Demineralized murine skeletal histology.

Cartilage and bone are specialized skeletal tissues composed of unique extracellular matrices. Bone, in particular, has a highly calcified or mineralized matrix that makes microtomy and standard histological studies very challenging. Therefore, methods to appropriately fix and decalcify mineralized skeletal tissues have been developed to allow for paraffin processing and standard microtomy. In this chapter, we illustrate methods for tissue grossing, fixation, decalcification, paraffin processing, embedding, sectioning, and routine histological staining of demineralized murine skeletal tissues. We also discuss methods for decalcified frozen sectioning of skeletal tissues with and without the use of a tape-transfer system.

Osr2 acts downstream of Pax9 and interacts with both Msx1 and Pax9 to pattern the tooth developmental field.

Mammalian tooth development depends on activation of odontogenic potential in the presumptive dental mesenchyme by the Msx1 and Pax9 transcription factors. We recently reported that the zinc finger transcription factor Osr2 was expressed in a lingual-to-buccal gradient pattern surrounding the developing mouse molar tooth germs and mice lacking Osr2 developed supernumerary teeth lingual to their molars. We report here generation of a gene-targeted mouse strain that allows conditional inactivation of Pax9 and subsequent activation of expression of Osr2 in the developing tooth mesenchyme from the Pax9 locus. Expression of Osr2 from one copy of the Pax9 gene did not disrupt normal tooth development but was sufficient to suppress supernumerary tooth formation in the Osr2(-/-) mutant mice. We found that endogenous Osr2 mRNA expression was significantly downregulated in the developing tooth mesenchyme in Pax9(del/del) mice. Mice lacking both Osr2 and Pax9 exhibited early tooth developmental arrest with significantly reduced Bmp4 and Msx1 mRNA expression in the developing tooth mesenchyme, similar to that in Pax9(del/del) mutants but in contrast to the rescue of tooth morphogenesis in Msx1(-/-)Osr2(-/-) double mutant mice. Furthermore, we found that Osr2 formed stable protein complexes with the Msx1 protein and interacted weakly with the Pax9 protein in co-transfected cells. These data indicate that Osr2 acts downstream of Pax9 and patterns the mesenchymal odontogenic field through protein-protein interactions with Msx1 and Pax9 during early tooth development.

Bmpr1a signaling plays critical roles in palatal shelf growth and palatal bone formation.

Cleft palate, including submucous cleft palate, is among the most common birth defects in humans. While overt cleft palate results from defects in growth or fusion of the developing palatal shelves, submucous cleft palate is characterized by defects in palatal bones. In this report, we show that the Bmpr1a gene, encoding a type I receptor for bone morphogenetic proteins (Bmp), is preferentially expressed in the primary palate and anterior secondary palate during palatal outgrowth. Following palatal fusion, Bmpr1a mRNA expression was upregulated in the condensed mesenchyme progenitors of palatal bone. Tissue-specific inactivation of Bmpr1a in the developing palatal mesenchyme in mice caused reduced cell proliferation in the primary and anterior secondary palate, resulting in partial cleft of the anterior palate at birth. Expression of Msx1 and Fgf10 was downregulated in the anterior palate mesenchyme and expression of Shh was downregulated in the anterior palatal epithelium in the Bmpr1a conditional mutant embryos, indicating that Bmp signaling regulates mesenchymal-epithelial interactions during palatal outgrowth. In addition, formation of the palatal processes of the maxilla was blocked while formation of the palatal processes of the palatine was significantly delayed, resulting in submucous cleft of the hard palate in the mutant mice. Our data indicate that Bmp signaling plays critical roles in the regulation of palatal mesenchyme condensation and osteoblast differentiation during palatal bone formation.

Jag2-Notch1 signaling regulates oral epithelial differentiation and palate development.

During mammalian palatogenesis, palatal shelves initially grow vertically from the medial sides of the paired maxillary processes flanking the developing tongue and subsequently elevate and fuse with each other above the tongue to form the intact secondary palate. Pathological palate-mandible or palate-tongue fusions have been reported in humans and other mammals, but the molecular and cellular mechanisms that prevent such aberrant adhesions during normal palate development are unknown. We previously reported that mice deficient in Jag2, which encodes a cell surface ligand for the Notch family receptors, have cleft palate associated with palate-tongue fusions. In this report, we show that Jag2 is expressed throughout the oral epithelium and is required for Notch1 activation during oral epithelial differentiation. We show that Notch1 is normally highly activated in the differentiating oral periderm cells covering the developing tongue and the lateral oral surfaces of the mandibular and maxillary processes during palate development. Oral periderm activation of Notch1 is significantly attenuated during palate development in the Jag2 mutants. Further molecular and ultrastructural analyses indicate that oral epithelial organization and periderm differentiation are disrupted in the Jag2 mutants. Moreover, we show that the Jag2 mutant tongue fused to wild-type palatal shelves in recombinant explant cultures. These data indicate that Jag2-Notch1 signaling is spatiotemporally regulated in the oral epithelia during palate development to prevent premature palatal shelf adhesion to other oral tissues and to facilitate normal adhesion between the elevated palatal shelves.

