Differentiation of pericytes in culture is accompanied by changes in the extracellular matrix

Summary We have previously reported that pericytes derived from retinal and brain microvessels aggregate into nodules soon after reaching confluence. Nodule formation involves a reorganization of the cells resulting in the presence of sparse cells, confluent monolayers, multilayers, sprouts, and nodules within the same culture dish. Extracellular calcification occurs only within the nodules, demonstrating that pericytes are capable of undergoing osteogenic differentiation in culture and that this differentiation is related to nodule formation. Using immunofluorescence we have now studied the distribution of laminin, type IV collagen, type X collagen, and tenascin in pericyte cultures during nodule formation. These matrix macromolecules were also identified by a combination of biochemical techniques, including Northern blot hybridization, immunoblotting and sodium dodecyl sulfate-polyacrylamide gel electrophoresis. A molecule that seems to be related to type X collagen was demonstrated by the presence of a pepsin-resistant, collagenase-sensitive polypeptide of molecular weight approximately 45 kDa. The production of laminin, type X-related collagen, and tenascin by pericytes has not been previously reported. Our results suggest that the synthesis or distribution or both of these molecules is dependent on the state of pericyte differentiation. The expression of laminin, type IV collagen, and type X-related collagen was maximal in multilayer areas, sprouts, and nodules. Tenascin appeared homogeneously distributed in monolayer and multilayer areas; when calcified nodules were present, the anti-tenascin serum preferentially decorated a discrete area circumscribing the nodules. Tenascin and type X collagen have been found transiently in vivo preceding calcification; their possible role in this process is not known. Our results also suggest an association between laminin, type IV collagen, and calcification. The in vitro experimental system described here may help to clarify the role of matrix macromolecules in the calcification process.     

The Angiopoietin-1 Variant COMP-Ang1 Enhances BMP2-Induced Bone Regeneration with Recruiting Pericytes in Critical Sized Calvarial Defects

Craniofacial bone defects are observed in a variety of clinical situations, and their reconstructions require coordinated coupling between angiogenesis and osteogenesis. In this study, we explored the effects of cartilage oligomeric matrix protein-angiopoietin 1 (COMP-Ang1), a synthetic and soluble variant of angiopoietin 1, on bone morphogenetic protein 2 (BMP2)-induced cranial bone regeneration, and recruitment and osteogenic differentiation of perivascular pericytes. A critical-size calvarial defect was created in the C57BL/6 mouse and COMP-Ang1 and/or BMP2 proteins were delivered into the defects with absorbable collagen sponges. After 3 weeks, bone regeneration was evaluated using micro-computed tomography and histologic examination. Pericyte recruitment into the defects was examined using immunofluorescence staining with anti-NG2 and anti-CD31 antibodies. In vitro recruitment and osteoblastic differentiation of pericyte cells were assessed with Boyden chamber assay, staining of calcified nodules, RT-PCR and Western blot analyses. Combined administration of COMP-Ang1 and BMP2 synergistically enhanced bone repair along with the increased population of CD31 (an endothelial cell marker) and NG2 (a specific marker of pericyte) positive cells. In vitro cultures of pericytes consistently showed that pericyte infiltration into the membrane pore of Boyden chamber was more enhanced by the combination treatment. In addition, the combination further increased the osteoblast-specific gene expression, including bone sialoprotein (BSP), osteocalcin (OCN) and osterix (OSX), phosphorylation of Smad/1/5/8, and mineralized nodule formation. COMP-Ang1 can enhance BMP2-induced cranial bone regeneration with increased pericyte recruitment. Combined delivery of the proteins might be a therapeutic strategy to repair cranial bone damage.     

