Nobuhiro Shimozawa

Cloned Mice from Fetal Fibroblast Cells Arrested at Metaphase by a Serial Nuclear Transfer

Abstract Cloning using G0-arrested somatic cells has led to the suggestion that this stage of the cell cycle is necessary for the success of cloning. In this study we report that cloned mice can be generated from fetal fibroblasts arrested at metaphase of the cell cycle. The procedure involves fusing a metaphase-arrested fetal fibroblast to an enucleated oocyte. After parthenogenetic activation a polar body and single diploid pronucleus were formed. Some of these were allowed to develop to the blastocyst stage, while others were enucleated and the nucleus was transferred to an enucleated fertilized 1-cell embryo. After the single transfer technique, 2 out of 164 developed to late stages of gestation were dead with gross abnormalities. However, after the serial nuclear transfer, 5 out of 272 embryos were recovered live at Day 19.5, and 2 of these went on to develop into apparently normal adults. All of the cloned embryos showed severe placental hypertrophy and defective differentiation of placental tissues. This study illustrates that reprogramming can occur after nuclear transfer at metaphase of the cell cycle.

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.

Transgene stability and features of rasH2 mice as an animal model for short‐term carcinogenicity testing

The transgenic mouse rasH2 line, in which the mouse carries the human c‐Ha‐ras gene under the control of its own enhancer and promoter, has been proposed as one of the alternative short‐term models for carcinogenicity testing. To apply this purpose, we have produced a genetically homogeneous population as C57BL/6JJic‐TgN(RASH2) (Tg‐rasH2) by continuous backcrossing. In this study, we examined the transgene stability between different generations and the detailed transgene architecture of the integrated human c‐Ha‐ras gene. Fluorescence in situ hybridization analysis showed that the integrated human c‐Ha‐ras gene was stably located on chromosome 15E3 in Tg‐rasH2 mice at generation number (N) 15 and 20. Southern and Northern blot analysis did not show any differences in the hybridized band pattern in each generation. Southern blot analyses showed that the Tg‐rasH2 mouse contained three copies of the human c‐Ha‐ras gene arrayed in a head‐to‐tail configuration. We also determined the nucleotide sequence of the transgene in the Tg‐rasH2 mouse at N20 and confirmed that the sequence of the coding region was perfectly matched with human c‐Ha‐ras cDNA. Cloning and sequencing of genome/transgene junctions revealed that integration of the microinjected human c‐Ha‐ras gene into mouse host genome resulted in a 1820‐bp deletion in the rasH2 line. The deleted sequence did not have any sequence homologies with known functional genes. We assumed that either the deletion or the transgene insertion, or both, would not cause insertional mutation. In short‐term carcinogenicity testing with a genetically engineered mouse model, confirmation of the transgene or modified gene stability at each generation is one of the important factors that affect the sensitivity to carcinogenic compounds in the same way as the genetic background, age and route of administration.

Diabetes Mellitus Accelerates Aβ Pathology in Brain Accompanied by Enhanced GAβ Generation in Nonhuman Primates

Growing evidence suggests that diabetes mellitus (DM) is one of the strongest risk factors for developing Alzheimer’s disease (AD). However, it remains unclear why DM accelerates AD pathology. In cynomolgus monkeys older than 25 years, senile plaques (SPs) are spontaneously and consistently observed in their brains, and neurofibrillary tangles are present at 32 years of age and older. In laboratory-housed monkeys, obesity is occasionally observed and frequently leads to development of type 2 DM. In the present study, we performed histopathological and biochemical analyses of brain tissue in cynomolgus monkeys with type 2 DM to clarify the relationship between DM and AD pathology. Here, we provide the evidence that DM accelerates Aβ pathology in vivo in nonhuman primates who had not undergone any genetic manipulation. In DM-affected monkey brains, SPs were observed in frontal and temporal lobe cortices, even in monkeys younger than 20 years. Biochemical analyses of brain revealed that the amount of GM1-ganglioside-bound Aβ (GAβ)—the endogenous seed for Aβ fibril formation in the brain—was clearly elevated in DM-affected monkeys. Furthermore, the level of Rab GTPases was also significantly increased in the brains of adult monkeys with DM, almost to the same levels as in aged monkeys. Intraneuronal accumulation of enlarged endosomes was also observed in DM-affected monkeys, suggesting that exacerbated endocytic disturbance may underlie the acceleration of Aβ pathology due to DM.

