Background
Central nervous system (CNS) and neuroendocrine-immune systems (NEI) are the two major systems which respond adaptively to the numerous challenges to maintain the physiological homeostasis. The adaptive responses could be impaired by some physical and psychological stressors in neuroendocrine-immune feedback system. Such dysfunction could also contribute to the pathogenesis of allergic or autoimmune diseases [
1]. The studies on the cross-talk between neuroendocrine and immune systems added further evidences that interactions among the neural, neuroendocrine and immune systems are bidirectional [
1‐
3]. Recent studies have shown that this bidirectional cross-talk is based on the secretion of pro-inflammatory factors including mediators and cytokines, hormones, neurotransmitters and neuropeptides [
4‐
6]. The hypothalamic-pituitary-adrenal (HPA) axis is the major pathway in NEI, hypothalamus secretes corticotropin releasing hormone (CRH) when the HPA axis is activated. This molecule travels to the anterior pituitary gland, which responds to its presence by secreting a pulse of adrenocorticotropin hormone (ACTH). The ACTH signal is carried through the peripheral circulation to the adrenal glands, which synthesize and release cortisol and lead to reduction of inflammation.
Leukotriene (LT) B
4 is a product of the action of LTA
4 hydrolase (LTA
4-H) on LTA
4 in 5-lipoxygenase (5-LO) pathway. It is a potent leukocyte chemoattractant and activator, which plays an important role in modulating immune and inflammatory responses [
7]. An early study showed that LTB
4 increases CRH secretion in explanted and cultured hypothalamus via autocrine/paracrine or as endocrine factor [
8]. Further studies found that inflammatory mediator such as IL-1, IL-6 can activate the HPA axis and regulate the inflammatory response in periphery [
9]. From previous work, we found that the changes of Th1/Th2 paradigm (ratio of interferon [IFN]-gamma/interleukin [IL]-4 decreased) [
10], and the content of LTB
4 in the cerebral cortex increases corresponding to their changes in bronchoalveolar lavage fluid (BALF) or lung tissue in inflammatory status of asthmatic rats [
11]. Also, the expression of 5-LO and LTA
4-H mRNA in cerebral cortex of asthmatic rats are significantly higher than those of control rats [
12]. All these findings indicate that the changes of these proinflammatory mediators in the CNS may have pathophysiologic effects in asthmatic rats.
So far, it is unclear how LTB4 in the CNS regulates inflammation in lung tissue of asthma. Based on these studies, we postulate that the increase of LTB4 in brain activates NEI, which may regulate asthmatic response in rats. To explore this hypothesis, rats were actively sensitized with ovalbumin (OVA), and LTB4 was administered via intracerebroventricular injection (i.c.v). The pulmonary function and inflammatory cell infiltration in lung were evaluated. Meanwhile, the HPA axis activity was also explored by measuring CRH mRNA and protein expression in hypothalamus, corticosterone (CORT) and ACTH level in plasma during antigen challenge in sensitized rats.
Methods
Animal and study design
Sprague-Dawley (SD) rats of either sex weighing 180~200 g were purchased from Laboratory Animal Center in Medical Science College of Zhejiang University (Grade II, Certificate No. 220010014). All animals were housed in Plexiglas cages and kept on a 12/12 h light-dark cycle in temperature and humidity controlled rooms, standard laboratory food and water were provided ad libitum. Food was withheld 8 hours before the experiments, with free access to water. Unless otherwise indicated, Animal treatments were strictly in accordance with the China Community Guidelines for the Use of Experimental Animals and the National Institutes of Health Guide for the Care and Use of Laboratory Animals. Rats were assigned to different treatments, Vehicle-sham group was as normal control, ovalbumin (OVA) sensitized and challenged rats were treated as asthmatic model (Vehicle-OVA), the effects of LTB4 (LTB4-OVA) via i.c.v on asthmatic rats were evaluated. And U75302, the selective BLT1 receptor antagonist, was administered via i.c.v alone (U75302-OVA) or 5 min before LTB4 dosing (U75302-LTB4-OVA).
