A WNT/beta-catenin signaling activator, R-spondin, plays positive regulatory roles during skeletal myogenesis.

R-spondins (RSPOs) are a recently characterized family of secreted proteins that activate WNT/ß-catenin signaling. In this study, we investigated the potential roles of the RSPO proteins during myogenic differentiation. Overexpression of the Rspo1 gene or administration of recombinant RSPO2 protein enhanced mRNA and protein expression of a basic helix-loop-helix (bHLH) class myogenic determination factor, MYF5, in both C2C12 myoblasts and primary satellite cells, whereas MYOD or PAX7 expression was not affected. RSPOs also promoted myogenic differentiation and induced hypertrophic myotube formation in C2C12 cells. In addition, Rspo2 and Rspo3 gene knockdown by RNA interference significantly compromised MYF5 expression, myogenic differentiation, and myotube formation. Furthermore, Myf5 expression was reduced in the developing limbs of mouse embryos lacking the Rspo2 gene. Finally, we demonstrated that blocking of WNT/ß-catenin signaling by DKK1 or a dominant-negative form of TCF4 reversed MYF5 expression, myogenic differentiation, and hypertrophic myotube formation induced by RSPO2, indicating that RSPO2 exerts its activity through the WNT/ß-catenin signaling pathway. Our results provide strong evidence that RSPOs are key positive regulators of skeletal myogenesis acting through the WNT/ß-catenin signaling pathway.

Bilateral lambdoid and sagittal synostosis (BLSS): a unique craniosynostosis syndrome or predictable craniofacial phenotype?

Multisutural craniosynostosis that includes bilateral lambdoid and sagittal synostosis (BLSS) results in a very characteristic head shape with frontal bossing, turribrachycephaly, biparietal narrowing, occipital concavity, and inferior displacement of the ears. This entity has been reported both in the genetics literature as craniofacial dyssynostosis and in the surgical literature as "Mercedes Benz" syndrome. Craniofacial dyssynostosis was first described in 1976 by Dr. Neuhauser when he presented a series of seven patients with synostosis of the sagittal and lambdoid sutures, short stature, and developmental delay. Over the past 30 years nine additional patients with craniofacial dyssynostosis have been reported in the literature adding to the growing evidence for a distinct craniosynostosis syndrome. The term "Mercedes Benz" syndrome was coined by Moore et al. in 1998 due to the characteristic appearance of the fused sutures on three-dimensional CT imaging. In contrast to the aforementioned reported cases of craniofacial dyssynostosis, all three patients had normal development. Recently, there have been several case reports of patients with BLSS and distinct chromosomal anomalies. These findings suggest that BLSS is a heterogeneous disorder perhaps with syndromic, chromosomal, and isolated forms. In this manuscript we will present the largest series of patients with BLSS and review clinical, CT, and molecular findings.

An in vivo reporter of BMP signaling in organogenesis reveals targets in the developing kidney.

BACKGROUND: Bone morphogenetic proteins (BMPs) regulate essential processes during organogenesis, and a functional understanding of these secreted proteins depends on identification of their target cells. In this study, we generate a transgenic reporter for organogenesis studies that we use to define BMP pathway activation in the developing kidney. RESULTS: Mouse strains reporting on BMP pathway activation were generated by transgenically expressing beta-galactosidase under the control of BMP responsive elements from Id1. Reporter expression corresponds well with immunoassays for pathway activation in all organs studied, validating the model. Using these reporters we have generated a detailed map of cellular targets of BMP signaling in the developing kidney. We find that SMAD dependent BMP signaling is active in collecting duct trunks, but not tips. Furthermore, glomerular endothelial cells, and proximal nephron tubules from the renal vesicle stage onward show pathway activation. Surprisingly, little activation is detected in the nephrogenic zone of the kidney, and in organ culture BMP treatment fails to activate SMAD dependent BMP signaling in nephron progenitor cells. In contrast, signaling is efficiently induced in collecting duct tips. CONCLUSION: Transgenic reporters driven by control elements from BMP responsive genes such as Id1 offer significant advantages in sensitivity and consistency over immunostaining for studies of BMP pathway activation. They also provide opportunities for analysis of BMP signaling in organ and primary cell cultures subjected to experimental manipulation. Using such a reporter, we made the surprising finding that SMAD dependent BMP signaling is inactive in nephron progenitors, and that these cells are refractory to activation by applied growth factors. Furthermore, we find that the BMP pathway is not normally active in collecting duct tips, but that it can be ectopically activated by BMP treatment, offering a possible explanation for the inhibitory effects of BMP treatment on collecting duct growth and branching.

