Jessica Pietsch

The Effects of Weightlessness on the Human Organism and Mammalian Cells

It has always been a desire of mankind to conquest Space. A major step in realizing this dream was the completion of the International Space Station (ISS). Living there for several months confirmed early observations of short-term spaceflights that a loss of gravity affects the health of astronauts. Space medicine tries to understand the mechanism of microgravity-induced health problems and to conceive potent countermeasures. There are four different aspects which make space medicine appealing: i) finding better strategies for adapting astronauts to weightlessness; ii) identification of microgravity-induced diseases (e.g. osteoporosis, muscle atrophy, cardiac problems and others); iii) defining new therapies to conquer these diseases which will benefit astronauts as well as people on Earth in the end; and iv) on top of that, unveiling the mechanisms of weightlessness-dependent molecular and cellular changes is a requirement for improving space medicine. In mammalian cells, microgravity induces apoptosis and alters the cytoskeleton and affects signal transduction pathways, cell differentiation, growth, proliferation, migration and adhesion. This review focused on gravi-sensitive signal transduction elements and pathways as well as molecular mechanisms in human cells, aiming to understand the cellular changes in altered gravity. Moreover, the latest information on how these changes lead to clinically relevant health problems and current strategies of countermeasures are reviewed.

Short-term weightlessness produced by parabolic flight maneuvers altered gene expression patterns in human endothelial cells

This study focused on the effects of short‐term microgravity (22 s) on the gene expression and morphology of endothelial cells (ECs) and evaluated gravisensitive signaling elements. ECs were investigated during four German Space Agency (Deutsches Zentrum für Luft‐ und Raumfahrt) parabolic flight campaigns. Hoechst 33342 and acridine orange/ethidium bromide staining showed no signs of cell death in ECs after 31 parabolas (P31). Gene array analysis revealed 320 significantly regulated genes after the first parabola (P1) and P31. COL4A5, COL8A1, ITGA6, ITGA10, and ITGB3 mRNAs were down‐regulated after P1. EDN1 and TNFRSF12A mRNAs were up‐regulated. ADAM19, CARD8, CD40, GSN, PRKCA (all down‐regulated after P1), and PRKAA1 (AMPKα1) mRNAs (up‐regulated) provide a very early protective mechanism of cell survival induced by 22 s microgravity. The ABL2 gene was significantly up‐regulated after P1 and P31, TUBB was slightly induced, but ACTA2 and VIM mRNAs were not changed. β‐Tubulin immunofluorescence revealed a cytoplasmic rearrangement. Vibration had no effect. Hypergravity reduced CARD8, NOS3, VASH1, SERPINH1 (all P1), CAV2, ADAM19, TNFRSF12A, CD40, and ITGA6 (P31) mRNAs. These data suggest that microgravity alters the gene expression patterns and the cytoskeleton of ECs very early. Several gravisensitive signaling elements, such as AMPKα1 and integrins, are involved in the reaction of ECs to altered gravity.—Grosse, J., Wehland, M., Pietsch, J., Ma, X., Ulbrich, C., Schulz, H., Saar, K., Hübner, N., Hauslage, J., Hemmersbach, R., Braun, M., van Loon, J., Vagt, N., Infanger, M., Eilles, C., Egli, M., Richter, P., Baltz, T., Einspanier, R., Sharbati, S., Grimm, D. Short‐term weightlessness produced by parabolic flight maneuvers altered gene expression patterns in human endothelial cells. FASEB J. 26, 639–655 (2012). www.fasebj.org

A Delayed Type of Three-Dimensional Growth of Human Endothelial Cells Under Simulated Weightlessness

Endothelial cells (ECs) form three-dimensional (3D) aggregates without any scaffold when they are exposed to microgravity simulated by a random positioning machine (RPM) but not under static conditions at gravity. Here we describe a delayed type of formation of 3D structures of ECs that was initiated when ECs cultured on a desktop RPM remained adherent for the first 5 days but spread over neighboring adherent cells, forming little colonies. After 2 weeks, tube-like structures (TSs) became visible in these cultures. They included a lumen, and they elongated during another 2 weeks of culturing. The walls of these TSs consisted mainly of single-layered ECs, which had produced significantly more beta(1)-integrin, laminin, fibronectin, and alpha-tubulin than ECs simultaneously grown adhering to the culture dishes under microgravity or normal gravity. The amount of actin protein was similar in ECs incorporated in TSs and in ECs growing at gravity. The ratio of tissue inhibitor of metalloproteinases-1 to matrix metalloproteinase-2 found in the supernatants was lower at the seventh than at the 28th day of culturing. These results suggest that culturing ECs under conditions of modeled gravitational unloading represents a new technique for studying the formation of tubes that resemble vascular intimas.

