At most three ES cells contribute to the somatic lineages of chimeric mice and of mice produced by ES-tetraploid complementation

Chimeric or entirely embryonic stem (ES) cell-derived mice ("ES mice") can be produced by injecting ES cells into diploid (2n) or tetraploid (4n) host blastocysts, respectively. Usually, between 10 and 15 ES cells are injected into the host blastocyst, but it is not clear how many of the injected cells contribute to the somatic lineages, thus serve as "founder cells" of the embryo proper. We have used genetically labeled ES cells to retrospectively determine the number of founder ES cells that generate the somatic lineages of chimeric and of ES mice. ES cell clones individually labeled with provirus were mixed in equal numbers and injected into 2n or 4n blastocysts to generate chimeric or ES mice. Southern analysis of DNA from the resulting animals indicated that the somatic lineages were most often derived from one or two and sometimes from up to three founder ES cells. The number of founder cells was independent of the total number of cells injected into the host blastocysts. Our results are consistent with the notion that constraints of the host embryo restrict the number of ES cells that can contribute to a chimeric or an ES mouse.     

The targeted disruption of the CD98 gene results in embryonic lethality

CD98 is one of the important molecules for development, cell differentiation, cell proliferation, and regulation of cellular function. In this study, CD98 heavy chain (HC) knockout mice were produced and analyzed. Five targeted ES clones were obtained and colony frequency was about 2%. One (clone 113) of the five heterozygous ES cell clones had undergone aberrant recombination at the 5' side. The aberrant recombination happened at the site between second intron and 5' arm. All lines from correctly targeted clones could not transmit the mutated allele to spermatozoa. The mutated allele derived from the aberrant targeted clone was transmitted to the progeny. However, none of the F2 mice was homozygous for the CD98 mutation, indicating that the targeted disruption of the CD98 gene results in embryonic lethality. The point of embryonic lethality is considered to be between 3.5 and 9.5 dps. These findings indicate that CD98 molecules are essential for mouse embryogenesis.     

Spermatozoa lacking acrosin protein show delayed fertilization

Acrosin (ACR), a serine proteinase located in the acrosome of the sperm, has been presumed to be involved in the recognition and binding of the sperm to the zona pellucida of the ovum and the sperm penetration through the zona pellucida. To examine the function of acrosin in vivo, we have generated mice carrying a mutation at the acrosin locus (Acr) through targeted disruption in embryonic stem (ES) cells. One chimeric male and female transmitted the targeted gene through their germ line. Homozygous Acr^+/− mice are fertile and yield litters comparable in number and size to those of Acr^+/− mice. These data show that sperm of the homozygous Acr^+/− mice are able to penetrate the zona pellucida, fertilize the ovum, and produce viable offspring. However, spermatozoa lacking acrosin protein show a delayed fertilization. One chimeric male which contained the targeted gene in 20% of its sperm transmitted only the Acr⁺ allele to its progeny. Furthermore, in vitro fertilization with equally mixed sperm cells of Acr^+/− and Acr^+/− mice resulted in fertilization only with the Acr⁺ sperm cells. Incubation of oocytes with Acr⁺ or Acr⁻ sperm show that the Acr⁻ sperm are faster to fertilize the oocytes than the Acr⁺ sperm cells. These results suggest that Acr⁻ sperm have a selective disadvantage when they are in competition with Acr⁺ sperm. Mol. Reprod. Dev. 46:370–376, 1997. © 1997 Wiley-Liss, Inc.     

Combining sperm plug genotyping and coat color chimerism predicts germline transmission

There has been a significant increase in the use of C57BL/6N-derived ES cells for the production of gene knockout mice. However, the potential for germline transmission (GLT) from chimeras on this genetic background has been observed to be highly variable. Using coat color as an indicator of somatic chimerism to infer the extent of chimeric contribution to the germ cell population, even highly agouti C57BL/6N-derived chimeras can fail to achieve GLT. We investigated the extent to which quantitative PCR genotyping for a marker gene expressed in gene targeted ES cells can be performed on DNA extracted from sperm present in copulatory plugs to determine the contribution of ES cells to the germ cells. We found that an objective assessment of sperm DNA from copulatory plugs combined with a subjective assessment of coat color chimerism can be used to accurately inform the selection of chimeras for breeding that are likely to achieve GLT. These results indicate that, compared to random selection of chimeras, including an analysis of copulatory plugs to set chimeras for breeding can help to reduce costs, minimize time, and facilitate research for projects requiring the production, selection, breeding, and testing of chimeras to generate gene-targeted mice.     

