Regulation of skeletogenic differentiation in cranial dermal bone

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First published online 1 August 2007
doi: 10.1242/dev.002709

Development 134, 3133-3144 (2007)
Published by The Company of Biologists 2007

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Regulation of skeletogenic differentiation in cranial dermal bone

Arhat Abzhanov¹^,*, Stephen J. Rodda², Andrew P. McMahon² and Clifford J. Tabin¹^,

¹ Department of Genetics, Harvard Medical School, Boston, MA 02115, USA.
² Department of Molecular and Cellular Biology, Harvard University, 16 Divinity Avenue, Cambridge, MA 02138, USA.

Author for correspondence (e-mail: tabin{at}genetics.med.harvard.edu)

Accepted 28 June 2007

SUMMARY

TOP
SUMMARY
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Although endochondral ossification of the limb and axial skeletonis relatively well-understood, the development of dermal (intramembranous)bone featured by many craniofacial skeletal elements is notnearly as well-characterized. We analyzed the expression domainsof a number of markers that have previously been associatedwith endochondral skeleton development to define the cellulartransitions involved in the dermal ossification process in bothchick and mouse. This led to the recognition of a series ofdistinct steps in the dermal differentiation pathways, includinga unique cell type characterized by the expression of both osteogenicand chondrogenic markers. Several signaling molecules previouslyimplicated in endochondrial development were found to be expressedduring specific stages of dermal bone formation. Three of thesewere studied functionally using retroviral misexpression. We foundthat activity of bone morphogenic proteins (BMPs) is requiredfor neural crest-derived mesenchyme to commit to the osteogenicpathway and that both Indian hedgehog (IHH) and parathyroidhormone-related protein (PTHrP, PTHLH) negatively regulate thetransition from preosteoblastic progenitors to osteoblasts.These results provide a framework for understanding dermal bone developmentwith an aim of bringing it closer to the molecular and cellular resolutionavailable for the endochondral bone development.

Key words: Dermal bone, Intramembranous ossification, Cranial development, Mouse, Chick

INTRODUCTION

TOP
SUMMARY
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Mineralized skeleton provides the structural framework underlyingthe morphology of the head and trunk in most modern vertebrates.These skeletal elements arise in two developmentally distinctways. Most of the trunk skeleton is produced from mesodermalprogenitors via the formation of cartilage models that are replacedby bone in the process of endochondral ossification (Erlebacheret al., 1995; Olsen et al., 2000; Karsenty and Wagner, 2002;Kronenberg, 2003). By contrast, many of the bones of the craniofacialskeleton arise directly from cranial dermis via a process termedintramembranous bone formation (Fig. 1A) (Noden, 1983; Noden,1991; Hall and Miyake, 1992; Dunlop and Hall, 1995; Jiang etal., 2002) (reviewed in Helms and Schneider, 2003). Intramembranousbones arise directly through differentiation of mesenchyme, initiallycompacted in sheets or membranes. Intramembranous bones are classifiedinto three categories: the sesamoid bones, which form in tendonsas a result of mechanical stress (such as the patella in thetendon of the quadriceps femoris); the periosteal bones, whichform from connective tissue and add to the thickness of longbones; and the dermal bones, which form within the dermis ofthe skin.

Considerably more is known about endochondral ossification thandermal bone formation. During endochondral ossification, thecartilage precursor expands via the growth of proliferatingchondrocytes (Kronenberg, 2003). However, shortly after formationof the skeletal condensation, the proliferating chondrocytesin the core start to mature into hypertrophic chondrocytes. Duringthis differentiation process, cells transverse through several well-characterizedintermediate cell types, including round proliferating chondrocytes,flattened proliferating chondrocytes, the so called `pre-hypertrophiccells', which have dropped out of the cell cycle but not yet begunto undergo overt hypertrophy, and several types of hypertrophiccells. Each of these steps is characterized by the expressionof discrete sets of molecular markers. All chondrocytes of thetrunk skeleton express the Coll II (also known as Col2a1 andCol II) gene, encoding collagen type II, and the transcriptionfactor Sox9 (Kronenberg, 2003; Harada and Roden, 2003; Zelzerand Olsen, 2003; Yamashiro et al., 2004; Aberg et al., 2005; Shibataet al., 2006). As the skeletal elements mature and growth platesform towards their distal ends, these two genes continue tobe expressed at high levels in both proliferating and restingchondrocytes, whereas Sox9 is downregulated during the transitionto the hypertrophic chondrocytes. Sox9 is required for chondrogenesis,and acts to induce the expression of such cartilage-specific markersas collagens II, IX and XI and aggrecan (Lefebvre et al., 1997; Lefebvreand de Crombrugghe, 1998; Bi et al., 1999; Healy et al., 1999;Mori-Akiyama et al., 2003). The hypertrophic state is characterizedby an extracellular matrix containing unique components, suchas collagen type X (Iyama et al., 1991; Kronenberg, 2003). The hypertrophicchondrocyte zone is later invaded by blood vessels from the perichondrium,which bring osteoblasts and hematopoietic cells. The invading osteoblastsreplace hypertrophic chondrocytes, which undergo apoptosis,and form ossification centers (Olsen et al., 2000; Zelzer andOlsen, 2003).

These processes of proliferation, hypertrophy, apoptosis andbone replacement are tightly controlled by the activity of severalsignaling molecules (Kronenberg, 2003), such as bone morphogenicprotein (BMP) family members, Indian hedgehog (IHH) and parathyroidhormone-related protein (PTHrP, PTHLH). BMPs have been shown toregulate the initiation of skeletal formation and to inducechondrocyte proliferation both in vitro and in vivo (Kronenberg,2003; Zhou et al., 1997; Shum et al., 2003). Suppression ofBMP activity with the antagonist noggin or with dominant-negativeversions of BMP receptors leads to severely reduced bone growth(Capdevila and Johnson, 1998; Pathi et al., 1999; Zou and Niswander, 1996).IHH is another crucial coordinating signal regulating both cellproliferation and differentiation in long-bone development.IHH stimulates proliferation of chondrocytes at the growth plate,indirectly suppresses chondrocyte hypertrophic differentiationand, later in development, is directly involved in osteoblastdifferentiation (Bitgood and McMahon, 1995; Vortkamp et al.,1996; St-Jacques et al., 1999; Long et al., 2004). In Ihh-nullembryos, no endochondral bone skeleton develops in the trunk,whereas, in the skull, dermal bones form but are markedly reducedat birth (St-Jacques et al., 1999; Karp et al., 2000). Ihh isinitially expressed throughout the chondrogenic condensations,where it promotes proliferation. Subsequently, the expressionof Ihh is mostly limited to the pre-hypertrophic chondrocytes.In addition to its growth-promoting effect on chondrocytes,Ihh is necessary and sufficient to activate PTHrP expressionin periarticular cells of the perichondrium (Schipani et al.,1997; St-Jacques et al., 1999; Long et al., 2004; Karp et al.,2000). In turn, PTHrP signaling through its receptor, PTHrP-R,acts to block hypertrophic differentiation (Vortkamp et al.,1996; Weir et al., 1996; Lanske et al., 1999). Together, IHHand PTHrP thus form a negative-feedback loop, which serves toregulate the onset of hypertrophic differentiation of chondrocytes(Vortkamp et al., 1996). Levels of IHH and PTHrP regulate thedistance between the cells undergoing hypertrophy and the articularsurface, the thickness of the growth plate (Vortkamp et al., 1996;Chung et al., 2001). BMP signaling also appears to play a rolein the IHH-PTHrP regulatory loop, acting to induce the expressionof IHH in differentiating chondrocyte cells released from PTHrPsignaling (Minina et al., 2001).