Protocol for the production of viable bimaternal mouse embryos

A reliable nuclear transfer method was first reported in 1983; it provided definite evidence that parthenogenetic embryos are lethal at early postimplantation in mammals. Subsequently, nuclear transfer has been extensively used as an important and versatile tool for investigating embryo and somatic-cell cloning and nucleo-cytoplasmic interactions. Further development of this technique has enabled the generation of bimaternal embryos containing two haploid sets of maternal genomes from female germ cells of different origins. By using a 2-d nuclear transfer system for oocyte reconstruction, viable mice can be produced solely from maternal genomes, without the participation of the paternal genome. This oocyte reconstruction system, as described in this protocol, could provide valuable guidelines for exploring the potential endowments of gametes and for conferring novel properties to them.

Characterization of a novel embryonic stem cell line from an ICSI-derived blastocyst in the African green monkey

Several cell types from the African green monkey (Cercopithecus aethiops), such as red blood cells, primary culture cells from kidney, and the Vero cell line, are valuable sources for biomedical research and testing. Embryonic stem (ES) cells that are established from blastocysts have pluripotency to differentiate into these and other types of cells. We examined an in vitro culture system of zygotes produced by ICSI in African green monkeys and attempted to establish ES cells. Culturing with and without a mouse embryonic fibroblast (MEF) cell monolayer resulted in the development of ICSI-derived zygotes to the blastocyst stage, while culturing with a buffalo rat liver cell monolayer yielded no development (3/14, 21.4% and 6/31, 19.4% vs 0/23, 0% respectively; P<0.05). One of the nine blastocysts, which had been one of the zygotes co-cultured with MEF cells, formed flat colonies consisting of cells with large nuclei, similar to other primate ES cell lines. The African green monkey ES (AgMES) cells expressed pluripotency markers, formed teratomas consisting of three embryonic germ layer tissues, and had a normal chromosome number. Furthermore, expression of the germ cell markers CD9 and DPPA3 (STELLA) was detected in the embryoid bodies, suggesting that AgMES cells might have the potential ability to differentiate into germ cells. The results suggested that MEF cells greatly affected the quality of the inner cell mass of the blastocysts. In addition, AgMES cells would be a precious resource for biomedical research such as other primate ES cell lines.

Collection and culture of primordial germ cells from cynomolgus monkeys (Macaca fascicularis)

AimTo clarify the location of primordial germ cells (PGC) in an embryo of target-age and to examine the culture environment of the PCG.MethodsThe days of ovulation and fertilization were estimated by measuring the serum concentration of estrogen. Pregnancy was confirmed by measurement of the serum concentration of the beta subunit of macaque chorionic gonadotropin and by ultrasonography We also examined the location of PGC in the embryo at the time of retrieval.ResultsResults showed that PGC in an embryo were in the hindguts at day 30 postfertilization, arrived at the genital ridges via mesenteries at approximately day 33 postfertilization, and colonized the gonads by day 36 postfertilization.ConclusionsIn conclusion, embryos collected on day 33 postfertilization are more suitable for obtaining PGC from cynomolgus monkeys. The PGC collected from cynomolgus monkey fetuses were cultured under conditions for the derivation and culture of human embryonic germ cells; enzymatically dispersed single cells were cultured on a SIM thioguanine-resistant ouabain-resistant cells (STO) feeder layer with recombinant human leukemia inhibitory factor, recombinant human basic fibroblast growth factor and forskolin. The cells from genital ridges and mesenteries at day 33 postfertilization had alkaline phosphatase (ALP) activity in vitro for a maximum of 13 days. In contrast, ALP activity had been held for 2 months under the same culture condition when the cells were derived from the gonads at day 66 postfertilization. Derivation of an embryonic germ cell from a cynomolgus monkey was not achieved from these cultures.

Reproductive Technologies and Related Studies in the Cynomolgus Monkey

Abstract In mice, basic reproductive technologies, such as oocyte/sperm collection, embryo production, micromanipulation, and embryo transfer, have been established. With these technologies, production of transgenic mice has become routine. The cynomolgus monkey, which is one of the laboratory animals closest to human beings, has been used to obtain vaccine approval and for medical research. Therefore, production of transgenic animals in the monkey is a very significant subject. We describe herein the current state of related studies in addition to current findings regarding reproductive technologies.

Current Reproductive Research in Non-Human Primates

ABSTRACT When using animals in experiments, it is important to select the animal that best suits the experiments purpose. Because non-human primates are closely related to humans, they are invaluable for use in clinical trials. Researchers using non-human primates should understand their characteristics before the start of the study and must execute the experiments efficiently. This article summarizes reproductive manipulation techniques in the study of non-human primates and the current status of this research.