Differential gene expression profile and altered cytokine secretion of thyroid cancer cells in space

This study focuses on the effects of short‐term [22 s, parabolic flight campaign (PFC)] and long‐term (10 d, Shenzhou 8 space mission) real microgravity on changes in cytokine secretion and gene expression patterns in poorly differentiated thyroid cancer cells. FTC‐133 cells were cultured in space and on a random positioning machine (RPM) for 10 d, to evaluate differences between real and simulated microgravity. Multianalyte profiling was used to evaluate 128 secreted cytokines. Microarray analysis revealed 63 significantly regulated transcripts after 22 s of microgravity during a PFC and 2881 after 10 d on the RPM or in space. Genes in several biological processes, including apoptosis (n=182), cytoskeleton (n=80), adhesion/extracellular matrix (n=98), proliferation (n=184), stress response (n=268), migration (n=63), angiogenesis (n=39), and signal transduction (n=429), were differentially expressed. Genes and proteins involved in the regulation of cancer cell proliferation and metastasis, such as IL6, IL8, IL15, OPN, VEGFA, VEGFD, FGF17, MMP2, MMP3, TIMP1, PRKAA, and PRKACA, were similarly regulated under RPM and spaceflight conditions. The resulting effect was mostly antiproliferative. Gene expression during the PFC was often regulated in the opposite direction. In summary, microgravity is an invaluable tool for exploring new targets in anticancer therapy and can be simulated in some aspects in ground‐based facilities.—Ma, X., Pietsch, J., Wehland, M., Schulz, H., Saar, K., Hübner, N., Bauer, J., Braun, M., Schwarzwälder, A., Segerer, J., Birlem, M., Horn, A., Hemmersbach, R., Waβer, K., Grosse, J., Infanger, M., Grimm, D. Differential gene expression profile and altered cytokine secretion of thyroid cancer cells in space. FASEB J. 28, 813–835 (2014). www.fasebj.org

Differential gene regulation under altered gravity conditions in follicular thyroid cancer cells: relationship between the extracellular matrix and the cytoskeleton

Extracellular matrix proteins, adhesion molecules, and cytoskeletal proteins form a dynamic network interacting with signalling molecules as an adaptive response to altered gravity. An important issue is the exact differentiation between real microgravity responses of the cells or cellular reactions to hypergravity and/or vibrations. To determine the effects of real microgravity on human cells, we used four DLR parabolic flight campaigns and focused on the effects of short-term microgravity (22 s), hypergravity (1.8 g), and vibrations on ML-1 thyroid cancer cells. No signs of apoptosis or necrosis were detectable. Gene array analysis revealed 2430 significantly changed transcripts. After 22 s microgravity, the F-actin and cytokeratin cytoskeleton was altered, and ACTB and KRT80 mRNAs were significantly upregulated after the first and thirty-first parabolas. The COL4A5 mRNA was downregulated under microgravity, whereas OPN and FN were significantly upregulated. Hypergravity and vibrations did not change ACTB, KRT-80 or COL4A5 mRNA. MTSS1 and LIMA1 mRNAs were downregulated/slightly upregulated under microgravity, upregulated in hypergravity and unchanged by vibrations. These data indicate that the graviresponse of ML-1 cells occurred very early, within the first few seconds. Downregulated MTSS1 and upregulated LIMA1 may be an adaptive mechanism of human cells for stabilizing the cytoskeleton under microgravity conditions.

Gravity-sensitive signaling drives 3-dimensional formation of multicellular thyroid cancer spheroids

This study focused on the effects induced by a random positioning machine (RPM) on FTC‐133 thyroid cancer cells and evaluated signaling elements involved in 3‐dimensional multicellular tumor spheroid (MCTS) formation. The cells were cultured on the RPM, a device developed to simulate microgravity, and under static 1‐g conditions. After 24 h on the RPM, MCTSs swimming in culture supernatants were found, in addition to growth of adherent (AD) cells. Cells grown on the RPM showed higher levels of NF‐κB p65 protein and apoptosis than 1‐g controls, a result also found earlier in endothelial cells. Employing microarray analysis, we found 487 significantly regulated transcripts belonging not only to the apoptosis pathway but also to other biological processes. Selected transcripts were analyzed with quantitative real‐time PCR using the same samples. Compared with 1‐g IL‐6, IL‐8, CD44, and OPN were significantly up‐regulated in AD cells but not in MCTSs, while ERK1/2, CAV2, TLN1, and CTGF were significantly down‐regulated in AD cells. Simultaneously, the expression of ERK2, IL‐6, CAV2, TLN1, and CTGF was reduced in MCTSs. IL‐6 protein expression and secretion mirrored its gene expression. Thus, we concluded that 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, J., Wehland, M., Pietsch, J., Schulz, H., Saar, K., Hübner, N., Eilles, C., Bauer, J., Abou‐El‐Ardat, K., Baatout, S., Ma, X., Infanger, M., Hemmersbach, R., Grimm, D. Gravity‐sensitive signaling drives 3‐dimensional formation of multicellular thyroid cancer spheroids. FASEB J. 26, 5124–5140 (2012). www.fasebj.org

Spheroid formation of human thyroid cancer cells in an automated culturing system during the Shenzhou-8 Space mission

Human follicular thyroid cancer cells were cultured in Space to investigate the impact of microgravity on 3D growth. For this purpose, we designed and constructed a cell container that can endure enhanced physical forces, is connected to fluid storage chambers, performs media changes and cell harvesting automatically and supports cell viability. The container consists of a cell suspension chamber, two reserve tanks for medium and fixative and a pump for fluid exchange. The selected materials proved durable, non-cytotoxic, and did not inactivate RNAlater. This container was operated automatically during the unmanned Shenzhou-8 Space mission. FTC-133 human follicular thyroid cancer cells were cultured in Space for 10 days. Culture medium was exchanged after 5 days in Space and the cells were fixed after 10 days. The experiment revealed a scaffold-free formation of extraordinary large three-dimensional aggregates by thyroid cancer cells with altered expression of EGF and CTGF genes under real microgravity.

