Role of the vestibular system in sudden shutdown of renal sympathetic nerve activity during microgravity in rats

Brain development, environment and sex: what can we learn from studying graviperception, gravitransduction and the gravireaction of the developing CNS to altered gravity?

As man embarks on space exploration and contemplates space habitation, there is a critical need for basic understanding of the impact of the environmental factors of space, and in particular gravity, on human survival, health, reproduction and development. This review summarizes our present knowledge on the effect of altered gravity on the developing CNS with respect to the response of the developing CNS to altered gravity (gravireaction), the physiological changes associated with altered gravity that could contribute to this effect (gravitransduction), and the possible mechanisms involved in the detection of altered gravity (graviperception). Some of these findings transcend gravitational research and are relevant to our understanding of the impact of environmental factors on CNS development on Earth.

Potential Role of Oxidative Stress in Mediating the Effect of Altered Gravity on the Developing Rat Cerebellum

We have previously reported that perinatal exposure to hypergravity affects cerebellar structure and motor coordination in rat neonates. In the present study, we explored the hypothesis that exposure to hypergravity results in oxidative stress that may contribute to the decrease in Purkinje cell number and the impairment of motor coordination in hypergravity-exposed rat neonates. To test this hypothesis we compared cerebellar oxidative stress marker 3-nitrotyrosine (3-NT; an index of oxidative protein modification) and 8-hydroxy-2'-deoxyguanosine (8-OH-dG; an index of oxidative DNA damage) between stationary control (SC) and rat neonates exposed to 1.65 G (HG) on a 24-ft centrifuge from gestational day (G) 8 to P21. The levels of 3-NT and 8-OH-dG were determined by specific ELISAs. We also compared the Purkinje cell number (stereorologically) and rotarod performance between the two groups. The levels of 3-NT were increased only in HG females on P6 and on P12 in the cerebellum, and only in HG females on P12 in the extracellabellar tissue. Limited cerebellar data suggests an increase in the levels of 8-OH-dG on P12 only in HG females. In extracerebellar tissue the increase in 8-OH-dG levels was observed in both HG males and HG females except on P6 when it was only observed in HG males. While preliminary, these data suggest that the effect of hypergravity on the developing brain is sex-dependent and may involve oxidative stress. Oxidative stress may, in turn, contribute to the decrease Purkinje cell number and impaired motor behavior observed in hypergravity-exposed rats.

Roles of the vestibular system in controlling arterial pressure in conscious rats during a short period of microgravity

In order to evaluate the roles of the vestibular system in controlling arterial pressure (AP) during exposure to a short period of microgravity (microG), the AP was measured in conscious free-moving rats having intact vestibular systems and those having vestibular lesions (FM-Intact and FM-VL groups, respectively). During free drop-induced microG, the AP increased in the FM-Intact group; it was 38+/-4 mmHg more than the AP observed during 1G. However, the increase in AP was significantly lower in the FM-VL group (20+/-2 mmHg). Further, to examine the sudden effect of a body floating in the midair in response to the AP during exposure to muG a body stabilizer was placed on the back of rats having intact vestibular systems and those having vestibular lesions (STAB-Intact and STAB-VL groups, respectively). The increase in the AP was significantly depressed in the STAB-Intact group; when compared with that in the FM-Intact group, but the increase was still significant (27+/-2 mmHg). On the other hand, the increase in the AP was completely eliminated in the STAB-VL group (7+/-5 mmHg). These results indicate that the AP increases during exposure to muG in conscious rats, and the vestibular system and body stability are significantly involved in this response.

Vestibular control on blood pressure during parabolic flights in awake rats

The aim of this study was to evaluate the role of the vestibular system in cardiovascular control in a varying gravito-inertial field induced by parabolic flight. We measured variations in arterial pressure and heart rate in eight awake rats, four of which had undergone bilateral labyrinthectomy 3 months previously. While the control rats showed heart rate and mean arterial pressure modulations depending on gravity level, no such variation was observed in the lesioned rats. This study confirms the role of the vestibular system in cardiovascular control and opens up new prospects for interpreting cardiovascular variations observed during space flights.

Vestibulosympathetic reflex mediates the pressor response to hypergravity in conscious rats: contribution of the diencephalon

To investigate the mechanism of arterial pressure (AP) regulation during hypergravity, the AP response to gravitational force was examined in conscious rats and the AP was found to increase, depending on the degree of gravity load induced by centrifugation. At 20 s after application of 2, 3, or 5 G, the AP increased by 9+/-2, 20+/-3, or 24+/-3 mm Hg, respectively. The AP increase during first 60 s was suppressed by vestibular lesion or pretreatment with hexamethonium, suggesting that the vestibular system and sympathetic nerve system be involved, respectively, in the afferent and efferent pathways. To further examine the central pathway of this response, Fos expression in the brain was examined after exposure to 5 G for 90 min. Intense Fos expression was seen in the medial vestibular nucleus, paraventricular hypothalamic nucleus, autonomic nuclei in the brain stem in intact rats, but not in rats with vestibular lesion. To examine the involvement of the diencephalic nuclei in this pressor response, AP was measured under hypergravity in rats with midcollicular transection. In these rats, the AP change was minimal at 2, 3, and 5 G, indicating that nuclei rostral to the transection level were involved in the pressor response. These results indicate that output from the vestibular system project to the diencephalon, and activation of diencephalic nuclei is indispensable to the pressor response via the sympathetic nerve system.