Expression of Wnt9b and activation of canonical Wnt signaling during midfacial morphogenesis in mice.

Cleft lip with or without cleft palate (CLP) is the most common craniofacial birth defect in humans. Recently, mutations in the WNT3 and Wnt9b genes, encoding two members of the Wnt family of signaling molecules, were found associated with CLP in human and mice, respectively. To investigate whether Wnt3 and Wnt9b directly regulate facial development, we analyzed their developmental expression patterns and found that both Wnt3 and Wnt9b are expressed in the facial ectoderm at critical stages of midfacial morphogenesis during mouse embryogenesis. Whereas Wnt3 mRNA is mainly expressed in the maxillary and medial nasal ectoderm, Wnt9b mRNA is expressed in maxillary, medial nasal, and lateral nasal ectoderm. During lip fusion, Wnt9b, but not Wnt3, is expressed in the epithelial seam between the fusing medial and lateral nasal processes. Furthermore, we found that expression of TOPGAL, a transgenic reporter of activation of canonical Wnt signaling pathway, is specifically activated in the distal regions of the medial nasal, lateral nasal, and maxillary processes prior to lip fusion. During lip fusion, the epithelial seam between the medial and lateral nasal processes as well as the facial mesenchyme directly beneath the fusing epithelia strongly expresses TOPGAL. These data, together with the CLP lip phenotype in WNT3-/- humans and Wnt9b-/- mutant mice, indicate that Wnt3 and Wnt9b signal through the canonical Wnt signaling pathway to regulate midfacial development and lip fusion.

Identification and developmental expression analysis of a novel homeobox gene closely linked to the mouse Twirler mutation.

The Twirler mutation arose spontaneously and causes inner ear defects in heterozygous and cleft lip and/or cleft palate in homozygous mutant mice, providing a unique animal model for investigating the molecular mechanisms of inner ear and craniofacial development. Here, we report the identification of a novel homeobox gene, Iroquois-related homeobox like-1 (Irxl1), from the Twirler locus. Irxl1 encodes a TALE-family homeodomain protein with its homeodomain exhibiting the highest amino acid sequence identity (54%) to those of invertebrate Iroquois and vertebrate Irx subfamily members. The putative Irxl1 protein lacks the Iro-box, a conserved motif in all known members of the Irx subfamily. Searching the databases showed that Irxl1 orthologs exist in Xenopus, chick, and mammals. In situ hybridization analyses of mouse embryos at various developmental stages showed that Irxl1 mRNA is highly expressed in the frontonasal process and palatal mesenchyme during primary and secondary palate development. In addition, Irxl1 mRNA is strongly expressed in mesenchyme surrounding the developing inner ear, in discrete regions of the developing mandible, in the dermamyotome during somite differentiation, and in a subset of muscular structures in late embryonic stages. The developmental expression pattern indicates that Irxl1 is a good candidate gene for the Twirler gene.

Odd-skipped related 1 (Odd 1) is an essential regulator of heart and urogenital development.

The Odd-skipped related 1 (Odd 1) gene encodes a zinc finger protein homologous to the Drosophila Odd-skipped class transcription factors that play critical roles in embryonic patterning and tissue morphogenesis. We have generated mice carrying a targeted null mutation in the Odd 1 gene and show that Odd 1 is essential for heart and intermediate mesoderm development. Odd 1(-/-) mutant mouse embryos fail to form atrial septum, display dilated atria with hypoplastic venous valves, and exhibit blood backflow from the heart into systemic veins. In contrast to other transcription factors implicated in atrial septum development, Odd 1 mRNA expression is restricted to the central dorsal domain of the atrial myocardium during normal heart development. Moreover, expression patterns of known key regulatory genes of atrial septum development, including Nkx2.5, Pitx2, and Tbx5, are unaltered in the developing heart in Odd 1(-/-) mutants compared to that of the wild-type littermates. Furthermore, homozygous Odd 1(-/-) mutant embryos exhibit complete agenesis of adrenal glands, metanephric kidneys, gonads, and defects in pericardium formation. Detailed molecular marker analyses show that key regulators of early intermediate mesoderm development, including Lhx1, Pax2, and Wt1, are all down-regulated and nephrogenic mesenchyme undergoes massive apoptosis, resulting in disruption of nephric duct elongation and failure of metanephric induction in the Odd 1(-/-) mutant embryos. These data provide new insights into the molecular mechanisms underlying heart morphogenesis and urogenital development.

Odd-skipped related 2 (Osr2) encodes a key intrinsic regulator of secondary palate growth and morphogenesis.

