Karyotype analysis of Meloidogyne hapla by 3-D reconstruction of synaptonemal complexes from electron microscopy of serial sections

Meloidogyne hapla Race A (meiotic, n=17) females have 17 synaptonemal complexes (SC). The karyotype length is constant throughout pachytene, although nuclear volume increases as pachytene progresses. Each SC has at least one region in which two pairs of lateral elements run parallel to each other for a distance of 1–2 m, thus forming a double SC (dSC). Decondensed chromatin regions (DCR) occur along some SCs and represent 5% of the length of the karyotype. The DCRs may be the location of the sex-determining chromatin. Spermatocytes from males of the same meiotic parthenogenetic race (A) have SCs and cylindrical granular complexes (CGC) while males and females from a mitotic (3n=45) parthenogenetic race (B) lack such structures. The CGCs may contribute precursors necessary for the formation of SCs.     

Development of the synaptonemal complex of two types of pachytene in oocytes and spermatocytes of Carausius morosus Br. (Phasmatodea)

During oogenesis of the parthenogenetic stick insect Carausius morosus (2n =61+XXX) pachytene is followed by a duplication of the desynapsed chromosomes, which results in a second type of pachytene (tetrapachytene) consisting of paired sister chromosomes (autobivalents). Electron microscopic studies on sections revealed that synaptonemal complexes (SCs) are formed during tetrapachytene only. This means that the parthenogenetically produced progeny have the genetic constitution of the mother. During spermatogenesis of rare fatherless males (2n=61 + XX) and intersexes (2n=61 +XXX) either an incomplete chromosome doubling (demonstrated by up to 10% additional DNA synthesis) or a complete chromosome doubling takes place during zygotene. EM studies on sections and spreads of germ cells of the first type of meiosis showed that unpaired lateral components (LCs), pieces of SCs and complete SCs are formed during pachytene only, the sex chromosomes being represented by unpaired thickened LCs. The incomplete SC formation reflects the complex heterozygosity of the chromosome complement. In the duplicated type SCs are found in tetrapachytene nuclei only; they are wider than the SCs in oocytes. The sex chromosome bivalents are represented by unpaired thickened LCs or partially paired LCs, in which localized chiasma formation was found. The idea is discussed that formation of SCs does not take place as long as a germ cell has been programmed either to replicate or to be able to replicate its chromosomes and that consequently SCs can be formed only once per meiosis.     

Ovarian nests in cultured females of the Siberian sturgeon Acipenser baerii (Chondrostei,Acipenseriformes)

Ovaries of Acipenser baerii are of an alimentary type and probably are meroistic. They contain ovarian nests, individual follicles, inner germinal ovarian epithelium, and fat tissue. Nests comprise cystoblasts, germline cysts, numerous early previtellogenic oocytes, and somatic cells. Cysts are composed of cystocytes, which are connected by intercellular bridges and are in the pachytene stage of the first meiotic prophase. They contain bivalents, finely granular, medium electron dense material, and nucleoli in the nucleoplasm. Many cystocytes degenerate. Oocytes differ in size and structure. Most oocytes are in the pachytene and early diplotene stages and are referred to as the PACH oocytes. Oocytes in more advanced diplotene stage are referred to as the DIP oocytes. Nuclei in the PACH oocytes contain bivalents and irregularly shaped accumulation of DNA (DNA‐body), most probably corresponding to the rDNA‐body. The DNA‐body is composed of loose, fine granular material, and comprises multiple nucleoli. At peripheries, it is fragmented into blocks that remain in contact with the inner nuclear membrane. In the ooplasm, there is the rough endoplasmic reticulum, Golgi complexes, free ribosomes, complexes of mitochondria with cement, fine fibrillar material containing granules, and lipid droplets. The organelles and material of nuclear origin form a distinct accumulation (a granular ooplasm) in the vicinity of the nucleus. Some of the PACH oocytes are surrounded by flat somatic cells. There are lampbrush chromosomes and multiple nucleoli present (early diplotene stage) in the nucleoplasm. These PACH oocytes and neighboring somatic cells have initiated the formation of ovarian follicles. The remaining PACH oocytes transform to the DIP oocytes. The DIP oocytes contain lampbrush chromosomes and a DNA‐body is absent in nuclei. Multiple nucleoli are numerous in the nucleoplasm and granular ooplasm is present at the vegetal region of the oocyte.     

