Quantitative proteomics reveals the dynamic proteome landscape of zebrafish embryos during the maternal-to-zygotic transition.

Maternal-to-zygotic transition (MZT) is central to early embryogenesis. However, its underlying molecular mechanisms are still not well described. Here, we revealed the expression dynamics of 5,000 proteins across four stages of zebrafish embryos during MZT, representing one of the most systematic surveys of proteome landscape of the zebrafish embryos during MZT. Nearly 700 proteins were differentially expressed and were divided into six clusters according to their expression patterns. The proteome expression profiles accurately reflect the main events that happen during the MZT, i.e., zygotic genome activation (ZGA), clearance of maternal mRNAs, and initiation of cellular differentiation and organogenesis. MZT is modulated by many proteins at multiple levels in a collaborative fashion, i.e., transcription factors, histones, histone-modifying enzymes, RNA helicases, and P-body proteins. Significant discrepancies were discovered between zebrafish proteome and transcriptome profiles during the MZT. The proteome dynamics database will be a valuable resource for bettering our understanding of MZT.

Blastocyst Cell Number and Allocation Affect the Developmental Potential and Transcriptome of Bovine Somatic Cell Nuclear Transfer Embryos.

Cloning cattle using somatic cell nuclear transfer (SCNT) is inefficient. Although the rate of development of SCNT embryos in vitro is similar to that of fertilized embryos, most fail to develop into healthy calves. In this study, we aimed to identify developmentally competent embryos according to blastocyst cell composition and perform transcriptome analysis of single embryos. Transgenic SCNT embryos expressing nuclear-localized HcRed gene at day 7 of development were imaged by confocal microscopy for cell counting and individually transferred to recipient heifers. Pregnancy rates were determined by ultrasonography. Embryos capable of establishing pregnancy by day 35 had an average of 117 ± 6 total cells, whereas embryos with an average of 128 ± 5 cells did not establish pregnancy (P < 0.05). A lesser average number of 41 ± 3 cells in the inner cell mass (ICM) also resulted in pregnancies (<0.05) than a greater number of 48 ± 2 cells in the ICM. Single embryos were then subjected to RNA sequencing for transcriptome analysis. Using weighted gene coexpression network analysis, we identified clusters of genes in which gene expression correlated with the number of total cells or ICM cells. Gene ontology analysis of these clusters revealed enriched biological processes in coenzyme metabolic process, intracellular signaling cascade, and glucose catabolic process, among others. We concluded that SCNT embryos with fewer total and ICM cell numbers resulted in greater pregnancy establishment rates and that these differences are reflected in the transcriptome of such embryos.

Early Cell Specification in Mammalian Fertilized and Somatic Cell Nuclear Transfer Embryos.

Early cell specification in mammalian preimplantation embryos is an intricate cellular process that leads to coordinated spatial and temporal expression of specific genes. Proper segregation into the first two cell lineages, the inner cell mass (ICM) and the trophectoderm (TE), is imperative for developing the embryo proper and the placenta, respectively. Somatic cell nuclear transfer (SCNT) allows the formation of a blastocyst containing both ICM and TE from a differentiated cell nucleus, which means that this differentiated genome must be reprogrammed to a totipotent state. Although blastocysts can be generated efficiently through SCNT, the full-term development of SCNT embryos is impaired mostly due to placental defects. In this review, we examine the early cell fate decisions in fertilized embryos and compare them to observations in SCNT-derived embryos, in order to understand if these processes are affected by SCNT and could be responsible for the low success of reproductive cloning.

Comparative analysis of single-cell transcriptomics in human and Zebrafish oocytes.

BACKGROUND: Zebrafish is a popular model organism, which is widely used in developmental biology research. Despite its general use, the direct comparison of the zebrafish and human oocyte transcriptomes has not been well studied. It is significant to see if the similarity observed between the two organisms at the gene sequence level is also observed at the expression level in key cell types such as the oocyte. RESULTS: We performed single-cell RNA-seq of the zebrafish oocyte and compared it with two studies that have performed single-cell RNA-seq of the human oocyte. We carried out a comparative analysis of genes expressed in the oocyte and genes highly expressed in the oocyte across the three studies. Overall, we found high consistency between the human studies and high concordance in expression for the orthologous genes in the two organisms. According to the Ensembl database, about 60% of the human protein coding genes are orthologous to the zebrafish genes. Our results showed that a higher percentage of the genes that are highly expressed in both organisms show orthology compared to the lower expressed genes. Systems biology analysis of the genes highly expressed in the three studies showed significant overlap of the enriched pathways and GO terms. Moreover, orthologous genes that are commonly overexpressed in both organisms were involved in biological mechanisms that are functionally essential to the oocyte. CONCLUSIONS: Orthologous genes are concurrently highly expressed in the oocytes of the two organisms and these genes belong to similar functional categories. Our results provide evidence that zebrafish could serve as a valid model organism to study the oocyte with direct implications in human.

