Glucose is a major source of energy for living organisms and its transport in vertebrates is a un... more Glucose is a major source of energy for living organisms and its transport in vertebrates is a universally conserved property. Of all cell lineages, human erythrocytes express the highest level of the Glut1 glucose transporter with >200,000 molecules/cell. However, we recently reported that erythrocyte Glut1 expression is a specific trait of vitamin C-deficient mammalian species, comprising only higher primates, guinea pigs and fruit bats (Montel-Hagen et al., Cell, 2008). We now show that in all other tested mammals, including mice, rats, dogs and cows, Glut1 is in fact transiently expressed in erythrocytes during the neonatal period. This is in marked contrast with humans, where Glut1 is present at equivalently high levels on both neonatal and adult RBC. In mice, we found that Glut1 expression was not associated with primitive erythropoiesis but was highly expressed during definitive fetal erythropoiesis. Indeed, this transporter was present at significantly earlier stages of erythropoiesis in fetal spleen and liver than immediately following birth. It was therefore important to determine whether erythrocyte Glut1 expression in mice is specifically associated with fetal erythropoiesis or alternatively, is common to any physiological state where an extensive erythropoiesis is provoked. Induction of a hemolytic anemia in adult mice resulted in a massive erythropoiesis with significant increase in glucose uptake but notably, Glut1 was not detected. Rather, in these conditions as well as following birth, Glut4, an insulin-sensitive transporter previously thought to be responsible for glucose uptake in muscle and adipose tissue, was highly expressed. Following birth, the concomitant repression of Glut1 and induction of Glut4 was associated with a significantly augmented ratio of the Sp3 to Sp1 zinc-finger transcription factors. Thus, in contrast to humans, murine Glut1 is highly expressed during definitive erythropoiesis and is then downregulated at birth. Further erythroid development is characterized by the upregulation of a distinct glucose transporter, Glut4. Expression of distinct glucose transporters in nonhuman erythrocytes, regulated at the transcriptional level, therefore characterizes different states of erythroid development and differentiation.
Recent studies have documented that cell metabolism regulates hematopoietic stem cell (HSC) renew... more Recent studies have documented that cell metabolism regulates hematopoietic stem cell (HSC) renewal and lineage commitment. However, the detailed metabolic changes that occur during human erythropoiesis remain to be defined. As erythroid cell differentiation is likely to be associated with changes in metabolic requirements, we hypothesized that progenitors adapt to these metabolic modulations by altering their nutrient transporter expression profile. Using an in vitro erythroid-inducing cell culture system employing CD34+ cells from human bone marrow and peripheral blood as well as primary erythroid cells isolated from fresh bone marrow samples, we assessed the cell surface nutrient transporter profiles of progenitors at different stages of erythroid development. Quantification of cell surface nutrient transporter expression was performed using a novel scaffold of retroviral envelope receptor binding domains (RBDs) that function as specific ligands of solute carrier (SLC) nutrient transporters. This bank allowed an evaluation of diverse metabolite transporters including GLUT1/SLC2A1 glucose transporter, the PiT1/SLC20A1 and PiT2/SLC20A2 phosphate importers, the XPR1/SLC53A1 phosphate exporter, the FLVCR1 heme exporter, the RFVT1/2 (SLC52A1/SLC52A2) riboflavin importers, the CAT1/SLC7A1 arginine importer, the ASCT2/SLC1A5 glutamine transporter and the SMVT/SLC5A6 sodium-dependent multivitamin transporter. Notably, the cell surface expression profiles of these nutrient transporters, as evaluated by flow cytometry, revealed marked changes as a function of the stage of erythroid differentiation, as shown in the figure below. Specifically, while FLVCR1, RFVT1/2, and SMVT are highly expressed on erythroid progenitors, the levels of these transporters decrease starting at the proerythroblast stage. In addition, PiT1, PiT2, XPR1, and CAT1 are expressed highly during the erythroid colony forming unit (CFU-E) stage while GLUT1 gradually increases and reaches a peak at late stages of erythroid differentiation, remaining elevated on mature red cells. The noted distinct changes in transporter expression are likely a reflection of the changing demands of various nutrients during human erythropoiesis. In summary, we have established a comprehensive metabolite transporter profile at distinct stages of normal human erythropoiesis using a novel experimental strategy. These original findings form a strong foundation for future studies aiming at elucidating the metabolic requirements of normal erythropoiesis, evaluating diseases affecting red blood cell maturation due to aberrant metabolic regulation, and for identifying new therapeutic targets. Figure Disclosures Bitaudeau: Metafora-biosystems: Employment. Petit:Metafora-biosystems: Equity Ownership, Other: CEO and co-founder. Sitbon:Metafora-biosystems: Membership on an entity's Board of Directors or advisory committees, Other: Co-founder.
