Chitayat syndrome: hyperphalangism, characteristic facies, hallux valgus and bronchomalacia results from a recurrent c.266A>G p.(Tyr89Cys) variant in the ERF gene.

BACKGROUND: In 1993, Chitayat et al., reported a newborn with hyperphalangism, facial anomalies, and bronchomalacia. We identified three additional families with similar findings. Features include bilateral accessory phalanx resulting in shortened index fingers; hallux valgus; distinctive face; respiratory compromise. OBJECTIVES: To identify the genetic aetiology of Chitayat syndrome and identify a unifying cause for this specific form of hyperphalangism. METHODS: Through ongoing collaboration, we had collected patients with strikingly-similar phenotype. Trio-based exome sequencing was first performed in Patient 2 through Deciphering Developmental Disorders study. Proband-only exome sequencing had previously been independently performed in Patient 4. Following identification of a candidate gene variant in Patient 2, the same variant was subsequently confirmed from exome data in Patient 4. Sanger sequencing was used to validate this variant in Patients 1, 3; confirm paternal inheritance in Patient 5. RESULTS: A recurrent, novel variant NM_006494.2:c.266A>G p.(Tyr89Cys) in ERF was identified in five affected individuals: de novo (patient 1, 2 and 3) and inherited from an affected father (patient 4 and 5). p.Tyr89Cys is an aromatic polar neutral to polar neutral amino acid substitution, at a highly conserved position and lies within the functionally important ETS-domain of the protein. The recurrent ERF c.266A>C p.(Tyr89Cys) variant causes Chitayat syndrome. DISCUSSION: ERF variants have previously been associated with complex craniosynostosis. In contrast, none of the patients with the c.266A>G p.(Tyr89Cys) variant have craniosynostosis. CONCLUSIONS: We report the molecular aetiology of Chitayat syndrome and discuss potential mechanisms for this distinctive phenotype associated with the p.Tyr89Cys substitution in ERF

Imaging calpain protease activity by multiphoton FRET in living mice

International audienceConstant efforts are ongoing for the development of new imaging methods that allow the investigation of molecular processes in vivo. Protein-protein interactions, enzymatic activities and intracellular Ca2+ fluxes, have been resolved in cultured cells using a variety of fluorescence resonance energy transfer (FRET) detection methods. However, FRET has not been used so far in conjunction with 3D intravital imaging. We evaluated here a combination of multiphoton microscopy (MPM), method of choice for non-destructive living tissue investigation, and FRET imaging to monitor calpain proteolytic activity in living mice muscle. We show that kinetics of ubiquitous calpains activation can be efficiently and quantitatively monitored in living mouse tissues at cellular level with a FRET-based indicator upon calcium influx. The ability to visualize calpain activity in living tissue offers a unique opportunity to challenge remaining questions on the biological functions of calpains and to evaluate the therapeutic potential of calpain inhibitors in many degenerative conditions. (C) 2004 Elsevier Ltd. All rights reserved

Investigation on TSV impact on 65nm CMOS devices and circuits

International audienc

Investigation on TSV impact on 65nm CMOS devices and circuits

International audienc

« Investigation on TSV impact on 65nm CMOS devices and circuits »

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