Project description:Iron is an irreplaceable co-factor for metabolism and iron deficiency affects >1 billion people, causing anaemia and impairing immunity. How iron deprivation influences normal cellular function remains poorly characterised. In activated CD8+ T-cells we found that iron scarcity profoundly stalled proliferation and disrupted mitochondrial redox control without influencing cell viability. The TCA cycle was partially redirected to a reductive trajectory, and the repressive H3K27me3 histone mark, usually decreased post-activation, was maintained. Surprisingly, aspartate, which is crucial for proliferation, was increased in stalled iron deficient cells but was not utilised cytosolically, indicating trapping within depolarised mitochondria. Exogenous aspartate increased ATP, suppressed H3K27me3 and markedly rescued clonal expansion. We propose that iron scarcity creates a metabolic bottleneck impairing activation and proliferation of T-cells, and which is bypassed by resupplying biochemical processes with aspartate. These findings reveal mechanistic consequences of iron deficiency and shed light on the response of T-cells to nutritional variation.

Project description:Iron is an irreplaceable co-factor for metabolism and iron deficiency affects >1 billion people, causing anaemia and impairing immunity. How iron deprivation influences normal cellular function remains poorly characterised. In activated CD8+ T-cells we found that iron scarcity profoundly stalled proliferation and disrupted mitochondrial redox control without influencing cell viability. The TCA cycle was partially redirected to a reductive trajectory, and the repressive H3K27me3 histone mark, usually decreased post-activation, was maintained. Surprisingly, aspartate, which is crucial for proliferation, was increased in stalled iron deficient cells but was not utilised cytosolically, indicating trapping within depolarised mitochondria. Exogenous aspartate increased ATP, suppressed H3K27me3 and markedly rescued clonal expansion. We propose that iron scarcity creates a metabolic bottleneck impairing activation and proliferation of T-cells, and which is bypassed by resupplying biochemical processes with aspartate. These findings reveal mechanistic consequences of iron deficiency and shed light on the response of T-cells to nutritional variation.

Project description:Iron is an irreplaceable co-factor for metabolism and iron deficiency affects >1 billion people, causing anaemia and impairing immunity. How iron deprivation influences normal cellular function remains poorly characterised. In activated CD8+ T-cells we found that iron scarcity profoundly stalled proliferation and disrupted mitochondrial redox control without influencing cell viability. The TCA cycle was partially redirected to a reductive trajectory, and the repressive H3K27me3 histone mark, usually decreased post-activation, was maintained. Surprisingly, aspartate, which is crucial for proliferation, was increased in stalled iron deficient cells but was not utilised cytosolically, indicating trapping within depolarised mitochondria. Exogenous aspartate increased ATP, suppressed H3K27me3 and markedly rescued clonal expansion. We propose that iron scarcity creates a metabolic bottleneck impairing activation and proliferation of T-cells, and which is bypassed by resupplying biochemical processes with aspartate. These findings reveal mechanistic consequences of iron deficiency and shed light on the response of T-cells to nutritional variation.

Project description:Iron is an irreplaceable co-factor for metabolism and iron deficiency affects >1 billion people, causing anaemia and impairing immunity. How iron deprivation influences normal cellular function remains poorly characterised. In activated CD8+ T-cells we found that iron scarcity profoundly stalled proliferation and disrupted mitochondrial redox control without influencing cell viability. The TCA cycle was partially redirected to a reductive trajectory, and the repressive H3K27me3 histone mark, usually decreased post-activation, was maintained. Surprisingly, aspartate, which is crucial for proliferation, was increased in stalled iron deficient cells but was not utilised cytosolically, indicating trapping within depolarised mitochondria. Exogenous aspartate increased ATP, suppressed H3K27me3 and markedly rescued clonal expansion. We propose that iron scarcity creates a metabolic bottleneck impairing activation and proliferation of T-cells, and which is bypassed by resupplying biochemical processes with aspartate. These findings reveal mechanistic consequences of iron deficiency and shed light on the response of T-cells to nutritional variation.

Project description:Iron is an irreplaceable co-factor for metabolism. Iron deficiency affects >1 billion people and decreased iron availability impairs immunity. Nevertheless, how iron deprivation impacts immune cell function remains poorly characterised. We interrogated how physiologically low iron availability affected CD8+ T cell metabolism and function, using multi-omic and metabolic labelling approaches. Iron limitation did not substantially alter initial post-activation increases in cell size and CD25 upregulation. However, low iron profoundly stalled proliferation (without influencing cell viability), altered histone methylation status, gene expression, and disrupted mitochondrial membrane potential. Glucose and glutamine metabolism in the TCA cycle was limited and partially reversed to a reductive trajectory. Previous studies identified mitochondria-derived aspartate as crucial for proliferation of transformed cells. Surprisingly and despite aberrant TCA cycling, aspartate was increased in stalled iron deficient CD8+ T-cells but was not utilised for nucleotide synthesis, likely due to trapping within depolarised mitochondria. Exogenous aspartate markedly rescued expansion and some functions of severely iron-deficient CD8+ T-cells. Overall, iron scarcity creates a mitochondrial-located metabolic bottleneck, which is bypassed by supplying inhibited biochemical processes with aspartate. These findings reveal molecular consequences of iron deficiency for CD8+ T cell function, providing mechanistic insight into the basis for immune impairment during iron deficiency.