Metabolic programs contribute to hematopoietic stem and progenitor cell (HSPC) fate, but it is no... more Metabolic programs contribute to hematopoietic stem and progenitor cell (HSPC) fate, but it is not known whether the metabolic regulation of protein synthesis controls HSPC differentiation. Here, we show that SLC7A1/CAT1-dependent arginine uptake and its catabolism to the polyamine spermidine control human erythroid specification of HSPCs via activation of the eukaryotic translation initiation factor 5A (eIF5A). eIF5A activity is dependent on its hypusination, a post-translational modification resulting from the conjugation of the aminobutyl moiety of spermidine to lysine. Notably, attenuation of hypusine synthesis in erythroid progenitors--by inhibition of deoxyhypusine synthase--abrogates erythropoiesis but not myeloid cell differentiation. Proteomic profiling reveals mitochondrial translation to be a critical target of hypusinated eIF5A and accordingly, progenitors with decreased hypusine activity exhibit diminished oxidative phosphorylation. This impacted pathway is critical for eIF5A-regulated erythropoiesis as interventions augmenting mitochondrial function partially rescue human erythropoiesis under conditions of attenuated hypusination. Levels of mitochondrial ribosomal proteins were especially sensitive to the loss of hypusine and we find that the ineffective erythropoiesis linked to haploinsufficiency of RPS14 in del(5q) myelodysplastic syndrome is associated with a diminished pool of hypusinated eIF5A. Moreover, patients with RPL11-haploinsufficient Diamond-Blackfan anemia as well as CD34+ progenitors with downregulated RPL11 exhibit a markedly decreased hypusination in erythroid progenitors, concomitant with a loss of mitochondrial metabolism. Thus, eIF5A-dependent protein synthesis regulates human erythropoiesis and our data reveal a novel role for RPs in controlling eIF5A hypusination in HSPC, synchronizing mitochondrial metabolism with erythroid differentiation.
The metabolic changes controlling the step-wise differentiation of human stem and progenitor cell... more The metabolic changes controlling the step-wise differentiation of human stem and progenitor cells (HSPC) to mature erythrocytes are poorly understood. Here, we show that HSPC development to an erythroid-committed proerythroblast results in augmented glutaminolysis, generating alpha-ketoglutarate (αKG) and driving mitochondrial oxidative phosphorylation (OXPHOS). However, sequential late-stage erythropoiesis is dependent on decreasing αKG-driven OXPHOS, and we find that isocitrate dehydrogenase (IDH1) plays a central role in this process. IDH1 downregulation augmented mitochondrial oxidation of αKG and inhibited reticulocyte generation. Furthermore, IDH1-knockdown resulted in the generation of multinucleated erythroblasts, a morphological abnormality characteristic of myelodysplastic syndrome and congenital dyserythropoietic anemia. We identify vitamin C homeostasis as a critical regulator of ineffective erythropoiesis –– oxidized ascorbate increased mitochondrial superoxide and significantly exacerbated the abnormal erythroblast phenotype of IDH1-downregulated progenitors whereas vitamin C, scavenging reactive oxygen species and reprogramming mitochondrial metabolism, rescued erythropoiesis. Thus, an IDH1-vitamin C crosstalk controls terminal steps of human erythroid differentiation.
