Intracytoplasmic sperm injection: stiletto conception or a stab in the dark

To describe the importance of molecular and cellular analyses in intracytoplasmic sperm injection (ICSI) the authors review the literature on biological challenges in ICSI and associated techniques. Several matters can be proposed in molecular and cellular challenges in ICSI for safety and efficacy: (1) a reliable and convenient animal model for understanding the molecular and cellular basis of human ICSI must be established, and molecular and cellular analysis of the first cell cycle of human fertilization should be better understood; (2) a proper assay for human sperm function that contributes to the indication for ICSI should be developed; and (3) de novo and transmitted genetic security in ICSI should be examined.

Arrest of cell cycle progression during first interphase in murine zygotes microinjected with anti-PCM-1 antibodies

To investigate the function of the centrosome protein PCM-1, antibodies against PCM-1 were microinjected into either germinal vesicle stage meiotic oocytes or fertilized mouse eggs, and cell cycle progression events (i.e., microtubule assembly, chromosome and centrosome organization, meiotic maturation) were assayed. These studies determined that microinjected PCM-1 antibodies arrested cell cycle progression, with anti-PCM-1 arresting fertilized eggs at the pronucleate stage when injected during G1. Analysis of the injected eggs determined that centrosome disruption and microtubule cytaster disorganization accompanied the cell cycle arrest. Anti-PCM-1 blocked neither pronuclear centration, completion of mitosis when microinjected into zygotes at G2, nor meiotic maturation when microinjected into immature oocytes. These results identify a novel role for PCM- 1 in cell cycle regulation, and indicate that PCM-1 must fulfill an essential function for cells to complete interphase.

Fertilization imaged in 2-, 3- and four dimensions: molecular insights for treating infertility

Fertilization in humans follows a complex series of events including binding of the sperm to the oocyte plasma membrane, oocyte activation, the completion of meiotic maturation of the oocyte with the extrusion of the second polar body, the decondensation of the sperm nucleus and the maternal chromosomes into male and female pronuclei and the restoration of the sperm centrosome. This duplicates and separates, forming two mitotic spindle poles upon which the parental genomes can intermix to complete fertilization. The use of intracytoplasmic sperm injection (ICSI) has been highly effective as a treatment for severe male infertility and thousands of ICSI babies have been born world-wide. Working with rhesus monkey gametes, we have developed a preclinical animal model for understanding the cell biological basis of ICSI. Typically, ICSI results in abnormal nuclear remodeling during sperm decondensation due to the presence of the sperm acrosome and perinuclear structures normally removed at the oolemma during in vitro fertilization. These unusual modifications raise concerns that the ICSI procedure itself might lead to the observed increase in chromosome anomalies reported for

Cytoskeletal aspects of assisted fertilization

During mammalian fertilization, the zygotic centrosome organizes a large sperm aster, critical for uniting the male and female pronuclei prior to first mitosis. Fluorescent imaging of inseminated human oocytes has shown that centrosomal defects may result in abnormal microtubule nucleation preventing genomic union, suggesting a novel cause of fertilization failure. Working with rhesus monkey gametes, we have developed a preclinical model for understanding the cell biological basis of intracytoplasmic sperm injection (ICSI). Typically, ICSI results in abnormal nuclear remodeling during sperm decondensation due to the presence of the sperm acrosome and perinuclear theca, structures normally removed at the oolemma during IVF; this is turn causes a delay in the onset of DNA synthesis. These unusual modifications raise concerns that the ICSI procedure itself may result in chromatin damage during DNA decondensation and further highlight the need for a more rigorous assessment of methods of assisted reproduction prior to their global application.

Transgenic monkeys produced by retroviral gene transfer into mature oocytes

Transgenic rhesus monkeys carrying the green fluorescent protein (GFP) gene were produced by injecting pseudotyped replication-defective retroviral vector into the perivitelline space of 224 mature rhesus oocytes, later fertilized by intracytoplasmic sperm injection. Of the three males born from 20 embryo transfers, one was transgenic when accessible tissues were assayed for transgene DNA and messenger RNA. All tissues that were studied from a fraternal set of twins, miscarried at 73 days, carried the transgene, as confirmed by Southern analyses, and the GFP transgene reporter was detected by both direct and indirect fluorescence imaging.

Contractile apparatus of the normal and abortive cytokinetic cells during mouse male meiosis

Mouse male meiotic cytokinesis was studied using immunofluorescent probes against various elements of cytokinetic apparatus and electron microscopy. In normal mice, some spermatocytes fail to undergo cytokinesis after meiotic I or II nuclear divisions, forming syncytial secondary spermatocytes and spermatids. Abnormal cytokinetic cells develop sparse and dispersed midzone spindles during the early stage. However, during late stages, single and compact midzone spindles are formed as in normal cells, but localize asymmetrically and attach to the cortex. Myosin and f-actin were observed in the midzone spindle and midbody regions of normally cleaving cells as well as in those cells that failed to develop a cytokinetic furrow, implying that cytokinetic failure is unlikely to be due to defect in myosin or actin assembly. Depolymerization of microtubules by nocodazole resulted in the loss of the midbody-associated f-actin and myosin. These observations suggest that actin-myosin localization in the midbody could be a microtubule-dependent process that may not play a direct role in cytokinetic furrowing. Anti-centrin antibody labels the putative centrioles while anti-(gamma)-tubulin antibody labels the minus-ends of the midzone spindles of late-stage normal and abnormal cytokinetic cells, suggesting that the centrosome and midzone spindle nucleation in abnormal cytokinetic cells is not different from those of normally cleaving cells. Possible use of mouse male meiotic cells as a model system to study cytokinesis has been discussed.

ICSI choreography: fate of sperm structures after monospermic rhesus ICSI and first cell cycle implications

We have dissected the initial stages of fertilization by intracytoplasmic sperm injection of single spermatozoa into prime oocytes from fertile rhesus monkeys (Macaca mulatta). DNA decondensation was delayed at the apical portion of the sperm head. It is possible that this asynchronous male DNA decondensation could be related to the persistence of the sperm acrosome and perinuclear theca after injection. However, incomplete male pronuclear formation did not prevent sperm aster formation, microtubule nucleation and pronuclear apposition. In contrast, DNA synthesis was delayed in both pronuclei until the sperm chromatin fully decondensed, indicating that male pronuclear formation constitutes an important checkpoint during the first embryonic cell cycle.

