Hypergravity susceptibility of ventral root activity during fictive swimming in tadpoles (Xenopus laevis)

1. Fictive swimming is an experimental model to study early motor development. As vestibular activity also affects the development of spinal motor projections, the present study focused on the question whether in Xenopus laevis tadpoles, the rhythmic activity of spinal ventral roots (VR) during fictive swimming revealed age-dependent modifications after hypergravity exposure. In addition, developmental characteristics for various features of fictive swimming between stages 37/38 and 47 were determined. Parameters of interest were duration of fictive swimming episodes, burst duration, burst frequency (i.e., cycle length), and rostrocaudal delay. 2. Ventral root recordings were performed between developmental stage 37/38, which is directly after hatching and stage 47 when the hind limb buds appear. The location of recording electrodes extended from myotome 4 to 17. 3. Hypergravity exposure by 3 g-centrifugation lasted 9 to 11 days. It started when embryos had just terminated gastrulation (stage 11/19-group), when first rhythmical activity in the ventral roots appeared (stage 24/27-group), and immediately after hatching (stage 37/41-group). Ventral root recordings were taken for 8 days after termination of 3 g-exposure. 4. Between stage 37/38 (hatching) and stage 47 (hind limb bud stage) burst duration, cycle length and rostrocaudal delay recorded between the 10th and 14th postotic myotome increased while episode duration decreased significantly. In tadpoles between stage 37 and 43, the rostrocaudal delay in the proximal tail part was as long as in older tadpoles while in caudal tail parts, it was shorter. During this period of development, there was also an age-dependent progression of burst extension in the proximal tail area that could not be observed between the 10th and 14th myotome. 6. After termination of the 3 g-exposure, the mean burst duration of VR activity increased significantly (p < 0.01) when 3 g-exposure started shortly after gastrulation but not when it started thereafter. Other parameters for VR activity such as cycle length, rostrocaudal delay and episode duration were not affected by this level of hypergravity. 7. It is postulated that (i) functional separation of subunits responsible for intersegmental motor coordination starts shortly after hatching of young tadpoles; and that (ii) gravity exerts a trophic influence on the development of the vestibulospinal system during different periods of embryonic development leading to the formation of more rigid neuronal networks earlier in the spinal than in the ocular projections.     

Altered gravity affects ventral root activity during fictive swimming and the static vestibuloocular reflex in young tadpoles (Xenopus laevis)

During early periods of life, modifications of the gravitational environment affect the development of sensory, neuronal and motor systems. The vestibular system exerts significant effects on motor networks that control eye and body posture as well as swimming. The objective of the present study was to study whether altered gravity (AG) affects vestibuloocular and spinal motor systems in a correlated manner. During the French Soyuz taxi flight Andromède to the International Space Station ISS (launch: October 21, 2001; landing: October 31, 2001) Xenopus laevis embryos were exposed for 10 days to microgravity (microg). In addition, a similar experiment with 3g-hypergravity (3g) was performed in the laboratory. At onset of AG, embryos had reached developmental stages 24 to 27. After exposure to AG, each tadpole was tested for its roll-induced vestibuloocular reflex (rVOR) and 3 hours later it was tested for the neuronal activity recorded from the ventral roots (VR) during fictive swimming. During the post-AG recording periods tadpoles had reached developmental stages 45 to 47. It was observed that microgravity affected VR activity during fictive swimming and rVOR. In particular, VR activity changes included a significant decrease of the rostrocaudal delay and a significant increase of episode duration. The rVOR-amplitude was transiently depressed. Hypergravity was less effective on the locomotor pattern; occurring effects on fictive swimming were the opposite of microg effects. As after microgravity, the rVOR was depressed after 3g-exposure. All modifications of the rVOR and VR-activity recovered to normal levels within 4 to 7 days after termination of AG. Significant correlations between the rVOR amplitude and VR activity of respective tadpoles during the recording period have been observed in both tadpoles with or without AG experience. The data are consistent with the assumptions that during this period of life which is characterized by a progressive development of vestibuloocular and vestibulospinal projections (i) microgravity retards the development of VR activity while hypergravity weakly accelerates it; (ii) that microgravity retards the rVOR development while hypergravity caused a sensitization, and that (iii) AG-induced changes of VR activity during fictive swimming have a vestibular origin.     

