Autoradiographic study of mouse spermatozoan arginine-rich nuclear protein in fertilization

The Assessment of Sperm DNA Integrity: Implications for Assisted Reproductive Technology Fertility Outcomes across Livestock Species

Sperm DNA integrity is increasingly considered a useful measure of semen quality in mammalian reproduction. However, the definition of DNA integrity, the ideal means by which it should be measured, and its predictive value for fertility remain a topic of much discussion. With an emphasis on livestock species, this review discusses the assays that have been developed to measure DNA integrity as well as their correlation with in vitro and in vivo fertility.

Chromosome formation during fertilization in eggs of the teleost Oryzias latipes

Upon fertilization, eggs shift their cell cycle from the meiotic to the mitotic pattern for embryogenesis. The information on chromosome formation has been accumulated by various experiments using inhibitors to affect formation and behavior of chromosomes in the cycle of cell proliferation. Based on experimental results on meiosis and early stages of development of the teleost Oryzias latipes, we discuss the roles of the activities of histone H1 kinase, microtubule-associated protein kinase, DNA polymerase, DNA topoisomerase, and other cytoplasmic factors that play a crucial role in formation and separation of chromosomes.

Function of sperm chromatin structural elements in fertilization and development

Understanding how DNA is packaged in the mammalian sperm cell has important implications for human infertility as well as for the cell biology. Recent advances in the study of mammalian sperm chromatin structure and function have altered our perception of this highly condensed, inert chromatin. Sperm DNA is packaged very tightly to protect the DNA during the transit that occurs before fertilization. However, this condensation cannot sacrifice chromosomal elements that are essential for the embryo to access the correct sequences of the paternal genome for proper initiation of the embryonic developmental program. The primary levels of the sperm chromatin structure can be divided into three main categories: the large majority of DNA is packaged by protamines, a smaller amount (2-15%) retains histone-bound chromatin and the DNA is attached to the nuclear matrix at roughly 50 kb intervals. Current data suggest that the latter two structural elements are transferred to the paternal pronucleus after fertilization where they have important functional roles. The nuclear matrix organization is essential for DNA replication, and the histone-bound chromatin identifies genes that are important for embryonic development. These data support the emerging view of the sperm genome as providing, in addition to the paternal DNA sequence, a structural framework that includes molecular regulatory factors that are required for proper embryonic development.

Fertilization and embryonic developmental capacity of epididymal and testicular sperm and immature spermatids and spermatocytes

Spermatogenesis in mammalian species begins after birth. The gonocytes, arrested at G2 of the cell cycle in the foetus, resume mitotic proliferation after birth. As identified in the mouse, the gonocytes migrate towards the periphery of the seminiferous cords at day 4 to day 6 after birth and are located in close contact with the basal lamina. From this stage the gonocytes are referred to as primitive type A spermatogonia. These cells continue mitotic proliferation and differentiate to form type B spermatogonia. By day 10 after birth, many of the type B spermatogonia have formed preleptotene primary spermatocytes which undergo a final phase of DNA synthesis (leptotene) prior to entering meiotic prophase (zygotene).

Sperm chromatin remodeling after intracytoplasmic sperm injection differs from that of in vitro fertilization

Intracytoplasmic sperm injection (ICSI) is a popular method used in assisted conception, and live offspring have been born from a variety of species, including humans. In ICSI, sperm chromatin is introduced into the oocyte together with the acrosome, a structure that does not enter the oocyte during normal fertilization. We compared sperm chromatin remodeling, the potential of embryos to develop in vitro, and DNA synthesis in mouse embryos obtained from in vitro fertilization (IVF) and ICSI. We also tested whether sperm pretreatment prior to ICSI (i.e., capacitation, acrosome reaction, membrane removal, and reduction of disulfide bonds in protamines) facilitates chromatin remodeling and affects embryo development. Sperm chromatin was examined on air-dried, Giemsa-stained preparations at 30-min intervals for up to 4.5 h postfertilization. In all experimental groups, the oocytes underwent activation and formed pronuclei with similar rates. However, the dynamics of sperm chromatin remodeling in ICSI and IVF embryos varied. In ICSI, chromatin remodeling was more asynchronous than in IVF. Sperm capacitation prior to injection enhanced remodeling asynchrony and resulted in delayed pronuclei formation and DNA synthesis. The removal of the acrosome prior to injection with calcium ionophore A23187 but not with detergent Triton X-100 allowed more synchronous chromatin remodeling, timely DNA synthesis, and good embryo development. Our data have significance for the refinement of the molecular and biologic mechanisms associated with ICSI for current and future applications.

The capability of reprogramming the male chromatin after fertilization is dependent on the quality of oocyte maturation

