During the entire evolution of life on Earth, the phylogenetic as well as the individual developm... more During the entire evolution of life on Earth, the phylogenetic as well as the individual development of all organisms took place under constant gravity conditions, against which they achieved specific countermeasures for compensation and adaptation. On the one side, gravity represents a factor of physical restriction, which compelled the ancestors of all extant living beings to develop basic achievements to counter the gravitational force (e.g., elements of statics like any kind of skeleton--from actin to bone--to overcome gravity enforced size limits or to keep form). On the other side, already early forms of life possibly used gravity as an appropriate cue for orientation and postural control, since it is continuously present and has a fixed direction. Due to such a thorough adaptation to the Earthly gravity vector, both orientation behaviour as well as the ontogenetic development of animals is impaired, when they have to experience altered gravity (delta g; i.e., hyper- or microgravity). On this background, it is still an open question to which extent delta g affects the normal individual development, either on the systemic level of the whole organism or on the level of individual organs or even single cells. The present review provides information on these questions, focusing on developing fish as model systems. Special emphasis is being laid on the effect of delta g on the developing brain and vestibular system, comprising investigations on behaviour and plastic reactivities of the brain and inner ear. Moreover, clues and insights into the possible basic causes of space motion sickness-phenomena (SMS; a kinetosis) are provided. Overall, the results speak in favour of the following concept: short-term altered gravity (< or = 1 day) can induce transitional aberrant behaviour due to malfunctions of the inner ear, originating from asymmetric otoliths or, generally, from a mismatch between canal and otolith afferents. The vanishing aberrant behaviour is due to a reweighing of sensory inputs and neurovestibular compensation, probably on bioelectrical basis. During long-term altered gravity (several days and more), step by step neuroplastic reactivities on molecular basis (i.e., molecular facilitation) in the brain and inner ears obviously activate feedback mechanisms between the CNS and the vestibular organs for the regain of normal behaviour. Mainly, the following areas of research with animals at altered gravity need to be addressed in the future: (1) Maintenance of animals through two complete life cycles in the space environment (developmental deficiencies?). (2) Investigation of the peripheral and central vestibular system by ground-based studies (mutants, hypergravity experiments...), focusing on plasticity in developing animals as well as in adults. (3) Investigation of the effect of microgravity during critical developmental periods (imprinting phase for graviperception?). Answers to these questions may be of crucial interest for basic gravitational research.
Stato- or otoliths are calcified structures in the organ of balance and equilibrium of vertebrate... more Stato- or otoliths are calcified structures in the organ of balance and equilibrium of vertebrates, the inner ear, where they enhance its sensitivity to gravity. The compact otoliths of fish are composed of the calcium carbonate polymorph aragonite and a small fraction of organic molecules. The latter form a protein skeleton which determines the morphology of an otolith as well as its crystal lattice structure. This short review addresses findings according to which the brain obviously plays a prominent role in regulating the mineralisation of fish otoliths and depends on the gravity vector. Overall, otolith mineralisation has thus been identified to be a unique, neuronally guided biomineralisation process. The following is a hypothetical model for regulation of calcification by efferent vestibular neurons: (1) release of calcium at tight junctions in the macular epithelia, (2) macular carbonic anhydrase activity (which in turn is responsible for carbonate deposition), (3) chemical composition of matrix proteins. The rationale and evidence that support this model are discussed.
A simple technique is introduced to achieve symmetrically oriented frozen sections of small speci... more A simple technique is introduced to achieve symmetrically oriented frozen sections of small specimens such as young fish or frog larvae. Small samples are especially difficult to orient if they are already frozen to the chuck in a freezing microtome. Orientation of the sample in a mold filled with embedding medium prior to freezing permits sectioning as well as easy labeling and storage of the specimens. The use of a stereo microscope during orientation is optional.