Short-term hypergravity does not affect protein-ubiquitination and proliferation in rat L6 myoblastic cells.

We previously reported that spaceflight (STS-90) and tail-suspension stimulated muscle protein ubiquitination and accumulated the degradation fragments. However, in space experiments the side-effects of hypergravity on samples are inevitable during the launch of a space shuttle into space or the reentry. To examine whether hypergravity also caused protein-ubiquitination in skeletal muscle cells, we exposed rat myoblastic L6 cells to various hypergravity conditions. Immunoblot analysis showed that the centrifugation at 2, 3, 30 or 100 G for 10 min did not increase the amount of ubiquitinated proteins in L6 cells, whereas the centrifugation at 100 G for 1 or 2 hrs significantly induced the protein-ubiquitination. In contrast, heat shock protein 70 (HSP70), another stress-responsive protein, in L6 cells was accumulated only by centrifugation at 100 G for more than 10 min. Short-term (10 min) hypergravity including 3 or 100 G did not affect the proliferation and morphological changes in L6 cells. Our present results suggest that the ubiquitination of muscle proteins is less sensitive to hypergravity than the induction of HSP70, and that the effect of hypergravity on protein-ubiquitination and proliferation of skeletal muscle cells may be negligible, as far as its duration is short-term.     

Influence of hypergravity on the pH profile and proteolytic activity of the avian gastrointestinal tract.

The present study deals with the effect of hypergravity (2xg) on the pH and on the proteolytic activity in the digesta of the gastrointestinal tract of Japanese quails during intense growth. The birds were raised on a semisynthetic diet containing free amino acids (A) and a commercial diet (B). During days 35 till 40 post-hatching the quails were exposed to hypergravity (2xg) using a specially designed centrifuge. On days 40 (experimental group, 2xg) and 41 (control group, 1xg) the animals were sacrificed. The pH of the digesta in various segments of the gastrointestinal tract was measured by means of a semi-microelectrode. Total proteolytic activity was determined by means of azo-dye-modified proteins serving as general proteolytic substrates. Hypergravity leads in general to an alkalization of digesta in various parts of the gastrointestinal tract. In case of the gizzard and duodenum (diet A) and also in the distal jejunum (diet B) the differences are significant. With both diets, hypergravity leads to a considerable decrease in the total proteolytic activity. The reduction is most expressed in the duodenum and jejunum. Changes in the pH of digesta compensate for the decrease in the proteolytic activity. This may explain why hypergravity per se does not seem to impair growth of the Japanese quails.     

Hypergravity induced prolonged diestrous in the rat can be prevented by bromergocryptine or by previous exposure to the same conditions — A “memory” effect

Female rats exposed to chronic moderate hypergravity (up to 2.3g) respond by a prolongation of their diestrous phase which resembles a pseudopregnancy. This reaction can be prevented by injection of bromergocrytine (E.C.) during the first few days of centrifugation, or by a previous 21 days of exposure of the rats to moderate hypergravity conditions followed by 36 days of exposure to 1.0g before re-exposure. A “memory” effect is suggested.     

Chronic centrifugation (hypergravity) disrupts the circadian system of the rat.

