Carotid Body Remodelling in l -NAME-Induced Hypertension in the Rat

J. Comp. Path. 2012, Vol. 146, 348e356

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EXPERIMENTALLY INDUCED DISEASE

Carotid Body Remodelling in L-NAME-Induced Hypertension in the Rat A. S. Felix, V. N. Rocha, A. L. R. Nascimento and J. J. de Carvalho Laboratory of Ultrastructure and Tissue Biology, Institute of Biology Roberto Alcantara Gomes, State University of Rio de Janeiro, Rio de Janeiro, Brazil

Summary The carotid body (CB) is a chemoreceptor organ located at the bifurcation of the common carotid artery. It is made up of the carotid glomus, a structure containing type 1 cells surrounded by type 2 cells. The aim of this study was to evaluate the morphological changes of the CB and carotid glomus in the rat model of L-NAME-induced hypertension. Male Wistar rats were divided in two groups: control untreated rats (C) and rats receiving L-NAME 40 mg/kg/day (LN) for 6 weeks. At the end of the experiment, the systolic blood pressure was 63% higher in the LN group compared with the C group. Morphometric analysis showed that the area of the CB was 29% greater in the LN group compared with the C group. The density of nuclei in the CB was similar between groups, but it was 31% less in the carotid glomus of the LN group. Cells in the CB of the LN group displayed cytoplasmic vacuolation and expressed several biogenic amines. There were more elastic fibres, proteoglycans and collagen fibres in the LN group compared with the C group. Immunohistochemistry showed increased expression of nuclear factor kB, substance P, vascular endothelial growth factor and neuronal nitric oxide synthase in the LN group, while expression of the protein gene product 9.5 was decreased. L-NAME alters cell morphology and the expression of extracellular matrix molecules in the CB and carotid glomus in rats with L-NAME-induced hypertension. Ó 2011 Elsevier Ltd. All rights reserved. Keywords: carotid body; carotid glomus; hypertension; L-NAME

Introduction Systemic hypertension augments the risk of morbidity and mortality due to cardiovascular disease (Mayet and Hughes, 2003; Gkaliagkousi et al., 2010; Park et al., 2010; Wang et al., 2010). The endothelium plays a central role in regulating the vascular tone through the synthesis and release of vasoactive substances such as nitric oxide (NO), prostaglandin (PG) I2 and endothelium-derived hyperpolarizing factor (EDHF), as well as vasoconstrictor factors (Qin et al., 2000; Gkaliagkousi et al., 2010). Endothelial dysfunction in hypertension triggers an imbalance between the production and release of these factors, increasing the generation of reactive oxygen species and diminishing NO synthesis and bioavailability. L-arginine is the precursor of NO Correspondence to: J. J. de Carvalho (e-mail: [email protected]). 0021-9975/$ - see front matter doi:10.1016/j.jcpa.2011.07.007

synthesis by NO synthase (NOS), an enzyme that exists in three isoforms: neuronal (nNOS), inducible (iNOS) and endothelial (eNOS) (Moncada and Higgs, 2006). Administration of L-arginine analogues such as L-NAME (hydrochloride NG-nitro-methylester-L-arginine) inhibits NOS activity and hence NO biosynthesis, leading to hypertension (Nakanishi et al., 1995; Swislocki et al., 1995; Fink et al., 1998; Bernatova et al., 1999; Fernandes-Santos et al., 2006). The carotid body (CB) is a chemoreceptor organ located at the bifurcation of the common carotid artery. The CB senses blood gas levels and regulates ventilation (Biscoe, 1971; Feng et al., 2008; Abudara and Eyzaguirre, 2008; Izal-Azcarate et al., 2008; Torres, 2009). It has a neural origin that can be characterized by the presence of the protein gene product 9.5 (PGP 9.5), a hydrolase found in neural and neuroendocrine tissues (Wilkinson, 2000). In rats, the CB consists of cellular aggregates (the carotid Ó 2011 Elsevier Ltd. All rights reserved.