Ultrastructural Study of Oogenesis in the Compound Ascidian Botryllus schlosseri(Tunicata)

On the basis of ultrastructural observations, Botryllus schlosserioogenesis is divided into five stages, of which stages 1–3 and 4–5 refer to previtellogenic and vitellogenic phases, respectively. Special attention was paid to the mechanisms of acquisition of nutrient, organelle differentiation, yolk formation and relationships between oocyte and its complex investment. In the gonadal blastema of young buds, small oocytes are recognized early, partially covered by a few primary follicle cells, the presumptive source of all the cellular envelopes of the fully grown oocyte. Some oocytes are seen in the zygotene–pachytene phase, characterized by synaptonemal complexes, but most are found at the end of the diplotene, when oocytes commonly stop meiosis, grow and migrate through blood vessels into blastozooids of successive generations. In laboratory animals, only 1–3 oocytes per blastozooid can reach complete maturity. Detailed observations on the time of appearance and development of organelles, microvilli and endocytotic activity in growing oocytes are also reported. Ultrastructural differentiation and the relationships between oocytes and their envelopes all indicate that both auto– and hetero–synthetic mechanisms for yolk formation occur in B. schlosseri.These mechanisms and the possible role of egg envelopes in the process are discussed, comparing the large yolky eggs of B. schlosseriwith those of solitary species.     

Effects of leptin supplementation in in vitro maturation medium on meiotic maturation of oocytes and preimplantation development of parthenogenetic and cloned embryos in pigs

The objective of the present study was to investigate the effects of leptin addition in in vitro maturation (IVM) medium on meiotic maturation of oocytes and preimplantation development of parthenogenetic and cloned embryos in pigs. In experiment 1, oocytes were matured in North Carolina State University 23 (NCSU-23) medium supplemented with various concentrations of leptin: 0, 1, 10 and 100 ng/ml. IVM medium added with 10 or 100 ng/ml leptin significantly increased the rate of oocytes reaching metaphase II compared to the control (76.8% and 73.8% versus 61.7%). In experiment 2, the influence of the timing of leptin addition in IVM medium on meiotic maturation of porcine oocytes was assessed, and maximum maturation rate of oocytes developing to metaphase II was achieved when supplemented during the first half (0-22 h), the latter half (22-44 h) or the entire maturation period (0-44 h) compared to the control (80.5%, 84.7% and 78.1% versus 70.4%). In experiment 3, leptin strikingly increased the blastocyst rate of parthenogenetic embryos at the concentration of 10 ng/ml (37.5% versus 21.7%) and this increase was independent of the addition timing (0-44, 0-22, 22-44 h) compared to the control (32.5%, 34.6% and 31.5% versus 16.2%). Moreover, total cell number per blastocyst of parthenogenetic embryos was obviously increased in the 10 and 100 ng/ml leptin treatments as compared with the control (36, 38 versus 28). In experiment 4, 10 ng/ml leptin treatment significantly increased the rate of cleavage (72% versus 56%) of cloned embryos. Meanwhile, the rate of blastocyst formation was also improved although no significant difference was found (12.8% versus 7.1%). Collectively, our results indicate that leptin supplementation in IVM medium may be beneficial not only for developmental potential of oocytes but for subsequent developmental competence of embryos produced by parthenogenetic activation and the cleavage of embryos derived by somatic cell nuclear transfer (SCNT).     

