Expression of heme oxygenase in the oxygen-sensing regions of the rostral ventrolateral medulla

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Expression of heme oxygenase in the oxygen-sensing regions of the rostral ventrolateral medulla

Emilio Mazza¹, Smita Thakkar-Varia², Carol A. Tozzi¹, and Judith A. Neubauer¹

¹ Division of Pulmonary and Critical Care Medicine, Department of Medicine, and ² Department of Neuroscience and Cell Biology, University of Medicine and Dentistry of New Jersey Robert Wood Johnson Medical School, New Brunswick, New Jersey 08903-0019

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES

Recently, unique regions in the rostral ventrolateral medulla (RVLM) have been found to be oxygen sensitive. However, themechanism of sensing oxygen in these RVLM regions is unknown.Because heme oxygenase (HO) has been shown to be involved in thehypoxic responses of the carotid body and pulmonary artery, theaim of this study was to determine whether HO is present in theRVLM and whether expression of HO is altered by chronic hypoxia.Adult rats were exposed to hypoxia (10% O₂) or normoxia (21% O₂)for 10 days, and the mRNA for HO-1 and HO-2 was examined in theRVLM by using RT-PCR. Expression of HO-2 mRNA was seen in theRVLM of both control and hypoxic samples, whereas expression ofHO-1 mRNA was only seen in the RVLM of hypoxic samples. HO-2 wasimmunocytochemically localized in brain sections (40 µm) to theC1 region and pre-Bötzinger complex of the RVLM. Together, theseresults indicate that HO-2 is present in the RVLM under controlconditions and that HO-1 is induced in the RVLM during chronichypoxia, consistent with a potential role for HO in the oxygen-sensingfunction of these cardiorespiratory RVLMregions.

oxygen chemosensitivity; respiration; sympathetic; chronic hypoxia; immunocytochemistry

	INTRODUCTION

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

CARDIORESPIRATORY NEURONS within the rostral ventrolateral medulla (RVLM) have been shown to be excited by hypoxia both invivo (36, 39) and in vitro (23, 40). Sun et al. (39)demonstrated that microinjection of NaCN in the C1 region of theRVLM produces an increase in tonic sympathetic output and an increasein arterial pressure. In addition, Solomon et al. (36) haveshown that local microinjection of NaCN into the pre-Bötzingercomplex, the hypothesized locus of respiratory rhythmogenesis,produces an augmentation in phrenic nerve output. The hypoxicsensitivity of these regions appears to be due to a direct oxygensensitivity of neurons because neurons cultured from these areasof the RVLM containing both the C1 region and pre-Bötzinger complexexhibit an intrinsic excitatory response to hypoxia (15). However,the mechanism(s) underlying this chemosensitive process isunknown.

In other oxygen-sensing systems, such as the carotid body and the pulmonary artery, heme oxygenase (HO) has been found tobe involved in the adaptive responses to hypoxia (4, 30,47). HO is an oxygen-dependent enzyme catalyzing the reactionthat converts heme into biliverdin and carbon monoxide, an importantsecond messenger within the central nervous system (13). Threeforms of HO have been described to date (14, 16). HO-1, aninducible isoform of the enzyme, has been shown to increase withhypoxia in the pulmonary artery and aorta and after transientischemia within the brain (7, 22, 24, 42). HO-2 is aconstitutive isoform of the enzyme whose expression is not affectedby these same stimuli (7, 14). A recently described form,HO-3, closely resembles HO-2 but is not well characterized asfar as stimuli that affect its expression (16). HO-1 and HO-2expression have been shown in several areas of the brain (6),but their presence in the RVLM has not beendescribed.

If HO is to be considered a potential candidate involved in the acute and/or adaptive responses of the cardiorespiratory regionsof the rostral medulla, its presence in these regions must firstbe demonstrated. Thus the specific aims of this study were todetermine 1) whether the constitutive form of the enzyme, HO-2,is expressed in the RVLM of adult rats during control normoxicconditions; and 2) whether the inducible form of the enzyme, HO-1,is expressed in the RVLM in rats exposed to 10 days of chronichypoxia.

