CYR61 (CCN1) Is Essential for Placental Development and Vascular Integrity

CYR61 (CCN1) is a member of the CCN family of secreted matricellularproteins that includes connective tissue growth factor (CCN2),NOV (CCN3), WISP-1 (CCN4), WISP-2 (CCN5), and WISP-3 (CCN6).First identified as the product of a growth factor-inducibleimmediate-early gene, CYR61 is an extracellular matrix-associatedangiogenic inducer that functions as a ligand of integrin receptorsto promote cell adhesion, migration, and proliferation. Aberrantexpression of Cyr61 is associated with breast cancer, woundhealing, and vascular diseases such as atherosclerosis and restenosis.To understand the functions of CYR61 during development, wehave disrupted the Cyr61 gene in mice. We show here that Cyr61-nullmice suffer embryonic death: $~$ 30% succumbed to a failure in chorioallantoicfusion, and the reminder perished due to placental vascularinsufficiency and compromised vessel integrity. These findingsestablish CYR61 as a novel and essential regulator of vasculardevelopment. CYR61 deficiency results in a specific defect invessel bifurcation (nonsprouting angiogenesis) at the chorioallantoicjunction, leading to an undervascularization of the placentawithout affecting differentiation of the labyrinthine syncytiotrophoblasts.This unique phenotype is correlated with impaired Vegf-C expressionin the allantoic mesoderm, suggesting that CYR61-regulated expressionof Vegf-C plays a role in vessel bifurcation. The genetic andmolecular basis of vessel bifurcation is presently unknown,and these findings provide new insight into this aspect of angiogenesis.

INTRODUCTION

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Introduction

Development of the vascular system during embryogenesis occursin two distinct processes: vasculogenesis, the formation ofblood vessels in situ from angioblasts, and angiogenesis, theformation of blood vessels by sprouting from preexisting ones(38, 50). Successful vessel formation requires the orchestratedexecution of multiple cellular processes—including themigration, proliferation, differentiation, and tube formationof vascular cells—that are coordinated with remodelingof the extracellular matrix (ECM). Many aspects of these processesare in turn subject to regulation by components of the ECM (44).

CYR61 (CCN1) is a novel ECM-associated angiogenic regulatorof the CCN family, sharing a $~$ 40 to 50% amino acid sequence homologywith connective-tissue growth factor (CTGF) (CCN2), NOV (CCN3),WISP-1 (CCN4), WISP-2 (CCN5), and WISP-3 (CCN6) (7, 32, 37).Both CYR61 and CTGF are encoded by growth factor-inducible immediate-earlygenes, which are rapidly activated at the transcriptional levelwhen responsive cells are stimulated with serum growth factorssuch as fibroblast growth factor, platelet-derived growth factor,and tumor transforming growth factor ß (31, 36, 40).CCN proteins are organized into four conserved modular domainsthat share sequence similarities with insulin-like growth factor-bindingproteins (IGFBPs), the von Willebrand factor type C repeat,the thrombospondin type 1 repeat, and the carboxyl termini ofseveral extracellular mosaic proteins such as mucins and slit(5). The prominent structural similarities to ECM componentssuggest that CCN proteins resemble the functionally diversematricellular proteins, which are also characterized by a mosaicof matrix protein domains (6). Despite discernible sequencesimilarity to IGFBPs, CYR61 is unlikely to bind insulin-likegrowth factor, since the specific residues in IGFBPs that interactwith insulin-like growth factor are not conserved in CCN proteins(23, 25).

A cysteine-rich, secreted heparin-binding protein, CYR61 mediatescell adhesion, stimulates cell migration, and enhances growthfactor-stimulated cell proliferation in culture (27, 28). Asan adhesion substrate, CYR61 promotes cell spreading and adhesivesignaling, resulting in the activation of focal adhesion kinase,paxillin, and Rac (9). CYR61 can regulate the expression ofgenes involved in angiogenesis and matrix remodeling, includingvascular endothelial growth factor A (VEGF-A), VEGF-C, typeI collagen, matrix metalloproteinase 1 (MMP1), and MMP3 (10).Furthermore, CYR61 induces neovascularization in corneal implants(3). These activities, as well as the expression of Cyr61 ingranulation tissue during wound healing, support a functionfor CYR61 in wound repair (10). Mechanistically, CYR61 functionsas a ligand of multiple integrin receptors, including integrins ${alpha}$ _vß₃, ${alpha}$ _vß₅, ${alpha}$ ₆ß₁, ${alpha}$ _IIbß₃,and ${alpha}$ _Mß₂, which mediate many of its activities in variouscell types (11, 16, 24, 26, 42). Integrins and their ligandsin the ECM have been implicated in angiogenesis and other morphogeneticevents (22, 44). The specific roles of CYR61 in development,however, have remained unknown heretofore.