The present experiments compared the ability of pig oocytes matured either in vivo or in vitro to structurally reorganize the penetrated sperm chromatin into male pronucleus (PN) and to carry out, in parallel, the epigenetic processes of global chromatin methylation and acetylation, 12-14 h after in vitro fertilization (IVF). In addition, PN distribution of histone deacetylase (HDAC), a major enzyme interfacing DNA methylation and histone acetylation, was investigated. The ability of the oocyte to operate an efficient block to polyspermy was markedly affected by maturation. The monospermic fertilization rate was significantly higher for in vivo than for in vitro matured (IVM) oocytes (P < 0.01) which, furthermore, showed a reduced ability to transform the chromatin of penetrated sperm into male PN (P < 0.01). Indirect immunofluorescence analysis of global DNA methylation, histone acetylation and HDAC distribution (HDAC-1, -2 and -3), carried out in monospermic zygotes that reached the late PN stage, showed that IVM oocytes also had a reduced epigenetic competence. In fact, while in about 80% of in vivo matured and IVF oocytes the male PN underwent a process of active demethylation and showed a condition of histone H4 hyperacetylation, only 40% of IVM/IVF zygotes displayed a similar PN remodelling asymmetry. Oocytes that carried out the first part of maturation in vivo (up to germinal vesicle breakdown; GVBD) and then completed the process in vitro, displayed the same PN asymmetry as oocytes matured entirely in vivo. A crucial role of HDAC in the establishment of PN acetylation asymmetry seems to be confirmed by the use of HDAC inhibitors as well as by the abnormal distribution of the enzyme between the two PN in IVM zygotes. Collectively, these data demonstrated that some pig IVM oocytes fail to acquire full remodelling competence which is independent from their ooplasmic ability to morphologically reorganize the sperm nucleus into PN.

Asymmetry in histone H3 variants and lysine methylation between paternal and maternal chromatin of the early mouse zygote

In mammalian fertilization, the paternal genome is delivered to the secondary oocyte by sperm with protamine compacted DNA, while the maternal genome is arrested in meiotic metaphase II. Thus, at the beginning of fertilization, the two gametic chromatin sets are strikingly different. We elaborate on this contrast by reporting asymmetry for histone H3 type in the pre-S-phase zygote when male chromatin is virtually devoid of histone H3.1/3.2. Localization of the histone H3.3/H4 assembly factor Hira with the paternal chromatin indicates the presence of histone H3.3. In conjunction with this, we performed a systematic immunofluorescence analysis of histone N-tail methylations at position H3K4, H3K9, H3K27 and H4K20 up to the young pronucleus stage and show that asymmetries reported earlier are systematic for virtually all di- and tri-methylations but not for mono-methylation of H3K4 and H4K20, the only marks studied present in the early male pronucleus. For H4K20 the expanding male chromatin is rapidly mono-methylated. This coincides with the formation of maternally derived nucleosomes, a process which is observed as early as sperm chromatin decondensation occurs. Absence of tri-methylated H3K9, tri-methylated H4K20 and presence of loosely anchored HP1-beta combined with the homogenous presence of mono-methylated H4K20 suggests the absence of a division of the paternal chromatin in eu- and heterochromatin. In summary the male, in contrast to female G1 chromatin, is uniform and contains predominantly histone H3.3 as histone H3 variant.

Remodelling the paternal chromatin at fertilization in mammals

At fertilization, the highly condensed and transcriptionally inert chromatin of the spermatozoa becomes remodelled into the decondensed and transcriptionally competent chromatin of the male pronucleus. The chromatin initially becomes dispersed and then transiently recondenses into a small mass upon entry into the ooplasm. This morphological change is coincident with and likely dependent on the replacement of the sperm-specific protamines by oocyte-supplied histones and the organization of the chromatin into nucleosomes. The chromatin then extensively decondenses within the male pronucleus and acquires many of the proteins that are associated with the maternal chromatin. Nonetheless, the paternal chromatin manifests distinct characteristics, including transient hyperacetylation of histone H4, increased transcription of endogenous and microinjected genes, and replication-independent demethylation of DNA. Sperm chromatin remodelling is controlled by an oocyte activity that appears during meiotic maturation and disappears approximately 3 h after activation (release from metaphase II arrest), and which requires factors associated with the germinal vesicle of the oocyte. The molecular components of this activity remain largely unknown. In frogs, nucleoplasmin is required to assemble histones H2A and H2B onto the paternal chromatin. Evidence is presented that related proteins may perform similar functions in mammals. Identifying the mechanisms that underlie sperm chromatin remodelling at fertilization may be relevant for understanding reprogramming of somatic cell nuclei after transfer into oocytes.

The ability to develop an activity that transfers histones onto sperm chromatin is acquired with meiotic competence during oocyte growth

Following fertilization, the oocyte remodels the sperm chromatin into the male pronucleus. As a component of this process, during meiotic maturation, oocytes develop an activity that transfers histones onto sperm DNA. To further characterize this activity, we tested whether oocytes at different stages of growth could, upon entry into metaphase of maturation, transfer histones onto sperm DNA, as judged by chromatin morphology and immunocytochemistry. Meiotically competent growing oocytes, which spontaneously enter metaphase upon culture, transferred histones onto sperm chromatin, whereas incompetent oocytes did not, even when treated with okadaic acid to induce germinal vesicle breakdown (GVBD) and chromosome condensation. When incompetent oocytes were cultured until they acquired the ability to undergo GVBD, only a small proportion also developed histone-transfer activity during maturation. However, this proportion significantly increased when the oocytes were cultured as granulosa-oocyte complexes. The failure of histone-transfer activity to develop in incompetent oocytes treated with okadaic acid was not linked to low H1 kinase activity nor rescued by injected histones. Because competent, but not incompetent, oocytes produce natural calcium oscillations, incompetent oocytes were exposed to SrCl2. One-third of treated oocytes produced at least one Ca2+ oscillation and, following insemination, the same proportion transferred histones onto sperm DNA. Histone transfer did not occur in oocytes pretreated with the Ca2+ chelator, BAPTA-AM. These results indicate that the ability to develop histone-transfer activity is acquired by growing oocytes near the time of meiotic competence, that it is separable from this event, and that it may be regulated through a Ca2+-dependent process.

