the presence and in the absence of a female pronucleus.     

Dose-dependent relationship between oocyte cytoplasmic volume and transformation of sperm nuclei to metaphase chromosomes

We have studied the chromosome condensation activity of mouse oocytes that have been inseminated during meiotic maturation. These oocytes remain unactivated, and in those penetrated by up to three or four sperm, each sperm nucleus is transformed, without prior development of a pronucleus, into metaphase chromosomes. However, those penetrated by more than four sperm never transform any of the nuclei into metaphase chromosomes (Clarke, H. J., and Y. Masui, 1986, J. Cell Biol. 102:1039-1046). We report here that, when the cytoplasmic volume of oocytes was doubled or tripled by cell fusion, up to five or eight sperm nuclei, respectively, could be transformed into metaphase chromosomes. Conversely, when the cytoplasmic volume was reduced by bisection of oocytes after the germinal vesicle (GV) had broken down, no more than two sperm could be transformed into metaphase chromosomes. Thus, the capacity of the oocyte cytoplasm to transform sperm nuclei to metaphase chromosomes was proportional to its volume. The contribution of the nucleoplasm of the GV and the cytoplasm outside the GV to the chromosome condensation activity was investigated by bisecting oocytes that contained a GV and then inseminating the nucleate and anucleate fragments. The anucleate fragments never induced sperm chromosome formation, indicating that GV nucleoplasm is required for this activity. In the nucleate fragments, the capacity to induce sperm chromosome formation was reduced as compared with whole oocytes, in spite of the fact that the fragments contained the entire GV nucleoplasm. This implies that non-GV cytoplasmic material also was required for chromosome condensation activity. When inseminated oocytes were incubated in the presence of puromycin, the sperm nuclei were transformed into interphase-like nuclei, but no metaphase chromosomes developed. However, when protein synthesis resumed, the interphase nuclei were transformed to metaphase chromosomes. These results suggest that the transformation of sperm nuclei to metaphase chromosomes in the cytoplasm of mouse oocytes requires both the nucleoplasm of the GV and non-GV cytoplasmic substances, including proteins synthesized during maturation.     

Behavior of sperm nuclei in intact and bisected metaphase II mouse oocytes fertilized in the presence of colcemid

Our objective was to examine the developmental fate of sperm nuclei in oocytes fertilized under conditions of meiotic arrest. Therefore zona-free metaphase II oocytes and oocyte fragments (nucleate and anucleate) were fertilized in the presence of colcemid. In anucleate oocyte fragments, normal male pronuclei develop. In contrast, in intact oocytes and nucleate fragments sperm nuclei after initial decondensation undergo secondary condensation. This state is maintained as long as the oocytes are treated with colcemid. When the drug is removed 3 h after insemination, the meiotic spindle(s) is reconstructed, the second polar body(ies) is extruded, and a female pronucleus (or micronuclei) forms. At the same time the sperm nucleus decondenses again and transforms into a male pronucleus. In addition oocytes fertilized in the presence of colcemid could not be refertilized. These observations suggest that oocytes and oocyte fragments fertilized in the presence of colcemid undergo activation despite the failure of pronucleus formation. The inhibitory effect of colcemid on the formation of pronuclei is expressed only in the presence of oocyte chromosomes. We suggest that colcemid stabilizes factors responsible for chromosome condensation that are associated with oocyte chromosomes but not factors (whether the same or different) present in the cytoplasm.     

