Inhibition of FGF and TGF-β Pathways in hESCs Identify STOX2 as a Novel SMAD2/4 Cofactor

Nephron progenitors rhythmically alternate between renewal and differentiation phases that synchronize with kidney branching morphogenesis

The mammalian kidney achieves massive parallelization of function by exponentially duplicating nephron-forming niches during development. Each niche caps a tip of the ureteric bud epithelium (the future urinary collecting duct tree) as it undergoes branching morphogenesis, while nephron progenitors within niches balance self-renewal and differentiation to early nephron cells. Nephron formation rate approximately matches branching rate over a large fraction of mouse gestation, yet the nature of this apparent pace-maker is unknown. Here we correlate spatial transcriptomics data with branching 'life-cycle' to discover rhythmically alternating signatures of nephron progenitor differentiation and renewal across Wnt, Hippo-Yap, retinoic acid (RA), and other pathways. We then find in human stem-cell derived nephron progenitor organoids that Wnt/β-catenin-induced differentiation is converted to a renewal signal when it temporally overlaps with YAP activation. Similar experiments using RA activation indicate a role in setting nephron progenitor exit from the naive state, the spatial extent of differentiation, and nephron segment bias. Together the data suggest that nephron progenitor interpretation of consistent Wnt/β-catenin differentiation signaling in the niche may be modified by rhythmic activity in ancillary pathways to set the pace of nephron formation. This would synchronize nephron formation with ureteric bud branching, which creates new sites for nephron condensation. Our data bring temporal resolution to the renewal vs. differentiation balance in the nephrogenic niche and inform new strategies to achieve self-sustaining nephron formation in synthetic human kidney tissues.

Knock-Out of the Five Lysyl-Oxidase Family Genes Enables Identification of Lysyl-Oxidase Pro-Enzyme Regulated Genes

The five lysyl-oxidase genes share similar enzymatic activities and contribute to tumor progression. We have knocked out the five lysyl-oxidase genes in MDA-MB-231 breast cancer cells using CRISPR/Cas9 in order to identify genes that are regulated by LOX but not by other lysyl-oxidases and in order to study such genes in more mechanistic detail in the future. Re-expression of the full-length cDNA encoding LOX identified four genes whose expression was downregulated in the knock-out cells and rescued following LOX re-expression but not re-expression of other lysyl-oxidases. These were the AGR2, STOX2, DNAJB11 and DNAJC3 genes. AGR2 and STOX2 were previously identified as promoters of tumor progression. In addition, we identified several genes that were not downregulated in the knock-out cells but were strongly upregulated following LOX or LOXL3 re-expression. Some of these, such as the DERL3 gene, also promote tumor progression. There was very little proteolytic processing of the re-expressed LOX pro-enzyme in the MDA-MB-231 cells, while in the HEK293 cells, the LOX pro-enzyme was efficiently cleaved. We introduced point mutations into the known BMP-1 and ADAMTS2/14 cleavage sites of LOX. The BMP-1 mutant was secreted but not cleaved, while the LOX double mutant dmutLOX was not cleaved or secreted. However, even in the presence of the irreversible LOX inhibitor β-aminoproprionitrile (BAPN), these point-mutated LOX variants induced the expression of these genes, suggesting that the LOX pro-enzyme has hitherto unrecognized biological functions.

MicroRNA Regulation of Bone Marrow Mesenchymal Stem Cell Chondrogenesis: Toward Articular Cartilage

The production of a clinically useful engineered cartilage is an outstanding and unmet clinical need. High-throughput RNA sequencing provides a means of characterizing the molecular phenotype of populations of cells and can be leveraged to better understand differences among source cells, derivative engineered tissues, and target phenotypes. In this study, small RNA sequencing is utilized to comprehensively characterize the microRNA transcriptomes (miRNomes) of native human neonatal articular cartilage and human bone marrow-derived mesenchymal stem cells (hBM-MSCs) differentiating into cartilage organoids, contrasting the microRNA regulation of engineered cartilage with that of a promising target phenotype. Five dominant microRNAs are upregulated during cartilage organoid differentiation and disproportionately regulate transcription factors: miR-148a-3p, miR-140-3p, miR-27b-3p, miR-140-5p, and miR-181a-5p. Two microRNAs that dominate the miRNomes of hBM-MSCs, miR-21-5p and miR-143-3p, persist throughout the differentiation process and may limit the ability of these cells to differentiate into an engineered cartilage resembling target native articular cartilage. By using predictive bioinformatics tools and antagomir inhibition, these persistent microRNAs are shown to destabilize the mRNA of genes with known or potential roles in cartilage biology including FGF18, TGFBR2, TET1, STOX2, ARAP2, N4BP2L1, LHX9, NFIA, and RPS6KA5. These results shed light on the extent to which only a few microRNAs contribute to the complex regulatory environment of hBM-MSCs for engineered tissues. Impact statement MicroRNAs are emerging as important controlling elements in the differentiation of human bone marrow-derived mesenchymal stem cells (hBM-MSCs). By using a robust bioinformatic approach and further validation in vitro, here we provide a comprehensive characterization of the microRNA transcriptomes (miRNomes) of a commonly studied and clinically promising source of multipotent cells (hBM-MSCs), a gold standard model of in vitro chondrogenesis (hBM-MSC-derived cartilage organoids), and an attractive in vivo target phenotype for clinically useful engineered cartilage (neonatal articular cartilage). These analyses highlighted a specific set of microRNAs involved in the chondrogenic program that could be manipulated to acquire a more robust articular cartilage-like phenotype. This characterization provides researchers in the cartilage tissue engineering field a useful atlas with which to contextualize microRNA involvement in complex differentiation pathways.