The present study was conducted to evaluate the response of rat deep body temperature (DBT) and gross locomotor activity (LMA) circadian rhythms to acute hypergravity onset and adaptation to chronic (14 day) hypergravity exposure over three gravity intensities (1.25, 1.5, and 2 G). Centrifugation of unanesthetized naive animals resulted in a dramatic acute decrease in DBT (-1.45, -2.40, and -3.09 degrees C for the 1.25, 1.5, and 2.0 G groups, respectively). LMA was suppressed for the duration of centrifugation (vs. control period); the percent decrease for each group on days 12-14, respectively, was 1.0 G, -15.2%, P = not significant; 1.25 G, -26.9%, P < 0.02; 1.5 G, -44.5%, P < 0.01; and 2.0 G, -63.1%, P < 0.002. The time required for DBT and LMA circadian rhythmic adaptation and stabilization to hypergravity onset increased from 1.25 to 2.0 G in all circadian metrics except daily means. Periodicity analysis detected the phenomenon of circadian rhythm splitting, which has not been reported previously in response to chronic hypergravity exposure. Our analysis documents the disruptive and dose-dependent effects of hypergravity on circadian rhythmicity and the time course of adaptation to 14-day chronic centrifugation exposure.     

Effect of vasotocin on locomotor activity in bullfrogs varies with developmental stage and sex

Although neurohypophysial peptides are present in many regions of the developing and adult bullfrog (Rana catesbeiana) brain, the function of these peptides remains unclear. To investigate possible behavioral actions, we examined locomotor activity following peptide injection in bullfrogs at various developmental stages. An intraperitoneal (ip) injection of arginine vasotocin (AVT) in tadpoles (stages V, X, or XVII) produced an immediate and dose-dependent inhibition of locomotor activity. On the other hand, AVT stimulated activity when administered ip to juvenile or adult female bullfrogs, but did not influence activity in juvenile or adult males. The minimum effective dose of AVT, when injected directly into the brain of tadpoles, was 100-fold less than that observed when injected ip, suggesting a central nervous system site of action for this peptide. A vasopressin receptor antagonist (d(CH2)5[Tyr(Me)2]AVP administered ip or icv) significantly increased locomotor activity in tadpoles, compared to controls. Oxytocin, vasopressin, and AVP4-9 inhibited activity in tadpoles while mesotocin, des Gly(NH2)AVP, and pressinoic acid had no significant effect. Injection of PGF2 alpha also significantly decreased activity levels in tadpoles. However, pretreatment of tadpoles with indomethacin, a prostaglandin synthesis inhibitor, did not prevent the behavioral effects of AVT, suggesting that prostaglandin synthesis is not required for this response. In summary, AVT influenced locomotor activity in bullfrog tadpoles and female frogs. This effect shifted during development from an inhibitory action in tadpoles to a stimulatory effect in metamorphosed female frogs. The effect of AVT on juvenile and adult frog locomotion was sexually dimorphic, as this peptide altered female behavior but not male behavior.     

Effects of long duration +2G hypergravity on MHC distribution and maximal tension of rat m.soleus fibers

Effects of long duration hypergravity on skeletal muscles are much less studied than effects of microgravity. For instance, it was revealed that hypergravity of 2 week duration induces decrease in cross sectional area (CSA) of slow fibers (SF), while their size remains constant, or increases. Exposure to +2G of 14 day duration results in decreased number of type I fibers, and in changed myosin heavy chain (MHC) profiles of rat hindlimb extensor muscle. It is interesting that gravitational unloading also decreases number of type I fibers. However, while effects of microgravity on relationship between the structural and functional characteristics of skeletal muscles are studied in detail, similar characteristics of skeletal muscles under conditions of gravitational overloading are very much understudied. The aim of our work was to follow dynamics of MHC in rat m.soleus after exposure to 19 and to 33 days of +2G acceleration, and to compare content of contractile proteins in muscle fibers, and their contractile properties.     

Hypergravity results in human platelet hyperactivity

Thrombotic diseases or fatalities have been reported to occasionally occur under conditions of hypergravity although the mechanism is still unclear. To investigate the effect of hypergravity on platelets that are the primary players in thrombus formation, platelet rich plasma (PRP) or washed platelets were exposed to hypergravity at 8 G for 15 minutes. No platelet aggregation was induced by 8 G alone, whereas ristocetin or collagen-induced platelet aggregation was significantly increased. The number of platelets adherent to immobilized fibrinogen and the area of platelets spreading on von Willbrand factor (VWF) matrix were increased simultaneously. Flow cytometry assay indicated that integrin αIIbß3 was partially activated in 8 Gexposed platelets, but there was no significant difference in P-selectin surface expression between platelets treated with 8 G and 1 G control. The results indicate that hypergravity leads to human platelet hyperactivity, but fails to incur essential platelet activation events, suggesting a novel mechanism for thrombotic diseases occurring under hypergravitional conditions.     