Effects of basic fibroblast growth factor on endothelial cells under conditions of simulated microgravity

Fibroblast growth factors interact with appropriate endothelial cell (EC) surface receptors and initiate intracellular signal cascades, which participate in modulating blood vessel growth. EC, upon exposure to basic fibroblast growth factors (bFGFs) undergo profound functional alterations, which depend on their actual sensitivity and involve gene expression and de novo protein synthesis. We investigated the effects of bFGF on signaling pathways of EA.hy926 cells in different environments. EC were cultured under normal gravity (1 g) and simulated microgravity (µg) using a three‐dimensional (3D) clinostat. Microgravity induced early and late apoptosis, extracellular matrix proteins, endothelin‐1 (ET‐1) and TGF‐β1 expression. Microgravity reduced eNOS mRNA within 24 h. Moreover, a six‐ to eightfold higher amount of IL‐6 and IL‐8 was secreted within 24 h µg. In addition, microgravity induced a duplication of NF‐kappaB p50, while p65 was quadrupled. At 1 g, bFGF application (4 h) reduced ET‐1, TGF‐β1 and eNOS gene expression. After 24 h, bFGF enhanced fibronectin, VEGF, Flk‐1, Flt‐1, the release of IL‐6, IL‐8, and TGF‐β1. Furthermore, bFGF promoted apoptosis, reduced NFkB p50, but enhanced NFkB p65. After 4 h µg, bFGF decreased TGF‐β1, eNOS, and ET‐1 gene expression. After 24 h µg, bFGF elevated fibronectin, Flk‐1 and Flt‐1 protein, and reduced IL‐6 and IL‐8 compared with vehicle treated µg cultures. In µg, bFGF enhanced NF‐KappaB p50 by 50%, Bax by 25% and attenuated p65, activation of caspase‐3 and annexin V‐positive cells. bFGF differently changes intracellular signals in ECs depending whether it is applied under microgravity or normal gravity conditions. In microgravity, bFGF contributes to protect the EC from apoptosis. J. Cell. Biochem. 104: 1324–1341, 2008.

A proteomic approach to analysing spheroid formation of two human thyroid cell lines cultured on a random positioning machine

The human cell lines FTC‐133 and CGTH W‐1, both derived from patients with thyroid cancer, assemble to form different types of spheroids when cultured on a random positioning machine. In order to obtain a possible explanation for their distinguishable aggregation behaviour under equal culturing conditions, we evaluated a proteomic analysis emphasising cytoskeletal and membrane‐associated proteins. For this analysis, we treated the cells by ultrasound, which freed up some of the proteins into the supernatant but left some attached to the cell fragments. Both types of proteins were further separated by free‐flow IEF and SDS gel electrophoresis until their identity was determined by MS. The MS data revealed differences between the two cell lines with regard to various structural proteins such as vimentin, tubulins and actin. Interestingly, integrin α‐5 chains, myosin‐10 and filamin B were only found in FTC‐133 cells, while collagen was only detected in CGTH W‐1 cells. These analyses suggest that FTC‐133 cells express surface proteins that bind fibronectin, strengthening the three‐dimensional cell cohesion.

Application of free-flow IEF to identify protein candidates changing under microgravity conditions.

Using antibody‐related methods, we recently found that human thyroid cells express various proteins differently depending on whether they are cultured under normal gravity (1g) or simulated microgravity (s‐μg). In this study, we performed proteome analysis in order to identify more gravity‐sensitive thyroid proteins. Cells cultured under 1g or s‐μg conditions were sonicated. Proteins released into the supernatant and those remaining in the cell fragments were fractionated by free‐flow IEF. The fractions obtained were further separated by SDS‐gel electrophoresis. Selected gel pieces were excised and their proteins were determined by MS. A total of 235 different proteins were found. Out of 235 proteins, 37 appeared to be first identifications in human thyroid cells. Comparing SDS gel lanes of equally numbered free‐flow IEF fractions revealed similar patterns with a number of identical bands if proteins of a distinct cell line had been applied, irrespective of whether the cells had been cultured under 1g or s‐μg. Most of the identical band pairs contained identical proteins. However, the concentrations of some types of proteins were different within the two pieces of gel. Proteins that concentrated differently in such pieces of gel are considered as candidates for further investigations of gravitational sensitivity.