Xiangzhong Yang

Epigenetic Characteristics and Development of Embryos Cloned from Donor Cells Treated by Trichostatin A or 5-aza-2′-deoxycytidine

Abstract Development to blastocyst following nuclear transfer is dependent on the donor cells ability to reprogram its genome to that of a zygote. This reprogramming step is inefficient and may be dependent on a number of factors, including chromatin organization. Trichostatin A (TSA; 0–5 μM), a histone deacetylase inhibitor, was used to increase histone acetylation and 5-aza-2′-deoxycytidine (5-aza-dC; 0–5 μM), a DNA methyl-transferase inhibitor, was used to decrease methylation of chromatin in donor cells in an attempt to improve their reprogrammability. Adult fibroblast cells treated with 1.25 or 5 μM TSA had elevated histone H3 acetylation compared to untreated controls. Cells treated with 0.3 μM 5-aza-dC had decreased methylation compared to untreated controls. Both drugs at 0.08 μM caused morphological changes of the donor cells. Development to blastocysts by embryos cloned from donor cells after 0.08 or 0.3 μM 5-aza-dC treatments was lower than in embryos cloned from untreated control cells (9.7% and 4.2%, respectively, vs. 25.1%), whereas 0.08 μM TSA treatment of donor cells increased blastocyst development compared to controls (35.1% vs. 25.1%). These results indicate that partial erasure of preexisting epigenetic marks of donor cells improves subsequent in vitro development of cloned embryos.

Culture of in vitro produced bovine zygotes in vitro vs in vivo: Implications for early embryo development and quality

The objectives of this study were to examine the effect of culture system on bovine blastocyst formation rates and quality. Presumptive IVM/IVF bovine zygotes were cultured either in vitro in synthetic oviduct fluid (SOF, 25 embryos/25 microL in 5% CO2, 5% O2, 90% N2 at 39 degrees C) or in vivo in the ewe oviduct (approximately 100 embryos per oviduct). The recovery rate after in vivo culture was 53% (813/1,530). The blastocyst rate on Day 7 was significantly higher for the in vitro system (28%, 362/1,278 vs 17%, 37/813; P< 0.0001). However, after culture in vitro for a further 24 h, there was no difference in Day 8 yields (36%, 457/1,278 vs 32%, 258/813, for in vitro and in vivo culture, respectively). There was no difference in blastocyst cell number between treatments (Day 7: 96 vs 103; Day 8: 78 vs 85 for in vitro and in vivo culture, respectively). Irrespective of culture system, Day 7 blastocysts had a significantly higher cell number than those appearing on Day 8. There was no difference in pregnancy rate at Day 35 after fresh transfer of a single Day 7 blastocyst (37.5%, 21/56 vs 45.3%/, 24/53 for in vitro and in vivo culture, respectively). After cryopreservation by freezing in 10% glycerol, VS3a vitrification or solid surface vitrification, the survival of in vitro cultured embryos was significantly lower than survival of embryos cultured in the ewe oviduct or those produced by superovulation of donors. In conclusion, these findings demonstrate that while bovine zygotes cultured in vitro are capable of rates of development similar to those of their in vivo cultured counterparts (in terms of Day 8 blastocyst yield, cell number and early pregnancy rate), there are significant differences in embryo cryosurvival. This suggests that current in vitro culture systems need to be improved to optimize embryo quality and pregnancy rates.

Control of oocyte maturation in cows--biological factors.

Since bovine in vitro fertilization became possible in the early 80s, a lot of effort has been done to clarify the mechanisms of what seems more and more one of the crucial steps in this procedure, being oocyte maturation. Undoubtedly, many biological factors act together to prepare the immature oocyte for a successful development to a competent embryo after fertilization. Defects in oocyte maturation can possibly be caused by an inadequate nuclear or cytoplasmic maturation or even by a failure of both. There is a general agreement upon the fact that the origin of the oocyte can play an important role. Oocytes derived from very small follicles show a lower rate of maturation and lower blastocyst development with currently used maturation protocols. Parthenogenetic activation of small size follicle derived oocytes suggests that their poor development was not caused by fertilization problems but more likely by intrinsic oocyte factors. Similar developmental rates achieved through nuclear transfer and parthenogenetic activation suggests that the nucleus of the incompetent oocyte may not be the sole reason for a poor development. Another important factor appears to be the donor animal age. The younger the donor animal, the more impaired is its oocytes developmental competence in most of the embryo IVP systems. Treatment with exogeneous gonadotropins can be beneficial in young donors on the oocyte cleavage rates but does not always increase the final blastocyst outcome. This review briefly documents some of the biological factors and their possible effects on the developmental capacities of the bovine oocyte in vitro.