Roles of baroreflex and vestibulosympathetic reflex in controlling arterial blood pressure during gravitational stress in conscious rats

Gravity acts on the circulatory system to decrease arterial blood pressure (AP) by causing blood redistribution and reduced venous return. To evaluate roles of the baroreflex and vestibulosympathetic reflex (VSR) in maintaining AP during gravitational stress, we measured AP, heart rate (HR), and renal sympathetic nerve activity (RSNA) in four groups of conscious rats, which were either intact or had vestibular lesions (VL), sinoaortic denervation (SAD), or VL plus SAD (VL + SAD). The rats were exposed to 3 G in dorsoventral axis by centrifugation for 3 min. In rats in which neither reflex was functional (VL + SAD group), RSNA did not change, but the AP showed a significant decrease (-8 +/- 1 mmHg vs. baseline). In rats with a functional baroreflex, but no VSR (VL group), the AP did not change and there was a slight increase in RSNA (25 +/- 10% vs. baseline). In rats with a functional VSR, but no baroreflex (SAD group), marked increases in both AP and RSNA were observed (AP 31 +/- 6 mmHg and RSNA 87 +/- 10% vs. baseline), showing that the VSR causes an increase in AP in response to gravitational stress; these marked increases were significantly attenuated by the baroreflex in the intact group (AP 9 +/- 2 mmHg and RSNA 38 +/- 7% vs. baseline). In conclusion, AP is controlled by the combination of the baroreflex and VSR. The VSR elicits a huge pressor response during gravitational stress, preventing hypotension due to blood redistribution. In intact rats, this AP increase is compensated by the baroreflex, resulting in only a slight increase in AP.

Relationship between transmural pressure and aortic diameter during free drop-induced microgravity in anesthetized rats

To test the hypothesis that the aortic wall is stretched without increasing aortic pressure (AP) during microgravity (microG), the AP, intrathoracic pressure (ITP), and aortic diameter (AD) were measured in anesthetized Sprague-Dawley rats during 4.5 s of microG produced by freefall. A smooth and immediate reduction in gravity (G) occurred during freefall, microG being achieved 100 ms after the start of the drop. Acute microG elicited an immediate increase in AD, which was not accompanied by an increase in AP. However, the ITP decreased during microG resulted in an increase in the calculated transmural pressure (TP = AP-ITP) of the aortic wall. A simple linear regression analysis showed that the slopes of the plot of AP vs. AD differed at 1 G and microG, whereas those for the plot of TP vs. AD did not. Thus, the increase in AD during microG was accounted for by the increase in TP. These results suggest that a decrease in ITP, resulting in an increase in TP of the aorta, is a key issue in understanding cardiovascular responses to microG.

Cerebral Circulation during Acute Microgravity Induced by Free Drop in Anesthetized Rats

To evaluate changes in the cerebral circulation during acute microgravity (microG), we measured intracranial pressure (ICP), aortic pressure at the diaphragm level, and cerebral flow velocity (CFV) in anesthetized rats (n = 5) during 4.5 s of microG induced by free drop, then calculated arterial pressure at the eye level (AP(eye)) and cerebral perfusion pressure (CPP = AP(eye)-ICP), and estimated CPP-CFV relationship. The rats were placed in the flat and the 30 degrees head-up positions. In the head-up position, ICP, AP(eye), and CPP were significantly increased by 2.2 +/- 0.4, 12.3 +/- 2.0, and 10.1 +/- 1.7 mmHg respectively during microG, whereas the CFV did not change significantly. In the flat position, none of these variables were significantly affected by microG. The slope of the CPP-CFV relationship was decreased only in the head-up position, suggesting that the cerebrovascular resistance was increased by microG. These findings indicate that the change in gravitational (hydrostatic) pressure is a key factor in understanding the changes in cerebral circulation during acute microG.

Response of renal sympathetic nerve activity to parabolic flight-induced gravitational change in conscious rats

The renal sympathetic nerve activity (RNA) response to gravitational changes induced by parabolic flight was examined in chronically instrumented conscious rats. Two types of RNA responses were found. In six out of 12 rats, the RNA did not respond during the 2 G period, but immediately fell to background levels on entry into microgravity (microG), then recovered to the 1 G control level during continued microG (shutdown obvious group). In the other six rats, the RNA increased to 158+/-13% at the end of the 2 G period, increased further to 195+/-22% on entry into microG, then gradually recovered to that seen at 1 G (shutdown obscure group). The mean arterial pressure in the shutdown obvious group was significantly higher and the heart rate tended to be higher than in the shutdown obscure group, suggesting that the baseline sympathetic tone in the shutdown obvious group was higher than in the shutdown obscure group. These results suggest that the RNA response to parabolic flight might be affected by the baseline sympathetic tone.

Acute response of aortic nerve activity to free drop-induced microgravity in anesthetized rats

To test the hypothesis that arterial baroreflex was stimulated during microgravity (microG), arterial pressure (AP), intrathoracic pressure (ITP), and aortic nerve activity (ANA) were measured in anesthetized rats during 4.5 s of microG produced by free drop. A smooth and immediate reduction in G occurred during free drop, microG being achieved 100 ms after the start of the drop. Acute microG elicited an immediate and striking, but transient, increase in ANA, with no significant change in the AP, but a significant decrease in the end-expiratory ITP. The calculated transmural pressure of the aorta increased by 6.9 mmHg 2 s after the start of the drop. The increase in ANA lasted 2 s, then ANA returned to the control level, despite the calculated end-expiratory transmural pressure still being high. These results suggest that microG conditions stimulate the aortic baroreceptor by increasing transmural pressure by reducing the ITP. However, this effect is only transient, probably due to the high-pass property of the baroreceptors.