Sandra Loaiza

Single-cell profiling of human megakaryocyte-erythroid progenitors identifies distinct megakaryocyte and erythroid differentiation pathways

BackgroundRecent advances in single-cell techniques have provided the opportunity to finely dissect cellular heterogeneity within populations previously defined by “bulk” assays and to uncover rare cell types. In human hematopoiesis, megakaryocytes and erythroid cells differentiate from a shared precursor, the megakaryocyte-erythroid progenitor (MEP), which remains poorly defined.ResultsTo clarify the cellular pathway in erythro-megakaryocyte differentiation, we correlate the surface immunophenotype, transcriptional profile, and differentiation potential of individual MEP cells. Highly purified, single MEP cells were analyzed using index fluorescence-activated cell sorting and parallel targeted transcriptional profiling of the same cells was performed using a specifically designed panel of genes. Differentiation potential was tested in novel, single-cell differentiation assays. Our results demonstrate that immunophenotypic MEP comprise three distinct subpopulations: “Pre-MEP,” enriched for erythroid/megakaryocyte progenitors but with residual myeloid differentiation capacity; “E-MEP,” strongly biased towards erythroid differentiation; and “MK-MEP,” a previously undescribed, rare population of cells that are bipotent but primarily generate megakaryocytic progeny. Therefore, conventionally defined MEP are a mixed population, as a minority give rise to mixed-lineage colonies while the majority of cells are transcriptionally primed to generate exclusively single-lineage output.ConclusionsOur study clarifies the cellular hierarchy in human megakaryocyte/erythroid lineage commitment and highlights the importance of using a combination of single-cell approaches to dissect cellular heterogeneity and identify rare cell types within a population. We present a novel immunophenotyping strategy that enables the prospective identification of specific intermediate progenitor populations in erythro-megakaryopoiesis, allowing for in-depth study of disorders including inherited cytopenias, myeloproliferative disorders, and erythromegakaryocytic leukemias.

Inadequate fine-tuning of protein synthesis and failure of amino acid homeostasis following inhibition of the ATPase VCP/p97

The cellular mechanisms that control protein degradation may constitute a non-oncogenic cancer cell vulnerability and, therefore, a therapeutic target. Although this proposition is supported by the clinical success of proteasome inhibitors in some malignancies, most cancers are resistant to proteasome inhibition. The ATPase valosin-containing protein (VCP; p97) is an essential regulator of protein degradation in multiple pathways and has emerged as a target for cancer therapy. We found that pharmacological depletion of VCP enzymatic activity with mechanistically different inhibitors robustly induced proteotoxic stress in solid cancer and multiple myeloma cells, including cells that were insensitive, adapted, or clinically resistant to proteasome inhibition. VCP inhibition had an impact on two key regulators of protein synthesis, eukaryotic initiation factor 2α (eIF2α) and mechanistic target of rapamycin complex 1 (mTORC1), and attenuated global protein synthesis. However, a block on protein translation that was itself cytotoxic alleviated stress signaling and reduced cell death triggered by VCP inhibition. Some of the proteotoxic effects of VCP depletion depended on the eIF2α phosphatase, protein phosphatase 1 regulatory subunit 15A (PPP1R15A)/PP1c, but not on mTORC1, although there appeared to be cross-talk between them. Thus, cancer cell death following VCP inhibition was linked to inadequate fine-tuning of protein synthesis and activity of PPP1R15A/PP1c. VCP inhibitors also perturbed intracellular amino acid levels, activated eukaryotic translation initiation factor 2α kinase 4 (EIF2AK4), and enhanced cellular dependence on amino acid supplies, consistent with a failure of amino acid homeostasis. Many of the observed effects of VCP inhibition differed from the effects triggered by proteasome inhibition or by protein misfolding. Thus, depletion of VCP enzymatic activity triggers cancer cell death in part through inadequate regulation of protein synthesis and amino acid metabolism. The data provide novel insights into the maintenance of intracellular proteostasis by VCP and may have implications for the development of anti-cancer therapies.