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Fig. 1. Origin and contribution of dermal bone in cranial skeletal development. (A) Contribution of cranial neural crest cells (orange) and mesoderm (grey) to the cartilage (blue) and bone (red) components of the avian skull (see also Noden, 1986

; Couly et al., 1993

). Notice the heavy contribution of neural crest to the cranial dermal bones. (B) Bone mineralization in E9-E13 chick embryonic heads as revealed with alizarin red stain. dnt, dentary bone; ep, epidermis; fnt, frontal bone; nt, neural tube; pmx, pre-maxillary bone.

At later stages of endochondral development, the hypertrophiccells are replaced by osteoblasts. Development of osteoblastsfrom mesenchymal cells depends on Runx2 (formerly Cbfa1); noossification occurs without its activity (Ducy et al., 1997

;Komori et al., 1997

; Otto et al., 1997

; Komori, 2000

; Yamaguchiet al., 2000

). RUNX2 protein regulates several bone-specificgenes, such as bone sialoproteins [BSPI (also known as Spp1,Opn and osteopontin - Mouse Genome Informatics) and BspII],collagen type I and osteocalcin (also known as Bglap1 - MouseGenome Informatics) (Ducy et al., 1997

). RUNX2 also plays amore limited role in chondrocyte hypertrophy during long-bonedevelopment (Inada et al., 1999

; Kim et al., 1999

). The early chondrogenicmarkers Coll II and Sox9, discussed above, are also expressedin early osteogenic precursors, but are never found in differentiatedosteoblasts (Yamashiro et al., 2004

; Aberg et al., 2005

In contrast to endochondral differentiation, the process ofdermal bone formation is poorly understood. Several recent studieshave demonstrated that many of the molecules associated withendochondral development are also present during intramembranousbone development, thus suggesting certain similarities in thedevelopment of these tissues; however, closer analyses alsorevealed some specific differences between appendicular anddermal bone development, including differences in their respectivematrix composition and structure (Bitgood and McMahon, 1995;Vortkamp et al., 1996; St-Jacques et al., 1999; Long et al., 2004;Scott and Hightower, 1991; Zhao et al., 2002; Holleville etal., 2003; Vega et al., 2004). The different cellular eventsleading up to dermal and endochondral bone formation, the differencesbetween these tissues themselves, as well as distinct ontogeneticorigins of the dermal and endochondral bones, all suggest thata thorough detailed analysis specifically of dermal bone developmentis required to understand the formation of this important tissue type.

In this study, we characterized the expression of a number ofmolecular markers during the development of frontal and dentarybones in chick embryos (the proximal part of the dentary boneis occasionally referred to as surangular). This has allowedus to define a series of distinct cellular steps involved indermal bone formation, including a novel transitional cell type,a chondrocyte-like osteoblast, characterized by the co-expressionof both osteogenic and chondrogenic markers in both chicks andmice. The presumptive role that we assigned to the novel `chondrocyte-likeosteoblast' as a precursor to the mature osteoblasts was verifiedin mice by recombinase-based fate mapping. With this context,we analyzed the expression domains of several growth factorsknown to play key roles in regulating endochondral ossification,including Bmp2, Bmp4, Ihh and PTHrP, assigning their expressionto specific cell types. Their functions during dermal bone formationwere assayed using retrovirus-based constructs in chicken embryos. Wefound that BMPs play an important role in dermal bone development, regulatingthe earliest cell differentiation decisions. IHH and PTHrP actat a later step to negatively regulate the formation of osteoblastsfrom osteoprogenitors. In the case of IHH, the conclusions basedon these gain-of-function studies were verified by analysisof mice deficient for the Ihh gene.

MATERIALS AND METHODS

TOP
SUMMARY
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Chicken embryo manipulations
Eggs were obtained from SPAFAS (Norwich, CT) and staged accordingto Hamburger and Hamilton (Hamburger and Hamilton, 1951). TheRISAP, RCAS(A)::noggin, RCAS(A)::Bmp4, RCAS(B)::Bmp2 and RCAS(A,E)::Ihh constructshave been previously described (Capdevila and Johnson, 1998; Vortkampet al., 1996; Chen et al., 1999; Duprez et al., 1996; Yu etal., 2002). The RCAS::PTHrP construct was from H. Kempf (A.Lassar's laboratory, Harvard Medical School, Boston, USA).

Mouse work
Col2::Cre3 transgenic mice have been described previously (Longet al., 2001). For timed pregnancies, we used the plug dateas 0 days post-coitum (dpc). Activity of Col2::Cre3 was assessedby mating the Col2::Cre3 mouse line (Long et al., 2001) to the Rosa26-lacZreporter mouse (Soriano, 1999), after which embryos were collectedat 16.5 dpc and ß-galactosidase activity detected asdescribed previously (Whiting et al., 1991).

In situ hybridizations and bone/cartilage staining of embryos
Heads of chick embryos were collected and fixed in 4% paraformaldehyde (PFA)overnight, washed with 30% sucrose, and frozen in OCT for coronal sections.Older embryos we collected and fixed in 4% PFA and then dehydrated in95% ethanol for 2 days before staining with Alcian blue to revealcartilage and alizarin red to reveal bone.

