The partial purification of mouse mammary gland stem cells (MaSCs) using combinatorial cell surface markers (Lin − CD24 + CD29 h CD49f h ) has improved our understanding of their role in normal development and breast tumorigenesis. Despite the significant improvement in MaSC enrichment, there is presently no methodology that adequately isolates pure MaSCs. Seeking new markers of MaSCs, we characterized the stem-like properties and expression signature of label-retaining cells from the mammary gland of mice expressing a controllable H2b-GFP transgene. In this system, the transgene expression can be repressed in a doxycycline-dependent fashion, allowing isolation of slowly dividing cells with retained nuclear GFP signal. Here, we show that H2b-GFP h cells reside within the predicted MaSC compartment and display greater mammary reconstitution unit frequency compared with H2b-GFP neg MaSCs. According to their transcriptome profile, H2b-GFP h MaSCs are enriched for pathways thought to play important roles in adult stem cells. We found Cd1d, a glycoprotein expressed on the surface of antigen-presenting cells, to be highly expressed by H2b-GFP h MaSCs, and isolation of Cd1d + MaSCs further improved the mammary reconstitution unit enrichment frequency to nearly a single-cell level. Additionally, we functionally characterized a set of MaSC-enriched genes, discovering factors controlling MaSC survival. Collectively, our data provide tools for isolating a more precisely defined population of MaSCs and point to potentially critical factors for MaSC maintenance.
It is well recognized that, in the mouse, high-dose estrogen induces sclerosis within the shaft of long bones, an action that is largely thought to reflect increased osteoblastic cellular activity. We undertook to characterize this response in more detail, by performing a histologic analysis of the early changes induced by high-dose estrogen in the tibial cavity of young intact female mice. Female mice were sacrificed immediately before or 4, 8, 12, or 24 days after commencing subcutaneous injections of 17-estradiol (500 µg/animal/week), and longitudinal tibial sections were subsequently examined. Estrogen was found to cause a rapid gain in cancellous bone, with cancellous bone volume increasing by ∼50% after 8 days, and by 5-fold after 24 days. Analysis of cancellous double-labeled surfaces revealed that this gain in bone reflected the emergence of new cancellous bone formation sites within the medullary cavity, rather than the reactivation and extension of formation over pre-existing bone surfaces. Comparison of the time course of these changes between proximal and distal regions of the proximal tibial metaphysis suggested that these new cancellous formation sites appear as a rapid wave extending distally from the secondary spongiosa. Alkaline phosphatase (ALP) immunocytochemistry revealed that, by 12 days after estrogen administration, a population of strongly ALP positive cells had appeared throughout the marrow cavity. We conclude that, at the proximal tibial metaphysis of female mice, estrogen-induced medullary sclerosis largely reflects a process of de novo medullary bone formation, possibly mediated by the generation of osteoblasts from bone marrow osteoprogenitor cells. (J Bone Miner Res 1999;14:178-186)
High-dose estrogen both stimulates new medullary bone formation and suppresses hematopoiesis in mouse long bones. To determine whether the latter response is a direct consequence of the former, we compared the time course of estrogen's effects on osteogenesis and hematopoietic bone marrow. Flow cytometry was employed to measure hematopoietic subpopulations in bone marrow from femurs of female mice killed at different times after commencing 0.5 mg estradiol/wk to each animal. Estrogen markedly reduced the number of leucocytes (CD11a positive), which had already diminished by 75% after 4 days and had virtually disappeared by 18 days. Specific populations showed a similar pattern of decline after estrogen, including B lymphocytes, monocytes, and endothelial cells. In contrast, the osteogenic precursor population showed a marked increase after estrogen treatment, as assessed by assaying alkaline phosphatase-positive colony-forming units (fibroblastic) ex vivo. However, this rise did not reach significance until 8 days after estrogen administration, suggesting that it follows rather than precedes estrogen's effects on hematopoiesis. We conclude that estrogen does not suppress hematopoiesis in mouse long bones as a direct consequence of its effects on osteogenesis.
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