Mechanical forces influence chondrocyte metabolism and are critically important for maintenance of normal cartilage structure and integrity. In cells of the musculoskeletal system and mechanoresponsive cells in other tissues, integrins seem to be involved in the mechanotransduction process. Integrin activity is important in the early cellular responses to mechanical stimulation, regulating activation of a number of intracellularcascades that induce changes in gene expression and tissue remodeling. In normal human articular chondrocytes, integrin activation, consequent to mechanical stimulation in vitro, results in tyrosine phosphorylation of regulatory proteins and subsequent secretion of autocrine and paracrine acting soluble mediators including substance P and interleukin 4. Significant differences in signaling events and cellular responses are seen when normal and osteoarthritic chondrocytes are mechanically stimulated. These differences may relate to differences in integrin expression and function. Improved comprehension of how integrins mediate chondrocyte responses to mechanical stimulation, and how cross talk between integrin signaling, extracellular matrix, and autocrine/paracrine signaling molecules regulate mechanotransduction and cellular reactions are necessary for further understanding of how load influences cartilage structure.
Introduction The aim of this study was to compare the effects of tumour necrosis factor-alpha (TNF-α) and interleukin-1-beta (IL-1β) on protease and catabolic cytokine and receptor gene expression in normal and degenerate human nucleus pulposus cells in alginate culture.
Mechanical stimulation of human articular chondrocytes in vitro results in increased levels of aggrecan mRNA and decreased levels of MMP-3 mRNA. The transduction process involves integrins, stretch-activated ion channels, and IL-4. This chondroprotective response is absent in chondrocytes from OA cartilage. Abnormalities of mechanotransduction leading to aberrant chondrocyte activity in diseased articular cartilage may be important in the progression of OA.
Chondrocyte function is regulated partly by mechanical stimulation. Optimal mechanical stimulation maintains articular cartilage integrity, whereas abnormal mechanical stimulation results in development and progression of osteoarthritis (OA). The responses of signal transduction pathways in human articular chondrocytes (HAC) to mechanical stimuli remain unclear. Previous work has shown the involvement of integrins and integrin-associated signaling pathways in activation of plasma membrane apamin-sensitive Ca2+-activated K+ channels that results in membrane hyperpolarization of HAC after 0.33 Hz cyclical mechanical stimulation. To further investigate mechanotransduction pathways in HAC and show that the hyperpolarization response to mechanical stimulation is a result of an integrin-dependent release of a transferable secreted factor, we used this response. Neutralizing antibodies to interleukin 4 (IL-4) and IL-4 receptor α inhibit mechanically induced membrane hyperpolarization and anti–IL-4 antibodies neutralize the hyperpolarizing activity of medium from mechanically stimulated cells. Antibodies to interleukin 1β (IL-1β) and cytokine receptors, interleukin 1 receptor type I and the common γ chain/CD132 (γ) have no effect on me- chanically induced membrane hyperpolarization. Chondrocytes from IL-4 knockout mice fail to show a membrane hyperpolarization response to cyclical mechanical stimulation. Mechanically induced release of the chondroprotective cytokine IL-4 from HAC with subsequent autocrine/paracrine activity is likely to be an important regulatory pathway in the maintenance of articular cartilage structure and function. Finally, dysfunction of this pathway may be implicated in OA.
Cellulases expressed by Cellulomonas fimi consist of a catalytic domain and a discrete non-catalytic cellulose-binding domain (CBD). To establish whether CBDs are common features of plant cell-wall hydrolases from C. fimi, the molecular architecture of xylanase D (XYLD) from this bacterium was investigated. The gene encoding XYLD, designated xynD, consisted of an open reading frame of 1936 bp encoding a protein of M(r) 68,000. The deduced primary sequence of XYLD was confirmed by the size (64 kDa) and N-terminal sequence of the purified recombinant xylanase. Biochemical analysis of the purified enzyme revealed that XYLD is an endoacting xylanase which displays no detectable activity against polysaccharides other than xylan. The predicted primary structure of XYLD comprised an N-terminal signal peptide followed by a 190-residue domain that exhibited significant homology to Family-G xylanases. Truncated derivatives of xynD, encoding the N-terminal 193 amino acids of mature XYLD directed the synthesis of a functional xylanase, confirming that the 190-residue N-terminal sequence constitutes the catalytic domain. The remainder of the enzyme consisted of two approximately 90-residue domains, which exhibited extensive homology with each other, and limited sequence identity with CBDs from other polysaccharide hydrolases. Between the two putative CBDs is a 197-amino-acid sequence that exhibits substantial homology with Rhizobium NodB proteins. The four discrete domains in XYLD were separated by either threonine/proline-or novel glycine-rich linker regions. Although full-length XYLD adsorbed to cellulose, truncated derivatives of the enzyme lacking the C-terminal CBD hydrolysed xylan but did not bind to cellulose.(ABSTRACT TRUNCATED AT 250 WORDS)
Under our experimental conditions, only AC generated tissues containing relevant amounts of GAG and with cell phenotypes compatible with those of the inner and outer meniscus regions. Instead, the other investigated cell sources formed tissues resembling only the outer region of meniscus. It remains to be determined whether grafts based on AC will have the ability to reach the complex structural and functional organization typical of meniscus tissue.
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