The level of BCR-ABL1 kinase activity before treatment does not identify chronic myeloid leukemia patients who fail to achieve a complete cytogenetic response on imatinib

This study investigated the in vitro inhibition of Crkl phosphorylation by imatinib in CD34+ cells from patients with chronic myeloid leukemia, and showed that it does not correlate with the cytogenetic response, possibly indicating that BCR-ABL1-independent resistance mechanisms exist. Imatinib is currently the first line therapy for newly diagnosed patients with chronic myeloid leukemia. However, 20–25% of patients do not achieve durable complete cytogenetic responses. The mechanism underlying this primary resistance is unknown, but variations in BCR-ABL1 kinase activity may play a role and can be investigated by measuring the autophosphorylation levels of BCR-ABL1 or of a surrogate target such as Crkl. In this study we used flow cytometry to investigate the in vitro inhibition of Crkl phosphorylation by imatinib in CD34+ cells in diagnostic samples from two groups of patients distinguished by their cytogenetic response. No difference in inhibition of Crkl phosphorylation was observed in the two groups. The observation that increasing the dose of imatinib in vivo did not increase the level of cytogenetic response in some non-responders suggests that in at least a proportion of patients imatinib resistance may be due to activation of BCR-ABL1-independent pathway.

Differential Regulation of Human Bone Marrow Mesenchymal Stromal Cell Chondrogenesis by Hypoxia Inducible Factor‐1α Hydroxylase Inhibitors

The transcriptional profile induced by hypoxia plays important roles in the chondrogenic differentiation of marrow stromal/stem cells (MSC) and is mediated by the hypoxia inducible factor (HIF) complex. However, various compounds can also stabilize HIFs oxygen‐responsive element, HIF‐1α, at normoxia and mimic many hypoxia‐induced cellular responses. Such compounds may prove efficacious in cartilage tissue engineering, where microenvironmental cues may mediate functional tissue formation. Here, we investigated three HIF‐stabilizing compounds, which each have distinct mechanisms of action, to understand how they differentially influenced the chondrogenesis of human bone marrow‐derived MSC (hBM‐MSC) in vitro. hBM‐MSCs were chondrogenically‐induced in transforming growth factor‐β3‐containing media in the presence of HIF‐stabilizing compounds. HIF‐1α stabilization was assessed by HIF‐1α immunofluorescence staining, expression of HIF target and articular chondrocyte specific genes by quantitative polymerase chain reaction, and cartilage‐like extracellular matrix production by immunofluorescence and histochemical staining. We demonstrate that all three compounds induced similar levels of HIF‐1α nuclear localization. However, while the 2‐oxoglutarate analog dimethyloxalylglycine (DMOG) promoted upregulation of a selection of HIF target genes, desferrioxamine (DFX) and cobalt chloride (CoCl2), compounds that chelate or compete with divalent iron (Fe2+), respectively, did not. Moreover, DMOG induced a more chondrogenic transcriptional profile, which was abolished by Acriflavine, an inhibitor of HIF‐1α‐HIF‐β binding, while the chondrogenic effects of DFX and CoCl2 were more limited. Together, these data suggest that HIF‐1α function during hBM‐MSC chondrogenesis may be regulated by mechanisms with a greater dependence on 2‐oxoglutarate than Fe2+ availability. These results may have important implications for understanding cartilage disease and developing targeted therapies for cartilage repair. Stem Cells 2018;36:1380–1392

