Selective induction of human renal interstitial progenitor-like cell lineages from iPSCs reveals development of mesangial and EPO-producing cells.

Recent regenerative studies using human pluripotent stem cells (hPSCs) have developed multiple kidney-lineage cells and organoids. However, to further form functional segments of the kidney, interactions of epithelial and interstitial cells are required. Here we describe a selective differentiation of renal interstitial progenitor-like cells (IPLCs) from human induced pluripotent stem cells (hiPSCs) by modifying our previous induction method for nephron progenitor cells (NPCs) and analyzing mouse embryonic interstitial progenitor cell (IPC) development. Our IPLCs combined with hiPSC-derived NPCs and nephric duct cells form nephrogenic niche- and mesangium-like structures in vitro. Furthermore, we successfully induce hiPSC-derived IPLCs to differentiate into mesangial and erythropoietin-producing cell lineages in vitro by screening differentiation-inducing factors and confirm that p38 MAPK, hypoxia, and VEGF signaling pathways are involved in the differentiation of mesangial-lineage cells. These findings indicate that our IPC-lineage induction method contributes to kidney regeneration and developmental research.

In vitro methods to ensure absence of residual undifferentiated human induced pluripotent stem cells intermingled in induced nephron progenitor cells.

Cell therapies using human induced pluripotent stem cell (hiPSC)-derived nephron progenitor cells (NPCs) are expected to ameliorate acute kidney injury (AKI). However, using hiPSC-derived NPCs clinically is a challenge because hiPSCs themselves are tumorigenic. LIN28A, ESRG, CNMD and SFRP2 transcripts have been used as a marker of residual hiPSCs for a variety of cell types undergoing clinical trials. In this study, by reanalyzing public databases, we found a baseline expression of LIN28A, ESRG, CNMD and SFRP2 in hiPSC-derived NPCs and several other cell types, suggesting LIN28A, ESRG, CNMD and SFRP2 are not always reliable markers for iPSC detection. As an alternative, we discovered a lncRNA marker gene, MIR302CHG, among many known and unknown iPSC markers, as highly differentially expressed between hiPSCs and NPCs, by RNA sequencing and quantitative RT-PCR (qRT-PCR) analyses. Using MIR302CHG as an hiPSC marker, we constructed two assay methods, a combination of magnetic bead-based enrichment and qRT-PCR and digital droplet PCR alone, to detect a small number of residual hiPSCs in NPC populations. The use of these in vitro assays could contribute to patient safety in treatments using hiPSC-derived cells.

Progenitor analysis of primitive erythropoiesis generated from in vitro culture of embryonic stem cells.

OBJECTIVE: A variety of hematopoietic lineage cells have been produced from embryonic stem (ES) cells, but their differentiation processes have not been elucidated well, especially from the point of view of progenitor analysis. In this study, we utilized our coculture system, in which ES-derived Flk-1+ cells differentiated into TER-119+ primitive erythroid (EryP) cells on OP9 cells, and looked for progenitors in primitive erythropoiesis. MATERIALS AND METHODS: We studied the kinetics of TER-119+ erythroblast generation from Flk-1+ cells by monitoring the expression of TER-119, CD41, VE-cadherin, CD34, and c-kit antigens. Multicolor analysis was performed to detect CD41+TER-119+ cells and the stained cells were sorted to examine their morphology and EryP-producing potential in colony formation. RESULTS: Kinetic studies showed that the CD41+ population appeared early in the coculture and its expression pattern implied a role as an immediate progenitor of TER-119+ EryP cells. Multicolor analysis and colony-formation study supported this notion. Other progenitor markers such as VE-cadherin, CD34, and c-kit did not seem to define an immediate progenitor of EryP cells. One interesting observation is the detection of unique populations, CD41dim and CD41bright, detectable after 48 hours of the coculture. Majority of the CD41dim population progressed to the EryP lineage, whereas the CD41bright population seemingly advanced on a pathway distinct from the CD41dim population. CONCLUSIONS: CD41 expression was a useful marker to trace hematopoietic progenitors in ES-derived differentiation system. In particular, the CD41dim but not CD41bright population could serve as immediate precursors of EryP cells.

Demethylating agent, 5-azacytidine, reverses differentiation of embryonic stem cells.

The de novo methylation activity is essential for embryonic development as well as embryonic stem (ES) cell differentiation, where the intensive and extensive DNA methylation was detected. In this study, we investigated the effects of a demethylating agent, 5-azacytidine (5-AzaC), on differentiated ES cells in order to study the possibility of reversing the differentiation process. We first induced differentiation of ES cells by forming embryoid bodies, and then the cells were treated with 5-AzaC. The cells showed some undifferentiated features such as stem cell-like morphology with unclear cell-to-cell boundary and proliferative responsiveness to LIF. Moreover, 5-AzaC increased the expressions of ES specific markers, SSEA-1, and alkaline phosphatase activity as well as ES specific genes, Oct4, Nanog, and Sox2. We also found that 5-AzaC demethylated the promoter region of H19 gene, a typical methylated gene during embryonic differentiation. These results indicate that 5-AzaC reverses differentiation state of ES cells through its DNA demethylating activity to differentiation related genes.

Erythroblasts derived in vitro from embryonic stem cells in the presence of erythropoietin do not express the TER-119 antigen.

OBJECTIVE: In this study, we analyzed murine primitive erythropoiesis by coculturing Flk-1+ ES-derived cells with OP9 to find efficient culture conditions for erythroid cell induction. We utilized a nonserum culture system and EPO (erythropoietin) and found that this cytokine had unique properties. MATERIALS AND METHODS: ES cells (E14.1) were first differentiated to Flk-1+ cells and then cocultured with OP9 stromal cells. BIT9500 was used as a serum replacement. The erythroid morphology, hemoglobin types, and TER-119 expression levels were analyzed. RESULTS: Primitive erythroid cells with embryonic hemoglobin were generated very efficiently when the serum-containing culture was converted to the nonserum system. In this serum-free culture, TER-119+ erythroblasts appeared first on day 2 and maturation proceeded until day 7. When EPO was added to this coculture, the number of induced floating cells increased twofold to threefold. Unexpectedly, the erythroid-specific antigen TER-119 expression of these cells was drastically reduced. Since reduced TER-119 expression is usually interpreted as maturation arrest, we examined the phenotypic features of the EPO-treated cells. We found, however, no evidence of maturation arrest in the aspects of morphology and hemoglobin content. EPO did not suppress TER-119 expression of erythroblasts derived from fetal liver or adult bone marrow. CONCLUSIONS: Our results showed that EPO had the unusual property of inducing TER-119- erythroblasts in ES-derived primitive erythropoiesis. It is likely that this effect is unique to primitive erythropoiesis.