Soluble erythropoietin receptor is present in the mouse brain and is required for the ventilatory acclimatization to hypoxia

While erythropoietin (Epo) and its receptor (EpoR) have been widely investigated in brain, the expression and function of the soluble Epo receptor (sEpoR) remain unknown. Here we demonstrate that sEpoR, a negative regulator of Epo's binding to the EpoR, is present in the mouse brain and is down-regulated by 62% after exposure to normobaric chronic hypoxia (10% O₂ for 3 days). Furthermore, while normoxic minute ventilation increased by 58% in control mice following hypoxic acclimatization, sEpoR infusion in brain during the hypoxic challenge efficiently reduced brain Epo concentration and abolished the ventilatory acclimatization to hypoxia (VAH). These observations imply that hypoxic downregulation of sEpoR is required for adequate ventilatory acclimatization to hypoxia, thereby underlying the function of Epo as a key factor regulating oxygen delivery not only by its classical activity on red blood cell production, but also by regulating ventilation.     

Erythropoietin and respiratory control at adulthood and during early postnatal life

Erythropoietin (Epo) was originally discovered as a cytokine able to increase the production of red blood cells upon conditions of reduced oxygen availability. Now we know that Epo does far more than “only” augmenting the number of erythrocytes. Since the demonstration that Epo (and its receptor) is expressed in the mammalian brain, several elegant experiments were performed to reveal the function of this molecule in the neuronal tissue. Accordingly to its anti-apoptotic, neurotrophic and proliferative effects in the bone marrow, it was suitably suggested that upon pathological conditions Epo exerts neuroprotective functions (i.e. reducing the infarct volume of stroke, thus allowing better and faster recovery). We considered however, that Epo in brain might also exert a physiological function. Indeed, we found that Epo is an important modulator of the respiratory control system. By using adult mice we showed that Epo increases the hypoxic ventilatory response by interacting with both the central respiratory network (brainstem) as well as the main peripheral sensory organs detecting systemic hypoxia, the carotid bodies. More recently, our research turned to examine the exciting hypothesis that Epo is also implicated in the regulation of the neuronal control of ventilation during the postnatal development. The objective of this review is to summarize the role and mode of action of Epo on respiratory control in adult mammals and highlight the potential pathways by which this cytokine achieve this function. Additionally, we review recent evidences showing that Epo play a crucial role in setting the respiratory motor output (measured on the isolated brainstem spinal cord preparation, en bloc technique) during the early postnatal life.     

Ventilatory response to acute hypoxia in transgenic mice over-expressing erythropoietin: effect of acclimation to 3-week hypobaric hypoxia

We used transgenic mice constitutively over-expressing erythropoietin ("tg6" mice) and wild-type (wt) mice to investigate whether the high hematocrit (hct), consequence of Epo over-expression affected: (1) the normoxic ventilation (V (E)) and the acute hypoxic ventilatory response (HVR) and decline (HVD), (2) the increase in ventilation observed after chronic exposure to hypobaric hypoxia (430mmHg for 21 days), (3) the respiratory "blunting", and (4) the erythrocythemic response induced by chronic hypoxia exposure. V (E) was found to be similar in tg6 and wt mice in normoxia (FIO2=0.21). Post-acclimation V (E) was significantly elevated in every time point in wt mice at FIO2=0.10 when compared to pre-acclimation values. In contrast, tg6 mice exhibited a non-significant increase in V (E) throughout acute hypoxia exposure. Changes in V (E) are associated with adjustments in tidal volume (V(T)). HVR and HVD were independent of EE in tg6 and wt mice before chornic hypoxia exposure. HVR was significantly greater in wt than in tg6 mice after chronic hypoxia. After acclimation, HVD decreased in tg6 mice. Chronic hypoxia exposure caused hct to increase significantly in wt mice, while only a marginal increase occurred in the tg6 group. Although pre-existent EE does not appear to have an effect on HVR, the observation of alterations on V(T) suggests that it may contribute to time-dependent changes in ventilation and in the acute HVR during exposure to chronic hypoxia. In addition, our results suggest that EE may lead to an early "blunting" of the ventilatory response.     