Nucleus transfer in mammals: how the oocyte cytoplasm modifies the transferred nucleus

Successful development of clones depends on the reprogramming of transferred nuclei in enucleated oocytes. Thus far, oocytes are the only cells that can convert nuclei, which are already differentiated, into undifferentiated stages resembling pronuclei in freshly fertilized zygotes and that can then complete development of the reconstructed embryos. However, we still don't know exactly how the enucleated oocyte (cytoplast) secures this reprogramming. Oocytes exhibit a number of cytoplasmic activities that may be involved reprogramming. We discuss how these activities may be involved in reprogramming of transferred nuclei.

Studies on fertilization of the teleost. II. Nuclear behavior and changes in histone H1 kinase

In order to understand the dynamic responses of gamete nuclei upon fertilization in the fish, Oryzias latipes, the relationship between changes in the activity of histone H1 kinase and nuclear behavior was examined during fertilization. Kinase activity rapidly decreased concomitant with the initiation of the propagative exocytosis of cortical alveoli following sperm attachment to the egg plasma membrane post-insemination (PI). Activity again increased 30 min PI. Similar changes in kinase activity, migration and syngamy of pronuclei, and subsequent cleavage were observed with aphidicolin or actinomycin D treatment, except that formation of abnormal metaphase chromosomes was retarded in aphidicolin-treated zygotes. Pretreatment of unfertilized eggs with cycloheximide or 6-dimethylaminopurine (6-DMAP) caused no nuclear changes. The activity of histone H1 kinase in these eggs rapidly declined following sperm penetration and exocytosis, but did not undergo subsequent increase in the presence of these inhibitors. In these eggs with low histone H1 kinase activity, the fertilization process from sperm penetration to syngamy occurred normally, but the pronuclear membrane did not break down and the chromosomes did not condense. The present data suggest that in fish eggs, DNA replication as well as the synthesis and phosphorylation of proteins, especially cyclin B, are required for normal formation of metaphase chromosomes at the first cleavage, but not for fertilization events from sperm penetration through to nuclear migration resulting in syngamy.

Sperm nuclear activation during fertilization

The delivery of the paternal genome to the egg is a primary goal of fertilization. In preparation for this step, the nucleus of the developing spermatozoon undergoes extensive morphological and biochemical transformations during spermatogenesis to yield a tightly compacted sperm nucleus. These modifications are essentially reversed during fertilization. As a result, the incorporated sperm nucleus undergoes many steps in the egg cytoplasm as it develops into a male pronucleus. The sperm nucleus (1) loses its nuclear envelope, (2) undergoes nucleoprotein remodeling, (3) decondenses and increases in size, (4) becomes more spherical, (5) acquires a new nuclear envelope, and (6) becomes functionally competent to synthesize DNA and RNA. These changes are coordinate with meiotic processing of the maternal chromatin, and often result in behaviors asynchronous with the maternal chromatin. For example, in eggs fertilized during meiosis, the sperm nucleus decondenses while the maternal chromatin remains condensed. A model is presented that suggests some reasons why this puzzling behavior exists. Defects in any of the processes attending male pronuclear development often result in infertility. New assisted reproductive technologies have been developed that ensure delivery of the sperm nucleus to the egg cytoplasm so that a healthy embryo is produced. An emerging challenge is to further characterize the molecular mechanisms that control sperm nuclear transformations and link these to causes of human infertility. Further understanding of this basic process promises to revolutionize our understanding of the mystery of the beginning of new life.

Changes in protamine 1 distribution in human sperm nucleus during in vitro sperm-oocyte interaction: an immunoelectron microscopic study

OBJECTIVE

To determine whether the process of sperm nuclear destabilization would begin before sperm-oocyte fusion in humans.

DESIGN

Changes in the distribution of human protamine 1 were investigated in human spermatozoa from the ejaculate, in spermatozoa selected by swim-up or Percoll techniques, and in spermatozoa bound to zona pellucida (ZP) from oocytes that failed to fertilize in an IVF program.

SETTING

Center for Infertility and Assisted Reproductive Technology, and university departments.

PATIENT(S)

Fifteen couples undergoing an IVF program.

INTERVENTION(S)

Women underwent a similar superovulation induction protocol that consisted of GnRH agonist associated with hMG.

MAIN OUTCOME MEASURE(S)

Comparative immunoelectron microscopic study of sperm nucleus labeling with an anti-human protamine 1 specific protamine monoclonal antibody.

RESULT(S)

After selection by swim-up or by Percoll, spermatozoa show a significantly lower nuclear labeling than in the ejaculate. After binding to the ZP, labeling increases, more in spermatozoa selected by swim-up than by Percoll, but, after Percoll selection, labeling in zona-bound spermatozoa is lower than in the ejaculate.

CONCLUSION(S)

In humans sperm binding to the ZP induces differences in the accessibility of the anti-human protamine 1 antibody, which are consistent with structural rearrangements of the DNA-nucleoproteins complex. These modifications must be a prelude to sperm decondensation, protamines replacement by histones, and subsequent reactivation of the sperm genome in the oocyte.

