Project description:Brain pericytes are critical for regulating endothelial barrier function and activity, thus ensuring adequate blood flow to the brain. How the developmental acquisition of pericytes to naked endothelium is regulated, is largely unknown, but is relevant to disorders where vessels are poorly stabilized. Although pericytes are derived from neural crest and mesoderm, brain pericytes from both origins are currently indistinguishable; the genetic pathways leading to a convergent pericyte phenotype are unknown. We show here that a precursor population expressing the transcription factor nkx3.1 with origins in both NCC and mesoderm, develops into brain pericytes. We identify the gene signature of these precursors and show that an nkx3.1, foxf2a, and cxcl12b -expressing pericyte precursor population is present around the cxcr4 expressing basilar artery, and that these cells later spread throughout the brain. Cxcl12b- Cxcr4 signaling is required for pericyte attachment and differentiation but not for later pericyte development. Further, both nkx3.1 and cxcl12b are necessary and sufficient in regulating pericyte number. Thus, we have defined an undescribed population of pericyte precursors and identified genes critical for their differentiation.

Project description:Brain pericytes are one of the critical cell types that regulate endothelial barrier function and activity, thus ensuring adequate blood flow to the brain. The genetic pathways guiding undifferentiated cells into mature pericytes are not well understood. We show here that pericyte precursor populations from both neural crest and head mesoderm of zebrafish express the transcription factor nkx3.1 develop into brain pericytes. We identify the gene signature of these precursors and show that an nkx3.1-, foxf2a-, and cxcl12b-expressing pericyte precursor population is present around the basilar artery prior to artery formation and pericyte recruitment. The precursors later spread throughout the brain and differentiate to express canonical pericyte markers. Cxcl12b-Cxcr4 signaling is required for pericyte attachment and differentiation. Further, both nkx3.1 and cxcl12b are necessary and sufficient in regulating pericyte number as loss inhibits and gain increases pericyte number. Through genetic experiments, we have defined a precursor population for brain pericytes and identified genes critical for their differentiation. This SuperSeries is composed of the SubSeries listed below.

Project description:Human pericytes demonstrate multilineage differentiation potential, and their descendants participate in tissue homeostasis and repair.  Increasing evidence from developmental biology and tissue engineering suggest that regional specification by tissue of origin exists among human pericytes.Here, we sought to define the differentiation of CD146+ human pericytes from skeletal and soft tissue sources.  Uncultured CD146+CD31-CD45- pericytes were derived by fluorescent activated cell sorting from human periosteum, adipose, or dermal tissue.  Periosteal CD146+CD31-CD45- cells retained canonical features of pericytes, including cell surface marker expression, multilineage differentiation potential, and paracrine induced tubulogenesis.  Periosteal pericytes demonstrated a striking tendency to undergo osteoblastogenesis, while soft tissue pericytes did not in vitro or in vivo. Microarray analysis demonstrated enrichment in CXCR4 and BMP signaling among periosteal pericytes in comparison to their soft tissue pericyte counterparts.  Signaling pathway manipulation of CXCR4 among soft tissue pericytes led to an increase in osteoblastogenesis and bone formation.  In sum, skeletal and soft tissue pericytes differ in their relative lineage differentiation potential and ability to form bone.  Plasticity exists, however, and manipulation of CXCR4 signaling pathway may ‘coax’ a soft tissue pericyte toward an osteoblastogenic cell fate.

Project description:Pericytes are multifunctional contractile cells that reside on capillaries. Pericytes are critical regulators of cerebral blood flow and blood-brain barrier function, and pericyte dysfunction may contribute to the pathophysiology of human neurological diseases including Alzheimer’s disease, multiple sclerosis, and stroke. Induced pluripotent stem cell (iPSC)-derived pericytes (iPericytes) are a promising tool for vascular research. However, it is unclear how iPericytes functionally compare to primary human brain vascular pericytes (HBVPs). We differentiated iPSCs into iPericytes of either the mesoderm or neural crest lineage using established protocols. We compared iPericyte and HBVP morphologies, quantified gene expression by qPCR and bulk RNA sequencing, and visualised pericyte protein markers by immunocytochemistry. To determine whether the gene expression of neural crest iPericytes, mesoderm iPericytes or HBVPs correlated with their functional characteristics in vitro, we quantified EdU incorporation following exposure to the key pericyte mitogen, platelet derived growth factor (PDGF)-BB and, contraction and relaxation in response to the vasoconstrictor endothelin-1 or vasodilator adenosine, respectively. iPericytes were morphologically similar to HBVPs and expressed canonical pericyte markers. Consistent with the ability of HBVPs to respond to PDGF-BB signalling, PDGF-BB enhanced and PDGF receptor (PDGFR)β inhibitors impaired iPericyte proliferation. Administration of endothelin-1 led to iPericyte contraction and adenosine led to iPericyte relaxation, of a magnitude similar to the response evoked in HBVPs. We determined that neural crest iPericytes were less susceptible to PDGFRβ inhibition, but responded most robustly to vasoactive meditators. iPericytes express pericyte-associated genes and proteins and, exhibit an appropriate physiological response upon exposure to a key endogenous mitogen or vasoactive mediators. Therefore, this protocol to generate functional iPericytes would be suitable for use in future investigations exploring pericyte function or dysfunction in neurological diseases.