Syndromic craniosynostosis: from history to hydrogen bonds.

The syndromic craniosynostoses, usually involving multiple sutures, are hereditary forms of craniosynostosis associated with extracranial phenotypes such as limb, cardiac, CNS and tracheal malformations. The genetic etiology of syndromic craniosynostosis in humans is only partially understood. Syndromic synostosis has been found to be associated with mutations of the fibroblast growth factor receptor family (FGFR1, -R2, -R3), TWIST1, MSX2, and EFNB1. Apert, Pfeiffer, Crouzon, and Jackson-Weiss syndromes are due to gain-of-function mutations of FGFR2 in either the Ig II-III linker region (Apert) or Ig III domain. Loss of function mutations of TWIST1 and gain-of-function mutations of MSX2 lead to Saethre-Chotzen and Boston-type syndromes, respectively. The mutations in Pfeiffer (FGFR1), Muenke (FGFR3), and Apert syndrome (FGFR2) are caused by the same amino acid substitution in a highly conserved region of the Ig II-III linker region of these proteins, which suggests that these receptor tyrosine kinases have an overlapping function in suture biology. In this review we will discuss the historical descriptions, current phenotypes and molecular causes of the more common forms of syndromic craniosynostosis.

Isolated sagittal and coronal craniosynostosis associated with TWIST box mutations.

Craniosynostosis, the premature fusion of one or more cranial sutures, affects 1 in 2,500 live births. Isolated single-suture fusion is most prevalent, with sagittal synostosis occurring in 1/5,000 live births. The etiology of isolated (nonsyndromic) single-suture craniosynostosis is largely unknown. In syndromic craniosynostosis, there is a highly nonrandom pattern of causative autosomal dominant mutations involving TWIST1 and fibroblast growth factor receptors (FGFRs). Prior to our study, there were no published TWIST1 mutations in the anti-osteogenic C-terminus, recently coined the TWIST Box, which binds and inhibits RUNX2 transactivation. RUNX2 is the principal master switch for osteogenesis. We performed mutational analysis on 164 infants with isolated, single-suture craniosynostosis for mutations in TWIST1, the IgIIIa exon of FGFR1, the IgIIIa and IgIIIc exons of FGFR2, and the Pro250Arg site of FGFR3. We identified two patients with novel TWIST Box mutations: one with isolated sagittal synostosis and one with isolated coronal synostosis. Kress et al. [2006] reported a TWIST Box "nondisease-causing polymorphism" in a patient with isolated sagittal synostosis. However, compelling evidence suggests that their and our sequence alterations are pathogenic: (1) a mouse with a mutation of the same residue as our sagittal synostosis patient developed sagittal synostosis, (2) mutation of the same residue precluded TWIST1 interaction with RUNX2, (3) each mutation involved nonconservative amino acid substitutions in highly conserved residues across species, and (4) control chromosomes lacked TWIST Box sequence alterations. We suggest that genetic testing of patients with isolated sagittal or coronal synostosis should include TWIST1 mutational analysis.

Intracellular retention, degradation, and signaling of glycosylation-deficient FGFR2 and craniosynostosis syndrome-associated FGFR2C278F.

