Conditional expression of Wnt4 during chondrogenesis leads to dwarfism in mice.

Wnts are expressed in the forming long bones, suggesting roles in skeletogenesis. To examine the action of Wnts in skeleton formation, we developed a genetic system to conditionally express Wnt4 in chondrogenic tissues of the mouse. A mouse Wnt4 cDNA was introduced into the ubiquitously expressed Rosa26 (R26) locus by gene targeting in embryonic stem (ES) cells. The expression of Wnt4 from the R26 locus was blocked by a neomycin selection cassette flanked by loxP sites (floxneo) that was positioned between the Rosa26 promoter and the Wnt4 cDNA, creating the allele designated R26(floxneoWnt4). Wnt4 expression was activated during chondrogenesis using Col2a1-Cre transgenic mice that express Cre recombinase in differentiating chondrocytes. R26(floxneoWnt4); Col2a1-Cre double heterozygous mice exhibited a growth deficiency, beginning approximately 7 to 10 days after birth, that resulted in dwarfism. In addition, they also had craniofacial abnormalities, and delayed ossification of the lumbar vertebrae and pelvic bones. Histological analysis revealed a disruption in the organization of the growth plates and a delay in the onset of the primary and secondary ossification centers. Molecular studies showed that Wnt4 overexpression caused decreased proliferation and altered maturation of chondrocytes. In addition, R26(floxneoWnt4); Col2a1-Cre mice had decreased expression of vascular endothelial growth factor (VEGF). These studies demonstrate that Wnt4 overexpression leads to dwarfism in mice. The data indicate that Wnt4 levels must be regulated in chondrocytes for normal growth plate development and skeletogenesis. Decreased VEGF expression suggests that defects in vascularization may contribute to the dwarf phenotype.

Introduction

Wnt signaling has been implicated in the regulation of early patterning and initial outgrowth of the vertebrate limb bud [1]–[4]. More recently, several Wnts have been shown to be expressed in the developing long bones, suggesting that they may have roles in endochondral bone formation. In the developing chick skeleton, Wnt4 and Wnt9a (previously known as Wnt14) are expressed in joint-forming regions, Wnt5a and Wnt11 in the perichondrium, and Wnt5b in prehypertrophic chondrocytes of the growth plate [5]–[8]. Misexpression studies in chick embryos suggested that both Wnt4 and Wnt5a can alter chondrogenesis and shorten limb growth, apparently by different mechanisms. Wnt4 accelerates chondrocyte differentiation, whereas Wnt5a inhibits this process [5]. Wnt9a misexpression has been shown to induce the initiation of joint formation [6]. However, Wnt9a knockout mice formed joints but had ectopic cartilaginous nodules that was enhanced by loss of Wnt4 [9]. Wnt4/Wnt9a double mutants also had some limb bone fusions apparently because of an inability to maintain joint cell identity [10]. Misexpression of Wnt5b as well as Wnt5a inhibits chondrogenesis in mice, but they appear to act differently. Wnt5a inhibits the transition from resting to proliferating chondrocytes in the growth plate, whereas Wnt5b promotes this transition as well as chondrocyte proliferation [11].

Wnt signaling components have also been investigated for their roles in skeletogenesis. Frb1, a secreted form of Frizzled that is a Wnt receptor, can function as an antagonist when misexpressed in long bone, causing shortening of skeletal elements, joint fusion, and delayed chondrocyte maturation [12]. In addition, constitutive expression of Lef1 in chondrocytes stimulated chondrocyte maturation as well as replacement of cartilage by bone [13]. Furthermore, mice with a disruption of the LDL receptor-related protein 5 (Lrp5) gene that encodes a Wnt co-receptor, showed decreased osteoblast proliferation [14]. In addition, Lrp5-deficient mice also displayed persistent eye vascularization. These bone and eye phenotypes are similar to the abnormalities associated with osteoporosis-pseudoglioma syndrome in human, caused by mutation of LRP5 [15].

Most studies of Wnt signaling in skeleton development have been restricted to the chick model. However, the expression of Wnts appears to vary in different animal models. For example, in addition to the perichondrium of chick, Wnt5a expression was also found at the junction of proliferating and prehypertrophic chondrocytes in the radius and ulna of mice [11].

