Deciphering the Role of Filamin B Calponin-Homology Domain in Causing the Larsen Syndrome, Boomerang Dysplasia, and Atelosteogenesis Type I Spectrum Disorders via a Computational Approach.

Hatem Zayed,Balu Kamaraj,Muneera Naseer Ahmad,Salma Younes,George Priya Doss C.,Srivarshini Sankar,Sarah Samer Okashah,Abeer Mohammed Al-Subaie,Thirumal Kumar D.,Udhaya Kumar S.

doi:10.3390/molecules25235543

Abstract

Filamins (FLN) are a family of actin-binding proteins involved in regulating the cytoskeleton and signaling phenomenon by developing a network with F-actin and FLN-binding partners. The FLN family comprises three conserved isoforms in mammals: FLNA, FLNB, and FLNC. FLNB is a multidomain monomer protein with domains containing an actin-binding N-terminal domain (ABD 1–242), encompassing two calponin-homology domains (assigned CH1 and CH2). Primary variants in FLNB mostly occur in the domain (CH2) and surrounding the hinge-1 region. The four autosomal dominant disorders that are associated with FLNB variants are Larsen syndrome, atelosteogenesis type I (AOI), atelosteogenesis type III (AOIII), and boomerang dysplasia (BD). Despite the intense clustering of FLNB variants contributing to the LS-AO-BD disorders, the genotype-phenotype correlation is still enigmatic. In silico prediction tools and molecular dynamics simulation (MDS) approaches have offered the potential for variant classification and pathogenicity predictions. We retrieved 285 FLNB missense variants from the UniProt, ClinVar, and HGMD databases in the current study. Of these, five and 39 variants were located in the CH1 and CH2 domains, respectively. These variants were subjected to various pathogenicity and stability prediction tools, evolutionary and conservation analyses, and biophysical and physicochemical properties analyses. Molecular dynamics simulation (MDS) was performed on the three candidate variants in the CH2 domain (W148R, F161C, and L171R) that were predicted to be the most pathogenic. The MDS analysis results showed that these three variants are highly compact compared to the native protein, suggesting that they could affect the protein on the structural and functional levels. The computational approach demonstrates the differences between the FLNB mutants and the wild type in a structural and functional context. Our findings expand our knowledge on the genotype-phenotype correlation in FLNB-related LS-AO-BD disorders on the molecular level, which may pave the way for optimizing drug therapy by integrating precision medicine.

Highlights

Human Filamins constitute a group of large actin-binding proteins comprised of 24 immunoglobulin-like repeats and actin-binding domain (ABD), forming a dynamic structure via crosslinking cytoskeleton filaments
Evolutionary conservation analysis was carried out for all the 79 variants; six variants
F161C, L171Q, L171R, W165C, and G168C) that are present in the calponin-homology 2 (CH2) domain were shown to be functionally essential and showed a highly conserved score of 9 (Figure 1)

Summary

Introduction

Human Filamins constitute a group of large actin-binding proteins comprised of 24 immunoglobulin-like repeats and actin-binding domain (ABD), forming a dynamic structure via crosslinking cytoskeleton filaments. Filaments cooperate with various signaling proteins in the cytosol and transmembrane receptors through which they connect the cell membrane to the cytoskeleton mechanically and functionally [1]. The filamin family encompasses three main homologous proteins: filamin A (FLNA), filamin B (FLNB), and filamin C (FLNC). The first discovered member of the family, FLNA, was considered the most abundant and widely distributed member of this lineage [3,4]. Polymorphisms in the FLN genes result in abnormal expression of filamin proteins, causing a broad range of congenital abnormalities

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