We used the following in situ hybridization probes for chicken: Bmp4(1.2 kb), PTHrP-R ( $~$ 970 bp), Runx2 ( $~$ 700 bp, gift from Dr Helms,Stanford University, Stanford, USA), Ptc1 ( $~$ 3 kb), Gli (Gli1; $~$ 1.5 kb), Bmpr1a ( $~$ 1.6 kb, gift from Dr Niswander, Universityof Colorado, Denver, USA), Bmpr1b ( $~$ 1.6 kb, 5' UTR, gift fromDr Niswander), Sox9 ( $~$ 1.5 kb; gift from Dr Sharpe, King's College, Universityof London, London, UK), Bmp2 ( $~$ 1.9 kb), Bmp7 ( $~$ 750 bp, gift fromDr Niswander), Bmp2 ( $~$ 780 bp, gift from Dr Niswander), Bmp6 ( $~$ 2kb), Bmp5 ( $~$ 1.6 kb), Coll II (450 bp, amplified from AA182-AA616region of the GenBank sequence #M74435), Opn ( $~$ 640 bp, AA34-249),Coll IX (Col9a1; $~$ 500 bp, gift from Dr Olsen, Harvard DentalSchool, Boston, USA) and Ihh ( $~$ 1.6 kb). We used the followingin situ hybridization probes for mouse: Coll IIa1 ( $~$ 400 bp fromthe 3' UTR; gift from Dr Olsen), Ptc2 (Ptch2; 2 kb), Opn ( $~$ 950bp, gift from Dr Rosen, Harvard Dental School, Boston, USA),Ihh (700 bp), Osc (Lss; $~$ 500 bp), PTHrP ( $~$ 500 bp), PTHrP-Rec (Pthr1; $~$ 700 bp), Osx (Sp7; $~$ 1 kb), Bmp7 ( $~$ 2.1 kb), Bmp2 ( $~$ 1.2 kb) and Bmp4( $~$ 1 kb).

Isolation of osteoblastic cells and immunohistochemical procedures
Bone cells were isolated from frontal bones of embryonic day(E)13 chick or 17.5 dpc mouse embryos by sequential enzymaticdigestion as previously described (Yokose et al., 1996; Ishizuyaet al., 1997). More specifically, the calvaria were minced andincubated at room temperature for 15 minutes with gentle shakingin a mix of 0.1% collagenase P, 0.05% trypsin and 4 mM EDTAin calcium and magnesium-free phosphate buffered saline. Thisenzymatic procedure was repeated a total of three times. Theresultant supernatant was forced through a 40 µm nylon cellstrainer (BD Falcon, Bedford, USA). The cells were placed ona slide and used for in situ hybridization.

Double fluorescent in situ hybridization (FISH) protocol
The slides with dissociated cells or embryonic head sectionswere post-fixed in 4% paraformaldehyde for 10 minutes, washedin PBT and treated with acetylation solution (acetic anhydridein 0.1 M triethanolamine). Hybridization was performed at 65°Covernight. After hybridization, the slides were washed twicewith 0.2x SSC at 65°C. Following the wash, the slides wereincubated in TNT buffer (0.1 M Tris-HCl, pH 7.5, 0.15 M NaCl, 0.05%Tween 20). Then, the slides were blocked before antibody (anti-DIGor anti-FITC POD-conjugated antibody) was applied. Followingthe antibody exposure, we performed the tyramide amplificationreaction following the manufacturer's instructions (PerkinElmerLife Sciences, Boston). The red Cy-3 and Oregon Green signalswere obtained with the TSA-Plus Fluorescence Palette System(PerkinElmer Life Sciences, Boston) and TSA Kit#9 (MolecularProbes, Oregon). We empirically determined that the embryonichead sections needed to be treated with 1% H₂O₂ for 30 minutesprior to the TNT buffer wash to suppress the endogenous peroxidaseactivity.

RESULTS

TOP
SUMMARY
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Expression of molecular markers during the development of dermal bone
To identify the cellular transitions in the development of dermalbone, we analyzed the expression of a number of chondrogenicand osteogenic markers in chick and mouse embryos. In the chickembryo, pre-skeletal, alkaline phosphatase-positive, mesenchymalcondensations can be detected at stage HH30 [Hamburger-Hamiltonstage 30 or embryonic day 7 (E7)]; mineralized bone matrix depositionin the skull begins at around HH36 (E10); osteogenesis is well underwayat HH39 (E13) and most of the skeletal structures are in placeby HH41 (E15) (Fig. 1B) (Hamburger and Hamilton, 1951; Halland Miyake, 1992; Dunlop and Hall, 1995; Eames and Helms, 2004).In mouse embryos, definitive bone mineralization begins at around15.0 days post coitum (dpc) and is well underway by 17.5 dpc (Kaufman,2003). Expression patterns of a variety of skeletogenic celltype markers were examined in both species on both dentary andfrontal bones, with the purpose of characterizing dermal bonecells from morphologically distinct structures. These markers includedSox9, Coll II, Coll IX (also known as Col9a1) and aggrecan,which are markers for cells undergoing various stages of chondrogenesisin the trunk skeleton (Harada and Roden, 2003; Lefebvre andde Crombrugghe, 1998; Bi et al., 1999). We also explored theexpression of Runx2, Osx (also known as Sp7 - Mouse Genome Informatics),Opn and BspII; the presence of these markers is characteristicof the osteoblastic lineage (Harada and Roden, 2003; Zelzerand Olsen, 2003; Ducy et al., 1997; Komori et al., 1997; Ottoet al., 1997). Some of these markers are known to be expressedin both chondrogenic and osteogenic cells, especially at earlydevelopmental points. In particular, Runx2 is known to be expressedin, and to be important for the differentiation of, early chondrocytesas well as osteoblasts, whereas Sox9 is known to be expressedin common progenitors of both cartilage and bone (Stricker etal., 2002; Akiyama et al., 2005; Shibata et al., 2006). However,the particular combinations of markers that we examined werehighly diagnostic of the specific bone versus cartilage cell identity.We examined the expression of these multiple skeletogenic genes duringdermal bone formation in coronal sections of HH39 chick embryosand 16.5 dpc mouse embryos (Fig. 2A-O). We first focused onthe developing dermal dentary bone in sections also featuringMeckel's cartilage of the lower jaw, as an internal control.As expected, the neural crest-derived Meckel's cartilage cells expressedthe chondrogenic markers Coll II and Coll IX but not osteogenicmarkers (Runx2, Opn, Osx, BspII) (Fig. 2A-E, see Fig. S1 inthe supplementary material; and data not shown) (Noden, 1991; Coulyet al., 1993; Le Douarin et al., 1993). Expression of Sox9 wasweak at HH39 in chick embryos but was much stronger at the earlierstages of development (data not shown). Turning to the intramembranous(dermal) dentary bone, we observed cells that expressed CollII and Coll IX, and also Runx2, Osx and osteopontin, both inchicks and mice (Fig. 2A-E,L-N; see Fig. S1 in the supplementary material;data not shown). Expression of the typically chondrogenic markersColl II and Coll IX in particular was unexpected because dermalbone is not believed to arise via a cartilage template. Othercartilage markers known to be expressed in the cartilage, suchas Sox9 and aggrecan, were not expressed in this tissue. Weobserved very similar expression profiles for these skeletogenicmarkers in the developing dermal frontal bone of HH39 (E13) chickembryos (data not shown).