Ubiquitinated sperm mitochondria, selective proteolysis, and the regulation of mitochondrial inheritance in mammalian embryos

The strictly maternal inheritance of mitochondria and mitochondrial DNA (mtDNA) in mammals is a developmental paradox promoted by an unknown mechanism responsible for the destruction of the sperm mitochondria shortly after fertilization. We have recently reported that the sperm mitochondria are ubiquitinated inside the oocyte cytoplasm and later subjected to proteolysis during preimplantation development (P. Sutovsky et al., Nature 1999; 402:371-372). Here, we provide further evidence for this process by showing that the proteolytic destruction of bull sperm mitochondria inside cow egg cytoplasm depends upon the activity of the universal proteolytic marker, ubiquitin, and the lysosomal apparatus of the egg. Binding of ubiquitin to sperm mitochondria was visualized by monospecific antibodies throughout pronuclear development and during the first embryonic divisions. The recognition and disposal of the ubiquitinated sperm mitochondria was prevented by the microinjection of anti-ubiquitin antibodies and by the treatment of the fertilized zygotes with lysosomotropic agent ammonium chloride. The postfecundal ubiquitination of sperm mitochondria and their destruction was not seen in the hybrid embryos created using cow eggs and sperm of wild cattle, gaur, thus supporting the hypothesis that sperm mitochondrion destruction is species specific. The initial ligation of ubiquitin molecules to sperm mitochondrial membrane proteins, one of which could be prohibitin, occurs during spermatogenesis. Even though the ubiquitin cross-reactivity was transiently lost from the sperm mitochondria during epididymal passage, likely as a result of disulfide bond cross-linking, it was restored and amplified after fertilization. Ubiquitination therefore may represent a mechanism for the elimination of paternal mitochondria during fertilization. Our data have important implications for anthropology, treatment of mitochondrial disorders, and for the new methods of assisted procreation, such as cloning, oocyte cytoplasm donation, and intracytoplasmic sperm injection.

Centriole and centrin degeneration during mouse spermiogenesis

Centrosome reduction during mouse spermiogenesis has been studied by immunofluorescent microscopy using anticentrin antibody (20H5) and TEM. Centrin is detected as two spots in round spermatids, corresponding to a pair of centrioles. In elongating spermatids, centrin spots colocalize with the centrioles in the neck region, while the perinuclear ring from which manchette microtubules arise, does not label with the antibody 20H5. The proximal centriole of the elongating spermatids develops a prominent adjunct, which assembles an aster of microtubules. TEM studies after immunogold labeling revealed that centrin is associated with the distal and the proximal centrioles, but not with the adjunct. Centrin labeling in the neck region diminishes after spermiation stage, although it is not completely lost from all testicular sperm. Mature epididymal sperm do not display centrin labeling. Mouse sperm lose both distal and proximal centrioles at maturity. Loss of centrin staining appears to correlate with the degeneration of centrioles during mouse spermiogenesis.

Microfilament stabilization by jasplakinolide arrests oocyte maturation, cortical granule exocytosis, sperm incorporation cone resorption, and cell-cycle progression, but not DNA replication, during fertilization in mice

Jasplakinolide (JAS), which induces microfilament polymerization and stabilization, inhibits microfilament-mediated events in murine oocyte maturation and fertilization in a fashion unlike the effects of cytochalasin B (CCB) and latranculin A (LAT A). JAS prevents egg polar body emission at a much lower concentration than either CCB or LAT A. Microfilament bundles were detected on the entire egg cortex after JAS exposure. Conversely, microfilament patterns did not change after exposure to CCB, and few microfilaments were observed after exposure to LAT A. Eggs that were allowed to recover from JAS were unable to recover normal microfilament organization. During oocyte maturation, JAS prevented both spindle migration to the oocyte cortex and first polar body emission. During in vitro fertilization, sperm head entered the eggs and formed pronuclei, but sperm tail entry, pronuclear centration, and second polar body emission were not detected. DNA synthesis occurs in these JAS-treated zygotes. JAS inhibited not only the formation, but also the disassembly, of incorporation cones. JAS was also found to prevent cortical granule exocytosis following artificial activation, and cortical granules were still beneath the plasma membrane even after activation. Finally, incorporation of microinjected nonmuscle actin into the microfilament network of mice eggs was delayed by JAS. We conclude that JAS acts as a microfilament inhibitor during maturation and fertilization and is more powerful than other inhibitors. Its mechanism differs in that it promotes assembly and stabilization of microfilaments. JAS is a novel cell permeable tool for the investigation of microfilament-dependent events in early mammalian development.

Highly degenerated distal centrioles in rhesus and human spermatozoa

In humans and other mammals except rodents, the spermatozoa contribute the proximal centriole during fertilization. The inheritance of the distal centriole is not yet fully clear. In the present work, the distal centrioles of rhesus and human spermatozoa have been studied by transmission electron microscopy. The round and elongating rhesus spermatids possess both proximal and distal centrioles. The distal centriole extends posteriorly as an axoneme while the proximal centriole produces a microtubular adjunct. Ejaculated rhesus and human spermatozoa have intact proximal centrioles, but the distal centrioles have degenerated. The central pair of microtubules of the axoneme extends continuously into the distal centriolar region up to the sperm head. Serial transverse and longitudinal sections of the sperm neck region reveal few scattered microtubule duplexes or triplets in the distal centriolar region. The loss of the centriolar microtubules is more extensive on the ventral side of the neck region, the side where the proximal centriole resides. The distal centriole degenerates caudally from the rostral area. Immunogold electron microscopy with anti-beta-tubulin antibody showed that the distal centriolar regions possess 50% fewer gold particles than the proximal centrioles, indicating a significant loss of centriolar microtubules in the distal centriolar region. The A-tubules of the remaining triplets are filled with a dense material, as observed in the axoneme. Thus, rhesus and human spermatozoa introduce only proximal centrioles intact, whereas the distal centrioles are mostly disorganized in the mature spermatozoa.

