Contractile proteins in pericytes at the blood-brain and blood-retinal barriers

Evidence from a variety of sources suggests that pericytes have contractile properties and may therefore function in the regulation of capillary blood flow. However, it has been suggested that contractility is not a ubiquitous function of pericytes, and that pericytes surrounding true capillaries apparently lack the machinery for contraction. The present study used a variety of techniques to investigate the expression of contractile proteins in the pericytes of the CNS. The results of immunocytochemistry on cryosections of brain and retina, retinal whole-mounts and immunoblotting of isolated brain capillaries indicate strong expression of the smooth muscle isoform of actin (α-SM actin) in a significant number of mid-capillary pericytes. Immunogold labelling at the ultrastructural level showed that α-SM actin expression in capillaries was exclusive to pericytes, and endothelial cells were negative. Compared to α-SM actin, non-muscle myosin was present in lower concentrations. By contrast, smooth muscle myosin isoforms, were absent. Pericytes were strongly positive for the intermediate filament protein vimentin, but lacked desmin which was consistently found in vascular smooth muscle cells. These results add support for a contractile role in pericytes of the CNS microvasculature, similar to that of vascular smooth muscle cells.     

Heterogeneity of microvascular pericytes for smooth muscle type alpha- actin

Microvascular pericytes are believed to be involved in various functions such as regulation of capillary blood flow and endothelial proliferation. Since pericytes represent a morphologically heterogeneous cell population ranging from circular smooth musclelike to elongated fibroblast-like morphology it is possible that regulation of blood flow (via contractility) and control of endothelial proliferation (as well as other metabolic functions) may be accomplished by different subsets of pericytes. In the present study we provide evidence for heterogeneity of pericytes at the molecular level by using two novel technical approaches. These are (a) immunostaining of whole mounts of the microvascular beds of the rat mesentery and bovine retina and (b) immunoblotting studies of microdissected retinal microvessels. We show that pericytes of true capillaries (midcapillaries) apparently lack the smooth muscle isoform of alpha-actin whereas transitional pericytes of pre- and postcapillary microvascular segments do express this isoform. Thus, regulation of capillary blood flow may be accomplished by the smooth muscle-related pre- and postcapillary pericytes whereas the nonmuscle pericytes of true capillaries may play a role in other functions.     

The expression of sarcomeric muscle-specific contractile protein genes in BC3H1 cells: BC3H1 cells resemble skeletal myoblasts that are defective for commitment to terminal differentiation

The BC3H1 cell line has been used widely as a model for studying regulation of muscle-related proteins, such as the acetylcholine receptor, myokinase, creatine kinase, and actin. These cells, derived from a nitrosourea-induced mouse brain neoplasm, have some of the morphological characteristics of smooth muscle and have been shown to express the vascular smooth muscle isoform of alpha-actin. To provide further information about the contractile protein phenotype of BC3H1 and to gain additional insights into the possible tissue of origin of these cells, we have examined the expression of a battery of contractile protein genes. During rapid growth, subconfluent BC3H1 cells express the nonmuscle isoform of alpha-tropomyosin (alpha-Tm) and the nonsarcomeric isoforms of myosin heavy and light chains (MHCs and MLCs, respectively), but do not express troponin T(TnT). However, when BC3H1 cells differentiate in response to incubation in serum-deprived medium or upon approaching confluence, they express TnT as well as sarcomeric muscle isoforms of MHC, MLC 2 and 3, alpha-Tm, and alpha-actin. These results suggest that BC3H1 is a skeletal muscle cell line of ectodermal origin that is defective for commitment to terminal differentiation.     

Pro-inflammatory effect of freshly solubilized beta-amyloid peptides in the brain