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Fig. 2. Expression domains of skeletogenic markers in the developing dentary bone. (A-J) HH39 chick embryos; (K-O) 16.5 dpc mouse embryos. Expression of Coll II (A) and Coll IX (B) is detected in cells of both Meckel's cartilage and dentary bone. (C) Expression of Sox9 can be seen in cells of Meckel's cartilage but not in the dentary bone. (D) Expression of Runx2 is limited to the cells of the dentary bone. (E) Osteopontin is expressed in cells of dentary bone but is restricted to the more mature cells. (F) Bmp2,(G) Bmp4, (H) Ihh and (I) strong expression of PTHrP-R are detected in the dentary bone. (J) H&E staining of the dentary bone and Meckel's cartilage from the embryo in A-I. In mice, (K) Coll II, (L) Runx2 and (M) Osx are expressed in the peripheral cells, whereas (N) the more mature osteoblast marker Opn is expressed in cells surrounded by mineralized matrix (H&E stain; O). dnt, dentary bone; MC, Meckel's cartilage. Scale bars: 200 µm.

Identification of major cell types in the developing dermal bone
To identify which markers were co-expressed in the same dermalbone cells, and thereby to define cell types within the developingdermal bones, we used fluorescent double in situ hybridizationon embryonic sections at HH39 (E13) (Fig. 3A-X). These datasuggest the existence of four distinct cellular types in theprocess of dermal ossification (see Fig. 8A). The developingdermal elements can first be divided into two domains, expressing theearly osteogenic marker Runx2 and expressing the later osteoblasticmarker osteopontin. The expression patterns of these two markers weremutually exclusive (Fig. 3G-I). Runx2-positive cells lied peripherally.These were also regions of active proliferation based on BrdUand PCNA staining (data not shown). The osteopontin-expressingcells could be further subdivided into two distinct domains.These cells also expressed the marker BspII (Fig. 2S-U; datanot shown), whereas more-peripheral cells within the osteopontin-positivedomain expressed Coll II and Coll IX (Fig. 3A-C; data not shown);the expression of these markers, BspII, Coll II and Coll IX,identified mutually exclusive domains of the osteopontin-positivecells (Fig. 2S-U; data not shown). The more medial of the Runx2-positivecells also expressed Coll II and Coll IX (Fig. 3J-L), whereas themost peripheral Runx2-expressing cells did not. Our analysisthus allows us to define four transitional cell types duringdermal bone formation (Fig. 8A). The most peripheral cells atthe surface of the dermal elements, and hence presumably themost immature, express Runx2, but not Coll II or Coll IX. Thesepreosteoblast cells gave rise to a secondary preosteoblast cell characterizedby the activation of Coll II and Coll IX in addition to Runx2expression. The next differentiation step involved the shut-offof Runx2 expression and the activation of osteopontin expression,while maintaining Coll II and Coll IX expression. This is acell type characterized by the expression of both chondrocyte(Coll II and Coll IX) and osteoblast (osteopontin) markers.We detected no Sox9 or aggrecan expression in these cells, whichmakes them distinct from both chondrocytes and osteoblasts observedin the trunk (Fig. 2A-C; data not shown). We have termed these`chondrocyte-like osteoblasts', or CLO cells. Finally, these cellsdifferentiated into mature osteoblasts, expressing BspII as wellas osteopontin, but no longer expressing Coll II or Coll IX.

To verify the observed overlap in expression, we dissociateddermal bone tissue from HH39 chick embryos and from 17.5 dpcmouse embryos. As expected from the results of in situ hybridizationin sections, when the dissociated cells were probed for CollIX and osteopontin (or Coll II with either Osx or Osc in mouseembryos) expression, we identified four classes of cells: cellsexpressing osteopontin but not Coll IX, cells expressing osteopontinand Coll IX, cells expressing Coll IX but not osteopontin andcells expressing neither; representing, respectively, the mostdifferentiated to least differentiated cell types. We foundthat approximately 40% (43±6%; P $≤$ 0.003) of cells thathad been dissociated from chick frontal bone (n=500) co-expressedColl IX and Opn (Fig. 4A-D). Even fewer cells (17±8%;P $≤$ 0.0043) co-expressed Runx2 and Opn (Fig. 4E-H). By contrast,co-expression of Coll IX with Runx2, a very early osteoblasticmarker, was close to 70% (71±7%; P $≤$ 0.005, n=500) in HH39chick frontal bone cells (Fig. 4I-L). Similarly, in mouse, approximately35% (34±7%; P $≤$ 0.035; n=500) of the cells co-expressedColl II and Osx, whereas less than 10% (7±2%; P $≤$ 0.002;n=500) co-expressed Coll II and Osc, and 28% (27±8%;P $≤$ 0.01; n=500) co-expressed Runx2 and Coll II (see Fig. S2A-Pin the supplementary material).

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Fig. 3. Fluorescent double in situ hybridizations showing expression of Coll IX, Coll II and Opn relative to each other and to the domains of Runx2, PTHrP-R, Bmp4 and Bmpr1b expression. (A-C) Direct comparison of the Opn and Coll IX expression domains. (C) There are cells that express Coll IX only (red; broad arrows), Opn only (green; arrowheads) or that co-express Opn and Coll IX (yellow; narrow arrows). (D-F,J-O) Considerable overlap is detected between Opn and Bmp4 (D-F), between Runx2 and Coll IX (J-L), and between Coll IX and PTHrP-R (M-O). (G-I) Expression domains of Opn (green) and Runx2 (Cbfa1; red) have very little or no overlap. The same is true for the expression domains of Coll II versus BspII (S-U) and Ihh versus Opn (V-X). Some overlap is detected for the expression domains of Bmpr1b versus Ptc1 (P-R). Scale bar: 200 µm.