ABSTRACT It has been shown earlier that hypergravity slows down inner ear otolith growth in devel... more ABSTRACT It has been shown earlier that hypergravity slows down inner ear otolith growth in developing fish as an adaptation towards increased environmental gravity. Suggesting that otolith growth is regulated by the central nervous system, thus adjusting otolithic weight to produce a test mass, applying functional weightlessness should yield an opposite effect, i.e. larger than normal otoliths. Therefore, larval siblings of cichlid fish (Oreochromis mossambicus) were housed for 7 days in a submersed, two-dimensional clinostat, which provided a residual gravity of approximately 0.007g. After the experiment, otoliths were dissected and their size (area grown during the experiment) was determined. Maintenance in the clinostat resulted in significantly larger utricular otoliths (lapilli, involved in graviperception). There were no statistical significant differences regarding saccular otoliths obtained (sagittae, involved in transmitting linear acceleration and, especially, in the hearing process). These results indicated, that the animals had in fact received functional weightlessness. In line and contrasting results on the otoliths of other teleost species kept at actual microgravity (spaceflight) or within rotating wall vessels are discussed.
Previous investigations revealed that the growth of fish inner ear otoliths (otolith size and cal... more Previous investigations revealed that the growth of fish inner ear otoliths (otolith size and calcium incorporation) depends on the amplitude and the direction of gravity, suggesting the existence of a (negative) feedback mechanism. In a search for the regulating unit, the vestibular nerve was unilaterally transected in neonatal swordtail fish (Xiphophorus helleri) which were subsequently incubated in the calcium-tracer alizarin-complexone. Calcium incorporation and thus otolith growth ceased on the operated head sides, indicating that the brain is significantly involved in regulating otolith growth.
The gravity-dependent behavior of Paramecium biaurelia and Euglena gracilis have previously been ... more The gravity-dependent behavior of Paramecium biaurelia and Euglena gracilis have previously been studied on ground and in real microgravity. To validate whether high magnetic field exposure indeed provides a ground-based facility to mimic functional weightlessness, as has been suggested earlier, both cell types were observed during exposure in a strong homogeneous magnetic field (up to 30 T) and a strong magnetic field gradient. While swimming, Paramecium cells were aligned along the magnetic field lines; orientation of Euglena was perpendicular, demonstrating that the magnetic field determines the orientation and thus prevents the organisms from the random swimming known to occur in real microgravity. Exposing Astasia longa, a flagellate that is closely related to Euglena but lacks chloroplasts and the photoreceptor, as well as the chloroplast-free mutant E. gracilis 1F, to a high magnetic field revealed no reorientation to the perpendicular direction as in the case of wild-type E. gracilis, indicating the existence of an anisotropic structure (chloroplasts) that determines the direction of passive orientation. Immobilized Euglena and Paramecium cells could not be levitated even in the highest available magnetic field gradient as sedimentation persisted with little impact of the field on the sedimentation velocities. We conclude that magnetic fields are not suited as a microgravity simulation for gravitactic unicellular organisms due to the strong effect of the magnetic field itself, which masks the effects known from experiments in real microgravity.
Stimulus dependence is a general feature of developing sensory systems. It has been shown earlier... more Stimulus dependence is a general feature of developing sensory systems. It has been shown earlier that the growth of otoliths of late-stage Cichlid fish (Oreochromis mossambicus) and Zebrafish (Danio rerio) was slowed down by hypergravity, whereas microgravity during spaceflight yielded an opposite effect, i.e., larger than 1 g otoliths, in Swordtail (Xiphophorus helleri) late-stage embryos. Using ground-based techniques to apply simulated weightlessness, long-term clinorotation (exposure on a fast-rotating clinostat with one axis of rotation for 7 days) led to larger than 1 g otoliths in late-stage Cichlid fish, which is fully in line with the results obtained on Swordtails from spaceflight. Hitherto, early-staged fish have not yet been subjected to (simulated or real) long-term (i.e., more than 3 or 4 days) weightlessness to investigate otolith growth. The present study was carried out in order to fill this gap. Therefore, we subjected Zebrafish at a somite-stage to Wall Vessel Rotation (WVR; a method regarded to provide simulated weightlessness), when the anlage of the inner ear already is present (10 h post fertilisation, hpf). Siblings were maintained under WVR for 3, 6, 9 and 12 days. Further short-term experiments (3 days) were carried out on 10 hpf animals as well as on very early larvae (1 K cell stage, 3 hpf) at two different rotation speeds. WVR (both rotation speeds) had no effect on otolith biogenesis in both stages as all otoliths were present after the experiments. In comparison with 1 g controls, WVR had significantly increased otolith growth (normalised by fish length) after 3 and 6 days of exposure, but significant differences of otolith growth between experimental animals and controls were not found after 9 and 12 days. In conclusion, WVR (at least within a time-span of exposure of up to 6 days) brings, comparable to the situation in real microgravity, a kind of feedback mechanism into action, resulting in larger otoliths. Later, possible effects of WVR might be overruled by normal allometric growth since the action of the feedback mechanism may be discontinued in the course of an adaptation.
