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Orthopaedic Proceedings
Vol. 94-B, Issue SUPP_XXVII | Pages 48 - 48
1 Jun 2012
Moreau A Yuan Q Akoume M Karam N Taheri M Bouhanik S Rompre P Bagnall K Labelle H Poitras B Rivard C Grimard G Parent S
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Introduction

From the many human studies that attempt to identify genes for adolescent idiopathic scoliosis (AIS), the view emerging is that AIS is a complex genetic disorder with many predisposing genes exhibiting complex phenotypes through environmental interactions. Although advancements in genomic technology are transforming how we undertake genetic and genomic studies, only some success has been reached in deciphering complex diseases such as AIS. Moreover, the present challenge in AIS research is to understand the causative and correlative effects of discovered genetic perturbations. An important limitation to such investigations has been the absence of a method that can easily stratify patients with AIS.

To overcome these challenges, we have developed a functional test that allows us to stratify patients with AIS into three functional subgroups, representing specific endophenotypes. Interestingly, in families with multiple cases of AIS, a specific endophenotype is shared among the affected family members, indicating that such a transmission is inherited. Moreover, increased vulnerability to AIS could be attributable to sustained exposure to osteopontin (OPN), a multifunctional cytokine that appears to be at the origin of the Gi-coupled receptor signalling dysfunction discovered in AIS. We examined the molecular expression profiles of patients with AIS and their response to OPN.

Methods

Osteoblasts isolated from patients with AIS were selected for each functional subgroup and compared with osteoblasts obtained from healthy matched controls. We used the latest gene chip human genome array Affymetrix (HuU133 Plus 2.0 array) that allows for the analysis of the expression level of 38 000 well characterised human genes. Raw data were normalised with robust multiarray analysis method. Statistical analysis was done by the EB method with FlexArray software. Selection criteria for in-depth analysis include the magnitude of change in expression (at least □} 3-fold) and 5% false discovery rate as stringency selection. Validation of selected candidate genes was done by qPCR and at the protein level by Western blot and ELISA methods. Plasma OPN concentrations were measured by ELISA on a group of 683 consecutive patients with AIS and were compared with 262 healthy controls and 178 asymptomatic offspring, born from at least one scoliotic parent, and thus considered at risk of developing the disorder. The regulation of OPN signalling pathway in normal and AIS cells were validated in vitro by cellular dielectric spectroscopy (CDS).


Orthopaedic Proceedings
Vol. 90-B, Issue SUPP_III | Pages 442 - 442
1 Aug 2008
Moreau A Azeddine B Labelle H Poitras B Rivard C Ouellet J Grimard G
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Introduction: Spinal deformities and scoliosis in particular, represent the most prevalent type of orthopaedic deformities in children and adolescents. At present, the most significant problem for clinicians is that there is no proven method or test available to identify children or adolescents at risk of developing AIS or to identify which of the affected individuals are at risk of progression. As a consequence, the application of current treatments, such as bracing or surgical correction, has to be delayed until a significant deformity is detected or until a significant progression is clearly demonstrated, resulting in a delayed and less optimal treatment. Among patients with AIS needing treatment, 80% to 90% will be treated by brace and 10% will need surgery to correct the deformity by spinal instrumentation and fusion of the thoracic and/or lumbar spine. About 15000 such surgeries are done every year in North America, resulting in significant psychological and physical morbidity. Moreover, there is no pharmacotherapy available to either prevent or reduce spinal deformities due mainly to our limited knowledge of AIS aetiopathogenesis. We have recently reconciled the role of melatonin in AIS aetiopathogenesis by demonstrating a melatonin signalling dysfunction occurring in a cell autonomous manner in cells derived from AIS patients exhibiting severe scoliotic deformities. This defect could potentially explain the majority of abnormalities reported in AIS since melatonin receptors and signalling activities are normally found in all tissues and systems affected in AIS, thus offering a very innovative and unifying concept to explain the aetiology of AIS. Moreover, several lines of evidence suggested that inactivation of Gi proteins by an increased phosphorylation of serine residues could be at the source of this signalling defect in AIS. The goals of that study were to assess the possibility to establish a molecular classification of AIS patients and to demonstrate the feasibility to correct this melatonin signalling defect in cells of AIS patients using therapeutic compounds.