Wnt4 expression has also been analyzed during kidney and female reproductive system development. Wnt4 homozygous mutant mice died after birth due to a failure of pretubular cell aggregation, an essential step in the formation of nephrons of the kidney [16]. In addition, Wnt4 mutant mice with an XX karyotype lacked female-specific genital ducts and developed male-specific genital ducts [17]. During chick skeletogenesis, Wnt4 is initially expressed in joint-forming regions, and then is detected in the region of the joint capsule and surface articular chondrocytes [5], [18]. However at later stages, Wnt4 expression in long bones is also detected in hypertrophic chondrocytes [18]. In the mouse, Wnt4 is also expressed in forming joints and mesenchyme that will form the joint capsule [19]. The patterns of Wnt4 expression in chick and mouse suggest roles in joint development and chondrocyte hypertrophy. In addition, the restricted pattern of Wnt4 expression in bone-forming tissues suggests that its expression must be precisely controlled to coordinate normal bone and skeleton formation.

To study the actions of Wnt4 during skeleton development, we created a conditional genetic system to express Wnt4 during chondrogenesis. To accomplish this, we exploited the ubiquitously expressed Rosa26 locus. The ROSA26 mouse mutant was originally produced by infection of embryonic stem (ES) cells with a ROSAβ-geo retrovirus [20]. Rosa26 heterozygotes express β-galactosidase (β-gal) reporter activity ubiquitously that initiates during preimplantation development at the morula-blastocyst stage. Examination of serial sections through 9.5 days post-coitus (dpc) Rosa26 heterozygotes demonstrated β-gal activity in all cells [21]. Rosa26 homozygous mutants are viable although they are recovered at a lower than expected frequency [21]. The Rosa26 locus has been used to ubiquitously or conditionally express various gene products in mice [22]–[26]. Therefore, we exploited the Rosa26 locus to express Wnt4 in a Cre-dependent manner. We placed a drug selection cassette flanked by loxP sites between the Rosa26 promoter and a mouse Wnt4 cDNA, blocking Wnt4 expression at the endogenous Rosa26 locus. Cre expression should delete the blocking drug selection cassette, leading to Wnt4 expression.

To examine the action of Wnt4 during endochondral bone formation, we used Col2a1-Cre transgenic mice that express Cre activity in cartilage-forming tissues [27], [28]. We found that Wnt4 expression in chondrogenic tissues alters skeletogenesis, resulting in skull abnormalities and dwarfism. These studies indicate that alterations in Wnt4 expression can cause severe skeletal pathologies.

Results

Dwarfism in R26 mutant mice

A conditional genetic system was created to express Wnt4 in a Cre-dependent manner, potentially in any tissue. We modified the ubiquitously-expressed Rosa26 locus by gene targeting in ES cells ( ). A mouse Wnt4 cDNA was placed 3′ of a floxed neomycin resistance expression cassette, floxneo, which should block the transcription of the Wnt4 cDNA from the Rosa26 promoter. This block in transcription should be relieved by Cre recombinase-mediated excision of the floxneo cassette. ES cell clones carrying the R26 targeted allele were identified and chimeras were generated that transmitted the targeted allele to progeny. R26 heterozygous and homozygous mutant mice appeared normal and were fertile.

Figure 1

Generation of R26 mice.

A, Gene targeting strategy. Open box, R26 exon 1; DT-A, diphtheria toxin expression cassette. SA, splice acceptor; X, XbaI. B, Southern analysis of ES cell clones. Genomic DNAs were digested with XbaI and detected by 5′ external or 3′ internal probes. C, PCR genotyping of R26 mice. Primers shown in panel A (arrowheads) amplify R26 wild-type (∼600-bp) and targeted (∼350-bp) alleles. Cre-specific primers yield a ∼550-bp band to identify mice carrying the Col2a1-Cre transgene.

