Aims. Degenerative cervical spondylosis (DCS) is a common musculoskeletal disease that encompasses a wide range of progressive degenerative changes and affects all components of the cervical spine. DCS imposes very large social and economic burdens. However, its genetic basis remains elusive. Methods. Predicted whole-blood and skeletal muscle gene expression and genome-wide association study (GWAS) data from a DCS database were integrated, and functional summary-based imputation (FUSION) software was used on the integrated data. A transcriptome-wide association study (TWAS) was conducted using FUSION software to assess the association between predicted gene expression and DCS risk. The TWAS-identified genes were verified via comparison with differentially expressed genes (DEGs) in DCS RNA expression profiles in the Gene Expression Omnibus (GEO) (Accession Number: GSE153761). The Functional Mapping and Annotation (FUMA) tool for genome-wide association studies and Meta tools were used for gene functional enrichment and annotation analysis. Results. The TWAS detected 420 DCS genes with p < 0.05 in skeletal muscle, such as ribosomal protein S15A (RPS15A) (PTWAS = 0.001), and 110 genes in whole blood, such as selectin L (SELL) (PTWAS = 0.001). Comparison with the DCS RNA expression profile identified 12 common genes, including Apelin Receptor (APLNR) (PTWAS = 0.001, PDEG = 0.025). In total, 148 DCS-enriched Gene Ontology (GO) terms were identified, such as mast cell degranulation (GO:0043303); 15 DCS-enriched Kyoto Encyclopedia of Genes and Genomes (KEGG) pathways were identified, such as the sphingolipid signalling pathway (ko04071). Nine terms, such as degradation of the extracellular matrix (R-HSA-1474228), were common to the TWAS enrichment results and the RNA expression profile. Conclusion. Our results identify putative susceptibility genes; these findings provide new ideas for exploration of the genetic mechanism of DCS development and new targets for preclinical intervention and clinical treatment. Cite this article: Bone Joint Res 2023;12(1):80–90

Aims

Lumbar spinal stenosis (LSS) is a common skeletal system disease that has been partly attributed to genetic variation. However, the correlation between genetic variation and pathological changes in LSS is insufficient, and it is difficult to provide a reference for the early diagnosis and treatment of the disease.

Introduction. Adolescent idiopathic scoliosis (AIS) is the most common form of spinal deformity. It occurs mainly in girls and progresses during pre-pubertal and pubertal growth, which is a crucial period for bone mass acquisition. The cause and molecular mechanisms of AIS are not clear; at present the consensus is that AIS has a multifactor cause, with many genetic factors. During the past 5 years, considerable effort has been devoted to identify a gene or genes that cause a predisposition to AIS. Many loci for this disorder have been mapped to different chromosome regions, but no genes have been clearly identified as being responsible for AIS, and, most importantly, the resulting protein defects remain to be shown. We aimed to identify the gene(s) that could be involved in AIS and to validate their involvement by both genetic and functional analyses. Methods. A large multiplex AIS French family was chosen for this study on the basis of clinical and radiological data. Whole genome genotyping of the 20 members of this family led to the mapping of a dominant disease-causing gene to two critical genomic intervals (Edery and colleagues, Eur J Hum Genet, accepted [2011]), but the causative mutation remains to be identified. In parallel, gene expression profiling was investigated by microarray analysis in RNA samples isolated from osteoblasts derived from healthy individuals and those with AIS. RNA samples were extracted from osteoblasts, purified, fluorescently labelled, and then hybridised to gene expression microarrays with the Illumina expression BeadChips technology containing more than 46 000 probes for the human genome (HumanHT-12). Data analysis in R version 2.10.1 (Bioconductor packages oligo and limma) was done, and genes that had at least 1·5-fold change in expression were considered differentially regulated relative to controls. AIS candidate genes within the critical intervals were selected on the basis of their mRNA expression in AIS individuals and by their known functions. The coding regions of these candidate genes were then sequenced to identify potential mutations. The biological activity of mutant proteins is under evaluation by in-vivo functional studies in zebrafish. Results. In the AIS family, a maximum LOD score of 3·01 was reached on two specific chromosomal regions. The interval lengths of these regions were 7cM and 12cM. These two regions contain several genes that might be responsible for AIS. Microarray analysis showed many genes that are differentially regulated in AIS osteoblasts compared with control osteoblasts. We recorded that 2·6% of the 24000 genes examined were upregulated in AIS osteoblasts, whereas 2·16% of them were downregulated. We observed a roughly 3-fold increase or decrease in the transcripts of many genes in AIS osteoblasts. Some of the differentially regulated genes are located within the two chromosomal candidate regions. The sequencing of the candidate genes' coding sequences was done on the family members. Sequence analysis showed two rare SNPs located on the coding regions of a gene that we called CH5G1. These two SNPs are located on the C-terminal region of the CH5G1 protein and affect its structure and probably its cellular activity and biological process leading to the disease. The C-terminal region of this protein interacts with the mRNA of a gene whose defects cause scoliosis as a secondary phenotype. The pathogenic nature of these SNPs is being investigated in the zebrafish model. The results suggest that CH5G1 gene's defects could be associated with AIS in this family. Conclusions. Identification of susceptibility genes for AIS will facilitate the understanding of underlying biochemical pathways (functional studies) and ultimately the development of specific therapies (pharmacological studies). This is likely to have important implications, since the cause of AIS is unknown. Acknowledgments. This study is supported by the Fondation Yves Cotrel, Institut de France

Aims

Inflammatory response plays a pivotal role in the pathophysiological process of intervertebral disc degeneration (IDD). A20 (also known as tumour necrosis factor alpha-induced protein 3 (TNFAIP3)) is a ubiquitin-editing enzyme that restricts nuclear factor-kappa B (NF-κB) signalling. A20 prevents the occurrence of multiple inflammatory diseases. However, the role of A20 in the initiation of IDD has not been elucidated. The aim of the study was to investigate the effect of A20 in senescence of TNF alpha (TNF-α)-induced nucleus pulposus cells (NPCs).