Project description:The molecular mechanisms that drive hematopoietic stem cell (HSC) functional decline under conditions of stress are not completely understood. Here, in light of the recent advances in single-cell technologies, we sought to redefine the transcriptional and epigenetic landscape of mouse and human hematopoietic stem cells (HSCs) under telomeric stress, as that induced by pathogenic germline mutations in telomerase complex genes. These analyses revealed that telomere attrition maintains HSCs in a state of persistent metabolic activation and differentiation towards the megakaryocytic lineage through the cell-intrinsic upregulation of interferon (IFN) signaling response, which directly comprises HSCs’ self-renewal capabilities and eventually leads to their exhaustion. Telomerase reactivation completely restored HSC transcriptional homeostasis at the single-cell level, overcame enhanced megakaryocytic differentiation and significantly ameliorated HSCs’ repopulation capacity in the setting of competitive transplantation, suggesting that HSCs can repristinate their function upon telomere damage resolution. This study challenges the long-standing hypothesis that telomere attrition limits the proliferative potential of HSCs by inducing apoptosis or senescence and suggests that early intervention targeting the IFN axis could prevent bone marrow failure syndromes in patients with pathogenic mutations affecting telomere maintenance.

Project description:Molecular distinctions between the stasis and telomere attrition senescence barriers in cultured human mammary epithelial cells Normal human epithelial cells in culture have generally shown a limited proliferative potential of ~10-40 population doublings before encountering a stress-associated senescence barrier (stasis) associated with elevated levels of cyclin-dependent kinase inhibitors p16 and/or p21. We now show that simple changes in media composition can expand the proliferative potential of human mammary epithelial cells (HMEC) initiated as primary cultures to 50-60 population doublings, followed by p16(+), senescence-associated b-galactosidase(+) stasis. We compared the properties of growing and senescent pre-stasis HMEC with growing and senescent post-selection HMEC, i.e., cells grown in a serum-free medium that overcame stasis via silencing of p16 expression and that display senescence associated with telomere dysfunction. Cultured pre-stasis populations contained cells expressing markers associated with luminal and myoepithelial HMEC lineages in vivo, in contrast to the basal-like phenotype of the post-selection HMEC. Gene transcript and protein expression, DNA damage-associated markers, mean TRF length, and genomic stability, differed significantly between HMEC populations at the stasis vs. telomere attrition senescence barriers. Senescent isogenic fibroblasts showed greater similarity to HMEC at stasis than at telomere attrition, although their gene transcript profile was distinct from HMEC at both senescence barriers. These studies support our model of the senescence barriers encountered by cultured HMEC in which the first barrier, stasis, is Rb-mediated and independent of telomere length, while a second barrier (agonescence or crisis) results from telomere attrition leading to telomere dysfunction. Additionally, the ability to maintain long-term growth of genomically stable multi-lineage pre-stasis HMEC populations can greatly enhance experimentation with normal HMEC. 48 samples from Human Mammary Epithelial cells which includes samples from four different individuals at different passage levels which includes prestasis,intermediate,post selection and agonesence stages of cell cycle.

Project description:Aged hematopoietic stem cells (HSC) display diminished self-renewal and a myeloid differentiation bias. However, the physiological drivers and molecular processes that underpin this fundamental switch are not understood. HSCs produce formaldehyde and are protected from this metabolite by two tiers of protection: the detoxification enzymes ALDH2 and ADH5 and the Fanconi anemia (FA) DNA repair pathway. Using single cell RNA sequencing, we find that the HSC and progenitor cells in young Aldh2-/- Fancd2-/- mice harbor a transcriptomic signature equivalent to aged wild-type HSCs, along with increased epigenetic age, telomere attrition and myeloid-biased progenitors. In addition, the p53 response is vigorously activated in Aldh2-/- Fancd2-/- HSCs, whilst p53 deletion rescued this aged transcriptomic signature and telomere attrition. Transplantation of single Aldh2-/- Fancd2-/- HSCs also reveals a predominantly myeloid output, which is reversed upon p53 deletion. To further define the origins of the myeloid differentiation bias, a GFP genetic reporter which detects Vwf+ myeloid primed HSCs was crossed into Aldh2-/- Fancd2-/- mice, revealing a striking enrichment of these lineage-biased Vwf+ HSCs. These results indicate that metabolism derived formaldehyde causes endogenous DNA damage which stimulates the p53 response in HSCs, which then accelerates their aging, resulting in a myeloid lineage biased output.