Bi-directional cell-pericellular matrix interactions direct stem cell fate

Modifiable hydrogels have revealed tremendous insight into how physical characteristics of cells’ 3D environment drive stem cell lineage specification. However, in native tissues, cells do not passively receive signals from their niche. Instead they actively probe and modify their pericellular space to suit their needs, yet the dynamics of cells’ reciprocal interactions with their pericellular environment when encapsulated within hydrogels remains relatively unexplored. Here, we show that human bone marrow stromal cells (hMSC) encapsulated within hyaluronic acid-based hydrogels modify their surroundings by synthesizing, secreting and arranging proteins pericellularly or by degrading the hydrogel. hMSC’s interactions with this local environment have a role in regulating hMSC fate, with a secreted proteinaceous pericellular matrix associated with adipogenesis, and degradation with osteogenesis. Our observations suggest that hMSC participate in a bi-directional interplay between the properties of their 3D milieu and their own secreted pericellular matrix, and that this combination of interactions drives fate.3D hydrogels have provided information on the physical requirements of stem cell fate, but the contribution of interactions with the pericellular environment are under-explored. Here the authors show that pericellular matrix secreted by human bone marrow stromal cells (hMSC) embedded in a HA-based hydrogel contribute to hMSC fate.

Neighboring cells override 3D hydrogel matrix cues to drive human MSC quiescence

Physical properties of modifiable hydrogels can be tuned to direct stem cell differentiation in a role akin to that played by the extracellular matrix in native stem cell niches. However, stem cells do not respond to matrix cues in isolation, but rather integrate soluble and non-soluble signals to balance quiescence, self-renewal and differentiation. Here, we encapsulated single cell suspensions of human mesenchymal stem cells (hMSC) in hyaluronic acid-based hydrogels at high and low densities to unravel the contributions of matrix- and non-matrix-mediated cues in directing stem cell response. We show that in high-density (HD) cultures, hMSC do not rely on hydrogel cues to guide their fate. Instead, they take on characteristics of quiescent cells and secrete a glycoprotein-rich pericellular matrix (PCM) in response to signaling from neighboring cells. Preventing quiescence precluded the formation of a glycoprotein-rich PCM and forced HD cultures to differentiate in response to hydrogel composition. Our observations may have important implications for tissue engineering as neighboring cells may act counter to matrix cues provided by scaffolds. Moreover, as stem cells are most regenerative if activated from a quiescent state, our results suggest that ex vivo native-like niches that incorporate signaling from neighboring cells may enable the production of clinically relevant, highly regenerative cells.

An engineered, quantifiable in vitro model for analysing the effect of proteostasis- targeting drugs on tissue physical properties

Cellular function depends on the maintenance of protein homeostasis (proteostasis) by regulated protein degradation. Chronic dysregulation of proteostasis is associated with neurodegenerative and age-related diseases, and drugs targeting components of the protein degradation apparatus are increasingly used in cancer therapies. However, as chronic imbalances rather than loss of function mediate their pathogenesis, research models that allow for the study of the complex effects of drugs on tissue properties in proteostasis-associated diseases are almost completely lacking. Here, to determine the functional effects of impaired proteostatic fine-tuning, we applied a combination of materials science characterisation techniques to a cell-derived, in vitro model of bone-like tissue formation in which we pharmacologically perturbed protein degradation. We show that low-level inhibition of VCP/p97 and the proteasome, two major components of the degradation machinery, have remarkably different effects on the bone-like material that human bone-marrow derived mesenchymal stromal cells (hMSC) form in vitro. Specifically, whilst proteasome inhibition mildly enhances tissue formation, Raman spectroscopic, atomic force microscopy-based indentation, and electron microscopy imaging reveal that VCP/p97 inhibition induces the formation of bone-like tissue that is softer, contains less protein, appears to have more crystalline mineral, and may involve aberrant micro- and ultra-structural tissue organisation. These observations contrast with findings from conventional osteogenic assays that failed to identify any effect on mineralisation. Taken together, these data suggest that mild proteostatic impairment in hMSC alters the bone-like material they form in ways that could explain some pathologies associated with VCP/p97-related diseases. They also demonstrate the utility of quantitative materials science approaches for tackling long-standing questions in biology and medicine, and could form the basis for preclinical drug testing platforms to develop therapies for diseases stemming from perturbed proteostasis or for cancer therapies targeting protein degradation. Our findings may also have important implications for the field of tissue engineering, as the manufacture of cell-derived biomaterial scaffolds may need to consider proteostasis to effectively replicate native tissues.