In view of space exploration and long-term satellite missions, a new generation of multi-modular,... more In view of space exploration and long-term satellite missions, a new generation of multi-modular, multi-organism bioregenerative life support system with different experimental units (Modul.LES) is planned, and subunits are under construction. Modul.LES will be managed via telemetry and remote control and therefore is a fully automated experimental platform for different kinds of investigations. After several forerunner projects like AquaCells (2005), C.E.B.A.S. (1998, 2003) or Aquahab (OHB-System AG the Oreochromis Mossambicus Eu-glena Gracilis Aquatic Habitat (OmegaHab) was successfully flown in 2007 in course of the FOTON-M3 Mission. It was a 3 chamber controlled life support system (CLSS), compris-ing a bioreactor with the green algae Euglena gracilis, a fish chamber with larval cichlid fish Oreochromis mossambicus and a filter chamber with biodegrading bacteria. The sensory super-vision of housekeeping management was registered and controlled by telemetry. Additionally, all scientific data and videos of the organisms aboard were stored and sequentially transmitted to relay stations. Based on the effective performance of OmegaHab, this system was chosen for a reflight on Bion-M1 in 2012. As Bion-M1 is a long term mission (appr. 4 weeks), this CLSS (OmegaHab-XP) has to be redesigned and refurbished with enhanced performance. The number of chambers has been increased from 3 to 4: an algae bioreactor, a fish tank for adult and larval fish (hatchery inserted), a nutrition chamber with higher plants and crustaceans and a filter chamber. The OmegaHab-XP is a full automated system with an extended satellite downlink for video monitoring and housekeeping data acquisition, but no uplink for remote control. OmegaHab-XP provides numerous physical and chemical parameters which will be monitored regarding the state of the biological processes and thus enables the automated con-trol aboard. Besides the two basic parameters oxygen content and temperature, products of the nitrogene-cycle (concentration of ammonium, nitrite and nitrate) as well as conductivity will be measured. For this long term mission an external food supply as has been used with OmegaHab is not sufficient and, therefore, in OmegaHab-XP a nutrition compartment has been added. OmegaHab-XP is a multi-trophic system, designed as a basic concept and test-bed for future multi-modular platform Modul.LES. OmegaHab-XP comprises four different trophic lev-els. The algae experimental container is used as CO2 / O2 exchanger and serves as oxygen source for all heterotrophic organisms. The fish compartment is divided into two areas -namely a hatchery (larval cichlid fish Oreochromis mossambicus) and a fish tank (subadult cichlids). Once the yolk sack is resorbed (stage 19) the juvenile fish are capable to leave the hatchery via escapements into the fish compartment. In order to enable the development of fish from larval yolk sack stages to subadult fish a nutrition compartment is enclosed: In this nutrition compartment the crustacean Hyalella azteca will reproduce and build up a stable population by feeding on the Rigid Hornwort (Ceratophyllum demersum). Younger crustaceans can cross the barrier to the fish tank and can serve as nutrition for fully developed subadult fish. Waste products of all organisms will be assimilated by the water snail Biomphalaria glabrata. The scientific concept of Modul.LES is to establish a multidisciplinary framework of scientists and areas of scientific research (biophysics, molecular-organismic biology, biochemistry etc.) to analyze impacts of g on plants and animals.
