Abstract
This chapter provides an overview of experiments conducted in space and on Earth using machines created to simulate microgravity. Today, research in space on the International Space Station (ISS) or in orbit, as well as the exploration by humans of extraterrestrial environments like the Moon or Mars, is of worldwide interest. The commercial use of space and future space tourism will further increase this interest. The space travels of European astronauts have contributed to this great success with their enormously positive PR activities before, during and after their respective missions.
In the past, space medicine and gravitational biology were disciplines familiar only to a small research community, but they are attracting a lot of interest today. A large number of exciting research findings have been discovered in the last 40 years. Today we know that microgravity has an enormous influence on the biology of human cells, in particular on cellular morphology, the cytoskeleton and growth behavior. Moreover, it changes various biological processes in human cells.
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5.1 Introduction
Analysis of the cellular response to real microgravity in space offers new aspects in cell biology, tissue engineering and cancer research. Studies of the cellular response to microgravity have revealed novel adaptive mechanisms. Growing cells in a microgravity environment induces a three-dimensional (3D) growth behavior in different cell types more closely representing the in vivo situation in the human body (Grimm et al. 2014). This chapter summarizes data regarding space experiments conducted aboard the space shuttle, MIR, and the International Space Station (ISS). In addition, experiments obtained aboard unmanned space missions (SIMBOX/Shenzhou-8), rocket missions or parabolic flight missions will be discussed (Fig. 5.1). To compare and validate these findings, experiments using so-called ESA ground-based facilities, such as the Random Positioning Machine (RPM), the 2D clinostat and the NASA-developed Rotating Wall Vessel (RWV) bioreactor, will be evaluated (Fig. 5.2).
Long-term space missions induce a variety of health problems in astronauts, cosmonauts and taikonauts (White and Averner 2001; Grimm et al. 2011, 2016). Examples of these are bone loss, osteoporosis and cardiac atrophy together with hypotension and arrhythmias, muscle atrophy or a dysfunction of the immune system (White and Averner 2001; Grimm et al. 2011, 2016). In addition, visual problems are considered to be a major complication of spaceflights. One relevant health concern is the dysfunction of the immune system. This can result in opportunistic infections, or a poor wound-healing process.
One of the main aims of the current research on space medicine is to evaluate the effects of microgravity on human cells. Therefore, investigations of the primary molecular mechanisms of how microgravity might affect cell signaling are currently of interest.
5.2 Human Adult Retinal Pigment Epithelium Cells
A long-term stay in orbit can affect the eyes and might result in visual impairment for space travellers. Identification of the underlying mechanisms is very important. Studies of astronauts revealed spaceflight-induced ocular changes such as choroidal folds, optic disk edema, globe flattening and hyperopic shifts (Mader et al. 2011). It has been hypothesized that these visual problems are connected to cephalad fluid shifts, intracranial pressure and optic nerve sheath compartment syndrome, as a consequence of longterm microgravity exposure (Zwart et al. 2016; Mader et al. 2016).
The risk of visual impairment is an important health concern for NASA. We had recently examined the effects of simulated microgravity on human adult retinal epithelium cells (ARPE-19 cells). This study showed alterations in the cytoskeleton of ARPE-19 cells (Fig. 5.3). This was paralleled by changes in cell growth and the expression patterns of selected genes involved in cell structure, shape, adhesion, extracellular matrix, migration and angiogenesis (Corydon et al. 2016a).
5.3 Lymphocytes Cultured Under Conditions of Microgravity
A dysfunction of the immune response of astronauts is already evident after a few days in space and after longterm space flights (Pietsch et al. 2011).
Therefore, many researchers have demonstrated in the course of nearly 40 years of space research that human cells subjected to microgravity reveal a number of alterations in structure and function, including changes in proliferation, but also changes in cytokine production, or in protein kinase C distribution, as well as an elevation of programmed cell death.
To find the reasons for the altered immune response, researchers examined isolated lymphocytes during the first Spacelab missions and focused on the proliferation of these cells (Cogoli et al. 1979). In other studies, they detected an impairment of the response of lymphocytes to mitogenic stimulation (Cogoli et al. 1984; Cogoli and Tschopp 1985).