Carotid Body Morphology in Hypertension

glomus) interspersed between blood vessels and nerve bundles. The carotid glomus has four to seven type 1 cells (or glomus cells) incompletely surrounded by two to three type 2 cells (or sustentacular cells) (Izal-Azcarate et al., 2008). Type 1 cells are characterized by the presence of numerous cytoplasmic vesicles containing dopamine, a biogenic amine, and gap junctions between adjacent cells (Morgan et al., 1975; Eyzaguirre, 2005). Afferent nerve endings establish synaptic contact with one or more type 1 cells (Rigual et al., 1991; Conde et al., 2006). Taquinin is an excitatory neurotransmitter that has a role in the brainstem-mediated response to CB stimulation. The tachykinin, P substance (PS) and the amino acid, L-glutamate, appear to be important excitatory neurotransmitters. PS acts on NK1 (PS receptor), a typical G protein-coupled receptor located in the afferent nerve endings of the CB (Mazzone et al., 1997). The extracellular matrix of the CB is composed of ground substance (i.e. glycosaminoglycans, proteoglycans and adhesive glycoproteins) and fibres (Evangelisti et al., 1984; Boudreau and Rabinovitch, 1991). However, data are scant regarding CB morphology in hypertension. It is known that there is a significant increase in CB volume in spontaneously hypertensive rats (SHRs) compared with normotensive Wistar Kyoto rats (Habeck et al., 1987). Similarly, New Zealand genetically hypertensive rats have fewer type 1 cells than control rats (Bee et al., 1989). Finally, abnormalities in dopamine production have been described in severe hypertension in man (Murphy et al., 2001). We hypothesize that systemic hypertension changes the normal morphology and protein expression of the CB. The aim of the present study was to characterize the morphological changes in the CB and carotid glomus in the rat model of L-NAME-induced hypertension.

Materials and Methods Animals and Sample collection

Three-month old Male Wistar rats were obtained from the State University of Rio de Janeiro (UERJ). Rats were kept under standard housing conditions (21
2 C, 60
10% humidity and a 12 h lightedark cycle) and received water and standard rodent chow (Nuvilab, Parana, Brazil) ad libitum. All procedures were approved by the Ethics and Research Committee of the Institute of Biology Roberto Alcantara Gomes/UERJ (Protocol 257/08) and were carried out in accordance with the conventional guidelines for the Care and Use of Laboratory Animals (US National Institutes of Health, revised 1996).

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Animals were divided into two groups (n ¼ 10): untreated rats (control group, C) or rats treated with L-NAME (SigmaeAldrich, St Louis, Missouri, USA) at a dosage of 40 mg/kg/day in their drinking water (L-NAME group, LN) (Bernatova et al., 1999; Kasal et al., 2008). Body mass and systolic blood pressure (SBP) were measured weekly throughout the 6 weeks of the experiment by plethysmographic flow (LETICA LE 5100; Panlab, Barcelona, Spain). At the end of the experiment, rats were anaesthetized with sodium pentobarbital (50 mg/kg by intraperitoneal injection). An incision was made in the neck to expose the carotid bifurcation and then the CB was rapidly freed from adherent adipose and connective tissue for isolation and fixation. Samples were collected from both sides of the neck and processed for light (n ¼ 6) and electron (n ¼ 4) microscopy. Microscopy

CB samples were fixed in 4% paraformaldehyde in 5 mM CaCl2 and in 0.1% glutaraldehyde and were processed routinely and embedded in paraplast plus (SigmaeAldrich). Sections (3 mm) were stained with haematoxylin and eosin (HE), Weigert’s resorcinfuchsin (Fullmer, 1960), picrosirius red (to demonstrate collagen fibres) (Puchtler et al., 1973) and alcian blue pH 2.5 (to demonstrate proteoglycans) (Whiteman, 1973). In order to study the vesicles containing biological amines, CB samples were examined with a laser scanning confocal microscope (LSM 510 Meta; Carl Zeiss, G€ottingen, Germany) using formaldehyde-induced fluorescence (FIF).

Immunohistochemistry

CB sections were incubated with primary antibodies specific for: vascular endothelial growth factor (VEGF; dilution 1 in 100; Santa Cruz Biotechnology, Santa Cruz, California, USA; sc-7269), nuclear factor kB (NF-kB; dilution 1 in 100; Santa Cruz Biotechnology; sc-114), substance P (PS; dilution 1 in 100; Chemicon, Billerica, Massachusetts, USA; AB1566), nNOS (dilution 1 in 50, Santa Cruz Biotechnology; sc-648) and PGP 9.5 (dilution 1 in 50; Abcam; AB8189). The reaction was amplified using a biotinestreptavidin complex system (LSAB Kit Universal; DakoCytomation, Glostrup, Denmark) and the immunolabelling was ‘visualized’ after incubation with 3, 30 diaminobenzidine tetrachloride (DAB; DakoCytomation). Sections were counterstained with Mayer’s haematoxylin.

