An affiliation between vascular pericytes and renin producing cells in the human foetal kidney

Stefanska, Anna Maria

January 2014

Pericytes, progenitor cells embedded in the microvascular wall, are crucial for vascular homeostasis. Renin is the rate-limiting enzyme that regulates blood pressure and fluid/electrolyte balance. Previous work suggested the relationship between renin-expressing/ producing cells and pericytes, however human kidney pericytes have not been characterized in depth and the molecular switch controlling renin cell plasticity is not understood. Here, I describe a method of isolation of CD146+CD34-CD45-CD56- pericytes, putative progenitors for renin-producing cells, from the human foetal kidney and demonstrate their potential in vitro to express and produce renin. Co-staining of pericyte markers (CD146 and NG2) and renin showed coincidence in the juxtaglomerular region and along renal arterioles in the human foetal kidney. I have obtained primary cultures of renal pericytes from the developing human kidney that were purified via fluorescence-activated cell sorting. Primary cultures of renal pericytes exhibited tri-lineage mesodermal differentiation potential. Renin expression was triggered by cAMP induction (10μM forskolin and 100μM 3-isobutyl-1- methylxanthine [IBMX] and resulted in 64.3 fold increase of renin mRNA (p <0.01) and 41.5 fold increase in enzymatic activity of renin (p <0.05) over controls. Pericytes derived from non-renal tissues (placenta and foetal adrenal glands) also expressed renin in an inducible fashion. Renin positive cells following induction were confirmed to be CD146+/NG2+. Interestingly, alpha-smooth muscle actin expression was not always correlated with renin immunostaining. Wnt/β-catenin signalling plays a crucial role during kidney development and in disease, specifically; in pericyte modulation of the Wnt pathway has been shown to regulate cell differentiation. CHIR 99021, a specific inhibitor of glycogen synthase kinase 3, mimicking Wnt signalling, and C59, a potent Porcupine acyltransferase inhibitor that is required for Wnt biological activity, were tested in renin induction experiments. Preliminary data showed that renin expression was blocked by Wnt activation, whereas Wnt suppression increased renin mRNA levels above the level of stimulation achieved with cAMP inducers. These findings provide evidence that renin expression is an intrinsic feature of pericytes and can be regulated through the Wnt pathway.

612.4

pericyte ; renin ; RAS ; foetal kidney

Validation of Rat Mesentery Culture Model for Time-Lapse Drug Evaluation and Cell Lineage Studies

January 2017

acase@tulane.edu / An emerging need in the microcirculation research is the development of biomimetic angiogenesis models that recapitulate the complexity of a real tissue. Angiogenesis, defined as the growth of new vessels from pre-existing vessels, involves multiple cell types, such as endothelial and perivascular cells, in a multi-system setting since blood vessel networks are usually accompanied by lymphatic and nervous systems. Therefore, a need exists for a model of angiogenesis from intact microvascular networks that more closely reflects an in vivo scenario for the investigation of underlying mechanisms and the pre-clinical development of therapies. While other approaches have proven useful in identifying mechanistic signaling information, they are often limited in their complexity and capability to mimic physiologically relevant scenarios in one way or another and do not fully recapitulate the in vivo scenario. The first aim of this study was to demonstrate the ability for time-lapse comparisons of microvascular networks in angiogenesis scenarios to investigate the fate of vascular islands and investigate the endothelial cell plasticity. We developed a time-lapse angiogenesis model based on our previously introduced rat mesentery model. We demonstrated that time-lapse rat mesentery culture model is a powerful tool to study multi-cell, multi-system dynamics in microvascular networks. For the second aim of this study, we used the method developed in aim one to establish rat mesentery culture model as a novel anti-angiogenic drug screening tool. Using time-lapse model enabled tissue-specific comparisons before and after drug treatment to investigate its effects on entire microvascular networks. Validation of this method for anti-angiogenic drug testing was demonstrated using known angiogenesis inhibitor. Next, we showcased a potential application of the model for evaluating unknown effects of drug repositioning based on FDA-approved drug combinations. The results demonstrated the ability to identify concentration-dependent effects in an intact network scenario. The objective of the third aim was to showcase the capability of the rat mesentery culture model to study stem cell fate. We developed a protocol to deliver mesenchymal stem cells to mesentery tissues and culture for a period of time in a controlled environment. We confirmed the perivascular location of a subset of stem cells within capillaries, with morphologies resembling pericytes, and expressing pericyte markers. We also demonstrated that tracking stem cells within the microvascular networks is possible using the rat mesentery culture model. Furthermore, we reported a high variability in perivascular incorporation among cells from different donors. This work establishes for the first time, to the best of our knowledge, an ex vivo model to look at microvascular networks before and after growth. We confirmed, for the first time, vascular island incorporation as a new mode of angiogenesis using a novel method for time-lapse imaging of microvascular networks ex vivo. The results also establish this method for drug testing and stem cell tracking in a microvascular setting. / 1 / Mohammad Sadegh Azimi