Dynamic imaging of the metaphase II spindle and maternal chromosomesin bovine oocytes: implications for enucleation efficiency verification, avoidanceof parthenogenesis, and successful embryogenesis

Manipulations of DNA and cellular structures are essential for the propagation of genetically identical animals by nuclear transfer. However, none of the steps have been optimized yet. This study reports a protocol that improves live dynamic imaging of the unfertilized bovine oocyte's meiotic spindle microtubules with microinjected polymerization-competent X-rhodamine-tubulin and/or with vital long-wavelength excited DNA fluorochrome Sybr14 so that the maternal chromosomes can be verifiably removed to make enucleated eggs the starting point for cloning. Suitability of the new fluorochromes was compared to the conventional UV excitable Hoechst 33342 fluorochrome. Enucleation removed the smallest amount of cytoplasm (4-7%) and was 100% efficient only when performed under continuous fluorescence, i.e., longer fluorescence exposure. This was in part due to the finding that the second metaphase spindle is frequently displaced (60.7 +/- 10%) from its previously assumed location subjacent to the first polar body. Removal of as much as 24 +/- 3% of the oocyte cytoplasm underneath the polar body, in the absence of fluorochromes, often resulted in enucleation failure (36 +/- 6%). When labeled oocytes were exposed to fluorescence and later activated, development to the blastocyst stage was lowest in the group labeled with Hoechst 33342 (3%), when compared to Sybr14 (19%), rhodamine-tubulin (23%), or unlabeled oocytes (37%). This suggests that longer wavelength fluorochromes can be employed for live visualization of metaphase spindle components, verification of their complete removal during enucleation, and avoidance of the confusion between artifactual parthenogenesis versus "cloning" success, without compromising the oocyte's developmental potential after activation.

Cellular and molecular events after in vitro fertilization and intracytoplasmic sperm injection

Intracytoplasmic sperm injection (ICSI) has heralded an era of tremendous improvements in treating male infertility leading to the births of thousands of babies. However, recent concerns over possible long-term effects of ICSI on offspring has prompted the development of a preclinical, nonhuman primate model to assess the safety of ICSI. Fluorescent imaging of rhesus macaque IVF zygotes revealed that this species shares many similarities with humans in terms of cytoskeletal and chromatin dynamics during fertilization. However, rhesus monkey zygotes fertilized by ICSI resulted in abnormal nuclear remodeling leading to asynchronous chromatin decondensation in the apical region of the sperm head, delaying the onset of DNA synthesis. The persistence of the acrosome and perinuclear theca on the apex of sperm introduced into the oocyte by ICSI may constrict the DNA in this region. Despite these differences, normal rhesus monkey ICSI embryos have been produced and have lead to several births after transfer. The irregularities described in this paper raise concerns that the ICSI procedure may result in chromatin damage during DNA decondensation and further highlight the need for devising improved pre-clinical assessment prior to global acceptance of this, and other, novel methods of assisted reproduction.

Optimization Strategies for Production of Mammalian Embryos by Nuclear Transfer

In order to optimize each of the individual steps in the nuclear transfer procedure, we report alternative protocols useful for producing recipient cytoplasts and for improving the success rate of nuclear transfer embryos in cattle, rhesus monkey, and hamster. Vital labeling of maternal chromatin/spindle is accomplished by long wavelength fluorochromes Sybr14 and rhodamine labeled tubulin allowing constant monitoring and verification during enucleation. The use of Chinese hamster ovary (CHO) donor cells expressing the viral influenza hemagglutinin fusion protein (HA-300a+), to adhere and induce fusion between the donor cells and enucleated cow, rhesus and hamster oocytes was examined. Cell surface hemagglutinin was activated with trypsin prior to nuclear transfer and fusion was induced by a short incubation of a newly created nuclear transfer couplet at pH 5.2 at room temperature. Donor cell cytoplasm was dynamically labeled with CMFDA, or further transfected with the green fluorescence protein (GFP) gene, so that fusion could be directly monitored using live imaging. High rates of fusion were observed between CHO donor cells and hamster (100%), rhesus (100%), and cow recipient cytoplasts (81.6%). Live imaging during fusion revealed rapid intermixing of cytoplasmic components between a recipient and a donor cell. Prelabeled donor cytoplasmic components were uniformly distributed throughout the recipient cytoplast, within minutes of fusion, while the newly introduced nucleus remained at the periphery. The fusion process did not induce activation as evidenced by unchanged distribution and density of cortical granules in the recipient cytoplasts. After artificial activation, the nuclear transfer embryos created in this manner were capable of completing several embryonic cell divisions. These procedures hold promise for enhancing the efficiency of nuclear transfer in mammals of importance for biomedical research, agriculture, biotechnology, and preserving unique, rare, and endangered species.

Biparental inheritance of gamma-tubulin during human fertilization: molecular reconstitution of functional zygotic centrosomes in inseminated human oocytes and in cell-free extracts nucleated by human sperm

Human sperm centrosome reconstitution and the parental contributions to the zygotic centrosome are examined in mammalian zygotes and after exposure of spermatozoa to Xenopus laevis cell-free extracts. The presence and inheritance of the conserved centrosomal constituents gamma-tubulin, centrin, and MPM-2 (which detects phosphorylated epitopes) are traced, as is the sperm microtubule-nucleating capability on reconstituted centrosomes. gamma-Tubulin is biparentally inherited in humans (maternal >> than paternal): Western blots detect the presence of paternal gamma-tubulin. Recruitment of maternal gamma-tubulin to the sperm centrosome occurs after sperm incorporation in vivo or exposure to cell-free extract, especially after sperm "priming" induced by disulfide bond reduction. Centrin is found in the proximal sperm centrosomal region, demonstrates expected calcium sensitivity, but appears absent from the zygotic centrosome after sperm incorporation or exposure to extracts. Sperm centrosome phosphorylation is detected after exposure of primed sperm to egg extracts as well as during the early stages of sperm incorporation after fertilization. Finally, centrosome reconstitution in cell-free extracts permits sperm aster microtubule assembly in vitro. Collectively, these results support a model of a blended zygotic centrosome composed of maternal constituents attracted to an introduced paternal template after insemination.

Unique checkpoints during the first cell cycle of fertilization after intracytoplasmic sperm injection in rhesus monkeys

Intracytoplasmic sperm injection has begun an era of considerable improvements in treating male infertility. Despite its success, questions remain about the dangers of transmitting traits responsible for male infertility, sex and autosomal chromosome aberrations and possible mental, physical and reproductive abnormalities. We report here the first births of rhesus monkeys produced by intracytoplasmic sperm injection at rates greater or equal to those reported by clinics. Essential assumptions about this process are flawed, as shown by results with the preclinical, nonhuman primate model and with clinically discarded specimens. Dynamic imaging demonstrated the variable position of the second meiotic spindle in relation to the first polar body; consequently, microinjection targeting is imprecise and potentially lethal. Intracytoplasmic sperm injection resulted in abnormal sperm decondensation, with the unusual retention of vesicle-associated membrane protein and the perinuclear theca, and the exclusion of the nuclear mitotic apparatus from the decondensing sperm nuclear apex. Male pronuclear remodeling in the injected oocytes was required before replication of either parental genome, indicating a unique G1-to-S transition checkpoint during zygotic interphase (the first cell cycle). These irregularities indicate that the intracytoplasmic sperm injection itself might lead to the observed increased chromosome anomalies.

