Functional and cellular adaptation to weightlessness in primates

Considerable data has been collected on the response of hindlimb muscles to unloading due to both spaceflight and hindlimb suspension. One generalized response to a reduction in load is muscle fiber atrophy, although not all muscles respond the same. For example, predominantly slow extensor muscles like the Sol exhibit a large reduction in fiber size to unloading, while fast extensors like the plantaris and fast flexors like the tibialis anterior show little, if any, atrophy. Our understanding of how muscles respond to microgravity, however, has come primarily from the examination of hindlimb muscles in the unrestrained rat in space. The non-human primate spaceflight paradigm differs considerably from the rodent paradigm in that the monkeys are restrained, usually in a sitting position, while in space. Recently, we examined the effects of microgravity on muscles of the Rhesus monkey by taking biopsies of selected hindlimb muscles prior to and following spaceflights of 14 and 12 day durations (Cosmos 2044 and 2229). Our results revealed that the monkey's response to microgravity differs from that of the rat. The apparent differences in the atrophic response of the hindlimb muscles of the monkey and rat to spaceflight may be attributed to 1) a species difference, 2) a difference in the manner in which the animals were maintained during the flight (i.e., chair restraint or "free-floating"), and/or 3) an ability of the monkeys to counteract the effects of spaceflight with resistive exercise.     

Differential adaptation to weightlessness of functional and structural characteristics of rat hindlimb muscles

Soleus, vastus intermedius, tibialis anterior, and extensor digitorum longus muscles were removed from rats following space flight onboard the SLS-2 mission and from control animals. Muscle tissues were studied for their calcium and strontium activated tension characteristics and for structural changes. Muscles were also examined for myosin composition using electrophoresis. Results indicate that changes occurred in structural and functional muscle characteristics in both slow and fast muscle fiber types. These results are detailed and discussed.     

Future research directions in seeking countermeasures to weightlessness

The goal of this paper is to briefly review the state of knowledge concerning the adaptive properties of mammalian skeletal muscle in response to varying duration in weightlessness, to identify voids in the understanding of this adaptive process, and to provide some insight for undertaking future research on this important topic.     

Leptin responses to physical inactivity induced by simulated weightlessness

Physical inactivity induced by head-down bed rest (HDBR) affects body composition (BC). Leptin is involved in BC regulation by acting on fuel homeostasis. We investigated whether leptin and counterregulatory hormone levels are affected by a 7-day HDBR. Fasting blood was sampled daily (0700) in males (n = 8) and on alternating days in females (n = 8) for measurements of leptin, insulin, norepinephrine (NE), epinephrine (Epi), growth hormone (GH), cortisol, nonesterified fatty acid (NEFA), and glucose. BC was measured by H(2)(18)O dilution. Energy intake (men 10.5 +/- 0.2 MJ/day, women 7.9 +/- 0.3 MJ/day) and BC were unchanged by HDBR. Increased levels of leptin (men 40%, P = 0.003; women 20%, P = 0. 050), insulin (men 34%, P = 0.018; women 25%, P = 0.022), and the insulin-to-glucose ratio (men 30%, P = 0.049; women 25%, P = 0.031) were noted. GH, NE, Epi, and cortisol levels were unaltered. NEFA dropped in both sexes, but glucose decreased only in women. In conclusion, HDBR increased leptin levels independently of stress response, changes in fat mass, energy intake, or gender. These changes were correlated to the insulin-resistance development in men. Further analyses are required, but the results have to be considered for longer HDBR periods with 1) the well-described drop in energy intake and 2) the BC changes.     

