Mutations of the TWIST gene in the Saethre-Chotzen syndrome.

Saethre-Chotzen syndrome (acrocephalo-syndactyly type III, ACS III) is an autosomal dominant craniosynostosis with brachydactyly, soft tissue syndactyly and facial dysmorphism including ptosis, facial asymmetry and prominent ear crura. ACS III has been mapped to chromosome 7p21-22. Of interest, TWIST, the human counterpart of the murine Twist gene, has been localized on chromosome 7p21 as well. The Twist gene product is a transcription factor containing a basic helix-loop-helix (b-HLH) domain, required in head mesenchyme for cranial neural tube morphogenesis in mice. The co-localisation of ACS III and TWIST prompted us to screen ACS III patients for TWIST gene mutations especially as mice heterozygous for Twist null mutations displayed skull defects and duplication of hind leg digits. Here, we report 21-bp insertions and nonsense mutations of the TWIST gene (S127X, E130X) in seven ACS III probands and describe impairment of head mesenchyme induction by TWIST as a novel pathophysiological mechanism in human craniosynostoses.

Dorso-ventral and rostro-caudal sequential expression of M-twist in the postimplantation murine embryo.

M-twist is the murine homolog of the Drosophila twist gene which is a zygotic target for maternal genes that establish embryonic dorso-ventral polarity and is necessary for mesoderm formation. We recently showed that before gastrulation, M-twist transcripts are detected in morulae and blastocysts, then in extra-embryonic tissues of early implanted mouse embryos before the onset of gastrulation, and we suggested that M-twist might be involved in embryonic polarity (Stoetzel et al., submitted). Here, using in situ hybridization on whole mount embryos, we present the expression pattern of M-twist from primitive streak stage up to 10.5 days p.c. In implanted embryos, M-twist is first expressed in extra-embryonic tissues, then in embryo proper around egg cylinder stage within some embryonic ectodermal cells of the primitive streak. Slightly later, scattered cells within the amniotic cavity apparently detached from the primitive streak also express the gene. Then, M-twist transcripts accumulate in head mesenchyme, the first aortic arches, somites and lateral mesoderm and, as development proceeds, successively the second, third and fourth branchial arches, the anterior limb buds and, finally, the posterior limb buds. Thus M-twist expression in implanted embryos occurs first along a dorso-ventral gradient pattern until the headfold stage, then it is gradually observed along the rostro-caudal axis of the embryos as development procedes in the mesodermal cell layer and in neural crest cell derivatives. In addition, we show the existence of some previously undescribed subsets of scattered cells that express M-twist and thus might participate in murine embryo development.

X-twi is expressed prior to gastrulation in presumptive neurectodermal and mesodermal cells in dorsalized and ventralized Xenopus laevis embryos.

Early X-twi expression has been now investigated from egg laying to the early neurulation stages in Xenopus embryos, using both in situ hydridization and the more sensitive techniques of RT-PCR. We show that in unfertilized eggs, a decreasing gradient of X-twi transcript distribution is observed from animal to vegetative caps. X-twi RNA can be weakly detected at stages prior to gastrulation, and with increased intensity from stage 8 onwards. At blastula, X-twi transcripts are located towards the animal pole, and as gastrulation begins, they are detected in the developing axial mesoderm and then they accumulate in the sensorial layer of the neurectoderm, the mesodermal layer and in neural crest cells up to late neurula stages. We show, in addition, that in lithium-chloride- and UV-treated Xenopus embryos (that are respectively both "anteriorized/dorsalized" and in "posteriorized/ventralized"), X-twi RNA is detected in cells in similar positions to those that express X-twi in normal embryos. As a whole, our results show that X-twi is expressed even when regionalization of the mesoderm is disturbed and raises the question of a putative function of X-twi prior to gastrulation.

Expression of mRNAs encoding for alpha and beta integrin subunits, MMPs, and TIMPs in stretched human periodontal ligament and gingival fibroblasts.

The biological mechanisms of tooth movement result from the cellular responses of connective tissues to exogenous mechanical forces. Among these responses, the degradation of the extracellular matrix takes place, but the identification of the molecular basis as well as the components implicated in this degradation are poorly understood. To contribute to this identification, we subjected human fibroblasts obtained from the periodontal ligament (PDLs) and from the gingiva (HGFs) to a continuous stretch to quantify the mRNAs encoding for various metalloproteinases (MMPs), their tissue inhibitors (TIMPs), and alpha and beta integrin subunits. Both cell lines reacted by inducing the expression of the mRNAs encoding for MMP-1, MMP-2, TIMP-1, and TIMP-2, while other mRNAs did not vary (MT1-MMP, TIMP-3) or were not expressed (MMP-9). PDLs expressed selectively the mRNAs encoding for alpha4 and alphav, with no difference measurable under stretching, while the mRNAs encoding for alpha6 and beta1 were increased and the one encoding for alpha5 was decreased. HGFs increased the mRNAs encoding for alpha2, alpha6, beta1, and beta3 and decreased the one encoding for alpha3. Analysis of our data indicated that stretched HGFs and PDLs induced the same pattern of mRNAs encoding for MMPs and TIMPs but differed for those encoding various integrin subunits, known to act as protein receptors in mechanotransduction.