Fertilization and embryo development to blastocysts after intracytoplasmic sperm injection in the rhesus monkey

Notwithstanding the thousands of seemingly healthy children born after intracytoplasmic sperm injection (ICSI), it is not yet possible to conclude absolutely that the ICSI procedure might induce some altered development or that the ICSI protocol might not be improved even further. To address this in a clinically relevant system, the developmental potential of rhesus monkey embryos produced by ICSI is reported. Oocytes collected by laparoscopy from gonadotrophin-stimulated fertile females were fertilized by ICSI using spermatozoa obtained from fertile males by electro-ejaculation. Neither sperm immobilization prior to injection nor an additional chemical stimulus were necessary to achieve oocyte activation and pronuclear formation. Survival and activation of the injected oocytes were judged by the extrusion of the second polar body. Successful fertilization was confirmed by the presence of two pronuclei within 12 h post-ICSI. Some oocytes were fixed and processed for the detection of microtubules and chromatin. Fluorescent labelling revealed that by 12 h post-ICSI the male and female pronuclei were closely apposed and eccentrically positioned within a large microtubule aster. ICSI resulted in a 76.6 +/- 14.9% fertilization rate. First cleavage was completed within 24 h post-ICSI. Two-cell ICSI embryos were co-cultured in CMRL medium on a buffalo rat liver cell monolayer until the hatched blastocyst stage. Oocytes collected laparoscopically from stimulated monkeys can be fertilized by ICSI and will complete preimplantation embryo development in vitro demonstrating that the rhesus monkey is an excellent preclinical model for examining and understanding many aspects of human ICSI.

Assembly of nuclear pore complexes and annulate lamellae promotes normal pronuclear development in fertilized mammalian oocytes

In addition to functional nuclear pore complexes engaged in nucleo-cytoplasmic transport, the cytoplasmic stacks of pore complexes, called annulate lamellae, exist in numerous cell types. Although both annulate lamellae and nuclear pore complexes are present in fertilized mammalian oocytes, their relative roles in the process of fertilization and preimplantation development are not known. Using epifluorescence and electron microscopy, we explored their fate during bovine fertilization. The assembly of annulate lamellae in bovine oocytes was triggered by sperm-oocyte binding and continued concomitantly with the incorporation of the nuclear pores in the nuclear envelopes of the developing male and female pronuclei. This process was also induced by the parthenogenetic activation of metaphase-II-arrested oocytes. Depletion of Ca2+, previously implicated in oocyte activation and in the insertion of pore complexes into the nuclear envelope, prevented the formation of nuclear pore complexes, but not the assembly of annulate lamellae in oocyte cytoplasm. Injection of the nuclear pore antagonist, wheat germ agglutinin, into the cytoplasm of mature oocytes that were subsequently fertilized caused the arrest of pronuclear development, indicating the requirement of nuclear pore complexes for normal pronuclear development. Treatment of the fertilized oocytes with the microtubule inhibitor, nocodazole, prevented gathering of annulate lamellae around the developing pronuclei, insertion of nuclear pores into their nuclear envelopes, and further pronuclear development. The formation of the male pronuclei was reconstituted in Xenopus egg extracts and reflected the behavior of nuclear pores during natural fertilization. These data suggest that nuclear pore complexes are required for normal pronuclear development from its beginning up until pronuclear apposition. Annulate lamellae may be involved in the turnover of nuclear pore complexes during fertilization, which is in turn facilitated by the reorganization of oocyte microtubules and influx of Ca2+ into oocyte cytoplasm.

Differential expression and functions of cortical myosin IIA and IIB isotypes during meiotic maturation, fertilization, and mitosis in mouse oocytes and embryos

To explore the role of nonmuscle myosin II isoforms during mouse gametogenesis, fertilization, and early development, localization and microinjection studies were performed using monospecific antibodies to myosin IIA and IIB isotypes. Each myosin II antibody recognizes a 205-kDa protein in oocytes, but not mature sperm. Myosin IIA and IIB demonstrate differential expression during meiotic maturation and following fertilization: only the IIA isoform detects metaphase spindles or accumulates in the mitotic cleavage furrow. In the unfertilized oocyte, both myosin isoforms are polarized in the cortex directly overlying the metaphase-arrested second meiotic spindle. Cortical polarization is altered after spindle disassembly with Colcemid: the scattered meiotic chromosomes initiate myosin IIA and microfilament assemble in the vicinity of each chromosome mass. During sperm incorporation, both myosin II isotypes concentrate in the second polar body cleavage furrow and the sperm incorporation cone. In functional experiments, the microinjection of myosin IIA antibody disrupts meiotic maturation to metaphase II arrest, probably through depletion of spindle-associated myosin IIA protein and antibody binding to chromosome surfaces. Conversely, the microinjection of myosin IIB antibody blocks microfilament-directed chromosome scattering in Colcemid-treated mature oocytes, suggesting a role in mediating chromosome-cortical actomyosin interactions. Neither myosin II antibody, alone or coinjected, blocks second polar body formation, in vitro fertilization, or cytokinesis. Finally, microinjection of a nonphosphorylatable 20-kDa regulatory myosin light chain specifically blocks sperm incorporation cone disassembly and impedes cell cycle progression, suggesting that interference with myosin II phosphorylation influences fertilization. Thus, conventional myosins break cortical symmetry in oocytes by participating in eccentric meiotic spindle positioning, sperm incorporation cone dynamics, and cytokinesis. Although murine sperm do not express myosin II, different myosin II isotypes may have distinct roles during early embryonic development.