Abnormal angiogenesis contributes to the development and progressionof a number of pathological conditions (15). Consistent witha role in angiogenesis, aberrant expression of Cyr61 is associatedwith vascular diseases such as atherosclerosis, restenosis,and later-stage human breast cancer (10, 17, 41, 42, 47, 49).Furthermore, expression of Cyr61 can promote tumor growth andvascularization (3, 49). Aside from their association with diseasestates, CYR61 and other CCN family members have been suggestedto play an important role in embryonic development based ontheir expression in the fetal cardiovascular, skeletal, andnervous systems (Fig. 2J) (30, 32, 37). To determine the functionsof CYR61 during development, we disrupted Cyr61 in mice by genetargeting. We show here that Cyr61 is an essential gene thatplays novel roles in vascular development, regulating both vesselbifurcation in the placenta and large vessel integrity in theembryo. Phenotypes of Cyr61 mutants bear intriguing similaritiesto those of mice lacking ${alpha}$ _v integrins (4), which is consistentwith the hypothesis that CYR61 may act as a physiological ligandof ${alpha}$ _v integrins during development.

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FIG. 2. Embryonic lethality in Cyr61-deficient mutants. (A) Chorioallantoic fusion occurred in WT embryos by E10.5, with the allantois (black arrowhead) attached to the placenta (white arrow). In some Cyr61^-/- embryos, the allantois (white arrowhead) failed to fuse with the placenta, resulting in atrophy. (B) WT embryos at E11.5 showing successful chorioallantoic fusion and healthy placenta. (C) Some Cyr61^-/- embryos at E11.5 showing successful chorioallantoic fusion but displaying vascular deficiency in the chorionic plate, resulting in a relatively pale placenta. (D) WT E14.5 embryo. (E) Cyr61^-/- embryo (littermate of that shown in panel D) that developed to E14.5, exhibiting edema (arrowhead) and hemorrhage (arrow). (F) Other embryos obtained from E14.5 litters. These embryos were moribund, showing evidence of hemorrhage from the umbilical artery, filling the amnion. Vascular structure appeared normal in hematoxylin-stained yolk sacs from E10.5 Cyr61^+/-(G) and Cyr61^-/- (H) embryos. Bars in panels G and H, 200 µm. (I) Expression of ß-galactosidase driven by the Cyr61 promoter. Expression was detected in both the chorion (white arrowhead) and the allantois (white arrow) at E7.5, when the allantois approached the chorion for eventual fusion. LacZ expression was also detected in the notochordal plate (black arrow). Bar, 10 µm. (J) Whole-mount staining of an E13.5 embryo showing LacZ expression in the sclerotomes of somites, endochondral bones (including those in fore- and hind limbs, digits, and ribs), and large arteries.

MATERIALS AND METHODS

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Materials and Methods

Gene targeting. The Cyr61 genomic DNA used in the targeting construct was clonedfrom a 129SvJ library (Stratagene). A LacZ-PGK-neo cassettewas flanked by two Cyr61 genomic DNA fragments, a 1.7-kb fragmentincluding the promoter region at the 5' end and a 3.7-kb fragmentcontaining part of the coding region at the 3' end. A PGK-tkcassette was positioned at the 5' end of the promoter fragmentwith reversed transcription orientation. Transfection of thetargeting construct DNA and the selection of the mutant embryonicstem (ES) cells (J1) were performed as described previously(33), except that the 2'-fluoro-2'-deoxy-1-ß-D-arabinofuranosyl-5-iodouracil(FIAU) was replaced by 2 µM ganciclovir (a gift from Roche).Verification of the positive ES cell clones and genotyping ofmice were carried out by Southern blot analysis and/or PCR byfollowing standard procedures (20) (Fig. 1B and C). Two mutantES cell clones, 2A11 and 4B7, were used to generate chimericmice by blastocyst injection. Both clones yielded mutant micewith similar phenotypes, irrespective of their genetic background(C57BL/6J or 129SvJ). Most of the analysis was done on embryosderived from intercrosses with heterozygotes that were backcrossedwith C57BL/6J at least twice. To verify that the targeted Cyr61allele is null, mouse embryonic fibroblasts were isolated fromembryos on embryonic day 11.5 (E11.5 embryos), placed in culture,and stimulated with serum for 60 min. Total cell lysates weresubjected to Western blot analysis with anti-CYR61 antiserum.

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FIG. 1. Gene targeting of Cyr61 in mice. (A) Targeting vector. The Cyr61 genomic locus was disrupted by replacement of the XhoI-SmaI fragment, which includes the translation start site, exon I, and half of exon II, with a LacZ-PGK-neo cassette after homologous recombination. B, BamHI; R, EcoRI; S, SmaI; X, XhoI. (B) Southern blot analysis. DNA isolated from ES cell clones was digested with EcoRI and probed with a BamHI-EcoRI fragment (panel A), yielding 6.4- and 7.4-kb bands for the WT and targeted alleles, respectively. (C) PCR. Homologous recombination was confirmed by using a PCR primer pair, P1 and P1' (panel A), to amplify a 2.1-kb fragment specific to the targeted allele. ES cell clones 2A11 and 4B7 showed the targeted allele. Additionally, PCR primer pairs (P2-P2' and P2-P1') yielded a 388-bp fragment and a 600-bp fragment from the WT and targeted alleles, respectively (data not shown). (D) Western blot analysis. Mouse embryo fibroblasts isolated from E11.5 embryos were stimulated with 10% serum for 1 h; total cell lysates were probed with anti-CYR61 antibodies after electrophoresis. KO, knockout.