Matrix GLA protein and BMP-2 regulate osteoinduction in calcifying vascular cells

Expression of matrix GLA protein (MGP), an alleged calcification inhibitor, is increased in calcified arteries. We used calcifying vascular cells (CVC) that form calcified nodules in vitro to clarify the importance of MGP in vascular cell calcification and differentiation. Unexpectedly, MGP dose-dependently increased calcification in CVC. It also increased expression of the osteogenic marker Cbfal, while decreasing expression of the smooth muscle marker alpha-actin as assessed by immunoblotting. Bone morphogenetic protein-2 (BMP-2), a known osteoinductive factor also increased calcification and osteogenic differentiation in CVC. We hypothesized that the effect of MGP was linked to that of BMP-2 since previous studies show that MGP modulates BMP-2 activity. Therefore, we compared the effect of MGP at different levels of exogenous BMP-2. Results showed that high BMP-2 levels significantly increased the stimulatory effect of low levels of MGP. A relative inhibition of calcification was observed at intermediate levels of MGP and a trend towards renewed stimulation at high levels of MGP. Thus, addition of MGP either promoted or inhibited calcification, depending on the relative amounts of BMP-2 and MGP. This was confirmed in human CVC with different relative expression of BMP-2 and MGP. Calcification in CVC with high relative expression of BMP-2 was inhibited by MGP, while calcification in CVC with low relative expression of BMP-2 was stimulated by MGP. MGP and BMP-2 both accelerated nodule formation, but had opposite effects on nodule size; MGP decreased while BMP-2 increased nodule size. The effect of BMP-2 may partly be explained by a BMP-2 induced decrease in MGP expression. Together, our results suggest that the effect of MGP on calcification and osteogenic differentiation is determined by availability of BMP-2.     

Pericytes Regulate Vascular Basement Membrane Remodeling and Govern Neutrophil Extravasation during Inflammation

During inflammation polymorphonuclear neutrophils (PMNs) traverse venular walls, composed of the endothelium, pericyte sheath and vascular basement membrane. Compared to PMN transendothelial migration, little is known about how PMNs penetrate the latter barriers. Using mouse models and intravital microscopy, we show that migrating PMNs expand and use the low expression regions (LERs) of matrix proteins in the vascular basement membrane (BM) for their transmigration. Importantly, we demonstrate that this remodeling of LERs is accompanied by the opening of gaps between pericytes, a response that depends on PMN engagement with pericytes. Exploring how PMNs modulate pericyte behavior, we discovered that direct PMN-pericyte contacts induce relaxation rather than contraction of pericyte cytoskeletons, an unexpected response that is mediated by inhibition of the RhoA/ROCK signaling pathway in pericytes. Taking our in vitro results back into mouse models, we present evidence that pericyte relaxation contributes to the opening of the gaps between pericytes and to the enlargement of the LERs in the vascular BM, facilitating PMN extravasation. Our study demonstrates that pericytes can regulate PMN extravasation by controlling the size of pericyte gaps and thickness of LERs in venular walls. This raises the possibility that pericytes may be targeted in therapies aimed at regulating inflammation.     

The impact of pericytes on the blood-brain barrier integrity depends critically on the pericyte differentiation stage

The blood-brain barrier consists of the cerebral microvascular endothelium, pericytes, astrocytes and neurons. In this study we analyzed the differentiation stage dependent influence of primary porcine brain capillary pericytes on the barrier integrity of primary porcine brain capillary endothelial cells. At first, we were able to induce two distinct differentiation stages of the primary pericytes in vitro. TGFβ treated pericytes expressed more α-SMA and actin while desmin, vimentin and nestin expression was decreased when compared to bFGF induced cells. Further analysis of α-SMA revealed that most of the pericytes differentiated with TGFβ expressed functional α-SMA while only few cells expressed functional α-SMA in the presence of bFGF. In addition the permeability factors VEGF, MMP-2 and MMP-9 were higher secreted by the α-SMA positive phenotype indicating a proangiogenic role of this TGFβ induced pericyte differentiation stage. Higher level of VEGF, MMP-2 and MMP-9 were as well detected in the TGFβ pretreated pericyte coculture with endothelial cells when compared to the influence of the bFGF pretreated pericytes. The TEER measurement of the barrier integrity of endothelial cells revealed that bFGF induced α-SMA negative pericytes stabilize the barrier integrity while α-SMA positive pericytes differentiated by TGFβ decrease the barrier integrity. These results together reveal the potential of pericytes to regulate the endothelial barrier integrity in a differentiation stage dependant pathway.     