Mesentery

Microcirculation and Angiogenesis

Pericyte and Endothelial Cell

Functional Contribution of PDGFRbeta+ Cells in Angiogenesis and Metastatic Breast Cancer

Keskin, Doruk

January 2013

Tumor stroma is known to affect tumor growth and metastasis. Inhibiting PDGF signaling, with the goal of depleting PDGFR&beta;+ stromal cells, is a putative therapeutic approach in this context. PDGFR&beta; is widely accepted as a pericyte marker and targeting PDGF signaling primarily affects pericytes. Pericyte-endothelial cell interactions modulate angiogenesis and vascular stability in developmental and pathological contexts. Owing to this, pericytes are speculated to be important regulators of tumor growth and metastasis, although their role is not clear.

Biology

Angiogenesis

Cancer

Metastasis

Pericyte

Retina

Perivascular stem cells at the crossroads of tissue regeneration and pathology

Murray, Iain Robert

January 2015

Pericytes represent a population of potential mesenchymal stem cells (MSC) that reside within a perivascular niche until they are required in normal homeostasis and the response to injury. Their mesenchymal capacities for multipotent differentiation, immune modulation and release of trophic factors hold great promise for regenerative therapies. Pathological expression of these potentials has been described in disease states, while acute or chronic inflammation following injury can lead to the production of signalling molecules that ultimately drive these progenitors to a fibrotic fate. The aim of this work was to explore how fate decisions of pericytes are regulated by their niche (in the setting of osteogenesis), and in the response to acute and chronic injury (in the setting of fibrosis). It was hypothesized that interactions between pericytes and endothelial cells (EC) within their perivascular niche are responsible for regulating mesenchymal differentiation. The osteogenic, adipogenic and chondrogenic potential of pericytes following isolation from multiple human organs was confirmed. The interactions between pericytes and EC in 2D and 3D coculture and the production of basement membrane proteins in these settings were confirmed. The osteogenic differentiation of pericytes was accelerated by EC but no influence of EC on the adipogenic and chondrogenic differentiation of pericytes was detected. Furthermore, data indicated that the influence on pericyte osteogenic potential by EC may occur through wnt signaling. The activation of TGFβ (transforming growth factor beta) through αv integrins has been suggested as central mediator of fibrosis in multiple organs. We hypothesized that selective αv integrin deletions in PDGFRβ (platelet derived growth factor receptor beta) expressing pericytes identifies a targetable pathway regulating fibrosis in skeletal muscle. We report that PDGFRβ-Cre inactivates genes in murine skeletal muscle pericytes with high efficiency. Deletion of the αv integrin subunit in pericytes protected mice from chemical injury induced skeletal muscle fibrosis. Pharmacological blockade of αv integrins by a novel small molecule (CWHM 12) attenuated muscle fibrosis, even when administered after fibrosis was established.

612.7

Endothelial deletion of <i>Rbpj</i> leads to perivascular abnormalities in the brain

Selhorst, Samantha Ann

January 2019

No description available.

Biology

Neurosciences

Pericyte-Endothelial Cell Interactions during Blood Vessel Formation and in Diabetic Scenarios