Histology, immunohistochemistry, and the terminal deoxynucleotidyltransferase-mediated dUTP-biotin nick end labeling (TUNEL) assay. Embryos were fixed in buffered 10% formalin and embedded inparaffin, and 7-µm-thick sections were prepared for standardhematoxylin and eosin staining. Yolk sacs were fixed in bufferedformalin and stained with hematoxylin. For immunostaining, embryoswere fixed in 4% paraformaldehyde; embedded in OCT; sectioned(7 µm); probed with monoclonal anti-platelet endothelialcell adhesion molecule 1 (anti-PECAM-1; Pharmingen), monoclonalanti- ${alpha}$ -smooth-muscle actin (clone 1A4; Sigma), monoclonal anti-desmin(ZC18; Zymed), affinity-purified polyclonal anti-VEGF-A (sc-1836;Santa Cruz), and anti-VEGF-C (sc-9047; Santa Cruz) antibodies;and detected with either peroxidase (PECAM-1, VEGF-A, and VEGF-C)or alkaline phosphatase ( ${alpha}$ -smooth-muscle actin and desmin) chromogen.All histological and immunohistochemical analyses were carriedout on embryos that were still alive at the time of harvest.

To detect the expression of LacZ, Cyr61^+/-embryos were processedand stained as described previously (20). TUNEL assays weredone on cryopreserved sections ( $~$ 7 µm thickness) with afluorescein in situ cell death detection kit (Roche MolecularBiochemicals) by following the manufacturer's protocol.

RNA analysis. To study the effects of CYR61 on Vegf-C gene expression, mouseembryonic fibroblasts isolated from E14.5 wild-type (WT) CD-1embryos were serum starved for 24 h and then treated with 10µg of purified recombinant mouse CYR61/ml (27) in serum-freemedia for various times. Total cellular RNA was isolated, resolvedon an agarose-formaldehyde gel, and blotted onto a nylon membraneby following standard protocols. Partial mouse Vegf-C cDNA wasgenerated by reverse transcription-PCR with primers correspondingto nucleotides 202 to 222 and 757 to 779 (GenBank accessionno. U73620). Human GAPDH cDNA was purchased from the AmericanType Culture Collection. Probes were radiolabeled by enzymaticincorporation of [³²P]dCTP. The blots were hybridized to thelabeled probes and washed at high stringency (0.1x SSC [1x SSCis 0.15 M NaCl plus 0.015 M sodium citrate], 0.1% sodium dodecylsulfate; 65°C), and the hybridization signal was quantifiedby the Phosphorimager (Molecular Dynamics) apparatus.

Transmission electron microscopy. Placentae were harvested and immersion fixed with 2.5% glutaraldehydeovernight at 4°C. Following fixation, the tissue was washedthree times in phosphate-buffered saline and then postfixedin aqueous 1% OsO4-1% K₃Fe(CN)₆ for 1 h. Following three washeswith phosphate-buffered saline, the tissue was dehydrated througha graded series of 30 to 100% ethanol-100% propylene oxide andthen infiltrated in a 1:1 mixture of propylene oxide-Polybed812 epoxy resin (Polysciences, Warrington, Pa.) for 1 h. Afterseveral changes of 100% resin over 24 h, pellets were embeddedin molds and cured at 37°C overnight, followed by additionalhardening at 65°C for two more days. Ultrathin (60-nm) crosssections of placenta were collected on copper grids and stainedwith 2% uranyl acetate in 50% methanol for 10 min, followedby staining with 1% lead citrate for 7 min. Sections were photographedby using a JEM 1210 transmission electron microscope (JEOL,Peabody, Ma.) at 80 kV onto electron microscope film (ESTARthick base; Kodak, Rochester, N.Y.).

RESULTS

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Results

Disruption of murine Cyr61 causes embryonic lethality. We disrupted Cyr61 in mice by homologous recombination, replacingthe translation start site and exon 1 through part of exon 2with the LacZ-neomycin resistance cassette (Fig. 1A). The targetingconstruct was transfected into J1 ES cells, and recombinantswere identified by Southern blot and PCR analyses (Fig. 1B and C,respectively). The resulting targeted allele expressed lacZunder the Cyr61 promoter while shifting the remaining Cyr61coding sequence out of frame. Chimeric mice capable of germline transmission were generated with two independently targetedES cell clones, and the offspring of both yielded mutant micewith similar phenotypes. Heterozygous Cyr61^+/-mice expressedß-galactosidase in a manner that accurately recapitulatesexpression of the Cyr61 gene, as judged by comparing ß-galactosidasestaining patterns with those from the localization of Cyr61mRNA and protein by in situ hybridization and immunohistochemistry(27, 30, 35, 48). To confirm that the targeted allele is null,embryo fibroblasts were isolated from Cyr61^-/- embryos and theirheterozygous and WT littermates. WT embryo fibroblasts expresseda robust amount of Cyr61 mRNA upon serum stimulation; this wasexpected since Cyr61 is an immediate-early gene inducible byserum growth factors (36). No Cyr61 mRNA was detected in Cyr61^-/-fibroblasts, even after serum stimulation (data not shown).Likewise, immunoblot analysis showed that CYR61 was completelyabsent from Cyr61^-/- embryo fibroblasts, confirming that thetargeted allele is indeed null (Fig. 1D). Consistent with genedosage effects, the level of CYR61 in Cyr61^+/-fibroblasts was $~$ 50% of that in Cyr61^+/+ fibroblasts.