Evolution of matrix and bone gamma-carboxyglutamic acid proteins in vertebrates

The evolution of calcified tissues is a defining feature in vertebrate evolution. Investigating the evolution of proteins involved in tissue calcification should help elucidate how calcified tissues have evolved. The purpose of this study was to collect and compare sequences of matrix and bone gamma-carboxyglutamic acid proteins (MGP and BGP, respectively) to identify common features and determine the evolutionary relationship between MGP and BGP. Thirteen cDNAs and genes were cloned using standard methods or reconstructed through the use of comparative genomics and data mining. These sequences were compared with available annotated sequences (a total of 48 complete or nearly complete sequences, 28 BGPs and 20 MGPs) have been identified across 32 different species (representing most classes of vertebrates), and evolutionarily conserved features in both MGP and BGP were analyzed using bioinformatic tools and the Tree-Puzzle software. We propose that: 1) MGP and BGP genes originated from two genome duplications that occurred around 500 and 400 million years ago before jawless and jawed fish evolved, respectively; 2) MGP appeared first concomitantly with the emergence of cartilaginous structures, and BGP appeared thereafter along with bony structures; and 3) BGP derives from MGP. We also propose a highly specific pattern definition for the Gla domain of BGP and MGP.     

Coordinated expression of matrix Gla protein is required during endochondral ossification for chondrocyte survival

Matrix Gla protein (MGP) is a 14-kD extracellular matrix protein of the mineral-binding Gla protein family. Studies of MGP-deficient mice suggest that MGP is an inhibitor of extracellular matrix calcification in arteries and the epiphyseal growth plate. In the mammalian growth plate, MGP is expressed by proliferative and late hypertrophic chondrocytes, but not by the intervening chondrocytes. To investigate the functional significance of this biphasic expression pattern, we used the ATDC5 mouse chondrogenic cell line. We found that after induction of the cell line with insulin, the differentiating chondrocytes express MGP in a stage-specific biphasic manner as in vivo. Treatment of the ATDC5 cultures with MGP antiserum during the proliferative phase leads to their apoptosis before maturation, whereas treatment during the hypertrophic phase has no effect on chondrocyte viability or mineralization. After stable transfection of ATDC5 cells with inducible sense or antisense MGP cDNA constructs, we found that overexpression of MGP in maturing chondrocytes and underexpression of MGP in proliferative and hypertrophic chondrocytes induced apoptosis. However, overexpression of MGP during the hypertrophic phase has no effect on chondrocyte viability, but it does reduce mineralization. This work suggests that coordinated levels of MGP are required for chondrocyte differentiation and matrix mineralization.     

Effect of cell density and growth factors on matrix GLA protein expression by normal rat kidney cells

The present studies demonstrate that the expression of the vitamin K-dependent matrix Gla protein (MGP) is critically dependent on cell density in culture. Subculture of confluent NRK cells to 1/30 of the confluent cell density causes a 50- to 100-fold decline in MGP expression per cell within two days. MGP expression subsequently increases with increasing cell density and eventually attains a level of expression per cell at five days post-confluence that is over 2,000-fold greater than was seen in the cells two days after the 1 to 30 subculture. These reversible, density-dependent changes in MGP expression are far larger than have been previously reported for other secreted proteins and suggest that the as yet unknown function of MGP requires its expression at high cell density but not at low. We have also observed that human epidermal growth factor (EGF) causes a 20-fold reduction in MGP expression in post-confluent, non-dividing cultures and suggest that the suppression of MGP function at high density may be a prelude to cell migration or division in response to appropriate signals. J. Cell. Physiol. 171:125–134, 1997. © 1997 Wiley-Liss, Inc.     