Inheritance defects of the sperm centrosome in humans and its possible role in male infertility

During fertilization in humans, the sperm introduces the centrosome, the oocyte's microtubule organizing centre (MTOC), restoring centrosome function. The newly activated oocyte initiates extrusion of the second polar body and begins pronuclear formation. Apposition of the male and female pronuclei requires microtubule-mediated motility in the form of an aster of microtubules emanating from the sperm centrosome. The centrosome then duplicates and separates, forming the two poles of the mitotic spindle, upon which the parental genomes intermix, completing fertilization. The restoration and function of the centrosome is critical for successful fertilization suggesting that a defective sperm centrosome will lead to fertilization arrest and may be a new cause of male infertility. Several types of fertilization failure, associated with the sperm centrosome, are documented. These include: i) failure of the sperm to nucleate microtubules after sperm incorporation; ii) detachment of the sperm centrosome from the sperm head; and iii) failure in microtubule elongation after successful sperm aster formation. Although some types of severe male infertility can be overcome with the use of intracytoplasmic sperm injection (ICSI), men with defective sperm centrosomes are unlikely to benefit. The rate of sperm aster formation, size and organization during bovine fertilization has been used as a measurement of bovine sperm quality. Sperm from bulls which developed large highly organized sperm asters resulted in a higher rate of fertilization in vitro. The development of an assay using Xenopus laevis oocyte extracts has also been used to test centrosome function and sperm aster formation using sperm from men with questionable fertility. In general, these sperm were incapable of forming sperm asters and when used for in vitro fertilization, resulted typically in fertilization failure. These discoveries on the inheritance and function of the sperm centrosome have revealed a new cause of fertilization failure linked to male infertility which may not be circumvented using ICSI.

Cell and molecular biological challenges of ICSI: ART before science?

Authors discuss the possible genetic and cell biological risks to offspring conceived by ICSI in relation to the lack of fundamental research using relevant animal models.

A casein kinase I isoform is required for proper cell cycle progression in the fertilized mouse oocyte

Casein kinase I is a family of serine/threonine protein kinases common to all eukaryotes. In yeast, casein kinase I homologues have been linked to the regulation of growth, DNA repair and cell division. In addition, their subcellular localization to membraneous structures and the nucleus is essential for function. In higher eukaryotes, there exist seven genetically distinct isoforms: (alpha), ss, (gamma)1, (gamma)2, (gamma)3, (delta) and (epsilon). Casein kinase I(alpha) exhibits a cell cycle-dependent subcellular localization including an association with cytosolic vesicular structures and the nucleus during interphase, and the spindle during mitosis. casein kinase I has also been shown to modulate critical regulators of growth and DNA synthesis/repair in mammalian cells such as SV40 large T antigen and p53. These results suggest that casein kinase I may be involved in processes similar to those ascribed to the yeast casein kinase I homologues. To define a role for casein kinase I(alpha) in cell cycle regulation, the mouse oocyte was utilized because of its well-defined cell cycle and ease of micromanipulation. Immunofluorescence studies from meiosis I of maturation to the first zygotic cleavage demonstrated that the kinase was associated with structures similar to those previously reported. Microinjection of casein kinase I(alpha) antibodies at metaphase II-arrest and G2 phase, had no effect on the completion of second meiosis or first division. However, microinjection of these antibodies during the early pronucleate phase prior to S-phase onset blocked uptake of the kinase into pronuclei and interfered with proper and timely cell cycle progression to first cleavage. These results suggest that the kinase regulates the progression from interphase to mitosis during the first cell cycle.

Microtubule organization and chromatin configurations in hamster oocytes during fertilization and parthenogenetic activation, and after insemination with human sperm

The cytoskeletal components of hamster oocytes, zygotes, and spontaneously activated parthogenotes were examined after immunocytochemical labeling. Microtubules were found only in the anastral, tangentially arranged second meiotic spindle of unfertilized oocytes. Taxol treatment of unfertilized oocytes greatly augmented astral microtubules in both the metaphase II spindle and the cortex. Disruption of the meiotic spindle microtubules with nocodazole resulted in cortical chromosomal scattering. During hamster sperm incorporation and pronuclear formation, no sperm aster was detected in association with the male DNA. Instead, a large overlapping array of microtubules assembled in the cortex. By mitosis, this interphase array disassembled and an anastral metaphase spindle formed. Microtubule and chromatin configurations were also imaged in hamster oocytes injected with human sperm. Astral microtubules were absent from the sperm centrosome. The implications of these results are discussed in relation to the hamster oocyte penetration assay, a test commonly used by in vitro fertilization clinics to demonstrate the fertilizing ability of human sperm. We conclude that since hamsters and humans follow different methods of centrosome inheritance, maternal and paternal, respectively, the hamster may be an inappropriate model for exploring microtubule and centrosomal defects in humans or for assaying postinsemination forms of human male fertility defects.

Evidence for the presence of myosin I in the nucleus

We produced and affinity-purified polyclonal antibodies to adrenal myosin I. These antibodies recognize adrenal myosin I by Western blot analysis (116 kDa) and inhibit the actin-activated ATPase activity of purified adrenal myosin I. They also recognize a 120-kDa protein in extracts prepared from many different cell lines. Fluorescence microscopy demonstrated the presence of immunoreactive material in the perinuclear region, the leading edges, and the nuclei of 3T3 cells. Fluorescence microscopy also demonstrated nuclear staining in mouse oocytes at the germinal vesicle stage and in the pronuclei during fertilization. Confocal and immunoelectron microscopy confirmed the intranuclear localization. Electron microscopy also demonstrated staining of structures in nucleoli that are thought to be associated with rDNA transcription. Western blot analyses revealed the presence of the 120-kDa protein in extracts prepared from nuclei that are apparently free of cytosolic contamination. The same nuclear protein binds 125I-calmodulin and is photoaffinity labeled with [alpha-32P]ATP. The 120-kDa protein was partially purified from twice washed nuclei using ammonium sulfate fractionation and gel filtration chromatography. Column fractions containing 120-kDa protein as revealed by Western blot analysis also contain K+-EDTA ATPase activity. The 120-kDa protein was also shown to bind actin in the absence, but not the presence, of ATP. Since K+-EDTA ATPase activity, actin, and ATP binding are defining features of the members of the myosin superfamily of proteins, we propose that the 120-kDa protein is a previously undescribed myosin I isoform that is an intranuclear actin-based molecular motor.