Hybrid nucleoprotein particles containing a subset of male and female histone variants form during male pronucleus formation in sea urchins

To determine the changes in chromatin organization during male pronucleus remodeling, we have compared the composition of nucleoprotein particles (NP-ps) resulting from digestion with endogenous nuclease (ENase) and with micrococcal nuclease (MNase). Whole nuclei were isolated from sea urchin gametes and zygotes containing partially decondensed (15 min postinsemination, p.i.) or a fully decondensed (40 min p.i.) male pronucleus and digested with nucleases. The NP-ps generated were analyzed in agarose gels, and their histone composition was determined. Sperm core histones (SpH) and cleavage stage (CS) variants were identified by Western immunoblots revealed with specific antibodies. A single NP-ps was generated after digestion of sperm nucleus with MNase, which migrated in agarose gels between DNA fragments of 1.78-1.26 Kb. Sperm chromatin remained undigested after incubation in ENases activating buffer, indicating that these nuclei do not contain ENases. One type of NP-ps was obtained by digestion of unfertilized egg nuclei, either with ENase or MNase; the NP-ps was located in the region of the agarose gel corresponding to DNA fragments of 3.4-1.95 Kb [Imschenetzky et al. (1989): Exp Cell Res 182:436-444]. When whole nuclei from zygotes containing the female pronucleus and a partially remodeled male pronucleus were digested with ENase, a single NP-ps was generated, which migrated between DNA fragments of 2.5-1.9 Kb. This particle contained only CS histone variants. Alternatively, when these nuclei were digested with MNase, two NP-ps were generated; the slower migrating NP-ps (s) was located in the same position of the agarose gel as those resulting from ENase digestion and the faster migrating NP-ps (f) migrated between DNA fragments of 1.95-1.26 Kb. It was found that NP-ps (s) contained only CS histone variants, whereas NP-ps (f) were formed by a subset of SpH and by CS histone variants. When nuclei from zygotes containing a fully decondensed male pronucleus were digested either with ENase or MNase, a single type of NP-ps was observed, which migrated in the same position as NP-ps (s) in agarose gels. This particle contained only CS histone variants. On the basis of the histone compositions and on electrophoretic similarities, it was concluded that NP-ps (s) originated from the female pronucleus and that NP-ps (f) were generated from the partially remodeled male pronucleus. Consequently, our results indicate that at an intermediate stage of male pronucleus remodeling the chromatin is formed by NP-ps containing a subset of both SpH and of CS histone variants, whereas at final stages of male pronucleus decondensation chromatin organization is similar to that of the female pronucleus.

Intracytoplasmic injection of human sperm into the hamster oocyte (hamster ICSI assay) as a test for fertilizing capacity of the severe male-factor sperm

OBJECTIVE

Our objective was to investigate the fertilizing ability of human sperm from severe male-factor patients, by microinjection of single sperm into the hamster oocyte.

DESIGN

Semen samples of severe male factor either with a 0% penetration rate in the zona-free hamster test or with a very low number of motile sperm for which performing the standard penetration test was impossible were used. For the control study, oligozoospermic semen samples with at least 10% penetration rate in zona free hamster test were used.

SETTING

All materials were collected from the National University Hospital, Singapore.

METHODS

There were 10 patients in both the experimental and the control groups. Intracytoplasmic sperm injection (ICSI) was carried out. The main outcome measures were sperm head decondensation and pronuclear formation.

RESULTS

Twenty-one percent of the injected sperm could decondense and undergo male pronuclear formation. This rate was not significantly different from that in the control study group (28%; P = 0.13). A small proportion of the oocytes was damaged during the procedure (9.2 and 8.75% in experimental and control groups, respectively).

CONCLUSIONS

Hamster-ICSI assay may be of benefit in predicting the sperm's ability for further development before allowing the patient to undergo the clinical program.

DNA synthesis and pronucleus development in pig zygotes obtained in vivo: an autoradiographic and ultrastructural study

Porcine zygotes flushed from oviducts 48, 52, 56, 60, or 64 hr after hCG were incubated 30 min in 3H-thymidine, transferred to nonradioactive medium for 2 hr, and incubated for 30 min with 14C-thymidine. After this procedure, ova were prepared (i.e., at 51, 55, 59, 63, or 67 hr after hCG) for autoradiography and ultrastructural observations, respectively. The first autoradiographic labelling, i.e., DNA synthesis, was observed at 56-56.5 hr after hCG, while the latest labelling was seen at 60-60.5 hr. At 51 hr after hCG, formation of the pronuclear envelope was observed, while no nucleolus precursor bodies or prestages to these structures were found. At 55 hr a few clusters of small electron-dense granules were observed, together with condensed chromatin in the pronuclei. At 59 hr the apposed regions of both pronuclei contained nucleolus precursor bodies and condensed chromatin, in close contact with both clusters of small granules and clusters of an additional category of large granules and the nuclear envelope. Additionally, large accumulations of the small granules were found in the vicinity of similarly sized accumulations of the large granules without chromatin association. At 63 hr the spherical accumulations of large granules on some occasions presented a central vacuole, and condensed chromatin and clusters of small granules were attached to its periphery. Within the vacuole, electron-dense material was found.(ABSTRACT TRUNCATED AT 250 WORDS)

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.