Ability of hamster spermatozoa to digest their own DNA

Mammalian sperm chromatin is bound by protamines into highly condensed toroids with approximately 50 kilobases (kb) of DNA. It is also organized into loop domains of about the same size that are attached at their bases to the proteinaceous nuclear matrix. In this work, we test our model that each sperm DNA-loop domain is condensed into a single protamine toroid. Our model predicts that the protamine toroids are linked by chromatin that is more sensitive to nucleases than the DNA within the toroids. To test this model, we treated hamster sperm nuclei with DNase I and found that the sperm chromatin was digested into fragments with an average size of about 50 kb, by pulse-field gel electrophoresis (PFGE). Surprisingly, we also found that spermatozoa treated with 0.25% Triton X-100 (TX) and 20 mM MgCl2 overnight resulted in the same type of degradation, suggesting that sperm nuclei have a mechanism for digesting their own DNA at the bases of the loop domains. We extracted the nuclei with 2 M NaCl and 10 mM dithiothreitol (DTT) to make nuclear halos. Nuclear matrices prepared from DNase I-treated spermatozoa had no DNA attached, suggesting that DNase I digested the DNA at the bases of the loop domains. TX-treated spermatozoa still had their entire DNA associated with the nuclear matrix, even though the DNA was digested into 50-kb fragments as revealed by PFGE. The data support our donut-loop model for sperm chromatin structure and suggest a functional role for this type of organization in that sperm can digest its own DNA at the sites of attachment to the nuclear matrix.     

Hydrozoan eggs can only be fertilized at the site of polar body formation

Hydrozoan eggs are normally fertilized at the site of polar body formation. The female pronucleus is just under the cell membrane at this site. Sperm are attracted to the eggs and aggregate at this site. This paper demonstrates that this site is the only region on the egg surface where the sperm can fuse with the egg. This has been done by cutting unfertilized eggs into fragments containing the site of polar body formation and fragments without this region. Sperm were added to the fragments and their ability to be fertilized was assayed by noting whether or not they cleaved. Only fragments containing the site of polar body formation cleaved. The absence of cleavage in fragments lacking the site of polar body formation cannot be attributed to the inability of these fragments to attract sperm. Such fragments attract sperm for several hours while fragments which contain the site of polar body formation stop attracting sperm a few minutes after fertilization. Cytological studies of egg fragments which do not contain the site of polar body formation show that they do not contain sperm nuclei. The lack of cleavage in these fragments cannot be attributed to the lack of a female pronucleus. By using centrifugation it is possible to move the female pronucleus away from the site of polar body formation. By cutting these centrifuged eggs in an appropriate way it is possible to create egg fragments with the site of polar body formation that lack the female pronucleus and egg fragments that lack the site of polar body formation but contain a female pronucleus. Only fragments which contain the site of polar body formation can be fertilized.     

Remodeling of Human Sperm Chromatin Mediated by Nucleoplasmin from Amphibian Eggs

The molecular events associated with decondensation of human sperm nuclei were analyzed by incubating sperm with egg extracts from an amphibian, Bufo japonicus . Acid-urea-Triton polyacrylamide gel electrophoresis (AUT-PAGE) showed that the nuclear basic proteins of human sperm consist mainly of protamines (HPI, HPII) with minor amounts of nucleosomal histones. On incubation of lysolecithin (LC)- and dithiothreitol (DTT)-treated human sperm with the egg extract, the nuclei lost HPI and HPII within 15 min in association with extensive nuclear decondensation, and the acquirement of a whole set of nucleosomal histones. Incubation of LC-DTT-sperm with nucleoplasmin purified from Bufo eggs also induced nuclear decondensation and loss of protamines within 30 min. Native-PAGE and Western blot analyses of incubation medium indicated tight association of the released protamines to nucleoplasmin, strongly suggesting that protamines are removed from sperm nuclei not enzymatically but by their specific binding to nucleoplasmin. On incubation of LC-DTT-sperm with nucleoplasmin and exogenous nucleosomal core histones, micrococcal nuclease-protected DNA fragments were released, although their unit repeat length was slightly less than that of somatic nucleosomes. Thus remodeling of human sperm during fertilization can be mimicked under defined conditions with nucleoplasmin and exogenous histones.     

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.     

Molecular structure of human protamine P4 (HP4), a minor basic protein of human sperm nuclei

Protamine HP4 is a minor protein which was purified from human sperm nuclei. It was characterized by its amino acid composition, peptide mapping after digestion with highly specific endoproteinases and finally by its amino acid sequence. Protamine HP4 contains high amounts of arginine, cysteine and histidine. The primary structure of the protein was established by sequence analysis of intact protamine and of its fragments. HP4 is a P2-type protamine of 58 residues (Mr 7783) structurally related to human protamines HP2 and HP3 from which it only differs by an amino-terminal extension of one and four residues, respectively. These three protamines exhibit a close structural relationship with mouse protamine mP2. The heterogeneity of protamines in human sperm nuclei is discussed.     

