Although cells of the immune system experience force and pressure throughout their lifecycle, almost nothing is known about how these mechanical processes regulate the immune response 1. Both tissue-resident and tissue-infiltrating immune cells in highly mechanical organs, such as the lung, are constantly exposed to tonic and dynamically changing mechanical cues 2. Here using reverse genetics, we show that myeloid cells respond to force and alterations in cyclical hydrostatic pressure via the mechanosensory ion channel PIEZO1 3. Unbiased RNA sequencing from macrophages subjected to cyclical hydrostatic pressure reveals a striking state of proinflammatory reprogramming. We report a novel mechanosensory-immune signaling circuit which PIEZO1 initiates in response to cyclical hydrostatic pressure, driving c-JUN activation and transcriptional upregulation of Endothelin-1 (EDN1). EDN1 in turn stabilizes HIF1α, which facilitates transcription of a potent and prolonged program of proinflammatory mediators. Using mice conditionally deficient of PIEZO1 in myeloid cells, and cellular depletion assays, we show 10
An understanding of how mechanical forces impact cells within valve leaflets would greatly benefit the development of a tissue-engineered heart valve. Previous studies by this group have shown that exposure to constant static pressure leads to enhanced collagen synthesis in porcine aortic valve leaflets. In this study, the effect of cyclic pressure was evaluated using a custom-designed pressure system. Different pressure magnitudes (100, 140, and 170 mmHg) as well as pulse frequencies (0.5, 1.167, and 2 Hz) were studied. Collagen synthesis, cell proliferation, sGAG synthesis, alpha-SMC actin expression, and extracellular matrix (ECM) structure were chosen as markers for valvular biological responses. Results showed that aortic valve leaflets responded to cyclic pressure in a magnitude and frequency-dependent manner. Increases in pressure magnitude (with the frequency fixed at 1.167 Hz) resulted in significant increases in both collagen and sGAG synthesis, while DNA synthesis remained unchanged. Responses to pulse frequency (with the magnitude fixed at 100 mmHg) were more complex. Collagen and sGAG synthesis were increased by 25 and 14% respectively at 0.5 Hz; but were not affected at 1.167 and 2 Hz. In contrast, DNA synthesis increased by 72% at 2 Hz, but not at 0.5 and 1.167 Hz. Under extreme pressure conditions (170 mmHg, 2 Hz), collagen and sGAG synthesis were increased but to a lesser degree than at 170 mmHg, and 1.167 Hz. Cell proliferation was not affected. A notable decline in a-SMC actin was observed over the course of the experiments, although no significant difference was observed between the cyclic pressure and control groups. It was concluded that cyclic pressure affected biosynthetic activity of aortic valve leaflets in a magnitude and frequency dependent manner. Collagen and sGAG synthesis were positively correlated and more responsive to pressure magnitude than pulse frequency. DNA synthesis was more responsive to pulse frequency than pressure magnitude. However, when combined, pressure magnitude and pulse frequency appeared to have an attenuating effect on each other. The number of alpha-SMC actin positive cells did not vary with cyclic pressure, regardless of pulse frequency and pressure magnitude.
Viral vector is the most effective means of gene transfer to modify specific cell type or tissue and can be manipulated to express therapeutic genes. Several virus types are currently being investigated for use to deliver genes to cells to provide either transient or permanent transgene expression. These include adenoviruses (Ads), retroviruses (γ-retroviruses and lentiviruses), poxviruses, adeno-associated viruses, baculoviruses, and herpes simplex viruses. The choice of virus for routine clinical use will depend on the efficiency of transgene expression, ease of production, safety, toxicity, and stability. This chapter provides an introductory overview of the general characteristics of viral vectors commonly used in gene transfer and their advantages and disadvantages for gene therapy use.
An understanding of how mechanical forces impact cells within valve leaflets would greatly benefit the development of a tissue-engineered heart valve. In this study, the effect of constant ambient pressure on the biological properties of heart valve leaflets was evaluated using a custom-designed pressure system. Native porcine aortic valve leaflets were exposed to static pressures of 100, 140, or 170 mmHg for 48 h. Collagen synthesis, DNA synthesis, sulfated glycoaminoglycan (sGAG) synthesis, alpha-SMC actin expression, and extracellular matrix (ECM) structure were examined. Results showed that elevated pressure caused an increase in collagen synthesis. This increase was not statistically significant at 100 mmHg, but at 140 mmHg and 170 mmHg collagen synthesis increased by 37.5 and 90%, respectively. No significant difference in DNA or sGAG synthesis was observed at elevated pressures, with the exception that DNA synthesis at 100 mmHg decreased. A notable decline in alpha-SMC actin was observed over the course of the experiments although no significant difference was observed between the pressure and control groups. It was concluded that elevated pressure caused a proportional increase in collagen synthesis of porcine aortic valve leaflets, but was unable to preserve alpha-SMC actin immunoreactive cells.
Mechanical in vitro preconditioning of tissue engineered heart valves is viewed as an essential process for tissue development prior to in vivo implantation. However, a number of pro-inflammatory genes are mechanosensitive and their elaboration could elicit an adverse response in the host. We hypothesized that the application of normal physiological levels of strain to isolated valve interstitial cells would inhibit the expression of pro-inflammatory genes. Cells were subjected to 0, 5, 10, 15 and 20% strain. Expression of VCAM-1, MCP-1, GM-CSF and OPN was then measured using qRT-PCR. With the exception of OPN, all genes were significantly up regulated when no strain was applied. MCP-1 expression was significantly lower in the presence of strain, although strain magnitude did not affect the expression level. VCAM-1 and GM-CSF had the lowest expression levels at 15% strain, which represent normal physiological conditions. These findings were confirmed using confocal microscopy. Additionally, pSMAD 2/3 and IkappaBalpha expression were imaged to elucidate potential mechanisms of gene expression. Data showed that 15% strain increased pSMAD 2/3 expression and prevented phosphorylation of IkappaBalpha. In conclusion, cyclic strain reduces expression of pro-inflammatory genes, which may be beneficial for the in vitro pre-conditioning of tissue engineered heart valves.
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