Impaired ventilation and metabolism response to hypoxia in histamine H1 receptor-knockout mice

The role of central histamine in the hypoxic ventilatory response was examined in conscious wild-type (WT) and histamine type1 receptor-knockout (H1RKO) mice. Hypoxic gas (7% O(2) and 3% CO(2) in N(2)) exposure initially increased and then decreased ventilation, referred to as hypoxic ventilatory decline (HVD). The initial increase in ventilation did not differ between genotypes. However, H1RKO mice showed a blunted HVD, in which mean inspiratory flow was greater than that in WT mice. O(2) consumption (V(O2)) and CO(2) excretion were reduced 10min after hypoxic gas exposure in both genotypes, but (V(O2)) was greater in H1RKO mice than in WT mice. The ratio of minute ventilation to (V(O2)) during HVD did not differ between genotypes, indicating that ventilation is adequately controlled according to metabolic demand in both mice. Peripheral chemoreceptor sensitivity did not differ between genotypes. We conclude that central histamine contributes via the H1 receptor to changes in metabolic rate during hypoxia to increase HVD in conscious mice.     

Carotid sinus nerve responses and ventilatory acclimatization to hypoxia in adult rats following 2 weeks of postnatal hyperoxia

Adult rats have decreased carotid body volume and reduced carotid sinus nerve, phrenic nerve, and ventilatory responses to acute hypoxic stimulation after exposure to postnatal hyperoxia (60% O2, PNH) during the first 4 weeks of life. Moreover, sustained hypoxic exposure (12%, 7 days) partially reverses functional impairment of the acute hypoxic phrenic nerve response in these rats. Similarly, 2 weeks of PNH results in the same phenomena as above except that ventilatory responses to acute hypoxia have not been measured in awake rats. Thus, we hypothesized that 2-week PNH-treated rats would also exhibit blunted chemoafferent responses to acute hypoxia, but would exhibit ventilatory acclimatization to sustained hypoxia. Rats were born into, and exposed to PNH for 2 weeks, followed by chronic room-air exposure. At 3-4 months of age, two studies were performed to assess: (1) carotid sinus nerve responses to asphyxia and sodium cyanide in anesthetized rats and (2) ventilatory and blood gas responses in awake rats before (d0), during (d1 and d7), and 1 day following (d8) sustained hypoxia. Carotid sinus nerve responses to i.v. NaCN and asphyxia (10 s) were significantly reduced in PNH-treated versus control rats; however, neither the acute hypoxic ventilatory response nor the time course or magnitude of ventilatory acclimatization differed between PNH and control rats despite similar levels of PaO2 . Although carotid body volume was reduced in PNH rats, carotid body volumes increased during sustained hypoxia in both PNH and control rats. We conclude that normal acute and chronic ventilatory responses are related to retained (though impaired) carotid body chemoafferent function combined with central neural mechanisms which may include brainstem hypoxia-sensitive neurons and/or brainstem integrative plasticity relating both central and peripheral inputs.     

Prenatal nicotine alters maturation of breathing and neural circuits regulating respiratory control

While perinatal nicotine effects on ventilation have been widely investigated, the prenatal impact of nicotine treatment during gestation on both breathing and neural circuits involved in respiratory control remains unknown. We examined the effects of nicotine, from embryonic day 5 (E5) to E20, on baseline ventilation, the two hypoxic ventilatory response components and in vivo tyrosine hydroxylase (TH) activity in carotid bodies and brainstem areas, assessed at postnatal day 7 (P7), P11 and P21. In pups prenatally exposed to nicotine, baseline ventilation and hypoxic ventilatory response were increased at P7 (+48%) and P11 (+46%), with increased tidal volume (p<0.05). Hypoxia blunted frequency response at P7 and revealed unstable ventilation at P11. In carotid bodies, TH activity increased by 20% at P7 and decreased by 48% at P11 (p<0.05). In most brainstem areas it was reduced by 20-33% until P11. Changes were resolved by P21. Prenatal nicotine led to postnatal ventilatory sequelae, partly resulting from impaired maturation of peripheral chemoreceptors and brainstem integrative sites.     