Inhibition of protein kinases by 6-dimethylaminopurine accelerates the transition to interphase in activated mouse oocytes

Mouse oocyte activation is followed by a peculiar period during which the interphase network of microtubules does not form and the chromosomes remain condensed despite the inactivation of MPF. To evaluate the role of protein phosphorylation during this period, we studied the effects of the protein kinase inhibitor 6-dimethylaminopurine (6-DMAP) on fertilization and/or parthenogenetic activation of metaphase II-arrested mouse oocytes. 6-DMAP by itself does not induce the inactivation of histone H1 kinase in metaphase II-arrested oocytes, and does not influence the dynamics of histone H1 kinase inactivation during oocyte activation. However, 6-DMAP inhibits protein phosphorylation after oocyte activation. In addition, the phosphorylated form of some proteins disappear earlier in oocytes activated in the presence of 6-DMAP than in the activated control oocytes. This is correlated with the acceleration of some post-fertilization morphological events, such as sperm chromatin decondensation and its transient recondensation, formation of the interphase network of microtubules and pronuclear formation. In addition, numerous abnormalities could be observed: (1) the spindle rotation and polar body extrusion are inhibited; (2) the exchange of protamines into histones seems to be impaired, as judged by the morphology of DNA fibrils by electron microscopy; (3) the formation of a new nuclear envelope around the sperm chromatin proceeds prematurely, while recondensation is not yet completed. These observations suggest that the 6-DMAP-sensitive kinase(s) is (are) involved in the control of post-fertilization events such as the formation of the interphase network of microtubules, the remodelling of sperm chromatin and pronucleus formation.

Differential chromatin condensation of female and male pronuclei in mouse zygotes

Mouse zygotes or halves of zygotes, containing either a female or a male pronucleus, were fused with ovulated metaphase II oocytes. In 59.7% of the resulting hybrid cells, the pronuclei underwent premature chromosome condensation (PCC). In some of these heterokaryons the 2 pronuclei differed in the dynamics of condensation. Detectability of differential PCC of pronuclei (dPCC) depended on the type of preparation. In hybrids with PCC, produced by fusion of intact zygotes with metaphase II oocytes and processed for whole-mount preparations, one pronucleus was more advanced in the condensation process in 47% of cases. In air-dried preparations dPCC was detected in as many as 94% of hybrids. Experiments with the fusion of halves of zygotes with metaphase II oocytes have shown that the differential reaction of pronuclei to condensation factor depended on their parental origin. Maternal chromatin responded faster to the condensation factor and attained more advanced stages of PCC than paternal chromatin. Different responses of the maternal and paternal pronucleus to the condensation factor suggests that the 2 pronuclei are not identical with regard to the organization of chromatin and/or the lamin composition of the nuclear envelope.

Chromatin remodeling in mammalian zygotes

With sperm-egg fusion at the time of fertilization the gamete nuclei are remodeled from genetically quiescent structures into pronuclei capable of DNA synthesis. Features of this process that are critical to insure the genetic integrity of the zygote and the success of subsequent embryonic development include: oocyte responses that prevent polyspermy; completion of the 2nd meiotic division by the oocyte; exchange of proteins in the sperm nucleus; and, remodelling of the oocyte chromosomes and sperm nucleus into functional pronuclei. Elucidation of the biological and molecular mechanisms underlying zygote formation and chromatin remodeling should enhance our understanding of the potential vulnerability of the zygote to toxicant-induced damage.

Characterization of the ooplasmic factor inducing decondensation of and protamine removal from toad sperm nuclei: involvement of nucleoplasmin

Immunohistochemical studies with antiserum against the protamines of the toad, Bufo japonicus, revealed that the sperm nucleus loses protamines within 5 min after entry into the egg. Likewise, lysolecithin-permeabilized sperm incubated with the egg extract lose the protamines within 1 min, accompanied by nuclear decondensation. The activities that induce both protamine removal and decondensation in sperm nuclei were found in extracts from growing and mature oocytes and pregastrula embryos, but not in postneurula embryos or adult tissues. SDS-PAGE analyses revealed that the egg extract removed not only protamines from the Bufo sperm, but also selectively the sperm-specific basic proteins from sperm nuclei of Xenopus laevis. The protamine-removing activity (PRA) was partially purified from egg extracts as negatively charged macromolecules by anion-exchange chromatography and gel filtration. The PRA was heat-stable (100 degrees C, 10 min) and sensitive to proteinase K, but not to RNase A and DNase I. Immunoblot analysis of the supernatant after incubation of Bufo sperm in the fraction with the PRA revealed that protamines derived from sperm nuclei were associated with a major protein of the fraction. This protein exhibited mobilities of 140 and 36 kDa on native- and SDS-PAGE, respectively, with the isoelectric points in the range 4.2 to 4.5 and possessed an amino acid composition quite similar to that reported for Xenopus nucleoplasmin. We propose that in fertilized eggs the protamines are removed from sperm nuclei by nucleoplasmin by binding to but not by enzymatic degradation of the protamine.

Immunobiochemical evidence for the loss of sperm specific histones during male pronucleus formation in monospermic zygotes of sea urchins

To obtain information on the remodeling of sperm chromatin during male pronuclei formation, we have followed the sperm specific histones (SpH) that form the nucleosomal core by Western immunoblot analysis with polyclonal antibodies directed against the core SpH. The results obtained indicate that the complete set of SpH is absent from zygote chromatin at the beginning of the first S phase. The disappearance of SpH is not coincidental for the five histone classes: SpH4 and SpH3 are lost 5-15 min post insemination (p.i.), SpH2B and SpH2A disappear 20-40 min p.i., and SpH1 is progressively diminished up to 30 min p.i. This order of sperm chromatin remodeling is not affected by the inhibition of protein synthesis by emetine, indicating that the factor(s) responsible for SpH disappearance are present in unfertilized eggs. The lost SpH's are not replaced by newly synthesized CS variants, since the basic proteins synthesized de novo during male pronuclei formation are not incorporated into chromatin remaining in the cytoplasm. These newly synthesized proteins are different from the CS variants as judged by their electrophoretic migration.