Different influences of genomic imprinting on the development of parthenogenetic cell clones in C57BL/6 and CBA mice

Clonal analysis of parthenogenetic chimeric mouse embryos C57B1/6(PG)<-->BALB/c has shown that parthenogenetic cell clones C57BL/6 are present in the brain, liver, and kidneys of 14- and 18-day-old embryos. The content of the parthenogenetic component (PG) in these organs on day 18 was lower than on day 14, and, in some 18-day-old embryos, parthenogenetic cell clones were absent from the liver and/or kidneys. These data suggest that, during the embryogenesis of parthenogenetic chimeras, parthenogenetic cell clones of mostly endodermal and mesodermal origins were actively eliminated. Therefore, in such parthenogenetic adult chimeras, parthenogenetic clones of mostly ectodermal origins were preserved. In parthenogenetic chimeras CBA(PG)<-->BALB/c, parthenogenetic cell clones were actively eliminated at early embryonic stages, and, as a result, they were absent at the post-implantation stages. Hence, during development of parthenogenetic cell clones, the effects of genomic imprinting are expressed unequally in C57BL/6 and CBA mice.     

Effects of DNA damage and short-term spindle disruption on oocyte meiotic maturation

DNA damage has recently been shown to inhibit or delay germinal vesicle breakdown (GVBD) in mouse oocytes, but once meiosis resumes, DNA-damaged oocytes are able to extrude the first polar body. In this study, using porcine oocytes, we showed that DNA damage did not affect GVBD, but inhibited the final stages of maturation, as indicated by failure of polar body emission. Unlike mitotic cells in which chromosome mis-segregation causes DNA double-strand breaks, meiotic mouse oocytes did not show increased DNA damage after disruption of chromosome attachment to spindle microtubules. Nocodazole-treated oocytes did not display increased DNA damage signals that were marked by γH2A.X signal strength, but reformed spindles and underwent maturation, although aneuploidy increased after extended nocodazole treatment. By using the mouse for parthenogenetic activation studies, we showed that early cleavage stage embryos derived from parthenogenetic activation of nocodazole-treated oocytes displayed normal activation rate and normal γH2A.X signal strength, indicating that no additional DNA damage occured. Our results suggest that DNA damage inhibits porcine oocyte maturation, while nocodazole-induced dissociation between chromosomes and microtubules does not lead to increased DNA damage either in mouse meiotic oocytes or in porcine oocytes.     

Synaptic behaviour of the tetraploid wheat Triticum timopheevii

Triticum timopheevii (2n=4x=A^tA^tGG) is an allotetraploid wheat which shows a diploid-like behaviour at metaphase-I. The synaptic process was analyzed in fully traced spread nuclei at mid-zygotene, late-zygotene and pachytene. The length and type of synaptonemal complexes, as well as the number of bivalent and multivalent associations, were determined in each nucleus. A high number of bivalents per nucleus was detected at all three stages. Nuclei at pachytene showed a lower frequency of multivalents than did zygotene nuclei, which suggests the existence of a pairing correction mechanism. At metaphase-I only homologous bivalents and, rarely, one pair of univalents were observed. Similarities between the diploidization mechanism of T. timopheevii and that of allohexaploid wheat, controlled by chromosome 5B, are discussed.     

The effects of estrous cow serum on the in vitro maturation and fertilization of the bovine follicular oocyte

The effect of serum obtained from a cow at the time of standing estrus (serum A), at ovulation (serum B), and at 24 h after ovulation (serum C) on the in vitro maturation and fertilization of bovine oocytes was examined. Of 144 (Group A), 159 (Group B), and 158 (Group C) oocytes, 77 (53.4%), 82 (51.6%) and 82 (51.9%) oocytes were characterized by expansion of cumulus cells, respectively. There was no significant difference in the effect of the three types of cow serum on the cumulus expansion (P < 0.05). Of 461 oocytes, 316 oocytes were cultured with sperm for fertilization, and 145 oocytes were cultured without sperm for evidence of parthenogenetic development. Of 56 (Group A), 56 (Group B), and 62 (Group C) oocytes with expanded cumulus cells, 19 (33.9%), 7 (12.5%), and 11 (17.7%) oocytes were cleaved, respectively, after exposed to the sperm for 24 h. There was a significant difference in the effect of the three types of cow serum on the fertilization rate (P < 0.05). A total of 145 oocytes was cultured in the absence of sperm and no evidence of parthenogenetic division was observed. The effect of the three types of serum obtained from the cow on the maturation of oocytes was not significant, but a significant difference did exist in the fertilization rate of oocytes. Cow serum obtained at the time of standing estrus had a beneficial effect on the fertilization rate of oocytes in vitro.     