Abstract 1261: Comprehensive failure of intracellular protein homeostasis kills myeloma and solid cancer cells following VCP/p97 inhibition

Introduction: Intracellular protein homeostasis requires a well-controlled protein degradation machinery to clear damaged and old proteins and to replenish intracellular amino acid pools. Cancer cells may be particularly susceptible to agents that disrupt protein degradation because of unbalanced protein levels related to gain or loss of genetic material, high protein turnover, or high-level production of specific proteins such as Ig in multiple myeloma (MM). The AAA ATPase VCP (p97) is a master regulator of protein degradation that has been implicated in oncogenesis. Small molecule VCP inhibition (VCP-i) rapidly activates caspases in cancer cells, induces endoplasmic reticulum (ER) stress, and has anti-tumor activity in murine xenograft models. A phase 1 trial of VCP-i in relapsed MM has recently opened. Methods: We investigated the cellular mechanisms that govern VCP-i mediated cancer cell death in MM cell lines including bortezomib-adapted AMO1 cells, MM cells from patients with bortezomib-resistant MM, as well as lung cancer (A549) and osteosarcoma (Saos2) cells. Results: The ATP-competitive inhibitor DBeQ and the allosteric inhibitor NMS873 induced cell line as well as primary MM cell death at similar low micromolar concentrations independently of bortezomib sensitivity. DBeQ and NMS873 caused phosphorylation of eIF2alpha in a time- and dose-dependent manner and resulted in strong transcriptional and translational up-regulation of ATF4, CHOP and GADD34. VCP-i also increased expression of ER chaperones BiP and p58IPK. Inhibition of eIF2alpha de-phosphorylation with guanabenz reduced S6 phosphorylation, a marker of protein translation, and increased A549 and OPM2 cell survival early (8h) after VCP-i. Direct inhibition of protein translation with cycloheximide also decreased early VCP-i mediated cell death. Using MEFs deficient in eIF2alpha kinases we show that eIF2alpha phosphorylation following VCP-i depends on both the unfolded protein response mediator PERK and the nutrient sensor GCN2. We found that DBeQ induces GCN2 phosphorylation in parallel with loss of mTORC1 signalling, induction of the key autophagy factor p62, and accumulation of LC3-II. DBeQ also induced a rapid decrease in free intracellular L-amino acids. Depletion of selected amino acids in the cell culture medium increased cell death and mRNA levels of CHOP and GADD34 following VCP-i with DBeQ or NMS873, but not following induction of ER stress with tunicamycin. Conclusion: Collectively, these data show that both ATP-competitive and allosteric VCP-i effectively kills cancer cells independently of bortezomib sensitivity. Disrupting VCP function induces early cell death via inappropriate eIF2alpha-regulated protein translation downstream of GADD34. VCP-i also depletes the intracellular free amino acid pool, resulting in cell death despite compensatory catabolic processes. Citation Format: Katarzyna Parzych, Sandra Loaiza, Tamara M. Chinn, Philippa May, Florentina Porsch, Anastasios Karadimitris, Christoph Driessen, Heather P. Harding, David Ron, Holger W. Auner. Comprehensive failure of intracellular protein homeostasis kills myeloma and solid cancer cells following VCP/p97 inhibition. [abstract]. In: Proceedings of the 106th Annual Meeting of the American Association for Cancer Research; 2015 Apr 18-22; Philadelphia, PA. Philadelphia (PA): AACR; Cancer Res 2015;75(15 Suppl):Abstract nr 1261. doi:10.1158/1538-7445.AM2015-1261