Project description:Aging of hematopoietic stem cells (HSCs) is associated with the decline of their regenerative capacity, and multi-lineage differentiation potential, contributing to development of blood disorders. The bone marrow microenvironment was recently suggested to influence HSC aging, however the underlying mechanisms remain largely unknown. Here, we show that HSC aging critically depends on bone marrow innervation by the sympathetic nervous system (SNS), as premature loss of SNS nerves or adrenoreceptor b3 (ADRb3) signaling in the microenvironment accelerated the appearance of HSC aging phenotypes reminiscent of physiological aging. Strikingly, supplementation of ADRb3 sympathomimetics to old mice significantly rejuvenated in vivo function of old HSCs, suggesting that the preservation or restitution of SNS innervation during aging may hold the potential for novel HSC rejuvenation strategies.

Project description:Mesenchymal stem cells (MSCs) exist in many tissues and have emerged as promising candidates for therapeutic interventions. While MSCs may be used to reverse aging, they themselves also age. For example, bone marrow-derived MSCs from old individuals are known to have reduced ability to produce bone and cartilage cells, while biased towards making adipose tissues, hence aged bone marrow are referred to as "yellow marrow". Here we report, using step-wise treatment with different "cocktails" of small molecules, we turned old skin fibroblasts into much younger MSC-like cells (MSC-LCs), which reversed many aging features including shortened telomere as well as reduced proliferation potentials and differentiation bias. Moreover, MSC-LCs manifest potent effects in bone and cartilage repair in vivo. MSC-LCs also demonstrated strong immune modulatory functions both in vitro and in vivo during liver damage repair. Taken together, our study demonstrated that old skin fibroblasts could be reprogrammed to acquire youth and harbor huge therapeutic values.

Project description:Antler blastema progenitor cell (ABPC) is a novel type of skeletal stem cells with strong stemness and renewal ability. Here, we discovered that ABPC-derived extracellular vesicles (EVsABPCs) can strongly rejuvenate aging tissues in aged mice and rhesus macaques (Macaca mulattas). We identified a variety of rejuvenating signals in EVsABPCs, which exhibited a robust in vitro ability to rejuvenate senescent bone marrow stromal stem cells. In vivo, EVsABPCs increased bone mineral density in femur by 2.4-fold in mice, and 1.53-fold in rhesus macaques. Besides, intravenous EVsABPCs significantly outperformed fetal-EVsBMSCs in improving physical performance, reducing systemic inflammation and rejuvenating major tissues of aged mice, with no observed immunological side effects. Notably, EVsABPCs showed similar rejuvenating effects in old rhesus macaques as in elderly mice. These findings suggest that ABPC is a novel and practical source of EVs containing unique rejuvenating factors and has considerable translational value for anti-aging interventions, particularly rejuvenation of aging bones.

Project description:Antler blastema progenitor cell (ABPC) is a novel type of skeletal stem cells with strong stemness and renewal ability. Here, we discovered that ABPC-derived extracellular vesicles (EVsABPCs) can strongly rejuvenate aging tissues in aged mice and rhesus macaques (Macaca mulattas). We identified a variety of rejuvenating signals in EVsABPCs, which exhibited a robust in vitro ability to rejuvenate senescent bone marrow stromal stem cells. In vivo, EVsABPCs increased bone mineral density in femur by 2.4-fold in mice, and 1.53-fold in rhesus macaques. Besides, intravenous EVsABPCs significantly outperformed fetal-EVsBMSCs in improving physical performance, reducing systemic inflammation and rejuvenating major tissues of aged mice, with no observed immunological side effects. Notably, EVsABPCs showed similar rejuvenating effects in old rhesus macaques as in elderly mice. These findings suggest that ABPC is a novel and practical source of EVs containing unique rejuvenating factors and has considerable translational value for anti-aging interventions, particularly rejuvenation of aging bones.

Project description:A central hallmark of brain aging is the alteration of neuronal functions in the hippocampus, leading to a progressive decline in learning and memory. Multiple reports have shown the importance of blood-borne factors in inter-tissue communication for the maintenance of cognitive fitness and proper regulation of neuronal homeostasis throughout life. Among these blood-borne factors, we identified Osteocalcin (OCN), a bone-derived hormone. OCN induces autophagy machinery in hippocampal neurons which is essential for activity-dependent synaptic plasticity. However, the way in which blood-borne factors like OCN communicate with neurons, including their regulatory mechanisms, remains largely elusive. Here, we show the importance of a core primary cilium (PC)-proteins/autophagy machinery axis in hippocampal neurons that mediate the effects of the pro-youthful blood factor OCN on neuronal homeostasis and cognitive fitness. We found that OCN’s receptor, GPR158, is present at the PC of hippocampal neurons and mediates the regulation of autophagy machinery by OCN. During aging, PC-core proteins are reduced in hippocampal neurons and associated with neuronal PC morphological abnormalities. Restoring their levels is sufficient to improve neuronal autophagy and cognitive impairments in aged mice. Mechanistically, we found that OCN promotes neuronal autophagy in the hippocampus by the induction of PC-dependent cAMP response element-binding protein (CREB) signaling pathway. Altogether, this study proposes a novel paradigm for blood factor-neuron communication dependent on a neuronal PC/autophagy axis by identifying a novel regulatory pathway fostering cognitive fitness and providing the foundation for autophagy-based therapeutic strategies to treat age-related cognitive dysfunction.