Zhao, Huaning

08 April 2019

Diabetic retinopathy (DR) is an incurable, chronic disease that is the leading cause of blindness in working-age adults. A prominent characteristic of DR is the extensive dysfunction within the retina microvasculature. Specialized vascular cells known as pericytes (PCs) are lost or become dysfunctional during disease progression; a thickening of the extracellular matrix (ECM) composing the vascular basement membrane (vBM) and endothelial cell (EC) tight junction disruption are also key features of this disease and contribute to its pathogenesis. PC loss is believed to be a central cue for disease initiation. However, studies inducing PC loss and observing acute changes in the vasculature did not report severe vessel damage or vBM thickening, suggesting that the effects of PC loss occur over a longer period of time. Because the chronic effects of PC loss are more difficult to ascertain, especially in a complex condition such as DR, the mechanisms underlying microvascular defects in DR remain poorly understood. The work presented in this dissertation focuses on pericyte-endothelial cell interactions and their interplay with the ECM/vBM during a variety of physiological and pathological conditions. First, we isolated and functionally validated a primary mouse embryonic PC cell line that we then applied to a co-culture model with ECs to better understand the dynamic interactions between these two critical components of the capillary wall. In the co-culture model, we found that primary PCs promoted EC organization into vessel-like structures and enhanced EC-EC junctions. To complement these in vitro studies, we analyzed animal models and human tissue for the PC-EC interactions and ECM/vBM remodeling under different conditions (physiological and pathological). Moreover, we analyzed microglia and astrocytes to enhance our understanding of the tissue-vessel interface, bolstering our experimental results and facilitating the generation of more hypotheses for future research. Overall, our work suggests that PC-EC interactions in diabetic scenarios play a crucial role in ECM/vBM remodeling; engagement with the ECM/vBM in turn impacted PC behaviors including migration away from the endothelium and induced EC loss of tight junctions, key changes in the onset and progression of DR. / Doctor of Philosophy / Diabetic retinopathy is a group of eye diseases occurring in patients suffering from diabetes and is the leading cause of adult blindness among the working-aged. About one in three people with diabetes over the age of 40 have overt signs of DR. The primary cause for this disease is long-term, high blood sugar levels that damages blood vessels systemically as well as in the eye. Current treatments for DR can prevent the condition from getting worse, but no treatment exists that results in a complete cure. This work described in this dissertation focuses on the interactions between vascular pericytes and endothelial cells, two of the main cell types that compose capillaries (i.e. the smallest blood vessels important for oxygen delivery). The studies presented herein also focus on the response of these cells to the extracellular matrix, a scaffold of proteins that surround pericytes and endothelial cells to stabilize blood vessels. We found that extracellular matrix components dramatically increase as a result of the interactions between pericytes and endothelial cells exposed to diabetic conditions. These changes in the extracellular matrix also had important effects on pericytes and endothelial cells and their engagement with their environment and other cells. Taken together, our work suggests that pericyte-endothelial cell interactions and their crosstalk with the ECM play an important role in blood vessel formation and in the accumulation of microvascular defects that fuel diabetic retinopathy progression.

diabetic retinopathy

pericyte

endothelial cell

extracellular matrix

PLATELET DERIVED GROWTH FACTOR RECEPTOR B (PDGFRB) EXPRESSING CELLS DURING ZEBRAFISH CORONARY VESSEL DEVELOPMENT

Fierros, Juancarlos

01 June 2017

Coronary heart disease is a prevalent issue in developed countries throughout the world. It can have crippling effects on the quality of life and even lead to mortality, in the case of myocardial infarction. Part of the problem is the lack of a robust regenerative response in mammals after injury. Zebrafish have an amazing ability to regenerate after injury, and studies have demonstrated that the regenerative response recapitulates embryonic development. Our lab previously reported the first analysis of coronary vessel development in zebrafish and demonstrated that coronary endothelial cells undergo angiogenesis to form a vascular network. The roles of perivascular cells in this process have not been examined in zebrafish. Using a transgenic reporter line marking pdgfrb expression, I found that pdgfrb is first observed in epicardium at the AV canal. At later stages of coronary vessel development, pdgfrb positive cells become localized to the perivascular region of mature vessels. I also observe that early in development, Tcf21 and pdgfrb co-express, which suggests a close relationship between the epicardium and pdgfrb+ cells. Previous findings from our lab revealed that cxcl12b+ cells localize to large coronary vessels during development. My findings reveal that pdgfrb+ marks perivascular cells of both capillaries and large coronary vessels. Lineage tracing analysis revealed that a subset of pdgfrb+ perivascular cells derive from tcf21 labeled epicardial cells. To see if disruption of Pdgfrb signaling impacts coronary development, I examined pdgfrb mutant hearts. In the Pdgfrb mutant, a mature coronary vessel network fails to form, and instead we observe isolated endothelial cell islands. Lastly, I characterized a transgenic line that expresses a dominant negative form of Pdgfrb (dnpdgfrb) and can be potentially used for later developmental and/or regenerative studies. My findings indicate strong dnpdgfrb induction can be achieved at adult stages. My studies will greatly enhance our current understanding of coronary vessel development, and can be used as the basis for studying perivascular cells and their interactions with endothelial cells after cardiac injury in regeneration.