A 13-plex of tetra- and penta-STRs to identify zebrafish.

The zebrafish species Danio rerio has become one of the major vertebrate model organisms used in biomedical research. However, there are aspects of the model that need to be improved. One of these is the ability to identify individual fish and fish lines by DNA profiling. Although many dinucleotide short tandem repeat (diSTR) markers are available for this and similar purposes, they have certain disadvantages such as an excessive polymerase slippage ("stutter") that causes difficulties in automated genotyping and cross-laboratory comparisons. Here we report on the development of a 13-plex of tetranucleotide and pentanucleotide STRs (tetraSTRs and pentaSTRs, respectively) that have low stutter. The system uses an inexpensive universal primer labelling system, which can easily be converted to a direct labeling system if desired. This 13-plex was examined in three zebrafish lines (NHGRI-1, kca33Tg, and kca66Tg, originally obtained from ZIRC). The average observed heterozygosity (Ho) and expected heterozygosity (He) in these highly inbred lines were 0.291 and 0.359, respectively, which is very similar to what has been found with diSTRs. The probability of identity (PI) for all fish tested was 2.1 × 10-5 and the PI for siblings (PIsib) was 6.4 × 10-3, as calculated by the Genalex package. Ninety percent of the fish tested were correctly identified with their respective strains. It is also demonstrated that this panel can be used to confirm doubled-haploid cell lines. This multiplex should find multiple uses for improving the accuracy and reproducibility of studies using the zebrafish model.

Use of soluble sperm extract to improve cloning efficiency in zebrafish.

During somatic cell nuclear transfer (SCNT), egg activation is required to initiate embryonic development. In zebrafish cloning, the reconstructed egg is activated by exposing it to hypotonic water. Egg activation using water-only is not capable of activating the same intracellular calcium release as fertilization which is required for proper embryonic development. Here we test whether the use of soluble sperm extract (SSE) can properly modulate the activation of reconstructed eggs during SCNT. We microinjected SSE from genomic-inactivated zebrafish sperm into unfertilized eggs and reconstructed eggs right after somatic cell nuclear transfer. We also evaluated the most effective approach for SSE microinjection. Microinjection of SSE (with 0.68 mg/ml of protein concentration) into non-activated eggs through the micropyle induced parthenogenetic development beyond the blastula stage, whereas all water-only activated eggs failed to enter the cleavage period. Microinjection of SSE at 1 mg/ml of protein concentration into non-activated reconstructed egg improved the developmental rate of cloned embryos in comparison to non-injected control clones. The cumulative survival time of cloned embryos injected with SSE was significantly longer than reconstructed eggs activated following sham injection (P<0.01). No significant difference was found among controls (P=0.32). SSE benefits both parthenogenesis and the survival cloned embryos which have never been reported in zebrafish. Further work is necessary to define the functional component(s) of SSE as well as the physiological pathway, to understand its principle of action and advance the utilization of SSE in cloning.

Optimized Protocol of Zebrafish Somatic Cell Nuclear Transfer (SCNT).

Zebrafish (Danio rerio) is an established animal model to study developmental biology as well as a wide array of human diseases. Here we describe a protocol for somatic cell nuclear transfer (SCNT). This protocol can be used to introduce genetic modifications in zebrafish and for the study of cell plasticity.

Somatic Cell Reprogramming Informed by the Oocyte.