It has recently been shown that the level of soluble beta-amyloid (Abeta) peptides correlates well with the severity of synaptic loss and the density of neurofibrillary tangles observed in Alzheimer's disease (AD) brain. However, the biological activity of soluble forms of Abeta peptides in the brain remains to be determined. We have investigated ex vivo the effect of freshly solubilized Abeta1-40 peptides (fsAbeta) on prostaglandin E2 (PGE2) production in rat brain slices. PGE2 levels increased rapidly following treatment with fsAbeta, an effect that was prevented by SB202190, a selective inhibitor of p38 mitogen-activated protein kinase (p38 MAPK), and by NS-398, which preferentially inhibits cyclooxygenase-2 (COX-2) compared to COX-1. In an attempt to determine the cellular systems of the brain responsible for prostaglandin production in response to fsAbeta, the effect of fsAbeta was tested on isolated brain microvessels, primary cultures of brain smooth muscle cells/pericytes and endothelial cells, and a human neuron-like cell line (IMR32). Our data show that fsAbeta ex vivo can stimulate prostaglandin accumulation in incubates of isolated rat brain microvessels. In addition, fsAbeta appears to cause a concentration-dependent enhancement of prostaglandin accumulation in primary cultures of brain microvessel-derived smooth muscle cells/pericytes but not of brain endothelial cells. Finally, fsAbeta also stimulated PGF2alpha accumulation in cultures of differentiated IMR32 cells, but to a lesser extent than in brain smooth muscle cell/pericyte cultures. Deposition of aggregated forms of Abeta in the brain has been thought to trigger an inflammatory response which accompanies the neuropathologic events of AD. Our data provide evidence that fsAbeta triggers a pro-inflammatory reaction in rat brain, and suggest that the cerebrovasculature may constitute an important source of pro-inflammatory eicosanoids.     

Platelet-derived growth factor receptor-alpha is a key determinant of smooth muscle alpha-actin filaments in bone marrow-derived mesenchymal stem cells

Smooth muscle alpha-actin filaments are a defining feature of mesenchymal stem cells, and of mesenchyme-derived contractile smooth muscle cells, pericytes and myofibroblasts. Here, we show that adult bone marrow-derived mesenchymal stem cells express abundant cell surface platelet-derived growth factor receptor-alpha, having a high ratio to platelet-derived growth factor receptor-beta. Signaling through platelet-derived growth factor receptor-alpha increases smooth muscle alpha-actin filaments by activating RhoA, which results in Rho-associated kinase (ROCK)-dependent cofilin phosphorylation, enhancing smooth muscle alpha-actin filament polymerization, and also upregulates smooth muscle alpha-actin expression. In contrast, platelet-derived growth factor receptor-beta signaling strongly upregulates RhoE, which inhibits ROCK activity, promoting smooth muscle alpha-actin filament depolymerization. This study thus provides new insights into the distinct roles of platelet-derived growth factor receptor-alpha and -beta signaling in regulating the adult mesenchymal stem cell contractile cytoskeleton.     

Contractile proteins in pericytes. I. Immunoperoxidase localization of tropomyosin

In these studies we have compared the relative amounts and isoforms of tropomyosin in capillary and postcapillary venule pericytes, endothelial cells, and vascular smooth muscle cells in four rat microvascular beds: heart, diaphragm, pancreas, and the intestinal mucosa. The results, obtained by in situ immunoperoxidase localization, indicate that (a) tropomyosin is present in capillary and postcapillary venule pericytes in relatively high concentration; (b) the tropomyosin content of pericytes appears to be somewhat lower than in vascular smooth muscle cells but higher than in endothelia and other vessel-associated cells; and (c) pericytes, unlike endothelia and other nonmuscle cells, contain detectable levels of tropomyosin immunologically related to the smooth muscle isoform. These results and our previous findings concerning the presence of a cyclic GMP-dependent protein kinase (Joyce, N., P. DeCamilli, and J. Boyles, 1984, Microvasc. Res. 28:206-219) in pericytes demonstrate that these cells contain significant amounts of at least two proteins important for contraction regulation. Taken together, the evidence suggests that pericytes are contractile elements related to vascular smooth muscle cells, possibly involved, as are the latter, in the regulation of blood flow through the microvasculature.     

Pericytes of the brain microvasculature express gamma-glutamyl transpeptidase.