Pronuclear formation in starfish eggs inseminated at different stages of meiotic maturation: correlation of sperm nuclear transformations and activity of the maternal chromatin

Changes in sperm nuclei incorporated into starfish, Asterina miniata, eggs inseminated at different stages of meiosis have been correlated with the progression of meiotic maturation. A single, uniform rate of sperm expansion characterized eggs inseminated at the completion of meiosis. In oocytes inseminated at metaphase I and II the sperm nucleus underwent an initial expansion at a rate comparable to that seen in eggs inseminated at the pronuclear stage. However, in oocytes inseminated at metaphase I, the sperm nucleus ceased expanding by meiosis II and condensed into chromosomes which persisted until the completion of meiotic maturation. Concomitant with the formation and expansion of the female pronucleus, sperm chromatin of oocytes inseminated at metaphase I enlarged and developed into male pronuclei. Condensation of the initially expanded sperm nucleus in oocytes inseminated at metaphase II was not observed. Instead, the enlarged sperm nucleus underwent a dramatic increase in expansion commensurate with that taking place with the maternal chromatin to form a female pronucleus. Fusion of the relatively large female pronucleus and a much smaller male pronucleus was observed in eggs fertilized at the completion of meiotic maturation. In oocytes inseminated at metaphase I and II, the male and female pronuclei, which were similar in size, migrated into juxtaposition, and as separate structures underwent prophase. The chromosomes in each pronucleus condensed, intermixed, and became aligned on the metaphase palate of the mitotic spindle in preparation for the first cleavage division. These observations demonstrate that the time of insemination with respect to the stage of meiotic maturation has a significant effect on sperm nuclear transformations and pronuclear morphogenesis.

Anucleate fragments of parthenogenetic eggs and of maturing oocytes contain complementary factors required for development of a male pronucleus

Eight-h-old anucleate fragments of artificially activated mouse oocytes produced within 30 min after activation were fused with anucleate fragments of ovarian oocytes bisected at the GV stage and matured in vitro for 4-5 h. The resulting cybrids were inseminated soon after fusion and fixed 3-4 h or 14 h later. After 3-4 h of culture most of the sperm nuclei underwent decondensation. Early male pronuclei were observed sporadically. After overnight culture small or fully formed male pronuclei were present in monospermic and dispermic cybrids. The abortive nuclei, designated as stage IIa (earlier described by Borsuk and Tarkowski, 1989) were also observed and their occurrence was strongly correlated with the rate of polyspermy. In unfused (control) anucleate fragments of maturing and activated oocytes inseminated at the same time as the cybrids, male pronuclei were never observed. These results show that the cytoplasms of activated eggs and of maturing oocytes contain complementary factors required for the transformation of the sperm nucleus into the male pronucleus. The former has lost the capability to break down the sperm nucleus envelope but contains factors required for pronuclear growth. The latter is able only to initiate the process of transformation, i.e., to break down the nuclear envelope and decondense the denuded sperm chromatin. However, the activity of the factor responsible for nuclear envelope breakdown is limited because in cybrids penetrated by more than two spermatozoa, transformation of sperm nuclei was usually abnormal.

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 anucleate 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 pronuclear 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.

Molecular probes for general testicular and specific spermatogenic function

Northern analysis of human testis poly(A+) RNA with a mixture of oligonucleotide primer extended cDNA probes revealed several similar RNAs. These RNAs were subsequently cloned into a VPCS (vector-primer-cloner-sequencer) plasmid. One of these clones, NDHu1, was represented within the library a number of times and hybridized strongly to a poly(A+) RNA of congruent to 1.2 kb. Sequence analysis identified this clone as the URF 1 subunit of the mitochondrial NADH dehydrogenase (NDHu1). Comparison of the relative levels of the NDHu1 and human protamine 1 (HP1) transcripts revealed that HP1 was less abundant than NDHu1. This was unexpected, since it is known that within differentiating mammalian spermatid cells, protamine (HP1) is an abundant transcript. This suggested that the ratio of the relative levels of these two very different mRNAs was indicative of the relationship between specific spermatogenic function (germ cell transcription, determined by the level of the HP1 transcript) and general testicular cell function (determined by the level of the mitochondrial mRNAs, i.e. NDHu1). This correlation was maintained when several individuals expressing various degrees of testicular dysfunction were examined. This study suggests that these probes may be useful markers for general testicular and specific spermatogenic function.

Chromatin topology during the transformation of the mouse sperm nucleus into pronucleus in vivo

Time relationships of sperm chromatin dispersion and sperm nucleoprotein replacement have been studied in vivo, by an in situ cytochemical approach. We used the Feulgen reaction to reveal DNA, which allow us to record both processes simultaneously, on the basis of the return after fertilization to haploid Feulgen values after sperm nucleoprotein replacement with somatic histones. We have shown that sperm nucleoprotein replacement occurs at around anaphase II, whereas sperm chromatin dispersion is massive between the anaphase and telophase II oocyte phases. The morphological pattern of sperm chromatin dispersion supports the idea that the process involves the whole sperm chromatin mass simultaneously, with the region located between the implantation fossa and the postacrosomial region the last to swell.