Characterisation of the ventilatory response to hypoxia in a model of transgenic anemic mice

Both polycythemia and the increase in hypoxic ventilatory response (HVR) are considered as important factors of acclimatization to hypoxia. The objective of this study was to characterise the ventilation pattern at different inspired oxygen fraction in a model of chronic anemic mice. These mice have a targeted disruption in the 5' untranslated region of the Epo gene that reduces Epo expression such that the homozygous animal is severely anemic. Ventilation in normoxia in Epo-TAg(h) mice was significantly greater than in wild type, and the difference was mainly due to a higher tidal volume. HVR was higher in Epo-TAg(h) mice at every FIO2 suggesting a higher chemosensitivity. Resting oxygen consumption was maintained in anemic mice. Maximal oxygen consumption was 30% lower while hemoglobin was 60% lower in anemic mice compared to wild type. This small decrease in maximal oxygen consumption is probably due a greater cardiac output and/or a better tissue oxygen extraction and would allow these anemic mice to acclimatize to hypoxia in spite of low oxygen carrying capacity. In conclusion, Epo-TAg(h) anemic mice showed increased ventilation and hypoxic ventilatory response. However, whether these adaptations will contribute to acclimatization in chronic hypoxia remains to be determined.     

Ibuprofen blocks time-dependent increases in hypoxic ventilation in rats

Recently, inflammatory processes have been shown to increase O(2)-sensitivity of the carotid body during chronic sustained hypoxia [Liu, X., He, L., Stensaas, L., Dinger, B., Fidone, S., 2009. Adaptation to chronic hypoxia involves immune cell invasion and increased expression of inflammatory cytokines in rat carotid body. Am. J. Physiol. Lung Cell Mol. Physiol. 296, L158-L166]. We hypothesized that blocking inflammation with ibuprofen would reduce ventilatory acclimatization to hypoxia by blocking such increases in carotid body O(2) sensitivity. We tested this in conscious rats treated with ibuprofen (4mg/kg IP daily) or saline during acclimatization to hypoxia ( [Formula: see text] for 7 days). Ibuprofen blocked the increase in hypoxic ventilation observed in chronically hypoxic rats treated with saline; ibuprofen had no effects on ventilation in normoxic control rats. Ibuprofen blocked increases in inflammatory cytokines (IL-1β, IL-6) in the brainstem with chronic hypoxia. The data supports our hypothesis and further analysis indicates that ibuprofen also blocks inflammatory processes in the central nervous system contributing to ventilatory acclimatization to hypoxia. Possible mechanisms linking inflammatory and hypoxic signaling are reviewed.     

Ventilatory responses during and following exposure to a hypoxic challenge in conscious mice deficient or null in S-nitrosoglutathione reductase

Exposure to a hypoxic challenge increases ventilation in wild-type (WT) mice that diminish during the challenge (roll-off) whereas return to room air causes an increase in ventilation (short-term facilitation, STF). Since plasma and tissue levels of ventilatory excitant S-nitrosothiols such as S-nitrosoglutathione (GSNO) increase during hypoxia, this study examined whether (1) the initial increase in ventilation is due to generation of GSNO, (2) roll-off is due to increased activity of the GSNO degrading enzyme, GSNO reductase (GSNOR), and (3) STF is limited by GSNOR activity. Initial ventilatory responses to hypoxic challenge (10% O₂, 90% N₂) were similar in WT, GSNO+/? and GSNO?/? mice. These responses diminished markedly during hypoxic challenge in WT mice whereas there was minimal roll-off in GSNOR+/? and GSNOR?/? mice. Finally, STF was greater in GSNOR+/? and GSNOR?/? mice than in WT mice (especially females). This study suggests that GSNOR degradation of GSNO is a vital step in the expression of ventilatory roll-off and that GSNOR suppresses STF.     