Reproductive Characteristics of Cloned Heifers Derived from Adult Somatic Cells

Abstract This study examined the onset of puberty, follicular dynamics, reproductive hormone profiles, and ability to maintain pregnancy in cloned heifers produced by somatic cell nuclear transfer. Four adult somatic cell-cloned heifers, derived from a 13-yr-old Holstein cow, were compared to 4 individual age- and weight-matched heifers produced by artificial insemination (AI). From 7 to 9 mo of age, jugular venous blood samples were collected twice weekly, and from 10 to 11 or 12 mo of age, blood sampling was carried out every other day. After the heifers reached puberty (defined as the first of 3 consecutive blood samples with peripheral plasma progesterone concentrations of >1 ng/ml), ultrasound examination of ovaries and jugular plasma sample collection were carried out daily for 1 estrous cycle. Cloned heifers reached puberty later than controls (mean ± SEM, 314.7 ± 9.6 vs. 272 ± 4.4 days and 336.7 ± 13 vs. 302.8 ± 4.5 kg for clones and controls, respectively; P < 0.05). However, cloned and control heifers were not different in estrous cycle length, ovulatory follicle diameter, number of follicular waves, or profiles of hormonal changes (LH, FSH, estradiol, and progesterone). Three of the 4 clones and all 4 control heifers became pregnant after AI. These results demonstrate that clones from an aged adult have normal reproductive development.

Micromanipulation of mammalian embryos: Principles, progress and future possibilities

Numerous advances in development of techniques for manipulating mammalian embryos outside the maternal environment have been made over the past decade. Some techniques were developed primarily for use in research; others were developed in response to problems of practical livestock production but have proven useful in research as well. Embryo micromanipulation procedures are used often in conjunction with embryo transfer, and interest in these procedures was stimulated by growth of the embryo transfer industry. Included in this review are discussions of procedures for manipulation of gametes and embryos, including sperm injection into oocytes, pronuclear and nuclear transfer, embryo biopsy and splitting, experimental chimera production and isolation of embryonic stem cells.

Timed breeding of rabbits with fresh and frozen-thawed semen and evidence of acrosome alteration following freezing and thawing

The objectives of this research were to compare extenders for freezing rabbit spermatozoa, to study the effect of freezing on the acrosome and to test the possibility that an effect on the acrosome could alter the optimal time for insemination relative to expected ovulation time. In Experiment 1, the percentage of motile spermatozoa frozen in 0.5 ml straws was higher (P 0.05) in the pregnancy rate between does inseminated with fresh or frozen semen. The percentage of does pregnant (12 does per group) with fresh semen inseminated at 0 and 10 h after Buserelin was 75 and 75, and correspondingly for frozen-thawed semen was 100 and 42. Litter size and the number of young born was greater (P < 0.05) for both semen treatment groups at 0 h (the normal time for insemination) than at 10 h, which was the expected time of ovulation. Thus, if freezing did reduce the time required for capacitation, it was not detectable by these experiments.

Influence of somatotropin and nutrition on bovine oocyte retrieval and in vitro development.

The objective of this study was to determine the effects of supplemental bovine somatotropin (bST) and limit feeding on follicular growth and oocyte competence in yearling beef heifers. Sixteen growing heifers (424+/-4 kg) were randomly assigned to 1 of 4 treatments in a 2 x 2 factorial arrangement, with main effects of bST (0 or 33 microg/kg BW/d) and feeding regimen (ad libitum or 0.75 ad libitum intake). Animals were treated for 100 d prior to follicular aspiration, and treatments continued for the 42-d period that follicles were aspirated. Follicles were observed ultrasonically then aspirated, and recovered oocytes were matured, fertilized and developed in vitro. The number of follicles observed ultrasonically was greater with bST treatment (P<0.01) but was unchanged by plane of nutrition. The number and quality of recovered oocytes were similar among treatments, as was the number of oocytes resulting in blastocyst formation.

Development of cellular polarity of hamster embryos during compaction

Development of cellular polarity is an important event during early mammalian embryo development and differentiation. Blastomeres of hamster embryos at various stages were examined by scanning electron microscopy (SEM) and immunocytochemical staining. SEM observations revealed that 1- to 7-cell-stage embryos showed a uniform distribution of microvilli throughout the cell surface. Microvillous polarization was initially noted in the blastomeres (10-35%) of 8-cell-stage embryos. The polarized microvilli were observed mostly in the basal region of cell-cell contact and occasionally at the apical, outward-facing surface of the blastomere. Fluorescein-isothiocyanate-conjugated concanavalin A failed to reveal any polarity in the blastomeres regardless of the stages of the embryos. Actin staining showed that microfilaments were present beneath the cell surface, and in addition, areas of cell contact were more heavily stained, indicating a thick microfilament domain. Microtubules were located throughout the cytoplasm and were heavily concentrated near the nucleus during interphase, although they became redistributed in the region of the mitotic spindle during karyokinesis. The position of nucleus changed from the cell center to the apical, outward-facing surface of the cell, and it distanced itself from the basal microvillous pole. It is suggested that the changes in the cell surface and nuclear position are the first manifestations of cell polarity in peri-compacted hamster embryos, which appear as early as the 8-cell stage; furthermore, the outward migration of the nuclei may parallel the redistribution of microtubules in the cytoplasm.