Development of the mammalian secondary palate involves multiple steps of highly regulated morphogenetic processes that are frequently disturbed during human development, resulting in the common birth defect of cleft palate. Neither the molecular processes governing normal palatogenesis nor the causes of cleft palate is well understood. In an expression screen to identify new transcription factors regulating palate development, we previously isolated the odd-skipped related 2 (Osr2) gene, encoding a zinc-finger protein homologous to the Drosophila odd-skipped gene product, and showed that Osr2 mRNA expression is specifically activated in the nascent palatal mesenchyme at the onset of palatal outgrowth. We report that a targeted null mutation in Osr2 impairs palatal shelf growth and causes delay in palatal shelf elevation, resulting in cleft palate. Whereas palatal outgrowth initiates normally in the Osr2 mutant embryos, a significant reduction in palatal mesenchyme proliferation occurs specifically in the medial halves of the downward growing palatal shelves at E13.5, which results in retarded, mediolaterally symmetric palatal shelves before palatal shelf elevation. The developmental timing of palatal growth retardation correlates exactly with the spatiotemporal pattern of Osr1 gene expression during palate development. Furthermore, we show that the Osr2 mutants exhibit altered gene expression patterns, including those of Osr1, Pax9 and Tgfb3, during palate development. These data identify Osr2 as a key intrinsic regulator of palatal growth and patterning.

The T-box gene Tbx10 exhibits a uniquely restricted expression pattern during mouse embryogenesis.

The human TBX10 gene was previously identified from a genomic DNA sequence containing a partial open reading frame and was mapped to Chromosome 11q13, a chromosomal region associated with multiple inherited developmental disorders. Since mutations in several T-box family genes have been found to underlie distinct inherited developmental disorders, it has been speculated that TBX10 may be a candidate for one of the disease loci at Chromosome 11q13. To investigate the role of TBX10 in development and pathogenesis, we have isolated a full-length human TBX10 cDNA and cloned the mouse ortholog, Tbx10. Sequence analysis of cDNA clones and reverse transcription-polymerase chain reaction products revealed that the previously predicted TBX10 open reading frame (GenBank accession number AH006177) was incorrect. We have characterized the developmental expression patterns of Tbx10 during mouse embryogenesis by using in situ hybridization analyses. Our results show that Tbx10 mRNA expression is highly restricted and exhibits a unique spatio-temporal pattern during hindbrain development. These data will facilitate investigation of the role of TBX10 in development and disease.

Isolation and developmental expression analysis of Tbx22, the mouse homolog of the human X-linked cleft palate gene.

Mutations in the TBX22 gene have been identified recently in patients with the X-linked cleft palate and ankyloglossia syndrome, suggesting that the TBX22 transcription factor plays an important role in palate development. However, because ankyloglossia has been reported in the majority of patients with TBX22 mutations, it has been speculated that the cleft palate phenotype is secondary to defective fetal tongue movement. To understand the role of TBX22 in disease pathogenesis and in normal development, it is necessary to carry out a detailed temporal and spatial gene expression analysis. We report here the isolation and developmental expression analysis of the mouse homolog Tbx22. The mouse Tbx22 gene encodes a putative protein of 517 amino acid residues, which shares 72% overall amino acid sequence identity with the human TBX22 protein. By using interspecific backcross analysis, we have localized the Tbx22 gene to mouse chromosome X, in a region syntenic to human chromosome Xq21, where the TBX22 gene resides, indicating that Tbx22 is the ortholog of human TBX22. Our in situ hybridization analysis shows that Tbx22 is expressed in a temporally and spatially highly restricted pattern during mouse palate and tongue development. Together with the mutant phenotypes in human patients, our data indicate a primary role for Tbx22 in both palate and tongue development.

Expression of human smooth muscle calponin in transgenic mice revealed with a bacterial artificial chromosome.

Defining regulatory elements governing cell-restricted gene expression can be difficult because cis-elements may reside tens of kilobases away from start site(s) of transcription. Artificial chromosomes, which harbor hundreds of kilobases of genomic DNA, preserve a large sequence landscape containing most, if not all, regulatory elements controlling the expression of a particular gene. Here, we report on the use of a bacterial artificial chromosome (BAC) to begin understanding the in vivo regulation of smooth muscle calponin (SM-Calp). Long and accurate polymerase chain reaction, sequencing, and in silico analyses facilitated the complete sequence annotation of a BAC harboring human SM-Calp (hSM-Calp). RNase protection, in situ hybridization, Western blotting, and immunohistochemistry assays showed the BAC clone faithfully expressed hSM-Calp in both cultured cells and transgenic mice. Moreover, expression of hSM-Calp mirrored that of endogenous mouse SM-Calp suggesting that all cis-regulatory elements governing hSM-Calp expression in vivo were contained within the BAC. These BAC mice represent a new model system in which to systematically assess regulatory elements governing SM-Calp transcription in vivo.