Nuclear assembly of demembranated Xenopus sperm in plant cell-free extracts from Nicotiana ovules

The cell-free preparation derived from Nicotiana tabaccum ovules induced chromatin decondensation and pronuclear formation from demembranated Xenopus laevis sperm nuclei. Fluorescent microscope and phase-contrast microscope visualization of assembly intermediates indicated that 95.6% of X. leavis sperm changed their tadpole-like shape to circular shape or elliptical shape after over 1.5 h of incubation. Transmission electron microscope visualization showed that nuclear membrane was assembled around the periphery of the dispersed chromatin. Nuclear envelope of most reassembled nuclei was composed of a double membrane inlaid with a little single membrane. Nucleosome assembly was verified by means of micrococcal nuclease digestion. After 2 to 5 h of incubation, digestion of the product of nuclear assembly with micrococcal nuclease produced at least six nucleosome fragments of about 250 bp each.     

Relationship between sperm nucleus remodelling and cell cycle progression of fragments of mouse parthenogenotes

Nucleate and anucleate fragments of parthenogenetically activated mouse oocytes, as well as cybrids obtained by fusion of anucleate fragments (cytoplasts) of maturing and activated matured oocytes were fertilized at different time after activation. Remodelling of the sperm nucleus was studied by electron microscopy at 1.5 and 3 h after fertilization and, in addition, at 14 h in cybrids. Results show that (1) the nuclear envelope of the sperm nucleus can break down when the insemination takes place after the end of M-phase, but the capacity of the parthenote cytoplasm to remodel the sperm nucleus is restricted in time. (2) Male chromatin can decondense within the old, unbroken nuclear envelope, but in such cases formation of a male pronucleus, one of the two nuclei of zygote possessing inactive nucleoli, is never observed. © 1994 Wiley-Liss, Inc.     

Size-uniform heparin fragments as nuclear decondensation and acrosome reaction inducers in human spermatozoa

Using size- uniform mixtures of di-, tetra-, octa- and decasaccharides obtained from the depolymerization of heparin with heparinase, we have studied the activity that these low molecular weight heparin fragments may have on the acrosome reaction and sperm nuclei decondensation processess. Swelling of human spermatozoa nuclei was stimulated by heparin and their fragments and was dependent on the incubation time and directly correlated with the size of the fragment tested. Disaccharides were unable to increase the number of swollen nuclei. At short times (2-8 hrs) decasaccharides were the most active substances tested, including heparin. Only heparin and the tetra- and decasaccharides showed a significant increase in the number of acrosome-reacted spermatozoa, both fragments were more active than heparin at 2 hour incubation. Hexa- and octasaccharides induced a slight increase in the number of acrosome reacted spermatozoa and disaccharides were ineffective. The presence in animal systems of oligosaccharides derived from macromolecules and having specific biochemical properties, remembers the recent discovery of to those mediated by oligosaccharins in plants may exist in animals.     

Interspecies differences in the stability of mammalian sperm nuclei assessed in vivo by sperm microinjection and in vitro by flow cytometry