Fibroblast growth factors (FGFs) and their receptors (FGFRs) are known to play a critical role in a variety of fundamental processes, including wound healing, angiogenesis, and development of multiple organ systems. Mutations in the FGFR gene family have been linked to a series of syndromes (the craniosynostosis syndromes) whose primary phenotype involves aberrant development of the craniofacial skeleton. Craniosynostosis syndrome-linked FGFR mutations have been shown to be gain of function in terms of receptor activation and have been presumed to result in increased levels of FGF/FGFR signaling. Unfortunately, studies attempting to link expression of mutant FGFRs with changes in cellular phenotype have yielded conflicting results. In an effort to better understand the biochemical consequences of these mutations on receptor function, here we have investigated the effect of the FGFR2C278F mutation of Crouzon craniosynostosis syndrome on receptor trafficking, ubiquitination, degradation, and signaling. We find that FGFR2C278F exhibits diminished glycosylation, increased degradation, and limited cellular sublocalization in the osteoblastic cell line, MC3T3E1(C4). Additionally, we show that trafficking and autoactivation of wild type FGFR2 is glycosylation-dependent. Both FGFR2C278F and unglycosylated wild type FGFR2 signal through phospholipase Cgamma in a ligand-independent manner as well as exhibit dramatically increased binding to the adaptor protein, Frs2. These findings suggest that autoactive FGFR2 can signal from intracellular compartments. Based upon our results, we propose that the functional signaling of craniosynostosis mutant, autoactive receptors is limited in some cell types by protective cellular responses, such as increased trafficking to lysosomes and proteasomes for degradation.

Cleidocranial dysplasia with severe parietal bone dysplasia: C-terminal RUNX2 mutations.

BACKGROUND: Cleidocranial dysplasia (CCD) is an autosomal-dominant skeletal dysplasia syndrome that is characterized by widely patent calvarial sutures, clavicular hypoplasia, supernumerary teeth, and short stature. CCD is caused by mutations in the transcription factor RUNX2, which is known to function as a major regulator of bone differentiation. Despite the characterization of 67 unique mutations in 97 individual cases, and the availability of animal models, no obvious genotype-phenotype correlation has emerged. METHODS: We describe 3 new cases that were ascertained on the basis of a severe calvarial phenotype, that were associated with 3 novel mutations in the C-terminal region of RUNX2 distal to the DNA-binding runt domain. In addition, a review of all previously described cases was undertaken in an effort to standardize mutation nomenclature, characterize the position of known mutations relative to the runt domain, and explore the hypothesis that C-terminal mutations that preserve the runt domain may lead to more-severe craniofacial phenotypes. RESULTS: Upon mutational analysis of RUNX2, we identified either frameshift or splice-site mutations that affect the C-terminal region of the resultant protein distal to the runt domain. CONCLUSIONS: In the context of previously described mutations, these cases suggest that C-terminal mutations that preserve the DNA-binding runt domain while disrupting the SMAD 1,2,3,5 binding domain and the nuclear matrix targeting signal may be responsible for the severe phenotype observed.

In vitro differentiation profile of osteoblasts derived from patients with Saethre-Chotzen syndrome.

Seathre-Chotzen syndrome (SCS) is an autosomal dominant craniosynostosis syndrome, associated with loss-of-function mutations in the basic helix-loop-helix transcription factor, TWIST1. The biologic activity of TWIST1 has been implicated in the inhibition of differentiation of multiple cell lineages. Therefore, premature fusion of cranial sutures (craniosynostosis) in SCS may be mediated by altered differentiation of calvarial osteoblasts. In this study, we evaluated osteoblasts derived from calvarial bone of three patients with SCS and three unaffected individuals as controls to investigate the principle stages of osteoblast differentiation: (1) proliferation, (2) matrix maturation, and (3) mineralization. Using a BrdU-Hoechst flow cytometry assay, we found that the percent of proliferating cells was significantly reduced in cells derived from patients with SCS compared with those derived from controls (P < or = 0.05). In the matrix maturation stage, alkaline phosphatase (ALP) enzyme activity and the expression of extracellular matrix genes, collagen I alpha 2 (COL1A2), osteopontin (OPN), osteocalcin (OC), and the runt-related transcription factor RUNX2 were examined by enzymatic assay and real-time quantitative RT-PCR, respectively. We identified no significant differences in the expression of matrix related transcripts. However, we found significant reductions in ALP activity on days 3 and 7 and in RUNX2 expression on days 14 and 21 (P < or = 0.05). Quantitative alizarin red S mineralization assays showed a trend toward increased mineralization in osteoblasts derived from patients with SCS at days 21 and 28, although not statistically significant. Our results demonstrated that loss-of-function mutations of TWIST1 led to reduced proliferation regardless of the functional domain affected. We did not find any conclusive differences in matrix maturation or mineralization in these primary osteoblasts. It is plausible that mutations in different functional domains of TWIST1 have divergent effects on these later stages of differentiation.