Characterization of hypoxia-induced ventilatory depression in newborn piglets

We evaluated the hypothesis that a 'central oxygen detector' in the brainstem is necessary for depressions of ventilatory activity to be manifested in the newborn. Decerebrate piglets, ventilated with 100 % O(2), were studied following neuromuscular blockade. The vagi and carotid sinus nerves were sectioned bilaterally in order to remove the influence of the peripheral chemoreceptors. Activity of the phrenic nerve was recorded as the index of the central respiratory rhythm. This activity declined and, in some preparations, ceased upon ventilation with air or a hypoxic gas, at either normocapnia or hypercapnia. The degree of depression in hypercapnic hypoxia was greatest in the youngest piglets. Following a medial section of the brainstem, extending to the caudal pons, the depression was reduced. In some preparations, a similar reduction followed the placement of radiofrequency lesions in the caudal ventromedial pons. We conclude that a region of the caudal mesencephalon or pons is necessary for the manifestation of depressions of ventilatory activity in the newborn pig.     

Respiratory, cerebrovascular and cardiovascular responses to isocapnic hypoxia

We simultaneously measured respiratory, cerebrovascular and cardiovascular responses to 10-min of isoxic hypoxia at three constant CO(2) tensions in 15 subjects. We observed four response patterns, some novel, for ventilation, middle cerebral artery blood flow velocity, heart rate and mean arterial blood pressure. The occurrence of the response patterns was correlated between some measures. Isoxic hyperoxic and hypoxic ventilatory sensitivities to CO(2) derived from these responses were equivalent to those measured with modified (Duffin) rebreathing tests, but cerebrovascular sensitivities were not. We suggest the different ventilatory response patterns reflect the time course of carotid body afferent activity; in some individuals, carotid body function changes during hypoxia in more complex ways than previously thought. We concluded that isoxic hyperoxic and hypoxic ventilatory sensitivities to CO(2) can be measured using multiple hypoxic ventilatory response tests only if care is taken choosing the isocapnic CO(2) levels used, but a similar approach to measuring the cerebrovascular response to isocapnic hyperoxia and hypoxia is unfeasible.     

Respiratory responses to intermittent hypoxia in unsedated piglets: relation to substance P binding in brainstem

Respiratory responses to single intermittent hypoxia (5 min 21% O(2), 5 min 8% O(2) X6) in 5-6, 10-11, 21-22 and 26-27 day-old piglets, and to recurrent six daily intermittent hypoxia in 10-11 and 26-27 day-old piglets were assessed. Substance P binding in the piglets' brainstem immediately after the last hypoxic episode was measured. All piglets hyperventilated during hypoxia. Weight adjusted inspired ventilation, tidal volume and instantaneous flow decreased with age. The oldest piglets uniquely displayed attenuated ventilation and tidal volume during the sixth versus first hypoxic episode with single intermittent hypoxia, and reduced inspired ventilation and tidal volume during the first hypoxic episode on the sixth daily hypoxia compared to single hypoxia. By contrast, substance P binding was greatly reduced in the solitary, hypoglossal, paraambigual and lateral reticular brainstem nuclei of both younger and older piglets following either single or recurrent intermittent hypoxia. Thus, the reduction in membrane-bound neurokinin receptors by intermittent hypoxia, presumably consequent to endogenously released substance P, does not exclusively determine whether the ventilatory response to that hypoxia will be attenuated or not.     

Functional erythropoietin autocrine loop in melanoma

Although erythropoietin (Epo) is a known stimulator of erythropoiesis, recent evidence suggests that its biological functions are not confined to hematopoietic cells. To elucidate the role of Epo and erythropoietin receptor (EpoR) in melanoma, we examined the expression and function of these proteins in melanocytes and melanoma cells. We found increased expression of Epo in melanoma cells compared to melanocyte in vitro. EpoR was also strongly expressed in all of the melanoma cell lines and two of the three melanocyte cell lines examined. Epo expression was significantly higher in melanoma than in benign nevi as determined by immunohistochemistry. Although melanoma cells secreted Epo in normoxic condition in vitro, hypoxia and CoCl(2) treatment increased Epo secretion. EpoR in melanoma cells was functional, because exogenous Epo increased melanoma resistance to hypoxic stress, pretreatment of melanoma cells with Epo significantly increased resistance to dacarbazine treatment, and Epo increased the phosphorylation of EpoR, RAF, and MEK. In conclusion, we demonstrated constitutive expression of Epo and EpoR as well as autonomous secretion of Epo by melanoma cells, indicating a novel autocrine loop of Epo in melanoma. The results suggest that the autocrine and paracrine functions of Epo might play a role in malignant transformation of melanocytes and in the survival of melanoma cells in hypoxia and other adverse conditions.     