Bovine parthenogenetic blastocysts following in vitro maturation and oocyte activation with ethanol

The appropriate in vitro bovine oocyte maturation and ethanol activation conditions for preimplantation bovine embryo parthenogenetic development to the blastocyst stage were investigated. A 7% ethanol concentration significantly enhanced (P<0.05) the proportion of activated, in vitro-matured bovine oocytes (7% ethanol, 83.4 +/- 3.2% versus 0% ethanol, 63.9 +/- 2.0%). The proportion of activated oocytes was significantly higher (P<0.05) by treatment with 7% ethanol for a minimum of 2 minutes (2 minutes, 89.8 +/- 4.0% versus 0.5 minutes 63.4 +/- 4.9%). Oocyte maturation for periods ranging from 30, 34, 38 and 44 hours resulted in a significant increase (P<0.05) in the proportion of activated oocytes, and in oocytes displaying 2 or 3 pronuclei versus oocytes matured for 26 hours. The proportion of cleaved, activated oocytes (2-cell stage), 4 -cell stage and parthenogenetic morula/blastocysts was significantly higher (P<0.05) within the 34-hour oocyte maturation treatment group. Although the 44-hour oocyte maturation treatment group displayed the highest proportion of activated oocytes with 2 pronuclei, it did not display the highest cleavage frequency, possibly due to the effects of postovulatory aging. Several morphologically normal parthenogenetic bovine blastocysts developed from oocytes that were in vitro matured for 34 hours. The ability to produce such parthenogenetic embryos will eventually facilitate investigation into the role(s) of the maternal and paternal genomes during bovine early development.     

The temporal and spatial distribution of the proliferation associated Ki-67 protein during female and male meiosis

We used immunolocalization in tissue sections and cytogenetic preparations of female and male gonads to study the distribution of the proliferation marker pKi-67 during meiotic cell cycles of the house mouse, Mus musculus. During male meiosis, pKi-67 was continuously present in nuclei of all stages from the spermatogonium through spermatocytes I and II up to the earliest spermatid stage (early round spermatids) when it appeared to fade out. It was not detected in later spermatid stages or sperm. During female meiosis, pKi-67 was present in prophase I oocytes of fetal ovaries. It was absent in oocytes from newborn mice and most oocytes of primordial follicles from adults. The Ki-67 protein reappeared in oocytes of growing follicles and was continuously present up to metaphase II. Thus, pKi-67 was present in all stages of cell growth and cell division while it was absent from resting oocytes and during the main stages of spermiocytogenesis. Progression through the meiotic cell cycle was associated with extensive intranuclear relocation of pKi-67. In the zygotene and pachytene stages, most of the pKi-67 colocalized with centromeric (centric and pericentric) heterochromatin and adjacent nucleoli; the heterochromatic XY body in male pachytene, however, was free of pKi-67. At early diplotene, pKi-67 was mainly associated with nucleoli. At late diplotene, diakinesis, metaphase I and metaphase II of meiosis, pKi-67 preferentially bound to the perichromosomal layer and was almost absent from the heterochromatic centromeric regions of the chromosomes. After the second division of male meiosis, the protein reappeared at the centromeric heterochromatin and an adjacent region in the earliest spermatid stage and then faded out. The general patterns of pKi-67 distribution were comparable to those in mitotic cell cycles. With respect to the timing, it is interesting to note that relocation from the nucleolus to the perichromosomal layer takes place at the G2/M-phase transition in the mitotic cell cycle but at late diplotene of prophase I in meiosis, suggesting physiological similarity of these stages.     