ABSTRACT Developing cichlid fish (Oreochromis mossambicus) were subjected to microgravity (spacef... more ABSTRACT Developing cichlid fish (Oreochromis mossambicus) were subjected to microgravity (spaceflight) and were analysed in comparison to direct control batches (1g on orbit, 1g on ground and 1.4g hyper-gravity in the reference centrifuge on ground) employing quantitative behavioral, histochemical and electronmicroscopic-cytochemical techniques. After the experiment, the microgravity animals performed slow and disoriented movements as compared to 1g controls for some 5 days. Histochemically demonstrated succinate dehydrogenase reactivity, a marker for metabolic activity, was increased from microgravity via 1 g to hypergravity in vestibulum-related brain nuclei, whereas no alterations were found regarding non-vestibular nuclei. On the electronmicroscopical level, cytochrome oxidase activity was augmented in a vestibular nucleus according to the strength of the acceleration provided. Regarding the inner ear epithelia, weightlessness resulted in a decrease of CO reactivity in the gravity related utricle, whereas in the saccule, no differences were found. The results are discussed in the context with our non-spaceflight related gravity experiments.
Synapse counts were undertaken by conventional electron microscopy in primary vestibular integrat... more Synapse counts were undertaken by conventional electron microscopy in primary vestibular integration centers, (i.e. nucleus descendens and nucleus magnocellularis of the brainstem area octavolateralis) and in the diencephalic visual nucleus corticalis of spaceflown neonate swordtail fish Xiphophorus helleri as well as in 1 g control siblings. Spaceflight (16 days microgravity, (microg), STS-90 Neurolab Mission) yielded an increase in synaptic contacts within the vestibular nucleus descendens indicating that lack of input resulted in compensation processes. No effect of microg, however, was observed in the visual nucleus corticalis and in the vestibular nucleus magnocellularis which is situated in the close vicinity of the nucleus descendens. In contrast to the latter, the nucleus magnocellularis does not receive exclusively vestibular input, but inputs from the lateral line as well, possibly providing sufficient input at microgravity.
During the entire evolution of life on Earth, the phylogenetic as well as the individual developm... more During the entire evolution of life on Earth, the phylogenetic as well as the individual development of all organisms took place under constant gravity conditions, against which they achieved specific countermeasures for compensation and adaptation. On the one side, gravity represents a factor of physical restriction, which compelled the ancestors of all extant living beings to develop basic achievements to counter the gravitational force (e.g., elements of statics like any kind of skeleton--from actin to bone--to overcome gravity enforced size limits or to keep form). On the other side, already early forms of life possibly used gravity as an appropriate cue for orientation and postural control, since it is continuously present and has a fixed direction. Due to such a thorough adaptation to the Earthly gravity vector, both orientation behaviour as well as the ontogenetic development of animals is impaired, when they have to experience altered gravity (delta g; i.e., hyper- or microgravity). On this background, it is still an open question to which extent delta g affects the normal individual development, either on the systemic level of the whole organism or on the level of individual organs or even single cells. The present review provides information on these questions, focusing on developing fish as model systems. Special emphasis is being laid on the effect of delta g on the developing brain and vestibular system, comprising investigations on behaviour and plastic reactivities of the brain and inner ear. Moreover, clues and insights into the possible basic causes of space motion sickness-phenomena (SMS; a kinetosis) are provided. Overall, the results speak in favour of the following concept: short-term altered gravity (< or = 1 day) can induce transitional aberrant behaviour due to malfunctions of the inner ear, originating from asymmetric otoliths or, generally, from a mismatch between canal and otolith afferents. The vanishing aberrant behaviour is due to a reweighing of sensory inputs and neurovestibular compensation, probably on bioelectrical basis. During long-term altered gravity (several days and more), step by step neuroplastic reactivities on molecular basis (i.e., molecular facilitation) in the brain and inner ears obviously activate feedback mechanisms between the CNS and the vestibular organs for the regain of normal behaviour. Mainly, the following areas of research with animals at altered gravity need to be addressed in the future: (1) Maintenance of animals through two complete life cycles in the space environment (developmental deficiencies?). (2) Investigation of the peripheral and central vestibular system by ground-based studies (mutants, hypergravity experiments...), focusing on plasticity in developing animals as well as in adults. (3) Investigation of the effect of microgravity during critical developmental periods (imprinting phase for graviperception?). Answers to these questions may be of crucial interest for basic gravitational research.