Molecular medical approaches for alleviating infertility and understanding assisted reproductive technologies

Fertilization is a precisely orchestrated cascade of events that results in the union of paternal and maternal genomes and in the establishment of mitotic potential of the zygote. To initiate embryonic development, the structures of the fertilizing sperm have to be disassembled and transformed into zygotic components by interactions with the cytoplasm of the egg. These interactions include the decondensation of the sperm nucleus into male pronucleus, the assembly of the zygotic centrosome, and the gathering of centrosomal proteins and sperm aster microtubules around the sperm centriole. Both the formation of the male pronucleus and the assembly of the zygotic centrosome are crucial steps required for pronuclear apposition and genomic union. The discovery of previously undetected fertilization failures that are due to defects in the assembly of the zygotic centrosome, abnormal pronuclear development, and compromised cytoskeletal dynamics enforces the development of new diagnostic strategies. Moreover, the introduction of new methods of infertility treatments, such as intracytoplasmic sperm injection and round spermatid nucleus injection into assisted human reproductive technology programs, emphasizes our lack of understanding of the cellular and molecular basis of human fertilization and evokes the need for additional experimentation. These efforts, however, are compromised by the sensitive nature of human embryo research and thus are severely restricted. Animal models that are reliable and cost-effective and that feature the characteristics of human fertilization have therefore been sought. Rodents such as the rat, mouse, and hamster are poor models owing to their maternal inheritance of the zygotic centrosome that is in strong contrast with the biparentally contributed assembly of the human zygotic centrosome during fertilization. Although rabbits are similar to humans from the standpoint of mitotic potential inheritance, information on postfertilization events in rabbits are lacking. Nonhuman primates represented by the rhesus monkey proved to be a reliable model for human in vitro fertilization and intracytoplasmic sperm injection, an advantage that is further emphasized by phyllogenetic similarity. In situations in which the high cost of primate research does not allow for large-scale experimentation (i.e., when large numbers of oocytes and embryos are needed), ruminants would be an ideal solution. Represented by the cow and sheep, domestic ruminants feature a fertilization strategy similar to that of the human. In addition, large numbers of gametes can be obtained wherever farms and slaughterhouses are accessible. Moreover, the detailed information on ruminant fertilization is strengthened by years of research and well-defined reproductive technology aimed at increasing the productivity of farm animals. Ruminants and rhesus monkeys have been extensively studied, and the data from these studies have been extrapolated in order to propose new strategies for the diagnosis and treatment of human infertility.

Microtubule and chromatin dynamics during fertilization and early development in rhesus monkeys, and regulation by intracellular calcium ions

To explore primate fertilization, oocytes and zygotes from fertile rhesus monkeys were imaged throughout fertilization, polyspermy, and artificial activation using confocal microscopy for microtubules and DNA, as well as ratiometric computer-enhanced video microscopy for intracellular calcium. Unfertilized oocytes displayed microtubules only in the radially oriented meiotic spindles. At insemination, a large calcium transient was followed by a series of smaller oscillations, and sperm astral microtubules had assembled from the sperm centrosome by 2.5 h after transient onset. This aster enlarged, and later duplicated, as the pronuclei converged near the cortex. Pronuclear apposition was prevented by microtubule inhibitors. At mitotic prophase, microtubules ensheathed both sets of condensing chromosomes. At metaphase, the spindle was barrel-shaped and eccentrically positioned with two small asters at the pole with the sperm tail. Microtubules emanating from the telophase spindle interacted with the adjacent cortex and displaced the spindle toward the cell center as first cytokinesis ensued. During polyspermy, each sperm nucleated an aster, and the frequency of calcium oscillations increased. Activation resulted initially in disarrayed microtubules that eventually organized into functional mitotic spindles. These kinetic results demonstrate that rhesus monkeys accomplish fertilization in a fashion nearly identical to that of humans and are, therefore, ideal models in which to investigate cytoskeletal events during human reproduction.

Microtubule organization in porcine oocytes during fertilization and parthenogenesis

Microtubule configurations in porcine oocytes after sperm penetration or after artificial activation by electrical stimulation were imaged by immunocytochemistry and laser scanning confocal microscopy. Soon after sperm penetration, an aster was seen adjacent to the incorporated sperm head. Polyspermic penetrations led to the presence of multiple sperm asters in association with each sperm. The sperm aster enlarged and, at the time of pronuclear apposition, filled the cytoplasm. After male and female gamete union, the microtubule matrix was reduced. At the mitotic metaphase stage, microtubules were detected in the spindle, which was anastral and fusiform. At anaphase, asters assembled at each spindle pole, and at telophase, large asters filled the cytoplasm. Artificial activation by electrical stimulation induced in the cytoplasm a dense network of microtubules, which seem to be involved in proper positioning of the female pronucleus. At mitotic metaphase, microtubules were concentrated around the chromatin. The results of experiments using taxol, a microtubule stabilizing agent, suggest that maternal centrosomal material is present in the mature porcine oocyte as dispersed undetectable material that can form a microtubule network after parthenogenetic activation. However, at fertilization, the paternal centrosome collects centrosomal material to form a sperm aster. These results suggest that the functional centrosome that forms during fertilization is a result of the blending of paternal and maternal centrosomal components.

Imaging motility during fertilization

Studying reproduction in domestic species is now possible at the cellular and molecular level due to advances in the production of large numbers of zygotes and embryos in these species. In this paper we review the microtubule patterns during fertilization in domestic species. These results indicate that domestic species accomplish fertilization in a similar fashion to one another but in a far different fashion from rodents. Recent results indicate that human fertilization is similar to that of domestic species. We discuss the significance this has on the use of domestic species as a model system for human studies and possible consequences for the alleviation of human infertility.

The stages at which human fertilization arrests: microtubule and chromosome configurations in inseminated oocytes which failed to complete fertilization and development in humans

The goal of fertilization is the union of one, and only one, sperm nucleus with the female pronucleus within the activated oocyte. For this to occur successfully, several events must transpire, including the incorporation of the entire spermatozoon into the oocyte, the completion of meiotic maturation with the extrusion of the second polar body, the metabolic activation of the previously quiescent oocyte, the decondensation of the sperm nucleus and the maternal chromosomes into the male and female pronuclei respectively, and the cytoplasmic migrations of the pronuclei, which bring them into apposition. Defects in any of these events are lethal to the zygote and might prove to be causes of infertility. In this study, the microtubules and DNA were imaged in inseminated human oocytes that had been discarded as unfertilized. The presence and number of incorporated sperm tails were also documented using a monoclonal antibody specific for the post-translationally modified acetylated-alpha-tubulin found in the tail, but not the oocyte, microtubules. An analysis of 211 oocytes from failed in-vitro fertilizations from 58 patient couples resulted in the determination of several previously undetectable phases at which fertilization arrests: (i) metaphase II arrest; (ii) arrest after the successful incorporation of the spermatozoon, (iii) arrest after the formation of the sperm aster; (iv) arrest during mitotic cell cycle progression; and (v) arrest during meiotic cell cycle progression. Data on polyspermy and arrested embryonic development are also presented. These results have implications for the diagnosis and treatment of female, as well as male, infertility.(ABSTRACT TRUNCATED AT 250 WORDS)