The successful production of animals and embryonic stem cells using somatic cell nuclear transfer (SCNT) has demonstrated the unmatched nuclear reprogramming capacity of the oocyte and helped prove the degree of plasticity of differentiated cells. The introduction of transcription factors to generate induced pluripotent stem cells (iPSCs) displaced SCNT and, due to its ease of implementation, became the method of choice for cell reprogramming. Nonetheless, iPSC derivation remains inefficient and stochastic. This review article focuses on using the oocyte as a source of reprogramming factors, comparing the SCNT and iPSC mechanisms for remodeling chromatin and acquiring pluripotency.

Custom-Made Oocytes to Clone Non-human Primates.

In this issue of Cell, Liu et al. (2018) report the birth of two healthy cloned macaque monkeys using fetal fibroblasts. By artificially enhancing the arsenal of epigenetic modifiers in the oocyte, the authors overcome the earliest roadblocks that take place during somatic cell nuclear transfer (SCNT).

Conserved Role of bFGF and a Divergent Role of LIF for Pluripotency Maintenance and Survival in Canine Pluripotent Stem Cells.

Dogs have been widely used as a preclinical model for human disease. With the successful generation of canine induced pluripotent stem cells (ciPSCs), the biomedical community has a unique opportunity to study therapeutic interventions using autologous stem cells that can benefit dogs and humans. Unlike mice and human pluripotent cells, which are leukemia inhibitory factor (LIF)- and basic fibroblast growth factor (bFGF)-dependent, respectively, dog iPSCs require both growth factors simultaneously. In an effort to elucidate the role of each factor in the control of ciPSC self-renewal, we performed a series of experiments aiming at understanding the signaling pathways activated by them. We found that bFGF regulates pluripotency by indirectly activating the SMAD2/3 pathway in the presence of feeder cells, exclusively targeting NANOG expression, and inhibiting spontaneous differentiation toward ectoderm and mesoderm. LIF activates the JAK-STAT3 pathway but does not function in the typical manner described in mouse naïve embryonic stem cells. These results show that a unique mechanism for maintenance of pluripotency is present in ciPSC. These findings should be taken into account when establishing stem cell differentiation protocols and may provide more insight into pluripotency regulation in species other than mice and humans.

Functional characterization of CDX2 during bovine preimplantation development in vitro.

Placental defects are common in bovine embryos produced using assisted reproductive techniques. A proper understanding of the events leading to inner cell mass (ICM) and trophectoderm (TE) specification could help identify the origins of such developmental failures. We focused on caudal-type homeobox transcription factor 2 (CDX2) since it has a specific role during TE differentiation in mouse embryos. Of all the preimplantation stages analyzed, CDX2 protein was present only at the blastocyst stage. To further understand the roles of CDX2 during bovine development, we depleted CDX2 mRNA; despite a significant loss of detectable protein, embryos were able to form blastocysts at the same rate as controls. Embryos lacking CDX2 did not show abnormalities in the number of TE, ICM, or total cells in the blastocyst. Expression of the developmentally important genes SOX2, POU5F1, and NANOG, or TE markers such as IFN-T and KRT18 were not affected by the reduction in CDX2 levels, nor was the localization of SOX2 and POU5F1 protein. Using a functional barrier assay, we observed that the TE epithelial layer of embryos lacking CDX2 had lost its integrity. Our results thus indicate that CDX2 is not required for TE formation during bovine development; nevertheless, it is necessary for maintaining TE integrity.

Cell reprogramming. Histone chaperone ASF1A is required for maintenance of pluripotency and cellular reprogramming.

Unfertilized oocytes have the intrinsic capacity to remodel sperm and the nuclei of somatic cells. The discoveries that cells can change their phenotype from differentiated to embryonic state using oocytes or specific transcription factors have been recognized as two major breakthroughs in the biomedical field. Here, we show that ASF1A, a histone-remodeling chaperone specifically enriched in the metaphase II human oocyte, is necessary for reprogramming of human adult dermal fibroblasts (hADFs) into undifferentiated induced pluripotent stem cell. We also show that overexpression of just ASF1A and OCT4 in hADFs exposed to the oocyte-specific paracrine growth factor GDF9 can reprogram hADFs into pluripotent cells. Our Report underscores the importance of studying the unfertilized MII oocyte as a means to understand the molecular pathways governing somatic cell reprogramming.

Human somatic cell nuclear transfer is alive and well.

In this issue, Chung et al. (2014) generate human embryonic stem cells by fusing an adult somatic cell to a previously enucleated human oocyte, in agreement with recent reports by the Mitalipov and Egli groups. We can now safely say that human somatic cell nuclear transfer is alive and well.