Multiple synaptinemal complexes at the region of gene amplification in Acheta

Ovaries of Acheta domesticus (house cricket) were fixed for electron microscopy at two stages of development: (1) ovaries containing mainly oocytes at interphase and early prophase of meiosis, and (2) ovaries with oocytes mainly at pachytene and diplotene. The E.M. study was accompanied by three types of light microscopy controls consisting mainly of cytochemical tests. Every oocyte contains a DNA body which at pachytene and diplotene acquires the appearance of a puff. In the light microscope two zones can be distinguished inside the body: (1) an inner core of DNA and (2) and outer shell of RNA. In the E. M. the inner core consists of a fibrillar material and the outer shell is composed of areas of high electron opacity consisting mainly of tightly packed particles and fibrils. At these stages synaptinemal complexes are seldom seen associated with the DNA body but are present throughout the nucleus as part of the paired chromosomes. The complexes are present as single units. — In the oocytes at interphase and early prophase of meiosis, where the DNA body is active in DNA replication, the body appears in the light microscope as a large Feulgen positive sphere containing Feulgen negative areas. In the E. M. at these stages the DNA body consists of: (a) the two components found at pachytene, (b) a third electron dense component which is more homogeneous than the other two, and (c) of large assemblies of synaptinemal complexes originating from several centers. The most significant features of the axial complexes are: (1) the circular packing of the complexes, (2) their occurrence in packages of 300 to 400 units and (3) the fact that not all of the DNA body forms complexes but only a part of it.Biochemical experiments (Lima-de-Faria, Birnstiel and Jaworska, 1969) have demonstrated the amplification of ribosomal cistrons in the DNA body of Acheta. The simplest explanation is that the multiple complexes are formed either between the extra gene copies of the two homologues, or between the extra copies of each chromosome as well. There seems to be a correlation between the presence of multiple axial complex formation and gene amplification in Acheta but the exact relation between the two phenomena demands further study.Dedicated to Dr. Sally Hughes-Schrader on the occasion of the seventyfifth birthday on the twentyfifth of January 1970.     

Changes in global histone acetylation pattern in somatic cell nuclei after their transfer into oocytes at different stages of maturation

In our study, we have examined the pattern of global histone modification changes in somatic cell nuclei after their transfer into mouse oocytes at different stages of maturation or after their parthenogenetic activation. While germinal vesicle (GV) staged immature oocytes are strongly labeled with anti-acetylated histone H3 and H4 antibodies, the signal is absent in both metaphase I and metaphase II oocytes (MI, MII). In contrast, the oocytes of all maturation stages show a presence of trimethylated H3/K4 in their chromatin. When somatic cells were fused to intact or enucleated GV oocytes, both the GV and the somatic cell nucleus showed a very strong signal for all the antibodies used. On the other hand, when somatic cells nuclei that are AcH3 and AcH4 positive before fusion are introduced into either intact or enucleated MI or MII oocytes, their acetylation signal decreased rapidly and was totally absent after a prolonged culture. This was not the case when anti-trimethyl H3/K4 antibody was used. The somatic cell chromatin showed only a slight decrease in the intensity of labeling after its transfer into MI or MII oocytes. This decrease was, however, evident only after a prolonged culture. These results suggest not only a relatively higher stability of the methylation modification but also some difference between the oocyte and somatic chromatin. The ability to deacetylate the chromatin of transferred somatic nuclei disappears rapidly after the oocyte activation. Our results indicate that at least some reprogramming activity appears in the oocyte cytoplasm almost immediately after GV breakdown (GVBD), and that this activity rapidly disappears after the oocyte activation.     

Developmental potential of LT/Sv parthenotes derived from oocytes matured in vivo and in vitro

Release of oocytes of LT/Sv mice from the meiosis-inhibiting influence of antral follicles promotes parthenogenetic activation and development to early cleavage stages of 14% of the eggs. However, to attain the potential to develop to blastocysts under the culture conditions used, the oocytes must mature within follicles for 8–9 hr after human chorionic gonadotropin (HCG) administration. The results suggest that some positive influence, which does not occur during spontaneous oocyte maturation under defined conditions in vitro, occurs within preovulatory follicles and imparts developmental competence to the maturing oocytes.     

