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.     

Sex differentiation and germ cell production in chimeric pigs produced by inner cell mass injection into blastocysts

This study aimed at collecting background knowledge for chimeric pig production. We analyzed the genetic sex of the chimeric pigs in relation to phenotypic sex as well as to functional germ cell formation. Chimeric pigs were produced by injecting Day 6 or Day 7 inner cell mass (ICM) cells into Day 6 blastocysts. Approximately 20% of the piglets born from the injected blastocysts showed overt coat color chimerism regardless of the embryonic stage of donor cells. The male:female sex ratio was 7:2 and 6:1 in the chimeras derived from Day 6 and Day 7 ICM cells, respectively, showing an obvious bias toward males. When XX donor cells were injected into XY blastocysts at the same embryonic stage, the phenotypic sex of the resulting chimera was male with no germ-line cells formed from the donor cell lineage. On the other hand, when the donor was XY and the recipient blastocyst was XX, the phenotypic sex of the chimera was male, and germ-line cells were derived only from the donor cells. The combination of XY donor cells and XY blastocysts produced some chimeras in which the donor cell lineage did not contribute to germ-line formation even when it appeared in coat color. When the embryonic stage of the donor was advanced by 1 day in the XY-XY combination, 100% of the germ-line cells of the chimeras were derived from the donor cell lineage. These data showed that characteristics of sex differentiation and germ cell formation in chimeric pigs are similar to those in chimeric mice.     

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.     

Quantitative estimation of chimerism in mice using microsatellite markers

An embryonic stem cell line was established from SV129 mouse blastocysts and used to generate chimeric mice by injection into OF1 blastocysts; 18 out of the 30 resulting offspring appeared chimeric as judged from their coat color patterns, and 3 of the 13 males proved to be germ-line chimeras as they transmitted the SV129 agouti phenotype to all or part of their offspring. The degree of chimerism of these males was evaluated for different tissues using polymorphic microsatellite markers amplified by the polymerase chain reaction. It was shown that these new markers can be effectively used to quantitatively estimate levels of chimerism. The CKMM (creatine kinase, muscle) microsatellite system was used to distinguish the SV129 from the OF1 genotype. In all performed tests, the correlation between DNA ratio and signal ratio, expressed as a base 10 logarithm, was shown to exceed or equal 0.98 for known DNA ratios (SV129/OF1) ranging from 1/99 to 99/1. Linear calibration methods were used to predict the % SV129 DNA of a test sample based on the obtained signal ratio. The accuracy of the prediction was evaluated by performing repeated measurements. Differences among three repeated estimates ranged from 2 to 17% for a given sample. Microsatellite systems should be very useful to monitor chimerism involving strains that can not be discerned with coat color or biochemical markers. This will be particularly important when ES methodology becomes available in species other than mice. © 1993 Wiley-Liss, Inc.     

Production of germline chimeras by transfer of chicken gonadal primordial germ cells maintained in vitro for an extended period

We previously reported that germline chimeras could be produced by transfer of chicken gonadal primordial germ cells (gPGCs) cultured for a short term (5 days). This study was subsequently undertaken to examine whether gPGCs maintained in vitro for an extended period could retain their specific characteristics to induce germline transmission. Chicken (White Leghorn, WL) gPGCs were retrieved from embryos at stage 28 (5.5 days of incubation) and continuously cultured for 2 months in modified Dulbecco's minimal essential medium without subpassage and changing of the feeder cell layer. After the identification of gPGC characteristics using Periodic acid-Shiff's (PAS) reaction and anti stage-specific embryonic antigen-1 (SSEA-1) antibody staining at the end of the culture, cultured gPGCs were injected into the dorsal aorta of Korean Ogol Chicken (KOC) recipient embryos at stage 17 (2.5 days of incubation). Nineteen chickens (13 males and 6 females) were hatched, grown to sexual maturity, and subsequently subjected to testcross analysis employing artificial insemination with adult KOC. Of these, four (three males and one female) hatched chickens with white coat color. The percentage of germline chimerism was 21% (4/19). The results of this study demonstrated that gPGCs could maintain their specific characteristics for up to 2 months in vitro, resulting in the birth of germline chimeras following transfer to recipient embryos.     

Chimeric pigs following blastocyst injection of transgenic porcine primordial germ cells.