DNA synthesis following microinjection of heterologous sperm and somatic cell nuclei into hamster oocytes

We have investigated the ability of the hamster oocyte to initiate DNA synthesis in nuclei differing in basic protein content. DNA synthesis was studied by autoradiography in oocytes that had been incubated in 3H-thymidine after being parthenogenetically activated by sham microinjection, or microinjected with hamster, mouse, rabbit, or fish sperm nuclei, or hamster hepatocyte nuclei. Within 6 hr of sham or nucleus microinjection, nuclei of each type underwent transformation into pronuclei and synthesized DNA. These results demonstrated that the hamster egg can access and utilize its own and each type of template provided, whether homologous or heterologous. However, pronuclei derived from hamster sperm nuclei were more likely to be synthesizing DNA at 6 hr than pronuclei derived from sperm nuclei of other species. We conclude that the mechanisms employed by the hamster oocyte to transform hamster sperm nuclei into pronuclei and to effect DNA synthesis in these nuclei are not specific for the hamster sperm nucleus. Nevertheless, these mechanisms apparently operate more efficiently when the hamster sperm nucleus, rather than a heterologous sperm nucleus, is present.

Isolation and characterization of a cDNA clone encoding testis protamine Z1 from the dog-fish Scylliorhinus caniculus

A clone containing a 445-bp cDNA insert was isolated from a cDNA library synthesized from dog-fish testes mRNA. The nucleotide sequence was determined and corresponded to a 50-amino-acid protein. The known five-amino-acid N-terminal sequence corresponded exactly to our deduced amino acid sequence. After in vitro transcription of this cDNA using SP6 RNA polymerase, the translated polypeptide comigrated with the Z1 scylliorhinine marker. Analysis of the cDNA 3' flanking region of our Scylliorhinus protamine Z1 revealed an inverted repeat sequence, an ACAA motif and a CAGGAAAGA box known as regulatory signals for transcription termination in histone genes. In addition, sequences homologous to the simian virus (SV 40) and polyoma virus core enhancer elements were identified in the 5' and 3' flanking regions.

Degradation of sperm histones in vitro by cytoplasm of the sea urchin egg

Sperm-specific histone variants in the sea urchin Paracentrotus lividus are replaced early after fertilization with a specific embryonic set of histone variants. A possible in vitro model for the involvement of a degradation mechanism in the replacement of sperm-specific histones is presented. Soluble sperm histones are shown to be degraded quickly by egg cytoplasm. The proteolytic activity is maximal at pH 3.0; H1 and H2A histones are the most sensitive while H3 and H4 are the most resistant. H2B histones have an intermediate sensitivity. Histone degradation by egg cytoplasm or by purified fractions of it can be inhibited by chymostatin and leupeptin and, to a lesser degree, by pepstatin.

Nucleotide sequence of a cDNA clone encoding Scylliorhinus caniculus protamine Z2

A cDNA library was constructed from a protamine-enriched fraction of dogfish (Scylliorhinus caniculus) mRNA. The nucleotide sequence of a 440-bp insert was determined, and its produced protein sequence confirmed its identification as a cysteine-rich protamine Z2 [Martinage, A., Gusse, M., Belaiche, D., Sautiere, P. and Chevaillier, P. (1985) Biochim. Biophys. Acta 831, 172-178]. The frequency of utilization of the different triplets coding for arginine, which represents 30-70% of the total amino acid residues for trout, mouse and dogfish protamines, is discussed. An alternative repetitive sequence of CGC-AGG was found in the N terminus of the protein. Analysis of the 3' flanking region after the mRNA-terminating TAA codon identified an inverted repeat sequence and an ACCA sequence, which may be possible vestiges of a histone-like termination signal.

Transformation of sperm nuclei to metaphase chromosomes in the cytoplasm of maturing oocytes of the mouse

Zona-free oocytes of the mouse were inseminated at prometaphase I or metaphase I of meiotic maturation in vitro, and the behavior of the sperm nuclei within the oocyte cytoplasm was examined. If the oocytes were penetrated by up to three sperm, maturation continued during subsequent incubation and became arrested at metaphase II. Meanwhile, each sperm nucleus underwent the following changes. First, the chromatin became slightly dispersed. By 6 h after insemination, this dispersed chromatin had become coalesced into a small mass, from which short chromosomal arms later became projected. Between 12 and 18 h after insemination, each mass of chromatin became resolved into 20 discrete metaphase chromosomes. In contrast, if oocytes were penetrated by four to six sperm, oocyte meiosis was arrested at metaphase I, and each sperm nucleus was transformed into a small mass of chromatin rather than into metaphase chromosomes. If oocytes were penetrated by more than six sperm, the maternal chromosomes became either decondensed or pycnotic, and the sperm nuclei were transformed into larger masses of chromatin. As control experiments, immature and fully mature metaphase II oocytes were inseminated. In the immature oocytes, which were kept immature by exposure to dibutyryl cyclic AMP, no morphological changes in the sperm nucleus were observed. On the other hand, in the fully mature oocytes, which were activated by sperm penetration, the sperm nucleus was transformed into the male pronucleus. Therefore, the cytoplasm of the maturing oocyte develops an activity that can transform the highly condensed chromatin of the sperm into metaphase chromosomes. However, the capacity of an oocyte is limited, such that it can transform a maximum of three sperm nuclei into metaphase chromosomes. Furthermore, the presence of more than six sperm causes a loss of the ability of the oocyte to maintain the maternal chromosomes in a metaphase state.