The synaptonemal complexes of Meloidogyne: relationship of structure and evolution of parthenogenesis

The synaptonemal complexes of three amphimictic (meiotic) strains of Meloidogyne are examined in this study. M. microtyla (n = 19) has a tripartite synaptonemal complex (SC) comprised of two lateral elements and one central region with a distinct central element. The central region of the SC in both M. carolinensis (n = 18) and M. megatyla (n = 18) lack a distinct central element. The evolutionary history is different in the strains since M. microtyla has arisen by a mechanism involving an increase in chromosome number (from an ancestral stock of n = 18) while both M. carolinensis and M. megatyla have maintained the number of chromosomes of the ancestral stock. The structure of the SCs of the latter two strains are identical to the structure of the SC of the meiotic parthenogenetic M. hapla. Thus, the pachytene karyotype of M. carolinensis was reconstructed to establish the pairing pattern and identify any changes that may be related to the different morphology of the SC in an amphimictic stock. Although recombination nodules (RN) have been observed in the parthenogenetic M. hapla, none of the three amphimictic strains had any SC associated structures that resembled a RN.     

Unusual cytoskeletal and chromatin configurations in mouse oocytes that are atypical in meiotic progression

Meiotic maturation progresses atypically in oocytes of strain LT/Sv and l/LnJ mice. LT/Sv occytes show a high frequency of metaphase l-arrest and parthenogenetic activation. l/LnJ oocytes display retarded kinetics of meiotic maturation and a high frequency of metaphase l-arrest. Some l/LnJ oocytes fail to resume meiosis. Changes in the configuration of chromatin, microtubules, and centrosomes are associated with specific stages of meiotic progression. In this study, the configuration of these subcellular components was examined in LT/Sv, l/LnJ, and C57BL/6J (control) oocytes either freshly isolated from large antral follicles or after culture for 15 hr to allow progression of spontaneous meiotic maturation. Differences were found in the organization of chromatin, microtubules, and centrosomes in LT/Sv and l/LnJ oocytes compared to control oocytes. For example, rather than exhibiting multiple cytoplasmic and nuclear centrosomes as in the normal germinal vesicle-stage oocytes, LT/Sv oocytes typically contain a single large centrosome. In contrast, l/LnJ oocytes displayed many small centrosomes. The microtubules of normal germinal vesicle-stage oocytes were organized as arrays or asters, but microtubules were shorter in LT/Sv oocytes and absent from l/LnJ oocytes. After a 15-hr culture, centrosomal material of normal metaphase II oocytes was organized at both spindle poles. In contrast, metaphase l-arrested LT/Sv oocytes exhibited an elongated spindle with centrosomal material appearing more organized at one pole of the spindle. Both control and LT/Sv oocytes displayed cytoplasmic centrosomes. Metaphase l-arrested l/LnJ oocytes rarely had cytoplasmic centrosomes but exhibited centrosomal foci at the spindle periphery. Thus, oocytes that are atypical in the progression of meiotic maturation displayed aberrant configurations of microtubules and centrosomes, which are thought to participate in the regulation of meiotic maturation.     

The gene coding the human S11 surface antigens maps between the loci for HPRT and G6PD on the X-chromosome

1-Methyladenine, which has been previously shown to be the hormone responsible for meiosis reinitiation in starfish oocytes, triggers parthenogenetic activation when applied to matured starfish oocytes after emission of the second polar body and formation of the pronucleus. In Marthasterias glacialis and Asterias rubens oocytes parthenogenetic activation includes elevation of a fertilization membrane, cleavage and the formation of normal bipinnaria larvae. Activation is likely to result from 1-methyladenine interaction with the category of stereospecific membrane receptors involved in meiosis reinitiation, since structural requirements of this compound are identical for both biological responses. Appearance of oocyte responsiveness to 1-MeAde after, but not before emission of the second polar body cannot be accounted for by their increased sensitivity to intracellular Ca²⁺ at that time, although it is shown that Ca²⁺ mediates hormone effect in inducing parthenogenetic activation. Pretreatment of immature oocytes with the free hormone in excess strongly inhibits the 1-methyladenine-induced parthenogenetic activation of the oocytes when they have completed maturation.It is suggested that reappearance of 1-MeAde sensitivity when oocytes form a pronucleus depends either upon recruitment or new receptor units or on the reactivation of pre-existing inactivated receptors at this stage of oocyte maturation.