Coll II-expressing cells contribute to bone in mice
Based on their spatial arrangement within the developing skeletalelements, we postulated that the cell types identified in thisanalysis form a linear cascade of cell differentiation. It was,however, formally possible that the CLO cells were an independent,coexisting transient cell type and not the precursors of themature osteoblasts. Recombinase-based fate mapping in mice providedthe opportunity to directly test the relationship between these cells.Mice expressing Cre recombinase from a Coll II regulatory element(Col2::Cre3) were crossed to Rosa26::lacZ reporter lines. Inthese reporters, the Rosa26 promoter is ubiquitously active,but the reporter, lacZ, is not expressed due to a floxed transcriptionalstop cassette. In mice carrying both the Col2::Cre3 transgeneand one of the Rosa26 reporters, Cre activity in the Coll II-expressingcell population resulted in irreversible activation of the reportergene irrevocably marking the Coll II-expressing cells and, importantly,their descendants. A previous similar study only studied upto 15 dpc (Ovchinnikov et al., 2000

). In our study, many ß-galactosidase-positivecells could be observed deep inside the mineralized parts ofthe dentary and frontal bones, demonstrating that a significantportion of the mature osteoblasts (estimated 5-20% of osteoblastsdepending on specific bone) are indeed derived from Coll II-positiveCLO cells (Fig. 4Q-T; data not shown). It should be noted, however,that none of the dermal bones were completely ß-galactosidase-positive,and often had a `salt-and-pepper' appearance. Unfortunately,our in situ hybridization protocols did not allow us to confirmthe identity of ß-galactosidase-positive cells usingmolecular markers. The relative proportion of the ß-galactosidase-positiveosteoblasts differed from bone to bone (Fig. 4Q-T). This might reflectvariation in the timing and/or extent of expression of the particular Col2::Cre3transgene we used, or alternatively might indicate an alternativedifferentiation pathway (see below). In either case, however,it is clear that the (Coll II-positive) CLO cells are indeedprecursors of mature osteoblasts.

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Fig. 4. Analysis of dissociated frontal bone cells of HH39 chick embryos reveals distinct cell populations defined by the expression of skeletogenic markers. (A-D) Four populations of cells were identified: cells expressing only Coll IX (arrowheads in C), only Opn (broad arrows in C), both Coll IX and Opn (narrow arrows in C), and cells expressing neither marker (arrow in D). FISH revealed a similar situation with Opn and Runx2 (E-H), with Runx2 and Coll IX (I-L), and with PTHrP-R and Coll IX (M-P). (M-P) Despite the high degree of co-expression between Coll IX and PTHrP-R that was observed, some slides showed many cells expressing neither marker (arrows, P), suggesting that many of these cells were early osteoblasts not expressing Coll IX. (Q) Analysis of Col2::Cre3xRosa26::lacZ dentary bones with both alizarin red and ß-galactosidase staining revealed a considerable contribution of Coll II-expressing cells to the developing dentary bone. (R-T) Similar analysis of ß-galactosidase and H&E stainings of the developing frontal bone in 17.5 dpc Col2::Cre3xRosa26::lacZ embryos showed many ß-galactosidase-positive cells within this intramembranous bone. Db, dentary bone; FB, frontal bone. Scale bars: 50 µm.

Dermal bone osteoblasts express signaling molecules with known association to chondrogenesis
Having identified markers for the various stages of dermal bone differentiation,we next wanted to examine the expression patterns of various secretedproteins known to modulate endochondral differentiation. Thecells of the dentary bone expressed high levels of Bmp2, Bmp4,Bmp7 and Ihh, and weak but detectable levels of PTHrP (Fig. 2F-I;data not shown). We used double in situ hybridization to identifythe cell types expressing each of these factors. Our analysisshowed that Bmp4 was expressed in a very similar pattern toColl II and Coll IX, overlapping with the same subset of osteopontin-expressingCLO cells and Coll II, Coll IX, Runx2-positive preosteoblasts) (Fig. 3D-F;data not shown). PTHrP was expressed in the same two cell types,the Coll II- and Coll IX-expressing preosteoblasts and CLO cells(data not shown). By contrast, Ihh was co-expressed with Opnin both the CLO cells and the more mature osteoblasts (Fig. 3V-X).

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Fig. 5. Analysis of chick frontal bone development with the RISAP replication-incompetent virus. (A-F) Viral injections into condensations in areas `I' and `II' (dark red spots) labeled large portions of the developing frontal bone (A,D), with cells contributing to the anterior (B) and posterior (E) halves of the frontal bone, respectively. Expansion of the two condensations results in a relatively sharp boundary between the anterior and posterior parts, but no suture forms (arrowheads; C,F). Notice that cells from the anterior condensation contribute to the more posterior part (C). (G-L) Skeletal phenotypes in frontal bones after condensations were infected with the RCAS-based viral constructs at E6. Bone and cartilage mineralized structures were revealed with alizarin red (bone) and Alcian blue (cartilage) histological stains. (G) Normal ossification pattern of the posterior frontal bone in E15 embryos. The top, side and back of the skull are covered with membranous bone. Infection with RCAS::noggin led to a loss of bone mineralization in the posterior (H) parts of the frontal bone. By contrast, infection of the posterior (I) and anterior (L) frontal bone with RCAS::Bmp4 led to a loss of mineralized bone material and its replacement with cartilage. (J) RCAS::Ihh misexpression resulted in a significant decrease of frontal bone mineralization, a phenotype that was similar to that of RCAS::PTHrP misexpression (K). Scale bars: 0.7 cm in B,E; 2 mm in G.

To get an indication of the roles that these various factorsmight play, we next examined the expression patterns of thereceptors through which each is known to act, to identify potentialtarget cell types. Bmpr1b was expressed at a low level throughoutthe forming dermal elements, suggesting that BMP signaling mightplay a role at multiple stages of dermal osteogenesis (Fig. 3P-R).By contrast, PTHrP-R was expressed specifically in the CLO cells,based on its co-expression with osteopontin, Coll II and CollIX (Fig. 3M-O; data not shown), indicating that this is thecell type that is the likely target of PTHrP signaling. Finally,the IHH receptor Ptc1 (Ptch1) and the downstream transcriptionfactor Gli1, both known transcriptional targets of hedgehogsignaling, were co-expressed with osteopontin both in CLO cellsand Coll II- and Coll IX-positive preosteoblasts, suggestingthat these cells were actively responding to IHH signaling (Fig. 3P-R;see Fig. S3 in the supplementary material; data not shown).