To activate the Wnt4 transgene, R26 heterozygotes were bred with Col2a1-Cre transgenic mice to generate R26; Col2a1-Cre double heterozygotes, hereafter designated mutants ( ), that were obtained at the predicted Mendelian ratio (∼25%). The Col2a1-Cre transgene has been shown to initiate Cre reporter activity as early as 8.5 dpc [27]. All R26; Col2a1-Cre mutants were viable and developed a dwarf phenotype ( ). Most of the mutants initiated growth defects beginning around 7 to 10 days after birth (data not shown). The body weights of mutants and controls were measured starting from postnatal day 12 (P12) to P72 at 3-day intervals ( ). Male and female R26; Col2a1-Cre mutants had similar body weight growth rate characteristics. After weaning at 3 weeks of age, male mutants were approximately 50 to 60% and female mutants were approximately 60 to 70%, of the body weight of their age- and sex-matched controls ( ).

Figure 2

Growth defects in R26 mutants.

A, 4-week-old R26 mutant and control littermates. The mutant has a significantly shorter body and altered head shape relative to the control. B, Mean body weight comparisons±standard error between sex-matched mice from 12 to 72 days after birth. n = 5 for mutants, and n = 6 for controls.

Skeleton preparations of 6-week-old mice were examined ( ). In addition to shortened axial skeletons and limbs, R26 mutants had smaller skulls ( ). The skulls had a dome-shaped neurocranium vault, shorter viscerocranium, and a wider distance between the two orbits ( ). Separation of the dorsal skull bones revealed the parietal bones to be fairly equal in size, the frontal and occipital bones to be slightly smaller, and the nasal bones to be significantly shortened in comparison to controls ( ). The limbs of the R26 mutants were disproportionately shorter than controls ( ).

Figure 3

Skeletal defects in R26 mutants.

Skeleton preparations from 6-week-old R26 mutants and R26controls. A, Intact skeletons, control (left) and mutant (right). B, Dorsal view of skulls, control (left) and mutant (right). C, individual dorsal skull bones, control (left) and mutant (right). D, Isolated forelimbs, mutant (top) and control (bottom). E, Isolated hindlimbs, mutant (top) and control (bottom). F, Third lumbar vertebrae, showing lateral ossifications (arrow) in the control (left) that are hypoplastic in the mutant (right). G, Isolated pelvic bones from 6-week-old mice, control (left) and mutant (right). H, Higher magnification of boxed region shown in panel G, showing pubic and ischial bone fusion of the control. I, Higher magnification of boxed region shown in panel G, showing lack of fusion between the pubic and ischial bones of the mutant. fr, frontal bone; nas, nasal bone; par, parietal bone; oc, occipital bone.

R26 mutants also had lumbar vertebrae and pelvic bone defects. The vertebrae of 6-week-old mutants were narrow and flat as illustrated by the third lumbar vertebrae, which showed a reduction in lateral bone ( ). The posterior region of the pelvic bone is composed of the pubic and ischial bones that are fused in 6-week-old controls ( ). However, these bones retained cartilage between them in the mutants ( ). Ossification of the cartilage between these two bones was present in 8-week-old mutants, although the pelvic bone was still thinner than controls.

Radiographic analyses of 9-month-old mice showed that the R26 mutants had small skeletons, dome-shaped skulls, protruding incisors, and kyphosis of the cervical-thoracic spine ( ). In addition, the 9-month-old mutants moved slowly, suggesting that these skeletal abnormalities inhibited movement. No gross differences in bone mineralization were observed in X-ray images of mutants and controls ( ).

Figure 4

Radiographic analysis for 9-month-old R26 ; Col2a1-Cre mutants.

The mutants had a smaller skeleton, abnormal skulls with a domed vault (arrowhead) and protruding incisors (small arrow). Kyphosis (large arrow) of the cervical-thoracic spine was also observed in the mutants. Control, R26 heterozygote; mutant, R26.