Generation of progeny from embryonic stem cells by microinsemination of male germ cells from chimeric mice

Mice chimeric for embryonic stem (ES) cells have not always successfully produced ES-derived offspring. Here we show that the male gametes from ES cells could be selected in male chimeric mice testes by labeling donor ES cells or host blastocytes with GFP. Male GFP-expressing ES-derived germ cells occurred as colonies in the chimeric testes, where the seminiferous tubules were separated into green and non-green regions. When mature spermatozoa from green tubules were used for microinsemination, GFP-expressing offspring were efficiently obtained. Using a reverse study, we also obtained ES-derived progeny from GFP-negative ES cells in GFP-labeled host chimeras. Furthermore, we showed this approach could be accelerated by using round spermatids from the testes of 20-day-old chimeric mice. Thus, this technique allowed us to generate the ES cell-derived progeny even from the low contributed chimeric mice, which cannot produce ES-origin offspring by natural mating.     

Tumor suppression by a severely truncated species of retinoblastoma protein

Rb(+/+):Rb(-/-) chimeric mice are healthy until early in adulthood when they develop lethal pituitary tumors composed solely of Rb(-/-) cells. In an effort to delineate the minimal structures of the retinoblastoma protein necessary for RB tumor suppression function, chimeric animals derived from stably transfected RB(-/-) embryonic stem (ES) cells were generated. One such ES cell transfectant expressed a human RB allele encoding a stable, truncated nuclear derivative lacking residues 1 to 378 (Delta 1-378). Others encoded either wild-type human RB or an internally deleted derivative of the Delta 1-378 mutant. All gave rise to viable chimeric animals with comparable degrees of chimerism. However, unlike control mice derived, in part, from naive Rb(-/-) ES cells or from ES cells transformed by the double RB mutant, Delta 1-378/Delta exon22, animals derived from either wild-type RB- or Delta 1-378 RB-producing ES cells failed to develop pituitary tumors. Thus, in this setting, a substantial fraction of the RB sequence is unnecessary for RB-mediated tumor suppression.     

MAPK p38 alpha is dispensable for lymphocyte development and proliferation

Signals mediated by the p38alpha MAPK have been implicated in many processes required for the development and effector functions of innate and adaptive immune responses. As mice deficient in p38alpha exhibit embryonic lethality, most analyses of p38alpha function in lymphocytes have relied on the use of pharmacologic inhibitors and dominant-negative or constitutively active transgenes. In this study, we have generated a panel of low passage p38alpha(+/+), p38alpha(+/-), and p38alpha(-/-) embryonic stem (ES) cells through the intercrossing of p38alpha(+/-) mice. These ES cells were used to generate chimeric mice by RAG-deficient blastocyst complementation, with the lymphocytes in these mice being derived entirely from the ES cells. Surprisingly, B and T cell development were indistinguishable when comparing chimeric mice generated with p38alpha(+/+), p38alpha(+/-), and p38alpha(-/-) ES cell lines. Moreover, proliferation of p38alpha(-/-) B and T cells in response to Ag receptor and non-Ag receptor stimuli was intact. Thus, p38alpha is not an essential component of signaling pathways required for robust B and T lymphocyte developmental, nor is p38alpha essential for the proliferation of mature B and T cells.     

Production of mouse pups from germline transmission-failed knockout chimeras

Occasionally, chimeras do not transmit the gene of interest to pups in gene disruption experiments. However, the risk of failure could be reduced if we could identify embryonic stem (ES)-derived germ cells in the testis. Here, we report the production of pups from three lines of infertile chimeric male mice and the establishment of knockout lines by combining green fluorescent protein-tagged ES cells with intracytoplasmic sperm injection.     

