Measurement of Mitochondrial Mass and Membrane Potential in Hematopoietic Stem Cells and T-cells by Flow Cytometry

A fine balance of quiescence, self-renewal, and differentiation is key to preserve the hematopoietic stem cell (HSC) pool and maintain lifelong production of all mature blood cells. In recent years cellular metabolism has emerged as a crucial regulator of HSC function and fate. We have previously demonstrated that modulation of mitochondrial metabolism influences HSC fate. Specifically, by chemically uncoupling the electron transport chain we were able to maintain HSC function in culture conditions that normally induce rapid differentiation. However, limiting HSC numbers often precludes the use of standard assays to measure HSC metabolism and therefore predict their function. Here, we report a simple flow cytometry assay that allows reliable measurement of mitochondrial membrane potential and mitochondrial mass in scarce cells such as HSCs. We discuss the isolation of HSCs from mouse bone marrow and measurement of mitochondrial mass and membrane potential post ex vivo culture. As an example, we show the modulation of these parameters in HSCs via treatment with a metabolic modulator. Moreover, we extend the application of this methodology on human peripheral blood-derived T cells and human tumor infiltrating lymphocytes (TILs), showing dramatic differences in their mitochondrial profiles, possibly reflecting different T cell functionality. We believe this assay can be employed in screenings to identify modulators of mitochondrial metabolism in various cell types in different contexts.

Deciphering Metabolic Regulation of Hematopoietic Stem Cell Fate

Mukul Girotra

Hematopoietic stem cells (HSCs) are responsible for life-long production of all mature blood cells. This unique characteristic makes them an ideal candidate for cell-based therapies to treat various hematological malignancies. Their extensive use in the clinic is often hampered due to insufficient number of cells obtained from donors. Countless attempts to expand HSCs in vitro have failed, primarily due to our inability to recapitulate key features of the native bone marrow microenvironment, termed niche, in a dish. The absence of important niche signals in vitro results in rapid proliferation of HSCs with a concomitant loss of their long-term multi lineage blood reconstitution potential. The niche in the bone marrow involves a highly complex network of physical and biochemical signals that, in concert with cell-intrinsic mechanisms, is believed to control HSC fate choices. Moreover, the hypoxic conditions in the niche presents an extreme metabolic environment, imposing HSCs to attain a distinct metabolic identity as compared to their differentiated progeny. However, despite decades of research it is currently very poorly understood how HSCs take the decision to either undergo self-renewal or differentiation. Insights into the mechanisms regulating HSC fate choices are key to design better strategies for HSC maintenance and expansion in vitro for use in clinical transplantations. The overall goal of this thesis is to employ innovative experimental tools to explore the role of metabolism in regulating HSC fate choices. In the first part of this thesis a versatile cell-tracking assay was developed to follow HSC divisions in vitro. A combination of cell tracking and immunostaining was used to systematically map phenotypic changes in HSCs up to four divisions, under defined culture conditions imposing specific fates. We found that the proportion of cells maintaining an HSC phenotype decreased with increasing number of cell divisions, supporting the notion that faster cycling results in HSC exhaustion. In the second part of this thesis, we for the first time identify a link between mitochondrial metabolism and HSC fate decision. Using flow cytometry and long-term blood reconstitution assays low mitochondrial activity was established as a reliable marker of functional HSCs, independent of their cell cycle state. Consequently, we could use this marker to reliable identify self-renewing HSCs from heterogeneous in vitro cultures. Strikingly, we found that HSC fate could be altered by artificially modulating their mitochondrial activity in vitro. These results suggest that mitochondrial activity is a determinant of HSC fate. The last part of this thesis describes an experimental paradigm to analyze in vivo niche-instructed fate choices in paired HSC daughter cells. Live single cell imaging revealed a significant increase in asynchronous divisions in niche activated HSCs compared to control cells, suggesting a possible involvement of niche-instructed asymmetric cell division program. Indeed, a significantly higher level of asymmetric gene expression was found in paired daughter cells arising from niche-instructed HSCs. This analysis led to the identification of 12 asymmetrically expressed genes, among them were key enzymes belonging to glycolytic and mitochondrial TCA cycle metabolic pathways. Altogether, this thesis successfully employed unique experimental strategies to provide an intriguing link between metabolism and HSC fate choices.

EPFL2015

Metabolic and microenvironmental strategies to accelerate hematopoietic recovery post-aplasia