Effects of hypergravity conditions on elongation growth and lignin formation in the inflorescence stem of Arabidopsis thaliana

The effects of hypergravity on elongation growth and lignin deposition in secondary cell walls of the Arabidopsis thaliana (L.) Heynh. inflorescence stem were examined in plants grown for 3 days after exposure to hypergravity in the direction from shoot to root at 300 g for 24 h. The content of acetylbromide-extractable lignins in a secondary cell wall fraction prepared by enzyme digestion of inflorescence stem segments removing primary cell wall components was significantly increased by the hypergravity stimulus. Xylem vessels, particularly in a region closer to the base of the inflorescence stem, increased in number. Gadolinium chloride at 0.1 mM, a blocker of mechanoreceptors, partially suppressed the effect of hypergravity on lignin deposition in the secondary cell wall fraction. These results suggest that mechanoreceptors are responsible for hypergravity-induced lignin deposition in secondary cell walls in A. thaliana inflorescence stems.     

Study on the effect of hypergravity stress on L-glutamate uptake by rat brain nerve endings

Using rat brain synaptosomes, we have investigated the effect of hypergravity on the kinetic parameters of Na(+)-dependent, high-affinity L-glutamate transport activity. The time-course of L-[14C]-glutamate uptake and dependence of L-[14C]-glutamate uptake velocity on glutamate concentrations were analyzed. K(m) and Vmax of this process have been determined. The hypergravity stress was created by centrifugation of rats for 1 hour at 10 g. We observed no differences in K(m) values between the control rats (10.7 +/- 2.5 microM) and animals exposed to hypergravity (6.7 +/- 1.5 microM). The similarity of this parameter for the two studied groups of animals showed that affinity of glutamate transporter to substrate was not sensitive to hypergravity stress. In contrast, the maximal velocity of glutamate uptake changed in hypergravity conditions. Vmax reduced from 12.5 +/- +/- 3.2 nmol/min per 1 mg of protein (control group) to 5.6 +/- 0.9 nmol/min per 1 mg of protein (animals, exposed to hypergravity stress). The possible mechanisms of attenuation of the glutamate transporter activity without modifying K(m) of glutamate uptake were discussed.     

Sleep duration in hornets is influenced by physical and chemical means

Hornet workers (Vespa orientalis, Hymenoptera, Vespinae) were anesthetized by diethyl-ether, and their sleeping period was monitored. Sleep duration in hornets was found to be influenced by preexposure to horizontal rotation or to hypo- and hypergravity, by volatile fractions of their own venom and by the size of their habitat (crowding effect).     

Induction of micronuclei in tadpoles of Rana temporaria and Xenopus laevis by the pyrethroid Fastac 10 EC.

The mutagenic properties of the pyrethroid Fastac 10 EC were estimated using the micronucleus test in tadpoles of Rana temporaria and Xenopus laevis. The frequency of erythrocytes with micronuclei was examined in blood smears obtained from animals kept for 14 days in water containing 3 different concentrations of Fastac 10 EC. The study was accompanied by a positive control using the known mutagens cyclophosphamide and N-methyl-N-nitrosourea. The results obtained showed that at high concentrations Fastac 10 EC has a clastogenic activity and/or damages the mitotic spindle, as manifested by a significant increase in the frequency of the micronucleated red blood cells. It was also demonstrated that tadpoles of Rana temporaria are more sensitive to the mutagenic effect of the pyrethroid than are those of Xenopus laevis.     