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Electron Microscopy

CB samples fixed in 2.5% glutaraldehyde in 0.1 M cacodylate buffer (pH 7.2) and 0.25% tannic acid (Merck, Darmstadt, Germany) were post-fixed in osmium tetroxide 1% (SigmaeAldrich) and potassium ferrocyanide 0.8% in 0.1 M cacodylate buffer (pH 7.2) for 1 h and then dehydrated in acetone and embedded in Epon (Embed-812; Electron Microscopy Sciences, Hatfield, Pennsylvania, USA). Semithin sections (1 mm) were stained with toluidine blue and observed by light microscopy to select the areas of interest. Ultrathin sections (Leica Ultracut-UCT, Vienna, Austria) were contrasted with uranyl acetate and lead citrate and analyzed with a transmission electron microscope (Zeiss EM 906; Carl Zeiss, Oberkochen, Germany) at 80 kV. CB sections were fixed in paraformaldehyde 4%, processed and embedded in LR-White resin for immunoelectronmicroscopical analysis of expression of the enzyme tyrosine hydroxylase (TH). The secondary antibodies were conjugated to colloidal gold particles (10 nm). After immunolabelling, the sections were contrasted with uranyl acetate and lead citrate and analyzed by transmission electron microscopy (TEM) as above.

Fig. 1. Selection of the CB area chosen for measurement. Measurement was performed by the functions ‘clear outside’ and ‘measure’ of the Image J software.

the Student’s t-test. P # 0.05 was considered statistically significant (GraphPad Prism version 5.03, San Diego, California, USA).

Morphometry

Digital images were obtained using a digital camera (Olympus DP70, Tokyo, Japan) attached to a microscope (Olympus BX51). Sections stained with HE were used to quantify the density of nuclei in the CB and carotid glomus. Firstly, the boundary of the CB was outlined and its area was assessed (Image J software version 1.4, National Institutes of Health, Bethesda, Maryland, USA). Then, all nuclei (type 1 and type 2 cells) located inside the carotid glomus were quantified. The density of nuclei per CB (nuclei/mm2 of CB area) was calculated as: number of nuclei/image area (Fig. 1). Secondly, to quantify the density of nuclei in the carotid glomus, its boundary was first outlined and the area calculated. Then, the number of nuclei inside the carotid glomus was automatically calculated by the software. The density of nuclei per carotid glomus (nuclei/mm2 of carotid glomus area) was calculated as: number of cells inside the carotid glomus/carotid glomus area. Seven rats were analyzed per group and for each sample, 20 fields were examined, totalling 140 fields per group.

Results L-NAME increased the SBP and induced body weight loss in the LN group compared with the C group (Table 1). A difference in SBP was first noticed in the second week of the experiment and it increased in the following weeks. SBP reached 190
7.01 mmHg in the LN group compared with 122.2
2.51 mmHg in the C group (an increase of 63%). Body weight was similar between C and LN groups at the beginning

Table 1 Blood pressure, body mass and CB morphometry Control

L-NAME

P

117
5.8 190
7.01

NS 0.0001

265.4
13.0 306.0
14.9 152,400
12,030 5,877
361 4,936
378

NS 0.0002 0.0056 NS 0.0003

Statistics

Blood pressure (mm Hg) Initial 120
7.0 Final 122.2
2.51 Body mass (g) Initial 271.3
9.0 Final 375.6
24.2 106,000
7,181 CB area (mm2) 6,602
160 Nuclei/CB (mm2) 7,190
350 Nuclei/carotid glomus (mm2)

Data are shown as mean and standard error of the mean (SEM). Data were tested for normality. Differences between the C and LN groups were analyzed by

Data are shown as mean
SEM, Student’s t-test. Initial refers to data assessed before the beginning of the experiment (week 0) and final are data on week 6. NS, non-significant.

Carotid Body Morphology in Hypertension

of the experiment, but it had decreased by 19% in LN group in the 6th week compared with the C group. The CB area increased in the LN group by 29% compared with the C group (Table 1). The density of nuclei in the CB was similar between the C and LN groups, suggesting CB cell hypertrophy rather than hyperplasia. Additionally, the density of nuclei in the carotid glomus was 31% less in the LN group compared with the C group. L-NAME-induced morphological changes in the carotid glomus are shown in Fig. 1. In the LN group, the regular morphology of the CB was lost as the carotid glomus cells were hypertrophic and had cytoplasmic vacuolation (Figs. 2a, b). The FIF technique allows the visualization of biogenic amines, and there was a greater amount of these in the LN group compared with the C group (Figs. 2c, d). Some electron-dense granules were