The expression of gamma-glutamyl transpeptidase (GGT) is a specific property of the brain capillary endothelium that constitutes the blood-brain barrier. We report here the detection of GGT, not only in endothelial cells, but also in pericytes, demonstrating that a brain capillary-specific pericyte population exists. We raised antibodies to GGT using a porcine brain microvessel GGT-protein-A (staphylococcal protein A) fusion protein as antigen which was expressed in Escherichia coli. The immunohistochemical analysis of the subcapillary distribution of GGT in porcine brain cortex and cerebellum sections by both light and electron microscopy revealed the expression of GGT in the capillary-adjacent pericytes in addition to the GGT-positive endothelial layer. We confirmed these data for cultured porcine brain microvascular endothelial cells and pericytes. GGT immunofluorescence could be detected in both cell types in culture. Endothelial cells exhibited a weak staining, whereas pericytes were strongly positive for GGT. Due to the high phagocytotic activity of pericytes and their location on the abluminal surface of the microvessels, we propose a possible protective or detoxifying function of GGT in cerebrovascular pericytes.     

Characterization of contractile function and expression of muscarinic receptors,G proteins and adenylate cyclase in cultured tracheal smooth muscle of Swine

Smooth muscle cells lose their contractile function and phenotype very rapidly when placed in culture. During organ culture of smooth muscle strips, phenotype is lost more slowly. In the present studies, we established an organ culture model to study contractile function and expression of muscarinic receptors, G proteins and adenylyl cyclase in different serum concentrations in tracheal smooth muscle from swine. The results show that contractile function and the amounts of M(3) receptors, G proteins and adenylyl cyclase were maintained for up to 5 days in culture. The expression of M(2) receptors was significantly decreased in culture when compared to freshly isolated muscles. Maximal isometric tension was significantly increased in cultured muscles compared with freshly isolated muscles. Different serum concentrations did not significantly affect contractile function and expression of muscarinic receptors, G proteins and adenylyl cyclase. In conclusion, our studies suggest that cultured smooth muscle might be used as a model to study the regulation of contractile function of smooth muscle by various signal transduction pathways.     

Peripheral nerve pericytes originating from the blood-nerve barrier expresses tight junctional molecules and transporters as barrier-forming cells

The objective of this study was to establish pure blood-nerve barrier (BNB)-derived peripheral nerve pericyte cell lines and to investigate their unique properties as barrier-forming cells. We isolated peripheral nerve, brain, and lung pericytes from transgenic rats harboring the temperature-sensitive simian virus 40 large T-antigen gene. These cell lines expressed several pericyte markers such as alpha-smooth muscle actin, NG2, osteopontin, and desmin, whereas they did not express endothelial cell markers such as vWF and PECAM. In addition, these cell lines expressed several tight junction molecules such as occludin, claudin-12, ZO-1, and ZO-2. In particular, the expression of occludin was detected in peripheral nerve and brain pericytes, although it was not detected in lung pericytes by a Western blot analysis. An immunocytochemical analysis confirmed that occludin and ZO-1 were localized at the cell-cell boundaries among the pericytes. Brain and peripheral nerve pericytes also showed significantly higher trans-pericyte electrical resistance values and lower inulin clearances than lung pericytes. We considered that occludin localized at the cell-cell boundaries among the pericytes might mechanically stabilize the microvessels of the BNB and the blood-brain barrier. Furthermore, we also showed that these cell lines expressed many barrier-related transporters. ABCG2, p-gp, MRP-1, and Glut-1 were detected by a Western blot analysis and were observed in the cytoplasm and outer membrane by an immunocytochemical analysis. These transporters on pericytes might facilitate the peripheral nerve-to-blood efflux and blood-to-peripheral nerve influx transport of substrates in cooperation with those on endothelial cells in order to maintain peripheral nerve homeostasis.     

The cytoarchitecture of the wall and the innervation pattern of the microvessels in the rat mammary gland: a scanning electron microscopic observation

This report describes the morphology of the smooth muscle cells, pericytes, and the perivascular autonomic nerve plexus of blood vessels in the rat mammary gland as visualized by scanning electron microscopy after removal of connective-tissue components. From the differences in cellular morphology, eight vascular segments were identified: 1) terminal arterioles (10-30 microns in outer diameter), with a compact layer of spindle-shaped and circularly oriented smooth muscle cells; 2) precapillary arterioles (6-12 microns), with a less compact layer of branched smooth muscle cells having circular processes; 3) arterial capillaries (4-7 microns), with " spidery " pericytes having mostly circularly oriented processes; 4) true capillaries (3-5 microns), with widely scattered pericytes having longitudinal and several circular processes; 5) venous capillaries (5-8 microns), with spidery pericytes having ramifying processes; 6) postcapillary venules (10-40 microns), with clustered spidery pericytes; 7) collecting venules (30-60 microns), with a discontinuous layer of circularly oriented and elongated stellate or branched spindle-shaped cells which may represent primitive smooth muscle cells; and 8) muscular venules (over 60 microns), with a discontinuous layer of ribbon-like smooth muscle cells having a series of small lateral projections. No focal precapillary sphincters were found. The nerve plexus appears to innervate terminal arterioles densely and precapillary arterioles less densely. Fine nerve fibers are only occasionally associated with arterial capillaries. Venous microvessels in the rat mammary gland seemingly lack innervation.     