Whereas Cyr61 heterozygotes were viable and fertile, all Cyr61^-/-mice died prenatally or perinatally and none survived beyond24 h of birth (141 Cyr61^+/+ mice, 225 Cyr61^+/-mice, and 0 Cyr61^-/-mice). To determine the onset of embryonic lethality, we isolatedand genotyped fetuses at various stages of gestation. Intercrossesof heterozygotes yielded WT, heterozygous, and homozygous Cyr61mutants in Mendelian ratios at E9.5, although some Cyr61^-/-embryos were already moribund (Table 1). About 30% of Cyr61^-/-embryos had died by E10.5 due to a failure in chorioallantoicfusion, as the placenta supplants the yolk sac in providingthe metabolic needs of the embryo (Table 1; Fig. 2A). The vascularstructure of the yolk sac appeared normal in Cyr61 mutants (Fig.2G and H), indicating that vasculogenesis was not impaired inthis tissue. Consistent with a direct role for Cyr61 in chorioallantoicfusion, its expression was detected in both the allantois andthe chorion in the E7.5 embryo just prior to the fusion eventat E8.5 (Fig. 2I) (39). The majority of Cyr61^-/- embryos exhibitedsuccessful chorioallantoic fusion and developed further butdied at midgestation due to vascular defects. More than 70%of mutant embryos analyzed between E11.5 and E14.5 perishedfrom hemorrhage and/or placental defects of varying degreesof severity (Table 1; Fig. 2C, E, and F). Only a few Cyr61^-/-offspring resulting from multiple Cyr61^+/-intercrosses developedto term and were born alive, but these mice died within 1 dayof birth. Investigation into the cause of this perinatal lethalityhas been hampered by the rarity of its occurrence.

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TABLE 1. Genotypes of offspring derived from intercrosses of Cyr61^+/- mice

Defective vessel bifurcation in the Cyr61^-/- chorioallantoic junction. After chorioallantoic fusion, the allantoic artery and veinundergo extensive nonsprouting angiogenesis. The parental vesselselongate and bifurcate into smaller daughter vessels (Fig. 3E),which undergo further bifurcation to develop a network of vesselsthat covers the chorionic plate (Fig. 3A). Sprouting angiogenesisthen emanates from this network to produce the finer embryonicvessels that interact with chorionic trophoblasts to form partof the labyrinth, where fetal-maternal exchange of gases, nutrients,and wastes occurs (Fig. 3I) (12, 39). In WT embryos, vesselsundergoing bifurcation could be observed in the chorioallantoicjunction (Fig. 3A and E). By contrast, vessel bifurcation wasseverely impaired in Cyr61^-/- embryos and the few vessels presentappeared compressed by the surrounding tissue (Fig. 3B and F).Cyr61 expression was detected in the chorioallantoic junctionat E9.5 (data not shown), and when the vascular structure wasmore defined by E10.5, Cyr61 expression was clearly discernedin the allantoic mesoderm and endothelial linings of bifurcatingvessels (Fig. 5A). Thus, Cyr61 is expressed in the allantoicmesoderm, concordant with the initiation and progression ofvessel bifurcation following chorioallantoic fusion.

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FIG. 3. Histological analysis of placental defects in Cyr61^-/- embryos. At E12.5, vessel branches had developed in the chorionic plate of the WT (A) but not Cyr61^-/- (B) placenta. Hematoxylin and eosin staining revealed that both WT (C) and null (D) placentae developed differentiated zones, including the chorionic plate (Ch), the labyrinth (La), and the spongiotrophoblast layer (Sp) adjacent to the maternal decidua (De). Close-up view (E) shows vessels (arrowheads) undergoing or having completed (arrows) nonsprouting angiogenesis, thus bifurcating the parental vessels at the WT chorionic plate. Al, allantois; G, giant cells. Vessels (arrows) in the Cyr61^-/- chorionic plate appear compressed, and no bifurcation was observed (F). Unlike the WT labyrinth (G), where fetal vessels containing nucleated red blood cells (yellow arrowhead) interdigitate with maternal blood sinuses (yellow arrow), the Cyr61^-/- labyrinth (H) was predominantly saturated with maternal blood sinuses (arrow) and few fetal vessels were found. Trophoblast nuclei (white arrowheads) were evident in both WT and mutant labyrinth (G and H). A schematic representation of the mouse placenta, with expanded views of the labyrinthine zone, is also shown (I). U, umbilical cord. White bars, 50 µm; black bars in panels C and D, 200 µm.

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FIG. 5. (A) ß-Galactosidase staining was detected at the chorioallantoic junction at E10.5, when embryonic vessels were actively bifurcating and invaded the placenta. Intense staining was found in the allantoic mesoderm and inner endothelial lining associated with bifurcating vessels (arrowhead). (B) By E13.5, ß-galactosidase staining was localized to the vessels in the chorionic plate, maternal decidua, and trophoblast giant cells. (C) Higher magnification of panel B is given to demonstrate staining in giant cells (arrowheads). (D) VEGF-C was detected in the allantoic mesoderm (arrowheads) and chorion of WT E9.5 placenta by immunostaining but not in allantoic mesoderm of Cyr61^-/- placenta (E). (F) In Northern blot analysis, serum-starved mouse embryonic fibroblasts isolated from E14.5 WT embryos were treated with purified recombinant CYR61 for various durations before the total RNA was isolated. Vegf-C mRNA was upregulated sixfold after 6 h of CYR61 treatment, and this upregulation was sustained for at least 24 h. The hybridization signal was quantified by Phosphorimager. Al, allantois; Ch, chorion; De, decidua; G, giant cells; La, labyrinth; Sp, spongiotrophoblast; U, umbilical cord. Yellow bars, 50 µm.