Porcine primordial germ cell (PGC) derived cell lines of WAPhGH-transgenic pigs have been established that were able to contribute to chimeras. PGCs were isolated from day 25 to 28 genital ridges of more than 30 individual transgenic fetuses in order to have an easy to follow marker gene. To support undifferentiated growth, cell lines were derived and stable maintained on STO no. 8 feeder cells, a murine embryonic fibroblast cell line expressing recombinant, membrane-bound porcine stem cell factor (SCF). Fifteen lines proliferated in an undifferentiated state up to passage 13; two lines were maintained for more than 23 passages. Cell staining experiments for differentiation markers in several cell lines, indicated the presence of pluripotent cells in prolonged cultures. Further characterization using karyotyping revealed a normal, euploid set of chromosomes in cells of passages 15 and higher. Pluripotency of freshly isolated, short-term (up to 24 hr before injection) and long-term cultured, frozen/thawed cells was tested by injection into day 6 recipient blastocysts to give rise to chimeric piglets. The injected embryos (n = 209) were endoscopically transferred into the uterine horns of 11 recipient gilts. Tissue analysis from 49 fetuses and eighteen liveborn piglets for PGC contribution in chimeras was carried out using PCR analysis for the presence of the marker transgene. Thirty-two fetuses showed detectable chimerism in up to five out of 12 tissues analyzed. Skin samples from eight piglets were positive for the transgene, four of them displayed coat colour chimerism.     

Pluripotency of Homozygous-Diploid Mouse Embryos in Chimeras

Pluripotency of mouse uniparental cells (complete homozygous-diploid gynogenetic) produced by embryo manipulation was examined in aggregation chimeras with normally fertilized embryos. A male pronucleus was removed from fertilized eggs by micromanipulation and eggs were diploidized with cytochalasin B. Uniparental cells that developed to 4-cell or more advanced stages were aggregated with normally fertilized 8-cell embryos and transferred to the pseudopregnant female uteri to develop to term. Among the pups, 1 female and 3 males were identified as overt chimeras by their coat color and pigmentation of the retina. Using electophoretic analysis of the isozymes, the contribution of uniparental cells in these chimeras was confirmed by findings in the major organs such as liver, brain, small intestine, kidney, spleen, heart and testis. The female chimera produced offspring derived from oocytes of uniparental origin. Our experiments verified the pluripotency of microsurgically produced mouse uniparental cells.     

Three methods for producing fertile hemopoietic chimeras in mice

Three methods for producing semiallogeneic (F1----parental) hemopoietic chimeras with retained or regained fertility are detailed here. Prenatal (PN) chimeras were produced by injecting F1 ([BALB/c female x C3H/HeJ male] or [CBA/J female x C57BL/6 male]) fetal liver (days 13-18) or adult bone marrow cells (10(6)-10(7) cells/20 microliters/embryo) into the yolk-sac cavities of days 13-17 gestation BALB/c or CBA/J embryos, respectively, and allowing them to be born naturally. Neonatal (NN) chimeras were made by introducing F1 bone marrow cells (1-2 x 10(7) cells/0.25 ml) into newborn (less than 24 hr old) female mice through the anterior facial vein. Female mice were raised to maturity in both cases. Ovary-transplanted (OT) chimeras were made by first irradiating (9.5 Gy) and repopulating young female adult mice with 10(7) F1 bone marrow cells, followed by bilateral orthotopic transplantation of syngeneic ovarian tissue six weeks later. Females reconstituted with the above three methods were mated with normal syngeneic males and sacrificed at 11-16 days of pregnancy to evaluate hemopoietic chimerism. This was determined in all cases by a radioautographic evaluation of the extent of donor H-2 phenotype marker expression on splenic small lymphocytes, after an indirect labelling of single-cell suspensions with monospecific antibody and [125I]protein-A. Results indicate that hemopoietic chimerism was best in the PN group (0.3-78.1%, mean = 27.1); intermediate in the OT group (5.8-38.2%, mean = 18.1); and low in the NN group (0-14%, with one exception, which was 83.6%). Observed fertility was best for BALB/c host PN chimeras.(ABSTRACT TRUNCATED AT 250 WORDS)     

小鼠ES细胞种系嵌合体的获得

种系嵌合体的获得是实现ＥＳ细胞介导的转基因途径的决定步骤,ＥＳ细胞种系分化能力的保持是决定种系嵌合的前提条件,而事体的主种系嵌合体的获得则是判定ＥＳ细胞系是否具有种系分化能力的唯一方法,为考察本室新近建立的３种小鼠ＥＳ细胞系ＭＥＳＰＵ２１．ＭＥＳＰＵ２２和ＭＥＳＰＵ２９的种系分化能力,选用近交系Ｃ５７ＢＬ／６Ｊ及远交系ＫＭＷ和ＩＣＲ为受体胚胎提供者,分别通过囊胚注射法和８细胞期桑椹胚注射法进行了嵌     

Unidirectional distribution of mosaicism in chimeric rats.

