The Emerging Role of Macrophages in Immune System Dysfunction under Real and Simulated Microgravity Conditions
Abstract
:1. Introduction
2. Comparison of Facilities Used for Microgravity Research
2.1. Parabolic Flight
2.2. 2-D Clinostat
2.3. Random Positioning Machine
2.4. Rotating Wall Vessel
Item | Modeled Microgravity | Real Microgravity | Cell | Levels | Reference |
---|---|---|---|---|---|
IL-1 | RWV | U937 (Human) | Increased | [37] | |
During spaceflight | B6MP102 cells (Murine) | Increased | [38] | ||
Spacelab | PBMC (Human) | Decreased | [5] | ||
Postflight | PBMC (Monkey) | Decreased | [39] | ||
IL-2 | Postflight | Whole blood-T cell | Decreased | [40] | |
RWV | U937 (Human) | Increased | [37] | ||
IL-6 | During spaceflight | PBMC (Human) | Decreased | [41] | |
Postflight | Blood-monocytes (Human) | Decreased | [42] | ||
RCCS | Macrophages (Murine) | Increased | [16] | ||
IFN-α | During spaceflight | Lymphocytes (Human) | Increased | [43] | |
During spaceflight | Spleen cells (Murine) | Increased | [44] | ||
IFN-β | During spaceflight | Lymph node T cells (Murine) | Increased | [43] | |
IFN-γ | During spaceflight | peripheral blood lymphocytes (Human) | Increased | [44] | |
Postflight | Splenocytes (Rat) | Decreased | [45] | ||
TNF-α | During spaceflight | Peripheral blood(Human) | Decreased | [41] | |
During spaceflight | B6MP102 cells (Murine) | Increased | [38] | ||
Postflight | Whole blood (Human) | Decreased | [46] | ||
RCCS | Macrophages (Murine) | Decreased | [17] |
Cell | Modeled Microgravity | Real Microgravity | Cell Location | Alterations | References |
---|---|---|---|---|---|
Lymphocyte | RWV | Lymph nodes (Mouse) | Abrogated antigen-specific function | [47] | |
Spacelab | Blood (Human) | Inhibited response to mitogen Con A | [48] | ||
RWV | Peripheral blood (Human) | Inhibited locomotion, blunted ability to respond to PHA | [35] | ||
RWV | PBMC (Human) | Suppression of PHA activation | [36] | ||
Postflight | PBMC (Human) | Reduction of activity | [49] | ||
Natural killer cell | Postflight | PBMC (Human) | Suppressed cytotoxic | [49] | |
Postflight | Peripheral blood (Human) | Lower cell counts | [50] | ||
Spaceflight | Spleen (Rat) | Inhibited cytotoxicity | [51] | ||
Neutrophil | Postflight | Blood (Human) | Increased number | [45,52] | |
Postflight | Peripheral blood (Human) | Increased number | [52,53] | ||
Postflight | Circulating leukocyte subsets (Human) | Increased number | [54] | ||
Postflight | Blood (Human) | Increased number, lower phagocytosis, and oxidative burst capacities | [49,55] | ||
Monocyte/ macrophage | SLS-1 | Blood (Human) | Increased number | [56] | |
Parabolic flight | BMDM (Mouse) | Enhanced proliferation, inhibited differentiation | [27] | ||
Postflight | Blood (Human) | Monocytopenia | [57] | ||
Postflight | Spleen (Rat) | Decreased number | [58] | ||
Postflight | Peripheral blood (Human) | Increased number | [53] | ||
Postflight | Peripheral blood leucocytes (Human) | Increased number | [59] | ||
RCCS | Spleen (Mouse) | Decreased number | [60] | ||
Postflight | PBMC (Human) | Reduction in phagocytosis | [49,61] |
Devices | Principle | Application | Characteristic | Shortcoming | References |
---|---|---|---|---|---|
RPM | Randomizing the gravity vector direction and the gravity vector is averaged to nearly zero over time | Osteoblasts; T lymphocytes; adherent cells | Two axes with different speeds and directions | Cell behavior affected by the shear forces and other forces; no gas change | [29,62] |
