Mechanotransduction Pathways (mechanotransduction + pathway)

Distribution by Scientific Domains


Selected Abstracts


Profiling microRNA expression in bovine articular cartilage and implications for mechanotransduction

ARTHRITIS & RHEUMATISM, Issue 8 2009
Walter Dunn
Objective Articular cartilage is an avascular tissue with precise polarity and organization comprising 3 distinct functional zones: the surface, middle, and deep zones. Each zone has a different gene expression pattern that plays a specific role in articular cartilage development and maintenance. MicroRNA (miRNA) are small noncoding gene products that play an important regulatory role in determining cell differentiation and function. The purpose of this study was to test our hypothesis that miRNA expression profiles in the different articular cartilage zones as well as between regions subjected to different levels of weight-bearing stresses are unique. Methods Using an miRNA microarray approach in conjunction with quantitative reverse transcription,polymerase chain reaction, we identified miRNA in bovine articular cartilage that were differentially expressed in the different functional zones and in the anterior weight-bearing and posterior non,weight-bearing regions of the medial femoral condyle (M1 and M4, respectively). Results We identified miRNA-221 and miR-222 as part of a subset of differentially expressed miRNA that were up-regulated in articular cartilage in the anterior, M1, greater weight-bearing location. Additionally, miR-126, miR-145, and miR-335 were down-regulated in monolayers of tissue-cultured chondrocytes as compared with levels determined directly from intact native cartilage. Conclusion In conclusion, miR-222 expression patterns in articular cartilage are higher in the weight-bearing anterior medial condyle as compared with the posterior non,weight-bearing medial condyle. Thus, miR-222 might be a potential regulator of an articular cartilage mechanotransduction pathway. These data implicate miRNA in the maintenance of articular cartilage homeostasis and are therefore targets for articular cartilage tissue engineering and regenerative medicine. [source]


The role of the calmodulin-dependent pathway in static magnetic field-induced mechanotransduction,

BIOELECTROMAGNETICS, Issue 4 2010
Jen-Chang Yang
Abstract While the effects of static magnetic fields (SMFs) on osteoblastic differentiation are well demonstrated, the mechanotransduction pathways of SMFs are still unclear. The aim of this study was to explore the role of calmodulin in the biophysical effects of SMFs on osteoblastic cells. MG63 cells were exposed to a 0.4,T SMF. The expression of phosphodiesterase RNA in the cytoplasm was tested using real-time polymerase chain reaction. The differentiation of the cells was assessed by detecting changes in alkaline phosphatase activity. The role of calmodulin antagonist W-7 was used to evaluate alterations in osteoblastic proliferation and differentiation after the SMF simulations. Our results showed that SMF exposure increased alkaline phosphatase activity and phosphodiesterase 1C gene expression in MG63 cells. Addition of W-7 significantly inhibited the SMF-induced cellular response. We suggest that one possible mechanism by which SMFs affects osteoblastic maturation is through a calmodulin-dependent mechanotransduction pathway. Bioelectromagnetics 31:255,261, 2010. © 2009 Wiley-Liss, Inc. [source]


The Effects of Hemodynamic Force on Embryonic Development

MICROCIRCULATION, Issue 3 2010
JAMES C. CULVER
Microcirculation (2010) 17, 164,178. doi: 10.1111/j.1549-8719.2010.00025.x Abstract Blood vessels have long been known to respond to hemodynamic force, and several mechanotransduction pathways have been identified. However, only recently have we begun to understand the effects of hemodynamic force on embryonic development. In this review, we will discuss specific examples illustrating the role of hemodynamic force during the development of the embryo, with particular focus on the development of the vascular system and the morphogenesis of the heart. We will also discuss the important functions served by mechanotransduction and hemodynamic force during placentation, as well as in regulating the maintenance and division of embryonic, hematopoietic, neural, and mesenchymal stem cells. Pathological misregulation of mechanosensitive pathways during pregnancy and embryonic development may contribute to the occurrence of cardiovascular birth defects, as well as to a variety of other diseases, including preeclampsia. Thus, there is a need for future studies focusing on better understanding the physiological effects of hemodynamic force during embryonic development and their role in the pathogenesis of disease. [source]


Altered integrin mechanotransduction in human nucleus pulposus cells derived from degenerated discs

ARTHRITIS & RHEUMATISM, Issue 2 2009
Christine Lyn Le Maitre
Objective Several studies have demonstrated biologic responses of intervertebral disc (IVD) cells to loading, although the mechanotransduction pathways have not been elucidated. In articular chondrocytes, which have a phenotype similar to that of IVD cells, a number of mechanoreceptors have been identified, with ,5,1 integrin acting as a predominant mechanoreceptor. The purpose of this study was to investigate the role of integrin signaling in IVD cells during mechanical stimulation and to determine whether RGD integrins are involved. Methods Human nucleus pulposus (NP) cells derived from nondegenerated and degenerated discs were subjected to dynamic compressive loading in the presence of an RGD inhibitory peptide. Expression of the ,5,1 heterodimer in IVD tissue was examined by immunohistochemistry and possible alternative mechanoreceptors by real-time quantitative polymerase chain reaction. Results Aggrecan gene expression was decreased following loading of NP cells from nondegenerated and degenerated discs. This response was inhibited by treatment with an RGD peptide in cells from nondegenerated, but not degenerated, IVDs. Immunohistochemistry demonstrated that expression of the ,5,1 heterodimer was unaltered in degenerated IVD tissue as compared with normal IVD tissue. Conclusion Our results indicate that the mechanotransduction pathways are altered in cells from degenerated IVDs. Mechanosensing in NP cells from nondegenerated discs occurs via RGD integrins, possibly via the ,5,1 integrin, while cells from degenerated discs show a different signaling pathway that does not appear to involve RGD integrins. [source]


The role of the calmodulin-dependent pathway in static magnetic field-induced mechanotransduction,

BIOELECTROMAGNETICS, Issue 4 2010
Jen-Chang Yang
Abstract While the effects of static magnetic fields (SMFs) on osteoblastic differentiation are well demonstrated, the mechanotransduction pathways of SMFs are still unclear. The aim of this study was to explore the role of calmodulin in the biophysical effects of SMFs on osteoblastic cells. MG63 cells were exposed to a 0.4,T SMF. The expression of phosphodiesterase RNA in the cytoplasm was tested using real-time polymerase chain reaction. The differentiation of the cells was assessed by detecting changes in alkaline phosphatase activity. The role of calmodulin antagonist W-7 was used to evaluate alterations in osteoblastic proliferation and differentiation after the SMF simulations. Our results showed that SMF exposure increased alkaline phosphatase activity and phosphodiesterase 1C gene expression in MG63 cells. Addition of W-7 significantly inhibited the SMF-induced cellular response. We suggest that one possible mechanism by which SMFs affects osteoblastic maturation is through a calmodulin-dependent mechanotransduction pathway. Bioelectromagnetics 31:255,261, 2010. © 2009 Wiley-Liss, Inc. [source]