Targeting the frontal bone condensations with RCAS viral constructs
To examine the roles of the various signaling molecules duringdermal bone formation, we wanted to use the ability of retroviralvectors to misexpress genes in the developing chick. To developprotocols for specifically targeting the relatively accessiblefrontal bone, we used a replication-defective RISAP vector (whichdoes not spread to adjacent cells following initial infection) (Chenet al., 1999). Our fate-mapping analysis based on infectionswith this vector indicated that the avian frontal bone formsby the fusion of cells derived from at least two distinct regionsof the craniofacial mesenchyme, which we refer to as area I andarea II, at E6; these areas contribute to the anterior and tothe posterior frontal bone, respectively (Fig. 5A-F). For ourfunctional analyses, in which we used the replication-competentretroviral vectors (RCAS), the frontal bone is particularlyconvenient because it is relatively easily isolated from other skeletalstructures and infections in the condensation areas `I' and`II' do not affect embryonic survival rates (data not shown).We infected only the right side of the embryonic head, withthe left acting as an internal control. Embryos were infectedat E6 and collected at HH41 when all ossified cranial skeletalstructures could be detected with alizarin red (bone) and Alcianblue (cartilage) histological stains and easily identified (Fig. 5G).

Roles for BMP signaling during intramembranous bone development
We first addressed whether signaling by BMP proteins is requiredfor proper frontal bone development by blocking their activitywith noggin, a specific inhibitor of BMP2 and BMP4 (Fig. 5H).Similar misexpression experiments were conducted previously, butcell types were not analyzed (Warren et al., 2003; Murtaughet al., 1999; Abzhanov et al., 2004; Wu et al., 2006). We foundthat, in response to noggin infection, there was a dramaticdecrease in the ossified (mineralized) bone material in bothanterior (n=6) and posterior (n=9) parts of the frontal bone,as indicated by staining with alizarin red (Fig. 5H, black arrow;data not shown). This experiment suggested that BMP2 and/orBMP4 activity is required for proper dermal frontal bone ossification.

To determine whether any of the early steps in dermal bone formationoccur in the absence of BMP signaling, we examined the effectof noggin misexpression at HH39 by using the molecular markersfor the various cell types that we had identified. By HH39,the frontal bone on the uninfected contralateral side was alreadyossified and contained cells expressing Runx2, Coll II, CollIX, Opn and BspII (data not shown). However, following nogginmisexpression, in most cases (4 out of 5), very little or noskeletogenic condensation formed and the infected cells failedto express markers for any of the four cell types (Coll II,Coll IX, Runx2, BspII or Opn) (data not shown). This observation suggeststhat BMP2 and/or BMP4 activities are required at the earlieststages for the proper formation of the frontal bone condensationand preosteoblastic progenitors.

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Fig. 6. Molecular and histological analysis of RCAS::Ihh and RCAS::PTHrP-infected frontal bones. (A-P) Analysis of the RCAS::Ihh-infected frontal bones with molecular markers and H&E staining shows that infected bone failed to produce differentiated osteoblasts (I,J) and to mineralize (M-P). Framed areas in M and N are shown amplified in O and P, respectively. (Q-F1) Misexpression of RCAS::PTHrP resulted in a very similar phenotype, with a loss of Opn expression in the infected skeletal element (Y,Z). Framed areas in C1 and D1 are shown amplified in E1 and F1, respectively. Scale bars: 1 mm.

Although noggin misexpression indicates a role for BMPs in allowingdermal bone formation to take place, it acts so early that wecould not ascertain a role for BMPs in later cell types. Toaddress this issue, we infected frontal bone primordia withRCAS::Bmp4 and RCAS::Bmp2 viruses (Fig. 5I; data not shown). Infectionwith either virus caused large areas of frontal bone to be replaced withcartilage material in both the anterior (Bmp4, n=5; Bmp2, n=8)and the posterior (Bmp4, n=11; Bmp2, n=5) part of the frontalbone, as determined with histological stains (Fig. 5I, arrowand asterisk; data not shown). In many cases, anterior frontalbone was replaced by a cartilage of a comparable size and shapewith that of the contralateral uninfected frontal bone (Fig. 5L,asterisk). In the posterior frontal bone, misexpression of RCAS::Bmp4caused a transformation of the dermal bone condensation intoa cartilaginous one, as revealed by suppression of the bone-specific Runx2,Opn and BspII, and by the upregulation of Sox9, Coll II, CollIX and aggrecan, all markers of cartilage formation (data notshown). Induction of Sox9 is important because it was previously shownthat ectopic Sox9 expression is sufficient to inhibit Runx2expression and induce chondrogenesis (Eames and Helms, 2004

);the primordium of the infected anterior part of the frontalbone fuses with an expanded nasal cartilage early in developmentand fails to ossify. These results suggest that BMP signalingcan act as a switch on the early neural crest skeletogenic condensation,promoting a chondrogenic fate at the expense of the initiationof dermal bone development.

Thus, BMP signaling appears to play multiple roles at variousstages of membranous bone development. In our misexpressionstudies with noggin and BMP4, we identified roles for BMP activityat the early stages of condensation and commitment to osteogenicfate. To assess whether BMP signaling also plays an essentialrole at later stages of dermal bone formation, we infected the developingfrontal bone with noggin virus at HH33 (E8), after skeletal condensationis fully formed and dermal bone differentiation is actively takingplace. In spite of widespread infection of the frontal bone,we observed no defect in the subsequent formation of this element,with little or no loss of mineralization (data not shown).

IHH and PTHrP signaling regulate the preosteoblast-to-osteoblast transition
Misexpression of Ihh indicated that this factor acts at a later stageof dermal bone formation. Analyses of RCAS::Ihh-injected frontalbone at HH41 showed a significant decrease in bone mineralizationin anterior (n=5/5) and posterior (n=8/8) infections; however, inthese cases, the dermal bone was not replaced by cartilage (Fig. 5J).Molecular analyses at HH39 (E13) indicated that IHH completelyinhibited the expression of osteopontin, Ihh and BspII, which,together, are markers of CLO cells (osteopontin, Ihh) and later-stagemature osteoblasts (osteopontin, BspII and Ihh); by contrast,earlier-stage cells, which express Runx2, Coll II and Coll IX,were unaffected (Fig. 6A-L; data not shown). In conjunctionwith our expression data, showing that CLO and mature osteoblastcells express Ihh whereas the earlier-stage preosteoblasts expressthe IHH receptor, this data suggests that IHH acts as a feedback-inhibitorof early stages of differentiation, a role very much analogousto that which it plays during limb cartilage development (Fig. 6M-P).In endochondral ossification, however, IHH acts indirectly oncartilage differentiation through PTHrP upregulation. That doesnot seem to be the case here, because PTHrP, normally expressedin CLO cells, was downregulated in the dermal bone condensationfollowing IHH misexpression, consistent with a block in differentiationat the preosteoblast stage (data not shown). We did, however, seescattered upregulation of PTHrP in mesenchyme outside of thecondensation in response to Ihh misexpression (see Fig. S4 inthe supplementary material).

