Your search keyword '"Hemmersbach, R"' showing total 15 results

1. Translation from Microgravity Research to Earth Application.

Author

Grimm D and Hemmersbach R

Subjects

Earth, Planet, Aerospace Medicine, Space Flight, Weightlessness

Abstract

The topic "Translation from Microgravity Research to Earth Application" comprises publications focusing on space life sciences, gravitational biology and space medicine [...].

Published

2022

2. In Prostate Cancer Cells Cytokines Are Early Responders to Gravitational Changes Occurring in Parabolic Flights.

Author

Schulz H, Dietrichs D, Wehland M, Corydon TJ, Hemmersbach R, Liemersdorf C, Melnik D, Hübner N, Saar K, Infanger M, and Grimm D

Subjects

Carcinogenesis, Cytokines genetics, Humans, Interleukin-6, Male, MicroRNAs genetics, Prostatic Neoplasms genetics, Space Flight, Weightlessness

Abstract

The high mortality in men with metastatic prostate cancer (PC) establishes the need for diagnostic optimization by new biomarkers. Mindful of the effect of real microgravity on metabolic pathways of carcinogenesis, we attended a parabolic flight (PF) mission to perform an experiment with the PC cell line PC-3, and submitted the resulting RNA to next generation sequencing (NGS) and quantitative real-time PCR (qPCR). After the first parabola, alterations of the F-actin cytoskeleton-like stress fibers and pseudopodia are visible. Moreover, numerous significant transcriptional changes are evident. We were able to identify a network of relevant PC cytokines and chemokines showing differential expression due to gravitational changes, particularly during the early flight phases. Together with differentially expressed regulatory lncRNAs and micro RNAs, we present a portfolio of 298 potential biomarkers. Via qPCR we identified IL6 and PIK3CB to be sensitive to vibration effects and hypergravity, respectively. Per NGS we detected five upregulated cytokines ( CCL2 , CXCL1 , IL6 , CXCL2 , CCL20 ), one zink finger protein ( TNFAIP3 ) and one glycoprotein ( ICAM1 ) related to c-REL signaling and thus relevant for carcinogenesis as well as inflammatory aspects. We found regulated miR-221 and the co-localized lncRNA MIR222HG induced by PF maneuvers. miR-221 is related to the PC-3 growth rate and MIR222HG is a known risk factor for glioma susceptibility. These findings in real microgravity may further improve our understanding of PC and contribute to the development of new diagnostic tools.

Published

2022

3. Alterations of the cytoskeleton in human cells in space proved by life-cell imaging.

Author

Corydon TJ, Kopp S, Wehland M, Braun M, Schütte A, Mayer T, Hülsing T, Oltmann H, Schmitz B, Hemmersbach R, and Grimm D

Subjects

Actins metabolism, Cell Line, Cytoskeleton genetics, Gene Expression, Humans, Microscopy, Fluorescence instrumentation, Microscopy, Fluorescence methods, Cytoskeleton metabolism, Molecular Imaging, Space Flight, Weightlessness

Abstract

Microgravity induces changes in the cytoskeleton. This might have an impact on cells and organs of humans in space. Unfortunately, studies of cytoskeletal changes in microgravity reported so far are obligatorily based on the analysis of fixed cells exposed to microgravity during a parabolic flight campaign (PFC). This study focuses on the development of a compact fluorescence microscope (FLUMIAS) for fast live-cell imaging under real microgravity. It demonstrates the application of the instrument for on-board analysis of cytoskeletal changes in FTC-133 cancer cells expressing the Lifeact-GFP marker protein for the visualization of F-actin during the 24(th) DLR PFC and TEXUS 52 rocket mission. Although vibration is an inevitable part of parabolic flight maneuvers, we successfully for the first time report life-cell cytoskeleton imaging during microgravity, and gene expression analysis after the 31(st) parabola showing a clear up-regulation of cytoskeletal genes. Notably, during the rocket flight the FLUMIAS microscope reveals significant alterations of the cytoskeleton related to microgravity. Our findings clearly demonstrate the applicability of the FLUMIAS microscope for life-cell imaging during microgravity, rendering it an important technological advance in live-cell imaging when dissecting protein localization.

