Alternative strategies for nuclear reprogramming in somatic cell nuclear transfer (SCNT)

Twenty years passed by since the production of Dolly the sheep, but despite significant technical progress has been achieved in the manipulation procedures, the proportion of offspring following transfer of SCNT embryos has remained almost unchanged in farm animals. Remarkable progress has been obtained instead in laboratory animals, particularly by Japanese Groups, in the mouse. However, the nuclear reprogramming strategies tested in mouse do not always work in farm animals, and others are difficult to be implemented, for require complicated molecular biology tools unavailable yet in large animals. In this review we put in contest the previous work done in farm and laboratory animals with recent achievements obtained in our laboratory, and we also indicate a road map to increase the reliability of SCNT procedures

Short spermatozoa–oocyte co-incubation improves outcomes of IVF in sheep

The assisted reproductive technique IVF is routinely applied in humans and large animals, both to boost reproductive performance and also for basic research. Despite its value, IVF has seen very little progress in the last two decades and relies on established paradigms, such as overnight sperm–egg co-incubation. However, the long exposure of oocytes to spermatozoa in a dish increases the risk of polyspermy and could be detrimental for early stages of embryonic development. We identified a time window within which fertilization occurs, in order to reduce the length of sperm–egg co-incubation and optimize the procedure, comparing polyspermy rate and embryo development after short (shIVF) and overnight (o/nIVF) spermatozoa–oocyte co-incubation. A total of 666 in vitro–matured sheep oocytes were co-incubated with spermatozoa in IVF medium (synthetic oviductal fluid (SOF) with 20% oestrus sheep serum and 16 µM isoproterenol). First, small batches of oocytes were collected every 30 min to check for the presence of a fertilizing spermatozoon. To assess this, cumulus cells were removed and presumptive fertilized oocytes were fixed and stained with propidium iodide for nuclei and Pisum sativum agglutinin for zona pellucida (ZP) detection, respectively. Then, pronuclear formation (PN) and embryo development were evaluated after 16 h (PN), 24 h (2 cells), and 7 days of culture (blastocyst). The oocytes that were not cleaved at 24 h were stained for DNA content with Hoechst 33342. Furthermore, we evaluated embryo quality by counting cells of 8-day blastocysts after differential staining of inner cell mass (ICM) and trophectoderm (TE). We found that spermatozoa reach the ZP no earlier than 90 min from the beginning of co-incubation and achieve fertilization within 4 h. Polyspermic fertilization (>2PN) was lower in shIVF (6.5%) than in o/nIVF (17.8%; P = 0.006). This proportion of polyspermy was maintained between groups in noncleaved oocytes at 24 h from fertilization. Likewise, cleavage and blastocyst rate were higher in shIVF compared with the o/n-IVF group (2-cells: 48.3% vs. 31.6%, P = 0.001; blastocyst: 29.4% vs. 20.5%, P = 0.046, respectively). Differential staining of blastocysts revealed no significant difference in cell number between the blastocysts of the two groups. This work demonstrates that 4 h of sperm-egg interaction are sufficient to achieve fertilization, reduce polyspermy, and improve the rate of embryos reaching blastocyst stage without compromising embryo quality

Somatic cell nuclear transfer: failures, successes and the challenges ahead

Somatic cell nuclear transfer (SCNT) has a broad spectrum of potential applications, including rescue of endangered species, production of transgenic animals, drug production, and regenerative medicine. Unfortunately, the efficiency of SCNT is still disappointingly low. Many factors affecting cloning procedures have been described in several previous reviews; here we review the most effective improvements in SCNT, with a special emphasis on the effect of mitochondrial defects on SCNT embryo/ foetus development, an issue never touched upon before

The impaired development of sheep ICSI derived embryos is not related to centriole dysfunction