Functional characterization of SOX2 in bovine preimplantation embryos.

To date, efforts to establish pluripotent embryonic stem cells from bovine embryos have failed. The lack of reliable pluripotency markers is an important drawback when attempting to derive these cells. This study aimed to identify genes upregulated in the inner cell mass (ICM) of bovine blastocysts, and we selected SOX2 for further characterization. Spatial and temporal localization of the SOX2 protein revealed that its expression starts at the 16-cell stage and then becomes restricted to the ICMs of blastocysts. To study the role of SOX2 during the early development of bovine embryos, we designed siRNA to target SOX2. We began by injecting this siRNA into zygotes; the rate at which blastocysts developed declined compared to noninjected or scramble-injected controls. When only one blastomere of a two-cell embryo was injected with SOX2 siRNA, we observed development rates similar to those of controls. Daughter cells of the injected blastomere were tracked by TRITC fluorescence and found to contribute to the ICM, as select cells also lacked SOX2. Gene expression analysis revealed a decrease in SOX2 and NANOG gene expression in siRNA-injected embryos, but OCT4 expression remained unchanged. We conclude that SOX2 localizes exclusively in the ICM of bovine blastocysts, and its downregulation negatively impacts preimplantation development; however, it is still unclear as to why downregulation of SOX2 in one cell of a two-cell embryo does not affect the composition of the ICM.

Caudalized human iPSC-derived neural progenitor cells produce neurons and glia but fail to restore function in an early chronic spinal cord injury model.

Neural progenitor cells (NPCs) have shown modest potential and some side effects (e.g. allodynia) for treatment of spinal cord injury (SCI). In only a few cases, however, have NPCs shown promise at the chronic stage. Given the 1.275 million people living with chronic paralysis, there is a significant need to rigorously evaluate the cell types and methods for safe and efficacious treatment of this devastating condition. For the first time, we examined the pre-clinical potential of NPCs derived from human induced pluripotent stem cells (hiPSCs) to repair chronic SCI. hiPSCs were differentiated into region-specific (i.e. caudal) NPCs, then transplanted into a new, clinically relevant model of early chronic cervical SCI. We established the conditions for successful transplantation of caudalized hiPSC-NPCs and demonstrate their remarkable ability to integrate and produce multiple neural lineages in the early chronic injury environment. In contrast to prior reports in acute and sub-acute injury models, survival and integration of hiPSC-derived neural cells in the early chronic cervical model did not lead to significant improvement in forelimb function or induce allodynia. These data indicate that while hiPSCs show promise, future work needs to focus on the specific hiPSC-derivatives or co-therapies that will restore function in the early chronic injury setting.

Defining the diversity of phenotypic respecification using multiple cell lines and reprogramming regimens.

To better understand the basis of variation in cellular reprogramming, we performed experiments with two primary objectives: first, to determine the degree of difference, if any, in reprogramming efficiency among cells lines of a similar type after accounting for technical variables, and second, to compare the efficiency of conversion of multiple similar cell lines to two separate reprogramming regimens-induced neurons and induced skeletal muscle. Using two reprogramming regimens, it could be determined whether converted cells are likely derived from a distinct subpopulation that is generally susceptible to reprogramming or are derived from cells with an independent capacity for respecification to a given phenotype. Our results indicated that when technical components of the reprogramming regimen were accounted for, reprogramming efficiency was reproducible within a given primary fibroblast line but varied dramatically between lines. The disparity in reprogramming efficiency between lines was of sufficient magnitude to account for some discrepancies in published results. We also found that the efficiency of conversion to one phenotype was not predictive of reprogramming to the alternate phenotype, suggesting that the capacity for reprogramming does not arise from a specific subpopulation with a generally "weak grip" on cellular identity. Our findings suggest that parallel testing of multiple cell lines from several sources may be needed to accurately assess the efficiency of direct reprogramming procedures, and that testing a larger number of fibroblast lines--even lines with similar origins--is likely the most direct means of improving reprogramming efficiency.

Effects of donor fibroblasts expressing OCT4 on bovine embryos generated by somatic cell nuclear transfer.

