Titin expression in human articular cartilage and cultured chondrocytes: A novel component in articular cartilage biomechanical sensing?

(Antibody Recognition and RT-PCR applications...)

The objective of this experiment was to test for the presence of titin on human articular cartilage tissue (e.g. joints). This large protein has previously been detected on heart and skeletal muscle tissue, where a biomechanical strain-bearing role has been attributed to it. "...Titin accounts for most of the passive elastic response retention that prevents over stretching... acts as an adjustable spring element..." Being this the case, it might be reasonable to look for the expression of this protein on other stress/strain-bearing tissues where elasticity is also required (e.g. joints).
Cartilage samples were taken from three groups of donors: Adults with osteoarthritis (OA), adults without OA, and infants (disgusting sampling). Immunolabelling was done with specific antibodies for "four" different domains of Titin; the N-terminal Z1-Z2 domain, the Novex III exon, the PEVK region, and N2A region (Fig.1). [I have to point out that even when only "three"antibodies were mentioned in the abstract, the paper showed results for "four" antibodies. Even section 2.3 (immunohystochemistry) doesn't make it clear (maybe it is me... I'm open to suggestions)].
However, it seems interesting to see positive results for titin presence in cartilage tissue (previously detected on muscle only). More than just existing on cartilage tissue, titin differences between Osteoarthritis and normal tissues were not detectable (Fig. 2,3). This suggests a crucial structural role of titin in cartilage.
Another result that called my attention was the detection of titin in extracellular matrix (ECM), when it was claimed to be intracellular (Fig. 2-4). This has two possible explanations:1) "a cross-reaction with other member of the Ig-domain gene superfamily, to which titin belongs" (detection of something else that has a domain in common with titin), and 2) titin has both intra- and extracellular strain-bearing functions.
Third interesting outcome: Some of the infant samples showed negative results for N2A region of titin (table 1, fourth column). This was associated to possible expression of a different titin isoform during maturation of the cartilage. This changes can be related to skeletal growth or mechanical load needs. This is a good point in favor of the specificity of antibody recognition (optimum trial and error, huh?). There were also discrepancies on the OA patients results (table 1, columns 2 & 3). This was similar to findings of aberrant forms of titin on patients with OA or Charcot Marie Tooth disease (Banes et. al. 2004). This is open to argument, though. Banes' aberrations where on the N2A region while aberrations here might be on Z1-Z2 (X112 113 X) and PEVK (9D10 ) regions.
Presence of titin was also shown by RT-PCR done from cells cultured from the samples. However, some domain fragments could not be amplified (see table2, Fig. 5). Again, might be related to the titin isoforms during cartilage maturation. Howeer, PEVK region was detected in all tissues by antibody recognition but not by RT-PCR. This case remains not clear. Further research will be required to clarify this.













Secondary Reference Sites:
1- http://www.ks.uiuc.edu/~ericlee/Telethonin/
2- http://www.psc.edu/science/2000/schulten/rude_mechanicals.html