Stato- or otoliths are calcified structures in the organ of balance and equilibrium of vertebrate... more Stato- or otoliths are calcified structures in the organ of balance and equilibrium of vertebrates, the inner ear, where they enhance its sensitivity to gravity. The compact otoliths of fish are composed of the calcium carbonate polymorph aragonite and a small fraction of organic molecules. The latter form a protein skeleton which determines the morphology of an otolith as well as its crystal lattice structure. This short review addresses findings according to which the brain obviously plays a prominent role in regulating the mineralisation of fish otoliths and depends on the gravity vector. Overall, otolith mineralisation has thus been identified to be a unique, neuronally guided biomineralisation process. The following is a hypothetical model for regulation of calcification by efferent vestibular neurons: (1) release of calcium at tight junctions in the macular epithelia, (2) macular carbonic anhydrase activity (which in turn is responsible for carbonate deposition), (3) chemical composition of matrix proteins. The rationale and evidence that support this model are discussed.
A simple technique is introduced to achieve symmetrically oriented frozen sections of small speci... more A simple technique is introduced to achieve symmetrically oriented frozen sections of small specimens such as young fish or frog larvae. Small samples are especially difficult to orient if they are already frozen to the chuck in a freezing microtome. Orientation of the sample in a mold filled with embedding medium prior to freezing permits sectioning as well as easy labeling and storage of the specimens. The use of a stereo microscope during orientation is optional.
ABSTRACT It has been shown earlier that hypergravity slows down inner ear otolith growth in devel... more ABSTRACT It has been shown earlier that hypergravity slows down inner ear otolith growth in developing fish as an adaptation towards increased environmental gravity. Suggesting that otolith growth is regulated by the central nervous system, thus adjusting otolithic weight to produce a test mass, applying functional weightlessness should yield an opposite effect, i.e. larger than normal otoliths. Therefore, larval siblings of cichlid fish (Oreochromis mossambicus) were housed for 7 days in a submersed, two-dimensional clinostat, which provided a residual gravity of approximately 0.007g. After the experiment, otoliths were dissected and their size (area grown during the experiment) was determined. Maintenance in the clinostat resulted in significantly larger utricular otoliths (lapilli, involved in graviperception). There were no statistical significant differences regarding saccular otoliths obtained (sagittae, involved in transmitting linear acceleration and, especially, in the hearing process). These results indicated, that the animals had in fact received functional weightlessness. In line and contrasting results on the otoliths of other teleost species kept at actual microgravity (spaceflight) or within rotating wall vessels are discussed.
Previous investigations revealed that the growth of fish inner ear otoliths (otolith size and cal... more Previous investigations revealed that the growth of fish inner ear otoliths (otolith size and calcium incorporation) depends on the amplitude and the direction of gravity, suggesting the existence of a (negative) feedback mechanism. In a search for the regulating unit, the vestibular nerve was unilaterally transected in neonatal swordtail fish (Xiphophorus helleri) which were subsequently incubated in the calcium-tracer alizarin-complexone. Calcium incorporation and thus otolith growth ceased on the operated head sides, indicating that the brain is significantly involved in regulating otolith growth.