In addition, signal transduction processes for T-cell activation were disturbed (Cogoli-Greuter 1998; Cogoli-Greuter et al. 2004). In parallel, microgravity induced an increase of apoptosis and enhanced apoptosis-associated Fas/APO-1 proteins in lymphocytes (Jurkat cells) (Lewis et al. 1998).
Maccarrone et al. (2003) demonstrated the induction of 5-lipoxygenase activity and cytochrome c release into the cytosol of human lymphocytes, a result obtained under simulated microgravity conditions and later proven in space on the ISS (Battista et al. 2012). In addition, apoptosis was accompanied by an imbalance of interleukin-2 (IL-2) and interferon-γ (INF-γ), as well as anti- and proapoptotic cytokines (Gasperi et al. 2014). 5-LOX inhibition reduced apoptotic death, restored the initial IL-2/INF-γ ratio and reverted μ-calpain activation induced by simulated microgravity (Gasperi et al. 2014).
In space and on Earth the activation of human T lymphocytes is reduced. Furthermore, human leukocytes exerted changes in the protein kinase C (PKC) distribution (Hatton et al. 1999) and in the IL-2 and IL-2-R-alpha expression (Galleri et al. 2002). In addition, protein kinase A (PKA) is involved in sensing gravity (Boonyaratanakornkit et al. 2005).
In the spaceflight experiment LEUKIN, the investigators found that the transcription of immediate early genes is inhibited in T cells activated in microgravity and that disrupted activation of Rel/NF-κB, CREB1 and SRF transcription factors is involved (Chang et al. 2012).
It had been demonstrated that human T lymphocytes showed a differential inhibition of transcription factor activation in modelled microgravity created by clinorotation (Morrow 2006). AP-1 activation was blocked by clinorotation, whereas NFAT dephosphorylation occurred. Clinorotation inhibits the activation of cellular signaling (Morrow 2006). Another study investigating non-activated human T lymphocytes during a parabolic flight mission showed a downregulation of CD3 and IL-2R surface receptor after 20 s (Tauber et al. 2015). The authors assume that a gravity condition of 1g is required for the expression of key surface receptors and appropriate regulation of signal molecules in T lymphocytes (Tauber et al. 2015). These data show that several transcription factors play a role in sensing gravity in human lymphocytes.
Adrian et al. (2013) investigated NR8383 rat alveolar macrophages under altered gravity conditions obtained by parabolic flight maneuvers and clinorotation (2D–clinostat) and focused on the oxidative burst reaction in macrophages, which is a key element in the innate immune response and cellular signaling processes. Their data showed that gravity-sensitive steps are located both in the first activation pathways and in the final oxidative burst reaction. This could be explained by the role of cytoskeletal dynamics in the assembly and function of the NADPH oxidase complex (Adrian et al. 2013).
In CD3/CD28-stimulated primary human T cells, the p21 mRNA expression increased 4.1-fold after 20 s in real microgravity during a parabola in primary CD4+ T cells and 2.9-fold in Jurkat T cells, compared with 1g in-flight controls after CD3/CD28 stimulation. The histone acetyltransferase (HAT) inhibitor curcumin was able to abrogate microgravity-induced p21 mRNA expression, whereas its expression was enhanced by a histone deacetylase (HDAC) inhibitor. The authors supposed that cell cycle progression in human T lymphocytes requires Earth gravity and that the disturbed expression of cell cycle regulatory proteins could contribute to the downregulated immune system of humans in space (Thiel et al. 2012).
5.4 Vascular Cells in Space
Endothelial cells are important for the integrity of the vascular wall. They form the inner layer of blood vessels throughout the whole organism and serve as an anticoagulant barrier between blood and the vessel wall. It is a unique multifunctional cell with important basal and inducible metabolic and synthetic functions (Infanger et al. 2006). It is known that modulation of the endothelial cell function can induce cardiovascular problems and other health problems of humans in space. Endothelial cells are important for several biological processes, such as immune regulation, blood coagulation, growth, extracellular matrix synthesis and others. These processes can be disturbed when the cells are exposed to altered gravity conditions.
Endothelial dysfunction of microvascular endothelial cells (MVECs) may contribute to cardiovascular deconditioning occurring in microgravity. Microgravity conditions induced apoptosis in MVECs. The authors found a downregulation of the PI3K/Akt pathway, an elevation of NF-κB and a depolymerization of F-actin (Kang et al. 2011). Moreover, simulated microgravity can trigger angiogenesis in endothelial cells and induce tube and spheroid formation (Grimm et al. 2009, 2010, 2014; Ma et al. 2014a, b; Aleshcheva et al. 2016).