Sensitizing procedures
To sensitize the rats, 1 mg OVA (Grade V, Sigma Chemical Co., St. Louis, MO) absorbed in 100 mg aluminium hydroxide adjuvant in 1.0 ml saline. Each rat was intraperitonealy injected (i.p) with 0.5 ml, and subcutaneously injected (s.c) with 0.05 ml/site at four footpads (4 sites), neck (one site), back (3 sites), and two groins (2 sites), respectively. Then, every rat was injected (i.p) with 1 × 1010 bordetella pertussis adjuvant (Shanghai Institute of Biological Products, China) on experiment day 0. Normal control (vehicle-sham) rats were injected with only aluminium hydroxide adjuvant in saline following the same protocol. At day 14 after sensitization, the rats were placed in a 45 cm × 45 cm × 15 cm plastic box and challenged by exposure to an aerosol of OVA (20 mg/ml in saline), which was generated in a jet nebulizer (particle size 1-5 μm; BARI, MASTER, Germany) for 20 min, and repeated daily to day 21 after sensitization. Vehicle-sham rats were similarly exposed to an aerosol of saline.
Intracerebroventricular injection
After 10% chloral hydrate (3 ml/kg i.p) anaesthesia, the animal's head was fixed in a stereotaxic apparatus (SR-6N, Narishige, Japan). The procedure of i.c.v. injection was in accordance with rat brain graph described by George Paxious and Charles Watson, and with minor improvement as described by Mauser et al [
13]. In brief, a midline incision was made from a point just posterior to the eyes to about 3 cm caudal, and the overlying connective tissue was removed to expose the skull. A small hole (about 2 mm in diameter) was opened perpendicularly to the skull, -1.0 or -1.5 mm anterior and 1.5 mm lateral to the bregma by using a dental drill (Minimo, Japan). A stainless steel guide cannula (internal diameter, 0.5 mm; length, 1.5 cm) was then slowly and vertically lowered to a depth of 3.8 mm from the dura into lateral ventricles. The guide cannula was then held in place by dental cement (oral cavity drugs and materials of Wuhan University, China) with a small anchor screw. The scalp was sutured and the animals were left to recover for 1 week before the first antigen challenge. All injections through the i.c.v. were made with a Hamilton syringe (Reno, NV, U.S.A.) and in a 10 μl volume of artificial CSF. In vehicle-sham or LTB
4-OVA group, vehicle 10 μl or LTB
4 10 ng (Sigma Chemical Co., St. Louis, MO) (Cayman Chemical) was administered via i.c.v 30 min before the antigen challenge from day 14 to day 21. In the U75302-LTB
4-OVA group, an extra dose of U75302 10 ng was administered via i.c.v 5 min before LTB
4 dosing.
Measurement of pulmonary function
The lung function was assessed 30 min before and after LTB
4 i.c.v on day 21 after sensitization as described previously [
14]. Briefly, each anaesthetized rat was placed supine inside a Plexiglas whole-body plethysmograph. The flow rate was monitored with a Fleisch tube connected to the airway in a pressure transducer. Changes in lung volume were measured by detecting pressure changes in the plethysmographic chamber through a port in the connecting tube with a pressure transducer. To measure pleural pressure, a needle (No. 16) with a multiholed tip was directly inserted into the pleural cavity (between fourth and fifthly rib at left thorax) through a port in the connecting tube with a differential pressure transducer. Transpulmonary pressure was calculated as the difference between mouth and pleural pressure. All signals of pressure transducers were continuously computed (MedLab, Nanjing Biotech Instruments, China) by fitting flow, volume, and pressure to an equation of motion. For antigen challenge, OVA 20 mg/ml dissolved in saline aerosolized by a jet nebulizer (BARI Co. Ltd, Germany) for 5 min. The respiratory waveform was monitored for 15 min and maximal changes from baseline for each parameter were recorded by the MedLab. The results were shown as airway resistance (
R
L
) and dynamic lung compliance (
C
dyn
) value before and after antigen challenge.