Both WT and Cyr61^-/- placentae developed into well-differentiatedzones of similar thicknesses (Fig. 3C and D). In the WT labyrinth,networks of maternal blood sinuses interdigitated with fetalblood vessels, which were readily identified by the primitivenucleated embryonic red blood cells they carried (Fig. 3G).The Cyr61^-/- labyrinth was dominated by saturated maternal bloodsinuses, with few embryonic vessels visible (Fig. 3H). Immunostainingfor PECAM-1 confirmed the paucity of embryonic vessels in theCyr61^-/- labyrinth (Fig. 4A and B). A higher-power view of PECAM-1-stainedsections showed the presence of embryonic red blood cells inendothelial tubules, whereas the endothelial cells in the Cyr61^-/-labyrinth were compressed and devoid of associated embryonicred blood cells (Fig. 4C and D). However, CYR61 is unlikelyto play a direct role in the labyrinth inasmuch as Cyr61 isexpressed in trophoblast giant cells (Fig. 5C) but not in labyrinthtrophoblasts (Fig. 5B) (35) and CYR61 acts locally due to itshigh-affinity binding to the ECM upon secretion (51). Moreover,high levels of VEGF-A were detected in both the WT and Cyr61^-/-labyrinth by immunostaining (Fig. 4E and F) (13), thereby assuringthe presence of a potent inducer for sprouting angiogenesisin the labyrinth. These results indicate that, although Cyr61^-/-placentae exhibited severe deficiency in labyrinthine embryonicvasculature, such defects originates at the chorioallantoicjunction, where nonsprouting angiogenesis failed.

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FIG. 4. Immunostaining of Cyr61^-/- placenta. (A) PECAM-1 staining for endothelial cells showed the embryonic vessels (arrowhead) in the WT chorionic plate and labyrinth. (B) Drastically fewer PECAM-staining endothelial cells (arrowhead) were found in the Cyr61^-/- placenta. (C) Higher magnification views show that the PECAM-staining fetal vessels (arrow) contained embryonic red blood cells (arrowhead) in the WT labyrinth. (D) In contrast, endothelial cells (arrow) of the Cyr61^-/- labyrinth appeared compressed and carried no apparent red blood cells. The white arrowhead in panel D points to maternal blood cells. Despite deficient vascularization of the Cyr61^-/- labyrinth, no difference in VEGF-A expression between the WT (E) and Cyr61^-/- (F) placentae could be detected by immunostaining. Similar expression of Tie-2 was also observed in WT and Cyr61^-/- placentae (data not shown). Ch, chorion, La, labyrinth. Bars, 50 µm.

These results show that CYR61 plays a novel role in regulatingvessel bifurcation, and to our knowledge, analysis of Cyr61^-/-mice provides the first description of a specific genetic defectin vessel bifurcation in any tissue. In an effort to understandhow CYR61 might act, we examined the expression of genes knownto affect vessel development. The expression of Vegf-A, Ang-1,Ang-2, and Tie-2 (50) was unaltered by CYR61 deficiency (datanot shown). However, whereas VEGF-C was detected in the WT allantoicmesoderm at E9.5, coincident with Cyr61 expression (Fig. 5A;data not shown), it was undetectable in Cyr61^-/- embryos (Fig.5D and E). These results suggest that CYR61 might act in partthrough the upregulation of specialized angiogenic factors suchas VEGF-C, known to induce both angiogenesis and lymphangiogenesis(8). To assess the ability of CYR61 to regulate Vegf-C expression,we evaluated Vegf-C mRNA levels in response to purified recombinantCYR61 protein in mouse embryonic fibroblasts isolated from WTE14.5 embryos. Indeed, CYR61 treatment upregulated Vegf-C mRNAlevels, with a notable response within 2 h after CYR61 addition(Fig. 5F). Upregulation of Vegf-C mRNA occurred sixfold by 6h, and a high level of mRNA was sustained for least 24 h afterCYR61 treatment. Consistent with this observation, purifiedCYR61 has been shown to upregulate Vegf-C mRNA and protein inhuman fibroblasts (10).

Differentiation of labyrinth trophoblasts in Cyr61^-/- placenta. Separating the maternal blood sinuses and fetal vessels in theplacental labyrinth are differentiated trophoblasts that forma trilaminar barrier, which is comprised of two layers of syncytiotrophoblastsand a mononuclear trophoblast layer (Fig. 3I and 6A) (19). Uponcontact of the allantois with the chorion, trophoblasts at thechorionic plate begin to fold, invaginate, and undergo extensivevillous branching together with their associated fetal bloodvessels (39). These chorionic trophoblasts differentiate andundergo cell fusion, giving rise to a syncytiotrophoblast layerthat is directly juxtaposed to the endothelial cells of fetalblood vessels. Adjacent to this syncytium is a second layerof syncytiotrophoblasts derived from ectoplacental trophoblastcells. Lying outside of the two syncytiotrophoblast layers andin direct contact with maternal blood is a layer of mononucleartrophoblasts (Fig. 3I).

