Deletion of Peg10, an imprinted gene acquired from a retrotransposon, causes early embryonic lethality.

By comparing mammalian genomes, we and others have identified actively transcribed Ty3/gypsy retrotransposon-derived genes with highly conserved DNA sequences and insertion sites. To elucidate the functions of evolutionarily conserved retrotransposon-derived genes in mammalian development, we produced mice that lack one of these genes, Peg10 (paternally expressed 10), which is a paternally expressed imprinted gene on mouse proximal chromosome 6. The Peg10 knockout mice showed early embryonic lethality owing to defects in the placenta. This indicates that Peg10 is critical for mouse parthenogenetic development and provides the first direct evidence of an essential role of an evolutionarily conserved retrotransposon-derived gene in mammalian development.

Dioxin receptor is a ligand-dependent E3 ubiquitin ligase.

Fat-soluble ligands, including sex steroid hormones and environmental toxins, activate ligand-dependent DNA-sequence-specific transcriptional factors that transduce signals through target-gene-selective transcriptional regulation. However, the mechanisms of cellular perception of fat-soluble ligand signals through other target-selective systems remain unclear. The ubiquitin-proteasome system regulates selective protein degradation, in which the E3 ubiquitin ligases determine target specificity. Here we characterize a fat-soluble ligand-dependent ubiquitin ligase complex in human cell lines, in which dioxin receptor (AhR) is integrated as a component of a novel cullin 4B ubiquitin ligase complex, CUL4B(AhR). Complex assembly and ubiquitin ligase activity of CUL4B(AhR) in vitro and in vivo are dependent on the AhR ligand. In the CUL4B(AhR) complex, ligand-activated AhR acts as a substrate-specific adaptor component that targets sex steroid receptors for degradation. Thus, our findings uncover a function for AhR as an atypical component of the ubiquitin ligase complex and demonstrate a non-genomic signalling pathway in which fat-soluble ligands regulate target-protein-selective degradation through a ubiquitin ligase complex.

Correction: Visualizing morphological structures of rice grains in precooked products using synchrotron radiation X-ray phase-contrast computed tomography.

Correction for 'Visualizing morphological structures of rice grains in precooked products using synchrotron radiation X-ray phase-contrast computed tomography' by Hiromi Miki et al., Food Funct., 2023, 14, 87-93, https://doi.org/10.1039/D2FO02714C.

Visualizing morphological structures of rice grains in precooked products using synchrotron radiation X-ray phase-contrast computed tomography.

Rice is a staple food eaten by more than half of the world's population. In recent years, various types of precooked rice products have become commercially available as more and more people, including the elderly, do not have time to prepare meals or are coping with eating disorders. To address this situation, analysis of the internal structure of rice is important to understand the phenomena that occur during cooking rice grains and to develop rice products for specific purpose with desired physical properties. Although the internal structure of food has been observed by many methods, it is difficult to image the internal structure of rice porridge or rice grains with sufficient spatial resolution in a nondestructive manner. In this study, we applied X-ray interferometer-based phase-contrast computed tomography for the nondestructive observation of precooked rice products. For comparison, X-ray absorption-contrast images were also observed. The samples consisted of packaged aseptic cooked rice, precooked rice porridge for the general public, and a texture-modified rice product for people with dysphagia. In the phase-contrast two-dimensional (2D) tomographic images, the central lines of the cooked rice grains were successfully observed in all samples. The changes in the peripheral regions and internal hollows of the cooked rice grains were also clearly observed. Meanwhile, rice grains were hardly discernible in the X-ray absorption images. These results indicate that X-ray interferometer-based phase-contrast imaging is a promising tool for analyzing the morphology and internal structure of cooked rice grains in various prepacked products such as rice porridge and texture-modified rice.

Observation of processed rice using synchrotron radiation X-ray phase-contrast imaging.

As a result of increasing elderly population, the number of people with dysphagia and difficulty eating is expected to increase as well. It is not always feasible to cook meals to the proper texture for elderly individuals and people with dysphagia living at home. Accordingly, there is high market demand for ready-made texture-modified foods for home consumption. Many methods have been widely used to analyze the structural properties of foods. However, it is difficult to observe the structure of foods in a nondestructive manner with the conventional analysis methods. To observe food as it is without destroying it, we adopted X-ray phase-contrast computed tomography (CT) using a crystal interferometer in this study. The samples were commercially available precooked rice porridge and two texture-modified rice products satisfying the Universal Design Food criteria. A texture profile analysis was also performed to compare the phase-contrast images and the food properties. In the phase-contrast images, both the ingredients and cohesion in the samples were successfully observed. It was also found that the texture-modified rice products were easier to eat and swallow than the rice porridge. These results show that X-ray phase-contrast CT using a crystal interferometer is a promising method for nondestructive observation of food structures and is expected to open up new horizons in food science.