Development and Initial Characterization of Xenomitochondrial Mice

Xenomitochondrial mice harboring trans-species mitochondria on a Mus musculus domesticus (MD) nuclear background were produced. We created xenomitochondrial ES cell cybrids by fusing Mus spretus (MS), Mus caroli (MC), Mus dunni (Mdu), or Mus pahari (MP) mitochondrial donor cytoplasts and rhodamine 6-G treated CC9.3.1 or PC4 ES cells. The selected donor backgrounds reflected increasing evolutionary divergence from MD mice and the resultant mitochondrial-nuclear mismatch targeted a graded respiratory chain defect. Homoplasmic (MS, MC, Mdu, and MP) and heteroplasmic (MC) cell lines were injected into MD ova, and liveborn chimeric mice were obtained (MS/MD 18 of 87, MC/MD 6 of 46, Mdu/MD 31 of 140, and MP/MD l of 9 founder chimeras, respectively). Seven MS/MD, 1 MC/MD, and 11 Mdu/MD chimeric founder females were mated with wild-type MD males, and 18 of 19 (95%) were fertile. Of fertile females, only one chimeric MS/MD (1% coat color chimerism) and four chimeric Mdu/MD females (80-90% coat color chimerism) produced homoplasmic offspring with low efficiency (7 of 135; 5%). Four male and three female offspring were homoplasmic for the introduced mitochondrial backgrounds. Three male and one female offspring proved viable. Generation of mouse lines using additional female ES cell lineages is underway. We hypothesize that these mice, when crossbred with neurodegenerative-disease mouse models, will show accelerated age-related neuronal loss, because of their suboptimal capacity for oxidative phosphorylation and putatively increased oxidative stress.     

Establishment of Smad2 conditional gene targeting mice based on the Cre-LoxP system

Smads is a new gene family in transforming growth factor-β (TGF- β signaling pathway. Smad2 mutated in multiple human tumors and may be a candidate tumor suppressor gene. Targeted disruption of murine Smad2 gene resulted in embryonic lethality at E6.5. To study the function of Smad2 in vertebrate organgenesis and tumorigenesis, we constructed the Smad2 conditional targeting vector in which two LoxP sequences were placed to flank the sequences encoding the C terminal functional domain of Smad2. The validity of the LoxP sites in the targeting construct was tested in E. coli that express the Cre recombinase constitutively. The vector was electropo-rated into ES cells and 3 targeted ES cell clones were obtained by Southern blot screening. Targeted ES cells were introduced into C57BL/6J blastocysts by microinjection to generate germ-line chimeras. Genotyping analysis showed that 2 progeny among these chimeras carried the Smad2 conditional targeted allele. The establishment of Smad2 conditional gene targetin     

Influence of maternal-fetal histocompatibility and MHC zygosity on maternal microchimerism

To investigate the relationship between maternal-fetal histocompatibility and maternal microchimerism, we developed a sensitive quantitative PCR assay for the neomycin resistance gene (neoR), and, in a mouse model system, used neoR as a noninherited maternal allele marker of maternal cells to detect and quantitate maternal microchimerism in tissues of neoR(-/-) N2 backcross progeny of (neoR(+/-))F(1) females mated with neoR(-/-) males. Using this approach, we obtained evidence for the presence of chimeric maternal cells in the brain, spleen, and thymus of all weanling and adult mice so tested. The numbers of chimeric maternal cells present in the spleen did not differ significantly from those in the thymus regardless of age or maternal-fetal histocompatibility. At all ages, brain tissue had higher level of maternal microchimerism than lymphoid tissue in mice MHC identical with their mothers, but the levels were similar in mice MHC disparate with their mothers. The levels of chimeric maternal cells in both brain and lymphoid tissue of mice with homozygous syngenicity and maternal allogenicity were similar, and tended to be higher than tissue-specific levels in mice with either combined maternal-fetal allogenicity or heterozygous syngenicity. Thus, MHC homozygous progeny had higher levels of maternal microchimerism than MHC heterozygous progeny. We conclude that normal mice possess small numbers of maternal cells in spleen, thymus, brain, and probably most other tissues, and that maternal-fetal histocompatibility influences the levels of these cells by mechanisms related to MHC zygosity of the progeny.     