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found in the cytoplasm of cells of the carotid glomus in the C group, but these were more frequently seen in the LN group (Figs. 2e, f). The presence of vacuoles in the cytoplasm of the carotid glomus cells (Figs. 2e, f) was also evident by TEM. TEM analysis for expression of TH showed reduced expression of the enzyme in the cytoplasm of type 1 cells in the LN group compared with those cells in the C group. Colloidal gold particles were found in smaller numbers in the hypertensive group (LN) (Fig. 3). Morphological changes in the extracellular matrix are depicted in Fig. 4. The LN group displayed more elastic fibres (Figs. 4a, b) and proteoglycans (Figs. 4c, d) compared with the C group. The picrosirius red stain, without (Figs. 4e, f) or with (Figs. 4g, h) light polarization, revealed an increased number of collagen fibres in the LN group compared with the C group.

Fig. 2. CB structure and ultrastructure. (a, b) Photomicrographs. HE. Bar, 30 mm. (c, d) FIF; arrows indicate biogenic amines. Bar, 30 mm. (e, f) TEM of the CB. Bar, 2 mm. White arrows indicate the biogenic amines in the CB. Oval white arrows show the location of biogenic amines in cells of the carotid glomus.

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Fig. 3. Immunoelectronmicroscopy of the CB with primary anti-TH antibody and a secondary antibody conjugated to 10 nm colloidal gold particles. White arrows indicate the labelling in the cytoplasm of the CB type 1 cells. (a, b) Group C. (c, d) LN group.

The expression of five different proteins was analyzed by immunohistochemistry. L-NAME treatment increased the expression of NF-kB, substance P, VEGF and nNOS compared with the C group. PGP 9.5 was the only protein that had its expression diminished by L-NAME treatment. NF-kB was expressed in the extracellular matrix, while substance P and PGP 9.5 were found in the carotid glomus. VEGF was mainly expressed by glomus cells in the C group, but it was distributed in scattered fashion throughout the cytoplasm of glomus cells and blood vessels in the LN group. Finally, nNOS was more highly expressed in the carotid glomus and extracellular matrix in the LN group, a pattern not seen in the C group (Fig. 5).

Discussion The NOS inhibitor L-NAME has been used extensively as a means of inducing hypertension in animal models (Kasal et al., 2008). The results of the

present study have shown that L-NAME-induced hypertension alters the amount of extracellular matrix proteins and cellular morphology of the CB. The increase in elastic fibres, proteoglycans and collagen fibres correlates with the increased CB area in L-NAME-treated rats. Changes in protein expression are thought to reflect the increased blood pressure and sympathetic activity and probably occur in order to normalize the physiological function of the CB. CB volume increases in rats subjected to chronic hypoxia (Dhillon et al., 1984; Clarke et al., 2000) and the same phenomenon is observed in New Zealand genetically hypertensive rats (Bee et al., 1989). An enlargement of the CB was also noticed in the present study. This was due to a combination of enhancement of extracellular matrix deposition and hypertrophy of the carotid glomus cells. The extracellular matrix deposition was characterized as an increased amount of elastic fibres, proteoglycans and collagen. The density of nuclei in the carotid glomus was diminished, while the carotid

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Fig. 4. Photomicrographs showing the extracellular matrix of the CB. (a, b) Weigert’s resorcin-fuchsin stain. (c, d) Alcian blue stain. (e, f) Picrosirius red stain. (g, h) Picrosirius red stain under polarized light. Bars, 30 mm. Thin black arrows indicate the presence of elastic fibres around blood vessels. Oval black arrows indicate the presence of elastic fibres within the extracellular matrix of the CB. Diamond black arrows indicate the deposition of proteoglycans around blood vessels. White arrowheads indicate collagen fibres within the CB.

