Introduction

Despite recent advances in antihypertensive therapy, hypertension is an important risk factor for the progression of chronic kidney disease and can lead to end-stage kidney disease (ESKD) [1, 2]. Thus, in addition to lowering blood pressure, therapeutic strategies to ameliorate hypertensive renal injury must be established. One potential target is oxidative stress-induced regional ischemia, based on the results of studies that have indicated hypertensive renal injury, which can be inhibited by tempol (a superoxide dismutase mimetic) [3,4,5], develops early in the juxtamedullary cortex, the renal region most susceptible to ischemic injuries, and subsequently extends toward more superficial regions with an abundant blood supply [6,7,8].

In addition to high blood pressure, it is well recognized that the renin–angiotensin–aldosterone system (RAAS) and vascular inflammation induce renal oxidative stress under the pathophysiology of hypertension [9, 10]. However, there is currently limited understanding of the other factors involved in the pathophysiology of hypertension. In the present study, we investigated the potential contribution of thromboxane A2 (TXA2), a vasopressor eicosanoid that frequently contributes to impaired renal hemodynamics under pathological conditions and potently stimulates reactive oxygen species (ROS) generation, to the development of regional heterogeneity in hypertensive glomerular injury [11, 12]. For this purpose, using an animal model of human essential hypertension, we examined the impact of the inhibition of TXA2 synthesis in relation to its antioxidant effects on regional glomerular injury. We also determined the regional expression of thromboxane synthase (TXAS) mRNA with and without tempol treatment.

Methods

Animals

Experiments were conducted using male stroke-prone spontaneously hypertensive rats (SHRSP/Kpo) and normotensive control Wistar–Kyoto (WKY/Kpo) rats. These rats were originally established in our laboratories (by Drs. Okamoto and Suzuki) [13] and were maintained under controlled conditions of temperature (23 °C ± 2 °C), humidity (50% ± 10%), and a 12-h light/dark cycle (lights on 07.00–19.00 h) in the Central Research Facilities, Kindai University Faculty of Medicine Center for Animal Experiments. The rats were fed standard rat chow and reverse osmotic water ad libitum. All experimental protocols conformed to the guidelines of the National Institutes of Health (Guide for the Care and Use of Laboratory Animals 1966) and were approved by the Institutional Animal Experimentation Committee of Kindai University Faculty of Medicine (KAME-28-013).

Experimental protocol

Protocol 1. Association between glomerular injury and TXAS and heme oxygenase-1 (HO-1) mRNA expression

Rats were housed in a wire-mesh metabolic cage for 24-h urine collection. The systolic blood pressure (SBP) of conscious rats at the ages of 5, 10, and 15 weeks was measured using tail-cuff plethysmography (BP-98A; Softron, Tokyo, Japan). The rats were subsequently anesthetized with an intraperitoneal injection of pentobarbital (Kyoritsuseiyaku Corporation, Tokyo, Japan) (~ 100 mg/kg). Prior to removing their right kidneys, blood was obtained from the abdominal aorta. The kidneys were perfused with phosphate-buffered saline (PBS) at a perfusion pressure that corresponded to the animal’s arterial pressure and were removed. The removed kidneys were subjected to laser microdissection (LMD) to assess the mRNA expression or perform histological analysis.

Protocol 2. Pathological roles of TXA2 together with oxidative stress

At the age of 10 weeks, the SHRSP were divided into three groups: untreated, treated with tempol at 1 mmol/L, or treated with ozagrel (a TXAS inhibitor) at 3.5 mmol/L. As both tempol and ozagrel were readily soluble in water, they were administered by dissolving the compounds in the drinking water and were provided for 5 weeks. Previous reports have indicated that there was no difference in the blood pressure lowering effect between 1 mmol/L and 3 mmol/L of tempol [14, 15]. We selected tempol at 1 mmol/L because Park et al. [16]. showed that this dose of tempol successfully prevented vascular remodeling and the progression of hypertension in salt-loaded SHRSP at 16 weeks of age. With respect to the dose of ozagrel, Gomi et al. [17] examined the effect of ozagrel with graded doses from 1.4 to 147 mg/kg/day in SHR. They indicated that ozagrel decreases the urinary excretion of thromboxane B2 (TXB2), which is a stable metabolite of TXA2, in a dose-dependent manner. SBP and the production of TXB2 from the kidney were decreased only by a high dose of ozagrel. Another researcher reported that 100 mg/kg/day of ozagrel improved proteinuria in streptozotocin-induced diabetic rats [18]. Based on these reports, we decided to use ozagrel at 100 mg/kg/day. We converted the dose of 100 mg/kg/day into 3.5 mmol/L of drinking water because the daily water intake of SHRSP maintained in our laboratories is approximately 30 ml/day. After the 5-week treatment period, the SBP and urinary albumin excretion (UAE) were measured, and the right kidneys were subsequently removed using the same method as previously described.