A recent paper by Shi et al. showed that clinorotation induces eNOS-mediated angiogenesis in HUVEC cells (Shi et al. 2016). In addition, the authors showed a requirement for Cav-1-associated signaling in microgravity-driven angiogenesis. They suggest that Cav-1 is a critical mediator in simulated weightlessness in endothelium-dependent angiogenesis (Shi et al. 2016).
It has been shown that both P2 receptor gene and protein expression in endothelial cells were altered under clinostat exposure. This indicates that P2 receptors might be important players responding to gravity changes in vascular cells (Zhang et al. 2014).
The post-flight microarray analysis of the ISS SPHINX experiment (HUVEC cells in space) revealed 1023 significantly modulated genes (Versari et al. 2013). The thioredoxin-interacting protein was 33-fold increased, and heat-shock proteins 70 and 90 5.6-fold downregulated. Ion channels, mitochondrial oxidative phosphorylation and focal adhesion were widely affected (Versari et al. 2013). The SPHINX investigators demonstrated that the space environment influences signaling pathways, inducing inflammatory responses, changing endothelial behavior and promoting senescence (Versari et al. 2013).
Endothelial cells exposed to short episodes of real microgravity achieved during parabolic flights exhibited changes in the cytoskeleton and a differential gene expression (Grosse et al. 2012a). In addition, this work showed that caveolins, AMPKα1 and integrins are possible gravi-sensitive elements (Grosse et al. 2012a).
Taking the available results together, protein kinases, integrins, caveolin-1, eNOS, P2 receptors and NF-kB might be key players in sensing gravity in endothelial cells.
5.5 Chondrocytes and Bone Cells
A prolonged exposure to microgravity has deleterious effects on human bone and cartilage (Grimm et al. 2016). Crewmembers suffer after a long-term spaceflight from a reduction of cartilage mass due to mechanical unloading (Zayzafoon et al. 2005).
Neocartilage was formed by porcine chondrocytes cultured in microgravity during the spaceflight 7S (Cervantes mission) on the ISS (Stamenkovic et al. 2010). A weaker extracellular matrix staining of ISS neocartilage tissue was detectable. Higher collagen II/I expression ratios were observed in ISS samples than in control tissue. In addition, there was a lower cell density in ISS neocartilage, which was significantly reduced compared with the normal-gravity neocartilage tissues.
Recent results from ten astronauts who spent more than 5 months in space showed that the cartilage extracellular matrix is sensitive to prolonged exposure to microgravity. This is supported by changes in serum molecular biomarker levels of cartilage turnover. A reduced mechanical loading through microgravity seems to initiate catabolic processes (Niehoff et al. 2016).
Shortterm microgravity during parabolic flight maneuvers had no damaging effects on human chondrocytes. The viability of the cells was normal during the parabolic flight, and a clearly elevated expression of anti-apoptotic genes was detectable after 31st parabolas (Wehland et al. 2015).
A similar result was obtained when human chondrocytes were cultured on the random positioning machine. No signs of apoptosis could be detected (Ulbrich et al. 2010).
Shortterm studies of human chondrocytes exposed to the RPM demonstrated early cytoskeletal changes within 30 min (Aleshcheva et al. 2013). No cytoskeletal changes in chondrocytes were detectable after the first parabola, but they appeared later (vimentin, tubulin, cytokeratin) after the 31st parabola of a parabolic flight, although F-actin remained unaltered (Aleshcheva et al. 2015).
Taking these results for chondrocytes together, chondrocytes exposed to microgravity exhibit only moderate changes of the cytoskeleton. After RPM exposure they change their extracellular matrix production behaviour while they rearrange their cytoskeletal proteins prior to forming three-dimensional aggregates (Fig. 5.4). No signs of programmed cell death were detectable.
