Decondensed Sperm Nuclei Research Articles

Rat eggs normally exhibit a variety of surface phenomena during fertilization

AbstractThe surface topography of the rat egg was examined during fertilization in vitro and in vivo. Using phase optics, 348 in vitro fertilized and 50 in vivo fertilized eggs were continuously monitored throughout the 7‐hour period of sperm incorporation. A myriad of different surface configurations were seen, with each egg exhibiting one or more of the following changes. A small number of eggs (4–6%) formed surface elevations over the sperm head after its detachment from the flagellum, 15–30 min after sperm‐egg fusion; 1 to 1.5 hr after fusion, 40–50% of the eggs produced the so‐called incorporation cone, a prominent surface elevation over the decondensing sperm nucleus. The vast majority of eggs (74–82%) formed surface elevations over the proximal tip of the flagellum 2–3 hr after sperm‐egg fusion. These had no association with the decondensing sperm nucleus. A few eggs (11–12%) exhibited multiple protrusions that were distributed randomly about the egg surface, whereas 14–20% did not manifest any surface elevations and remained spherical throughout the sperm incorporation period. Regardless of the type of surface change, all of the eggs resumed a spherical shape by the time sperm incorporation was complete. These observations are in contrast to the conclusions by previous authors that formation of the so‐called incorporation cone over the decondensing sperm nucleus is a ubiquitous event.

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

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

The germinal vesicle material required for sperm pronuclear formation is located in the soluble fraction of egg cytoplasm.

The chromatin of Xenopus laevis sperm nuclei was induced to decondense, swell and form mitotic chromosomes following its injection into mature Rana pipiens oocytes. In contrast, the sperm chromatin did not decondense or form mitotic chromosomes when injected into oocytes from which the germinal vesicle (GV) was removed prior to the initiation of maturation. Injection into enucleated oocytes of the material extracted from manually-isolated GVs restored their ability to decondense sperm nuclei. This soluble GV material was stable at 18 degrees C for 16 h but was inactivated by heating to 80 degrees C for 10 min. We examined the distribution of this GV material in a cytoplasmic preparation from activated eggs which can induce sperm pronuclear formation in vitro. The cytoplasmic preparation was separated into soluble and particulate fractions by centrifugation and then each fraction was injected into enucleated eggs to determine whether or not it restored the ability to decondense sperm nuclei. We found that the soluble, but not the particulate fraction could restore the ability to decondense sperm nuclei to enucleated oocytes. This result clearly indicates that the soluble fraction contains most of the GV material required for chromatin decondensation. However, since the soluble fraction fails to decondense sperm chromatin in vitro in the absence of material from the particulate fraction, sperm pronuclear formation appears to require both the soluble material derived from the GV and particulate material which can develop in the oocyte cytoplasm in the absence of the GV.

Decondensation of mouse sperm chromatin and reassembly into nucleosomes mediated by polyglutamic acid in vitro

The organization of the mammalian sperm nucleus was probed with staphylococcal nuclease. Although isolated nuclei are resistant to cleavage, following reduction and alkylation, 30% of the sperm DNA could be digested and the remaining DNA had a heterodisperse size distribution. By morphological criteria, a model acidic protein, polyglutamic acid was capable of decondensing purified sperm nuclei that had been reduced and alkylated. The maximal extent of nuclease digestion increased to 85–90%. The subsequent addition of purified, exogenous core histones in 0.1 M NaCl partially reversed this vulnerability to nuclease cleavage such that only 55% of the DNA was digested. Furthermore, analysis of the remaining DNA revealed a nucleosome ladder pattern with unit length repeat of 150 bp. These results strongly suggest that polyglutamic acid can mediate not only decondensation of sperm nuclei but also the assembly of sperm chromatin into nucleosomes.

Fertilizability of in vitro matured oocytes from golden hamsters.

The fertilizability of hamster oocytes matured in vitro was examined along with two factors potentially affecting nuclear maturation in culture. The four amino acids (isoleucine, methionine, phenylalanine, and glutamine) necessary for nuclear maturation of cumulus-free oocytes (Gwatkin and Haidri, '74) were not required if oocytes recovered on the morning of proestrus (day 4) were cultured with intact cumuli. Although follicular oocytes recovered on day 3 of the estrous cycle (late diestrus) had somewhat lower frequencies of maturation in vitro compared to those recovered on day 4 (76 vs. 95%, respectively), they still had a substantial frequency of spontaneous maturation. Follicular oocytes recovered on day 3 and matured in vitro were fertilized at frequencies equivalent to oviducal oocytes (80 vs. 82%, respectively) when incubation of oocytes with precapacitated sperm was continued for 6 h. Penetration of follicular oocytes was lower (37.4%) after only 4 h of sperm/egg incubation, indicating a delay in sperm penetration with follicular oocytes matured in vitro. Incubation for 4 h is sufficient time for penetration of 80% or more of oviducal oocytes. While 98% of penetrated oviducal oocytes were fertilized normally, only 2% of penetrated follicular oocytes were normal. The majority (85%) of follicular oocytes, unlike oviducal oocytes, were unable to cause decondensation of sperm nuclei after 6 h of sperm/egg incubation. Use of a highly defined system for in vitro fertilization of hamster gametes has provided rigorous proof that isolated cumulus-oocyte complexes do not undergo complete maturation in vitro.