A Simple and Convenient Method for Preparing Chimeric Animals from Embryonic stem (ES) Cells

Gene targeting in embryonic stem (ES) cells followed by preparation of chimeric animals is the most effective method to study the function of a gene during development and differentiation. Here, we describe a cost effective and convenient method to produce chimeric animals. Cryopreserved 8–16 cell mouse embryos were aggregated with ES cells in microwell petridishes (Khillan & Bao, 1997) to obtain blastocysts. Also, freshly isolated morulas were aggregated with ES cells that were positive for the green florescent protein (GFP). After overnight culture, the blastocysts that exhibited GFP florescence were transferred to the pseudo-pregnant mothers to obtain chimeric animals. The animals displayed high degree of ES contribution and transmitted gene to their progeny after mating with the normal animals. The studies demonstrate that the aggregation with cryopreserved embryos followed by the pre-selection for a visual marker can be a high throughput and cost effective method to create chimeric animals from the gene targeted ES cells.     

四倍体补偿技术的建立及其应用

常规基因剔除小鼠的获得主要是利用ES细胞的全能性先获得嵌合体小鼠,再利用:ES细胞的生殖系传递能力,通过嵌合体与野生型小鼠的交配获得杂合子小鼠.而四倍体补偿技术则可绕过嵌合体小鼠阶段,直接获得基因修饰杂合子小鼠.利用电融合技术和Piezoelectric microinjecfion显微注射技术建立了四倍体补偿技术,小鼠四倍体胚胎的获得率(电融合率)为(93.01±l.37)%,经体外培养囊胚形成率为(82.49±2.08)%.通过显微注射方法将2种129品系小鼠来源的ES细胞(CJ7和SCR012)注射到四倍体囊胚腔中,获得了完全ES细胞来源的小鼠,ES鼠的获得率分别为2.7%和8.3%.经微卫星DNA检测,成体小鼠的10个被检测组织均为129小鼠来源的.同时,也利用基因修饰的ES细胞进行了研究,获得了2种基因修饰的完全ES细胞来源的杂合子小鼠,部分小鼠具有繁殖能力,经繁育已获得了纯合子,其中凝血因子Ⅷ基因敲除小鼠获得了预期的血友病小鼠表型.上述结果说明四倍体补偿技术可应用于基因修饰小鼠的制备.     

Direct production of gene-targeted mice from ES cells by nuclear transfer and gene transmission to their progeny.

In order to evaluate the usefulness of a cloning technique to produce gene-manipulated mice for the field of laboratory animal science, we produced mice cloned from gene-targeted embryonic stem (ES) cells and examined the vertical transmission of a targeted gene to their progeny. Of 1257 eggs constructed by nuclear transfer using M-phase ES donor cells targeted with an oviduct-specific glycoprotein (OGP) gene, 990 formed a pseudo-pronucleus and a polar body after activation. Of 504 cloned embryos transferred into recipients, 20 live cloned pups (2%) were recovered by Caesarean section at 19.5 days of gestation. Fourteen of these cloned mice were studied. Genotyping of the OGP locus and 20 microsatellite loci showed that they were genetically identical to the OGP gene-targeted TT2 cells. Eight cloned pups grew into adults, of which 7 were male and 1 was female (missing the Y chromosome). Mating experiments using the cloned mice were carried out. Of 89 F1 mice produced from the mating of cloned and C57BL/6J mice, 50 had the targeted OGP gene heterozygously. Thirty-seven F2 mice from 4 pairs of the OGP-/+ mice were composed of 9 OGP-/-, 18 OGP-/+, and 10 OGP+/+. Moreover, 26 offspring of one pair of the cloned mice were composed of 10 OGP-/-, 12 OGP-/+, and 4 OGP+/+. These offspring were fertile and transmitted the mutant OGP gene to the next generation. Comparison of these results with those of germline chimeric mice indicates that gene-targeted mice can be produced at least one generation earlier by nuclear transfer than by the conventional methods. In addition, the targeted OGP gene was constantly transmitted to the progeny of the gene-targeted mice. Cloning techniques are potentially a more efficient way to generate gene-manipulated mice for laboratory animal science, although such techniques include many unresolved problems, such as low production efficiency, and selection of a cell source for gene manipulation among others.     