Alpha-smooth muscle actin, a differentiation marker of smooth muscle cells, is present in microfilamentous bundles of pericytes

alpha-Smooth muscle (alpha-sm) actin, an isoform typical of smooth muscle cells (SMC) and present in high amounts in vascular SMC, was demonstrated in the cytoplasm of pericytes of various rat and human organs by means of immunocytochemistry at the electron microscopic level. In SMC and pericytes, alpha-sm actin was localized in microfilament bundles, strengthening the assumption that it is the functional isoform in these cell types and supporting the assumption that pericytes exert contractile functions.     

Pericyte production of cell-associated VEGF is differentiation-dependent and is associated with endothelial survival

Pericytes have been suggested to play a role in regulation of vessel stability; one mechanism for this stabilization may be via pericyte-derived vascular endothelial growth factor (VEGF). To test the hypothesis that differentiation of mesenchymal cells to pericytes/smooth muscle cells (SMC) is accompanied by VEGF expression, we used endothelial cell (EC) and mesenchymal cell cocultures to model cell-cell interactions that occur during vessel development. Coculture of EC and 10T1/2 cells, multipotent mesenchymal cells, led to induction of VEGF expression by 10T1/2 cells. Increased VEGF expression was dependent on contact between EC-10T1/2 and was mediated by transforming growth factorbeta (TGFbeta). A majority of VEGF produced in coculture was cell- and/or matrix-associated. Treatment of cells with high salt, protamine, heparin, or suramin released significant VEGF, suggesting that heparan sulfate proteoglycan might be sequestering some of the VEGF. Inhibition of VEGF in cocultures led to a 75% increase in EC apoptosis, indicating that EC survival in cocultures is dependent on 10T1/2-derived VEGF. VEGF gene expression in developing retinal vasculature was observed in pericytes contacting newly formed microvessels. Our observations indicate that differentiated pericytes produce VEGF that may act in a juxtacrine/paracrine manner as a survival and/or stabilizing factor for EC in microvessels.     

PDGFRβ signaling regulates mural cell plasticity and inhibits fat development

Mural cells (pericytes and vascular smooth muscle cells) provide trophic and structural support to blood vessels. Vascular smooth muscle cells alternate between a synthetic/proliferative state and a differentiated/contractile state, but the dynamic states of pericytes are poorly understood. To explore the cues that regulate mural cell differentiation and homeostasis, we have generated conditional knockin mice with activating mutations at the PDGFRβ locus. We show that increased PDGFRβ signaling drives cell proliferation and downregulates differentiation genes in aortic vascular smooth muscle. Increased PDGFRβ signaling also induces a battery of immune response genes in pericytes and mesenchymal cells and inhibits differentiation of white adipocytes. Mural cells are emerging as multipotent progenitors of pathophysiological importance, and we identify PDGFRβ signaling as an important in vivo regulator of their progenitor potential.     

Spontaneous fibroblast‐derived pericyte recruitment in a human tissue‐engineered angiogenesis model in vitro