Efficient production of androgenetic embryos by round spermatid injection.

Mammalian androgenetic embryos can be produced by pronuclear exchange of fertilized oocytes or by dispermic in vitro fertilization of enucleated oocytes. Here, we report a new technique for producing mouse androgenetic embryos by injection of two round spermatid nuclei into oocytes, followed by female chromosome removal. We found that injection of round spermatids resulted in high rates of oocyte survival (88%). Androgenetic embryos thus produced developed into mid-gestation fetuses at various rates, depending on the mouse strain used. All the fetuses examined maintained paternally specific genomic imprinting memories. This technique also enabled us to produce complete heterozygous F1 embryos by injecting two spermatids from different strains. The best rate of fetal survival (12% per embryos transferred) was obtained with C57BL/6 x DBA/2 androgenetic embryos. We also generated embryonic stem cell lines efficiently with the genotype of Mus musculus domesticus x M. m. molossinus. Thus, injection of two round spermatid nuclei followed by maternal enucleation is an effective alternative method of producing androgenetic embryos that consistently develop into blastocysts and mid-gestation fetuses.

Effects of Akt signaling on nuclear reprogramming.

Reprogramming of the epigenetic state from differentiated to pluripotent cells can be attained by cell fusion of differentiated somatic cells with embryonic stem (ES) cells or transfer of the nucleus of a differentiated cell into an enucleated oocyte. Activation of Akt signaling is sufficient to maintain pluripotency of ES cells and promotes derivation of embryonic germ (EG) cells from primordial germ cells (PGCs). Here we analyzed the effects of Akt signaling on somatic cell nuclear reprogramming after cell fusion and nuclear transfer. We found that forced activation of Akt signaling stimulated reprogramming after cell fusion of ES cells with thymocytes or mouse embryonic fibroblasts. These hybrid cells showed ES cell characteristics, including in vitro and in vivo differentiation capacity. In contrast, Akt signaling significantly reduced the efficiency of reprogramming with nuclear transfer. Our results demonstrate that Akt signaling plays important roles on the nuclear reprogramming of somatic cells.

Centromeric DNA hypomethylation as an epigenetic signature discriminates between germ and somatic cell lineages.

Germ cells have unique features strikingly distinguishable from somatic cells. The functional divergence between these two cell lineages has been postulated to result from epigenetic mechanisms. Here we show that the chromosomal centric and pericentric (C/P) regions in male and female germline cells are specifically DNA-hypomethylated, despite the hypermethylation status in somatic cells. In multipotent germline stem cells, the C/P region was initially hypomethylated and then shifted to the hypermethylation status during differentiation into somatic lineage in vitro. Moreover, the somatic-type hypermethylation pattern was maintained in the somatic cell-derived nuclear transfer embryos throughout preimplantation development. These results imply that the identity of germ cell lineage may be warranted by the hypomethylation status of the C/P region as an epigenetic signature.

Production of knockout mice by gene targeting in multipotent germline stem cells.

Spermatogonial stem cells can convert into embryonic stem (ES) cell-like multipotent germline stem (mGS) cells in vitro and produce germline chimeras by blastocyst microinjection. Although homologous recombination was previously demonstrated in mGS cells, spermatogenesis was not found in chimeras, suggesting that they are not competent for germline modification. Here we conducted detailed analysis of chimeric animals to determine whether mGS cells retain germline potential after genetic manipulation. Spermatozoa that were deficient in the occludin gene could be recovered from animals that were chimeric with mGS cells that underwent homologous recombination. The phenotypes of the occludin knockout (KO) mice were similar to those reported for KO mice produced using ES cells, and the animals showed growth retardation, gastritis and male infertility. Furthermore, we found that heterozygous mGS cells acquire two copies of the G418-resistant genes and become homozygous for the targeted allele by culturing at high concentrations of G418. Cytogenetic analysis showed that the aneuploid mGS cells observed during genetic manipulation were trisomic for chromosome 8 or 11, which is a common chromosomal abnormality in ES cells. Thus, mGS cells can be used to produce KO animals, and this novel method of germline manipulation may prove useful in diverse mammalian species.

