Impairment of the transition from proliferative stage to prehypertrophic stage in chondrogenic differentiation of human induced pluripotent stem cells harboring the causative mutation of achondroplasia in fibroblast growth factor receptor 3

- ACH specific human iPS cells were established by CRISPR/Cas9 genome editing.
- Up-regulation of IHH was suppressed in chondrogenic differentiated ACH specific cell.
- Transition from proliferative stage to prehypertrophic stage may be impaired in ACH.

IntroductionAchondroplasia (ACH) is a congenital disease which causes dwarfism and many symptoms resulting from skeletal dysplasia. Because present therapeutic strategies are mainly surgical procedures as symptomatic treatments, development of a radical treatment is desired. Clarification of the ACH pathology is essential for creating a new remedy. However, there are many questions about the disease mechanisms that have not been answered.MethodsAs a single base substitution of the FGFR3 gene had been proved to be the ACH causing genome mutation, our group established disease specific iPS cells by introducing the causative mutation of achondroplasia into human iPS cells by CRISPR/Cas9 based genome editing. These cells were differentiated towards chondrocytes, then the gene and protein expressions were examined by real time RT-PCR and Western blotting, respectively.ResultsBased on the western blotting analysis, the FGFR3 protein and phosphorylated ERK were increased in the FGFR3 mutated iPS cells compared to the control cells, while the FGFR3 gene expression was suppressed in the FGFR3 mutated iPS cells. According to chondrogenic differentiation experiments, the IHH expression level was increased in the control cells as the differentiation progressed. On the other hand, up-regulation of the IHH gene expression was suppressed in the FGFR3 mutated iPS cells.ConclusionsThese results suggested that chondrocyte maturation was impaired between the proliferative stage and prehypertrophic stage in the chondrocytes of ACH. The development of chemical compounds which affect the specific maturation stage of chondrocytes is expected to contribute to the ACH treatment, and FGFR3 genome-edited hiPSCs will be a valuable tool in such research studies.