The paternal inheritance of the centrosome, the cell's microtubule-organizing center, in humans, and the implications for infertility

Successful fertilization in humans, achieved when parental chromosomes intermix at first mitosis, requires centrosome restoration and microtubule-mediated motility. Imaging of inseminated human oocytes reveals that the sperm introduces the centrosome. The centrosome then nucleates the new microtubule assembly to form the sperm aster--a step essential for successful fertilization. Oocytes from some infertile patients failed to complete fertilization because of defects in uniting the sperm and egg nuclei, indicating that failure to properly effect the cytoplasmic motions uniting the nuclei results in human infertility. These discoveries have important implications for infertility diagnosis and managing reproduction.

The sperm centrosome during fertilization in mammals: implications for fertility and reproduction

This article reviews the recent discoveries that: (1) nearly all mammals, including humans, inherit their centrosomes from their fathers; and (2) some sperm are ineffective in organizing the microtubules essential for effecting genomic union during fertilization, leading to the speculation that these sperm have centrosome defects. In addition, the molecular dissection and reconstitution of the human sperm centrosome in vitro is presented.

Microtubule configurations in oocytes, zygotes, and early embryos of a marsupial, Monodelphis domestica

The marsupials represent a separate evolutionary lineage from eutherians from which they diverged over 100 million years ago. In order to explore the origin and mode of centrosome inheritance amongst this group of mammals, this study investigates the microtubule organization during fertilization, parthenogenesis, and polyspermy in the didelphid, Monodelphis domestica. Microtubules and DNA were visualized in maturing ovarian oocytes, parthenogenetically activated oocytes, monospermic and polyspermic zygotes, and early embryos. Ovarian oocytes had a central region of yolky cytoplasm that, after fertilization, became polarized; much of the yolk was then extruded into the perivitelline space as an enucleated cytoplasmic mass. Immunofluorescence microscopy, using a monoclonal antibody to beta-tubulin, demonstrated microtubules in the meiotic spindle in unfertilized oocytes, but cytasters were not detected. After fertilization, a cluster of microtubules forming into a sperm aster was evident around the male pronucleus. The sperm aster remained largely restricted to the nonyolky region of the egg cytoplasm, resulting in a cytoplasmic heterogeneity between a microtubule-rich region and one in which microtubules were largely absent. Once the two pronuclei came close together, abundant microtubules were found surrounding both pronuclei. In the early embryo, microtubules were found in the outer cortical region of the blastomeres and, in addition, there was an extensive and elaborate network of microtubules throughout the yolk mass. Disruption of the meiotic spindle microtubules with nocodazole or cold treatment did not result in chromosome dispersion in the cortex and recovery from drug or cold depolymerization demonstrated that microtubules might not be as dynamic as those in eutherian mammals. Taxol stabilization resulted in an increase in cortical microtubules. In this marsupial species, therefore, the centrosome appears to be of paternal origin, and the radiating microtubules that form may well be involved both in bringing the pronuclei together and in the cytoplasmic polarization that results in extrusion of the yolk mass.

Gamma-tubulin reorganization during mouse fertilization and early development

gamma-Tubulin, a component of spindle pole bodies in fungal cells and pericentriolar material in vertebrate cells, is thought to play a role in the nucleation of microtubule growth and to define their polarity. In contrast to the adult somatic cells, microtubules are nucleated in the absence of centrioles in mammalian oocytes and early embryos. By studying acentriolar mouse oocytes and their early development following fertilization, we show that gamma-tubulin antibody crossreacts with a 50,000 M(r) protein in unfertilized mouse oocytes and demonstrate that gamma-tubulin distribution is rearranged dramatically during fertilization. In unfertilized mouse oocytes, gamma-tubulin is concentrated in the broad spindle poles of meiotic spindle (MII) and as the distinct foci which form the centers of the cytoplasmic microtubule asters (cytasters). The integrity of these gamma-tubulin foci and their cytoplasmic location is maintained during the drug- or cold-induced depolymerization of microtubules. gamma-Tubulin is also found in the basal body of the mouse sperm. During fertilization, the gamma-tubulin is found at the cytastral centers as well as in the incorporated sperm basal body complex, and the gamma-tubulin foci coalesce at the perinuclear microtubule organizing regions of the two pronuclei at the first mitotic prophase. During mitosis, gamma-tubulin is found associated with broad bands that form the poles of the first mitotic spindle. By the late preimplantation stage, when newly generated centrioles have been reported to arise, gamma-tubulin remains localized at the centrosome of mitotic cells.(ABSTRACT TRUNCATED AT 250 WORDS)

Meiosis, egg activation, and nuclear envelope breakdown are differentially reliant on Ca2+, whereas germinal vesicle breakdown is Ca2+ independent in the mouse oocyte

During early development, intracellular Ca2+ mobilization is not only essential for fertilization, but has also been implicated during other meiotic and mitotic events, such as germinal vesicle breakdown (GVBD) and nuclear envelope breakdown (NEBD). In this study, the roles of intracellular and extracellular Ca2+ were examined during meiotic maturation and reinitiation at parthenogenetic activation and during first mitosis in a single species using the same methodologies. Cumulus-free metaphase II mouse oocytes immediately resumed anaphase upon the induction of a large, transient Ca2+ elevation. This resumption of meiosis and associated events, such as cortical granule discharge, were not sensitive to extracellular Ca2+ removal, but were blocked by intracellular Ca2+ chelators. In contrast, meiosis I was dependent on external Ca2+; in its absence, the formation and function of the first meiotic spindle was delayed, the first polar body did not form and an interphase-like state was induced. GVBD was not dependent on external Ca2+ and showed no associated Ca2+ changes. NEBD at first mitosis in fertilized eggs, on the other hand, was frequently, but not always associated with a brief Ca2+ transient and was dependent on Ca2+ mobilization. We conclude that GVBD is Ca2+ independent, but that the dependence of NEBD on Ca2+ suggests regulation by more than one pathway. As cells develop from Ca(2+)-independent germinal vesicle oocytes to internal Ca(2+)-dependent pronuclear eggs, internal Ca2+ pools increase by approximately fourfold.