Growth plate abnormalities in R26 mutant mice

Tibiae and femurs of 15.5 dpc mutant mice were examined by histology. At this stage of embryogenesis, the primary ossification centers (POC) have developed in both the tibiae and femurs of controls ( ), with blood vessels originating from the perichondrium present in the metaphysis. However, at this stage of development in the mutants, the POC was not observed in tibiae and had just started to form in femurs ( ). At stages later than 15.5 dpc, only sections of tibiae were used for comparisons. At P1 and P5, there were no apparent differences between mutants and controls (data not shown). Hypertrophic chondrocytes, ready to be invaded by blood vessels in the future secondary ossification center (SOC), were observed in controls at P7, but not in the mutants. At P10, the secondary ossification centers of the controls had started to form, and proliferating chondrocytes were organized in columns (data not shown). In the same area of the mutants, only hypertrophic chondrocytes were present. At P14, most mutants had initiated hypertrophic chondrocyte development in the SOC ( ). The mutant growth plates were also less organized, with less columnar organization, and some hypertrophic chondrocytes had developed earlier than controls in the zone of proliferating chondrocytes ( ). The timing of these histological alterations in bone formation correlate with the initial growth defects observed in the mutants.

Figure 5

Histological analyses of long bones.

A, C, E, G are H & E stained histological sections of R26 heterozygous controls; and B, D, F, H are R26 mutants. A, B, 15.5 dpc tibiae. C, D, 15.5 dpc femurs. The formation of the primary ossification center (arrows) was delayed in both tibiae and femurs of the mutant in comparison to controls. E, F, 2-week-old tibiae, showing development of the secondary ossification center (black arrow) in the control but only chondrocyte hypertrophy (black arrow) in the mutant that also had a disorganized growth plate (red arrow). G, H, 9-month-old mutant tibia with little bone marrow (G) filled with adipocytes (H, arrow).

At P14, there were distinct differences in the chondrocyte zones between R26 mutants and controls. The proliferating chondrocyte zone in the tibiae of controls were larger than mutants, yet the hypertrophic chondrocyte zone in tibiae of mutants were larger than controls. At 3 weeks of age, both mutants and controls have developed SOCs in tibiae, though they were better developed in controls than in the mutants (data not shown). At 9 months of age, the tibiae of mutants (n = 2) were deficient in bone marrow and were filled with adipocytes in epiphyseal and metaphyseal regions ( ). In contrast, inspection of 12-month-old control mice (n = 2) showed metaphyseal regions full of bone marrow (data not shown).

We employed section in situ hybridization using several molecular markers, to study the chondrocyte zones in 3-week-old tibiae. Col2a1 is expressed in proliferating and prehypertrophic chondrocytes. Col2a1 transcripts were detected in a smaller region in the mutants relative to controls, indicating that tibiae of 3-week-old mutants have a narrower zone of proliferating and prehypertrophic chondrocytes ( ). Indian hedgehog (Ihh), a member of the Hedgehog gene family, is a key molecule in endochondral ossification [29]. At postnatal stages, Ihh is expressed predominantly in prehypertrophic chondrocytes. Hybridization of Ihh showed no obvious differences in mutant tibiae relative to controls ( ), suggesting that the narrower zone defined by Col2a1 expression is predominantly due to a reduced proliferating chondrocyte zone. Col10a1 is a marker of prehypertrophic and hypertrophic chondrocytes, cells that have exited the cell cycle [29]. Hypertrophic chondrocytes form the terminal zone of the growth plate that is poised to become apoptotic and replaced by bone. Col10a1 hybridized to a significantly larger zone in the mutant growth plates in comparison to controls, indicating a larger proportion of hypertrophic chondrocytes relative to controls ( ).

Figure 6

Section RNA in situ hybridization of tibial growth plates of 3-week-old animals.

Molecular marker analysis of tibiae of 3-week-old R26 heterozygous control (A, C, E, G) and R26 mutant (B, D, F, H) mice. Col2a1 marks proliferating and prehypertrophic chondrocytes; Col10a1 marks prehypertropic chondrocytes; Ihh marks prehypertropic and hypertropic chondrocytes. Brackets mark relevant regions. Wnt4 hybridization is undetectable in the growth plate of the control, whereas Wnt4 transcripts are detected throughout the growth plate of the mutant.