Cooperation between endothelial cells and pericytes is essential to the stabilization and maturation of blood microvessels. We developed a unique in vitro tissue‐engineered model to study angiogenesis. The human endothelialized reconstructed connective tissue model promotes the formation of a three‐dimensional branching network of capillary‐like tubes (CLT) with closed lumens. The purpose of this work was to investigate whether pericytes were spontaneously recruited around CLT in the model. We demonstrated that smooth muscle α‐actin (SMA)‐positive cells were found closely associated with PECAM‐1‐positive capillaries in the model. Twelve percent (±2.6) of SMA‐positive cells were detected along with 15% (±1.64) von Willebrand factor‐positive endothelial cells in the culture system after 31 days of in vitro maturation. Conversely, no SMA‐positive cells were detected in reconstructed connective tissues made solely of fibroblasts. Knowing that PDGF is a major factor in the recruitment of pericytes, we showed that blockade of the PDGFB receptor using the inhibitor AG1296 induced an overall 5, 2.6, and 2.4‐fold decrease in the SMA‐positive cells, von Willebrand factor‐positive cells, and number of capillaries, respectively. Using combinations of human GFP‐positive fibroblasts and endothelial cells, we demonstrated that pericytes were recruited from the fibroblast population in the model. In conclusion, our tissue‐engineered culture system promotes the spontaneous formation of a network of capillaries and the recruitment of pericytes derived from fibroblasts. Since pericytes are essential components of the blood microvasculature, this culture system is a powerful model to study angiogenesis and endothelial cell/pericyte interactions in vitro. J. Cell. Physiol. 227: 2130–2137, 2012. © 2011 Wiley Periodicals, Inc.     

Immunocytochemical studies of desmin and vimentin in pericapillary cells of chicken

The composition of intermediate filaments in pericytes was examined by immunofluorescent and immunoelectron microscopic labeling of frozen sections of various chicken microvascular beds in situ. Pericytes in capillaries of cardiac muscle, exocrine pancreas, and kidney (peritubular capillary) were found to contain both desmin and vimentin. In some capillaries where pericytes do not exist, cells apposed to endothelial cells--the Ito cell in the hepatic sinusoid and the reticular cell in the splenic sinusoid--were shown to contain both of the intermediate filament proteins. In contrast, podocytes and mesangial cells around renal glomerular capillaries contained only vimentin. The presence of desmin supports the hypothesis that pericytes may have a contractile apparatus similar to that of vascular smooth muscle cells. Our results also revealed that even in microvascular beds where pericytes are not found, cells having both desmin and vimentin exist next to endothelial cells and may assume similar functions to pericytes.     

Contractile proteins in pericytes. II. Immunocytochemical evidence for the presence of two isomyosins in graded concentrations

This paper describes the localization of isomyosins in the pericytes of four rat microvascular beds: heart, diaphragm, pancreas, and the intestinal mucosa, by use of immunoperoxidase techniques and IgGs specific for either nonmuscle or smooth muscle isoforms. Based on the semiquantitative nature of the peroxidatic reaction, we concluded that the amount and distribution of these isoforms vary with the microvascular bed and also with vascular segments within the same bed. In the pericytes of small capillaries, nonmuscle isomyosin is the predominant form, whereas the smooth muscle isomyosin is present in very low concentration. A reversed relationship is found in the pericytes associated with larger capillaries and postcapillary venules. These results, taken together with previous findings on actin (Herman, I., and P. A. D'Amore, 1983, J. Cell Biol. 97:278a), tropomyosin (Joyce, N. C., M. F. Haire, and G. E. Palade, 1985, J. Cell Biol. 100:1379-1386), and cyclic GMP-dependent protein kinase (Joyce, N., P. DeCamilli, and J. Boyles, 1984, Microvasc. Res. 28:206-219), indicate that pericytes contain proteins essential for contraction in higher concentration than any other cells associated with the microvasculature, except smooth muscle cells. Pericytes appear to be, therefore, cells differentiated for a contractile function within the microvasculature.     

Expression of contractile proteins α-actin and myosin of smooth muscle cells and of type IV collagen in human placenta at placental insufficiency in III trimester of pregnancy

Changes of expression of contractile proteins (smooth muscle cell α-actin and myosin) and of type IV collagen in villous stroma of human placenta were studied at the diagnosed placental insufficiency (PI) in III trimester of pregnancy. The study revealed pronounced disturbances of expression of contractile proteins and type IV collagen at PI. It is shown that in perivascular sheaths of vessels of stem and intermediate villi there is present a much greater amount of cells expressing smooth muscle actin and myosin. These cells are arranged by the denser concentric layers and more compactly than in norm and fill the intervascular space inside the villi. The width of perivascular sheaths of vessels is higher, while vascular lumens are lower than in norm. In terminal villi the capillary walls are thickened and the number of pericytes immunopositive against the smooth muscle cell α-actin and myosin as well as type IV collagen is increased. The change of synthesis of the cytoskeletal contractile proteins and type IV collagen is shown to lead to structural disturbances of villi of different types and of perivascular areas and vessels, which doubtlessly indicates their participation in pathogenesis of placental dysfunction and of disturbance of placental hemodynamics.     