	METHODS

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

Hypoxic exposure of adult rats. Six-week-old Sprague-Dawley rats (200-250 g) were exposed to hypoxia (10% O₂-90% N₂ at ambient pressure; n = 8) while correspondingage-matched controls were maintained in room air (21% O₂; n =8) in a Plexiglas chamber for 10 days. The Plexiglas chamber wasmonitored via a computer for percent oxygen and carbon dioxideand contained soda lime to maintain carbon dioxide at atmosphericlevels. Plexiglas chamber temperature was maintained at 37°C duringthe entire exposure period. Animals were fed ad libitum with standardrat chow andwater.

RT-PCR. For RT-PCR experiments, animals were anesthetized with pentobarbital sodium (30 mg/kg) and the brain, aorta, pulmonary artery,and lung were quickly dissected. Because HO-2 is present in thelungs and pulmonary and systemic arteries and HO-1 is inducibleunder hypoxic conditions (3, 17, 20, 43, 47), samplesof the lung, aorta, and pulmonary artery were used as positivecontrols. The brain was dissected to remove the cerebral hemispheres,cerebellum, and brain stem. Cerebral hemisphere samples consistedof the entire cortex, including the subcortical nuclei. The brainstem was further dissected to remove the RVLM. The pulmonary arterytrunk, the entire left extrapulmonary artery, and proximal 3 mmof the right pulmonary artery were excised en bloc. The aortasample included the proximal ascending aorta, aortic arch, andpart of the descending aorta. Lung samples were derived from peripherallung tissue and contained muscular pulmonary arteries. All studieswere done twice on individual pooled tissues from their respectiveoxygen-exposuregroup.

Total RNA (50 µg), from control and hypoxic tissues, was extracted by the guanidine isothiocyanate method and employed tosynthesize single-stranded cDNA by RT-PCR by adding 750 U Moloneymurine leukemia virus reverse transcriptase and 50-100 pmol ofoligo(dT)_12-18. An aliquot of the single-stranded cDNA wasprimed with the two oligonucleotide primers 5'-GAA TTC AGC ATGCCC CAG GAT TTG-3' and 5'-TCT AGA CTA GCT GGA TGT TGA GCA GGA-3'complementary to the rat HO-1 cDNA to amplify a 615-bp fragmentand 5'-GAA TTC GGG ACC AAG GAA GCA CAT-3' and 5'-TCT AGA CTA TGTAGT ACC AGG CCA AGA-3' complementary to the rat HO-2 cDNA to amplifyan 828-bp fragment (20). PCR fragments generated using theseprimer pairs had been cloned and sequenced to confirm their identity(20). Amplification was performed in a 100-µl reaction mixture(50 mM NaCl, 10 mM KCl, 10 mM Tris · HCl, 1.5 mM MgCl₂, 3 mM dithiothreitol,gelatin, and 200 µM each of nucleotide triphosphates, pH 8.8)containing 2.5 U of Taq polymerase. The reaction was carried outon a DNA thermal cycler (model 480, Perkin-Elmer Cetus Instruments)for 35 cycles as follows: denaturation at 94°C, 1.5 min; annealingat 54°C, 1 min; extension at 75°C, 1.5 min; and final extension,10 min. The RT-PCR products were electrophoresed on an agarosegel and blotted onto nitrocellulose, and Southern blot analysiswasperformed.

Immunocytochemistry and tissue sections. Brain sections were prepared for immunocytochemical localization of HO in the following manner. Adult rats were anesthetizedwith pentobarbital sodium (30 mg/kg) and transcardially perfusedwith heparinized saline followed by 4% paraformaldehyde (in PBS,pH 7.4; Sigma Chemical) by using gravity flow for 1 h. The entirebrain, including cerebellum and brain stem, was carefully removedand placed in 4% paraformaldehyde overnight at 5°C. The tissuewas cryoprotected in 4% paraformaldehyde containing 30% sucrosesolution for 72 h at 5°C. The tissue was then thoroughly frozenon dry ice, coated with embedding matrix (Lipshaw), and sectioned(40 µm on a cryostatmicrotome).

