Abstract
Intervertebral discs (IVDs) are fibrocartilagenous ovoids located between the vertebral bodies of the spine that provide the sole source of flexibility in that structure. IVDs are clinically very important as degeneration has been shown to be strongly associated with lower back pain, sciatica, and disc herniation: potentially disabling conditions that affect a very large section of the UK population.
The aetiology of disc degeneration is poorly understood although upregulation of matrix metalloproteinase (MMP) activity is thought to be involved. Degradation products of the extra-cellular matrix are known to increase MMP production and activity in other tissues. This project concentrated on examining the effects of degredation products of elastin. Elastin fragments (κ-elastin peptides) have been shown to upregulate mRNA levels and increase expression of pro-MMP-1 in human skin fibroblasts, cells that are thought to be similar to those residing in the annulus fibrosus of intervertebral discs. This study examined their effect on disc cells and on skin fibroblasts.
Total MMP-2 and -7 activity produced by cells extracted from the annulus fibrosus of bovine intervertebral disc cells and cultured for 24 hours with 0–300μg/ml κ-elastin was determined using fluorimetric and zymographic analyses. κ-elastin was prepared from bovine ligamentum nuchae or bovine intervertebral discs.
Culture with κ-elastin prepared from bovine ligamentum nuchae caused skin and disc cell potential pro-MMP-2 activity to increase in a dose-dependent manner; the potential pro-MMP-2 activity of both cell types is more than doubled when cultured with 300μg/ml κ-elastin.
These findings suggest that in the bovine disc, matrix breakdown may cause a feedback loop with degraded elastin stimulating disc cells to increase production of pro-MMP-2, with the possibility of further degrading elastin and other proteins and contributing to IVD breakdown.
Correspondence should be addressed to Major M Butler RAMC, 44 Theynes Croft, Long Ashton, Bristol, BS41 9NA, England.