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Spine

PRIMARY CILIUM: A SIGNALLING ORGANELLE INVOLVED IN HUMAN DISC DEGENERATION?

The Society for Back Pain Research (SBPR), Northampton, England, November 2017



Abstract

Introduction

Primary cilia are singular structures containing a microtubule-based axoneme which are believed to not only be mechanosensitive but also to co-ordinate many cell functions via signalling pathways including Hedgehog and Wnt. Primary cilia have previously been described on cells of mouse intervertebral discs (IVDs), but not in bovine or human IVDs. Our aim was to examine primary cilia in these species.

Methods

Nucleus pulposus cells were obtained from cows with no overt disc degeneration and patients following spine surgery (for herniations and/or degenerative disc disease) and cultured until confluent before maintaining with or without serum for 24h. Primary cilia were visualised with antibodies to the axoneme (acetylated α-tubulin and Arl13b) and/or the basal body (pericentrin) using fluorescent secondary antibodies and ≥200 cells per sample were counted.

Results

Primary cilia were detected in the majority of disc cells (81.2±4.1% and 54.8±28.7% with and without serum depletion, respectively, in bovine and 78.9±0.3% and 89.8±7.4% in human cells). Some cilia demonstrated abnormalities, such as bulbous tips or breaks in the axonome.

Conclusion

This is the first report of primary cilia being present on human and bovine IVD cells. There remain many other aspects to be investigated, for example, their length has been shown to alter in osteoarthritic chondrocytes. If this, or the incidence of abnormalities, differs in cells from normal and abnormal discs, it could suggest new pathways of disc degeneration, as these organelles are key to so many cell functions.

Conflicts of interest: None

Supported by the Orthopaedic Institute Ltd


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