Remodeling of sperm chromatin following fertilization: nucleosome repeat length and histone variant transitions in the absence of DNA synthesis

Within the first cell cycle following fertilization the average nucleosomal repeat length of sea urchin male pronuclear chromatin declines by 30-40 base pairs to a value typical of that found in the embryo. This decline occurs after a lag of about 30 min postfertilization, and is accompanied by replication of the male chromatin and accumulation of cleavage-stage (CS) core histone variants. When replication is inhibited by greater than 95% with aphidicolin, the decline in repeat length still occurs, although it is slightly retarded. The decline in repeat length also occurs when protein synthesis is blocked by greater than 98% and DNA synthesis by 60-70% with emetine. The adjustment of nucleosome repeat length therefore can occur in vivo without extensive movement of replication forks across the length of the chromatin, or normal progression of the cell cycle, and appears to require no proteins synthesized postfertilization. Blocking of DNA synthesis or protein synthesis also does not prevent the normal histone variant transitions involved in male pronuclear chromatin remodeling. Although their accumulation is slowed, CS core variants eventually become the predominant male pronuclear histones in their classes when replication is inhibited. Since a shortening of the average nucleosomal repeat length of approximately 10-20% is not sufficient to account for this large acquisition of CS variants, some of the sperm (Sp) core histones are probably displaced from the replication-blocked pronucleus. Therefore, accumulation of CS H2A and CS H2B are temporally correlated with the repeat length transition, whereas replication, normal progression of the cell cycle, and the early histone transitions involving SpH1 and SpH2B are not.

A cytochemical study of nuclear changes in fertilized hamster eggs

Nucleoprotein changes during male and female pronuclear development have been examined in fertilized hamster eggs utilizing the ammoniacal silver reaction (ASR) at the light and ultrastructural levels of observation. Prior to its incorporation, the paternally derived chromatin was heavily laden with ASR product. Immediately upon gamete fusion the sperm nucleus underwent a dramatic increase in staining, suggesting an augmentation in the availability of reactive sites already present in the sperm nucleus or an accumulation of "new" reactive sites from the egg cytoplasm. With subsequent transformations of the sperm nucleus into a male pronucleus, there was a progressive reduction in ASR product associated with the paternal chromatin. Concomitantly, the condensed maternal chromosomes remaining in the zygote after the conclusion of meiosis dispersed and developed into a female pronucleus; these changes were accompanied by a progressive decrease in ASR staining. At the conclusion of pronuclear development, the morphologically similar male and female pronuclei were diffusely stained with the ASR. The increase in ASR staining of the sperm nucleus immediately following gamete fusion demonstrates a major effect of the egg cytoplasm on the paternal chromatin that, heretofore, has not been recognized. This augmentation and the following decrease in ASR staining may reflect changes in nucleoproteins during pronuclear development. Differences in nuclear staining are discussed in light of previous studies of nucleoprotein transitions at fertilization.

Turnover of basic chromosomal proteins in fertilized eggs: a cytoimmunochemical study of events in vivo

The chromosomal complements of mouse oocytes, ova, and fertilizing sperm have been studied by immunofluorescence with specific antisera to the basic protein fraction of sperm nuclei and to histones H2b and H4, and by staining with ethidium bromide. These studies support the hypothesis, previously proposed (Rodman and Barth, 1979, Dev. Biol. 68:82-95), that the chromosomes of the oocyte in maturation incorporate unique basic protein(s) similar to those incorporated during spermiogenesis. That similarity is characterized, here, by immunologic cross-reactivity. The basic proteins of the fertilizing sperm nucleus and the cross-reactive moiety of the two haploid complements of the ovum are displaced simultaneously, shortly after sperm entry. However, because the unique basic proteins incorporated into the oocyte chromosomes do not, as in the spermatogenic sequence, entirely replace the histones, the maternal chromosomes display histones H2b and H4 at all postfertilization stages examined, whereas the decondensing paternal complement, for an interval before maturation of the pronuclei, contains neither sperm basic chromosomal proteins nor histones. Sequential staining of the same specimens with ethidium bromide revealed well-organized nuclear morphology of the residual DNA complex. Those observations suggest that, for an as yet undefined period in the transformation from spermatozoal to embryonic genome, the chromatin is devoid of a complement of basic proteins.

A study of hetero-specific sperm-egg interactions in the rat, mouse, and deer mouse using in vitro fertilization and sperm injection

Hetero-specific fertilization of zone-free eggs is used in these experiments as a tool to analyze the barriers to hybridization and to gain insight into the mechanisms of normal fertilization. When the zonae of rat eggs, which are a barrier to hetero-specific fertilization, are removed with pronase, the eggs can be fertilized by mouse sperm and the zygotes start to develop normally. A rat egg fertilized with mouse sperm completes meiosis and forms both male and female pronuclei. Chromosomes from both parents are found on he spindle at the metaphase stage of the first cleavage division. Under present culture conditions, embryos develop only to the two-cell stage, but this initial development of the hybrid is apparently normal. The question of whether sperm and egg membrane fusion is requisite for normal development is addressed by injecting sperm directly into the cytoplasm of unfertilized eggs. The injection of mouse sperm into rat eggs frequently leads to activation and formation of male and female pronuclei. The first cleavage division is indistinguishable from that following hetero-specific fertilization. Capacitated and uncapacitated sperm react alike when injected into eggs. Egg activation, however, is necessary for male pronucleus formation. Sperm from the deer mouse Peromyscus maniculatus bairdii, which are incapable of fertilizing even zonea-free eggs, respond like mouse sperm when injected into rat eggs. These data indicate that sperm interactions with the egg cytoplasm are less species-specific than interactions at the egg surface. Furthermore, the normal surface interactions of sperm and eggs are not essential for the start of development.