Gene expression of Wnt4 during skeletal development has been described previously. In chick, Wnt4 expression is first detected at embryonic stages in the joint regions between two long bones [5]. Another study showed Wnt4 expression in hypertrophic chondrocytes at later stages [18]. Using high-stringency for in situ hybridization, Wnt4 transcripts were not detected in the growth plates of 3-week-old control mice, but were found in almost the entire cell population of the growth plates of the mutants ( ). Although we have not determined the earliest stage that the Wnt4 transgene is activated by the Col2a1-Cre transgene these results suggest that Cre acts in chondrogenic precursors to activate Wnt4 transgene expression in all cells of the growth plate.

Chondrocyte proliferation was examined in 2-week-old mutants and controls by BrdU-labeling ( ). BrdU-labeling revealed that the fraction of chondrocytes in the zone of proliferation that incorporated BrdU was 0.189±0.051 in controls but only 0.122±0.002 in mutants, resulting in a mitotic index of 0.64 for the R26 mutants ( ). This indicates that overexpression of Wnt4 leads to decreased chondrocyte proliferation during tibial growth.

Figure 7

Cell proliferation in the epiphyseal growth plate of the proximal tibia.

A, B, BrdU-labeled cells in 2-week-old control and R26 mutant mice. C, The fraction of chondrocytes in the proliferation zone (pz) that incorporated BrdU was 0.189±0.051 in control mice compared to 0.122±0.020 in mutants (P<0.001). The labeling percentage of the control was designated as 1.0, and the relative percentage of the mutant was calculated as 0.64.

Decreased VEGF expression in R26 mutant mice

During endochondral bone formation, VEGF induces angiogenesis from the perichondrium. In mouse, VEGF has been reported to be secreted by hypertrophic chondrocytes [30]. However, VEGF immunostaining in 3-week-old wild-type tibiae was not restricted to the terminal hypertrophic chondrocytes, but rather was predominantly expressed in prehypertrophic and early hypertrophic chondrocytes ( ). In R26 mutants, VEGF immunostaining was weak in prehypertrophic chondrocytes and almost absent in hypertrophic chondrocytes ( ).

Figure 8

VEGF immunohistochemistry of 3-week-old tibiae.

A, B, VEGF immunostaining (brown) in growth plates of 3-week-old tibiae. A, The control stained strongly for VEGF in prehypertrophic and hypertrophic chondrocytes (arrow). B, VEGF immunostaining in the R26 mutant tibia was weaker and restricted to prehypertrophic chondrocytes (arrow).

Discussion

An in vivo system to tissue-specifically overexpress Wnt4 in mice

Wnt4 was initially shown to be essential for kidney tubulogenesis for nephron formation [16] and differentiation of the female gonad and reproductive tract [17]. Subsequently in chick, Wnt4 expression in the joint regions and misexpression studies indicated a role in skeleton development [5]. To further study Wnt4 function during development, we used a Cre/loxP system to conditionally express Wnt4 from the ubiquitously-expressed Rosa26 locus potentially in any mouse tissue in a Cre-dependent manner. To study the activity of Wnt4 in skeletal development, we used Col2a1-Cre transgenic mice that express Cre in chondrogenic tissues [27]. Examination of Wnt4 expression in the R26 mutants suggested that Cre activates Wnt4 transcription in chondrogenic precursors, leading to Wnt4 transgene expression throughout the entire growth plate. These findings suggest that the R26 mice may also be useful for Wnt4 misexpression studies in other tissues.

Overexpression of Wnt4 alters the growth plate

The external morphologies of the R26 mutants were similar to mice with mutations in Fgfr3, Mt1-Mmp, and Link protein (Hapln1) [31]–[36]. The length of the growth plates of the R26 mutants was nearly identical to wild type, although with an altered appearance. R26 mutants have an expanded zone of hypertrophic chondrocytes and a smaller zone of proliferating chondrocytes. Overexpression of Wnt4 also causes a decrease in VEGF expression that may result in a reduction of vascularization that in turn leads to delayed formation of primary and secondary ossification centers. The Col2a1-Cre transgene is active in chondrocyte precursors of endochondral bones [27]. Interestingly, the skulls of the R26 mutants were significantly smaller than controls. The skull is composed of elements derived from both endochondral and membranous bone formation. The alterations observed in the membranous bones of the mutant skulls may be indirect effects of altered endochondral skull bones. All of the skeletal alterations mentioned above likely contribute to the development of the dwarf phenotype.