Isolation of the inner acrosomal‐nuclear membrane complex from rabbit spermatozoa

AbstractRabbit spermatozoa were passed through a Bio‐Glas 2500 (BG) column to yield pure cytoplasmic droplets and consequently the droplet‐free spermatozoa. Rapid decondensation of sperm nuclei was achieved by 1 mM dithiothreitol (DTT) and 1.5 M NaCl. This treatment caused removal of the plasma and the outer acrosomal membranes. The viscosity of decondensed nuclei was reduced by pancreatic DNase. Further elution of the suspension from BG column yielded a membrane complex. On the basis of electron microscopic observations and the enzyme analysis, these membranes appeared to be the inner acrosomal‐nuclear membrane complex (IANC). The IANC was also prepared from isolated sperm head by DTT‐NaCl and Dnasetreatment and low‐speed centrifugation.

Decondensation of human sperm nuclei by glycosamineglycan‐sulfate from sea urchin egg

Decondensation of human and sea urchin spermatozoan nuclei has been induced by exposure of intact spermatozoa to glycosamineglycan-sulfate (GAGs) extracted from eggs of the sea urchin. Toxopneustes roseus. Swelling of human spermatozoan nuclei commenced about 60 min after the addition of GAGs and, depending on the extract concentration, the proportion of swollen nuclei reach 90% after 6 h of incubation when 20 mg of GAGs per ml was used. Swelling of sea urchin spermatozoan nuclei could be induced also with GAGs and/or with heparin. Swelling commenced about 10 min after the addition of GAGs/heparin reaching 90-92% after 60 min of incubation with 5 mg GAGs/500 USP heparin per ml. Preincubation of spermatozoa with 10 mg/ml of trypsin soybean inhibitor did not interfere with the swelling action of the GAGs.

Sperm nuclear decondensation in Barnea candida (mollusca, pelecypoda) oocytes does not require germinal vesicle breakdown.

Barnea candida oocytes, submitted to D-600 (100 microM) 15-20 seconds after insemination in order to inhibit Ca++ uptake but not acid release, fail to exhibit germinal vesicle breakdown (GVBD) whereas penetrated spermatozoa are able to decondense normally. Oocytes transferred in 100 mM Na-acetate seawater at pH 6.3, 1 minute after insemination, in order to inhibit acid release, fail to undergo GVBD and sperm nuclear decondensation. Upon return of these oocytes to normal seawater and treatment with an excess of KCl, they exhibit GVBD and decondensed sperm nuclei are seen within their cytoplasm. These results show that sperm nuclear decondensation does not require GVBD or Ca++ uptake but may be related to an intracellular pH increase.

The fusion of trout spermatozoa with Chinese hamster fibroblasts.

Polyethylene glycol (PEG) was used to fuse trout sperm with Chinese hamster fibroblasts (CHW-1102). As judged by light microscopy, PEG significantly increased the number of associations between the two cell types. Electron microscopy revealed that the sperm nuclei were in the cytoplasm of CHW-1102 in cultures that had been treated with PEG and in phagosomes of CHW-1102 in cultures not treated with PEG. In the cytoplasm many sperm nuclei had an extensive network of fibres whereas before fusion the sperm nuclei contained chromatin blocks which were packed together tightly. In phagosomes they consisted of dispersed blocks of chromatin. The chromatin of the few sperm that were found outside CHW-1100 cells but in the same culture that was treated with PEG also lacked fibres and consisted of loosely packed blocks. Most nuclei were unaltered by PEG treatment alone although in a few the packing of the chromatin blocks was loosened. Thus the decondensation of sperm nuclei within CHW-1102 cells appears to be brought about by the mammalian cytoplasm rather than by digestion in phagosomes, the culture conditions, or the treatment used to induce fusion.

Heparin binding sites in the human spermatozoa membrane.

The existence in the human spermatozoa membrane of receptorlike functional group for heparin was studied. Incubation of whole spermatozoa with tritiated heparin induced the specific binding of 745 +/- 112 pmol of heparin per 5 x 10(7) sperm cells with an intrinsic association constant KD = 3.6 x 10(-6) M. The specificity of binding was shown by the lack of competence in the binding process of some other glycosaminoglycans used at concentrations 20 x higher than heparin. However, dextran sulfate was a very efficient competitive agent. Autoradiography experiments showed that labeling was almost completely restricted to sperm cells in the process of nuclear decondensation. This technique showed the presence of a high amount of radioactive heparin in the isolated sperm membranes even after several washings. Heparin may participate both in the final part of the capacitation process (acrosome reaction) and in the decondensation of sperm nuclei.