Preparation of bronchoalveolar lavage fluids
Twenty-four hours after the final OVA challenge, rats were anesthetized with urethane (2 g/kg, i.p.). Bronchoalveolar lavage fluids (BALF) were obtained via tracheal tube by washing of the right lung with 1 ml of sterilized saline containing 1% bovine serum albumin (BSA) and 5 IU/ml heparin for three times. The total number of cells in the BALF was counted. The BALF was centrifuged for 10 min at 400 × g at 4°C. Two hundred cells from the cell suspension were stained by Wright-Giemsa and classified using a light microscope. The results were expressed as the numbers of each type of cell population in 1 ml of BALF.
Lung histopathology
The left lung was fixed in 10% neutral formalin for 7 days. Sections of 5 μm thickness were prepared and stained with hematoxylin-eosin (H&E). To determine the severity of inflammatory cell infiltration, peribronchial eosinophil cell number was blindly counted and the severity was evaluated by a 5 point scoring system described previously [
15]. Briefly, the scoring system was 5-marked, 4-moderate, 3-medium, 2-mild, 1-minimal and 0-no eosinophil cells.
ACTH and CORT assay
Blood samples were collected in heparin-coated tubes via the tail vein 30 min before, 30 min after LTB4 i.c.v, and 30 min after final antigen challenge. Blood samples were centrifuged at 2000 × g to separate plasma at 4°C for 15 min. All samples were stored at -80°C until analysis. The levels of ACTH and CORT in plasma were measured using a commercial ELISA kit (USCN-LIFE™, China) by following the manufacturer's instructions.
Isolation of hypothalamus
Rats were euthanized and then decapitated 24 h after the final antigen challenge. Hypothalamus was dissected with the following limits: anterior border of the optic chiasm, anterior border of the mamillary bodies, and lateral hypothalamic sulci. The depth of dissection was approximately 3 mm. The hypothalamus was then quickly frozen in liquid nitrogen and preserved at -80°C for extraction of RNA or protein.
Reverse transcription and polymerase chain reaction
Total RNA was isolated with TRIzol Reagent (Invitrogen, USA). First-strand cDNA was generated from 4 μg of total RNA using oligo-dT to prime the reverse transcription according to the supplied protocol (Invitrogen). PCR were performed using commercial PCR reagents Kit (TaKaRa) in a gradient thermal cycler PCR machine (Eppendorf, Germany). Rat CRH was amplified using primers 5'-TCACCTTCCACCTTCTGAGG-3' and 5'-GGAAATGAAATGTTGCGCTT-3' (317 bp, intron spanned) for 35 cycles (94°C 30 s, 58°C 45 s, 72°C 45 s). Primers for rat GAPDH were 5'-ACCACCATGGAGAAGGCTGG-3' and 5'-CACAGTGTAGCCCAGGATGC-3' (528 bp, intron spanned) for 28 cycles (94°C 30 s, 58°C 30 s, 72°C 60 s). Aliquots of polymerase chain reaction products were separated by electrophoresis on 1.5% agarose gels and visualized with ethidium bromide, and the PCR product bands were quantified by using UVP Gel Documentation system (UVP, Upland, CA). Results were expressed as a ratio of densitometry value of CRH to that of GAPDH.