Differential sensitivity to hypoxic inhibition of respiratory processes in the anesthetized rat

To estimate the sensitivity to hypoxic inhibition of various regulatory processes for respiration, changes in breathing pattern during hypoxic ventilatory depression (HVD) were analyzed in the halothane-anesthetized spontaneously breathing rat using a "progressive isocapnic hypoxia test." In the carotid sinus nerve (CSN) intact rats, ventilatory augmentation was followed by depression due to reduction in respiratory frequency (f) at end-tidal PO2 (PETO2) levels below 50-60 mmHg despite increased afferent activities from the carotid chemoreceptors. After CSN section, ventilation was progressively depressed at PETO2 lower than normoxic level with simultaneous decreases of f and tidal volume. An increase in CO2 stimulus or the prevention of arterial hypotension during hypoxia by infusing a vasoconstrictor agent (phenylephrine) inhibited the occurrence of ventilatory depression in both the CSN intact and denervated animals. In all cases studied, the reduction in f resulted mainly from the prolongation of expiratory time (TE). The results suggest that in the anesthetized rat the effect of respiratory stimulation from carotid chemoreceptor afferents becomes inadequate to offset the prolongation of TE due to the central hypoxia at lower PETO2, and that the neural process for regulating TE is the major site of deterioration during central hypoxic inhibition. Roles of CO2 stimulus and systemic circulatory conditions in the generation of HVD were also discussed.     

Dopaminergic mechanisms of neural plasticity in respiratory control: transgenic approaches

Data supporting the hypothesis that dopamine-2 receptors (D(2)-R) contribute to time-dependent changes in the hypoxic ventilatory response (HVR) during acclimatization to hypoxia are briefly reviewed. Previous experiments with transgenic animals (D(2)-R 'knockout' mice) support this hypothesis (J. Appl. Physiol. 89 (2000) 1142). However, those experiments could not determine (1) if D(2)-R in the carotid body, the CNS, or both were involved, or (2) if D(2)-R were necessary during the acclimatization to hypoxia versus some time prior to chronic hypoxia, e.g. during a critical period of development. Additional experiments on C57BL/6J mice support the idea that D(2)-R are critical during the period of exposure to hypoxia for normal ventilatory acclimatization. D(2)-R in carotid body chemoreceptors predominate under control conditions to inhibit normoxic ventilation, but excitatory effects of D(2)-R, presumably in the CNS, predominate after acclimatization to hypoxia. The inhibitory effects of D(2)-R in the carotid body are reset to operate primarily under hypoxic conditions in acclimatized rats, thereby optimizing O(2)-sensitivity.     

Intermittent hypoxia and plasticity of respiratory chemoreflexes in metamorphic bullfrog tadpoles

We tested the hypothesis that intermittent hypoxia elicits plasticity in respiratory chemoreflexes in bullfrog tadpoles. Metamorphic tadpoles (Taylor-Kollros stages XVI-XX) were subjected to intermittent hypoxia (PW(O(2))=45 Torr; 12 h/day) or constant normoxia (PW(O(2))=156 Torr) for 2 weeks before ventilatory responses to hypoxia and hypercarbia were measured. Buccal pressure changes were used to quantify the frequency and amplitude of movements associated with gill and lung ventilation. Morphometric assessment showed that intermittent hypoxia delayed development in comparison with controls. Oxygen consumption was enhanced in tadpoles subjected to intermittent hypoxia; however, this increase was not sufficient to affect basal ventilatory activity or the hypoxic ventilatory response. During acute hypercarbic exposure, tadpoles subjected to intermittent hypoxia showed (1) a greater decrease in gill ventilation frequency and (2) a greater increase in lung ventilation frequency than tadpoles maintained under control conditions. We conclude that intermittent hypoxia augments the responsiveness to hypercarbia, thereby promoting lung ventilation when animals face this stimulus. This manifestation of respiratory plasticity may reflect uncoupling between physiological and morphological development in the bi-modally breathing bullfrog tadpole.     

