Insulin-like growth factor binding protein (IGFBP6) is a cross-species tendon marker.

The main challenge in tendon injury management is suboptimal tissue healing that fails to re-establish original tendon function. Tissue bioengineering is a promising approach for tendon therapy, with potential to improve its functional outcomes. However, evaluation criteria for tissue-engineered tendon are unclear due to the lack of specific markers of differentiated tendon. The study aim was to identify a panel of genes that characterised tendons in comparison to cartilage or muscles and validate those genes, both in human and key species used as models for tendon diseases. Gene expression profiling of rat tendon and cartilage in whole-tissue samples and primary tenocytes and chondrocytes was undertaken using two independent microarray platforms. Genes that demonstrated high expression correlation across two assays were validated by qRT-PCR in rat tendon relative to cartilage and muscle. Five genes demonstrating the highest tendon-related expression in the validation experiment (ASPN, ECM1, IGFBP6, TNMD, THBS4) were further evaluated by qRT-PCR in ovine, equine and human tissue. The group of tendon markers, identified by unbiased transcriptomic analysis of rat musculoskeletal tissues, demonstrated species-dependent profiles of expression. Insulin-like growth factor binding protein 6 (IGFBP6) was identified as the only universal tendon marker. Further investigation in equine tendon showed that IGFBP6 expression was not affected by ageing or tendon function but decreased in anatomical regions subjected to elevated compressive force. IGFBP6 is a robust cross-species marker of tendon phenotype and may find application in evaluation of tendon physiology and guided differentiation of permissive cells towards functional tenocytes.

Distribution of purinergic P2X receptors in the equine digit, cervical spinal cord and dorsal root ganglia.

Purinergic pathways are considered important in pain transmission, and P2X receptors are a key part of this system which has received little attention in the horse. The aim of this study was to identify and characterise the distribution of P2X receptor subtypes in the equine digit and associated vasculature and nervous tissue, including peripheral nerves, dorsal root ganglia and cervical spinal cord, using PCR, Western blot analysis and immunohistochemistry. mRNA signal for most of the tested P2X receptor subunits (P2X1-5, 7) was detected in all sampled equine tissues, whereas P2X6 receptor subunit was predominantly expressed in the dorsal root ganglia and spinal cord. Western blot analysis validated the specificity of P2X1-3, 7 antibodies, and these were used in immunohistochemistry studies. P2X1-3, 7 receptor subunits were found in smooth muscle cells in the palmar digital artery and vein with the exception of the P2X3 subunit that was present only in the vein. However, endothelial cells in the palmar digital artery and vein were positive only for P2X2 and P2X3 receptor subunits. Neurons and nerve fibres in the peripheral and central nervous system were positive for P2X1-3 receptor subunits, whereas glial cells were positive for P2X7 and P2X1 and 2 receptor subunits. This previously unreported distribution of P2X subtypes may suggest important tissue specific roles in physiological and pathological processes.