Microgravity effects on sea urchin fertilization and development

Gravity has been a pervasive influence on all living systems and there is convincing evidence to suggest that it alters fertilization and embryogenesis in several developmental systems. Notwithstanding the global importance of gravity on development, it has only been recently possible to begin to design experiments which might directly investigate the specific effects of this vector. The goal of this research program is to explore and understand the effects of gravity on fertilization and early development using sea urchins as a model system. Sea urchin development has several advantages for this project including the feasibility of maintaining and manipulating these cells during spaceflight, the high percentage of normal fertilization and early development, and the abundant knowledge about molecular, biochemical, and cellular events during embryogenesis which permits detailed insights into the mechanism by which gravity might interfere with development. Furthermore, skeletal calcium is deposited into the embryonic spicules within a day of fertilization permitting studies of the effects of gravity on bone calcium deposition.

Maternal inheritance of centrosomes in mammals? Studies on parthenogenesis and polyspermy in mice

The centrosome, the microtubule-organizing center of the cell, is introduced typically by the sperm at fertilization. In some mammals, however, this paternal pattern of inheritance appears to be violated. The hypothesis that the centrosome is maternally inherited was tested during parthenogenesis, polyspermy, and polygyny as well as after recovery from microtubule inhibition at first mitosis. During parthenogenesis the paternal contribution was absent, and in polyspermy the paternal contribution was multiplied. Haploid and diploid parthenogenotes as well as polyspermic and digynic fertilized eggs each segregated their centrosomes to organize a bipolar mitotic apparatus. Oocytes recovering from a nocodazole block formed two normal bipolar mitotic apparatus; the paternal chromosomes aligned at one spindle equator, while the maternal chromosomes were found at the other. These results show that the centrosome is maternally inherited from cytoplasmic sites in the mouse. The evolutionary switch from paternal to maternal inheritance in mammals might be related to the additional dangers that parthenogenesis represents: a threat to the life of the mother as well as to the life of the fetus.

Three-dimensional imaging of fertilization and early development

The field of biological microscopy has recently enjoyed major technical advances, exemplified by the development of field-emission low-voltage scanning electron microscopes and laser scanning confocal light microscopes. In addition, computer processing of microscopical data is revolutionizing the way morphological information is imaged. In this paper, we illustrate methods by which this new technology can be used to examine events in fertilization and early development in three dimensions. Different types of specimen preparation protocols, using both echinoderm and mammalian gametes and embryos, are evaluated for their ability to preserve accurately the three-dimensional organization of these specimens for imaging by both low-voltage scanning electron microscopy and laser scanning confocal light microscopy.

Microinjected centromere [corrected] kinetochore antibodies interfere with chromosome movement in meiotic and mitotic mouse oocytes

Kinetochores may perform several functions at mitosis and meiosis including: (a) directing anaphase chromosome separation, (b) regulating prometaphase alignment of the chromosomes at the spindle equator (congression), and/or (c) capturing and stabilizing microtubules. To explore these functions in vivo, autoimmune sera against the centromere/kinetochore complex are microinjected into mouse oocytes during specific phases of first or second meiosis, or first mitosis. Serum E.K. crossreacts with an 80-kD protein in mouse cells and detects the centromere/kinetochore complex in permeabilized cells or when microinjected into living oocytes. Chromosome separation at anaphase is not blocked when these antibodies are microinjected into unfertilized oocytes naturally arrested at second meiotic metaphase, into eggs at first mitotic metaphase, or into immature oocytes at first meiotic metaphase. Microtubule capture and spindle reformation occur normally in microinjected unfertilized oocytes recovering from cold or microtubule disrupting drugs; the chromosomes segregate correctly after parthenogenetic activation. Prometaphase congression is dramatically influenced when antikinetochore/centromere antibodies are introduced during interphase or in prometaphase-stage meiotic or mitotic eggs. At metaphase, these oocytes have unaligned chromosomes scattered throughout the spindle with several remaining at the poles; anaphase is aberrant and, after division, karyomeres are found in the polar body and oocyte or daughter blastomeres. Neither nonimmune sera, diffuse scleroderma sera, nor sham microinjections affect either meiosis or mitosis. These results suggest that antikinetochore/centromere antibodies produced by CREST patients interfere with chromosome congression at prometaphase in vivo.

Microtubules in the metaphase-arrested mouse oocyte turn over rapidly

After ovulation mammalian oocytes arrest in second meiotic metaphase. We asked whether the microtubules that comprise the meiotic spindle of mouse oocytes were stable or were undergoing rapid cycles of assembly and disassembly. Porcine brain tubulin, derivatized with biotin or x-rhodamine [5- (and -6)-carboxy-x-rhodamine], was microinjected into living oocytes. Biotinylated tubulin incorporated into the meiotic spindle to apparent equilibrium within 15 min. To assess quantitatively the rates of disassembly and assembly of the microtubules, small domains within the spindles of oocytes injected with x-rhodamine-tubulin were photobleached and their recovery was analyzed by digital imaging microscopy. Fluorescence recovery in the spindles was rapid and extensive, plateauing to an average of 83% at 4 min. The calculated half-time for turnover of the spindle microtubules was 77 sec. In contrast, fluorescence recovery of the spindle midbodies in telophase oocytes was much more limited, averaging approximately 22% at 4 min. These data indicate that most microtubules within the arrested metaphase spindle of the mouse oocyte undergo rapid cycles of assembly and disassembly. Microtubules of the telophase midbody are more stable.

U3 snRNPs and nucleolar development during oocyte maturation, fertilization and early embryogenesis in the mouse: U3 snRNA and snRNPs are not regulated coordinate with other snRNAs and snRNPs

U3 small nuclear ribonucleic acids (snRNA) and U3 small nuclear ribonucleoprotein (snRNP), which are thought to be responsible for ribosomal RNA processing, are quantitated and localized during oocyte maturation, fertilization, and early embryogenesis in the mouse. On the basis of Northern blot and nuclease protection experiments, it is estimated that there are about 5 x 10(4) U3 snRNA molecules in an ovulated oocyte and in a two-cell embryo. This number then increases roughly 50-fold to 2.7 x 10(6) molecules per embryo by the blastocyst stage. At all stages of development U3 snRNP antigens colocalize with nucleoli, as defined by differential interference contrast microscopy and an antibody to a nucleolar epitope. The synthesis and distribution of U3 snRNA and U3 snRNP follow a pattern independent from other major U snRNPs and snRNAs.