The gravity-dependent behavior of Paramecium biaurelia and Euglena gracilis have previously been ... more The gravity-dependent behavior of Paramecium biaurelia and Euglena gracilis have previously been studied on ground and in real microgravity. To validate whether high magnetic field exposure indeed provides a ground-based facility to mimic functional weightlessness, as has been suggested earlier, both cell types were observed during exposure in a strong homogeneous magnetic field (up to 30 T) and a strong magnetic field gradient. While swimming, Paramecium cells were aligned along the magnetic field lines; orientation of Euglena was perpendicular, demonstrating that the magnetic field determines the orientation and thus prevents the organisms from the random swimming known to occur in real microgravity. Exposing Astasia longa, a flagellate that is closely related to Euglena but lacks chloroplasts and the photoreceptor, as well as the chloroplast-free mutant E. gracilis 1F, to a high magnetic field revealed no reorientation to the perpendicular direction as in the case of wild-type E. gracilis, indicating the existence of an anisotropic structure (chloroplasts) that determines the direction of passive orientation. Immobilized Euglena and Paramecium cells could not be levitated even in the highest available magnetic field gradient as sedimentation persisted with little impact of the field on the sedimentation velocities. We conclude that magnetic fields are not suited as a microgravity simulation for gravitactic unicellular organisms due to the strong effect of the magnetic field itself, which masks the effects known from experiments in real microgravity.
Stimulus dependence is a general feature of developing sensory systems. It has been shown earlier... more Stimulus dependence is a general feature of developing sensory systems. It has been shown earlier that the growth of otoliths of late-stage Cichlid fish (Oreochromis mossambicus) and Zebrafish (Danio rerio) was slowed down by hypergravity, whereas microgravity during spaceflight yielded an opposite effect, i.e., larger than 1 g otoliths, in Swordtail (Xiphophorus helleri) late-stage embryos. Using ground-based techniques to apply simulated weightlessness, long-term clinorotation (exposure on a fast-rotating clinostat with one axis of rotation for 7 days) led to larger than 1 g otoliths in late-stage Cichlid fish, which is fully in line with the results obtained on Swordtails from spaceflight. Hitherto, early-staged fish have not yet been subjected to (simulated or real) long-term (i.e., more than 3 or 4 days) weightlessness to investigate otolith growth. The present study was carried out in order to fill this gap. Therefore, we subjected Zebrafish at a somite-stage to Wall Vessel Rotation (WVR; a method regarded to provide simulated weightlessness), when the anlage of the inner ear already is present (10 h post fertilisation, hpf). Siblings were maintained under WVR for 3, 6, 9 and 12 days. Further short-term experiments (3 days) were carried out on 10 hpf animals as well as on very early larvae (1 K cell stage, 3 hpf) at two different rotation speeds. WVR (both rotation speeds) had no effect on otolith biogenesis in both stages as all otoliths were present after the experiments. In comparison with 1 g controls, WVR had significantly increased otolith growth (normalised by fish length) after 3 and 6 days of exposure, but significant differences of otolith growth between experimental animals and controls were not found after 9 and 12 days. In conclusion, WVR (at least within a time-span of exposure of up to 6 days) brings, comparable to the situation in real microgravity, a kind of feedback mechanism into action, resulting in larger otoliths. Later, possible effects of WVR might be overruled by normal allometric growth since the action of the feedback mechanism may be discontinued in the course of an adaptation.
In view of space exploration and long-term satellite missions, a new generation of multi-modular,... more In view of space exploration and long-term satellite missions, a new generation of multi-modular, multi-organism bioregenerative life support system with different experimental units (Modul.LES) is planned, and subunits are under construction. Modul.LES will be managed via telemetry and remote control and therefore is a fully automated experimental platform for different kinds of investigations. After several forerunner projects like AquaCells (2005), C.E.B.A.S. (1998, 2003) or Aquahab (OHB-System AG the Oreochromis Mossambicus Eu-glena Gracilis Aquatic Habitat (OmegaHab) was successfully flown in 2007 in course of the FOTON-M3 Mission. It was a 3 chamber controlled life support system (CLSS), compris-ing a bioreactor with the green algae Euglena gracilis, a fish chamber with larval cichlid fish Oreochromis mossambicus and a filter chamber with biodegrading bacteria. The sensory super-vision of housekeeping management was registered and controlled by telemetry. Additionally, all