While intracytoplasmic sperm injection (ICSI) is an asset in human Assisted Reproduction Technologies (ART), its outcomes, in terms of blastocyst, is still unacceptably low in ruminants. The picture typically found in ICSI derived bovine and ovine embryos is an asymmetry between a high activation rate, marked by a pronuclear development, and a low first cleavage rate. Abnormal centriole function has been indicated as a possible factor which undermines embryonic development following ICSI, especially when Freeze Dried spermatozoa (FD) are used. In order to verify the hypothesis that centriole dysfunction might be responsible for low ICSI outcomes in sheep, we have investigated micro-tubular dynamics, markedly aster nucleation, in fertilized sheep zygotes by ICSI with frozen/thawed (FT) and FD spermatozoa; In Vitro Fertilized (IVF) sheep oocytes were used as control. The spermatozoa aster nucleation was assessed at different time points following ICSI and IVF by immune-detection of a-tubulin. Pronuclear stage, syngamy and embryo development were assessed. No difference was noticed in the timing of aster nucleation and microtubule elongation in ICSI-FT derived embryos with control IVF ones, while a delay was recorded in ICSI-FD ones. The proportion of 2-pronuclear stage zygotes was similar in ICSI-FT and ICSI-FD (47% and 53%, respectively), both much lower comparing the IVF ones (73%). Likewise, syngamy was observed in a minority of both ICSI groups (28.5% vs 12.5% in ICSI-FT/FD respectively) comparing to IVF controls (50%), with a high number of zygotes blocked at the 2-pronuclear stage (71.5% vs 87.5% respectively). While no significant differences were noticed in the cleavage rate between ICSI-FD, ICSI-FT and IVF groups (31%, 34% and 44%) respectively, development to blastocyst stage was markedly compromised in both ICSI groups, especially with FD spermatozoa (10% in ICIS-FD and 19% in ICSI-FT vs 33% in IVF (P < 0.005, ICSI-FD vs IVF and P < 0.05, IVF vs ICSI-FT, respectively). Hence, here we have demonstrated that the reduced cleavage, and the ensuing impaired development to blastocysts stage of ICSI derived sheep embryos is not related to centriole dysfunction, as suggested by other authors. The major recorded problem is the lack of syngamy in ICSI derived zygotes, an issue that should be addressed in further studies to improve ICSI procedure in sheep embryos

Developmental peculiarities in placentae of ovine uniparental conceptuses

Genomic imprinting is an epigenetic phenomenon regulating mono-allelic expression of genes depending on their parental origin. Defective genomic imprinting is involved in several placental disorders, such as intrauterine growth restriction and pre-eclampsia. Uniparental embryos, having maternal-only or paternal-only genomes (parthenogenotes [PAR] and androgenotes [AND], respectively), are useful models to study placentation. The aim of this work was to reveal the effect of parental genome (maternal and paternal) on placentation. To do this, uniparental (AND and PAR) and biparental (CTR) in vitro produced sheep embryos transferred to recipient females were collected at day 20 of pregnancy and their placentae were analyzed. qPCR analysis showed that imprinted genes (H19, IGF2R and DLK1) were expressed accordingly to their parental origin while the expression f DNA methyltransferases () was disregulated, especially in PAR (P < 0.05). AND placentae were significantly hypomethylated compared to both PAR and CTR (P = 0.023). Chorion-allantoid of AND showed impaired development of vessels and reduced mRNA expression of vasculogenetic factors (ANG2 P = 0.05; VEGFR2 P< 0.001; TIE2 P < 0.001). Morphologically, PAR placentae were characterized by abnormal structure of the trophoectodermal epithelium and reduced total number (P<0.03) of Trophoblastic Binucleate Cells. A reduced implantation rate of both classes of uniparental embryos (P<0.03) was also noted. Our results provide new insights into the characterization of uniparental embryos and demonstrate the complementary role of parental genomes for the correct establishment of pregnancy. Thus, our findings may suggest new targets to improve our understanding of the origin of imprinting-related placental dysfunction

Ultrastructural analysis reveals abnormal mitochondria in cloned blastocysts

Somatic cell nuclear transfer (SCNT) is a powerful technique, but still very inefficient despite 20 years passed by since the cloned mammal was born. We have recently shown that the major cause of abnormalities observed in cloned fetuses are mitochondrial dysfunctions in placenta collected from cloned sheep. Investigations on mitochondria in SCNT are limited to the mtDNA hetero/homoplasmy in cloned offspring, whereas no data is available for an eventual role of mitochondria dysfunction on the developmental failure of cloned animals. Here we wanted to know whether mitochondrial abnormalities are observed already in cloned blastocysts since mitochondrial replication does not occur after the hatched blastocysts stage. SCNT and in vitro processed (IVP) blastocysts were produced and analysed for mitochondrial structure and functionality. First, embryos were analysed using transmission electron microscope (TEM). Drastic differences in mitochondrial structure between SCNT and IVP blastocysts were observed. Decrease density of mature mitochondria, very high degree of cytoplasmic vacuolisation, numerous cytoplasmic vesicle and autophagosomes were observed in SCNT blastocysts. Moreover, statistically lower expression of major mitochondrial, autophagic and apoptotic proteins were observed in SCNT embryos. Obtained results clearly shown that mitochondrial abnormalities are already observed in blastocysts stage embryos. It is important to point out that activity of mitochondria are strictly control by nuclear signals, thus, obtained results may suggest that incomplete nuclear reprogramming in cloned nucleus might be responsible also for the impaired mitochondrial function in cloned embryos/fetuses