Hormone-cytoplasmic interactions controlling sperm nuclear decondensation and male pronuclear development in starfish oocytes.

Numerous highly condensed sperm nuclei were present in the cytoplasm of starfish oocytes fertilized at the germinal vesicle stage. Decondensation of sperm nuclei and formation of male pronuclei and asters followed treatment of such fertilized oocytes with meiosis-inducing hormone 1-methyladenine (1-MA). Transformation of sperm nuclei was asynchronous, occurred only after germinal vesicle breakdown (GVBD), and was associated with characteristic clearing of the adjacent cytoplasmic organelles. GVBD and sperm nuclear changes were both inhibited when dinitrophenol was added to previously fertilized GV-intact oocytes. Results demonstrate that polyspermy occurs readily in immature oocytes and that 1-MA plays a key role in establishing the block to polyspermy. Furthermore, the factors necessary for sperm nuclear decondensation and pronuclear development do not exist in the cytoplasm of immature oocytes but arise following dispersal of germinal vesicle contents into the cytoplasm. Thus, absence of embryonic development in fertilized GV-intact oocytes is linked to a lack of both oocyte and sperm nuclear differentiation rather than to a lack of sperm entry into the cytoplasm.

Decondensation of sperm nuclei of australian marsupials: Effects of air drying and of calcium and magnesium

AbstractSpermatozoa of six species of Australian marsupials have been studied. The nucleus is highly unstable when compared with those of eutherian mammals. When thin films of spermatozoa in buffered saline are air‐dried on glass slides, the nucleus disintegrates and flattens, leaving the acrosome, midpiece, and tail intact. This spreading of the nucleus can be inhibited by seminal plasma proteins and by bovine serum albumin, but is potentiated by detergents. The nucleus also decondenses spontaneously in the presence of high concentrations (>0.25M) of calcium and magnesium salts, leaving the head membranes, acrosome, midpiece, and tail intact. This is inhibited by EDTA. In some species, certain areas of the nucleus appear more resistant t o Ca++/Mg++ treatment, and the initial stages of decondensation are uneven. Ultrastructurally the Ca++/Mg++ dispersed chromatin shows a moderately fine, branching, fibrillar structure, interspersed with dense granules. Treatment with disulphide bond cleaving agents together with detergents results in rapid and complete dispersal of the chromatin and acrosome, and slow digestion of midpiece and tail structures. Treatment with HCl, NaCl, KCl, EDTA, detergents, and sucrose has no effect on nuclear integrity, but treatment with NaOH (0.9–1.0M) results in complete digestion of the whole sperm. These findings are discussed in the light of evolutionary differences between marsupial and eutherian mammals in terms of sperm structure and composition.

Decondensation of sperm nuclei in vitro

Treatment of mouse spermatozoa with dithiothreitol and proteases, particularly trypsin, causes the nucleus to enlarge and decondense, while the acrosomal region remains relatively intact. Dithiothreitol or trypsin alone does not induce swelling, and exposure to the reducing agent is necessary before trypsin can act. Chymotrypsin, promise, and papain will substitute for trypsin, but micrococcal nuclease and pancreatic deoxyribonuclease will not. Similar results were obtained with rat, guinea pig, and rabbit sperm. These results provide the basis for a method of purifying sperm acrosomes and suggest possible mechanisms for decondensation of the sperm nucleus after penetration of the egg.

Maturation and sperm penetration of canine ovarian oocytes in vitro.

Canine ovarian oocytes were cultured in a medium consisting of TC medium 199, fetal calf serum and antibiotics. Ninety-nine percent of the apparently healthy oocytes were in the germinal vesicle (dictyate) stage when recovered from the ovaries; 25% of them reached metaphase I or II by 72 hours of culture. Washed ejaculated spermatozoa were added to BWW medium containing oocytes which had either been removed directly from the follicles or which had been cultured for 24--72 hours. The earliest acrosome reaction and zona penetration by spermatozoa were seen at seven hours after insemination. Seventy-four percent of the oocytes examined between 11 and 24 hours after insemination showed evidence of zona penetration by spermatozoa. Neither the condition of the oocyte vitellus nor the stage of nuclear maturation influenced the incidence of zona penetration. Decondensing sperm nuclei were found in the vitellus of 27% of the oocytes which had not been cultured and in the vitellus of 20% of those which had been cultured for 24--72 hours and were in various stages of maturation. These results indicate that (1) canine ovarian oocytes can be matured in vitro, (2) the spermatozoa require capacitation which takes approximately seven hours in vitro and (3) maturation of the oocytes is not required for sperm passage through the zona pellucida or entry into the vitellus nor for sperm nuclear decondensation.