Wnt4 is expressed in the developing joint regions and a subset of hypertrophic chondrocytes [5], [18], [19]. Wnt4 homozygous mutant mice die within 24 hours after birth due to severe defects in kidney function [16], but no skeletal abnormalities have been reported [9]. However, Wnt4/Wnt9a double mutants show some joint cell identity abnormalities [9], [10]. The perinatal lethality precludes studies of the role of Wnt4 in the skeleton after birth. Such studies will require the generation of a Wnt4 conditional null allele [37]. Retroviral-mediated Wnt4 misexpression in chick limbs accelerated chondrocyte maturation; in contrast, Wnt5a misexpression in the same model inhibited chondrocyte maturation [5]. Viral-mediated misexpression of β-catenin or a constitutive-active form of LEF/TCF display phenotypes similar to Wnt4 misexpression, suggesting that Wnt4 influence on limb shortening may be mediated by β-catenin [13]. In addition, viral-mediated misexpression of the Wnt-antagonist Frzb-1 in growth plates delayed chondrocyte differentiation [12]. Together these data imply that endogenous Wnt4 signaling may have a role in chondrocyte maturation.

We show that overexpression of Wnt4 in the mouse growth plate may also influence chondrocyte maturation, as shown by reduced zones of proliferating chondrocytes and expanded zones of Col10a1 hybridization and hypertrophic chondrocytes in R26 mutants. In addition, in growth plates of R26 mutants, the zone of Col2a1 hybridization was significantly smaller yet the Ihh zone essentially unchanged, indicating a decrease in proliferating chondrocytes. The decrease of the zone of proliferating chondrocytes may result from lower rate of proliferation in mutants or a higher percentage of cells exiting the proliferation state. However, an in vitro micromass culture assay has shown that infection by a retroviral-delivered Wnt4 did not decrease the rate of cell proliferation [18]. In addition, no detectable change of cell proliferation was observed by Wnt5a and 5b misexpresssion using the same system. Indeed, recent studies in transgenic mice demonstrated that Wnt5b could promote proliferation of chondrocytes in vivo [11]. These distinct results may reflect the difference between mouse and chick models, or differences between the in vitro and in vivo approaches. The ability of Wnt4 to decrease the zone of proliferating chondrocytes may represent an enhancement of the endogenous activity of Wnt4, a competition with the activity of Wnt5b that promotes proliferation of chondrocytes, or a mimicking of Wnt5a function that inhibits the transition from resting chondrocytes to proliferating chondrocytes. Moreover, since Wnt4 may accelerate the differentiation of chondrocytes, proliferating chondrocytes with overexpression of Wnt4 may exit the cell cycle rapidly, leading to narrower zone of proliferating chondrocytes.

The R26 mutants also had disorganized growth plates. The organized structure of the growth plate is tightly linked between the chondrocytes and the extracellular matrix (ECM) and Wnt actions on cell adhesion have been proposed [38]. Overexpression of Wnt4 may interrupt such a relationship, by either changing the cell membrane structure of chondrocytes or altering components of the ECM. Wnt4 has been shown to signal canonically, non-canonically, or through neither pathway, depending upon the experimental context [39]–[44]. It is not clear which pathway(s) is utilized for the Wnt4-induced dwarfism documented in our study.

Overexpression of Wnt4 and skeleton vascularization

The growth plates of R26 mutants displayed decreased VEGF expression. VEGF is a key regulator for vascularization and plays an important role during endochondral bone formation, where VEGF couples hypertrophic cartilage remodeling, ossification, and angiogenesis [30]. Vegf heterozygous mice die at early embryonic stages [45], [46], but animals that express only the VEGF120 isoform can survive to term. Vegf 120/120 mutants appeared to have low angiogenesis activity [47], [48], and share similar phenotypes with R26 mutants. These abnormalities include delayed invasion of vessels into the primary and secondary ossification centers, reduction in mineralization of mutant bone, and expansion of the zone of hypertrophic chondrocytes. Thus, these phenotypes observed in the R26 mutants may be caused by overexpression of Wnt4, causing reduced expression of VEGF.