A longterm stay in space without available countermeasures enormously affects the bone health of astronauts (Grimm et al. 2016). Bone loss, osteoporosis and bone fractures can occur. One of the mechanisms through which space ventures depress bone formation is through effects on the Wnt/β-catenin signaling pathway. Recent studies have shown that simulated microgravity conditions increase the expression of sclerostin and Dkk-1 in osteocytes (Yang et al. 2015). Wnt-signaling elevates osteoblastic cell differentiation and bone formation, but also inhibits bone resorption. It induces blocking of the receptor activator of nuclear factor-κB-ligand (RANKL)/RANK interaction (Jackson et al. 2005).
There is evidence that although the exact mechanisms are not known, it is possible that sclerostin plays a key role in skeletal adaptation to mechanical forces. Spatz et al. investigated the expression of sclerostin in osteocytes in vitro and showed that sclerostin is upregulated by mechanical unloading (Spatz et al. 2015). This suggests that mechanical loading regulates intrinsic osteocyte responses (Spatz et al. 2015).
A 5-day spaceflight resulted in an increase in bone resorption by osteoclasts as well as a decrease in osteoblast cellular integrity (Nabavi et al. 2011). Osteoblasts exposed to microgravity exhibited alterations of the microtubules, changes in focal adhesions, and thinner cortical actin and stress fibres (Nabavi et al. 2011).
Real microgravity induces alterations of the cytoskeleton and focal adhesions in bone cells. These are two major mechanosensitive structures. The cytoskeleton responds to changes in the mechanical environment because it is connected to the extracellular matrix through focal adhesions. Exposure of osteoblasts to microgravity impairs their cytoskeleton stability and reduces cellular tension, as well as focal adhesion formation and stability (Hughes-Fulford 2003). Kumei et al. demonstrated that microgravity influences cell adhesion, the cytoskeleton and extracellular matrix proteins of rat osteoblasts cultured in space. Osteopontin and tubulin gene expression levels were downregulated (Kumei et al. 2006).
After a 48 h-clinostat exposure, actin filaments of human osteosarcoma MG63 cells depolymerized, became thinner, and showed a dispersed distribution and disorder, especially in the cytoplasm (Dai et al. 2013).
Summarizing these findings on bone, microgravity clearly influences the cytoskeleton and extracellular matrix proteins in bone cells.
5.6 Cancer Cells Cultured in Microgravity
Different types of cancer cells exposed to microgravity exhibited specific alterations of the cytoskeleton. Human breast cancer cells exposed to real microgravity conditions in space revealed alterations in their microtubules as well as changes in the perinuclear cytokeratin network (Vassy et al. 2001).
These cytoskeletal changes are detectable early. After the first parabola during a parabolic flight, alterations of F-actin were found in follicular thyroid cancer cells (ML-1 cell line) (Ulbrich et al. 2011) and also observed in endothelial cells (EAhy926 cell line) (Grosse et al. 2012a). These findings were proven by the FLUMIAS (Fluorescence Microscopy Analysis System) experiment under microgravity (Fig. 5.5). During the TEXUS-52 sounding rocket flight, the FLUMIAS microscope revealed similar changes in the F-actin network to those observed after RPM-exposure (Corydon et al. 2016b).
When cancer cells were cultured under microgravity conditions, they started to grow three-dimensionally within 24 h, depending on the cell type. DU-145 human prostate carcinoma cells were cultured on a HARV (high-aspect rotating-wall vessel). The authors found that HARV cultivation induced a 3D organoid-like growth type, which was less aggressive, slower growing, less proliferative, more differentiated and a less pliant cell method (Clejan et al. 2001). A similar finding that microgravity induces a phenotype switch to a less aggressive one was detected for low-differentiated follicular thyroid cancer cells, which were investigated during the Sino-German space mission Shenzhou-8 in real microgravity (Ma et al. 2014b).
Moreover, 3D growth and the formation of 3D spheroids were confirmed in space (Pietsch et al. 2013). A scaffold-free formation of extraordinarily large 3D aggregates by thyroid cancer cells with altered expression of EGF and CTGF genes was detectable in space. The formation of 3D spheroids had already been demonstrated by exposing a variety of cancer cells to simulated microgravity conditions using a NASA rotary cell culture system (Ingram et al. 1997). The expression of the cell adhesion molecules CD44 and E cadherin was upregulated in the 3D constructs (Ingram et al. 1997).