Sections were processed for HO-2 immunocytochemistry according to a protocol modified from Ewing and Maines (6) using free-floatingsections. Specifically, brain sections were placed in six-wellculture trays (Falcon) immediately after cryosectioning and incubatedin 3% Triton X-100 (Sigma Chemical) and 10% goat serum at roomtemperature for 20 min. The sections were washed three times withPBS (pH 7.4) over 10 min and then placed in culture trays containingpolyclonal rabbit anti-rat HO-2 primary antibody (1:1,000; StressGen)diluted in PBS containing 0.3% Triton X-100 and 10% goat serumand incubated for 4 days at 5°C. The HO-2 antibody is raised againstpurified rat testes HO-2 and has been shown to be specific forthe HO-2 isoform (6, 14). The sections were then thoroughlywashed and incubated in a goat anti-rabbit secondary antibodylabeled with fluorescein isothiocyanate (1:100; Sigma Chemical)diluted in PBS containing 0.01% Triton X-100, 1% goat serum, and0.1% sodium azide for 2 h at room temperature. The sections werethen washed in distilled water and mounted on gelatin-coated glassslides (Fisher) with Gelmount (Biomeda). Control sections forbackground staining were processed as above except sections wereincubated in PBS lacking primary antibody and containing 0.3%Triton X-100 and 10% goat serum for 4 days at 5°C. Sections werevisualized for immunoreactivity and photographs taken by usingan upright microscope with fluorescent optics (Optiphot-Nikon).Serial sections not processed for HO-2 were directly mounted ongelatin-coated glass slides after cryosectioning and stained withneutral red to visualize cell bodies for anatomic localizationof nuclei. Cell nuclei were identified according to stereotaxicanatomy as described by Paxinos and Watson (25).

	RESULTS

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

Expression of HO mRNA in the RVLM. The expression of the mRNA for HO-2 was examined in both control and hypoxic tissues obtained from eight adult male rats (Fig.1). Samples from the pulmonary artery, aorta, and lung servedas positive controls because these tissues have been shown inprevious studies to express HO-2 mRNA (17, 43, 47). Consistentwith these previous reports, Fig. 1 demonstrates that an 828-bpfragment corresponding to HO-2 was seen in the pulmonary artery,aorta, and lung derived from both control (lane C) and hypoxic(lane H) rats. Expression of HO-2 was also observed in the RVLMfrom both control and hypoxic animals (Fig. 1). Thus the RVLMconstitutively expresses HO-2 under both normoxic and chronicallyhypoxic conditions.

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Fig. 1. RT-PCR amplification of heme oxygenase-2 in pulmonary artery (PA), aorta, rostral ventrolateral medulla (RVLM), and lung after exposure to either 21% O₂ (C) or 10% O₂ (H). An 828-bp heme oxygenase-2-specific fragment was detected in both control (lane C) and hypoxic (lane H) tissues. M, molecular weight markers.

The expression of HO-1 mRNA was also examined in both control and hypoxic tissue samples of the RVLM, pulmonary artery, aorta,cerebral hemispheres, and cerebellum (Fig. 2). Expression of a615-bp specific HO-1 fragment was not detected in tissue samplesfrom control rats (lane C) but was induced by hypoxia (lane H)in the pulmonary artery, aorta, and RVLM. HO-1 mRNA was not detectedin the cerebellum or cerebral hemispheres obtained from eithercontrol (lane C) or hypoxic (lane H) rats. HO-1 has been shownpreviously to be induced by hypoxia in the pulmonary artery andaorta (20, 43). Within the brain, the hypoxic induction ofHO-1 mRNA expression in the brain was localized to the RVLM. Takentogether, the constitutive expression of HO-2 in the RVLM, aswell as the induced expression of HO-1 in the RVLM during chronichypoxia, suggests that this enzyme may have an important functionduring hypoxic conditions.