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.     

Embryonic Stem Cells Are Redirected to Non-Tumorigenic Epithelial Cell Fate by Interaction with the Mammary Microenvironment

Experiments were conducted to redirect mouse Embryonic Stem (ES) cells from a tumorigenic phenotype to a normal mammary epithelial phenotype in vivo. Mixing LacZ-labeled ES cells with normal mouse mammary epithelial cells at ratios of 1∶5 and 1∶50 in phosphate buffered saline and immediately inoculating them into epithelium-divested mammary fat pads of immune-compromised mice accomplished this. Our results indicate that tumorigenesis occurs only when normal mammary ductal growth is not achieved in the inoculated fat pads. When normal mammary gland growth occurs, we find ES cells (LacZ+) progeny interspersed with normal mammary cell progeny in the mammary epithelial structures. We demonstrate that these progeny, marked by LacZ expression, differentiate into multiple epithelial subtypes including steroid receptor positive luminal cells and myoepithelial cells indicating that the ES cells are capable of epithelial multipotency in this context but do not form teratomas. In addition, in secondary transplants, ES cell progeny proliferate, contribute apparently normal mammary progeny, maintain their multipotency and do not produce teratomas.     

Embryonic stem cells derived from C57BL/6J and C57BL/6N mice

Mouse embryonic stem (ES) cells with the C57BL/6 genetic background allow the generation of knockout mice without the need to backcross to C57BL/6. However, C57BL/6 ES cells whose pluripotency after homologous recombination has been confirmed are not yet available from public cell banks. To facilitate the use of ES cells derived from C57BL/6 sublines in both biologic and medical research, we demonstrated that the use of knockout serum replacement as a medium supplement and 8-cell blastomeres as recipient embryos allowed establishment of ES cells and production of germline chimeric mice, respectively. Under effective conditions, a large number of ES cell lines were established from C57BL/6J and C57BL/6N blastocysts. The majority of ES cells in many cell lines obtained from both strains showed a normal chromosome number. Germline chimeric mice were generated from C57BL/6J and C57BL/6N ES cells. Finally, the ES cell line B6J-S1UTR, derived from C57BL/6J, was used for successful production of gene knockout mice. C57BL/6J ES (B6J-S1UTR and B6J-23UTR) and C57BL/6N ES (B6N-22UTR) cells are available from the cell bank of the BioResource Center at RIKEN Tsukuba Institute (http://www.brc.riken.jp/lab/cell/english/).     

Target-independent specification of proprioceptive sensory neurons

The c-fes protooncogene encodes a nonreceptor tyrosine kinase (Fes) implicated in cytokine receptor signal transduction, granulocyte survival, and myeloid differentiation. To study the role of c-fes during myelopoiesis, we generated embryonic stem (ES) cells with a targeted disruption of the c-fes locus. Targeted mutagenesis deletes the C-terminal SH2 and tyrosine kinase domains of c-fes (referred to as c-fes(Delta c/Delta c)). We demonstrate that the c-fes(Delta c/Delta c) allele results in a truncated Fes protein that retains the N-terminal oligomerization domain, but lacks both the SH2 and the tyrosine kinase domain. In vitro differentiation of c-fes(Delta c/Delta c) ES cells results in hyperproliferation of an early myeloid cell. Generation of c-fes(Delta c/Delta c) mutant chimeric mice causes lethality by E13.5 with embryos exhibiting pleiotropic defects, the most striking being cardiovascular abnormalities. These results establish that c-fes is an important regulator of myeloid cell proliferation and embryonic development.