Project description:Molecular distinctions between the stasis and telomere attrition senescence barriers in cultured human mammary epithelial cells Normal human epithelial cells in culture have generally shown a limited proliferative potential of ~10-40 population doublings before encountering a stress-associated senescence barrier (stasis) associated with elevated levels of cyclin-dependent kinase inhibitors p16 and/or p21. We now show that simple changes in media composition can expand the proliferative potential of human mammary epithelial cells (HMEC) initiated as primary cultures to 50-60 population doublings, followed by p16(+), senescence-associated b-galactosidase(+) stasis. We compared the properties of growing and senescent pre-stasis HMEC with growing and senescent post-selection HMEC, i.e., cells grown in a serum-free medium that overcame stasis via silencing of p16 expression and that display senescence associated with telomere dysfunction. Cultured pre-stasis populations contained cells expressing markers associated with luminal and myoepithelial HMEC lineages in vivo, in contrast to the basal-like phenotype of the post-selection HMEC. Gene transcript and protein expression, DNA damage-associated markers, mean TRF length, and genomic stability, differed significantly between HMEC populations at the stasis vs. telomere attrition senescence barriers. Senescent isogenic fibroblasts showed greater similarity to HMEC at stasis than at telomere attrition, although their gene transcript profile was distinct from HMEC at both senescence barriers. These studies support our model of the senescence barriers encountered by cultured HMEC in which the first barrier, stasis, is Rb-mediated and independent of telomere length, while a second barrier (agonescence or crisis) results from telomere attrition leading to telomere dysfunction. Additionally, the ability to maintain long-term growth of genomically stable multi-lineage pre-stasis HMEC populations can greatly enhance experimentation with normal HMEC.

Project description:Telomere erosion contributes to age-associated tissue dysfunction and senescence, and p53 plays a crucial role in this response. We undertook a genome-wide screen to identify gene deletions that sensitized p53-positive human cells to loss of telomere integrity, and uncovered a previously unannotated gene, C16ORF72, which we term Telomere Attrition and p53 Response 1: TAPR1. CRISPR-Cas9 mediated deletion of TAPR1 led to elevated p53 and induction of p53 transcriptional targets. TAPR1-disrupted cells exhibited a synthetic-sick relationship with the loss of telomerase, or treatment with the topoisomerase II inhibitor doxorubicin. Stabilization of p53 with nutlin-3a further decreased cell fitness in cells lacking TAPR1 or telomerase, whereas deletion of TP53 rescued the decreased fitness of TAPR1-deleted cells. We propose that TAPR1 regulates p53 turnover, thereby tapering the p53-dependent response to telomere erosion. We discuss the possible implications of such a mechanism in the preservation of genome integrity during senescence or aging.

Project description:Telomere shortening in populations of human mammary epithelial cells (HMECs) that survive early replicative arrest (M0) by the inactivation of p16INK4A during cell culture on plastic dishes leads to a state of permanent replicative arrest termed senescence. While culture of HMECs on feeder layers abrogates M0 and p16INK4A inactivation, progressive telomere attrition in these cells also eventually results in permanent replicative arrest. Expression of telomerase prevents both senescence on plastic (S-P) and senescence on feeder layers (S-FL) in HMECs, as it does also in cultured primary human fibroblasts. We report here that the gene expression profiles of senescence in HMECs of the same lineage maintained under different culture conditions showed surprisingly little commonality. Moreover, neither of these senescence-associated profiles in HMECs resembles the profile for senescence in human fibroblasts. These results indicate that senescence-associated alterations in gene expression resulting from telomere attrition are affected by culture conditions as well as by cell origins, and argue that replicative senescence at the molecular level is a diverse rather than unique cellular process.