Published

2016

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

Author

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, Waßer K, Grosse J, Infanger M, and Grimm D

Subjects

Cell Line, Tumor, Extracellular Matrix genetics, Extracellular Matrix metabolism, Gene Expression Regulation, Neoplastic, Humans, Microarray Analysis, Polymerase Chain Reaction, Thyroid Neoplasms genetics, Space Flight, Thyroid Neoplasms metabolism, Weightlessness

Abstract

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.

Published

2014

5. The impact of altered gravity and vibration on endothelial cells during a parabolic flight.

Author

Wehland M, Ma X, Braun M, Hauslage J, Hemmersbach R, Bauer J, Grosse J, Infanger M, and Grimm D

Subjects

Actins metabolism, Apoptosis, Cell Cycle Checkpoints, Cell Line, Cytoskeletal Proteins metabolism, Cytoskeleton metabolism, Down-Regulation, Endothelial Cells cytology, Extracellular Matrix metabolism, Humans, Microfilament Proteins metabolism, Neovascularization, Physiologic, Tubulin metabolism, Up-Regulation, Endothelial Cells metabolism, Gravity, Altered, Space Flight, Vibration

Abstract

Background: Endothelial cells (EC) cultured under altered gravity conditions show a cytoskeletal disorganization and differential gene expression (short-term effects), as well as apoptosis in adherently growing EC or formation of tubular 3D structures (long-term effects)., Methods: Investigating short-term effects of real microgravity, we exposed EC to parabolic flight maneuvers and analysed them on both protein and transcriptional level. The effects of hypergravity and vibration were studied separately., Results: Pan-actin and tubulin proteins were elevated by vibration and down-regulated by hypergravity. β-Actin was reduced by vibration. Moesin protein was reduced by both vibration and hypergravity, ezrin potein was strongly elevated under vibration. Gene expression of ACTB, CCND1, CDC6, CDKN1A, VEGFA, FLK-1, EZR, ITBG1, OPN, CASP3, CASP8, ANXA2, and BIRC5 was reduced under vibration. With the exception of CCNA2, CCND1, MSN, RDX, OPN, BIRC5, and ACTB all investigated genes were downregulated by hypergravity. After one parabola (P) CCNA2, CCND1, CDC6, CDKN1A, EZR, MSN, OPN, VEGFA, CASP3, CASP8, ANXA1, ANXA2, and BIRC5 were up-, while FLK1 was downregulated. EZR, MSN, OPN, ANXA2, and BIRC5 were upregulated after 31P., Conclusions: Genes of the cytoskeleton, angiogenesis, extracellular matrix, apoptosis, and cell cycle regulation were affected by parabolic flight maneuvers. We show that the microgravity stimulus is stronger than hypergravity/vibration., (Copyright © 2013 S. Karger AG, Basel.)

Published

2013

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

Author

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, and Grimm D

Subjects

Base Sequence, Caveolae metabolism, Cell Line, Cell Survival, Cytoskeleton genetics, Cytoskeleton metabolism, DNA Primers genetics, Endothelial Cells cytology, Extracellular Matrix genetics, Extracellular Matrix metabolism, Humans, Microtubules genetics, Microtubules metabolism, Neovascularization, Physiologic genetics, Oligonucleotide Array Sequence Analysis, RNA, Messenger genetics, RNA, Messenger metabolism, Real-Time Polymerase Chain Reaction, Signal Transduction genetics, Time Factors, Endothelial Cells metabolism, Gene Expression Profiling, Space Flight, Weightlessness adverse effects

Abstract

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.