area was bigger, suggesting hypertrophy of the carotid glomus cells. NF-kB is a protein complex expressed in almost all animal cells and it controls DNA transcription. In the heart, NF-kB activation enhances cardiac remodelling and dysfunction following myocardial infarction (Timmers et al., 2009), angiotensin II-induced cardiac hypertrophy (Dai et al., 2010) and pressure overload-induced left ventricular hypertrophy (Hingtgen et al., 2010). We found increased expression of NF-kB in L-NAME-treated rats, thus this complex may be driving both extracellular matrix remodelling and the hypertrophy of carotid glomus cells. PGP 9.5 has been described in glomus type 1 cells (Kameda, 1996) and its expression in the CB was diminished by L-NAME treatment. This result is probably due to a reduction in the deubiquitination process and thus accumulation of unnecessary proteins for CB cellular metabolism. L-NAME-treated rats had greater amounts of biogenic amines within the CB. The observed electron-dense granules likely represent biogenic amines, as does the fluorescence depicted in Figs. 1c, d. Biogenic amines such as catecholamines are particu-

larly found in vesicles located in the cytoplasm of type 1 cells of the glomus (Shirahata et al., 2007). Studies of patients with obstructive sleep apnoea and cardiovascular morbidity, particularly systemic hypertension, show a significant increase in the production and circulation of catecholamines during apnoea (Fletcher et al., 1987; Smith, 2007). This neurotransmitter is released and increases sympathetic activity in order to maintain blood pressure during sleep disorders and hypoxia (Chiocchio et al., 1966; Fidone et al., 1982). Glomus type 1 cells also produce the excitatory neurotransmitter SP. During hypoxia there is an increased demand, suggesting that nerves containing the SP receptor are involved in the chemosensory response and vascular dilation (Hallberg and Pernow, 1975; Kusakabe et al., 1998, 2003). In the present study, rats subjected to NOS inhibition had increased expression of SP, suggesting that this molecule is being used as a chemosensory stimulus and thus might be an important vasodilator to improve blood circulation and keep oxygen reaching the tissues. Dopamine, a catecholamine, is produced from the non-essential amino acid tyrosine and is transformed into L-DOPA by TH. Type 1 cells have been

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Fig. 5. Immunohistochemical analysis of the CB. (a, b) NF-kB. (c, d) PS. (e, f) protein PGP 9.5. (g, h) VEGF. (i, j) nNOS. (k, l) Negative control. Bars, 30 mm.

identified, in previous studies, as the main storage site for catecholamines in the CB. Dopamine is probably a neurotransmitter of afferent fibre discharge (Fidone and Gonzalez, 1982). The release of this neurotransmitter might alter stimulatory capacity of type 1 cells (Wang et al., 1998). Experimental studies have shown that levels of dopamine and noradrenaline decrease after an episode of acute hypoxia, suggesting that these molecules are released by type 1 cells (Rigual et al., 1991) in order to normalize the levels of blood oxygenation. The results of the present study show a reduction in TH in the hypertensive group (LN) compared with the control group (C) in response to L-NAME, even though there was an increase in catecholamines in the CB of the LN group. An explanation for this finding would be that the hypertension induced by L-NAME increases the production and storage of these biogenic amines within

the cytoplasm of the type 1 cells before the remodelling of the organ, with loss of their structure and reduction in TH level. Available data indicate that NOS isoforms produce NO within diverse cell types in the CB, such as the vascular endothelial cells, parasympathetic neurons, afferent nerve terminals and glomus type 1 cells (Ye et al., 2002; Yamamoto et al., 2006). The neuronal isoform of NOS is contained in a dense plexus of afferent nerve fibres that terminate near oxygen-sensitive type 1 cells in the CB of rats. Additionally, a distinct group of nNOS-positive parasympathetic neurons have been shown to innervate the CB vasculature (Wang et al., 1994, 1995). In the present study, there was increased expression of nNOS in glomus cells and in components of the extracellular matrix of LNAME-treated rats. VEGF increases vascularization and restores oxygen supply when blood flow to

Carotid Body Morphology in Hypertension

tissues becomes inadequate (Ferrara et al., 1992; Prabhakar et al., 2009). VEGF expression in CB also increased following inhibition of NOS and a similar result was found by Tipoe and Fung (2003) in rats exposed to chronic hypoxia. Hence, the increased expression of nNOS and VEGF in L-NAME-treated rats indicates an attempt to increase the synthesis of the vasodilator NO and tissue perfusion in the CB. In conclusion, the present study has shown that induction of hypertension in rats treated with L-NAME changes cellular morphology and the expression of extracellular matrix proteins in the CB and carotid glomus.

Acknowledgments The authors are grateful to the Brazilian Council of Science and Technology (CNPq), the Rio de Janeiro State Foundation for Scientific Research (FAPERJ), the Council for the Improvement of Graduate Personnel (CAPES) and the State University of Rio de Janeiro (UERJ).

Conflict of Interests The authors disclose no conflict of interest.

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February 18th, 2011 ½ Received,  Accepted, July 25th, 2011