scientific data and videos of the organisms aboard were stored and sequentially transmitted to relay stations. Based on the effective performance of OmegaHab, this system was chosen for a reflight on Bion-M1 in 2012. As Bion-M1 is a long term mission (appr. 4 weeks), this CLSS (OmegaHab-XP) has to be redesigned and refurbished with enhanced performance. The number of chambers has been increased from 3 to 4: an algae bioreactor, a fish tank for adult and larval fish (hatchery inserted), a nutrition chamber with higher plants and crustaceans and a filter chamber. The OmegaHab-XP is a full automated system with an extended satellite downlink for video monitoring and housekeeping data acquisition, but no uplink for remote control. OmegaHab-XP provides numerous physical and chemical parameters which will be monitored regarding the state of the biological processes and thus enables the automated con-trol aboard. Besides the two basic parameters oxygen content and temperature, products of the nitrogene-cycle (concentration of ammonium, nitrite and nitrate) as well as conductivity will be measured. For this long term mission an external food supply as has been used with OmegaHab is not sufficient and, therefore, in OmegaHab-XP a nutrition compartment has been added. OmegaHab-XP is a multi-trophic system, designed as a basic concept and test-bed for future multi-modular platform Modul.LES. OmegaHab-XP comprises four different trophic lev-els. The algae experimental container is used as CO2 / O2 exchanger and serves as oxygen source for all heterotrophic organisms. The fish compartment is divided into two areas -namely a hatchery (larval cichlid fish Oreochromis mossambicus) and a fish tank (subadult cichlids). Once the yolk sack is resorbed (stage 19) the juvenile fish are capable to leave the hatchery via escapements into the fish compartment. In order to enable the development of fish from larval yolk sack stages to subadult fish a nutrition compartment is enclosed: In this nutrition compartment the crustacean Hyalella azteca will reproduce and build up a stable population by feeding on the Rigid Hornwort (Ceratophyllum demersum). Younger crustaceans can cross the barrier to the fish tank and can serve as nutrition for fully developed subadult fish. Waste products of all organisms will be assimilated by the water snail Biomphalaria glabrata. The scientific concept of Modul.LES is to establish a multidisciplinary framework of scientists and areas of scientific research (biophysics, molecular-organismic biology, biochemistry etc.) to analyze impacts of g on plants and animals.
ABSTRACT Developing cichlid fish (Oreochromis mossambicus) were subjected to microgravity (spacef... more ABSTRACT Developing cichlid fish (Oreochromis mossambicus) were subjected to microgravity (spaceflight) and were analysed in comparison to direct control batches (1g on orbit, 1g on ground and 1.4g hyper-gravity in the reference centrifuge on ground) employing quantitative behavioral, histochemical and electronmicroscopic-cytochemical techniques. After the experiment, the microgravity animals performed slow and disoriented movements as compared to 1g controls for some 5 days. Histochemically demonstrated succinate dehydrogenase reactivity, a marker for metabolic activity, was increased from microgravity via 1 g to hypergravity in vestibulum-related brain nuclei, whereas no alterations were found regarding non-vestibular nuclei. On the electronmicroscopical level, cytochrome oxidase activity was augmented in a vestibular nucleus according to the strength of the acceleration provided. Regarding the inner ear epithelia, weightlessness resulted in a decrease of CO reactivity in the gravity related utricle, whereas in the saccule, no differences were found. The results are discussed in the context with our non-spaceflight related gravity experiments.
Synapse counts were undertaken by conventional electron microscopy in primary vestibular integrat... more Synapse counts were undertaken by conventional electron microscopy in primary vestibular integration centers, (i.e. nucleus descendens and nucleus magnocellularis of the brainstem area octavolateralis) and in the diencephalic visual nucleus corticalis of spaceflown neonate swordtail fish Xiphophorus helleri as well as in 1 g control siblings. Spaceflight (16 days microgravity, (microg), STS-90 Neurolab Mission) yielded an increase in synaptic contacts within the vestibular nucleus descendens indicating that lack of input resulted in compensation processes. No effect of microg, however, was observed in the visual nucleus corticalis and in the vestibular nucleus magnocellularis which is situated in the close vicinity of the nucleus descendens. In contrast to the latter, the nucleus magnocellularis does not receive exclusively vestibular input, but inputs from the lateral line as well, possibly providing sufficient input at microgravity.
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Papers by Ralf Anken