Cholinergic regulation of pericyte-containing retinal microvessels

The aim of this study was to test the hypothesis that the neurotransmitter acetylcholine regulates the function of pericyte-containing retinal microvessels. A vasoactive role for acetylcholine is suggested by the presence of muscarinic receptors on pericytes, which are abluminally positioned contractile cells that may regulate capillary perfusion. However, little is known about the response of retinal microvessels to this neurotransmitter. Here we assessed the effects of cholinergic agonists on microvessels freshly isolated from the adult rat retina. Ionic currents were monitored via perforated patch pipettes; intracellular Ca(2+) levels were quantified with the use of fura 2, and microvascular contractions were visualized with the aid of time-lapse photography. We found that activation of muscarinic receptors elevated pericyte calcium levels, increased depolarizing Ca(2+)-activated chloride currents and caused pericytes to contract in a Ca(2+)-dependent manner. Most contracting pericytes were near capillary bifurcations. Contraction of a pericyte caused the adjacent capillary lumen to constrict. Thus acetylcholine may serve as a vasoactive signal by regulating pericyte contractility and thereby capillary perfusion in the retina.     

The effect of moderate hypothermia in acute ischemic stroke on pericyte migration: an ultrastructural study

Pericytes are essential components of the blood–brain barrier together with endothelial cells and astrocytes. Any disturbance of brain perfusion may result in blood–brain barrier dysfunction due to pericyte migration from the microvascular wall. The neuroprotective influence of hypothermia on ischemic brain injury has been clearly shown in models of both global and focal ischemia. Leakage of plasma proteins contributes to the extension of neuronal injury and hypothermia has a neuroprotective influence during the ischemic insult. This line of thinking impelled us to investigate the possible role of the pericytes in the occurrence of hypothermic protection during cerebral ischemia.In this study, we examined at the ultrastructural level the effect of moderate hypothermia on microvascular pericyte responses using a rat model of permanent middle cerebral artery occlusion. Twenty rats were divided into four groups. Middle cerebral artery occlusion was performed in all rats except the control group (first group), which was used to determine the pericyte morphology under normal conditions. In the second group, pericyte response to irreversible ischemia under normothermic conditions was examined at the end of the first hour. In the third group, pericyte response to hypoxia was examined under normothermic conditions three hours after ischemia. In the fourth group, temporalis muscle temperature was maintained at 27–29 °C for 1 h after middle cerebral artery occlusion and pericyte response was then examined at the ultrastructural level. In ischemic normothermic conditions at the end of the first hour (Group 2), a separation was observed between pericytes and the basement membrane and this was interpreted as pericyte migration from the microvascular wall. In ischemic normothermic conditions at the end of the third hour (Group 3), basement membrane disorganization and increased space between the basement membranes were seen in addition to the differentiation of second group. In ischemic hypothermic conditions at the end of the first hour (Group 4), pericyte separation or migration from basement membrane were not seen and the blood–brain barrier remained firm. These findings were interpreted by the authors as a possible relationship between pericyte behavior and neural protection during hypothermia. We suggest that hypothermia may delay the pericyte response but not necessarily attenuate it, and should be associated with hypothermic protection.     