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FIG. 6. Transmission electron micrographs of the E12.5 labyrinth. Both WT (A) and Cyr61^-/- (B) labyrinths displayed the trilaminar barrier composed of two layers of syncytiotrophoblasts (II and III) in addition to a layer of mononuclear trophoblasts (I). In the Cyr61^-/- labyrinth, where maternal blood sinuses dominate (C), ectoplacental trophoblasts differentiated and formed syncytium (yellow arrows point to multiple nuclei within fused cells) without neighboring embryonic vessels. EC, endothelial cells; fRBC, fetal red blood cells; mRBC, maternal red blood cells; MS, maternal blood sinuses. White bar, 2 µm.

The Cyr61^-/- placental labyrinth appeared highly structureddespite the dearth of embryonic vessels (Fig. 3D). The maternalblood sinuses were well delineated, suggesting the presenceof differentiated trophoblasts that separate them (Fig. 3H).Under transmission electron microscopy, the trilaminar trophoblastbarrier was readily observed in the WT labyrinth (Fig. 6A).Interestingly, although few embryonic vessels were found inthe Cyr61^-/- labyrinth, where they did occur, they were encasedby an organized and normally structured trilaminar trophoblastbarrier (Fig. 6B). The Cyr61^-/- labyrinth also presented a uniquefeature normally not found in WT labyrinth: pools of maternalblood sinuses devoid of fetal vessels (Fig. 3H). The trilaminarstructure was absent among these maternal blood sinuses, asno barrier was needed. Instead, separating the maternal bloodsinuses were syncytiotrophoblasts derived from ectoplacentaltrophoblasts (Fig. 6C), judging from their large nuclei andlack of lipid vesicles (19). These data show that the invasionof chorionic trophoblasts into the labyrinth and their differentiationwere not impaired in Cyr61 mutants and that formation of thetrilaminar trophoblast barrier was unaffected. Furthermore,differentiation and syncytial cell fusion of ectoplacental trophoblastscan occur in the absence of juxtaposed chorionic trophoblastsor neighboring embryonic vasculature.

Compromised large-vessel integrity in Cyr61^-/- embryos. Vascular defects in Cyr61 mutants were not confined to the placenta.The large vessels in Cyr61^-/- embryos were unstable and leaky,resulting in severe hemorrhage and edema (Fig. 2E). Such defectswere frequently found in the dorsal aorta and umbilical arteries.A direct role for CYR61 in vessel integrity is consistent withthe high levels of Cyr61 expression in the endothelial liningsof large arteries during early vascular development; this expressionwas expanded to the vessel wall after the recruitment of smooth-musclecells (Fig. 7K). The level of Cyr61 expression was dramaticallyhigher in arteries than in veins, and consistently, most ofthe hemorrhaging occurred in Cyr61^-/- arteries.

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FIG. 7. Hemorrhage of the dorsal aorta in Cyr61-deficient E13.5 embryos. (A, C, E, G, I) WT embryos. (B, D, F, H, J) Cyr61^-/- embryos. Hematoxylin and eosin staining showed completely disorganized vascular cells (B) in the Cyr61^-/- dorsal aorta compared to that for the WT (A). Transverse sections were immunostained for PECAM-1 (C and D), ${alpha}$ -smooth-muscle actin (E and F), and desmin (G and H), showing the drastically dilated lumen in Cyr61^-/- embryos. The endothelial lining (arrows in panels C and D), the smooth-muscle cell wall (arrows in panels E and F), and the pericytes (arrows in panels G and H) of the aorta were disorganized compared to that for the WT, with the apparent mixing of endothelial cells, VSMCs, and pericytes. WT (I) and Cyr61^-/- (J) dorsal aorta sections were subjected to TUNEL analysis; apoptotic cells are identified by green fluorescence (arrowheads). ß-Galactosidase staining was prominent in arteries such as the dorsal aorta (arrow) but nearly undetectable in the vein (arrowhead) (K). Bars, 50 µm.

Transverse sections of the Cyr61^-/- dorsal aorta revealed aseverely disorganized vascular structure, with vascular cellsbeing loosely associated with or detached from a disintegratedbasal lamina (Fig. 7B). Remarkably, the Cyr61^-/- dorsal aortawas enormously dilated, resembling a large aneurysm (compareFig. 7C and E to 7D and F). Immunostaining showed that PECAM-positiveendothelial cells were not consistently found in the inner liningof the aorta, and in some areas, endothelial cells were foundin the surrounding tissue (arrow in Fig. 7D). Deficits in vascularsmooth-muscle cells (VSMCs) and pericytes that normally surroundthe vessel wall were also observed, since only parts of thedilated vessels stained positive for desmin, a marker for pericytes(Fig. 7G and H), or ${alpha}$ -smooth-muscle actin, a marker for VSMCs(Fig. 7E and F). Despite these deficits, the presence of bothpericytes and VSMCs suggests that the recruitment of pericytesand VSMCs was able to proceed in Cyr61^-/- mice. The deficitsin pericytes and VSMCs may be a consequence of vessel dilation,and thereby, many more cells would be required to fully surroundthe lumen. Based on the known activities of CYR61, it appearslikely that CYR61 deficiency may have impaired vessel integrityby having detrimental effects on the interactions among VSMCs,the endothelial lining, and their surrounding ECM.