促红细胞生成素在斑马鱼胚胎发育中抑制肾脏细胞凋亡

目的:研究促红细胞生成素(Epo)在斑马鱼早期胚胎肾脏细胞发育中的凋亡和坏死方面起到的作用。方法:使用吗啉反义寡核苷酸技术通过胚胎注射使Epo及其受体(EpoR)的表达下调,并用real-time PCR及血红蛋白染色进行基因下调的有效性验证。在胚胎受精48 h观察肾脏形态并进行TUNEL凋亡染色,使用流式细胞术分析Annexin V凋亡染色,并用Western blot进行Akt磷酸化验证。结果:Epo及EpoR基因表达下调的斑马鱼胚胎在受精48 h可见明显肾小球囊样改变,且肾小管颈部缩短消失。TUNEL及Annexin V染色结果提示受精48 h后,Epo及EpoR基因表达下调的斑马鱼胚胎中肾脏凋亡细胞增多,但EpoR基因下调的斑马鱼胚胎内主要表现为晚期凋亡细胞及坏死细胞增多。Western blot实验结果提示Epo及EpoR基因表达下调的斑马鱼胚胎较对照组Akt磷酸化减少(P0.05)。结论:促红细胞生成素可引起Akt磷酸化。促红细胞生成素通过保护肾脏细胞免于凋亡和坏死而在斑马鱼胚胎肾脏发育中发挥重要作用。     

Enhanced erythropoietin expression in the brainstem of newborn rats at high altitude

In addition to its role in elevating red blood cell number, erythropoietin (Epo) exerts protective functions against acute and delayed degenerative diseases of the brain. Moreover, we have recently demonstrated that endogenously synthesized Epo and soluble Epo receptor (a negative regulator of Epo binding to the Epo receptor) in the central nervous system play a crucial role in facilitating the ventilatory response and acclimatization to hypoxia. Here we hypothesized that cerebral Epo in the brainstem is implicated in the process that allows cardiorespiratory acclimatization to high altitude hypoxia during the postnatal period. Thus, we evaluated the postnatal ontogeny of cerebral Epo concentration of Sprague-Dawley rats living and reproducing at high altitude for longer than 19 years (3600 m in La Paz, Bolivia). Our results show that postnatal Epo concentration in high-altitude rats is higher in the brainstem than in the forebrain. Moreover, although Epo concentration in the forebrain of high-altitude rats is similar to sea-level controls, Epo level in the brainstem is surprisingly 2-fold higher in high-altitude rats than in sea-level controls. These findings strongly suggest that brainstem Epo plays an important role in tolerance to high altitude hypoxia after birth. From a clinical perspective, a better understanding of the role of Epo in the postnatal development of cardiorespiratory responses in neonates exposed to acute or chronic hypoxia might be useful.     

Developmental plasticity of the hypoxic ventilatory response after perinatal hyperoxia and hypoxia

Both genetic and environmental factors influence the normal development of the respiratory control system. This review examines the role perinatal O2 plays in the development of normoxic breathing and the hypoxic ventilatory response in mammals. Hyperoxia and hypoxia elicit plasticity in respiratory control that is unique to development and may persist weeks to years after return to normoxia. Specifically, both hyperoxia and hypoxia during early postnatal development attenuate the adult hypoxic ventilatory response, but the underlying mechanisms for this plasticity differ. Hyperoxia attenuates the hypoxic ventilatory response through potentially life-long changes in carotid body function. Neonatal hypoxia appears to have short-term effects on carotid body function, but persistent changes in the hypoxic ventilatory response may instead reflect changes in respiratory mechanics or related neural pathways. Overall, it appears that a relatively narrow range of environmental O2 is consistent with "normal" postnatal respiratory control development, predisposing animals to potentially maladaptive plasticity in the face of disease or atypical environmental conditions.