Progressive postnatal craniosynostosis and increased intracranial pressure.

Since its first description by Virchow in 1851, craniosynostosis has been known as a potentially serious condition resulting in premature fusion of skull sutures. Traditionally, craniosynostosis has been regarded as an event that occurs early in fetal development, resulting in a skull shape at birth that is determined by the suture or sutures involved. In recent years, a different form of craniosynostosis has been observed. Patients initially come to the attention of physicians because they exhibit midface hypoplasia or occasionally hypertelorism. The affected individuals all have a normal skull shape and open sutures in infancy but develop multiple-suture craniosynostosis postnatally, ultimately requiring surgical correction. These cases are significant because, although the patients do not initially display the physical manifestations of craniosynostosis, they frequently develop increased intracranial pressure, which can have devastating consequences. Unless these patients are recognized and vigilant follow-up monitoring is instituted at an early age, permanent impairment can result. A retrospective chart review study was conducted, and patients with multiple-suture craniosynostosis who developed symptoms of increased intracranial pressure were selected. The patients were divided into two groups, namely, those with normal sutures and/or head shape at birth (progressive craniosynostosis) (n = 15) and those with abnormal head shapes at birth (classic syndromic craniosynostosis) (n = 12). Clinical and radiological findings typically used to monitor the development of increased intracranial pressure were reviewed for both groups and compared. In addition, mutational analyses were performed. All patients with progressive postnatal craniosynostosis demonstrated clinical, radiological, or ophthalmological evidence of increased intracranial pressure, requiring skull expansion. Those patients displayed papilledema, anterior fontanelle bulge, and thumbprinting more often than did the patients with classic craniosynostosis. Thirteen of 15 patients were given the clinical diagnosis of Crouzon syndrome, which raises the question of whether such patients represent a subset of patients with this syndrome. Mutational analyses for the patients with progressive craniosynostosis demonstrated that, of 13 patients tested, 11 had mutations in exon 7 or 9 of FGFR2, which is a common site of mutations in Crouzon syndrome. The traditional indications of increased intracranial pressure used to monitor patients with classic craniosynostosis can be used to monitor patients with progressive postnatal craniosynostosis, particularly anterior fontanelle bulge, papilledema, and thumbprinting. It is thought that regular monitoring of these characteristics may lead to earlier diagnosis and allow for surgical intervention before the development of undesirable outcomes. It is important for clinicians to be aware of this group of patients, because any delay in diagnosis and treatment can result in severe consequences for the patients.

A child with Saethre-Chotzen syndrome, sensorineural hearing loss, and a TWIST mutation.

OBJECTIVE: Patients with syndromic craniosynostosis may have associated hearing deficits. A review of hearing loss associated with syndromic craniosynostosis as well as implications of cochlear implantation in the craniosynostosis patients is presented. In the literature, patients with Saethre-Chotzen syndrome have been shown to have conductive or mixed hearing losses. This case report describes a patient with Saethre-Chotzen syndrome caused by a mutation in the TWIST gene who exhibits a severe to profound sensorineural hearing loss.