Combining segmental bulk- and single-cell RNA-sequencing to define the chondrocyte gene expression signature in the murine knee joint.

OBJECTIVE: Due to the small size of the murine knee joint, extracting the chondrocyte transcriptome from articular cartilage (AC) is a major technical challenge. In this study, we demonstrate a new pragmatic approach of combining bulk RNA-sequencing (RNA-seq) and single cell (sc)RNA-seq to address this problem. DESIGN: We propose a new cutting strategy for the murine femur which produces three segments with a predictable mixed cell population, where one segment contains AC and growth plate (GP) chondrocytes, another GP chondrocytes, and the last segment only bone and bone marrow. We analysed the bulk RNA-seq of the different segments to find distinct genes between the segments. The segment containing AC chondrocytes was digested and analysed via scRNA-seq. RESULTS: Differential expression analysis using bulk RNA-seq identified 350 candidate chondrocyte gene in the AC segment. Gene set enrichment analysis of these genes revealed biological processes related- and non-related to chondrocytes, including, cartilage development (adj. P-value: 3.45E-17) and endochondral bone growth (adj. P-value 1.22E-4), respectively. ScRNA-seq of the AC segment found a cluster of 131 cells containing mainly chondrocytes. This cluster had 759 differentially expressed genes which enriched for extracellular matrix organisation (adj. P-value 7.76E-40) and other joint development processes. The intersection of the gene sets of bulk- and scRNA-seq contained 75 genes. CONCLUSIONS: Based on our results, we conclude that the combination of the two RNA-seq methods is necessary to precisely delineate the chondrocyte transcriptome and to study the disease phenotypes of chondrocytes in murine OA models in the future.

[CRISPR-Cas system as molecular scissors for gene therapy]. / CRISPR-Cas-System als molekulare Schere für Gentherapie.

Since the discovery of the CRISPR-Cas system as the adaptive immune system of prokaryotes, the underlying mechanism has proven to be a precise molecular tool for the targeted editing of genetic information in various cell types. By using the CRISPR-Cas9 system DNA sequences can be cut out at any site in the genome and changed in a sequence-specific manner. In the long term this provides the opportunity to cure diseases caused by gene mutations.

[Role of non-coding regulatory ribonucleic acids in chronic inflammatory diseases]. / Rolle nicht kodierender regulatorischer Ribonukleinsäuren bei chronisch entzündlichen Erkrankungen.

Non-coding regulatory ribonucleic acids (RNA), including microRNA, long non-coding RNA and circular RNA, can influence the expression of genes mediating inflammatory processes and therefore affect the course and progression of chronic inflammatory diseases. Recent studies using antisense oligonucleotides suggest that such non-coding regulatory RNAs are suitable as novel therapeutic target molecules for the treatment of inflammatory rheumatic diseases.