Although the relationship between Wnt proteins and VEGF during skeletal development has not yet been clarified, Wnt/β-catenin signaling has been suggested to play a role in activation of VEGF gene expression in benign colonic adenomas in which mutant activated Wnt/β-catenin pathway is often associated with up-regulated VEGF [49]. Moreover, after transfection of a dominant-negative form of TCF4, one of the downstream molecular components of Wnt signaling, VEGF expression was repressed. Truncated VE-cadherin in mice, lacking the β-catenin-binding cytosolic domain, impaired VEGF-mediated angiogenesis [50]. These results indicated that Wnt signaling mediated by the β-catenin pathway could activate VEGF function, but this in contradiction with the R26 mutant phenotype. However, Wnt gene family members often exert distinct functions in a particular tissue of the same stage. For instance, infection of chick limbs using a retrovirus carrying Wnt5a or Wnt4 presented distinct effects, with Wnt5a delaying chondrocyte differentiation, whereas Wnt4 accelerated it [5]. Also, Wnt5b promoted the transition of resting chondrocytes to proliferating chondrocytes, whereas Wnt5a inhibited it [11]. This may reflect unique activities of Wnt genes, or endogenously, Wnt proteins may function as antagonists of each other.

Wnt4 is an important regulator of female reproductive organ development in mice. The ovaries of female mice lacking Wnt4 were masculinized with indications of Leydig cell differentiation [17]. In addition, the mutant ovaries had a large coelomic blood vessel, a primary characteristic of the testis [51]. This has led to the proposal that Wnt4 may repress angiogenesis in developing female gonads, blocking the testis differentiation pathway.

The dwarfism of R26 mutants became apparent only after birth. However, skeletal changes were found earlier in development, consistent with the activity of the Col2a1-Cre transgene at the initial stages of cartilage formation [27]. The apparently weak response to transgenic Wnt4 at fetal stages may be attributable to limited expression of Wnt4 receptors or an excess of Wnt inhibitors. However, the overt dwarfism of the R26 mutants may be the result of VEGF insufficiency. Neonatal mice homozygous for a Vegf 120 isoform allele had 10% shorter tibiae, and slight differences in bone length were detected at 16.5 dpc in comparison to controls [47]. R26 mutants may have stronger VEGF activity than VEGF mutants because the phenotypes displayed in VEGF mutants were more severe than those of RWnt4; Col2a1-Cre mutants. For example, the expansion of the zone of hypertrophic chondrocytes was larger, and the delayed time of formation for the primary ossification center was longer in Vegf mutants. Thus, it may be reasonable to expect that the shortening of tibial length observed in R26 mutants as in Vegf 120/120 mutants becomes apparent only after birth.

In summary, Wnt4 is expressed during skeleton development. The studies presented here demonstrate that dysregulated Wnt4 expression in chondrogenic tissues leads to skeletal defects and dwarfism in mice. The data indicate that Wnt4 levels must be regulated in chondrocytes for normal growth plate development and skeletogenesis. In addition, these studies suggest that pathologies that lead to Wnt overexpression may influence chondrogenic tissues.

Materials and Methods

Generation of R26 mice

The mouse Wnt4 cDNA encoding the entire open reading frame was isolated by RT-PCR. RNA from 13.5 dpc gonads from mouse strain 129/EvSvTac was isolated and used to synthesize cDNA. The Wnt4 cDNA was subsequently amplified by two rounds of PCR. The first primer set was: forward 5′-CCGCGCGGCGAAAACCTG-3′ and reverse 5′-CTGTTTAAGTTATTGGCCTTC-3′. The second primer set was: forward 5′-GCCTTGGGATCCCTGCCCCGGGCTGG-3′ and reverse 5′-ACGCAGGCGGCCGCACTAGTCCTAGGCATGGTCA-3′. The final PCR product was subcloned into the BamHI and NotI sites of pBluescript KS(-) and sequenced.