Growth of the Cellular Slime Mold, Dictyostelium discoideum, Is Gravity Dependent

The effect of artificial gravity on the growth of a microorganism, Dictyostelium discoideum, was studied and the following results were obtained: (a) Germination efficiency increased as gravity increased up to 3 gravities. (b) Cell differentiation was influenced by gravity. Retardation of spore formation or reduction in the spore fraction was observed at hypergravity. (c) Fruiting bodies were taller at hypergravity and smaller at simulated microgravity when compared at 1 gravity. It is suggested that modulation of gravity provides useful information on the mechanisms of life.     

Chemical cues from multiple predator-prey interactions induce changes in behavior and growth of anuran larvae

Chemical signals are used as information by prey to assess predation risk in their environment. To evaluate the effects of multiple predators on prey growth, mediated by a change in prey activity, I exposed small and large bullfrog (Rana catesbeiana) larvae (tadpoles) to chemical cues from different combinations of bluegill sunfish (Lepomis macrochirus) and larval dragonfly (Anax junius) predators. Water was regularly transferred from predation trials (outdoor experiment) to aquaria (indoor experiment) in which activity and growth of tadpoles was measured. The highest predation mortality of small bullfrog larvae in the outdoor experiment was due to Anax, and it was slightly lower in the presence of both predators, probably resulting from interactions between predators. There was almost no mortality of prey with bluegill. The activity and growth of small bullfrog larvae was highest in the absence of predators and lowest in the presence of Anax. In the presence of bluegill only, or with both predators, the activity and growth of small bullfrog tadpoles was intermediate. Predators did not affect large tadpole activity and growth. Regressing mortality of small bullfrog tadpoles against activity and growth of bullfrog tadpoles revealed a significant effect for small bullfrog larvae but a non-significant effect for large bullfrog larvae. This shows that the response of bullfrog tadpoles to predators is related to their own body size. The experiment demonstrates that chemical cues are released both as predator odor and as alarm substances and both have the potential to strongly alter the activity and growth of prey. Different mechanisms by which chemical cues may be transmitted to species interactions in the food web are discussed. Received: 28 June 1999 / Accepted: 15 November 1999     

Conversion of retinol to 3,4-didehydroretinol in the tadpole

The conversion of retinol to 3,4-didehydroretinol in bullfrog tadpoles was studied by injecting [3H] all-trans retinol into the peritoneal cavity. The specific activities of retinoids in the eye and the rest of the body at various time intervals after the injection were then determined by HPLC (high-performance liquid chromatography). Radioactivity was observed in ocular 3,4-didehydroretinyl esters after 2 days and their specific activity increased throughout the 2 weeks of experiment. This demonstrates that tadpoles can convert retinol to its 3,4-didehydro derivative. In vitro experiments performed on isolated eye cups also suggested that the ocular tissues could convert retinol to 3,4-didehydroretinol. In the eye, the specific activity of porphyropsin or all-trans 3,4-didehydroretinal (extracted by the denaturing solvent acetone) exceeded that of the all-trans 3,4-didehydroretinyl esters in storage. This suggests that the main ocular store of 3,4-didehydroretinyl esters does not constitute a precursor pool for porphyropsin synthesis.     

In vitro study of the intestinal brush border enzyme activities in developing anuran amphibian: effects of thyroxine, cortisol, and insulin

The effects of several hormones on intestinal brush border membrane enzymatic activities have been investigated in intestinal explants taken from the amphibian midwife toad at different developmental stages. Explants were treated for at least 2 days with thyroxine (0.1 microgram/ml of culture medium) or for 2 days with cortisol (25 micrograms/ml) or insulin (6 mU/ml). The hydrolases examined were maltase, trehalase, glucoamylase, and alkaline phosphatase. In the explants from tadpoles in prometamorphosis, thyroxine had no effect on hydrolase activities; cortisol increased the activity of only glucoamylase, and insulin increased activity of maltase, glucoamylase, and alkaline phosphatase. When the explants were taken from tadpoles at the beginning of climax, cortisol and insulin generally stimulated the enzyme activities studied. When taken from tadpoles at the end of climax, at the moment when the embryonic cells under the degenerating epithelium divide, cortisol and insulin had little effect on these activities. When the animals terminate their metamorphosis, the intestinal epithelium of the explants is totally newly formed (secondary epithelium). At this time, cortisol stimulated the activities of maltase, glucoamylase, and alkaline phosphatase, while insulin decreased the activities of maltase and glucoamylase.     