Methods: Primary cell cultures were prepared from musculoskeletal tissues of AIS patients (n=150) and age- and gender-matched controls (n=35) obtained intra-operatively. An informed consent was obtained for each subject as approved by our Institutional Ethical Committee. The osteoblasts, the bone-forming cells, were selected to assess whether or not an alteration of melatonin signalling pathway occurs in AIS and accordingly to identify which component of the melatonin transduction machinery could be involved. Co-immunoprecipitation experiments with membrane extracts were performed to identify interacting molecules with key components of melatonin signal transduction machinery. The functionality of melatonin signalling was assessed by investigating the ability of Gi proteins to inhibit stimulated adenyl cyclase activity in osteoblast cultures. Inhibition curves of cAMP production were generated by adding melatonin to the forskolin-containing samples in concentrations ranging from 10-11M to 10-5M in a final volume of 1 ml of _-MEM media containing 0.2% bovine serum albumin (BSA) alone or in presence of 2.5 _M of therapeutic compound A or therapeutic compound B (the nature of both compounds tested cannot be disclosed at this stage). The cAMP content was determined using an enzyme immunoassay kit (Amersham-Pharmacia Biosciences). All assays were performed in duplicate. A non-parametric test, the Wilcoxon matched pairs test was performed to verify the significance between 2 means. Significance was defined as P< 0.05.

Results: Osteoblasts from patients with AIS showed a lack or a markedly reduced inhibition of forskolin-stimulated adenyl cyclase activity by melatonin generating three distinct response-curves corresponding to three functional groups. In order to identify candidate genes involved in AIS aetiopathogenesis, we focused our attention on known kinases and phosphatases modulating Gi protein functions and characterised their interacting partners. Interestingly, PKC_ was initially targeted owing to its property to phosphorylate Gi proteins in vitro. Indeed, in normal osteoblast interactions occurring between MT2 melatonin receptor and RACK1 (a cytosolic protein that bind to and stabilises the actives form of PKC and permits its translocation to different sites within the cells) and PKC_ were detected although those interactions among different AIS patients were altered. Interestingly, treatment with compound A or B rescued melatonin signal defect in cells derived from 36% and 47% of AIS patients respectively. Overall, melatonin signal transduction was restored in cells of 64% of AIS patients (23/36) when treated by one of these therapeutic compounds.

Conclusions: The functional classification of AIS patients is correlated at the molecular level by distinct interactions between key molecules normally involved in melatonin signal transduction in spite that these patients exhibited the same curve type (right thoracic, Lenke type 1). Collectively, these data strongly argue that traditional curve pattern classification is not a relevant stratification of AIS patients to identify its genetic causes. Moreover, using that molecular system we have demonstrated also the possibility to identify therapeutic compounds to rescue the melatonin signalling defect observed in AIS without any prior knowledge of mutations in any defective genes causing AIS because we are measuring a function.

Research project supported by La Fondation Yves Cotrel de l’Institut de France


Orthopaedic Proceedings
Vol. 90-B, Issue SUPP_I | Pages 149 - 150
1 Mar 2008
Grimard G Ouellet J Lévesque L Labelle H Poitras B Moreau A Moldovan F Azzedine B Wang D Turgeon I Leclerc S Letellier K Rivard C
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Purpose: Recently, we highlighted a dysfunction in the melatonin signalling pathway in the osteoblasts from adolescent idiopathic scoliosis patients (AIS). The objective of this project is to verify if in the cells coming from the SIA patients, estrogens interfere with melatonin signalling pathways and to identify mechanisms through which these effects are carried out.