Published

2012

7. Graviresponses of Paramecium biaurelia during parabolic flights.

Author

Krause M, Bräucker R, and Hemmersbach R

Subjects

Acceleration, Animals, Cell Movement, Cell Polarity, Hypergravity, Reproducibility of Results, Sensory Thresholds, Time Factors, Weightlessness, Gravitation, Gravity Sensing, Mechanotransduction, Cellular, Paramecium physiology, Space Flight methods

Abstract

The thresholds of graviorientation and gravikinesis in Paramecium biaurelia were investigated during the 5th DLR (German Aerospace Center) parabolic-flight campaign at Bordeaux in June 2003. Parabolic flights are a useful tool for the investigation of swimming behaviour in protists at different accelerations. At normal gravity (1 g) and hypergravity (1 g to 1.8 g), precision of orientation and locomotion rates depend linearly on the applied acceleration as seen in earlier centrifuge experiments. After transition from hypergravity to decreased gravity (minimal residual acceleration of <10(-2) g), graviorientation as well as gravikinesis show a full relaxation with different kinetics. The use of twelve independent cell samples per flight guarantees high data numbers and secures the statistical significance of the obtained data. The relatively slow change of acceleration between periods of microgravity and hypergravity (0.4 g/s) enabled us to determine the thresholds of graviorientation at 0.6 g and of gravikinesis at 0.4 g. The gravity-unrelated propulsion rate of the sample was found to be 874 microm/s, exceeding the locomotion rate of horizontally swimming cells (855 microm/s). The measured thresholds of graviresponses were compared with data obtained from earlier centrifuge experiments on the sounding rocket Maxus-2. Measured thresholds of gravireactions indicate that small energies, close to the thermal noise level, are sufficient for the gravitransduction process. Data from earlier hypergravity experiments demonstrate that mechanosensitive ion channels are functioning over a relative wide range of acceleration. From this, we may speculate that gravireceptor channels derive from mechanoreceptor channels.

Published

2006

8. Graviperception in ciliates: steps in the transduction chain.

Author

Hemmersbach R, Krause M, Bräucker R, and Ivanova K

Subjects

Animals, Behavior, Animal, Calcium Channels physiology, Electrophysiology, Hypergravity, Mechanoreceptors, Paramecium physiology, Potassium Channels physiology, Swimming, Ciliophora physiology, Gravity Sensing physiology, Signal Transduction physiology, Space Flight, Weightlessness

Abstract

Ciliates represent suitable model systems to study the mechanisms of graviperception and signal transduction as they show clear gravity-induced behavioural responses (gravitaxis and gravikinesis). The cytoplasm seems to act as a "statolith" stimulating mechanosensitive ion channels in the cell membrane. In order to test this hypothesis, electrophysiological studies with Stylonychia mytilus were performed, revealing the proposed changes (de- or hyperpolarization) depending on the cell's spatial orientation. The behaviour of Paramecium and Stylonychia was also analyzed during variable acceleration conditions of parabolic flights (5th German Parabolic Flight Campaign, 2003). The corresponding data confirm the relaxation of the graviresponses in microgravity as well as the existence of thresholds of graviresponses, which are found to be in the range of 0.4xg (gravikinesis) and 0.6xg (gravitaxis)., (c2005 COSPAR. Published by Elsevier Ltd. All rights reserved.)

Published

2005

9. Graviorientation in protists and plants.

Author

Hemmersbach R, Volkmann D, and Hader DP

Subjects

Animals, Eukaryota, Hypergravity, Plants, Signal Transduction physiology, Weightlessness Simulation, Gravitation, Gravitropism physiology, Gravity Sensing physiology, Orientation physiology, Space Flight, Weightlessness