The effect of moderate hypothermia in acute ischemic stroke on pericyte migration: An ultrastructural study

Pericytes are essential components of the blood–brain barrier together with endothelial cells and astrocytes. Any disturbance of brain perfusion may result in blood–brain barrier dysfunction due to pericyte migration from the microvascular wall. The neuroprotective influence of hypothermia on ischemic brain injury has been clearly shown in models of both global and focal ischemia. Leakage of plasma proteins contributes to the extension of neuronal injury and hypothermia has a neuroprotective influence during the ischemic insult. This line of thinking impelled us to investigate the possible role of the pericytes in the occurrence of hypothermic protection during cerebral ischemia.In this study, we examined at the ultrastructural level the effect of moderate hypothermia on microvascular pericyte responses using a rat model of permanent middle cerebral artery occlusion. Twenty rats were divided into four groups. Middle cerebral artery occlusion was performed in all rats except the control group (first group), which was used to determine the pericyte morphology under normal conditions. In the second group, pericyte response to irreversible ischemia under normothermic conditions was examined at the end of the first hour. In the third group, pericyte response to hypoxia was examined under normothermic conditions three hours after ischemia. In the fourth group, temporalis muscle temperature was maintained at 27–29 °C for 1 h after middle cerebral artery occlusion and pericyte response was then examined at the ultrastructural level. In ischemic normothermic conditions at the end of the first hour (Group 2), a separation was observed between pericytes and the basement membrane and this was interpreted as pericyte migration from the microvascular wall. In ischemic normothermic conditions at the end of the third hour (Group 3), basement membrane disorganization and increased space between the basement membranes were seen in addition to the differentiation of second group. In ischemic hypothermic conditions at the end of the first hour (Group 4), pericyte separation or migration from basement membrane were not seen and the blood–brain barrier remained firm. These findings were interpreted by the authors as a possible relationship between pericyte behavior and neural protection during hypothermia. We suggest that hypothermia may delay the pericyte response but not necessarily attenuate it, and should be associated with hypothermic protection.     

Lung, heart, and kidney express high levels of mRNA for the vitamin K-dependent matrix Gla protein. Implications for the possible functions of matrix Gla protein and for the tissue distribution of the gamma-carboxylase

We have used cDNA probes for two small vitamin K-dependent bone matrix proteins, bone Gla protein (BGP) and matrix Gla protein (MGP), to evaluate the possibility that either of these proteins might be synthesized by the various soft tissues previously shown to have gamma-carboxylase activity. BGP mRNA was found in bone but not in any of the soft tissues tested, a result which reinforces the view that plasma BGP is a specific marker for bone metabolism. In contrast, MGP mRNA was found in all rat tissues examined. Lung and heart have 10-fold higher levels of MGP mRNA than bone, and kidney has a 5-fold higher level. Despite the high levels of MGP mRNA in heart and kidney, these tissues contain 40-500-fold lower concentrations of MGP protein than bone. Immunofluorescence was used to identify cells that contain MGP in kidney, lung, heart, and spleen. In each tissue, MGP was found in discrete tissue-specific cell types. In most of the soft tissues tested, MGP is the first well characterized substrate for the vitamin K-dependent carboxylase found to be synthesized. The exceptionally broad tissue distribution for MGP synthesis demonstrates that the function of MGP is not specific to connective tissues, and the low levels of MGP antigen in soft tissues with high MGP mRNA levels indicate that MGP is unlikely to act solely by virtue of its accumulation in an extracellular matrix.     

Developmental appearance of matrix GLA protein during calcification in the rat

A marked dissociation has been observed between the timed accumulation in calcified tissues of two related vitamin K-dependent proteins, bone Gla protein (BGP) and the recently discovered matrix Gla protein (MGP). In long bone diaphyses, total levels of MGP were essentially equivalent in newborn, juvenile, and adult rats. In agreement with previous studies, BGP levels were only 5% of adult levels in newborn rat bones and increased to 90% of adult levels by 19 days of age. Similar results were obtained from the analysis of the longitudinal distribution of MGP and BGP in 14-day-old rat tibia, a bone in which new mineral is added rapidly at both growth plates. Again, MGP was essentially at the same level in the regions nearest the growth plates as in the midshaft while BGP levels were 10-fold lower in the regions nearest the growth plates. These differences in the timed accumulation of MGP and BGP in calcifying tissues indicate that MGP could function earlier in bone formation than does BGP. To further characterize the MGP antigen in bone, extracts from newborn and adult rat bones were chromatographed by gel filtration over Sephacryl S-200. All of the antigen extracted by formic acid and most of the antigen subsequently extracted by guanidine HCI emerged at the position expected for the 79-residue MGP. There was a significant difference in the fraction of total MGP which was extracted by guanidine HCI in newborn (50%) and adult (20%) bone. The radioimmunoassay for rat MGP which was developed for these studies employs rabbit antibody directed against calf MGP and rat MGP for standards and radioiodinated tracer. This assay has a sensitivity of 0.1 ng and does not detect rat or calf BGP.     