2-D Clinostat | Plants; small organism; unicellular; slow responsive living objects | One axis with fast and constant rotation | Vibration and centrifugal forces may lead to artifacts; no gas change | [63,64,65,66] | |
RWV (RCCS) | Suspended and anchorage-dependent cells; cell differentiation | Co-culture multiple cell types in a 3D spheroid morphology with low shear force | Lack of measurability; limited transfer of matter; additional environmental conditions such as the mixture | [67,68,69] | |
Parabolic Flight | Centrifugal forces counteract the gravity vector | Fast events, such as signal transduction, hormone secretion, binding of ligands to cell membranes | By controlling acceleration, creating a centrifugal force; about 25 s microgravity time | External conditions are not easy to control; high cost; short time of microgravity simulation | [25] |
3. Macrophages under Microgravity Conditions
3.1. TNF-α
3.1.1. TNF-α Expression under Simulated Microgravity Conditions
3.1.2. TNF-α Expression in Real Microgravity
3.2. Arginase I
3.2.1. Arginase I Expression under Simulated Microgravity Conditions
- STAT6
- C/EBPβ
3.2.2. Arginase I Expression in Real Microgravity
3.3. ICAM-1
3.3.1. ICAM-1 Expression under Simulated Microgravity Conditions
3.3.2. ICAM-1 Expression in Real Microgravity
4. Discussion
4.1. Molecules in Macrophages Sensitive to Real and Simulated Microgravity
4.2. The Impact of Real and Simulated Microgravity on Immune Cells
4.3. The Problems of Simulation of Microgravity in Comparison to Real Microgravity
4.4. Perspective
Author Contributions
Funding
Acknowledgments
Conflicts of Interest
Abbreviations
2-D clinostat | Two-dimensional clinostat |
AP-1 | Activator protein 1 |
BMDM | Bone marrow-derived macrophage |
C/EBPβ | CCAAT-enhancer-binding proteins β |
Con A | Concanavalin A |
HSE | Heat shock element |
HSF-1 | Heat shock factors 1 |
ICAM-1 | Intercellular adhesion molecule 1 |
IL-4R | Interleukin-4 receptor |
IL-4 | Interleukin-4 |
IL-6 | Interleukin-6 |
IL-8 | Interleukin-8 |
iNOS | Inducible nitric oxide synthase |
IkB | Inhibitor of nuclear factor kappa-B |
JAK | Janus kinase |
LFA -1 | Lymphocyte function-associated antigen 1 |
LPS | Lipopolysaccharide |
MAPK | Mitogen-activated protein kinase |
NF-kB | Nuclear factor-kappa B |
NO | Nitric oxide |
PBMC | Peripheral blood mononuclear cells |
PHA | Phytohemagglutinin |
RCCS | Rotary cell culture system |
RPM | Random positioning machine; |
RWV | Rotating wall vessel |
STAT | Signal transducer and activator of transcription |
TLR4 | Toll-like receptors 4 |
TNF-α | Tumor necrosis factor α |
YM1 | Chitinase-like protein |
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Sun, Y.; Kuang, Y.; Zuo, Z. The Emerging Role of Macrophages in Immune System Dysfunction under Real and Simulated Microgravity Conditions. Int. J. Mol. Sci. 2021, 22, 2333. https://doi.org/10.3390/ijms22052333
Sun Y, Kuang Y, Zuo Z. The Emerging Role of Macrophages in Immune System Dysfunction under Real and Simulated Microgravity Conditions. International Journal of Molecular Sciences. 2021; 22(5):2333. https://doi.org/10.3390/ijms22052333
Chicago/Turabian StyleSun, Yulong, Yuanyuan Kuang, and Zhuo Zuo. 2021. "The Emerging Role of Macrophages in Immune System Dysfunction under Real and Simulated Microgravity Conditions" International Journal of Molecular Sciences 22, no. 5: 2333. https://doi.org/10.3390/ijms22052333
APA StyleSun, Y., Kuang, Y., & Zuo, Z. (2021). The Emerging Role of Macrophages in Immune System Dysfunction under Real and Simulated Microgravity Conditions. International Journal of Molecular Sciences, 22(5), 2333. https://doi.org/10.3390/ijms22052333