The tight regulation of intracellular nucleotides is critical for the self-renewal and lineage sp... more The tight regulation of intracellular nucleotides is critical for the self-renewal and lineage specification of hematopoietic stem cells (HSCs). Nucleosides are major metabolite precursors for nucleotide biosynthesis and their availability in HSCs is dependent on their transport through specific membrane transporters. However, the role of nucleoside transporters in the differentiation of HSCs to the erythroid lineage and in red cell biology remains to be fully defined. Here, we show that the absence of the equilibrative nucleoside transporter (ENT1) in human red blood cells with a rare Augustine-null blood type is associated with macrocytosis, anisopoikilocytosis, an abnormal nucleotide metabolome, and deregulated protein phosphorylation. A specific role for ENT1 in human erythropoiesis was demonstrated by a defective erythropoiesis of human CD34+ progenitors following short hairpin RNA-mediated knockdown of ENT1. Furthermore, genetic deletion of ENT1 in mice was associated with red...
Primary familial brain calcification (PFBC) is a neurological disease characterized by calcium ph... more Primary familial brain calcification (PFBC) is a neurological disease characterized by calcium phosphate deposits in the basal ganglia and other brain regions and has thus far been associated with SLC20A2, PDGFB or PDGFRB mutations. We identified in multiple families with PFBC mutations in XPR1, a gene encoding a retroviral receptor with phosphate export function. These mutations alter phosphate export, implicating XPR1 and phosphate homeostasis in PFBC.
Solute carrier family 20 member 2 (SLC20A2) and xenotropic and polytropic retrovirus receptor 1 (... more Solute carrier family 20 member 2 (SLC20A2) and xenotropic and polytropic retrovirus receptor 1 (XPR1) are transporters with phosphate uptake and efflux functions, respectively. Both are associated with primary familial brain calcification (PFBC), a genetic disease characterized by cerebral calcium-phosphate deposition and associated with neuropsychiatric symptoms. The association of the two transporters in the same disease suggests that they jointly regulate phosphate fluxes and cellular homeostasis, but direct evidence is missing. Here, we found that cross-talk between SLC20A2 and XPR1 regulates phosphate homeostasis and identify XPR1 as a key inositol polyphosphate (IP)-dependent regulator of this process. We found that overexpression of wildtype SLC20A2 increases phosphate uptake as expected, but also unexpectedly increases phosphate efflux, whereas PFBC-associated SLC20A2 variants did not. Conversely, SLC20A2 depletion decreased phosphate uptake only slightly, most likely compe...
Glucose is a major source of energy for living organisms and its transport in vertebrates is a un... more Glucose is a major source of energy for living organisms and its transport in vertebrates is a universally conserved property. Of all cell lineages, human erythrocytes express the highest level of the Glut1 glucose transporter with >200,000 molecules/cell. However, we recently reported that erythrocyte Glut1 expression is a specific trait of vitamin C-deficient mammalian species, comprising only higher primates, guinea pigs and fruit bats (Montel-Hagen et al., Cell, 2008). We now show that in all other tested mammals, including mice, rats, dogs and cows, Glut1 is in fact transiently expressed in erythrocytes during the neonatal period. This is in marked contrast with humans, where Glut1 is present at equivalently high levels on both neonatal and adult RBC. In mice, we found that Glut1 expression was not associated with primitive erythropoiesis but was highly expressed during definitive fetal erythropoiesis. Indeed, this transporter was present at significantly earlier stages of erythropoiesis in fetal spleen and liver than immediately following birth. It was therefore important to determine whether erythrocyte Glut1 expression in mice is specifically associated with fetal erythropoiesis or alternatively, is common to any physiological state where an extensive erythropoiesis is provoked. Induction of a hemolytic anemia in adult mice resulted in a massive erythropoiesis with significant increase in glucose uptake but notably, Glut1 was not detected. Rather, in these conditions as well as following birth, Glut4, an insulin-sensitive transporter previously thought to be responsible for glucose uptake in muscle and adipose tissue, was highly expressed. Following birth, the concomitant repression of Glut1 and induction of Glut4 was associated with a significantly augmented ratio of the Sp3 to Sp1 zinc-finger transcription factors. Thus, in contrast to humans, murine Glut1 is highly expressed during definitive erythropoiesis and is then downregulated at birth. Further erythroid development is characterized by the upregulation of a distinct glucose transporter, Glut4. Expression of distinct glucose transporters in nonhuman erythrocytes, regulated at the transcriptional level, therefore characterizes different states of erythroid development and differentiation.