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Fig. 2. RT-PCR amplification of heme oxygenase-1 in PA, aorta, RVLM, cerebellum (Cb), and cerebral hemispheres (CH) after exposure to either 21% O₂ (lane C) or 10% O₂ (lane H). A 615-bp heme oxygenase-1-specific fragment was induced by hypoxia (lane H) in the RVLM, PA, and aorta compared with tissue derived from control animals (lane C). In contrast, HO-1 was not detected in the Cb or CH. B, blank, no DNA.

Immunocytochemical localization of HO-2 in the RVLM. Immunocytochemical techniques were utilized to determine whether expression of HO-2 within the RVLM was localized to the sympathetic(C1, lateral reticular nucleus) and respiratory (pre-Bötzingercomplex) regions of the RVLM. In addition, the expression of HO-2was determined in regions of the brain that have been shown previouslyto express HO-2, such as the cerebellum, trapezoid nucleus, mesencephalictrigeminal nucleus, and facial nucleus (6). As shown in Fig.3, immunoreactive staining for HO-2 was found in cells withinthe cerebellum, trapezoid nucleus, mesencephalic trigeminal nucleus,facial nucleus, and hypoglossal nucleus. Within the RVLM, HO-2was found to be localized in cell bodies in an area containingthe C1 region and pre-Bötzinger complex (Fig. 4, A and B). Inmore caudal extents of the RVLM, the lateral reticular nucleuswas also immunoreactive for HO-2 (Fig. 4, D and E). Sections ofthe RVLM processed without the primary antibody for HO-2 did notshow any staining (Fig. 4, C and F).

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Fig. 3. Immunocytochemical staining for heme oxygenase-2 within different regions of the brain. Heme oxygenase-2-specific staining was seen in the cerebellum (A and B), trapezoid nucleus. (Tz; C and D), mesencephalic trigeminal nucleus (MeT; E and F), facial nucleus (Fa; G), and hypoglossal nucleus (Hy; H). Mol, molecular cell layer; Pj, Purkinje cell layer; Gr, granular cell layer. Magnification of A and E, ×40 (calibration bar 500 µm); B, C, G, and H, ×100 (calibration bar 200 µm); D and F, ×200 (calibration bar 100 µm).

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Fig. 4. Immunocytochemical staining for heme oxygenase-2 in brain sections showing specific staining for nuclei and cell bodies within the RVLM. A and B: specific immunostaining of the C1 region and pre-Bötzinger complex (PreBotC) of the RVLM. C: negative control of the C1 region and PreBotC in which primary antibody was omitted from the staining protocol. D and E: specific immunostaining of the lateral reticular nucleus (LatR) localized to more caudal aspects of the RVLM. F: negative control of the LatR in which primary antibody was omitted from the staining protocol. Magnification of A and D, ×40 (calibration bar 500 µm); B and E, ×200 (calibration bar 100 µm); C and F, ×100 (calibration bar 200 µm).

	DISCUSSION

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

The results of this study demonstrate, for the first time, expression of HO within cardiorespiratory regions of the RVLM.The expression of the mRNA of the constitutive form of the enzyme,HO-2, was maintained under normoxic and hypoxic conditions, whereasexpression of the inducible form, HO-1, was only seen after exposureto hypoxia. Immunocytochemistry showed that HO-2 localized todiscrete regions of the RVLM, specifically the sympathoexcitatoryC1 region and respiratory pre-Bötzinger complex. The functionalrelevance of HO in these cardiorespiratory regions was not exploredin this study. However, HO regulates the production of carbonmonoxide, an important chemical messenger in the brain, whichcould modulate the hypoxic responses of these medullaryregions.