Abstract

Gravitaxis, gravikinesis, and gravitropism are different graviresponses found in protists and plants. The phenomena have been intensively studied under variable stimulations ranging from microgravity to hypergravity. A huge amount of information is now available, e.g. about the time course of these events, their adaptation capacity, thresholds, and interaction between gravity and other environmental stimuli. There is growing evidence that a pure physical mechanism can be excluded for orientation of protists in the gravity field. Similarly, a physiological signal transduction chain has been postulated in plants. Current investigations focus on the question whether gravity is perceived by intracellular gravireceptors (e.g. the Muller organelle of the ciliate Loxodes, barium sulfate vacuoles in Chara rhizoids or starch statoliths in higher plants) or whether the whole cell acts as a sedimenting body exerting pressure on the lower membrane. Behavioral studies in density adjusted media, effects of inhibitors of mechano-sensitive ion channels or manipulations of the proposed gravireceptor structures revealed that both mechanisms have been developed in protists and plants. The threshold values for graviresponses indicate that even 10% of the normal gravitational field can be detected, which demands a focusing and amplifying system such as the cytoskeleton and second messengers.

Published

1999

10. Putative graviperception mechanisms of protists.

Author

Block I, Freiberger N, Gavrilova O, and Hemmersbach R

Subjects

Animals, Ciliophora ultrastructure, Culture Media, Locomotion physiology, Motor Activity physiology, Organelles physiology, Paramecium, Physarum, Swimming, Tetrahymena, Viscosity, Ciliophora physiology, Cold Temperature, Gravity Sensing physiology, Orientation physiology, Space Flight, Weightlessness

Abstract

Many (if not all) free-living cells use the gravity vector for their spatial orientation (gravitaxis). Additional responses may include gravikinesis as well as changes in morphological and physiological parameters. Though using essentially different modes of locomotion, ameboid and ciliated cells seem to rely on common fundamental graviperception mechanisms. Uniquely in the ciliate family Loxodidae a specialized intracellular gravireceptor organelle has been developed, whereas in all other cells common cell structures seem to be responsible for gravisensing. Changes in direction or magnitude of acceleration (from 0 to 5 g) as well as experiments in density-adjusted media strongly indicate that either the whole cytoplasm or dense organelles like nuclei act as statoliths and open directly or via cytoskeletal elements mechano-sensitive ion channels in the cell membrane. A recent spaceflight experiment (S/MM-06) demonstrated that prolonged (9 d) actual weightlessness did not affect the ability of Loxodes to respond to acceleration stimuli. However, prolonged cooling (> or = l4 d, 4-10 degrees C) destroyed the ability for gravitactic orientation of Paramecium. This may reflect a profound effect either on the gravireceptor itself or on the gravity-signal processing. In gravity signalling the ubiquitous second messenger cAMP may be involved in acceleration-stimulus transduction.

Published

1999

11. Gravisensitivity of cells of several types.

Author

Tairbekov M, Hemmersbach R, and Gavrilova O

Subjects

Animals, Brassica, Cell Adhesion, Cells, Cultured, Centrifugation, Daucus carota, Eukaryota growth & development, Fibroblasts, Humans, Mice, Protoplasts metabolism, Cell Physiological Phenomena, Eukaryota physiology, Gravity Sensing physiology, Hypergravity, Space Flight, Weightlessness

Published

1998

12. Graviresponses in Paramecium biaurelia under different accelerations: studies on the ground and in space.

Author

Hemmersbach R, Voormanns R, and Hader DP

Subjects

Acceleration, Animals, Centrifugation instrumentation, Gravitation, Image Processing, Computer-Assisted, Microscopy instrumentation, Motor Activity, Swimming, Gravity Sensing physiology, Hypergravity, Paramecium, Rotation, Space Flight, Weightlessness

Abstract

Behavioural responses to different accelerations below 1 g and up to 5 g were investigated in Paramecium biaurelia by using a centrifuge microscope on Earth and in space during a recent space flight. Increased stimulation (hypergravity) enhanced the negative gravitactic and the gravikinetic responses in Paramecium biaurelia within seconds. Cells did not adapt to altered gravitational conditions. Repetitive stimulation did not change the graviresponses. The minimum acceleration found to induce gravitaxis was between 0.16 and 0.3 g.