Cardiopulmonary responses to static exercise

Ventilatory and cardiovascular responses to isometric exercise, with special reference to hand-grip exercise, were reviewed. Blood flow through the forearm (FBF) during muscular contraction is dependent on relative strength to MVC (maximum voluntary contraction), duration of exercise, and hand temperature. FBF could attain steady state during exercise with intensities less than 15% MVC. Heart rate (HR) starts to increase with a latency as short as 0.4 to 0.6 sec in conscious animals and men in response to voluntary as well as electrically induced isometric exercise. This response is vagally transmitted. The sympathetic nerves mediated HR response with a longer delay is also found. Cardiac contractility is augmented via sympathetic beta-receptors during isometric exercise. With aging, HR response tends to be intensified, whereas, stroke volume response tends to be depressed. Thus increased cardiac output is resulted in elevated arterial blood pressure. Total vascular resistance is reported to be unaltered, or to increase, despite of consistent increase in muscle sympathetic activities during the isometric exercise. Ventilation is augmented during exercise, but the pattern of its response is not in full agreement among investigators. The underlying mechanisms to elicit those responses are discussed.     

模拟失重降低大鼠心肌细胞对异丙肾上腺素的反应性

本文旨在研究模拟失重对大鼠单个心肌细胞无负荷收缩功能的影响以及对异丙肾上腺素(isoproterenol,ISO)反应性的变化.采用人鼠尾部悬吊法在地面模拟失重状态,4周后以胶原酶I消化分离心肌细胞,分别对左、右两心室心肌细胞进行收缩功能测量.结果显示,悬吊4周大鼠(悬吊组)左,右心室心肌细胞的长度和宽度与正常大鼠(对照组)相比均无显著差异.随刺激频率增加,对照组与悬吊组大鼠心肌细胞缩短幅值均逐步增加.在1.0、2.0与4.0 Hz刺激下,对照组大鼠左心室心肌细胞缩短幅值分别为(8.50±1.26)%、(9.00±1.38)%与(9.23±1.83)%,右心室心肌细胞缩短幅值分别为(9.80±2.48)%、(10.03±2.48)%与(10.28±2.27)%;与对照组大鼠相比,在1.0与2.0Hz刺激下,悬吊组大鼠左心室心肌细胞无负荷缩短幅值分别降低12.2%、10.9%(P《0.05),右心室则分别降低16.5%、16.3%(P《0.05);但是在4.0 Hz刺激下却无显著性改变.与同一频率刺激下的对照组大鼠相比,悬吊组大鼠左、右心室心肌细胞达到缩短峰值的时程(time to peak shortening,TPS)明显缩短(P《0.05);而从缩短峰值至75%舒张的时程(TR75)则明显延长(P《0.05).在各刺激频率下,悬吊组大鼠左、右心室心肌细胞缩短(+dL/dtmax)与舒张(-dL/dtmax)速度均未发生明显改变.用1、5、10 nmol/L ISO灌流达稳态水平后,对照组大鼠心肌细胞缩短幅值分别增加了(10.63±0.83)%、(35.06±5.22)%和(71.64±6.83)%;而悬吊组大鼠心肌细胞缩短幅值仅增加(5.75±0.76)%、(23.97±4.50)%和(26.38±8.13)%,均有显著性差异(P《0.05,P《0.01).用10、50、100 nmol/L forskolin 灌流达稳定水平后,对照组大鼠心肌细胞缩短幅值分别增加了(3.04±0.27)%、(9.81±2.66)%、(20.20±3.47)%;而悬吊组大鼠心肌细胞缩短幅值仅增加了(1.42±0.53)%、(3.83±1.71)%、(5.49±4.08)%,均有显著性差异(P《0.05).以上结果表明,模拟失重4周降低人鼠心肌细胞无负荷缩短幅值以及对ISO的反应性.     

Diminished plasma cGMP during weightlessness

We performed an experiment within the project "RLF" (Russian long-term flight) on a cosmonaut onboard the space station MIR. For creating an analogue to orthostatic stress, we used lower body negative pressure (LBNP) as stimulus. Decrease in central and peripheral baroreceptor load by LBNP can be used as a cardiovascular countermeasure in cosmonauts or for inducing endocrine responses. Altered steady-state plasma concentration values of volume sensitive hormones have been observed inflight as well as postflight. Within this project we measured plasma ANP and cGMP as second messenger. Changes in plasma cGMP concentration are generally considered to be a good indicator of those in ANP activity. However, in our experiments depression of cGMP during space flight was more impressive than ANP decline. We are not aware of previous measurements of plasma cGMP under these conditions, and believe to be the first to report complete suppression of plasma cGMP during long-term stay in space.     