Endogenous Brain Pericytes Are Widely Activated and Contribute to Mouse Glioma Microvasculature

Glioblastoma multiforme (GBM) is the most common brain tumor in adults. It presents an extremely challenging clinical problem, and treatment very frequently fails due to the infiltrative growth, facilitated by extensive angiogenesis and neovascularization. Pericytes constitute an important part of the GBM microvasculature. The contribution of endogenous brain pericytes to the tumor vasculature in GBM is, however, unclear. In this study, we determine the site of activation and the extent of contribution of endogenous brain pericytes to the GBM vasculature. GL261 mouse glioma was orthotopically implanted in mice expressing green fluorescent protein (GFP) under the pericyte marker regulator of G protein signaling 5 (RGS5). Host pericytes were not only activated within the glioma, but also in cortical areas overlying the tumor, the ipsilateral subventricular zone and within the hemisphere contralateral to the tumor. The host-derived activated pericytes that infiltrated the glioma were mainly localized to the tumor vessel wall. Infiltrating GFP positive pericytes co-expressed the pericyte markers platelet-derived growth factor receptor-β (PDGFR-β) and neuron-glial antigen 2. Interestingly, more than half of all PDGFR-β positive pericytes within the tumor were contributed by the host brain. We did not find any evidence that RGS5 positive pericytes adopt another phenotype within glioma in this paradigm. We conclude that endogenous pericytes become activated in widespread areas of the brain in response to an orthotopic mouse glioma. Host pericytes are recruited into the tumor and constitute a major part of the tumor pericyte population.     

Characterization of microvascular cell cultures from normotensive and hypertensive rat brains: pericyte-endothelial cell interactions in vitro

We used specific markers and fluorescence microscopy to identify and characterize cerebrovascular cells. Cultures were derived from brain microvessels isolated from normotensive (Wistar Kyoto, WKY) and spontaneously hypertensive (SHR) rat brains prior to, coincident with and following the onset of chronic hypertension. Endothelial cells were characterized using di-acyl LDL and non-muscle isoactin-specific antibodies. Cerebrovascular pericytes were identified with the anti-muscle and non-muscle actin antibody staining. Using this combination of cell culture and fluorescence localization, we have been able to demonstrate that brain pericytes are tightly associated with the endothelial cells of the hypertensive-prone and hypertensive cell cultures, but not with the normotensive endothelial cultures. While the endothelial-pericyte ratio in the hypertensive-prone microvascular cultures was between 5:1 and 10:1, the number of pericytes associated with the hypertensive rat brain cultures increased two to five times (2:1-1:1). Muscle and non-muscle actin antibody staining localized the spindle-shaped pericytes of the hypertensive microvascular colonies. Pericytes were found overlaying and encircling the endothelial cells. Normotensive pericytes were not endothelial-associated. Whereas the hypertensive pericyte is devoid of stress fibers, the normotensive pericyte is a larger, spread-out cell possessing numerous stress fibers rich in muscle and non-muscle actin. These results provide the first evidence that the etiology and inception of cerebrovascular disease may be pericyte-related and suggest that pericyte contraction could play a pivotal role in regulating the flow of blood within the brain microcirculation.