Published

1996

13. Graviperception in the flagellate Euglena gracilis during a shuttle space flight.

Author

Häder DP, Rosum A, Schäfer J, and Hemmersbach R

Subjects

Animals, Centrifugation, Image Processing, Computer-Assisted, Movement physiology, Swimming, Acceleration, Euglena gracilis physiology, Gravity Sensing physiology, Hypergravity, Space Flight, Weightlessness

Abstract

During a recent space flight, gravitaxis of the unicellular photosynthetic flagellate, Euglena gracilis, was studied on board of the American shuttle Columbia. Accelerations were varied between 0 and 1.5 x g using a slow rotating centrifuge microscope (NIZEMI). The cells showed a sigmoidal response curve for the dependence of the precision of gravitaxis on acceleration which is indicative of the involvement of an active, physiological gravireceptor with a threshold at g-values < or = 0.16 x g and a saturation at g-values > or = 1 x g. No adaptation to microgravity was found during the prolonged space mission. After return the cells showed a normal gravitactic behavior at 1 x g. Since the cells are heavier than water, their swimming velocity is affected by sedimentation. The velocity distribution at different accelerations closely follows Stokes' law for sedimentation indicating that, in contrast to the ciliate Paramecium, E. gracilis, does not show any gravikinesis.

Published

1996

14. Influence of accelerations on the spatial orientation of Loxodes and Paramecium.

Author

Hemmersbach R, Voormanns R, Briegleb W, Rieder N, and Häder DP

Subjects

Animals, Cell Culture Techniques methods, Centrifugation, Image Processing, Computer-Assisted, Movement, Swimming, Acceleration, Ciliophora physiology, Gravity Sensing physiology, Paramecium physiology, Space Flight, Weightlessness

Abstract

The gravitactic ciliates Paramecium and Loxodes were cultivated for 15 days in space during the IML-2 spacelab mission. At dedicated times their behavioral responses to different accelerations between 10(-3) x g and 1.5 x g were investigated by using a slow rotating centrifuge microscope (NIZEMI). The threshold for gravitaxis of Paramecium was found to be at > 0.16 x g and < or = 0.3 x g. No adaptation of Paramecium to the conditions of weightlessness was observed over the duration of 15 days. Loxodes showed no graviresponses to increasing accelerations, though it demonstrated gravitaxis after return to earth.

Published

1996

15. Gravitaxis in the flagellate Euglena gracilis is controlled by an active gravireceptor.

Author

Hader DP, Rosum A, Schafer J, and Hemmersbach R

Subjects

Acceleration, Animals, Centrifugation instrumentation, Gravity, Altered, Image Processing, Computer-Assisted, Microscopy instrumentation, Rotation, Swimming, Euglena gracilis physiology, Gravity Sensing physiology, Hypergravity, Motor Activity physiology, Space Flight, Weightlessness

Abstract

Gravitactic orientation was investigated in the unicellular photosynthetic flagellate, Euglena gracilis, under different accelerations between 0 and 1.5 x g during a recent space flight on board the American shuttle Columbia. The threshold for gravitaxis was found at < or = 0.16 x g. Above the threshold the precision of orientation increased with acceleration in a sigmoidal fashion and reached saturation at about 0.32 x g, a behavior typical for physiological receptors. At accelerations above the saturation point the cells were closely aligned with the gravity vector (negative gravitaxis) and deviated more and more as the acceleration decreased. Obviously the gravireceptor responds to an error signal that elicits a course correction, again indicating the involvement of an active physiological gravireceptor. No adaptation of the cells to the conditions of weightlessness could be observed over the duration of the space mission (12 days). After landing, the cells showed a normal gravitactic behavior at 1 x g.

Published

1995