Project description:Increasing evidence shows that brain pericytes can acquire multipotency to produce multi-lineage cells following injury. However, pericytes are a heterogenous population and it remains unknown whether there are different potencies from different subsets of pericytes in response to injury. Here, using single-cell RNA-sequencing (scRNA-seq) and immunohistochemistry analysis following ischemic stroke, we showed that NG2+ pericyte subset expressed very strong neural reprogramming potential to produce newborn neurons, while Tbx18+ pericytes displayed strong multipotency to produce endothelial cells, fibroblasts, and microglia but with minimal neural reprogramming potency. In addition, we mimicked ischemic stroke in vitro and developed an NG2+ pericyte neural reprogramming culture model. Here we discovered that AMP-dependent kinase (AMPK) modulators facilitated pericyte to neuron conversion by modulating Ser436 phosphorylation status of CREB-binding protein (Cbp), a histone acetyltransferase, which coordinated an acetylation shift between the non-histone substrate (Sox2) and the histone substrate (H2B) and modulated Sox2 nuclear-cytoplasmic trafficking during reprogramming/differentiation process. Finally, we identified that sequential treatment of compound C (CpdC) and metformin, AMPK inhibitor and activator respectively through reprogramming/differentiation process, robustly facilitated the conversion of human pericyte into functional neurons via transient pericyte-derived neural stem cell population.

Project description:Pericytes have been implicated in regulation of inflammatory, reparative, fibrogenic and angiogenic responses in several different organs and pathologic conditions. Although the adult mammalian heart contains abundant pericytes, their fate and involvement in myocardial disease remains unknown. We used NG2Dsred;PDGFRaEGFP pericyte-fibroblast dual reporter mice and inducible NG2CreER mice to study the fate and phenotypic modulation of pericytes in a model of myocardial infarction. The transcriptomic profile of pericyte-derived fibroblasts was studied using PCR arrays. The transcriptomic profile of NG2 lineage cells (pericytes) was studied in control and infarcted hearts using single cell RNA-sequencing analysis. The role of TGF-b signaling in regulation of pericyte phenotype in vivo was investigated using pericyte-specific Tgfbr2 knockout mice. In vitro, the effects of TGF-b were studied in cultured human placental pericytes.In normal mouse hearts, NG2 and PDGFRa identified distinct non-overlapping populations of pericytes and fibroblasts respectively. Following myocardial infarction, a population of cells expressing both pericyte and fibroblast markers emerged. These cells expressed large amounts of extracellular matrix (ECM) genes. Lineage tracing demonstrated that in the infarcted region, a subpopulation of pericytes underwent fibroblast conversion. Single cell RNA-seq experiments demonstrated expansion and diversification of pericyte-derived cells in the infarct, associated with emergence of subpopulations exhibiting accentuated matrix gene synthesis. In vitro studies and the profile of pericyte-derived fibroblasts identified TGF-b as a potentially causative mediator in fibrogenic activation of infarct pericytes. However, pericyte-specific Tgfbr2 disruption had no significant effects on myofibroblast infiltration and collagen deposition in the infarct. Pericyte-specific TGF-b signaling was involved in vascular maturation, mediating formation of a mural cell coat investing infarct neovessels. These reparative effects of infarct pericytes protected the infarcted heart from dilative remodeling.

Project description:hPSCs were differentiated to brain pericyte-like cells through a neural crest stem cell intermediate and compared to primary human brain pericytes

Project description:Background: Epidemiology and experimental studies suggest 1,25-dihydroxyvitamin D3 plays a neuroprotective role in neurodegenerative diseases including Alzheimer's disease. Most of the experimental data on the genes regulated by this hormone in brain cells have been obtained with neuron and glial cells. Emerging evidence demonstrates pericyte plays a critical role in brain function that encompasses its classical function in the control and maintenance of the blood brain barrier. However, the gene response of brain pericyte to 1,25D remains to be investigated. Methods: The transcriptomic response of human brain pericytes to 1,25-dihydroxyvitamin D3 was analyzed. Results were confirmed by RT-qPCR for the genes of interest. Results: We demonstrate that human brain pericyte in culture responds to 1,25-dihydroxyvitamin D3 by regulating genes involved in the control of neuro-inflammation. We also showed that pericytes respond to the pro-inflammatory cytokines TNF-alpha and Interferon gamma by inducing the expression of the gene involved in the synthesis of 1,25-dihydroxyvitamin D3 named CYP27B1. Conclusion: Taken together these results suggest that neuro-inflammation could trigger the synthesis of 1,25-dihydroxyvitamin D3 by brain pericytes, which will in turn respond to the hormone by a global anti-inflammatory response.

Project description:A subpopulation of pericytes expressing the Glast-CreERT2 transgene (Type A pericytes) has recently been identified as the main source of stromal scar tissue that forms after SCI. Identification of molecules associated with pericyte-derived scarring may offer new therapeutic targets to facilitate axon regeneration following central nervous system (CNS) injury. We conducted genome-wide RNA sequencing of (i) uninjured spinal cord segments and (ii) lesion sites presenting full or attenuated pericyte-derived scarring 14 days after SCI.

Project description:Ischemic injury leads to irreversible loss of neurons and cardiomyocytes in the brain and heart, respectively which ultimately results in fibrotic scar formation. Despite recent advances in tissue fibrosis, cellular mediators of scar formation in the heart and brain remain elusive. Pericytes are a heterogeneous population of mural cells that surround microvessels in various organs including the brain and heart. Their function beyond vascular integrity and contractility is poorly understood, although recent studies have suggested they may be a major contributor to tissue fibrosis. In both the heart and brain, differences in injury models, lack of proper transgenic mouse models for lineage tracing and absence of pericyte-specific markers have contributed to discrepancies in the literature regarding their direct contributions to fibrosis. Here, by performing a set of complementary experiments using a common pericyte transgenic model and clinically-relevant ischemic injury models of stroke and myocardial infarction, we demonstrated the parallel pro-fibrotic response of pericyte after vascular injury.