Pericyte

Epicardium

Coronary Vessel

Pdgfr

Zebrafish

Citrine

Developmental Biology

Links between the microvascular and neural systems: Multicellular interactions during angiogenesis

January 2013

acase@tulane.edu

Angiogenesis

Microvasculature

Pericyte

School of Science & Engineering

Biomedical Engineering

Ph.D

Inhibition of VEGF receptors induces pituitary apoplexy: an experimental study in mice / VEGF受容体の阻害は下垂体卒中を誘発する：マウスにおける実験的研究

Sugita, Yoshito

23 March 2023

京都大学 / 新制・課程博士 / 博士(医学) / 甲第24529号 / 医博第4971号 / 新制||医||1065(附属図書館) / 京都大学大学院医学研究科医学専攻 / (主査)教授 髙橋 良輔, 教授 浅野 雅秀, 教授 辻川 明孝 / 学位規則第4条第1項該当 / Doctor of Medical Science / Kyoto University / DFAM

OSI-930

pericyte

pituitary apoplexy

VE-cadherin

VEGF

490

Pericytes in Early Vascular Development

Darden, Jordan Alexandra

18 April 2019

Blood vessels are critical for the delivery of oxygen and nutrients to all cells in the body. To properly function, blood vessels and their primary components must develop and mature into a healthy network, capable of dynamic alterations to meet new needs of the body. The early genetic and molecular programs that "push" the vasculature to develop are the same programs that reactivate when there are normal changes to the body such as injury, muscle growth or decline, or aging; and when pathologies arise like cancer, stroke, and diabetes. Therefore, it is crucial to understand how the vasculature develops into a healthy system by studying all components as they mature. Endothelial cells that comprise the vessels themselves are joined by specialized partner cells called pericytes that help guide and mature vessel growth. Pericytes lie elongated along endothelial cells and have multiple points of contact with the endothelium. In this position, pericytes assist in cell-cell communication and even blood flow regulation in the microvasculature. To study the relationship between endothelial cells and pericytes during development, we observed vascular morphology in three and four dimensions, as well as the genetic and molecular mechanisms underlying how these cells are recruited and interact in several experimental models. Thus, to thoroughly analyze the morphology of these vessels, we developed a rigorous methodology using a MATLAB program to determine the colocalization and coverage of pericytes associated with vessels in large image sets. After developing analytical methods to investigate all the components of the blood vessel wall, we expanded our investigation of how pericytes and other aspects of microvasculature develop in animal models, specifically a more commonly used murine model for vascular development and for treatment of human diseases. Our findings of vascular development in mice suggest that there are important differences in how human and mouse brain blood vessels form. Therefore, studies using mice must be carefully designed to account for these discrepancies. Additionally, research into why human and mouse neurovascular development and maturation are different can aid in the development of improved experimental models to better treat human pathologies. / Doctor of Philosophy / Blood vessels have the crucial job of delivering oxygen and nutrients to all the cells in the body. To perform this duty, blood vessels- and the components that make them- must develop and mature into a healthy network, capable of altering itself to meet new needs of the body. The early programs that “push” the vessel system to develop are the same programs that reactivate when there are normal changes to the body such as injury, muscle growth or decline, or aging; and when abnormal diseases arise like cancer, stroke, and diabetes. Therefore, it is critical to understand how blood vessels develop into healthy systems by studying all of their components as they mature. Endothelial cells that comprise the vessels themselves are joined by specialized partner cells called pericytes that help guide and mature vessel growth. Pericytes lie elongated along endothelial cells and have multiple points of contact with the endothelium. In this position, pericytes assist in cell-cell communication and even blood flow regulation in smaller vessels called capillaries. To study the relationship between endothelial cells and pericytes during development, we observed vascular anatomy in three and four dimensions, as well as mechanisms underlying how these cells come together and interact in several experimental models. Thus, to thoroughly analyze the morphology of these vessels, we developed a rigorous methodology using a MATLAB program to determine the colocalization and coverage of pericytes associated with vessels in large image sets. After developing analytical method to investigate all the components of the blood vessel wall, we expanded our investigation of how pericytes and other aspects of blood vessels develop in animal models, specifically a more commonly used animal model for vascular development and for treatment of human diseases. Our findings of vascular development in mice suggest that there are important differences in how human and mouse brain blood vessels form. Therefore, studies using mice must be carefully designed to account for these discrepancies. Additionally, research into why human and mouse neurovascular development and maturation are different can aid in the development of improved experimental models to better treat human illness and injury.

pericyte recruitment

vascular development

periyte-endothelial cell interactions

developmental pathogenesis