The production of healthy, live, cloned animals by somatic cell nuclear transfer (SCNT) has been hampered by low efficiencies. Significant epigenetic changes must take place to ensure proper chromatin remodeling in SCNT. We hypothesized that exogenous expression of OCT4 in donor fibroblasts prior to its fusion with enucleated oocytes would facilitate SCNT reprogramming. We infected bovine adult fibroblasts with retroviral vectors containing yellow fluorescent protein (YFP) only, or the OCT4 gene fused to YFP (YO). We found that development to the blastocyst stage was not different between NT-YFP and NT-YO groups. NT-YFP embryos had the fewest trophoblast cells, measured by numbers of CDX2-positive cells. Fibroblasts expressing OCT4 had reduced levels of histone 3 lysine 9 or 27 trimethylation (H3K9me3 and H3K27me3, respectively). NT-YO blastocysts displayed higher H3K9me3 levels than IVF and NT-YFP embryos; however, they did not have different H3K27me3 levels. Levels of XIST mRNA expression in NT-YO and NT-YF were higher when compared to in vitro-fertilized blastocysts. We observed no differences in the expression of SOX2, NANOG, and CDX2. Although overexpression of OCT4 in donor cells increased H3K9me3 and did not reduce XIST gene expression, we show that a single transcription factor can affect the number of trophectoderm cells in bovine SCNT embryos.

Identification of a novel gene set in human cumulus cells predictive of an oocyte's pregnancy potential.

OBJECTIVE: To identify a gene expression signature in human cumulus cells (CCs) predictive of pregnancy outcome across multiple clinics, taking into account the clinic and patient variations inherent in IVF practice. DESIGN: Retrospective analysis of single human cumulus-oocyte complexes with the use of a combined microarray and quantitative reverse-transcription polymerase chain reaction (qRT-PCR) approach. SETTING: Multiple private IVF clinics. PATIENT(S): Fifty-eight patients. Samples from 55 patients underwent qRT-PCR analysis, and samples from 27 patients resulted in live birth. INTERVENTION(S): Gene expression analysis for correlation with pregnancy outcome on individual human CCs collected immediately after oocyte retrieval. Pregnancy prediction analysis used leave-one-out cross-validation with weighted voting. MAIN OUTCOME MEASURE(S): Combinatorial expression of 12 genes in 101 samples from 58 patients. RESULT(S): We found a set of 12 genes predictive of pregnancy outcome based on their expression levels in CCs. This pregnancy prediction model had an accuracy of 78%, a sensitivity of 72%, a specificity of 84%, a positive predictive value of 81%, and a negative predictive value of 76%. Receiver operating characteristic analysis found an area under the curve of 0.763 ± 0.079, significantly greater than 0.5 (random chance prediction). CONCLUSION(S): Gene expression analysis in human CCs should be considered in identifying oocytes with a high potential to lead to pregnancy in IVF-ET.

Conservation of avian germplasm by xenogeneic transplantation of spermatogonia from sexually mature donors.

Approximately 12.5% of all 9,920 extant bird species in the world are threatened with extinction, and yet conservation efforts through natural breeding of captive species continue to encounter difficulties. However, sperm cryopreservation and artificial insemination offer potential benefits over natural breeding, but their applicability is still limited in nondomestic species. In this study, we aimed to exploit the potential of germ cell xenotransplantation as an alternative tool for preserving germplasm of endangered birds. The study was designed to investigate whether transfer of either spermatogonia-enriched cell fraction (SEF) or crude testicular cell fraction (CTF) from adult Japanese quails (as a model for wild species) would result in recolonization of gamma-irradiated gonads of adult recipient chickens. One month after transplantation, 75% of recipients injected with SEF and 25% of recipients injected with CTF resumed spermatogenesis. However, it took more than 3 months for 33% of the negative controls to resume marginal production of sperm. Some SEF recipients produced more spermatozoa bearing head morphology compared with donor controls. DNA analysis using quail-specific primers did not detect donor's DNA in these recipients' semen. However, 6 months after xenotransplantation, presence of quail germ cells was demonstrated by polymerase chain reaction and by immunohistochemistry in 1 rooster injected with SEF. These findings indicate that spermatogonia from adult quails were capable of colonizing immunocompetent testis of adult chickens but failed to produce sufficient sperm. Despite this limitation, the present approach represents a potential conservation tool that may be used to rescue germ cells of endangered adult male birds.