Recent studies have documented that cell metabolism regulates hematopoietic stem cell (HSC) renew... more Recent studies have documented that cell metabolism regulates hematopoietic stem cell (HSC) renewal and lineage commitment. However, the detailed metabolic changes that occur during human erythropoiesis remain to be defined. As erythroid cell differentiation is likely to be associated with changes in metabolic requirements, we hypothesized that progenitors adapt to these metabolic modulations by altering their nutrient transporter expression profile. Using an in vitro erythroid-inducing cell culture system employing CD34+ cells from human bone marrow and peripheral blood as well as primary erythroid cells isolated from fresh bone marrow samples, we assessed the cell surface nutrient transporter profiles of progenitors at different stages of erythroid development. Quantification of cell surface nutrient transporter expression was performed using a novel scaffold of retroviral envelope receptor binding domains (RBDs) that function as specific ligands of solute carrier (SLC) nutrient transporters. This bank allowed an evaluation of diverse metabolite transporters including GLUT1/SLC2A1 glucose transporter, the PiT1/SLC20A1 and PiT2/SLC20A2 phosphate importers, the XPR1/SLC53A1 phosphate exporter, the FLVCR1 heme exporter, the RFVT1/2 (SLC52A1/SLC52A2) riboflavin importers, the CAT1/SLC7A1 arginine importer, the ASCT2/SLC1A5 glutamine transporter and the SMVT/SLC5A6 sodium-dependent multivitamin transporter. Notably, the cell surface expression profiles of these nutrient transporters, as evaluated by flow cytometry, revealed marked changes as a function of the stage of erythroid differentiation, as shown in the figure below. Specifically, while FLVCR1, RFVT1/2, and SMVT are highly expressed on erythroid progenitors, the levels of these transporters decrease starting at the proerythroblast stage. In addition, PiT1, PiT2, XPR1, and CAT1 are expressed highly during the erythroid colony forming unit (CFU-E) stage while GLUT1 gradually increases and reaches a peak at late stages of erythroid differentiation, remaining elevated on mature red cells. The noted distinct changes in transporter expression are likely a reflection of the changing demands of various nutrients during human erythropoiesis. In summary, we have established a comprehensive metabolite transporter profile at distinct stages of normal human erythropoiesis using a novel experimental strategy. These original findings form a strong foundation for future studies aiming at elucidating the metabolic requirements of normal erythropoiesis, evaluating diseases affecting red blood cell maturation due to aberrant metabolic regulation, and for identifying new therapeutic targets. Figure Disclosures Bitaudeau: Metafora-biosystems: Employment. Petit:Metafora-biosystems: Equity Ownership, Other: CEO and co-founder. Sitbon:Metafora-biosystems: Membership on an entity's Board of Directors or advisory committees, Other: Co-founder.
Metabolic programs contribute to hematopoietic stem and progenitor cell (HSPC) fate, but it is no... more Metabolic programs contribute to hematopoietic stem and progenitor cell (HSPC) fate, but it is not known whether the metabolic regulation of protein synthesis controls HSPC differentiation. Here, we show that SLC7A1/CAT1-dependent arginine uptake and its catabolism to the polyamine spermidine control human erythroid specification of HSPCs via activation of the eukaryotic translation initiation factor 5A (eIF5A). eIF5A activity is dependent on its hypusination, a post-translational modification resulting from the conjugation of the aminobutyl moiety of spermidine to lysine. Notably, attenuation of hypusine synthesis in erythroid progenitors--by inhibition of deoxyhypusine synthase--abrogates erythropoiesis but not myeloid cell differentiation. Proteomic profiling reveals mitochondrial translation to be a critical target of hypusinated eIF5A and accordingly, progenitors with decreased hypusine activity exhibit diminished oxidative phosphorylation. This impacted pathway is critical for eIF5A-regulated erythropoiesis as interventions augmenting mitochondrial function partially rescue human erythropoiesis under conditions of attenuated hypusination. Levels of mitochondrial ribosomal proteins were especially sensitive to the loss of hypusine and we find that the ineffective erythropoiesis linked to haploinsufficiency of RPS14 in del(5q) myelodysplastic syndrome is associated with a diminished pool of hypusinated eIF5A. Moreover, patients with RPL11-haploinsufficient Diamond-Blackfan anemia as well as CD34+ progenitors with downregulated RPL11 exhibit a markedly decreased hypusination in erythroid progenitors, concomitant with a loss of mitochondrial metabolism. Thus, eIF5A-dependent protein synthesis regulates human erythropoiesis and our data reveal a novel role for RPs in controlling eIF5A hypusination in HSPC, synchronizing mitochondrial metabolism with erythroid differentiation.