Expression of HO-2 is not unique to the RVLM. With the use of in situ hybridization and immunocytochemistry, HO-2 has beenfound by others to be localized in a number of brain regions (6,44). Consistent with these previous reports, we found a distributionof HO-2 within subpopulations of neurons in the central nervoussystem, including the cerebellum, trigeminal, trapezoid, and facialnuclei. The novel observation in this study, however, was thelocalization of HO in the RVLM. Within the RVLM, the mRNA forHO-2 was constitutively expressed under both control and hypoxicconditions. This constitutive pattern of expression was similarto the pattern of expression of HO-2 mRNA in the lung, pulmonaryartery, and aorta that has been shown in previous studies (17,20, 43, 47) and implies that HO-2 probably has a tonic influenceon cell function. In contrast, expression of HO-1 in the brainwas only seen during hypoxia and then only in the RVLM and notin the cerebellum or cerebral hemispheres, possibly implicatingHO-1 in the adaptive response to chronic hypoxia. Although HO-1expression can be induced by heat shock and focal ischemia inseveral regions of the brain (6, 22, 42), the observationthat the chronic hypoxia used in this study did not produce aglobal increase in HO-1 within the brain may suggest that hypoxiais a specific stimulus for the induction of HO-1 in the RVLM.An alternative explanation is that, although the level of hypoxiaused in this study (10% O₂ for 10 days) was sufficient to stimulatetranscription of the HO-1 gene in the RVLM, it may have been insufficientto stimulate expression of HO-1 in the cerebellum or cerebralhemispheres. Thus there could be a difference in the oxygen sensitivitywith a lower threshold for induction in the RVLM than in otherbrain regions. Further studies examining different levels of hypoxiaon the regional expression of HO-1 in the brain would be neededto address this question. Nevertheless, a greater sensitivityfor induction of HO-1 in the RVLM may be important for the cardiorespiratoryadaptations of this region during chronichypoxia.

The expression of HO within the C1 region and pre-Bötzinger complex of the RVLM is presumably related to some function ofthese regions. One function of interest is the recent observationthat these regions can be excited by acute localized hypoxia invivo, resulting in an augmentation of sympathetic and respiratoryoutput, respectively (36, 39, 41). Studies in vitro haveconfirmed this observation by demonstrating that a subpopulationof neurons cultured from the RVLM of neonatal rats containingthe pre-Bötzinger complex and C1 region are excited by acutehypoxia (15). If HO is important for oxygen sensing in theseneurons, a potential implication of the present finding is thatthis enzyme may be a potential marker for the hypoxia-excitedneurons in these cardiorespiratoryregions.

The functional significance for the presence of HO in the RVLM in both its constitutive and inducible isoforms may well belinked to the oxygen-sensing properties of this region. Oxygensensitivity of these medullary cardiorespiratory regions couldutilize similar mechanisms as other oxygen-sensitive structures.With regard to the one such organ, the carotid body, several hypotheseshave been proposed to explain the oxygen-sensing mechanism, butone theory has consistently implicated the involvement of a heme-typeoxygen-sensor protein in the oxygen-sensing process. This hemeprotein hypothesis proposes that changes in oxygen levels aresensed by a heme protein, which then, either directly or indirectly,modulates the conductance of ion channels altering the excitabilityof the cell (2, 29). Several heme-containing proteins havebeen proposed as potential candidate oxygen sensors in the carotidbody, including mitochondrial cytochromes, NADPH oxidases, NADPH-cytochromec reductase, nitric oxide synthase, and HO (1, 5, 18,19, 27-31).

HO also appears to modulate the oxygen-sensing process of the carotid body during both normoxic and hypoxic conditions. Presumably,it is the ability of HO to catalyze the reaction of heme and oxygento produce carbon monoxide (13) that is key to its influenceon the oxygen sensitivity of the cell. Endogenously produced carbonmonoxide is now recognized as an important chemical messengerlargely because of its ability to activate a host of other hemeenzymes, including the stimulation of soluble guanylate cyclase(9, 32, 38). But the effect of carbon monoxide on the sensorydischarge of the carotid body has been shown to be both excitatoryand inhibitory. For example, Lahiri et al. (10) found that exogenouslyapplied carbon monoxide stimulates carotid body discharge undernormoxic conditions, mimicking the effect of hypoxia. In contrast,Prabhakar and colleagues (27, 28, 30), using blockers ofHO, found that the endogenous production of carbon monoxide hasa tonic inhibitory effect on the carotid body. These investigatorswent on to suggest that HO modulates the excitability of the carotidbody by limiting the production of CO when oxygen is reduced,thereby promoting a disinhibition of carotid sensory discharge.Whether HO modulates the excitability of oxygen-sensitive RVLMneurons in the same manner is a possibility; however, the centraleffects of this chemical messenger need not mimic its peripheralpattern.