An essential role for CYR61 in the maintenance of vessel integrityis further supported by the observation that some of the vascularcells in Cyr61^-/- embryos appeared to be undergoing apoptosis(Fig. 7B). Indeed, TUNEL analysis confirmed that many vascularcells were apoptotic (Fig. 7I and J). Interestingly, expressionof Ang-1 and its receptor Tie-2, which are important for pericyterecruitment and vascular integrity (34, 46), was not disruptedin Cyr61^-/- embryos (data not shown). These results demonstratea critical and unique role for CYR61 in supporting vascularintegrity and vascular cell survival in major arteries afterthe vessels are formed.

DISCUSSION

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Discussion

Although CYR61 has been shown to induce angiogenesis, its functionsduring development were previously unknown. In this study, wedemonstrated by targeted gene disruption that Cyr61 is an essentialgene for mammalian vascular development. Whereas $~$ 30% of Cyr61-nullmice die from defects in chorioallantoic fusion, the majority( $~$ 70%) perish from vascular defects that include impaired allantoicvessel bifurcation in the placenta and compromised vascularintegrity in embryonic arteries. Furthermore, many of the phenotypesobserved in Cyr61-null mice are consistent with known activitiesof purified CYR61 protein, which functions largely through integrin-mediatedmechanisms (16, 31).

Several phenotypes of Cyr61-null mice are unexpected. AlthoughCyr61 is prominently expressed in trophoblast giant cells andin the ectoplacental cone (35), the normal Mendelian ratio ofCyr61 mutant embryos at E9.5 suggests that CYR61 is not criticalfor implantation. In addition, Cyr61 is not required for vasculogenesis,since formation of the major embryonic vessels and the primaryvascular plexus of the yolk sac is successful in Cyr61 mutants.However, about 30% of Cyr61-null embryos failed to establishchorioallantoic fusion and succumbed by E10.5. CYR61 is knownto support cell adhesion and regulate matrix protein synthesisand degradation (9, 10) and may therefore mediate cell-celladhesion in chorioallantoic fusion and/or establish a matrixenvironment in which fusion can occur. Attachment of the allantoisto the chorion likely involves multiple cell adhesion molecules,including ${alpha}$ ₄ integrins and vascular cell adhesion molecule 1(VCAM-1) (18, 29, 52). As in the case of Cyr61 mutants, chorioallantoicattachment defects exhibited in mutants deficient in ${alpha}$ ₄ integrinsor VCAM-1 are also incompletely penetrant. Thus, in additionto cell adhesion molecules such as ${alpha}$ ₄ integrins and VCAM-1, CYR61may play a role as a cell adhesive protein to participate inchorioallantoic attachment.

CYR61 deficiency results in a specific defect in vessel bifurcationat the chorioallantoic junction, leading to severe undervascularizationin the placental labyrinth. To our knowledge, analysis of Cyr61-nullmutants affords the first description of a specific geneticdefect in vessel bifurcation in any tissue and provides newinsight into the players that regulate this aspect of vasculardevelopment. This novel phenotype is correlated with the impairedexpression of Vegf-C in the allantoic mesoderm, suggesting thatCYR61 may regulate vessel bifurcation either directly or indirectlythrough VEGF-C (Fig. 5D and E). Consistent with this observation,CYR61 is able to upregulate Vegf-C expression in mouse embryonicfibroblasts (Fig. 5F) and in cultured human fibroblasts (10).While VEGF-C is involved in both lymphangiogenesis and angiogenesis,it induces more vessel branching and less sprouting comparedto VEGF-A (8), suggesting a role in vessel bifurcation. Althoughphenotypes of Vegf-C-null mice have not been described, thoseof mutants deficient in one of its receptors, VEGFR3, are consistentwith a role for VEGF-C in the development of the cardiovascularsystem and in vessel morphogenesis (14).

The labyrinthine defect of Cyr61-null mice is distinct fromthose caused by disruptions of other genes, many of which affecttrophoblasts (39). For example, deficiency for Gcm-1 resultsin a labyrinthine malformation due to the defective branchingmorphogenesis of chorionic trophoblasts but allantoic nonsproutingangiogenesis is not affected (1, 43). By contrast, trophoblastdifferentiation and syncytiotrophoblast formation proceed normallyin the Cyr61-null placenta, forming the trilaminar trophoblastbarrier where fetal vessels are found. Therefore, the labyrinthinevascular deficiency in Cyr61 mutants is not due to trophoblastdefects. Interestingly, syncytiotrophoblasts of ectoplacentalorigin, rather than of the trilaminar structure, separate poolsof maternal blood where no barrier from fetal vessels is needed.Inasmuch as pools of maternal blood sinuses devoid of fetalvessels are not normally observed in the WT labyrinth, thesefindings in the Cyr61-null placenta demonstrate that differentiationof ectoplacental trophoblasts occurs in the absence of cell-cellcommunication with juxtaposed chorionic trophoblasts or neighboringembryonic vasculature.