Experimental rat chimeras were produced by aggregation of eight-cell embryos from two inbred strains, ACI/Hkm and WKAH/Hkm, which differ from each other in their major histocompatibility complexes and coat colors, and their mosaicism was analyzed. The existence of the isozyme Es-1, a serum cholinesterase specifically produced by WKAH-derived cells, and the agouti coat color due to ACI cells, indicated that all of the rats analyzed were unequivocal chimeras. The proportion of ACI cells in the red blood cell populations of the chimeras varied from 45% to 98%, as determined with a fluorescence-activated cell sorter and a monoclonal antibody against class I (RT1) antigen. Digital analysis of the coat color revealed that the proportion of the ACI type of coat color ranged from 72% to 98% in these chimeric rats. Each phenotype expressed in the coat color was complex and varied in size. The ratios of red blood cells and the coat color inclined toward the ACI type of cell population. Conversely, the rate of the WKAH-cell-type population was less than 50%. A breeding test disclosed chimerism of germ cells in two chimeric rats, and there were more pups with agouti coats than with albino coats. Taken together, it was shown in most of the phenotypes analyzed that the ACI type of cells was predominant in all of the chimeric rats. We discuss the possible causes for this unbalanced distribution in the rats.     

Fertile male tortoiseshell cats. Mosaicism due to gene instability?

Two fertile male tortoiseshell Burmese cats with atypical coat color distribution were found to have normal 38XY karyotypes. Synaptonemal complex analysis of one of these cats revealed normal meiotic pairing. Progeny data indicated that both cats were transmitting both alleles at the sex-linked orange locus, but with unequal frequencies. For one of these cats, analysis of pedigree and progeny data indicated that gene instability at the orange locus was the only possible explanation for its mosaicism. A third male tortoiseshell Burmese cat with typical tortoiseshell phenotype was found to be 39XXY and sterile.     

Development of either split tolerance or robust tolerance along with humoral tolerance to donor and third-party alloantigens in nonmyeloablative mixed chimeras

Hematopoietic chimerism is considered to generate robust allogeneic tolerance; however, tissue rejection by chimeras can occur. This "split tolerance" can result from immunity toward tissue-specific Ags not expressed by hematopoietic cells. Known to occur in chimeric recipients of skin grafts, it has not often been reported for other donor tissues. Because chimerism is viewed as a potential approach to induce islet transplantation tolerance, we generated mixed bone marrow chimerism in the tolerance-resistant NOD mouse and tested for split tolerance. An unusual multilevel split tolerance developed in NOD chimeras, but not chimeric B6 controls. NOD chimeras demonstrated persistent T cell chimerism but rejected other donor hematopoietic cells, including B cells. NOD chimeras also showed partial donor alloreactivity. Furthermore, NOD chimeras were split tolerant to donor skin transplants and even donor islet transplants, unlike control B6 chimeras. Surprisingly, islet rejection was not a result of autoimmunity, since NOD chimeras did not reject syngeneic islets. Split tolerance was linked to non-MHC genes of the NOD genetic background and was manifested recessively in F(1) studies. Also, NOD chimeras but not B6 chimeras could generate serum alloantibodies, although at greatly reduced levels compared with nonchimeric controls. Surprisingly, the alloantibody response was sufficiently cross-reactive that chimerism-induced humoral tolerance extended to third-party cells. These data identify split tolerance, generated by a tolerance-resistant genetic background, as an important new limitation to the chimerism approach. In contrast, the possibility of humoral tolerance to multiple donors is potentially beneficial.     

Distribution analysis of transferred donor cells in avian blastodermal chimeras.

Blastodermal chimeras were constructed by transferring quail cells to chick blastoderm. Contribution of donor cells to host were histologically analyzed utilizing an in situ cell marker. Of the embryos produced by injection of stage XI-XIII quail cells into stage XI-2 chick blastoderm, more than 50 percent were definite chimeras. The restriction on the spatial arrangement of donor cells was induced by varying the stage of host. Ectodermal chimerism was limited to the head region and no mesodermal chimerism was shown when the quail cells were injected into stage XI-XIII blastoderm. Mesodermal and ectodermal chimerisms were limited to the trunk, not to the head region, when the quail cells were injected into the stage XIV-2 blastoderm. In these chimeras, however, some of the injected quail cells formed ectopic epidermal cysts. Consequently, the stage XIV-2 blastoderm may become intolerant of the injected cells. Our results suggest that it is possible to obtain chimeras that have chimerism limited to a particular germ layer and region by varying the stage of donor cell injection. Injected quail cells contributed to endodermal tissues and primordial germ cells regardless of the injection site. The quail-chick blastodermal chimeras could be useful in the production of a transgenic chicken and in the investigation of immunological tolerance.     