Western Blot
CRH protein expression in hypothalamus was assessed as described by Meloni EG et al [
16]. 20 μg protein/lane (determined by protein assay; Eppendorf Biophotometer, Germany) was loaded onto a 6-well, 12% Bis-Tris gel (Invitrogen) and electrophoresed in 1 × 2-N-morpholino-ethane sulfonic acid (MES)-SDS running buffer (Invitrogen). After electrophoretic transfer, the polyvinylidene fluoride (PVDF) membranes were cut to isolate the beta-actin band as well as the lower molecular weight CRH band. Membranes were incubated in blocking buffer (5% non-fat dry milk in PBS and 0.1% Tween 20; PBS-T) overnight at 4°C and then incubated with either polyclonal rabbit anti-CRH (1:200; Santa Cruz Biotechnology) or rabbit anti-beta-actin (1:1,000; Cell Signaling Technology) antibody diluted in PBS-T for 2 h at room temperature. After incubation in secondary antibody (HRP-conjugated goat anti-rabbit IgG, 1:5000; Li-cor Biosciences) diluted in blocking buffer for 2 h, immunoreactivity was visualized with chemiluminescence using an Image Station (Odyssey, American Gene Co.). Specific CRH band was determined by the synthetic rat CRH (rCRH, American peptide Company). Immunoblots were quantified by image analysis (UVP, Upland, CA) and data were expressed as a ratio of densitometry value of CRH to that of beta-actin.
Statistical analysis
Numerical data were presented as means ± S.D. Statistical calculations were performed using SigmaStat software (SigmaStat 2.0, SPSS Inc., Chicago, IL, USA), ANOVA and Student-Newman-Keuls multiple comparisons test were used to calculate the significance of differences of respiratory function, inflammatory cells in BALF, levels of CORT and ACTH in plasma, and expression of CRH in hypothalamus. A non-parametric test, the Mann-Whitney U-test, was used to compare differences in eosinophil infiltration in airway. Significance was assessed at the P < 0.05 level.
Discussion
Recent studies have emphasized an important role of inflammatory mediators in the regulation of neuroendocrine pathways during immune challenge and in pituitary hormone secretion [
17]. Particular emphasis is placed on the cross-talk between inflammation and the HPA axis. Studies have shown that inflammatory cytokines (IL-1, IL-6 etc) activate the HPA axis with the increase of secretion of cortisol, which in turn suppresses the inflammatory and immune reaction [
9]. During antigen-mediated activation, CD4+ and CD8+ lymphocytes are able to produce hormones like ACTH, growth hormone (GH), thyroid stimulating hormone (TSH) and gonadotropins [
18]. More directly, an antigenic challenge delivered either via the i.c.v or i.v routes evokes an increased HPA axis response in dogs that sensitized with IgE via the i.c.v route [
19]. The activation of the HPA axis is also observed in allergic rhinitis during nasal provocationand and in cutaneous inflammatory disease [
20,
21]. Thus, the activated HPA axis inhibits the inflammation via increased cortisol. Conversely, the deregulation of the HPA axis and inability to increase glucocorticoid production in response to stress is associated with increased airway inflammation with mechanical dysfunction of the lungs in asthma. For example, in CRH-knockout mice, the airway inflammation increased and lung mechanical function decreased with the increased IL-4 and IL-13 levels, and impaired adrenal responses to stress in asthmatic mice [
22]. This is also in agreement with the clinical observation that stressful life events increase the risk of a new asthma attack [
23]. All these studies indicate that the crosstalk between inflammatory mediator and HPA axis regulate asthma.
Evolving evidence indicates that LTB
4 has an important role in the development of asthma [
24], and LTB
4 mediated effects are thought through two G-protein coupled receptors (GPCRs), BLT1 (high affinity) and BLT2 (low affinity) [
25,
26].