Random root movements in weightlessness

The dynamics of root growth was studied in weightlessness. In the absence of the gravitropic reference direction during weightlessness, root movements could be controlled by spontaneous growth processes, without any corrective growth induced by the gravitropic system. If truly random of nature, the bending behavior should follow socalled 'random walk' mathematics during weightlessness. Predictions from this hypothesis were critically tested.
In a Spacelab ESA-experiment, denoted RANDOM and carried out during the IML-2 Shuttle flight in July 1994, the growth of garden cress ( Lepidium sativum ) roots was followed by time lapse photography at 1-h intervals.
The growth pattern was recorded for about 20 h. Root growth was significantly smaller in weightlessness as compared to gravity (control) conditions.
It was found that the roots performed spontaneous movements in weightlessness. The average direction of deviation of the plants consistently stayed equal to zero, despite these spontaneous movements. The average squared deviation increased linearly with time as predicted theoretically (but only for 8–10 h).
Autocorrelation calculations showed that bendings of the roots, as determined from the 1-h photographs, were uncorrelated after about a 2-h interval.
It is concluded that random processes play an important role in root growth. Predictions from a random walk hypothesis as to the growth dynamics could explain parts of the growth patterns recorded. This test of the hypothesis required microgravity conditions as provided for in a space experiment.     

Graviresponses of gliding and swimming Loxodes using step transition to weightlessness

Cells of Loxodes striatus were adjusted to defined culturing, experimental solution O2-supply, temperature, and state of equilibration to be subjected to step type transition of acceleration from normal gravity, (1 g) to the weightless condition (microgravity) during free fall in a 500 m drop shaft. Cellular locomotion inside a vertical experimental chamber was recorded preceding transition and during 10 s of microgravity. Cell tracks from video records were used to separate cells gliding along a solid surface from free swimmers, and to determine gravitaxis and gravikenesis of gliding and swimming cells. With O2 concentrations > or = 40% air saturation gliders and swimmers showed a positive gravitaxis. In microgravity gravitaxis of gliders relaxed within 5 s whereas gravitaxis relaxation of swimmers was not completed even after 10 s. Rates of horizontal gliders (319 micrometers/s) exceeded those, of horizontal swimmers (275 micrometers/s). Relaxation of gravikinesis was incomplete after 10 s of microgravity. Analysis of the locomotion rates during the g-step transition revealed that gliders sediment more slowly, than swimmers (14 versus 45 micrometers/s). The gravikinesis of gliders cancelled sedimentation effects during upward and downward locomotion tending to maintain cells at a predetermined level inside sediments of a freshwater habitat. At > or = 40% air saturation, gravikinesis of swimmers augmented the speed of the majority of cells during gravitaxis, which favours fast vertical migrations of Loxodes.     

A ground-based model to study the effects of weightlessness on lymphocytes

The mitogenic response of human lymphocytes was found to be markedly reduced in weightlessness conditions as compared to normal gravity. One possible explanation is that due to the non-existent sedimentation in space the lymphocytes could not adhere and spread on a substratum. Thus, we investigated the effect of substratum adhesiveness on lymphocyte responsiveness by reducing and blocking cell adhesion with poly-HEMA in a simple on-ground system. Lymphocyte adhesiveness was assessed by measuring the proportion of non-adhesive, slightly, and strongly adhesive 51Cr-radiolabelled cells on uncoated and poly-HEMA coated plastic. The amount of cell spreading on surfaces with varying adhesiveness was determined by measuring the area of cells. Cells grown on medium and thick poly-HEMA films were rounded in shape. By contrast, on tissue culture plastic, they showed clear signs of spreading. The mitogenic response of lymphocytes grown on thick poly-HEMA films was reduced by up to 68% of the control (tissue culture plastic). Interferon-gamma production was virtually nil when the cells were grown on the least adhesive substratum. These results show that activated lymphocytes need to anchor and spread prior to achieving an optimal proliferation response. We conclude that decreased lymphocyte adhesion could contribute to the depressed in vitro lymphocyte responsiveness found in the microgravity conditions of space flight.