Efficacious Production of Viable Germ-Line Chimeras between Embryonic Stem (ES) Cells and 8-Cell Stage Embryos

Many embryonic stem (ES) cell lines have been isolated from various mouse strains, but production of germ-line chimeras has been achieved with only strain 129. This report describes the isolation of a new ES cell line, F1/1, from a mouse blastocyst with the C57BL/6 X CBA male genotype and tests on its ability to produce germ-line chimeras by two techniques, blastocyst injection and 8-cell embryo injection. Chimera production using CD-1 blastocysts as a host was low (20%), as reported by others. But by the 8-cell embryo injection method, in which F1/1 cells were injected into the perivitelline space through a slit in the zona pellucida of 8-cell embryos, chimeric mice with extremely high chimerism were obtained at a rate of 80%. Breeding tests showed that 89% of the fertile males were germ-line chimeras and in most case, the majority of the sperms in their testes were derived from F1/1 cells. This F1/1 cell line with a different genotype from the 129 strain shows high ability to produce functional germ cells, moreover, the 8-cell embryo injection method using F1/1 cells seems to be an efficient way to produce viable germ-line chimeras.     

Hemopoietic origin of certain decidual cell precursors in murine pregnancy

The possible hemopoietic origin of certain precursors of uterine decidual cells appearing during normal murine pregnancy was investigated in semiallogeneic hemopoietic chimeras with retained or regained fertility. Chimeras were produced by three different methods in two donor-host combinations: F1 [BALB/c female x C3H/HeJ male] cells introduced into the parental strain BALB/c female hosts or F1 [CBA/J female x C57BL/6 male] cells introduced into CBA/J female hosts. Prenatal chimeras (PN) were made by reconstituting mouse fetuses (day 13-17) with 10(6)-10(7) adult bone marrow or fetal liver cells through the yolk sac and they were allowed to be delivered naturally. Neonatal chimeras (NN) were made by injecting 1-2 x 10(7) adult bone marrow cells into the anterior facial vein of neonatal mice (less than 24 hr old). In both cases, experimental animals were raised to maturity. Ovary-transplanted chimeras (OT) were made by injecting 10(7) bone marrow cells into lethally irradiated (9.5 Gy) young adult female mice, followed 6 weeks later with bilateral orthotopic transplants of syngeneic ovary grafts to restore fertility. All female chimeras produced by the three different methods were mated with syngeneic male partners to produce normal pregnancy. The extent of chimerism at the cellular level was determined in all cases by a radioautographic identification of the H-2 phenotype of splenic lymphocytes and decidual cells and macrophages in the collagenase-dispersed decidua at day 11-16 of normal pregnancy, following a sandwich labelling with monospecific anti-H-2 antibodies and 125I-protein A. Morphological discrimination of typical decidual cells from macrophages in the collagenase-dispersed decidua was carried out on the basis of several distinctive markers: presence of surface Dec-1 and Thy-1 and absence of surface F4/80 or latex phagocytosis for decidual cells, in contrast to macrophages which were phagocytic and expressed F4/80 but not Dec-1 or Thy-1. While the degree of hemopoietic chimerism (judged by the incidence of donor-derived lymphocytes in the spleen) varied from animal to animal, in all three groups (PN, NN, and OT) comprising a total of 26 chimeras, the percentage of typical decidual cells expressing donor H-2 phenotype showed an excellent correlation with that for small lymphocytes in the spleen. These results reveal that at least a subpopulation of typical decidual cells of the pregnant uterus has a hemopoietic genealogy. A possible familial relationship of these cells to granulated metrial gland cells remains unclear.     

Transmission of gametes with normal or translocation chromosomes in male and female single-sex mouse chimeras.

Three male and four female mouse single-sex chimeras derived from fusions of Rb(11.13)4Bnr T(1;13)70H homozygous embryos with +/+ embryos were caged with T(1;13)70H homozygotes of the opposite sex and followed through their reproductive lifespans. Six animals (three males and three females) were germline chimeras. The fz gene was used as a marker for the T70H reciprocal translocation. The ratio of fz/fz to fz/+ offspring did not change with increasing age in males, but decreased in two of the three female chimeras. Within males, there was generally good agreement between the proportions of translocation and nontranslocation germ cells from spermatogonial mitosis through the first and second meiotic division. In one male, this ratio was also reflected in the offspring. In the other two males, there was significant selection during haplophase, from which both types of spermatozoa could benefit.     

