In Vitro Modelling of Osteogenesis Imperfecta with Patient-Derived Induced Mesenchymal Stem Cells.

(1) Mesenchymal stem cells (MSCs) are a valuable cell model to study the bone pathology of Osteogenesis Imperfecta (OI), a rare genetic collagen-related disorder characterized by bone fragility and skeletal dysplasia. We aimed to generate a novel OI induced mesenchymal stem cell (iMSC) model from induced pluripotent stem cells (iPSCs) derived from human dermal fibroblasts. For the first time, OI iMSCs generation was based on an intermediate neural crest cell (iNCC) stage. (2) Skin fibroblasts from healthy individuals and OI patients were reprogrammed into iPSCs and subsequently differentiated into iMSCs via iNCCs. (3) Successful generation of iPSCs from acquired fibroblasts was confirmed with changes in cell morphology, expression of iPSC markers SOX2, NANOG, and OCT4 and three germ-layer tests. Following differentiation into iNCCs, cells presented increased iNCC markers including P75NTR, TFAP2A, and HNK-1 and decreased iPSC markers, shown to reach the iNCC stage. Induction into iMSCs was confirmed by the presence of CD73, CD105, and CD90 markers, low expression of the hematopoietic, and reduced expression of the iNCC markers. iMSCs were trilineage differentiation-competent, confirmed using molecular analyses and staining for cell-type-specific osteoblast, adipocyte, and chondrocyte markers. (4) In the current study, we have developed a multipotent in vitro iMSC model of OI patients and healthy controls able to differentiate into osteoblast-like cells.

Exploration of the skeletal phenotype of the Col1a1 +/Mov13 mouse model for haploinsufficient osteogenesis imperfecta type 1.

Introduction: Osteogenesis Imperfecta is a rare genetic connective tissue disorder, characterized by skeletal dysplasia and fragile bones. Currently only two mouse models have been reported for haploinsufficient (HI) mild Osteogenesis Imperfecta (OI); the Col1a1 +/Mov13 (Mov13) and the Col1a1 +/-365 mouse model. The Mov13 mice were created by random insertion of the Mouse Moloney leukemia virus in the first intron of the Col1a1 gene, preventing the initiation of transcription. Since the development of the Mov13 mice almost four decades ago and its basic phenotypic characterization in the 90s, there have not been many further studies. We aimed to extensively characterize the Mov13 mouse model in order to critically evaluate its possible use for preclinical studies of HI OI. Methods: Bone tissue from ten heterozygous Mov13 and ten wild-type littermates (WT) C57BL/6J mice (50% males per group) was analyzed at eight weeks of age with bone histomorphometry, micro computed tomography (microCT), 3-point bending, gene expression of different collagens, as well as serum markers of bone turnover. Results: The Mov13 mouse presented a lower bone strength and impaired material properties based on our results of 3-point bending and microCT analysis respectively. In contrast, no significant differences were found for all histomorphometric parameters. In addition, no significant differences in Col1a1 bone expression were present, but there was a significant lower P1NP concentration, a bone formation marker, measured in serum. Furthermore, bone tissue of Mov13 mice presented significantly higher expression of collagens (Col1a2, Col5a1 and Col5a2), and bone metabolism markers (Bglap, Fgf23, Smad7, Edn1 and Eln) compared to WT. Finally, we measured a significantly lower Col1a1 expression in heart and skin tissue and also determined a higher expression of other collagens in the heart tissue. Conclusion: Although we did not detect a significant reduction in Col1a1 expression in the bone tissue, a change in bone structure and reduction in bone strength was noted. Regrettably, the variability of the bone phenotype and the appearance of severe lymphoma in adult Mov13 mice, does not favor their use for the testing of new long-term drug studies. As such, a new HI OI type 1 mouse model is urgently needed.

GPCR structure and activation: an essential role for the first extracellular loop in activating the adenosine A2B receptor.

The highly variable extracellular loops in G protein-coupled receptors (GPCRs) have been implicated in receptor activation, the mechanism of which is poorly understood. In a random mutagenesis screen on the human adenosine A(2B) receptor (A(2B)R) using the MMY24 Saccharomyces cerevisiae strain as a read-out system, we found that two residues in the first extracellular loop, a phenylalanine and an aspartic acid at positions 71 and 74, respectively, are involved in receptor activation. We subsequently performed further site-directed and site-saturation mutagenesis. These experiments revealed that the introduction of mutations at either of the identified positions results in a wide variety of receptor activation profiles, with changes in agonist potency, constitutive activity, and intrinsic activity. Radioligand binding studies showed that the changes in activation were not due to changes in receptor expression. We interpret these data in the light of the recently revealed structure of the adenosine A(2A)R, the closest homologue of the A(2B)R. The two residues are suggested to be vital in maintaining the tertiary structure of a ß sheet in the extracellular domain of the A(2B)R. We hypothesize that deterioration of structure in the extracellular domains of GPCRs compromises overall receptor structure with profound consequences for receptor activation and constitutive activity.