Although PTHrP and IHH do not seem to form a common feedbackloop in regulating dermal differentiation, PTHrP misexpressiongives a very similar phenotype to Ihh misexpression in dermalbones, as it does in endochondral ossification. Misexpressionwith RCAS::PTHrP led to a decrease in bone mineralization atHH41 (anterior, n=9/9; posterior, n=11/11) (Fig. 5K, black arrows;data not shown). Frontal bones analyzed at a molecular levelat HH39 showed that, as did IHH, PTHrP completely inhibitedexpression of Opn, BspII and Ihh, whereas the expression domainsof Runx2, Coll II, Coll IX and Bmp4 expanded (Figs 6C-J; datanot shown). Consistent with it acting within the dermal bonedifferentiation pathway, PTHrP failed to induce the chondrogenicmarker Sox9, its known target in the endochondral bone (Huanget al., 2001) (data not shown). Thus, as does IHH, PTHrP actsduring dermal bone formation as a feedback-inhibitor preventingthe differentiation of the preosteoblasts to the CLO cell state (Fig. 6C1-F1).

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Fig. 7. Analysis of 18.5 dpc Ihh^-/- mutant mouse embryos. The skull of wild-type (WT) embryos (A-C) is larger than that of mutant siblings (D-F). Notice the presence of the ossified basal cranial bones in the mutant. Arrows indicate the leading edge of the mineralized dermal calvarial bone. Expression of the early osteoblastic markers, such as Runx2 (G) and Osx (H), is severely reduced in the Ihh^-/- condition (K and L, respectively). Red brackets indicate area occupied by undifferentiated proliferating osteoblasts. The expression of Opn (I,M), a marker for more mature osteoblasts, is unaltered or slightly expanded in the mutant condition. Green brackets indicate area occupied by differentiated mature osteoblasts. (J,N) H&E stainings of wild-type and mutant dentary bones, respectively. bas, basisphenoid; boc, basioccipital; dnt, dentary; exo, exoccipital; fnt, frontal bone; int, interparietal; max, maxillary; MC, Meckel's cartilage; nas, nasal; pal, palatal; par, parietal; pte, pterygoid; o.t., os tympanicum. Scale bars: 1 mm in A; 200 µm in G.

Molecular analysis of Ihh^-/- mouse embryos verifies the role of IHH in regulating dermal preosteoblast differentiation
Misexpression in chick embryonic heads suggests that IHH functionsto block the transition from preosteoblasts to osteoblasts.This observation suggests that loss of IHH activity should resultin premature ossification via the accelerated differentiationof preosteoblasts, and in smaller dermal bone structures viathe depletion of the pool of immature osteoprogenitors. A previousreport described the phenotype of mice carrying a targeted null mutationin Ihh (Ihh^-/-). These mice indeed displayed a smaller but otherwiseunaffected skull and endochondrally derived trunk bones weremissing (St-Jacques et al., 1999

The skulls of these mutant mice were not, however, characterizedin depth. We, therefore, reanalyzed the cranial skeletons ofwild-type and Ihh^-/- mutant 18.5 dpc embryos. We found thatthe mutant skulls were approximately 10% shorter and individualcranial bones were also smaller (n=4) (Fig. 7A-F). Interestingly,we found that the endochondrally derived cranial base bones,such as basioccipital, basisphenoid and others, were clearlypresent, albeit also proportionally smaller, in the mutant embryos (Fig. 7A-F) (Hankenand Hall, 1993). This could suggest either that there is a significantunrecognized dermal bone contribution to these structures orthat intramembranous ossification can compensate for the reductionof ossification, via the endochondral pathway. Alternatively,the endochondrally derived bones of the cranial base could differin their requirement for IHH activity from those in the limband axial skeleton. This observation is important because astrong phenotype in the cranial base would affect morphogenesisof the calvarial bones. By contrast, the jawbones are not expectedto be significantly affected by the changes in the calvarialbase. Nonetheless, dentary bones in Ihh^-/- mutants were approximately20% shorter, suggesting a localized phenotype (n=4) (Fig. 7A-F). Thiswas not due to the shortening of the Meckel's cartilage (lengthof Meckel's cartilage in wild-type mice was 3.7 mm±10%, P $≤$ 0.0058,n=7; in Ihh^-/- mutants it was 3.5 mm±14%, P $≤$ 0.007, n=8).Moreover, cells of this cartilage did not hypertrophy or expressIhh before or during the stages studied to be affected by themutation.

To investigate whether differentiation of the intramembranousosteoblasts was altered, we analyzed the expression of key skeletogenicmarkers (Fig. 7G-N). By 18.5 dpc, the dentary bones in mutantsshowed a significant downregulation of the preosteoblastic andearly-osteoblastic markers, such as Runx2 and Osx, whereas expressionof later markers, such as Opn and Osc, was unaltered or increased.This is exactly what would be expected if the loss of Ihh relieveda block in the differentiation of osteoblasts into CLO cellsand mature osteoblasts. As a result, the osteogenic front containingimmature osteoblasts was 60-70% thinner in mutant embryos, thusexplaining much of the bone size reduction (Fig. 7G,H,K,L, redbrackets). Osteoblast proliferation was only slightly downregulatedin the mutants (data not shown). This dramatic decrease in thenumber of preosteoblasts in Ihh homozygous mutants stronglysupports our model of IHH as a negative regulator of osteoblastdifferentiation during dermal bone development.

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Fig. 8. Regulation of osteoblastic differentiation in cranial dermal bone. (A) Table summarizing the expression pattern data for the developing dentary and frontal bones. Four major cell types could be distinguished based on skeletogenic markers: proliferating cells at the periphery of the osteogenic front, cells expressing only Runx2, preosteoblastic progenitors and surrounding cells expressing Runx2, Coll II, Coll IX, Ptc1, Gli1, PTHrP-R and Bmp4. (1) These cells differentiate into the CLO (chondrocyte-like osteoblast) cells expressing a unique combination of Opn, Coll II and Coll IX (but not Sox9 or aggrecan) as well as Ihh, Ptc1, Gli1, Bmp4 and PTHrP. As these cells develop into mature osteoblasts, they downregulate Coll II and Coll IX expression and, out of the analyzed markers, they express only Opn, BspII and Ihh. (2) Alternatively, some cells could differentiate directly into mature osteoblasts. (B) During craniofacial development, mesencephalic cranial neural crest cells migrate to populate mesenchyme of the future face and skull. Cells of the early cranial skeletogenic condensations depend on BMP2/4/7 activities to form preosteoblastic progenitors, whereas high levels of BMP2 and/or BMP4 alone induced a chondrogenic fate. Differentiation into the chondrocyte-like osteoblasts is regulated by both IHH and PTHrP activities.