The pR26-1 plasmid [22] was used to insert a conditional Wnt4 expression cassette into the Rosa26 locus. The expression cassette begins with a splice acceptor sequence (SA), followed by Pgkneo and five polyadenylation sequences flanked by loxP sites (floxneo). The mouse Wnt4 cDNA followed by a bovine growth hormone polyadenylation (bpA) sequence was placed 3′ of floxneo. The expression cassette, SA-loxP-Pgkneo-5pA-loxP-Wnt4-bpA, was inserted into the XbaI site of pR26-1, to generate the gene targeting vector ( ). A diphtheria toxin expression cassette (DT) is present within pR26-1 for negative selection. The targeting vector was linearized with KpnI and electroporated into AB1 ES cells and selected in G418 [52]. ES cell clone genomic DNAs were digested with XbaI and analyzed by Southern blot [53] using a 5′ external probe as described [22] and a 3′ internal probe using bpA ( ). Targeted ES cell clones were injected into C57BL/6 (B6) blastocysts to generate chimeras that transmitted the R26 allele to their progeny. The R26 allele was examined on a B6129 mixed genetic background. The Col2a1-Cre transgenic mice were originally generated on a B6SJLF2 genetic background but have been backcrossed to B6 for >5 generations. All procedures using animals were approved by the Institutional Animal Care and Use Committee.

Mouse genotyping

The R26 allele and Col2a1-Cre transgene were genotyped by PCR using tail DNA ( ). Two primer sets were used in a single PCR reaction to identify the R26 allele and the Col2a1-Cre transgene. Primers for identifying the R26 allele were, R26-R1: 5′-AAAGTCGCTCTGAGTTGTTAT-3′, R26-R2: 5′-GCGAAGCGTTTGTCCTCAACC-3′, and R26-R3: 5′-GGAGCGGGAGAAATGGATATG-3′. Primers for identifying the Col2a1-Cre transgene were, 5′- TCCAATTTACTGACCGTACACCAA-3′, and 5′- CCTGATCCTGGCAATTTCGGCTA-3′. PCR amplification was 40 cycles of 94°C for 30 sec, 62°C for 5 sec and 68°C for 60 sec. Approximately 600-bp and 350-bp fragments were amplified for the wild-type Rosa26 and targeted alleles, respectively. The Col2a1-Cre transgene was identified as a ∼550-bp fragment.

Skeleton preparations and histology

6-week-old mice were prepared to visualize bone by alizarin red staining as described [54]. For histological analysis, tissues were fixed in 4% paraformaldehyde at 4°C overnight for pups at postnatal day 7 (P7) or younger or for two days for pups older than P7. After fixation, samples were washed twice in PBS and decalcified with 0.5 M EDTA, pH 8.0 for 7 to 14 days at 4°C prior to dehydration and paraffin embedding. 7 mm sections were cut and stained with hematoxylin and eosin (H&E).

Radiographic analysis

4 and 9 month-old mice were sacrificed by CO2 asphyxiation. Skeleton morphology was imaged at 27 KV for 20 sec using a Cabinet X-Ray System (Faxitron X-ray Corporation, Wheeling, Illinois).

Immunohistochemistry

Skeletal tissues were treated with hyaluronidase (0.4% in PBS, pH 5.0) to unmask epitopes for immunohistochemistry. Immunostaining was performed using the Vectastain ABC kit (Vector Labs, Burlingame, California), according to the manufacturer's instructions. Rabbit anti-mouse VEGF antibody (Santa Cruz Biotechnology, Santa Cruz, California) was diluted 1∶20.

Cell proliferation

Mice were injected intraperitoneally with bromodeoxyuridine (BrdU) at 100 mg/g body weight and sacrificed 1 hour after injection. Histological sections of skeletal tissues were prepared and immunostained for BrdU (Oncogene Research Products, San Diego, CA). The proliferation rate was calculated as the number of BrdU-labeled cells divided by the total number of cells in the same microscopic field.

RNA in situ hybridization of histological sections

The procedures for RNA in situ hybridization of histological sections were adapted from those described [55]. 35[S]-UTP-labeled antisense or sense RNA probes were prepared. After hybiridzation, samples were exposed for 7 to 40 days and then developed using Kodak D-19 developer and fixer, and counterstained with Hoechst dye.