Whether and how CO modulates the excitability of central neurons appear to vary widely within the central nervous system.In the case where carbon monoxide has been used to produce progressivecarboxyhemoglobinemia to limit oxygen delivery to the brain, initialincreases in carboxyhemoglobin are associated with a generalizeddepression of respiration concomitant with an excitation of tonicsympathetic activity (21, 45). As the level of carboxyhemoglobinincreases, there is a general excitation of both sympathetic andrespiratory activity (45), suggesting either a threshold phenomenonand/or a neural release of the central respiratory chemosensitiveelements (35, 36). Of interest is that HO has been shown tomodulate the excitability of neurons in various sites within thecentral nervous system as well as olfactory receptor cells (8,12, 26, 48). For example, HO regulates depolarization-inducedglutamate release in the cortex (34), long-term potentiationin the hippocampus (8, 37, 48) and the intrinsic excitabilityof olfactory receptors and locus coeruleus neurons by the regulationof cGMP-gated ion channels (8, 12, 26, 48). Because theseeffects on neuronal excitability are presumably mediated throughcarbon monoxide, it is important to note that areas within thebrain immunoreactive for HO-2 produce measurable levels of carbonmonoxide (11). Thus it seems reasonable to propose that thepresence of HO in the RVLM would favor a functional role for thisenzyme in modulating the excitability of cardiorespiratory neuronsduring changes in tissueoxygenation.

Whether the induction of HO-1 within the RVLM during sustained hypoxia plays a role in the chronic adaptations of respirationand sympathetic activity remains to be studied. However, the inductionof HO-1 mRNA reflects an oxygen-sensitive change in gene expression.This increase in HO-1 gene transcription is mediated by the transcriptionalregulator hypoxia-inducible factor-1, which plays a key role inthe oxygen sensitivity of a large number of genes involved inangiogenesis, energy metabolism, erythropoiesis, cell proliferationand viability, vascular remodeling, and vasomotor responses (33).

Conclusion. In conclusion, we have shown that mRNA for HO-2, the constitutive form of the enzyme, is present in the RVLM in adult ratsunder room air and chronic hypoxia conditions. In addition, themRNA for the inducible form of the enzyme, HO-1, can be inducedin the RVLM in rats exposed to chronic hypoxia. The expressionof HO-2 within the RVLM is localized to the C1 region and pre-Bötzingercomplex, areas shown in vivo to be excited by hypoxia. Localizationof HO within the RVLM suggests that this enzyme may be importantto the oxygen-sensing function of thisregion.

	ACKNOWLEDGEMENTS

The authors thank Theresa Hoang-Le and Maria Zingariello for excellent technical assistance and Marcella Spioch for expertpreparation of themanuscript.

	FOOTNOTES

This work was supported by National Heart, Lung, and Blood Institute Research Grant HL-58730 and by a Predoctoral FellowshipAward from the American Heart Association, New JerseyAffiliate.

Address for reprint requests and other correspondence: J. A. Neubauer, Div. of Pulmonary and Critical Care Medicine, Dept.of Medicine, UMDNJ-Robert Wood Johnson Medical School, One RobertWood Johnson Place-PO Box 19, New Brunswick, NJ 08903-0019 (E-mail:neubauer{at}umdnj.edu).

The costs of publication of this article were defrayed in part by the payment of page charges. The article must thereforebe hereby marked "advertisement" in accordance with 18 U.S.C.Section 1734 solely to indicate thisfact.

Received 9 June 2000; accepted in final form 7 February 2001.

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