CYR61 is a ligand of, and binds directly to, integrins ${alpha}$ _vß₃and ${alpha}$ _vß₅ and promotes cell adhesion and migration throughthese integrins (3, 16, 26). Thus, it may be informative tocompare the phenotypes of Cyr61- and ${alpha}$ _v integrin-null mice. However,many ligands are known to bind the five ${alpha}$ _v integrins ( ${alpha}$ _vß₁, ${alpha}$ _vß₃, ${alpha}$ _vß₅, ${alpha}$ _vß₆, and ${alpha}$ _vß₈)and CYR61 is also known to bind several other integrins ( ${alpha}$ ₆ß₁, ${alpha}$ _IIbß₃, and ${alpha}$ _Mß₂). Therefore, the phenotypesof ${alpha}$ _v- and Cyr61-null mice are expected to be complex, reflectingthe superimposed consequences of multiple ablated-receptor-ligandinteractions. It is thus remarkable that there are intriguingsimilarities between Cyr61 mutants and ${alpha}$ _v integrin-deficientmice, which also suffer placental insufficiency and embryonichemorrhage (4). About 80% of mice lacking all ${alpha}$ _v integrins dieby E11.5 due to undervascularization of the placental labyrinth,while the remaining 20% succumb perinatally with prominent intracerebralhemorrhages. Strikingly, the placental labyrinthine zone of ${alpha}$ _v-null mice appears to be morphologically similar to that ofthe Cyr61 mutant and fetal vessels at the chorionic plate alsoappear deficient and collapsed (4). While the binding of CYR61to integrins ${alpha}$ _vß₃ and ${alpha}$ _vß₅ as a ligand hasbeen established biochemically, these similarities in the phenotypesof Cyr61- and ${alpha}$ _v-null mice are consistent with the hypothesisthat CYR61 interacts with ${alpha}$ _v integrins physiologically duringdevelopment.

Cyr61-null embryos suffer from compromised large-vessel integrity.This defect suggests that CYR61 is involved in the maintenanceof vessel integrity by stabilizing interactions among endothelialcells, VSMCs, and the ECM. Consistent with this interpretation,CYR61 has been shown to regulate the expression of various ECMmolecules (10), support cell adhesion, and induce chemotaxisthrough integrin ${alpha}$ _vß₃ in endothelial cells and throughintegrin ${alpha}$ ₆ß₁ in VSMCs (3, 17, 26). Thus, the celladhesive and chemotactic activities of CYR61 on endothelialand smooth-muscle cells may underlie the loss of vessel integrityin Cyr61^-/- embryos. Furthermore, vascular cells in Cyr61 mutantsare prone to apoptotic death, consistent with the ability ofCYR61 to support endothelial cell survival in culture (2, 32a).In this context, it is interesting to note that WISP-1, a CCNprotein closely related to CYR61, can inhibit p53-mediated apoptosisthrough the activation of Akt (45).

Members of the CCN family of vertebrate-specific proteins mayplay overlapping but nonredundant roles during embryonic development.Given that CYR61 and CTGF exhibit remarkably similar activitiesin vitro and expression patterns in vivo (9, 32), it is surprisingthat their loss-of-function mutants display distinct phenotypes.Ctgf-deficient mice display generalized chondrodysplasia, leadingto perinatal death due to respiratory failure (S. Ivkovic, S.N. Popoff, F. F. Safadi, M. Zhao, R. C. Stephenson, B. S. Yoon,A. Daluiski, P. Segarini, and K. M. Lyons, submitted for publication).Although Cyr61 mutants did not reveal defects in skeletal developmentdue to their early-embryonic lethality, expression of Cyr61is tightly associated with chondrogenesis during developmentand shows a pattern similar to that of Ctgf (Fig. 2J) (27, 35).Furthermore, purified CYR61 has been shown to promote chondrogenicdifferentiation in mouse limb bud mesenchymal cells (48). Lossof another CCN protein, WISP-3 (CCN6), causes progressive pseudorheumatoiddysplasia in humans (21), resulting in juvenile-onset cartilagedegeneration. Thus, members of the CCN family may be importantfor different aspects or stages of cartilage development andmaintenance. Likewise, although Ctgf mutants did not exhibitdefects in vessel integrity or placental vasculature, they displayedangiogenic deficiency in the growth plates during endochondralbone formation (S. Ivkovic et al., submitted). CTGF is thereforeimportant for angiogenesis specific to skeletal development.Together, these findings establish that both CYR61 and CTGFare essential regulators for vertebrate embryogenesis and indicatethat CCN proteins may serve tissue- and/or stage-specific functionsin the development of the vascular and skeletal systems. Furtherinvestigation by conditional knockout strategies will help elucidatethe tissue-specific functions of these CCN proteins.

ACKNOWLEDGMENTS

We are grateful to Hiroaki Kiyokawa for invaluable advice; PhilippeSoriano and Rudolf Jaenisch for gifts of reagents; Shr-JengLeu for protein analysis; and Ana Bursick, Mara Sullivan, andFengli Guo for technical assistance. We also thank Karen Lyonsfor sharing unpublished data and Jay Cross, Dan Linzer, KarenLyons, and our colleagues for illuminating discussions.

This work was supported by grants from the NIH (CA46565 to L.F.L.and CA76541 to D.B.S.).

FOOTNOTES

* Corresponding author. Mailing address: Department of Molecular Genetics, University of Illinois at Chicago, 900 South Ashland Ave., Chicago, IL 60607-7170. Phone: (312) 996-6978. Fax: (312) 996-7034. E-mail: LFLau{at}uic.edu.

REFERENCES

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