Increasing evidence links metabolism, protein synthesis, and growth signaling to impairments in the function of hematopoietic stem and progenitor cells (HSPC) during aging. The Lin28b/Hmga2 pathway controls tissue development and the postnatal downregulation of this pathway limits the self-renewal of adult vs. fetal hematopoietic stem cells (HSC). Igf2bp2 is an RNA binding protein downstream of Lin28b/Hmga2, which regulates mRNA stability and translation. The role of Igf2bp2 in HSC aging is unknown. Here, we show in an analysis of wildtype and Igf2bp2 knockout mice that Igf2bp2 regulates oxidative metabolism in HSPC and the expression of metabolism, protein synthesis, and stemness-related genes in HSC of young mice. Interestingly, Igf2bp2 expression and function strongly decline in HSC aging. In young mice, Igf2bp2-deletion mimics aging-related changes of HSC, including changes in Igf2bp2-target gene expression and the impairment in colony formation and repopulation capacity. In aged mice, Igf2bp2 gene status has no effect on these parameters in HSC. Unexpectedly, Igf2bp2 deficient mice exhibit an amelioration of the aging-associated increase of HSC numbers and myeloid skewed differentiation. Together, Igf2bp2 controls mitochondrial metabolism, protein synthesis, growth, and stemness of young HSC, which is required for full HSC function at young adult age. However, Igf2bp2 gene function is lost during aging and it appears to contribute to HSC aging in two ways: (i) the aging-related loss of Igf2bp2 gene function impairs the growth and repopulation capacity of aging HSC and (ii) the activity of Igf2bp2 at young age contributes to aging-associated HSC expansion and myeloid skewing.
Cells do not make fate decisions independently. Arguably, every cell-fate decision occurs in response to environmental signals. In many cases, cell-cell communication alters the dynamics of the internal gene regulatory network of a cell to initiate cell-fate transitions, yet models rarely take this into account. Here, we have developed a multiscale perspective to study the granulocyte-monocyte versus megakaryocyte-erythrocyte fate decisions. This transition is dictated by the GATA1-PU.1 network: a classical example of a bistable cell-fate system. We show that, for a wide range of cell communication topologies, even subtle changes in signaling can have pronounced effects on cell-fate decisions. We go on to show how cell-cell coupling through signaling can spontaneously break the symmetry of a homogenous cell population. Noise, both intrinsic and extrinsic, shapes the decision landscape profoundly, and affects the transcriptional dynamics underlying this important hematopoietic cell-fate decision-making system. This article has an associated ‘The people behind the papers’ interview.
Inference of gene regulatory networks (GRNs) to reveal how cell state transitions are controlled is possible with single-cell genomics data. However, obstacles to temporal inference from snapshot data are difficult to overcome. Single-nuclei multiomics data offer means to bridge this gap and derive temporal information from snapshot data using joint measurements of gene expression and chromatin accessibility in the same single cells. We developed popInfer to infer networks that characterize lineage-specific dynamic cell state transitions from joint gene expression and chromatin accessibility data. Benchmarking against alternative methods for GRN inference, we showed that popInfer achieves higher accuracy in the GRNs inferred. popInfer was applied to study single-cell multiomics data characterizing hematopoietic stem cells (HSCs) and the transition from HSC to a multipotent progenitor cell state during murine hematopoiesis across age and dietary conditions. From networks predicted by popInfer, we discovered gene interactions controlling entry to/exit from HSC quiescence that are perturbed in response to diet or aging.
Mammalian organs exhibit distinct physiology, disease susceptibility and injury responses between the sexes. In the mouse kidney, sexually dimorphic gene activity maps predominantly to proximal tubule (PT) segments. Bulk RNA-seq data demonstrated sex differences were established from 4 and 8 weeks after birth under gonadal control. Hormone injection studies and genetic removal of androgen and estrogen receptors demonstrated androgen receptor (AR) mediated regulation of gene activity in PT cells as the regulatory mechanism. Interestingly, caloric restriction feminizes the male kidney. Single-nuclear multiomic analysis identified putative cis-regulatory regions and cooperating factors mediating PT responses to AR activity in the mouse kidney. In the human kidney, a limited set of genes showed conserved sex-linked regulation while analysis of the mouse liver underscored organ-specific differences in the regulation of sexually dimorphic gene expression. These findings raise interesting questions on the evolution, physiological significance, and disease and metabolic linkage, of sexually dimorphic gene activity.
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