To assess the structural stability of mammalian sperm nuclei and make interspecies comparisons, we microinjected sperm nuclei from six different species into hamster oocytes and monitored the occurrence of sperm nuclear decondensation and male pronucleus formation. The time course of sperm decondensation varied considerably by species: human and mouse sperm nuclei decondensed within 15 to 30 min of injection, and chinchilla and hamster sperm nuclei did so within 45 to 60 min, but bull and rat sperm nuclei remained intact over this same period of time. Male pronuclei formed in oocytes injected with human, mouse, chinchilla, and hamster sperm nuclei, but rarely in oocytes injected with bull or rat sperm nuclei. However, when bull sperm nuclei were pretreated with dithiothreitol (DTT) in vitro to reduce protamine disulfide bonds prior to microinjection, they subsequently decondensed and formed pronuclei in the hamster ooplasm. Condensed rat spermatid nuclei, which lack disulfide bonds, behaved similarly. The same six species of sperm nuclei were induced to undergo decondensation in vitro by treatment with DTT and detergent, and the resulting changes in nuclear size were monitored by phase-contrast microscopy and flow cytometry. As occurred in the oocyte, human sperm nuclei decondensed the fastest in vitro, followed shortly by chinchilla, mouse, and hamster and, after a lag, by rat and bull sperm nuclei. Thus species differences in sperm nuclear stability exist and appear to be related to the extent and/or efficiency of disulfide bonding in the sperm nuclei, a feature that may, in turn, be determined by the type(s) of sperm nuclear protamine(s) present.     

The timing of hamster sperm nuclear decondensation and male pronucleus formation is related to sperm nuclear disulfide bond content

The relationship between the timing of both sperm nuclear decondensation and male pronucleus formation in the oocyte and the relative level of disulfide bonds within the sperm nucleus was evaluated. Since reduction of sperm nuclear disulfide (S-S) bonds is a prerequisite for sperm nuclear decondensation in vitro and in vivo, we hypothesized that sperm nuclei with relatively few S-S bonds would require less time to decondense in the oocyte than sperm nuclei with higher numbers of S-S bonds, and that male pronucleus formation would occur more rapidly as well. Four types of hamster sperm nuclei, in which the extent of S-S bonding differed, were microinjected into hamster oocytes, and the time course of sperm nuclear decondensation and male pronucleus formation was charted. Cauda epididymal sperm nuclei, which are rich in S-S bonds, required 45-60 min to decondense. In contrast, nuclei containing few S-S bonds (namely sonication-resistant spermatid nuclei and cauda epididymal sperm nuclei treated in vitro with the S-S bond-reducing agent dithiothreitol) decondensed within 5-10 min of microinjection. Caput epididymal sperm nuclei, with intermediate S-S bond content, decondensed in 10-20 min. Regardless of when decondensation occurred, formation of the male pronucleus never preceded that of the female pronucleus, which occurred 1.25-1.5 h after microinjection. However, sperm nuclei with few S-S bonds were more likely than S-S rich nuclei to transform into male pronuclei in synchrony with the formation of the female pronucleus. We conclude that the timing sperm nuclear decondensation and pronucleus formation depends in part upon the S-S bond content of the sperm nucleus.     

Isolation of the peri-acrosomal plasma membrane protein D40 enriched fraction from guinea pig spermatozoa using a monoclonal antibody

Membrane fragments were obtained from guinea pig spermatozoa by mechanical shearing. A membrane-enriched fraction was separated from other cellular debris, mainly sperm nuclei and tails, by centrifugation on 20% Ficoll 70 solution. Peri-acrosomal plasma membrane protein, D40, enriched fraction was separated from this membrane preparation using a mouse monoclonal antibody to D40 attached to magnetic beads. Enrichment of D40 antigen in this fraction was demonstrated by western blotting. The method provides a preparative route to a membrane, the constituents of which play an important role in sperm recognition of the zona pellucida and the acrosome reaction. Some constituents of the peri-acrosomal plasma membrane over the equatorial segment of the acrosome may also play a role in sperm docking with the oocyte plasma membrane and fusion of the two cells.     

Physiological polyspermy: Selection of a sperm nucleus for the development of diploid genomes in amphibians

The union between a sperm and an egg nucleus in egg fertilization is necessary to mix genetic materials to create a new diploid genome for the next generation. In most animals, only one sperm is incorporated into the egg (monospermy), but several animals exhibit physiological polyspermy in which several sperms enter the egg during normal fertilization. However, only one sperm nucleus forms the zygote nucleus with the egg nucleus, even in a polyspermic egg. The cellular and molecular mechanisms involved in the selection of sperm nuclei in the egg cytoplasm have been well investigated in urodele amphibians. The principal sperm nucleus develops a larger sperm aster and contacts the egg nucleus to form a zygote nucleus, whereas other accessory sperm nuclei are unable to approach the egg nucleus. The diploid zygote nucleus induces cleavage and participates in embryonic development, whereas the accessory sperm nuclei undergo pyknosis and degenerate. We propose several models to account for the mechanisms of the selection of one sperm nucleus and the degeneration of accessory sperm nuclei. The roles of physiological polyspermy in animal reproduction are discussed by comparison with other polyspermic species.     