Changes in the Architecture of Cancellous Bone in the Femora of Developing Mice as a Result of Short Duration Hypergravity

SYNOPSIS. Mice were used as a model system to demonstrate theeffects of increased loading on the trabecular bone in the developingproximal femur. A two-dimensional free body diagram revealedthat because the femur is normally held in a horizontal positionduring support, functional loading resulted in a net posteriorbending moment and a muscle generated axial compressive loadthat was 7.7 times the normal support weight for that limb.Experimental treatment consisted of four times normal gravityfor 10 min, six times per day for 30 days in addition to unrestrainednormal exercise. Unrestrained normal exercise served as thecontrol. An animal whose foot was amputated by his mother shortlyafter birth was used as a less than normal load example forcomparison with the hypergravity and control groups. All groupswere treated for 30 days. Two areas of trabecular bone wereexamined: a proximal central webbing area that may be underpredominantly tensile loading much of the time, and a more distalarea near the third trochanter that presumably experiences bendingstresses when the animal is exposed to normal activity or hypergravity.Results indicate that: 1) The central webbing area appears tohave a similar mass of bone regardless of loading conditions;however, with increased loading the trabeculae become orientedin directions that approximate directions of presumed principaltensile stresses. 2) There is no genetically predetermined amountof bony tissue in the third trochanter area; when the limb isrelatively unloaded no trabeculae are present, as the loadingincreases trabecular bone is formed. In the hypergravity group,trabeculae in the area of the third trochanter increased inlength and complexity and became more centrally positioned inthe lumen of the femur, a position that presumably would allowthe femur to better resist bending moments. These results demonstratethat short duration, high intensity functional loading can stimulategrowth of trabecular bone, and further, specific types of functionalloading can be correlated with specific architectural changes.     

Effects of hydroperiod duration on developmental plasticity in tiger frog(Hoplobatrachus chinensis) tadpoles

While developmental plasticity can facilitate evolutionary diversification of organisms,the effects of water levels as an environmental pressure on tiger frogs remains unclear.This study clarifies the relationship by studying the responses of tiger frog(Hoplobatrachus chinensis)tadpoles to simulated hydroperiods(i.e.,constant low water levels,constant high water levels,increasing water levels,decreasing water levels,rapid changes in water levels and gradual fluctuations in water levels)in a laboratory setting.ANOVA analysis showed that none of the water level treatments had any significant effect on the total length,body mass,or developmental stages of H.chinensis tadpoles half way through development(11 days old).Tadpoles raised in rapidly fluctuating water levels had protracted metamorphosis,whereas tadpoles raised under low and gradually fluctuating water levels had shortened metamorphosis.None of the water level treatments had a significant effect on the snout-vent length(SVL)or body mass of H.chinensis tadpoles at Gosner stage 42,or on the body mass of tadpoles at Gosner stage 45.However,the tadpoles raised in high levels and rapidly fluctuating water levels,significantly larger SVL at Gosner stage 45,while ones under gradually fluctuating water levels had smaller SVL than the other groups.Time to metamorphosis was positively correlated with body size(SVL)at metamorphosis in H.chinensis tadpoles.H.chinensis tadpoles under constant low water level had the highest mortality rate among all the treatments(G-test).Moreover,ANOVA and ACNOVA(with body length as the covariate)indicated that water levels had no significant effect on either the morphology(i.e.head length,head width,forelimb length,hindlimb length and body width)or the jumping ability of juvenile H.chinensis.These results suggest that the observed accelerated metamorphosis and high mortality of H.chinensis tadpoles under decreasing water level treatment was driven by density-induced physical interactions among increasing conspecifics.