	DISCUSSION

TOP SUMMARY INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

Dermal bone osteoblasts differentiate via a novel transient cell type
Our in situ hybridization analyses show that many of the dermalbone cells express combinations of skeletal markers not seenduring endochondral bone development. It is known that someof these markers, taken individually, can be shared by bothchondrogenic and osteogenic progenitors, especially during earlydifferentiation decisions. For example, Sox9, generally thought ofas a cartilage marker, is expressed by all early osteochondralprogenitors and in all cranial neural crest cells, includingthose giving rise to osteoblasts (Ng et al., 1997

; Zhao et al.,1997

). Similarly, although considered a bone marker, Runx2 expressionin early chondrocyte progenitors also appears important fortheir differentiation (Stricker et al., 2002

; Komori et al.,1997

; Otto et al., 1997

). However, as cells become differentiated,such markers become highly cell type specific. For example,Sox9, Coll II and Coll IX are expressed only in differentiatedchondrocytes and never overlap with the expression of more-matureosteoblastic markers, such as Opn. Thus, cell types in whichsuch unusual, albeit transient, combinations of both osteoblastand chondrocyte markers are found are unique to the developingdermal bone.

These cell types had not been previously recognized as such.Expression of the chondrogenic markers Coll II, Coll IX andaggrecan in the developing dermal bone was previously reportedas a result of northern blot and immunohistochemical analysis.However, in the absence of osteogenic markers and single-cellresolution, it was concluded that Coll II, Coll IX and aggrecanexpression was restricted to typical cartilage cells. Consequently,dermal bones were suggested to develop through a transient chondrogenicphase similar to the prechondrogenic mesenchyme (Ting et al.,1993; Nah et al., 2000). Also, the idea of an `osteochondro-progenitor'(osteochondral progenitor) has been around for some time, butthis concept referred to very early populations of cells givingrise to both chondrocytes and osteoblasts, whereas, in our study, werefer to a population of cells expressing markers indicativeof a differentiated osteoblastic state that are fated to giverise only to mature osteoblasts (Gerstenfeld and Shapiro, 1996;Akiyama Ddagger et al., 2005; Smith et al., 2005). Interestingly,although both Coll II and Coll IX RNA are readily observed inthese cells, we were unable to detect their translation productswith specific antibodies, indicating a post-transcriptionalregulation of collagen production specifically in these cells.

A model for dermal bone development
Cranial neural crest cells migrated to the facial region, inwhich, in response to ecto-mesenchymal interactions, they differentiatedinto skeletogenic progenitor cells, which formed condensationscapable of differentiating along either the chondrogenic orosteogenic lineage (Fig. 8B). Our noggin misexpression experimentsindicate that BMP signaling is required for these bi-potentialcondensations to form. In addition, the effect of BMP misexpressionindicates that further BMP signaling acts to direct cells towardsa chondrogenic pathway at the expense of dermal osteogenesis,by inducing Sox9 expression and inhibiting the expression of Runx2and osteopontin. The dermal condensations that committed toan osteogenic fate first expressed Runx2 in the early preosteoblastsof the proliferating osteogenic fronts and subsequently expressedRunx2, Coll II and Coll IX. These cells also expressed receptorsfor IHH and PTHrP, and, accordingly, are targets for the actionof those factors. These preosteoblasts differentiated into CLOcells by downregulating Runx2 expression and by expressing osteopontinin addition to Coll II and Coll IX. The CLO cells finally differentiatedinto mature osteoblasts expressing BspII, osteopontin and osteocalcin.Our recombinase-based fate mapping verified that the Coll II-expressingcells were indeed precursors of the mature dermal osteoblasts.Not all of the mature osteoblasts expressed the lacZ lineagemarkers in our experiments. Although this might reflect incompleterecombination due to less than uniform expression of the Col2::Cre3transgene, it also remains possible that there is an alternativedifferentiation pathway in which mesenchymal cells differentiate intomature osteoblasts without ever expressing Coll II (Fig. 8A).

The transition of the proliferating preosteoblasts to CLO cellsappears to be particularly important, moving from an expandingto a differentiating phase. This transition was regulated bytwo different factors, IHH and PTHrP, in apparently parallelpathways. Both factors were expressed by CLO cells and acted,presumably through their respective receptors, on preosteoblastsin the preceding stage in order to limit the differentiationof these cells. The role of IHH in maintaining dermal osteogeniccells in a proliferative state is consistent with the observationof the significantly smaller-than-normal size skulls and individualskull bones in the Ihh knockout embryos (Fig. 6) (St-Jacqueset al., 1999). Moreover, molecular analysis of Ihh^-/- mutantssuggests that the pool of preosteoblasts is depleted in theseanimals, whereas overall osteoblast differentiation was normal(Fig. 7G-N). The fact that there was sufficient proliferationin the absence of IHH to form skeletal elements with normal(albeit smaller) morphology (Fig. 7A-F) (St-Jacques et al.,1999; Suda et al., 2001; Long et al., 2001) might be explainedby the partially redundant role of PTHrP in negatively regulating thesame cellular transition. This negative regulation by IHH andPTHrP is analogous to their roles in controlling the pre-hypetrophic-to-hypertrophic chondrocytetransition.

Taken together, the studies reported here define a series ofcellular transitions that underlie dermal bone formation. Inparticular, we have identified four distinct stages of differentiation,namely the early preosteoblast, preosteoblast, chondrocyte-likeosteoblast and mature osteoblast stages (Fig. 8A). The progressionof cell types that we have identified provided us with a contextfor investigating the regulation of dermal bone formation. Further, ourstudies provide evidence for the roles of several key signalsin regulating these transitions. This model should provide auseful framework for future studies addressing the mechanismof craniofacial skeletal development.

Supplementary material
Supplementary material for this article is available at http://dev.biologists.org/cgi/content/full/134/17/3133/DC1

ACKNOWLEDGMENTS

Work on this project in both the C.J.T. and A.P.M. laboratorieswas funded by a program project grant PO1 DK56246 from the NIH.A.A. was supported by the Cancer Research Fund of the DamonRunyon-Walter Winchell Foundation Fellowship, DRG1618. S.J.R.was supported by postdoctoral fellowships from the NHMRC ofAustralia (#301299) and the Arthritis Foundation (#401683).

Footnotes

^* Present address: Department of Organismic and Evolutionary Biology,Harvard University, 16 Divinity Avenue, Cambridge, MA 02138,USA

REFERENCES

TOP
SUMMARY
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
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