Key Points Patient-derived iPSCs recapitulate juvenile myelomonocytic leukemia. MEK inhibition normalizes GM-CSF independence and hypersensitivity in myeloid precursors from JMML iPSCs.
SUMMARY TRIM58 is an E3 ubiquitin ligase superfamily member implicated by genome wide association studies (GWAS) to regulate human erythrocyte traits. Here we show that Trim58 expression is induced during late erythropoiesis and that its depletion by shRNAs inhibits the maturation of late stage nucleated erythroblasts to anucleate reticulocytes. Imaging flow cytometry studies demonstrate that Trim58 regulates polarization and/or extrusion of erythroblast nuclei. In vitro, Trim58 directly binds and ubiquitinates the intermediate chain of the microtubule motor dynein. In cells, Trim58 stimulates proteasome-dependent degradation of the dynein holoprotein complex. During erythropoiesis, Trim58 expression, dynein loss and enucleation occur concomitantly and all are inhibited by Trim58 shRNAs. Dynein regulates nuclear positioning and microtubule organization, both of which undergo dramatic changes during erythroblast enucleation. Thus, we propose that Trim58 regulates this process by eliminating dynein. Our findings identify an erythroid-specific regulator of enucleation and elucidate a previously unrecognized mechanism for controlling dynein activity.
2389 Osteolineage cells (OLCs) have been shown to participate in a regulatory bone marrow microenvironment for the hematopoietic stem and progenitor cells (HSPCs) – the endosteal niche. Our previous experiments using live animal imaging have demonstrated that single transplanted HSPCs preferentially home in close proximity to the individual OLCs. We hypothesized that these HSPC-proximal cells represent a distinct subpopulation of OLCs, which is specifically involved in a non-cell autonomous regulation of HSPC quiescence and self-renewal. To test this hypothesis, we developed a novel experimental platform, which allows visualization of HSPC-OLC cell pairs in-vivo and retrieval of the individual OLCs for molecular analysis. We intravenously injected DiI labeled adult bone marrow-derived FACS-sorted Lin−Sca1+c-kit+CD34−Flk2− HSPCs into irradiated newborn collagen 2.3GFP mouse recipients; in this transgenic strain, the majority of the OLCs are labeled with green fluorescent protein (GFP). 48 hours later, we sacrificed the animals and obtained fresh unfixed sections of femoral trabecular bone. Using a combination of differential interference contrast fluorescent microscopy, in-situ enzymatic digestion and micromanipulation, we harvested individual GFP-positive OLCs located within 2 cell diameters (“niche” OLCs) or greater than 5 cell diameters (“control” OLCs) from single DiI-bright HSPCs. Following reverse transcription and cDNA amplification with 29 cycles of PCR, as per the single cell RNA-Seq protocol (Tang et al, Nature Protocols 2010), we performed real-time RT-PCR analysis of 31 samples – 15 niche cells and 16 controls - for the OLC signature genes (osteocalcin, osterix) and for the genes implicated in playing a functional role in the HSPC-OLC cell interaction (osteopontin, CXCL12, angiopoietin 1). Transcripts for GAPDH, collagen 1 and GFP served as positive controls for the amplification. As expected, all cells were positive for GFP and over 85% cells expressed collagen 1. Osteopontin and CXCL12 were expressed at a similar level and frequency in the niche and control OLCs. However, we found that angiopoietin 1 transcripts were detected exclusively in the niche OLCs (3/15 versus 0/16, p <0.05 by Chi-squared). Moreover, niche OLCs were enriched for the osterix-positive cells (7/15 versus 2/16, p <0.05 by Chi-squared) and expressed a lower level of osteocalcin, as normalized for GAPDH expression (1.13 vs. 0.97, p< 0.05 by t-test). Our results suggest that niche OLCs may have a distinct molecular signature and reside within a population of very immature OLCs, as evidenced by the osterix + osteocalcin low phenotype. Further unbiased transcriptome characterization of these cells using genome-wide RNA-Seq assay is therefore likely to provide more evidence in support of our hypothesis and reveal novel non-cell autonomous regulators of HSPC quiescence. To our knowledge, this approach represents the first attempt to define molecular heterogeneity in-vivo at a single cell level using the micro-anatomical relationship between two heterologous cell types. Disclosures: Scadden: Fate Therapeutics: Equity Ownership.
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