The metabolic changes controlling the step-wise differentiation of human stem and progenitor cell... more The metabolic changes controlling the step-wise differentiation of human stem and progenitor cells (HSPC) to mature erythrocytes are poorly understood. Here, we show that HSPC development to an erythroid-committed proerythroblast results in augmented glutaminolysis, generating alpha-ketoglutarate (αKG) and driving mitochondrial oxidative phosphorylation (OXPHOS). However, sequential late-stage erythropoiesis is dependent on decreasing αKG-driven OXPHOS, and we find that isocitrate dehydrogenase (IDH1) plays a central role in this process. IDH1 downregulation augmented mitochondrial oxidation of αKG and inhibited reticulocyte generation. Furthermore, IDH1-knockdown resulted in the generation of multinucleated erythroblasts, a morphological abnormality characteristic of myelodysplastic syndrome and congenital dyserythropoietic anemia. We identify vitamin C homeostasis as a critical regulator of ineffective erythropoiesis –– oxidized ascorbate increased mitochondrial superoxide and significantly exacerbated the abnormal erythroblast phenotype of IDH1-downregulated progenitors whereas vitamin C, scavenging reactive oxygen species and reprogramming mitochondrial metabolism, rescued erythropoiesis. Thus, an IDH1-vitamin C crosstalk controls terminal steps of human erythroid differentiation.
The tight regulation of intracellular nucleotides is critical for the self-renewal and lineage sp... more The tight regulation of intracellular nucleotides is critical for the self-renewal and lineage specification of hematopoietic stem cells (HSCs). Nucleosides are major metabolite precursors for nucleotide biosynthesis and their availability in HSCs is dependent on their transport through specific membrane transporters. However, the role of nucleoside transporters in the differentiation of HSCs to the erythroid lineage and in red cell biology remains to be fully defined. Here, we show that the absence of the equilibrative nucleoside transporter (ENT1) in human red blood cells with a rare Augustine-null blood type is associated with macrocytosis, anisopoikilocytosis, an abnormal nucleotide metabolome, and deregulated protein phosphorylation. A specific role for ENT1 in human erythropoiesis was demonstrated by a defective erythropoiesis of human CD34+ progenitors following short hairpin RNA-mediated knockdown of ENT1. Furthermore, genetic deletion of ENT1 in mice was associated with red...
Primary familial brain calcification (PFBC) is a neurological disease characterized by calcium ph... more Primary familial brain calcification (PFBC) is a neurological disease characterized by calcium phosphate deposits in the basal ganglia and other brain regions and has thus far been associated with SLC20A2, PDGFB or PDGFRB mutations. We identified in multiple families with PFBC mutations in XPR1, a gene encoding a retroviral receptor with phosphate export function. These mutations alter phosphate export, implicating XPR1 and phosphate homeostasis in PFBC.
Solute carrier family 20 member 2 (SLC20A2) and xenotropic and polytropic retrovirus receptor 1 (... more Solute carrier family 20 member 2 (SLC20A2) and xenotropic and polytropic retrovirus receptor 1 (XPR1) are transporters with phosphate uptake and efflux functions, respectively. Both are associated with primary familial brain calcification (PFBC), a genetic disease characterized by cerebral calcium-phosphate deposition and associated with neuropsychiatric symptoms. The association of the two transporters in the same disease suggests that they jointly regulate phosphate fluxes and cellular homeostasis, but direct evidence is missing. Here, we found that cross-talk between SLC20A2 and XPR1 regulates phosphate homeostasis and identify XPR1 as a key inositol polyphosphate (IP)-dependent regulator of this process. We found that overexpression of wildtype SLC20A2 increases phosphate uptake as expected, but also unexpectedly increases phosphate efflux, whereas PFBC-associated SLC20A2 variants did not. Conversely, SLC20A2 depletion decreased phosphate uptake only slightly, most likely compe...
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