The production of chimeric rats and their use in the analysis of the hooded pigmentation pattern

New, improved media and procedures for making rat chimeric embryos and culturing them in vitro have been developed. We have produced 27 rat chimeras: 20 males and 7 females. This ratio of males to females is consistent with that seen in mouse chimeras, suggesting that rat sex chimeras develop as phenotypic males. By aggregating embryos containing appropriate genetic markers for pigment cell differentiation, it is possible to produce chimeras that elucidate the site of action of the hooded gene. The coat color patterns of black ? black hooded chimeras display a white belly spot. In black ? albino hooded chimeras, small patches of white hair appear on the head and a large white spot occurs on the belly. Black ? agouti hooded chimeras display both agouti and nonagouti pigmentation over the entire surface of the chimera. These animals are fully pigmented with no white spots. In black ? albino non-hooded chimeras, rather small irregular patches of black and white hairs are distributed throughout the pelage. Histological examination of sections of hair follicles obtained from the white areas in the head of black ? albino hooded chimeras revealed amelanotic melanocytes. On the other hand, hair bulbs from the white belly spots do not contain any such melanocytes. Thus the white hairs of the head are due to the presence of albino melanocytes, but the white hairs of the belly are due to the total absence of melanocytes. All these observations are consistent with the conclusion that the hooded gene acts within melanoblasts, probably to retard their migration from the neural crest and/or to prevent their entrance into the hair follicles of the white areas of hooded rats.     

Induction of pluripotency by injection of mouse trophectoderm cell nuclei into blastocysts following transplantation into enucleated oocytes

Pluripotency of mouse trophectoderm (TE) cells was examined using a nuclear transfer technique. We transferred a TE cell to an enucleated oocyte and cultured the reconstituted oocyte to be blastocyst stage. Then a portion of the inner cell mass (ICM) isolated from the TE-origin blastocyst was injected into the cavity of a fertilized blastocyst to produce a chimeric embryo, which was transferred to a recipient female. Of 319 oocytes reconstituted with TE cells, 263 (82.4%) had a single nucleus (1PN), 3 (0.9%) had 2 nuclei (2PN) and 53 (16.6%) had a nucleus with a polar body (1PN1PB). Although the oocytes with 1PN and 2PN developed to blastocysts (81 of 263, 30.8% and 1 of 3, respectively), only those with 1PN were used to produce chimeric blastocysts. After the transfer of chimeric embryos to recipient females, 7 (28%) of 25 conceptuses analyzed at midgestation showed chimerism. Of those 5 (71%), 6 (86%) and 4 (57%) chimeric conceptuses showed distribution of donor nuclei in the fetus, membrane and placenta, and the distributions were 10 to 65, 10 to 50 and 10 to 15%, respectively. Of the 23 young obtained, 7 (30%; 2 males and 5 females) were coat color chimeras. The contributions of donor nuclei were detected in the brain, lung, heart, liver, kidney, testis, ovary and blood. Each coat-color chimeric mouse was mated with CD-1 male or female mice, but no germ line chimera was obtained. When ICM cells were used as the control nuclear donor, the contribution was equivalent to those of TE cells. In conclusion, pluripotency of mouse TE cells on a somatic line was induced, and chimeric young were obtained using a nuclear transplantation technique.     

ES细胞（MESPU13）嵌合体小鼠的GPI分析

为了评判小鼠ＥＳ细胞系ＭＥＳＰＵ１３的分化潜能,我们对１９只嵌合小鼠的心、肝、脾、肺、肾、胰腺、生殖腺、肌肉和血液的ＧＰＩ（磷酸葡萄糖异构酶）进行了分析。在这些样品中,来源于ＥＳ细胞的Ａ型条带的检出情况和小鼠的毛色嵌合率成正比关系。当毛色嵌合率低于４０％时,除了少数小鼠的肾脏外,没有看到Ａ型的条带。当毛色嵌合率大于８５％时,几乎所有的器官组织都检测到Ａ型条带,显示了ＥＳ细胞在发育形成内、中、外胚层的细胞方面具有很高的分化潜能。另外,在毛色嵌合率大于８５％的其中的６只嵌合鼠的肌肉中,只观察到Ａ型的条带,表明这些肌肉只单独来源于ＥＳ细胞。