Follicular thyroid cancer cells investigated on the RPM started to grow in the form of two phenotypes: first as a 2D monolayer and second as a 3D spheroid within 24 h (Grimm et al. 2002; Grosse et al. 2012b; Warnke et al. 2014; Svejgaard et al. 2015; Kopp et al. 2015). Cells grown on the RPM for 24 h exhibited an increase in the NF-κB p65 protein and apoptosis compared to 1g controls, a result also found earlier in endothelial cells. The signaling elements IL-6, IL-8, OPN, TLN1 and CTGF are involved with NF-κB p65 in RPM-dependent thyroid carcinoma cell spheroid formation (Grosse et al. 2012b). In addition, a device comparison study (RPM and 2D clinostat) demonstrated changes in the regulation of CTGF and CAV1 appearing in a comparable manner on both machines. Both factors seem to play a role in 3D formation (Warnke et al. 2014). IL-6 and IL-8 application to the medium of ML-1 cancer cells has shown a direct influence on 3D formation (Svejgaard et al. 2015). In a longterm study, FTC-133 low-differentiated follicular thyroid cancer cells and normal thyrocytes were cultured on the RPM for 14 days (Kopp et al. 2015). Significant differences between normal and cancer cells were found concerning the gene expression of NGAL, VEGFA, OPN, IL6 and IL17 and the secretion of VEGFA, IL-17 and IL-6 (Kopp et al. 2015). These data suggest their involvement in 3D formation of thyroid cells after RPM exposure.
Taking these data together, cancer cells studied in real or simulated microgravity show early cytoskeletal changes, apoptosis and 3D growth. Several factors are known to be involved in the aggregation process and phenotype switch of the investigated cells. These are the growth factors CTGF, EGF and VEGF, the cytokines IL-6, IL-8 and IL-17 and NF-kB.
5.7 Hypothesis on How Gravity Is Perceived by Human Cells: The Tensegrity Model—How Unspecialized Human Cells Might Sense Gravity
As described, human cells in vitro can react to mechanical unloading in different ways; however, the question arises as to how they are able to sense the rather weak changes in force.
Ever since Rijken et al. found significant alterations of the cytoskeleton in human A431 cells during a TEXUS flight in 1991 (Rijken et al. 1991a, b), the cytoskeleton has been a hot candidate for transmitting mechanical unloading from the cells’ environment.
How the cells manage to transform the mechanical signal into a biochemical one is still today a current topic under investigation. However, an increasing yield of data supports the tensegrity model hypothesis, proposed by Ingber (1999).
The tensegrity model claims that cells are hardwired by the different parts of the cytoskeleton, which are connected to discrete cell adhesions. According to this model, cells are spanned open and are under continuous tension. The adhesion points are connected to the extracellular matrix. In sum, there is a balance of force between the extracellular matrix, adhesion points and the cytoskeleton in normal gravity conditions. Therefore, an imbalance of adhesion and cytoskeleton would result in a change of cell shape and have a direct impact on signaling cascades and downstream transcription events (Ingber 1999).
This theory is supported by various findings of cytoskeletal changes in different cell types after short-term exposure to real and simulated microgravity (Vorselen et al. 2014). Fixation of thyroid cancer cells and endothelial cells as well as chondrocytes after 22 s of microgravity revealed that actin fibres and/or microtubules were localized close to the nucleus while losing their distinct polarization (Grosse et al. 2012a; Aleshcheva et al. 2015; Ulbrich et al. 2011). These findings are in concert with significant gene expression changes after 22 s of real microgravity.
However, artefact building during fixation could not be neglected until Corydon et al. first investigated life-act GFP marked thyroid cancer cells during a parabolic flight campaign and the TEXUS 52 campaign in Kiruna, Sweden (Corydon et al. 2016b). Live imaging of the cells during microgravity revealed an instant rearrangement of actin filaments and a rapid change of cell shape.
These findings are in concert with gene expression changes in cytoskeletal genes and proteins, which are involved in proliferation and differentiation. Finally, these experiments further increased the evidence of a direct correlation between the cytoskeletal rearrangements upon microgravity and transcription alterations and strongly suggest that the interaction between the extracellular matrix, adhesion and connected cytoskeleton is a major part in gravi-sensing non-specialized human cells.
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Grimm, D. (2017). Cell Biology in Space. In: Biotechnology in Space. SpringerBriefs in Space Life Sciences. Springer, Cham. https://doi.org/10.1007/978-3-319-64054-9_5
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