Vasco Ledebur de Antas de Campos

The procedure-associated mortality rate of bone marrow transplantations (BMT) remains close to 25%. The BMT is therefore only indicated for life-threatening diseases, with no replacement of this technology to be expected in the foreseeable future. Modest improvements such as the use of G-CSF to accelerate hematopoietic recovery significantly reduce mortality. Hematopoietic stem cells (HSC) reside in the bone marrow (BM) and are mainly quiescent, dividing only to self-renew. Via extracellular signals and interactions with other cells of the BM (microenvironment), a stable HSC pool is maintained, while hematopoietic progenitor cells (HPC) proliferate and differentiate to mature blood cell types. Marrow adipocytes (BMA) have recently been recognized as a hematopoietic regulatory entity, although the mechanisms by which it interacts with HSCs and HPCs (HSPC) in vivo, remain unknown. During the hematopoietic recovery period post-BMT, HSPCs increase their metabolism as a response to hematopoietic stress, partly modulated by the microenvironment. In this work we identified novel pharmacological approaches to accelerate hematopoietic recovery in the post-BMT period, addressed via two strategies: (i) by directly modulating HSC metabolism, and (ii) by regulating the differentiation of BMA. Increasing oxidative phosphorylation, combined with an impaired mitochondrial stress response, can severely compromise the regenerative capacity of HSCs. Here we demonstrate that the NAD+-boosting agent Nicotinamide Riboside (NR) reduces mitochondrial activity within HSCs through increased mitophagy, the recycling mechanism of damaged mitochondria. We observed in vitro NR treatment of HSCs to lead to increased asymmetric HSC divisions, which resulted in a significantly enlarged pool of progenitor cells, without HSC exhaustion. Dietary supplementation of NR to mice undergoing BMT accelerated blood recovery and improved survival. We therefore established a novel link between HSC mitochondrial stress, mitophagy and stem cell fate decision. Recent studies have suggested BMA maintain HSCs quiescent, which, may be detrimental to the increased expansion of HPCs in the recovery phase post-BMT. BM stromal cells (BMSC) are the cellular precursors of both adipocytes and osteoblasts, and they have been strongly implicated in supporting hematopoiesis by secreting cytokines such as SCF and Cxcl12. We observed that adipocytes quickly accumulate the marrow space of mice undergoing BMT, followed by an expansion hematopoiesis-supportive multipotent Sca1+/CD24+ stromal cells, coinciding with hematopoietic recovery. We developed a novel screening platform using Digital Holographic Microscopy (DHM), quantifying in vitro adipocytic differentiation non-invasively, allowing for follow-up co-cultures with HSPCs. Using the OP9 BMSC-line, we modulated adipocyte differentiation prior to co-culture using a pharmacological approach and observed that high adipocytic content was associated to a decrease in HPC expansion. We perfomed a screening of over 4000 FDA-approved drugs and natural compounds and identified one to efficiently prevent adipocytic differentiation and maintain the hematopoietic supportive capacity of OP9 stroma. Altogether, this work opens the door to alternative strategies accelerating hematopoietic reconstitution and unveils the potential to improve recovery of patients undergoing BMT.

EPFL2019

Novel tools to dissect stem cell metabolism at single cell level

Gennady Nikitin

Hematopoietic stem cells (HSC) are responsible for the life-long maintenance of our blood system. Their long-term capacity to both self-renew and differentiate and the ability to efficiently âhomeâ to their bone marrow niches when injected in the blood stream, makes these rare cells ideal candidates for transplantation for the treatment of various blood cancers. However, countless attempts to expand HSC in vitro without losing their stem cell potential have failed, which is, to a large extent, linked to our poor understanding of the mechanisms that control HSC fate. Recent discoveries have revealed a crucial role of metabolism in controlling HSC function in vivo. However, because of major technical difficulties, we do not yet know the underlying mechanisms behind the metabolic control of HSC fate. Traditional, population-level experimental approaches link the fate of a stem cell to a cell surface protein expression phenotype. This method does not take into account the large heterogeneity of metabolic states in HSC. Consequently, to get mechanistic insights on HSC fate decision-making, metabolism must be studied at single cell level. Therefore, the overall goal of this thesis is to establish novel tools to study metabolic regulation of HSC at single cell level. Here we specifically focused on two functional metabolic read-outs, protein turnover and mitochondrial pH. Mitochondrial matrix pH is one of the most important functional parameters of mitochondria, as it is directly related to the efficiency of ATP production and thus reflects the metabolic state of the mitochondria. Here, a new ratiometric fluorescent probe, 5FA-PIP-Cy5-DA, able to reliably quantify mitochondrial pH, has been developed. It selectively accumulates in mitochondria of live cells and can be used to sensitively detect mitochondrial pH fluctuations upon various external stimuli. Spectral properties of 5FA-PIP-Cy5-DA allow it to be combined with the total mitochondrial membrane potential-dependent probes, enabling simultaneous imaging of total mitochondrial potential and mitochondrial pH. To complement the data on mitochondrial pH in live cells with an additional independent parameter of mitochondrial metabolism, a method of correlated TEM and nanoscale secondary ion mass-spectrometry (NanoSIMS) imaging was developed, that for the first time allows to study the subcellular protein turnover in single stem cells. Application of these novel tools to study HSC metabolism revealed a striking correlation between the levels of mitochondrial protein turnover and mitochondrial pH. This correlation reflects the burst in mitochondrial metabolism upon HSC activation. Intriguingly, an extreme burst in both mitochondrial pH alkalinization and protein turnover rate was observed for the most potent long-term HSC (LT-HSC) upon their activation and induction of differentiation. A new model is proposed to explain the link between the observed activation of mitochondrial protein structure reorganization and increase in mitochondrial pH level of LT-HSC undergoing differentiation. Finally, to demonstrate the broad range of applicability of the new mitochondrial pH probe, we applied it to measure the impact of anticancer treatment on mitochondrial metabolism in ovarian cancer cells exposed to two anticancer drugs, RAPTA-T and cis-platin. Distinctly different mitochondrial pH responses were measured for these two drugs, revealing alternative mechanisms behind their impact on mitochondria.

EPFL2018