Project description:Iron is an irreplaceable co-factor for metabolism. Iron deficiency affects >1 billion people and decreased iron availability impairs immunity. Nevertheless, how iron deprivation impacts immune cell function remains poorly characterised. We interrogated how physiologically low iron availability affected CD8+ T cell metabolism and function, using multi-omic and metabolic labelling approaches. Iron limitation did not substantially alter initial post-activation increases in cell size and CD25 upregulation. However, low iron profoundly stalled proliferation (without influencing cell viability), altered histone methylation status, gene expression, and disrupted mitochondrial membrane potential. Glucose and glutamine metabolism in the TCA cycle was limited and partially reversed to a reductive trajectory. Previous studies identified mitochondria-derived aspartate as crucial for proliferation of transformed cells. Surprisingly and despite aberrant TCA cycling, aspartate was increased in stalled iron deficient CD8+ T-cells but was not utilised for nucleotide synthesis, likely due to trapping within depolarised mitochondria. Exogenous aspartate markedly rescued expansion and some functions of severely iron-deficient CD8+ T-cells. Overall, iron scarcity creates a mitochondrial-located metabolic bottleneck, which is bypassed by supplying inhibited biochemical processes with aspartate. These findings reveal molecular consequences of iron deficiency for CD8+ T cell function, providing mechanistic insight into the basis for immune impairment during iron deficiency.

Project description:Iron is an irreplaceable co-factor for metabolism. Iron deficiency affects >1 billion people and decreased iron availability impairs immunity. Nevertheless, how iron deprivation impacts immune cell function remains poorly characterised. We interrogated how physiologically low iron availability affected CD8+ T cell metabolism and function, using multi-omic and metabolic labelling approaches. Iron limitation did not substantially alter initial post-activation increases in cell size and CD25 upregulation. However, low iron profoundly stalled proliferation (without influencing cell viability), altered histone methylation status, gene expression, and disrupted mitochondrial membrane potential. Glucose and glutamine metabolism in the TCA cycle was limited and partially reversed to a reductive trajectory. Previous studies identified mitochondria-derived aspartate as crucial for proliferation of transformed cells. Surprisingly and despite aberrant TCA cycling, aspartate was increased in stalled iron deficient CD8+ T-cells but was not utilised for nucleotide synthesis, likely due to trapping within depolarised mitochondria. Exogenous aspartate markedly rescued expansion and some functions of severely iron-deficient CD8+ T-cells. Overall, iron scarcity creates a mitochondrial-located metabolic bottleneck, which is bypassed by supplying inhibited biochemical processes with aspartate. These findings reveal molecular consequences of iron deficiency for CD8+ T cell function, providing mechanistic insight into the basis for immune impairment during iron deficiency.

Project description:Iron is an irreplaceable co-factor for metabolism. Iron deficiency affects >1 billion people and decreased iron availability impairs immunity. Nevertheless, how iron deprivation impacts immune cell function remains poorly characterised. We interrogated how physiologically low iron availability affected CD8+ T cell metabolism and function, using multi-omic and metabolic labelling approaches. Iron limitation did not substantially alter initial post-activation increases in cell size and CD25 upregulation. However, low iron profoundly stalled proliferation (without influencing cell viability), altered histone methylation status, gene expression, and disrupted mitochondrial membrane potential. Glucose and glutamine metabolism in the TCA cycle was limited and partially reversed to a reductive trajectory. Previous studies identified mitochondria-derived aspartate as crucial for proliferation of transformed cells. Surprisingly and despite aberrant TCA cycling, aspartate was increased in stalled iron deficient CD8+ T-cells but was not utilised for nucleotide synthesis, likely due to trapping within depolarised mitochondria. Exogenous aspartate markedly rescued expansion and some functions of severely iron-deficient CD8+ T-cells. Overall, iron scarcity creates a mitochondrial-located metabolic bottleneck, which is bypassed by supplying inhibited biochemical processes with aspartate. These findings reveal molecular consequences of iron deficiency for CD8+ T cell function, providing mechanistic insight into the basis for immune impairment during iron deficiency.

Project description:Iron is a biochemically critical metal cofactor in enzymes involved in photosynthesis, respiration, nitrate assimilation, nitrogen fixation, and reactive oxygen species defense. Marine microeukaryotes have evolved a phytotransferrin-based iron uptake system to cope with iron scarcity, a major factor limiting primary productivity in the global ocean. Diatom phytotransferrin is internalized via endocytosis, however proteins downstream of this environmentally ubiquitous iron receptor are unknown. We applied engineered ascorbate peroxidase APEX2-based subcellular proteomics to catalog proximal proteins of phytotransferrin in the model diatom Phaeodactylum tricornutum. Proteins encoded by poorly characterized iron-sensitive genes were identified including three that are expressed from a chromosomal gene cluster. Two of them showed unambiguous colocalization with phytotransferrin adjacent to the chloroplast. Further phylogenetic, domain, and biochemical analyses suggest their involvement in intracellular iron processing. Proximity proteomics holds enormous potential to glean new insights into iron acquisition pathways and beyond in these evolutionarily, ecologically, and biotechnologically important microalgae.

Project description:Human neutrophilic granulocytes form the largest pool of innate immune cells for host defense against bacterial and fungal pathogens. The dynamic changes that accompany the metamorphosis from a proliferating myeloid progenitor cell in the bone marrow into a mature non-dividing polymorphonuclear blood cell have remained poorly defined. Using mass spectrometry-based quantitative proteomics combined with transcriptomic data, we report on the dynamic changes of 5 developmental stages in the bone marrow and blood. Integration of transcriptomic and proteomic unveiled highly dynamic and differential interactions between RNA and protein kinetics during human neutrophil development which could be linked to functional maturation of typical end-stage blood neutrophil killing activities.