Generation of cloned mice by direct nuclear transfer from natural killer T cells.

Cloning mammals by nuclear transfer (NT) remains inefficient. One fundamental question is whether clones have really been derived from differentiated cells rather than from rare stem cells present in donor-cell samples. To date, cells, such as mature lymphocytes, with genetic differentiation markers have been cloned to generate mice only via a two-step NT involving embryonic stem (ES) cell generation and tetraploid complementation [1, 2 and 3]. Here, we show that the genome of a unique T-cell population, natural killer T (NKT) cells, can be fully reprogrammed by a single-step NT. The pups and their placentas possessed the rearranged TCR loci specific for NKT cells. The NKT-cell-cloned embryos had a high developmental potential in vitro: Most (71%) developed to the morula/blastocyst stage, in marked contrast to embryos from peripheral blood T cells (12%; p < 1 x 10(-25)). Furthermore, ES cell lines were efficiently established from these NKT-cell blastocysts. These findings clearly indicate a high level of plasticity in the NKT-cell genome. Thus, differentiation of the genome is not always a barrier to NT cloning for either reproductive or therapeutic purposes, so we can now postulate that at least some mammals cloned to date have indeed been derived from differentiated donor cells.

Stable embryonic stem cell lines in rabbits: potential small animal models for human research.

Although embryonic stem (ES) cell lines derived from mice and primates are used extensively, the development of such lines from other mammals is extremely difficult because of their rapid decline in proliferation potential and pluripotency after several passages. This study describes the establishment of rabbit ES cell lines with indefinite proliferation potential. It was found that the feeder cell density determines the fate of rabbit ES cells, and that maximum proliferation potential was obtained when they were cultured on a feeder cell density of one-sixth of the density at confluency. Higher and lower densities of feeder cells induced ES cell differentiation or division arrest. Under optimized conditions, rabbit ES cells were passaged 50 times, after which they still possessed high telomerase activity. This culture system enabled efficient gene transduction and clonal expansion from single cells. During culture, rabbit ES cells exhibited flattened monolayer cell colonies, as reported for monkey and human ES cells, and expressed pluripotency markers. Embryoid bodies and teratomas formed readily in vitro and in vivo respectively. These ES cell lines can be safely cryopreserved for later use. Thus, rabbit ES cells can be added to the list of stable mammalian ES cells, enabling the rabbit to be used as a small animal model for the study of human cell transplantation therapy.

Production of functional spermatids from mouse germline stem cells in ectopically reconstituted seminiferous tubules.

Testicular germ cell transplantation into the seminiferous tubules is at present the only way to induce spermatogenesis from a given source of spermatogonial stem cells. Here we show an alternative method that harnesses the self-organizing ability of testicular somatic cells. The testicular cells of embryonic or neonatal mice or rats and of newborn pigs were dissociated into single cells. Each of them reorganized into a tubular structure following implantation into the subcutis of immunodeficient mice. When mouse germline stem (GS) cells derived from spermatogonial stem cells and expanded in culture were intermingled with testicular cells of rodents, they were integrated in the reconstituted tubules and differentiated beyond meiosis into spermatids. Normal offspring were produced by the microinjection of those spermatids into oocytes. This method could be applicable to various mammalian species and useful for producing functional gametes from GS cells in a xenoectopic environment.

Microinsemination and nuclear transfer using male germ cells.

Microinsemination has been widely used in basic reproductive research and in human-assisted reproductive technology for treating infertility. Historically, microinsemination in mammals started with research on the golden hamster; since then, it has provided invaluable information on the mechanisms of mammalian fertilization. Thanks to advances in animal genetic engineering and germ-cell technologies, microinsemination techniques are now used extensively to identify the biological significance of genes of interest or to confirm the genetic normality of gametes produced by experimental manipulations in vitro. Fortunately, in mice, high rates of embryo development to offspring can be obtained so long as postmeiotic spermatogenic cells are used as male gametes-that is, round spermatids, elongated spermatids, and spermatozoa. For some other mammalian species, using immature spermatogenic cells significantly decreases the efficiency of microinsemination. Physically unstable chromatin and low oocyte-activating capacity are the major causes of fertilization failure. The youngest male germ cells, including primordial germ cells and gonocytes, can be used in the construction of diploid embryos by nuclear-transfer cloning. The cloned embryos obtained in this way provide invaluable information on the erasure and reestablishment of genomic imprinting in germ cells.