Expression of RNAs encoding for alpha and beta integrin subunits in periodontitis and in cyclosporin A gingival overgrowth.

BACKGROUND: Variation of integrin expression in healthy and diseased gingiva revealed a potential biological role for these cell matrix receptors during gingival remodeling. AIM: Here we determined the level of RNA and tissue localization of different integrin subunits in periodontitis and cyclosporin A-induced gingival overgrowth. METHODS: The level of expression was determined by Reverse Transcriptase Polymerase Chain Reaction in 12 periodontitis-affected patients, four patients exhibiting severe cyclosporin A-induced gingival overgrowth and seven healthy patients as controls. RESULTS: The RNA encoding for beta1, alpha2 and alpha5 integrin subunits were reduced in periodontitis gingiva. The reduction observed was stronger in cyclosporin A-treated patients as compared to the healthy controls, while RNA encoding for alpha1 subunit was increased. The RNA encoding for alpha6 integrin was only reduced in cyclosporin A-treated gingiva. Immunohistochemistry showed that i) integrin alpha2 expression is restricted to the gingival epithelium of cyclosporin A-treated patients, ii) the reduction of alpha6 integrin expression in cyclosporin A-treated gingiva is due to loss of expression at focal contacts and iii) beta1 integrin is evenly distributed in the three populations with an intensity decrease in periodontitis and cyclosporin A-treated gingiva. CONCLUSION: Taken together these results showed a role for the integrin receptors in periodontal diseases and cyclosporin A-induced gingival overgrowth.

Expression of matrix metalloproteinases in healthy and diseased human gingiva.

BACKGROUND, AIMS: The aim of our study was to investigate the patterns of several metalloproteinases (MMP-1, MMP-2 and MT1-MMP) mRNAs expression using a semi-quantitative reverse transcriptase-polymerase chain reaction (RT-PCR) and to correlate them with clinical parameters and bacteriological diagnosis in healthy versus diseased human gingiva. METHODS: To identify the cell origin of MMP production, in situ hybridization (ISH) was also performed for the MMPs on the same samples. 17 gingival biopsies were collected (13 affected by advanced periodontitis and 4 healthy used as controls) and plaque index, gingival index, pocket depth and bleeding on probing were measured. Subgingival microbial samples were also collected to be analysed by a DNA probe technique. The biopsies were processed both for RT-PCR and ISH. We also investigated a model for bacterial induced MMP expression in human gingival fibroblasts (HGF) infected by Eikenella corrodens. RESULTS: We found an expression of the mRNA encoding MMP-1 only in diseased gingiva but at low levels relative to beta-actin (mean+/-SD: diseased versus healthy: 0.013+/-0.024 versus 0). Although the frequencies and levels of mRNA encoding for MMP-2 or MT1-MMP are not significantly different between each group (mean+/-SD: 0.329+/-0.344 versus 0.137+/-0.219 for MMP-2; 0.485+/-0.374 versus 0.466+/-0.296 for MT1-MMP), using ISH, we observed an expression of both mRNAs in fibroblasts of pathological specimens at sites that histologically showed signs of chronic inflammation and connective tissue remodelling. In vitro infection of HGF by Eikenella corrodens stimulated 3-fold the production of the mRNA encoding MMP-2 while other mRNAs remained unchanged. CONCLUSION: Our results did not reveal significant differences in the expression of mRNAs encoding for the MMPs between healthy and periodontitis-affected patients, reflecting the great heterogeneity in the periodontal status of individuals. However, they indicate that gingival fibroblasts are an active source of MMP-2 production in response to a periopathogen.

The variable expressivity and incomplete penetrance of the twist-null heterozygous mouse phenotype resemble those of human Saethre-Chotzen syndrome.

Most targeted gene mutations are recessive and analyses of gene function often focus on homozygous mutant phenotypes. Here we describe parts of the expression pattern of M-twist in the head of developing wild-type mice and present our analysis of the phenotype of heterozygous twist- null animals at around birth and in adults. A number of twist -null heterozygous mice present skull and limb defects and, in addition, we observed other malformations, such as defects in middle ear formation and the xyphoïd process. Our study is of interest to understand bone formation and the role of M-twist during this process, as within the same animal growth of some bones can be accelerated while for others it can be delayed. Moreover, we show here that expressivity of the mouse mutant heterozygous phenotype is dependent on the genetic background. This information might also be helpful for clinicians, since molecular defects affecting one allele of the human H-twist ( TWIST ) gene were identified in patients affected with Saethre-Chotzen syndrome (SCS). Expressivity of this syndrome is variable, although most patients present craniofacial and limb malformations resembling those seen in mutant mice. Thus the mutant mouse twist -null strain might be a useful animal model for SCS. The twist -null mutant mouse model, combined with other mutant mouse strains, might also help in an understanding of the etiology of morphological abnormalities that appear in human patients affected by other syndromes.