Interestingly, particularly high levels of neuronal 5-LO expression and LTB
4 content have been identified in CNS upon challenge with a variety of stimuli [
27,
28]. Our previous study found that antigen challenge induces the expression of 5-LO and LTA
4H mRNA and LTB
4 levels in brain after antigen challenge in sensitized rats. And the glucocorticoid examethasone inhibited the 5-LO and LTA4-H mRNA expression in cerebral cortex in the asthmatic rats [
12]. In this study, we further evaluated the functional effect of LTB
4 in brain through exogenously injection of LTB
4 via i.c.v. We observed that antigen challenge or LTB
4 injection via i.c.v alone activates the HPA axis, while combination of both further increases the HPA axis activation, which is manifested by the increased CRH mRNA and protein expression in hypothalamus, and increased ACTH and CORT level in plasma of sensitized rats. The increased HPA activation was accompanied by the alleviation of airway inflammation and improvement of lung mechanical function in sensitized rats. Using the selective receptor antagonist, we found that pretreatment of BLT1 receptor antagonist U75302 via i.c.v, but not BLT2 antagonist, completely suppressed LTB
4 induced effects. In fact, the functional effect of LTB
4 via i.c.v on HPA axis and peripheral asthmatic symptom in this study was supported by other studies. For example, it was found eicosaniods including LTB
4 induces CRH secretion in explanted and cultured hypothalamus from rat [
8]. And the deficiency of CRH worsen the airway inflammation and lung mechanical disfunction in sensitized mouse [
22]. Base on these and aforementioned observations, we postulate that the increase of LTB
4 level in brain induced by antigen challenge may acts as an immunomodulator, stimulates HPA axis activity via its selective BLT1 receptor, and the final increased cortisol level attenuates antigen-induced airway contraction and inflammation in the asthmatic model of rats.
It appears that different mechanisms in acute vs chronic stress as the stimulator to the HPA axis influence the inflammatory responses of the airway in asthma. It supposed that acute stress cause the activation of HPA axis and consequent cortisol release, lead to reduction of airway inflammation. However, in chronic stress condition, after continuous prolonged or intermittent stimulation, HPA axis activity is suppressed and its anti-inflammatory effect is reduced [
23]. For example, studies found that acute stress or stress induced TNF-alpha or P substance production enhances airway reactivity or inflammation in OVA sensitized mice [
29,
30]. In adult mice, exposure to short term stress (3 days) decrease the inflammatory cell number in BALF, while the inflammatory cytokines level increased after a long-term exposure (7 days) [
31]. In our study, continuous antigen attack (7 days) to sensitized rats is supposed to be the chronic stressor, but we observed the increase of CRH expression in hypothalamus, ACTH and CORT level in plasma after antigen challenge, which is contradictory to the opinion of chronic stress inhibit of HPA axis. Our postulation is that the antigen attack still provokes the acute airway response in established disease state, which may acts as acute stressor activate the NEI system and regulate the HPA axis response.
We did not find significantly differences on airway inflammation and lung mechanical function in sensitized rats treated with U75302 alone via i.c.v, which may suggest that the endogenous intracerebral LTB4 activity does not normally play a large role in modulating airway inflammation in this model. Notably, we observed a mild decrease (around 15%-30%) in CRH expression in hypothalamus or ACTH and CORT level in plasma after BLT1 was blocked by U75302 after antigen challenge. We postulate that the increased endogenous LTB4 induced by antigen challenge may mildly activate the HPA axis, but this activation of the HPA axis may be not enough to antagonize peripheral inflammation in this asthmatic model. Another possible explanation is that the functional effect of increased endogenous LTB4 induced by antigen challenge may be balanced by other mediators or cytokines in brain. For example, the levels of Th2- (e.g IL-4, IL-13) and Th1- cytokines (e.g INF-gamma) during asthmatic attack in brain are also changed after antigen challenge. Further studies are needed to clarify how the HPA axis response to the change of asthma-related cytokines and other inflammatory mediators, and how the HPA axis communicates with neural and endocrine networks as well as their signal pathways in regulating peripheral allergic response.
Competing interests
The authors declare that they have no competing interests.
Authors' contributions
YMD carried out the experiment design, the western blot, the RT-PCR and the manuscript writing; SJZ carried out the intracerebroventricular injection, lung function measurement, the ACTH and CORT measurement; YLZ and XWD helped to carry out the lung pathological evaluation, the ACTH and CORT measurement and performed the statistical analysis. JXJ helped to ran the RT-PCR. QMX conceived and designed this study, and helped to draft the manuscript.