Project description:Telomere shortening in populations of human mammary epithelial cells (HMECs) that survive early replicative arrest (M0) by the inactivation of p16INK4A during cell culture on plastic dishes leads to a state of permanent replicative arrest termed senescence. While culture of HMECs on feeder layers abrogates M0 and p16INK4A inactivation, progressive telomere attrition in these cells also eventually results in permanent replicative arrest. Expression of telomerase prevents both senescence on plastic (S-P) and senescence on feeder layers (S-FL) in HMECs, as it does also in cultured primary human fibroblasts. We report here that the gene expression profiles of senescence in HMECs of the same lineage maintained under different culture conditions showed surprisingly little commonality. Moreover, neither of these senescence-associated profiles in HMECs resembles the profile for senescence in human fibroblasts. These results indicate that senescence-associated alterations in gene expression resulting from telomere attrition are affected by culture conditions as well as by cell origins, and argue that replicative senescence at the molecular level is a diverse rather than unique cellular process.

Project description:Adult hematopoietic stem cells (HSCs) are predominantly quiescent and can be activated in response to acute stress such as infection or cytotoxic insults. STAT1 is a pivotal mediator of interferon (IFN) signaling and is required for IFN-induced HSC proliferation, but the downstream mechanisms remain unclear and in particular little is known about the role of STAT1 in regulating hematopoietic stem/progenitor cells during homeostasis. Here we show that loss of STAT1 alters the steady state hematopoietic stem and progenitor (HSPC) landscape, impairs HSC function in transplantation assays and delays blood cell regeneration following myeloablation. Under steady state conditions STAT1 was essential for several HSC transcriptional programs including expression of genes involved in virus life cycle, a subset of interferon-stimulated genes, MHC class I genes and genes involved in cell cycle arrest. In addition Stat-1 deficient mice lacked a previously unrecognized quiescent subset of homeostatic HSCs with high levels of MHC II expression (MHC IIhi HSCs). This subset was refractory to 5’-FU induced myeloablation and displayed reduced megakaryocytic potential. Mutant calreticulin, which causes increased megakaryopoiesis in human myeloproliferative neoplasms, gave rise to preferential expansion of MHC IIlo HSCs. These data reveal a STAT1 dependent MHC IIhi quiescent HSC subset and show that STAT1 protects HSCs from proliferative exhaustion.

Project description:Adult hematopoietic stem cells (HSCs) are predominantly quiescent and can be activated in response to acute stress such as infection or cytotoxic insults. STAT1 is a pivotal mediator of interferon (IFN) signaling and is required for IFN-induced HSC proliferation, but the downstream mechanisms remain unclear and in particular little is known about the role of STAT1 in regulating hematopoietic stem/progenitor cells during homeostasis. Here we show that loss of STAT1 alters the steady state hematopoietic stem and progenitor (HSPC) landscape, impairs HSC function in transplantation assays and delays blood cell regeneration following myeloablation. Under steady state conditions STAT1 was essential for several HSC transcriptional programs including expression of genes involved in virus life cycle, a subset of interferon-stimulated genes, MHC class I genes and genes involved in cell cycle arrest. In addition Stat-1 deficient mice lacked a previously unrecognized quiescent subset of homeostatic HSCs with high levels of MHC II expression (MHC IIhi HSCs). This subset was refractory to 5’-FU induced myeloablation and displayed reduced megakaryocytic potential. Mutant calreticulin, which causes increased megakaryopoiesis in human myeloproliferative neoplasms, gave rise to preferential expansion of MHC IIlo HSCs. These data reveal a STAT1 dependent MHC IIhi quiescent HSC subset and show that STAT1 protects HSCs from proliferative exhaustion.

Project description:We collected significant amount of phenotypic and mechanistic data from a ATF4 knockout mouse model and demonstrated that HSC defects with an aging-like phenotype (expanded pool of phenotypical HSCs, decreased number of functional HSCs, impaired repopulating and self-renewal capacities of HSCs and myeloid bias) occurred in the ATF4 KO mice, suggesting that not only ATF4 indeed represents a pivotal factor for adult HSC function but also we had successfully constructed an ideal and attractive model to study aging and aging-related disease.