Methods: The effects of estrogens on the melatonin signalling pathway, in osteoblasts from AIS patients (n=7), were determined by measuring the capacity of the Gi proteins to inhibit the accumulation of cAMP. The osteoblasts were incubated in the presence of increasing amounts of melatonin (10–11 to 10–5 M) with or without 17-& #946;-estradiol in physiological concentrations (10–10 M) (n=7). Moreover, coimmunoprecipitations using anti-phosphoserine antibodies were carried out and then followed with a Western blot in order to detect melatonin receptors (MT1 and MT2).

Results: The intracellular level of cAMP is higher in the presence of a physiological concentration of 17-& #946;-estradiol among scoliotic patients compared to the level observed in the presence of melatonin alone. Moreover, the preliminary results of the coimmunoprecipitations seem to show an increase in the phosphorylation of proteins interacting with MT1 and MT2 receptors. The precise nature of these proteins remains to be identified.

Conclusions: These results seem to show the antagonistic effects of the 17-& #946;-estradiol on the melatonin signalling pathway in the osteoblasts from AIS patients. However, more cAMP dosages in the presence and absence of 17-& #946;-estradiol are underway so as to increase the number of patients. The results of this study could contribute to the development of the first molecular screening tests as well as the development of new therapeutic approaches.


Orthopaedic Proceedings
Vol. 85-B, Issue SUPP_III | Pages 191 - 191
1 Mar 2003
Rivard C Coillard C Leroux M Badeaux J
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Introduction: Until now, the non-surgical therapeutic approach for idiopathic scoliosis (IS) was based on rigid brace using three points pressure and distraction technique. For the first time we wanted to use a dynamic approach for the treatment of IS. For this goal we have developed a Dynamic Correction Brace (DCB) or SpineCor to use the forces of the dynamic spine to optimise the reduction of spinal curves and permit neuromuscular integration during the period of correction.

Methods and results: The effectiveness of the treatment depends on the reducibility of the curve with the brace. The goal of this study is to quantify the reducibility of scoliosis curves through a study of the variation of Cobb angle, during and after treatment.

Between 1993 and 1999, 113 adolescents with classic indications of idiopathic scoliosis were treated by the same orthopaedist with the DCB. The mean age at the beginning of the treatment is 12.9 years old. The potential reducibility (PR) of the curves was estimated by the percentage of reduction of the initial Cobb’s angle corresponding to the maximum correction obtained during the course of treatment and after the treatment for the patient at maturity. Fifty patients have completed their treatment and are at maturity.

From this cohort of patients treated by the DCB, 73.4% had a reduction of 5° or more than their principal Cobb angle; 22.8% were stable, but non-reducible, with a change of less than 5°; and 3.8% conserved an evolutive potential, with an increase in the Cobb angle of 5° or more. A significant difference was evident for PR between the group presenting an initial Cobb angle < 30° and those presenting an initial Cobb angle > 30° (p< 0.05). 65.8 per cent of the patients presented with an initial Cobb angle < 30° for a mean PR of 40.6% and were categorised according to the following: a) 26% of the patients had a PR ≤20%; b) 41% obtained a PR between 20% and 50%; and c) 33% had a PR > 50%. The other patients (34.2%) with an initial Cobb > 30° and a mean PR 22% were also categorised: 39% had a PR ≤20%; b) 48% had a PR between 20% and 50% and c) 13% > 50%. For patients who have completed their treatment 85% have a correction or are stabilised, 15% are worse or needed surgery during the treatment. For these patients, 53% have a correction of < 20%, 31% have a correction between 20 and 50%, and 16% have a correction of > 50%.

Conclusion: The reducibility of the curve during the treatment is very informative concerning the prognosis treatment. The effectiveness of a DCB is comparable to effectiveness of other rigid braces for which the results have been published.