Although the ovary has a large store of germ cells, most of them do not reach mature stages. If a culture system could be developed from early growing follicles to mature oocytes, it would be useful for biological research as well as for reproductive medicine. This study was conducted to establish a multistep culture system from isolated early growing follicles to mature oocytes using a mouse model. Early growing follicles with diameters of 60-95 mm corresponding to primary and early secondary follicles were isolated from 6-day-old mice and classified into three groups by diameter. These follicles contained oocytes with diameters of w45 mm and one or a few layered granulosa cells on the basal lamina. Embedding in collagen gel was followed by first-step culture. After 9-day culture, the growing follicles were transferred onto collagen-coated membrane in the second step. At day 17 of the culture series, the oocyte-granulosa cell complexes were subjected to in vitro maturation. Around 90% of the oocytes in follicles surviving at day 17 resumed second meiosis (metaphase II oocytes: 49.0-58.7%), regardless of the size when the follicle culture started. To assess developmental competence to live birth, the eggs were used for IVF and implantation in pseudopregnant mice. We successfully obtained two live offspring that produced next generations after puberty. We thus conclude that the culture system reported here was able to induce the growth of small follicles and the resultant mature oocytes were able to develop into normal mice.
There is increasing evidence that human hematopoietic stem cells can develop into lymphocytes expressing T cell surface markers in the organ culture of murine embryonic thymic lobes. If human T cells with functional maturity are inducible from human stem cells in the mouse, it may be a useful model to investigate human T cell development and the human immune response in vivo. To approach this, we produced a hybrid cluster of murine fetal thymic epithelial cells and human cord blood-derived CD34(+) cells (hu/m cluster) using reaggregate thymic organ culture, and subsequently implanted it under the kidney capsule of NOD/SCID mice. The implanted hu/m cluster grew in volume under the kidney capsule and contained increased numbers of CD4(+)CD8(+)cells as well as CD4 or CD8 single-positive cells with low CD1a expression. These lymphocytes were also shown to possess activity for producing IL-2 and IL-4. Characteristics similar to human T cells also developed in the thymus of newly established mice lacking NK activity from NOD/SCID mice. These results indicate that functionally mature T cells can develop in vivo from human hematopoietic progenitors in the murine environment composed of thymic epithelial cells.
We have generated mutant mice in which TCR beta chain enhancer (E(beta)) was replaced with the TCR alpha chain enhancer (E(alpha)). Using this mouse model, we analyzed (i) recombination status of the TCR beta chain genes after functional V(D)J rearrangements occurred in the first allele during double-negative (DN)-to-double-positive (DP) transition and (ii) involvement of E(beta) for the expression of rearranged TCR beta chain genes. Our data show that E(alpha) substituted for E(beta) function to express a similar extent of TCR beta chains exactly at the same time as did E(beta) (CD25+CD44- DN stage), although the proportion of TCR beta+ cells at this stage was low in mutant mice. At the DP stage, germline transcription and histone acetylation of D(beta)-J(beta) loci were detectable at a high degree in both mutant and wild-type mice. However, DP cells in mutant mice retained the germline D(beta)-J(beta) configuration at a higher frequency than that of wild-type mice, whereas both DP cells expressed TCR beta chains to a similar extent. These data suggest that chromatin opening has a limited impact on D(beta)-to-J(beta) recombination at the DP stage and that E(alpha) is functionally equivalent to E(beta) in promoting expression of functionally rearranged TCR beta chain genes through DN-to-DP transition.
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