Dynamics of gene expression during bone matrix formation in osteogenic cultures derived from human embryonic stem cells in vitro.

Characterization of directed differentiation protocols is a prerequisite for understanding embryonic stem cell behavior, as they represent an important source for cell-based regenerative therapies. Studies have investigated the osteogenic potential of human embryonic stem cells (HESCs), building upon those using pre-osteoblastic cells, however no consensus exists as to whether differentiating HESCs behave in a similar manner to the traditionally used osteoblastic progenitors. Thus, the aim of the current investigation was to define the gene expression pattern of osteoblastic differentiating HESCs, treated with ascorbic acid phosphate, beta-glycerophosphate and dexamethasone over a 25 day period. Characterization of the gene expression dynamics revealed a phasic pattern of bone-associated protein synthesis. Collagen type I and osteopontin were initially expressed in proliferating immature cells, whereas osterix was up-regulated at the end of active cellular proliferation. Subsequently, mineralization-associated proteins, bone sialoprotein and osteocalcin were detected. In light of this dynamic expression pattern, we concluded that two distinguishable phases occurred during osteogenic HESC differentiation; first, cellular proliferation and secretion of a pre-maturational matrix, and second the appearance of osteoprogenitors with characteristic extracellular matrix synthesis. Establishment of this model provided the foundation of a time-frame for the additional supplementation with growth factors, BMP2 and VEGF. BMP2 induced the expression of principle osteogenic factors, such as osterix, bone sialoprotein and osteocalcin, whereas VEGF had the converse effect on the gene expression pattern.

Differentiation of human embryonic stem cells into osteogenic or hematopoietic lineages: a dose-dependent effect of osterix over-expression.

Enhanced differentiation of human embryonic stem cells (HESCs), induced by genetic modification could potentially generate a vast number of diverse cell types. Such genetic modifications have frequently been achieved by over-expression of individual regulatory proteins. However, careful evaluation of the expression levels is critical, since this might have important implications for the differentiation potential of HESCs. To date, attempts to promote osteogenesis by means of gene transfer into HESCs using the early bone "master" transcription factor osterix (Osx) have not been reported. In this study, we attained HESC subpopulations expressing two significantly different levels of Osx, following lentiviral gene transfer. Both subpopulations exhibited spontaneous differentiation and reduced expression of markers characteristic of the pluripotent phenotype, such as SSEA3, Tra1-60, and Nanog, In order to promote bone differentiation, the cells were treated with ascorbic acid, beta-glycerophosphate and dexamethasone. The high level of Osx, compared to endogenous levels found in primary human osteoblasts, did not enhance osteogenic differentiation, and did not up-regulate collagen I expression. We show that the high Osx levels instead induced the commitment towards the hematopoietic-endothelial lineage-by up-regulating the expression of CD34 and Gata1. However, low levels of Osx up-regulated collagen I, bone sialoprotein and osteocalcin. Conversely, forced high level expression of the homeobox transcription factor HoxB4, a known regulator for early hematopoiesis, promoted osteogenesis in HESCs, while low levels of HoxB4 lead to hematopoietic gene expression.

Lentiviral-mediated HoxB4 expression in human embryonic stem cells initiates early hematopoiesis in a dose-dependent manner but does not promote myeloid differentiation.

The variation of HoxB4 expression levels might be a key regulatory mechanism in the differentiation of human embryonic stem cell (hESC)-derived hematopoietic stem cells (HSCs). In this study, hESCs ectopically expressing high and low levels of HoxB4 were obtained using lentiviral gene transfer. Quantification throughout differentiation revealed a steady increase in transcription levels from our constructs. The effects of the two expression levels of HoxB4 were compared regarding the differentiation potential into HSCs. High levels of HoxB4 expression correlated to an improved yield of cells expressing CD34, CD38, the stem cell leukemia gene, and vascular epithelium-cadherin. However, no improvement in myeloid cell maturation was observed, as determined by colony formation assays. In contrast, hESCs with low HoxB4 levels did not show any elevated hematopoietic development. In addition, we found that the total population of HoxB4-expressing cells, on both levels, decreased in developing embryoid bodies. Notably, a high HoxB4 expression in hESCs also seemed to interfere with the formation of germ layers after xenografting into immunodeficient mice. These data suggest that HoxB4-induced effects on hESC-derived HSCs are concentration-dependent during in vitro development and reduce proliferation of other cell types in vitro and in vivo. The application of the transcription factor HoxB4 during early hematopoiesis from hESCs might provide new means for regenerative medicine, allowing efficient differentiation and engraftment of genetically modified hESC clones. Our study highlights the importance of HoxB4 dosage and points to the need for experimental systems allowing controlled gene expression. Disclosure of potential conflicts of interest is found at the end of this article.

Bone matrix formation in osteogenic cultures derived from human embryonic stem cells in vitro.

Bone matrix production and mineralization involves sophisticated mechanisms, including the initial formation of an organic extracellular matrix into which inorganic hydroxyapatite crystals are later deposited. Human embryonic stem (hES) cells offer a potential to study early developmental processes and provide an unlimited source of cells. In this study, four different hES cell lines were used, and two different approaches to differentiate hES cells into the osteogenic lineage were taken. Undifferentiated cells were cultured either in suspension, facilitating the formation of embryoid bodies (EBs), or in monolayer, and both methods were in the presence of osteogenic supplements. Novel to our osteogenic differentiation study was the use of commercially available human foreskin fibroblasts to support the undifferentiated growth of the hES cell colonies, and their propagation in serum replacement-containing medium. Characterization of the osteogenic phenotype revealed that all hES cell lines differentiated toward the mesenchymal lineage, because T-Brachyury, Flt-1, and bone morphogenetic protein-4 could be detected. Main osteoblastic marker genes Runx2, osterix, bone sialoprotein, and osteocalcin were up-regulated. Alizarin Red S staining demonstrated the formation of bone-like nodules, and bone sialoprotein and osteocalcin were localized to these foci by immunohistochemistry. Cells differentiated in monolayer conditions exhibited greater osteogenic potential compared to those from EB-derived cells. We conclude that in vitro hES cells can produce a mineralized matrix possessing all the major bone markers, the differentiation of pluripotent hES cells to an osteogenic lineage does not require initiation via EB formation, and that lineage potential is not dependent on the mode of differentiation induction but on a cell line itself.

Transcriptome analysis of fetal metatarsal long bones by microarray, as a model for endochondral bone formation.

Endochondral bone formation is orchestrated by mesenchymal cell condensation to form cartilage anlagen, which act as a template for bone formation and eventual mineralization. The current study performed gene expression analysis to examine pre- and post-mineralization stages (E15 and E19) of endochondral bone formation, using fetal metatarsal long bones as a model. An extensive number of genes were differentially expressed, with 543 transcripts found to have at least 2-fold up-regulation and 742 with a greater than 2-fold down-regulation. A bioinformatics approach was adopted based on gene ontology groups, and this identified genes associated with the regulation of signaling and skeletal development, cartilage replacement by bone, and matrix degradation and turnover. Transcripts linked to skeletal patterning, including Hoxd genes 10-12, Gli2 and Noggin were considerably down-regulated at E19. Whereas genes associated with bone matrix formation and turnover, ACP5, MMP-13, bone sialoprotein, osteopontin, dentin matrix protein-1 and MMP-9 all were distinctly up-regulated at this later time point. This approach to studying the formation of the primary ossification center provides a unique picture of the developmental dynamics involved in the molecular and biochemical processes during this intricately regulated process.