Dry storage of mammalian spermatozoa and cells: state-of-the-art and possible future directions

This review provides a snapshot of the current state-of-the-art of drying cells and spermatozoa. The major successes and pitfalls of the most relevant literature are described separately for spermatozoa and cells. Overall, the data published so far indicate that we are closer to success in spermatozoa, whereas the situation is far more complex with cells. Critical for success is the presence of xeroprotectants inside the spermatozoa and, even more so, inside cells to protect subcellular compartments, primarily DNA. We highlight workable strategies to endow gametes and cells with the right combination of xeroprotectants, mostly sugars, and late embryogenesis abundant (LEA) or similar ‘intrinsically disordered’ proteins to help them withstand reversible desiccation. We focus on the biological aspects of water stress, and in particular cellular and DNA damage, but also touch on other still unexplored issues, such as the choice of both dehydration and rehydration methods or approaches, because, in our view, they play a primary role in reducing desiccation damage. We conclude by highlighting the need to exhaustively explore desiccation strategies other than lyophilisation, such as air drying, spin drying or spray drying, ideally with new prototypes, other than the food and pharmaceutical drying strategies currently used, tailored for the unique needs of cells and spermatozoa

Polychlorinated biphenyls (PCBs) alter DNA methylation and genomic integrity of sheep fetal cells in a simplified in vitro model of pregnancy exposure

Polychlorinated biphenyls (PCBs) are persistent organic pollutants ubiquitously detectable in the environment and in the food chain. Prenatal exposure to PCBs negatively affects fetal development and produces long-term detrimental effects on child health. The present study sought to evaluate the cytotoxic and genotoxic effects of chronic PCB exposure on fetal cells during pregnancy. To this aim, sheep embryonic fibroblasts (SEF) and amniocytes (SA) were cultured in vitro in the presence of low doses of PCBs for a period of 120 days, comparable to the full term of ovine pregnancy. Cellular proliferation rates, global DNA methylation, chromosome integrity, and markers of DNA damage were evaluated at different time points. Moreover, SEF treated with PCBs for 60 days were left untreated for one further month and then examined in order to evaluate the reversibility of PCB-induced epigenetic defects. PCB-treated SEF were more sensitive than SA treated with PCBs, in terms of low cell proliferation, and increased DNA damage and global DNA methylation, which were still detectable after interruption of PCB treatment. These data indicate that chronic exposure of fetal cells to PCBs causes permanent genomic and epigenetic instability, which may influence both prenatal and post-natal growth up to adulthood. Our in vitro model offer a simple and controlled means of studying the effects of different contaminants on fetal cells - one that could set the stage for targeted in vivo studies

Evidence of placental autophagy during early pregnancy after transfer of in vitro produced (IVP) sheep embryos

Pregnancies obtained by Assisted Reproductive Technologies (ART) are associated with limited maternal nutrient uptake. Our previous studies shown that in vitro culture of sheep embryos is associated with vascularization defects in their placentae and consequent reduction of embryo growth. Autophagy is a pro-survival cellular mechanism triggered by nutrient insufficiency. Therefore, the goal of our present study was to determine if autophagy is involved in early placental development after transfer of in vitro produced (IVP) embryos. To do this, placentae obtained following transfer of IVP sheep embryos were compared with placentae obtained after natural mating (control-CTR). The placentae were collected on day 20 post-fertilization and post-mating, respectively, and were analyzed using molecular (qPCR), ultrastructural and histological/immunological approaches. Our results show drastically increased autophagy in IVP placentae: high levels of expression (p<0.05) of canonical markers of cellular autophagy and a high proportion of autophagic cells (35.08%; p<0.001) were observed. We conclude that high autophagic activity in IVP placentae can be a successful temporary counterbalance to the retarded vasculogenesis and the reduction of foetal growth observed in pregnancies after transfer of IVP embryos