Improved postimplantation development of rabbit nuclear transfer embryos by activation with inositol 1,4,5-trisphosphate.

Cloned rabbit embryos are characterized by their extremely poor postimplantation development, despite their high survivability until the blastocyst stage in vitro. This study examined whether the developmental failure of cloned rabbit embryos in vivo can be overcome by technical improvements to the activation protocol. Freshly collected cumulus cells were transferred into enucleated oocytes by intracytoplasmic injection. One to two hours later, the oocytes were activated by electroporation with Ca(2+) or inositol 1,4,5-trisphosphate (IP3), which is known to induce repeated rises in intracellular Ca(2+), as in normal fertilization. After transfer of embryos at the two- to four-cell stages, well-defined implantation sites with remnant fetal tissue were observed at term (day 28) only in the IP3-stimulation groups (0.9% and 5.8% per transferred embryo for single and triple stimulation groups, respectively). When some recipients in the same group were examined at days 16-20, a viable cloned fetus (day 19) with normal organogenesis was obtained. These findings clearly demonstrate that the oocyte activation protocol using IP3 enhances the postimplantation development of nuclear-transferred rabbit embryos.

The Arf GAP SMAP2 is necessary for organized vesicle budding from the trans-Golgi network and subsequent acrosome formation in spermiogenesis.

The trans-Golgi network (TGN) functions as a hub organelle in the exocytosis of clathrin-coated membrane vesicles, and SMAP2 is an Arf GTPase-activating protein that binds to both clathrin and the clathrin assembly protein (CALM). In the present study, SMAP2 is detected on the TGN in the pachytene spermatocyte to the round spermatid stages of spermatogenesis. Gene targeting reveals that SMAP2-deficient male mice are healthy and survive to adulthood but are infertile and exhibit globozoospermia. In SMAP2-deficient spermatids, the diameter of proacrosomal vesicles budding from TGN increases, TGN structures are distorted, acrosome formation is severely impaired, and reorganization of the nucleus does not proceed properly. CALM functions to regulate vesicle sizes, and this study shows that CALM is not recruited to the TGN in the absence of SMAP2. Furthermore, syntaxin2, a component of the soluble N-ethylmaleimide-sensitive factor attachment protein receptor (SNARE) complex, is not properly concentrated at the site of acrosome formation. Thus this study reveals a link between SMAP2 and CALM/syntaxin2 in clathrin-coated vesicle formation from the TGN and subsequent acrosome formation. SMAP2-deficient mice provide a model for globozoospermia in humans.

Genetic influences in mouse spermatogonial stem cell self-renewal.

Spermatogonial stem cells (SSCs) are slowly dividing cells that undergo self-renewal division to support spermatogenesis. Although the effects of genetic background in stem cell self-renewal have been well studied in hematopoietic stem cells, little is known about its effect on stem cells in other self-renewing tissues, including SSCs. To examine whether genetic factors are involved in regulation of SSC self-renewal, we first studied spermatogenesis in different inbred mouse strains (C57BL/6, DBA/2, AKR, BALB/C and C3H) after chemical damage caused by busulfan. Spermatogenesis in the DBA/2 and AKR strains was relatively resistant to busulfan treatment, whereas spermatogenesis was diminished in C57BL/6 mice and nearly ablated in C3H and BALB/C mice. Serial germ cell transplantation experiments provided functional evidence that SSCs with the DBA/2 background expanded more rapidly than those with the B6 background. Finally, we also employed the Germline Stem (GS) cell culture technique to examine the self-renewal activity in vitro. Although genetic manipulation of GS cells has been limited to those from the DBA/2 background, we produced transgenic offspring of the C3H background by electroporation of GS cells with a plasmid vector. Our results underscore the importance of genetic factors in SSC self-renewal. Furthermore, application of genetic modification techniques to GS cells with non-DBA/2 backgrounds extends the potential of a SSC-based approach in male germline modification.

Heritable imprinting defect caused by epigenetic abnormalities in mouse spermatogonial stem cells.