Role of PDGF-B and PDGFR-beta in recruitment of vascular smooth muscle cells and pericytes during embryonic blood vessel formation in the mouse.

Development of a vascular system involves the assembly of two principal cell types - endothelial cells and vascular smooth muscle cells/pericytes (vSMC/PC) - into many different types of blood vessels. Most, if not all, vessels begin as endothelial tubes that subsequently acquire a vSMC/PC coating. We have previously shown that PDGF-B is critically involved in the recruitment of pericytes to brain capillaries and to the kidney glomerular capillary tuft. Here, we used desmin and alpha-smooth muscle actin (ASMA) as markers to analyze vSMC/PC development in PDGF-B-/- and PDGFR-beta-/- embryos. Both mutants showed a site-specific reduction of desmin-positive pericytes and ASMA-positive vSMC. We found that endothelial expression of PDGF-B was restricted to immature capillary endothelial cells and to the endothelium of growing arteries. BrdU labeling showed that PDGFR-beta-positive vSMC/PC progenitors normally proliferate at sites of endothelial PDGF-B expression. In PDGF-B-/- embryos, limb arterial vSMC showed a reduced BrdU-labeling index. This suggests a role of PDGF-B in vSMC/PC cell proliferation during vascular growth. Two modes of vSMC recruitment to newly formed vessels have previously been suggested: (1) de novo formation of vSMC by induction of undifferentiated perivascular mesenchymal cells, and (2) co-migration of vSMC from a preexisting pool of vSMC. Our data support both modes of vSMC/PC development and lead to a model in which PDGFR-beta-positive vSMC/PC progenitors initially form around certain vessels by PDGF-B-independent induction. Subsequent angiogenic sprouting and vessel enlargement involves PDGF-B-dependent vSMC/PC progenitor co-migration and proliferation, and/or PDGF-B-independent new induction of vSMC/PC, depending on tissue context.     

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.     

Recruitment of Type I Collagen Producing Cells from the Microvasculaturein Vitro

We have previously suggested that microvascular pericytes can differentiate into fibroblast-like, type I collagen-producing cells during excessive dermal scarringin vivo(Sundberg, C., Ivarsson, M., Gerdin, B., and Rubin, K.,Lab. Invest.74, 454–468, 1996). Here we have investigated to what extent pericytes derived from microvessels of full-term human placenta exhibited this capacityin vitro.Vascular fragments of human term placenta were isolated by enzymatic digestion and separation in Percoll. Their microvascular origin was ascertained by confocal microscopy using antibodies specific for endothelial cells (PAL-E) and pericytes (high-molecular-weight–melanoma-associated antigen). When vascular fragments were culturedin vitro,large cells with irregular edges migrated out from the fragments. After 4–6 days in culture, these cells started to proliferate and reached near confluence after approximately 8 days. The cultures were not overgrown by clones of cells with a high proliferative capacity, as demonstrated by cell membrane fluorescence staining and Ki67 expression. Expression of PAL-E, high-molecular-weight–melanoma-associated antigen, smooth muscle α-actin, desmin, and collagen synthesis (prolyl-4-hydroxylase and type I procollagen, as well as collagen pro-α1(I) mRNA) were followed during a culture period of 8 days. The cells were PAL-E negative but expressed high-molecular-weight–melanoma-associated antigen, smooth muscle α-actin, and desmin. Based on morphology and expression of the various markers, the outgrowing cells were identified as pericytes. With time in culture the cells decreased their expression of all these markers and increased their expression of prolyl-4-hydroxylase, type I procollagen, and collagen pro-α1(I) mRNA. Metabolic labeling and SDS–PAGE analysis of labeled proteins revealed that type I collagen was the major collagen species synthesized in the cultures. Our results support the hypotheses that pericytes can leave the vasculature and differentiate into collagen-producing cells and that cultured “fibroblasts” are derived from pericytes.