Project description:The aging of bone marrow stromal cells (BMSCs) lead to decreased ability to maintain hematopoiesis, however, effects of aging on BMSC-derived exosomes in bone marrow microenvironment remain unclear. The aim of this study is therefore to determine the age-related change of BMSC-derived exosomal miRNAs.

Project description:Antler blastema progenitor cell (ABPC) is a novel type of skeletal mesenchymal stem cell with strong stemness and renewal ability. Here, we discovered that ABPC-derived extracellular vesicles (EVsABPCs) can strongly rejuvenate aging tissues in aged mice and rhesus macaques (Macaca mulattas). We identified a variety of rejuvenating molecules in EVsABPCs that differed from EVs of mouse bone marrow stromal stem cells (EVsBMSCs). EVsABPCs exhibited a robust in vitro ability to rejuvenate senescence BMSCs of aged mice and shift their molecular signature into a youthful state. In vivo, EVsABPCs increased bone mineral density in the femur by 2.4-fold in mice, and 1.53-fold in rhesus macaques. Besides, intravenous EVsABPCs significantly outperformed mouse fetal-EVsBMSCs in improving physical performance, reducing systemic inflammation, and rejuvenating major tissues of elderly mice, with no observed immunological side effects. Furthermore, EVsABPCs showed similar rejuvenating effects in old rhesus macaques as in elderly mice. Particularly, EVsABPCs resulted in remarkable improvements in brain structure and behaviors of elderly rhesus macaques, providing the first batch of evidence of EVs’ beneficial effects on aging brains in primates. These findings suggest that the ABPC is a novel and practical source of EVs containing a wealth of systemic rejuvenating factors and has considerable translational value for anti-aging interventions, particularly the rejuvenation of aging bones.

Project description:Human aging is associated with loss of function and regenerative capacity. Human bone marrow derived mesenchymal stromal cells (hMSCs) are involved in tissue regeneration, evidenced by their capacity to differentiate into several lineages and therefore are considered the gold standard for cell-based regeneration therapy. Tissue maintenance and regeneration is dependent on stem cells and declines with age and aging is thought to influence therapeutic efficacy, therefore, more insight in the process of aging of hMSCs is of high interest. We, therefore, hypothesized that hMSCs might reflect signs of aging. In order to find markers for donor age, early passage hMSCs were isolated from bone marrow of 61 donors, with ages varying from 17-84, and clinical parameters, in vitro characteristics and microarray analysis were assessed. Although clinical parameters and in vitro performance did not yield reliable markers for aging since large donor variations were present, genome-wide microarray analysis resulted in a considerable list of genes correlating with human age. By comparing the transcriptional profile of aging in human with the one from rat, we discovered follistatin as a common marker for aging in both species. The gene signature presented here could be a useful tool for drug testing to rejuvenate hMSCs or for the selection of more potent, hMSCs for cell-based therapy. We used microaray gene expression profiling to find expressed genes that correlated with the donor age of bone-marrow derived mesenchymal stromal cells (hMSCs) Human mesenchymal stem cells (hMSC) were biopsied from bone marrow from 61 different donors aging from 17 - 89 years old. The genome wide expression profiles was assessed using Affymetrix microarrays. The expression of genes was correlated with the age of the donors.

Project description:The aim of this study was to characterize the age-related gene expression profiles between bone marrow adipocytes and peripheral white adipocytes. Alterations of gene expression with aging were analyzed in bone marrow and peripheral white adipocytes isolated from C57BL/6J male mice using Affymetrix Mouse Gene 1.0 ST arrays. Bone marrow adipocytes and peripheral white adipocytes (n=6-10 animals per group) were isolated from male C57BL/6J mice (6-months, 14-months and 18-months of age). Samples were grouped into cell type (bone marrow adipocytes vs. peripheral adipocytes) and age (6-month (6M), 14-month (14M) and 18-month (18M)).

Project description:Recent studies have provided links between glutamine metabolism and bone remodeling, but little is known about its role in primary osteoporosis progression. We aimed to determine the effects of inhibiting glutaminase (GLS) on two types of primary osteoporosis and elucidate the related metabolism. To address this issue, age-related and ovariectomy (OVX)-induced bone loss mouse models were used to study the in vivo effects of CB-839, a potent and selective GLS inhibitor, on bone mass and bone turnover. We also studied the metabolic profile changes related with aging and GLS inhibition in primary bone marrow stromal cells (BMSC) and that related with OVX and GLS inhibition in primary bone marrow-derived monocytes (BMM). Besides, we studied the possible metabolic processes mediating GLS blockade effects during aging-impaired osteogenic differentiation and RANKL-induced osteoclast differentiation respectively via in vitro rescue experiments. We found that inhibiting GLS via CB-839 prevented OVX-induced bone loss while aggravated age-related bone loss. Further investigations showed that effects of CB-839 treatment on bone mass were associated with alterations of bone turnover. Moreover, CB-839 treatment altered metabolic profile in different orientations between BMSC of aged mice and BMM of ovariectomized mice. In addition, rescue experiments revealed that different metabolic processes mediated glutaminase blockade effects between aging-impaired osteogenic differentiation and RANKL-induced osteoclast differentiation. Taken together, our data demonstrated the different outcomes caused by CB-839 treatment between two types of osteoporosis in mice, which were tightly connected to the suppressive effects on both aging-impaired osteoblastogenesis and OVX-enhanced osteoclastogenesis mediated by different metabolic processes downstream of glutaminolysis.