Male germ cells undergo dynamic epigenetic reprogramming during fetal development, eventually establishing spermatogonial stem cells (SSCs) that can convert into pluripotent stem cells. However, little is known about the developmental potential of fetal germ cells and how they mature into SSCs. We developed a culture system for fetal germ cells that proliferate for long periods of time. Male germ cells from embryos 12.5-18.5 days postcoitum could expand by glial cell line-derived neurotrophic factor, a self-renewal factor for SSCs. These cells did not form teratomas, but repopulated seminiferous tubules and produced spermatogenesis, exhibiting spermatogonia potential. However, the offspring from cultured cells showed growth abnormalities and were defective in genomic imprinting. The imprinting defect persisted in both the male and female germlines for at least four generations. Moreover, germ cells in the offspring showed abnormal histone modifications and DNA methylation patterns. These results indicate that fetal germ cells have a limited ability to become pluripotent cells and lose the ability to undergo epigenetic reprogramming by in vitro culture.

Large-scale production of growing oocytes in vitro from neonatal mouse ovaries.

Although fetal or neonatal mammalian ovaries contain many non-growing oocytes within primordial follicles, most degenerate and only a few contribute to the oocyte pool in the mature ovary. Here, we report a follicle-free culture system that allows a large number of these arrested oocytes to enter the growth phase in vitro. As many as 800 oocytes from a newborn mouse, corresponding to more than 10(4) oocytes in large animals, continued to develop, formed a zona pellucida, and were able to fuse with spermatozoa. Some oocytes reached the size of those in normal antral follicles and entered metaphase I, indicating the completion of the growth phase. The key to success was the sequential provision of essential nutrients and growth factors to the oocytes, while preventing the apoptosis that normally occurs in the majority of growing oocytes in vivo. Importantly, maternal genomic imprinting, which is necessary for normal embryonic development, was imposed correctly on their genomes autonomously. Thus, arrested primordial oocytes can be rescued effectively in vitro and can undergo the morphological and genomic modifications necessary for fertilization and subsequent embryonic development. This culture system may provide a significant impetus to the development of new techniques for the efficient production of oocytes from fetal or neonatal ovaries, for research, clinical, and zoological purposes.

Pluripotency of a single spermatogonial stem cell in mice.

Although pluripotent stem cells were recently discovered in postnatal testis, attempts to analyze their developmental potential have led to conflicting claims that spermatogonial stem cells are pluripotent or that they lose spermatogenic potential after conversion into pluripotent stem cells. To examine this issue, we analyzed the developmental fate of a single spermatogonial stem cell that appeared during transfection experiments. After transfection of a neomycin-resistance gene into germline stem cells, we obtained an embryonic stem-like, multipotent germline stem cell line. Southern blot analysis revealed that the germline stem and multipotent germline stem clones have the same transgene integration pattern, demonstrating their identical origin. The two lines, however, have different DNA methylation patterns. The multipotent germline stem cells formed chimeras after blastocyst injection but did not produce sperm after germ cell transplantation, whereas the germline stem cells could produce only spermatozoa and did not differentiate into somatic cells. Interestingly, the germline stem cells expressed several transcription factors (Pou5f1, Sox2, Myc, and Klf4) required for reprogramming fibroblasts into a pluripotent state, suggesting that they are potentially pluripotent. Thus, our study provides evidence that a single spermatogonial stem cell can acquire pluripotentiality but that conversion into a pluripotent cell type is accompanied by loss of spermatogenic potential.

Adenovirus-mediated gene delivery into mouse spermatogonial stem cells.

Spermatogonial stem cells represent a self-renewing population of spermatogonia, and continuous division of these cells supports spermatogenesis throughout the life of adult male animals. Previous attempts to introduce adenovirus vectors into spermatogenic cells, including spermatogonial stem cells, have failed to yield evidence of infection, suggesting that male germ cells may be resistant to adenovirus infection. In this study we show the feasibility of transducing spermatogonial stem cells by adenovirus vectors. When testis cells from ROSA26 Cre reporter mice were incubated in vitro with a Cre-expressing adenovirus vector, Cre-mediated recombination occurred at an efficiency of 49-76%, and the infected spermatogonial stem cells could reinitiate spermatogenesis after transplantation into seminiferous tubules of infertile recipient testes. No evidence of germ-line integration of adenovirus vector could be found in offspring from infected stem cells that underwent Cre-mediated recombination, which suggests that the adenovirus vector infected the cells but did not stably integrate into the germ line. Nevertheless, these results suggest that adenovirus may inadvertently integrate into the patient's germ line and indicate that there is no barrier to adenovirus infection in spermatogonial stem cells.