The role of disulfide bond reduction during mammalian sperm nuclear decondensation in vivo

These studies were designed to test the hypothesis that sperm nuclear decondensation and male pronuclear formation during hamster fertilization depend upon the ability of the fertilized oocyte to reduce sperm nuclear disulfide bonds. In a first series of experiments, treatment of mature oocytes with the sulfhydryl blocking agent iodoacetamide or the glutathione oxidant diamide caused a dose-dependent inhibition of decondensation in microinjected sperm nuclei. Inhibition of decondensation was not observed, however, when sperm nuclei were treated in vitro with dithiothreitol (DTT) to reduce disulfide bonds prior to their microinjection. In a second series of experiments, germinal vesicle (GV)-intact oocytes and pronuclear eggs, in which mature, disulfide-rich sperm nuclei do not decondense, were found to support the decondensation of disulfide-poor DTT-treated sperm nuclei or testicular spermatid nuclei. The decondensed sperm nuclei were not, however, transformed into male pronuclei. The results of these studies suggest: (1) that sperm nuclear decondensation in the hamster requires disulfide bond reduction, (2) that GV-intact oocytes and pronuclear eggs lack sufficient reducing power to effect sperm nuclear decondensation, and (3) that disulfide bond reduction is required but not sufficient for pronuclear formation.     

DNA-content in isolated nuclei of postembryonic stages of progeny from normal and irradiated males of Tetranychus urticae Koch (Acari,Tetranychidae)

The 1C DNA-content of isolated nuclei of postembryonic stages of Tetranychus urticae stained with the classic and a modified Schiffs reagent was cytophotometrically estimated as 0.1 pg, a low value in animals. For many tissues of this arrhenotokous species the ploidy ratio between males and females is 12, indicating the absence of sex-related differences in ploidy. — In addition, DNA measurements were performed to evaluate irradiation-experiments, starting with X-irradiation of mature sperm in males with doses known from previous work to induce chromosomal fragments that are subject to loss and missegregation in the embryonic mitotic stages of the female progeny despite the presumed holokinetic nature of the chromosomes. The DNA-content of the nuclei of the surviving postembryonic preadult stages did not indicate the occurrence of nuclei with in-between male/female values, ruling out loss and missegregation of fragments as important factors in postembryonic lethality. Abnormally low DNA-values in some adult females could be attributed to development of embryos before oviposition caused by radiation-induced effects.     

Evidence for nuclear internalization of exogenous DNA into mammalian sperm cells

Mature sperm cells have the spontaneous capacity to take up exogenous DNA. Such DNA specifically interacts with the subacrosomal segment of the sperm head corresponding to the nuclear area. Part of the sperm-bound foreign DNA is further internalized into nuclei. Using end-labelled plasmid DNA we have found that 15–22% of the total sperm bound DNA is associated with nuclei as determined on isolated nuclei. On the basis of autoradiographic analysis, nuclear permeability to exogenous DNA seems to be a wide phenomenon involving the majority of the sperm nuclei. In fact, the foreign DNA, incubated with sperm cells for different lengths of time, is found in 45% (10 min) to 65% (2 hr) of the sperm nuclei. Ultrastructural autoradiography on thin sections of mammalian spermatozoa, preincubated with end-labelled plasmid DNA, shows that the exogenous DNA is internalized into the nucleus. This conclusion is further supported by ultrastructural autoradiographic analysis on thin sections of nuclei isolated from spermatozoa preincubated with end-labelled DNA. © 1993 Wiley-Liss, Inc.