BACKGROUND: Hypertension is a risk factor for coronary heart disease. Macrophages are critically involved in both atherogenesis and plaque instability. Although macrophages may be subjected to excess mechanical stress in these diseases, the way in which biomechanical forces affect macrophage function remains incompletely defined. OBJECTIVE: To investigate the molecular response to mechanical force in macrophages. DESIGN AND METHODS: We used a DNA microarray with 1056 genes to describe the transcriptional profile of mechanically induced genes in human monocytic THP-1 cells. Mechanical deformation was applied to a thin and transparent membrane on which cells were cultured. After THP-1 cells were pre-incubated in the presence of phorbol 12-myristate 13-acetate (0.2 micromol/l) for 24 h, THP-1 cells attached to the membrane were subjected to biaxial mechanical strain. Interleukin-8 concentrations were determined using an enzyme-linked immunosorbent assay. RESULTS: In DNA microarray analysis, cyclic mechanical strain at 1 Hz induced only three genes more than 2.5-fold at 3 and 6 h in THP-1 cells: prostate apoptosis response-4 (3.0-fold at 3 h, 6.7-fold at 6 h), interleukin-8 (4.3-fold at 6 h) and the immediate-early response gene, IEX-1 (2.6-fold at 6 h). Real-time reverse transcriptase polymerase chain reaction analysis confirmed the amplitude-dependent induction of these three genes. In addition, mechanical strain increased interleukin-8 protein expression. CONCLUSION: The present study demonstrates that human monocytic cells respond to mechanical deformation with induction of immediate-early and inflammatory genes. These findings suggest that mechanical stress in vivo, such as that associated with hypertension, may play an important part in atherogenesis and instability of coronary artery plaques, through biomechanical effects on vascular macrophages.
BACKGROUND:Hypertension is a risk factor for coronary heart disease. Macrophages are critically involved in both atherogenesis and plaque instability. Although macrophages may be subjected to excess mechanical stress in these diseases, the way in which biomechanical forces affect macrophage function remains incompletely defined. OBJECTIVE: To investigate the molecular response to mechanical force in macrophages. DESIGN AND METHODS: We used a DNA microarray with 1056 genes to describe the transcriptional profile of mechanically induced genes in human monocytic THP-1 cells. Mechanical deformation was applied to a thin and transparent membrane on which cells were cultured. After THP-1 cells were pre-incubated in the presence of phorbol 12-myristate 13-acetate (0.2 micromol/l) for 24 h, THP-1 cells attached to the membrane were subjected to biaxial mechanical strain. Interleukin-8 concentrations were determined using an enzyme-linked immunosorbent assay. RESULTS: In DNA microarray analysis, cyclic mechanical strain at 1 Hz induced only three genes more than 2.5-fold at 3 and 6 h in THP-1 cells: prostate apoptosis response-4 (3.0-fold at 3 h, 6.7-fold at 6 h), interleukin-8 (4.3-fold at 6 h) and the immediate-early response gene, IEX-1 (2.6-fold at 6 h). Real-time reverse transcriptase polymerase chain reaction analysis confirmed the amplitude-dependent induction of these three genes. In addition, mechanical strain increased interleukin-8 protein expression. CONCLUSION: The present study demonstrates that human monocytic cells respond to mechanical deformation with induction of immediate-early and inflammatory genes. These findings suggest that mechanical stress in vivo, such as that associated with hypertension, may play an important part in atherogenesis and instability of coronary artery plaques, through biomechanical effects on vascular macrophages.
Authors: Sobia Raza; Kevin A Robertson; Paul A Lacaze; David Page; Anton J Enright; Peter Ghazal; Tom C Freeman Journal: BMC Syst Biol Date: 2008-04-23
Authors: Mohd Shahid; Ammar A Javed; David Chandra; Haley E Ramsey; Dilip Shah; Mohammed F Khan; Liping Zhao; Mei X Wu Journal: Sci Rep Date: 2016-04-11 Impact factor: 4.379