Measurement of oxidative stress and TXB2 production

Urine samples were used for the measurement of 8-hydroxy-2′-deoxyguanosine (8-OHdG), which is a marker of oxidative stress and TXB2. The urinary excretion of 8-OHdG was determined using a competitive enzyme-linked immunosorbent assay kit (8-OHdG Check; Japan Institute for the Control of Aging, Sizuoka, Japan) [19]. TXB2 was measured by an enzyme immuno assay (EIA) kit (R&D systems, Minneapolis, MN, USA) following the instructions of the manufacturer [20].

Histological analysis

The removed kidneys were divided into two parts at the center of the minor axis. One part was rapidly immersed in OCT compound and immediately frozen in liquid nitrogen for LMD. The other part was fixed with 10% buffered formalin and embedded in paraffin. Subsequently, 4-μm-thick sections were prepared and stained with periodic acid-Schiff (PAS) to assess renal damage. Regional injury was assessed by separately examining the superficial and juxtamedullary glomeruli. The glomerular sclerosis index (GSI) was blindly scored in at least 50 superficial and juxtamedullary glomeruli, in accordance with a previously described method [21]. Each section was scored twice, and the mean score was used for the analysis. The degree of sclerosis was scored as follows: 0, no changes; 1, lesions involving < 25% of the capillary tuft; 2, lesions affecting 25–49% of the capillary tuft; 3, lesions involving 50–75% of the capillary tuft; and 4, lesions involving > 75% of the capillary tuft.

Immunohistochemical analysis

Sections were deparaffinized, and the antigenic epitopes were retrieved by microwaving in citrate buffer (10 mmol/L, pH 6.0) for 10 min. To inactivate the endogenous peroxidase activity, the sections were subsequently soaked in methanol with 0.3% hydrogen peroxide for 30 min at room temperature. After blocking with 5% goat serum for 30 min, the sections were incubated overnight at 4 °C with the primary antibodies against an oxidative stress marker 8-OHdG (2.5 μg/ml) (Japan Institute for the Control of Aging, Shizuoka, Japan). The sections were washed in PBS, incubated with biotinylated secondary antibody at 1:300 dilution at room temperature for 30 min, incubated with avidin–biotin–peroxidase complex (Vectastain ABC kit; Vector Laboratories) for 30 min and visualized with diaminobenzidine tetrahydrochloride.

LMD

LMD was performed using the Leica AS LMD system (Leica Microsystems AG, Wetzlar, Germany), in accordance with the manufacturer’s manual [22]. In brief, frozen sections (9–10 μm in thickness) were cut by a cryostat and mounted on a glass slide cover with a 2.5 μm-thick laser pressure-catapulting membrane (PEN foil; Leica Microsystems). The sections were fixed in ethanol:acetic acid (19:1), gently washed with diethylpyrocarbonate (DEPC)-treated water, and stained with 0.05% toluidine blue (TB) solution (pH 7.0, Wako Pure Chemical Industries, Ltd., Osaka, Japan); the TB solution was then rinsed with the DEPC-treated water twice, following which the sections were completely air-dried. The superficial and juxtamedullary glomeruli were separately dissected from the frozen sections using the LMD system and were then immediately collected into a microcentrifuge tube cap filled with lysis buffer.

mRNA level determination

Total RNA from the microdissected glomeruli was extracted using an RNeasy mini kit (Qiagen, Valencia, CA). Isolated RNA samples were reverse-transcribed with a high-capacity RNA-to-cDNA kit (Applied Biosystems, Foster City, CA), and the TaqMan real-time PCR assay (Applied Biosystem) was employed for the following molecules: TXAS (Rn00562160_m1) and HO-1 (Rn00561387_m1). Amplification data were analyzed using Sequence Detection Software (SDS ver. 1.9), and the mRNA levels of each target were normalized to the level of β-actin using the ΔΔCt comparative method [23].

Mean glomerular volume (MGV) measurement

The MGV was estimated using the 2-profile method [24]. In brief, kidney specimens were sectioned at 5 µm thickness and stained with PAS. Two sections were made at 20-µm intervals onto sequential slides. At least 10 individual nonsclerotic glomeruli (sclerotic lesions < 75%) were randomly selected from both the superficial and juxtamedullary cortices. Glomerular images were obtained using a color video camera attached to a microscope (Nikon Instruments Inc., Melville, NY) at × 200 magnification. In each captured image, the glomerular tuft was digitally traced, and the areas were calculated using computer image analysis software (NIS-Elements D 3.22; Nikon Instruments Inc., Melville, NY). The MGV was subsequently calculated based on the areas of the two sections. We can obtain almost the same results using the 2-profile method compared with the Cavalieri method [25], which is the most reliable and accurate method to estimate the MGV if more than eight glomeruli are analyzed.

Statistical analysis

All values are expressed as the mean ± SEM and were analyzed using unpaired Student’s t test and one-way analysis of variance. P values < 0.05 were considered statistically significant.

Results

Association between glomerular injury and TXAS and HO-1 mRNA expression

The characteristics of the WKY rats and SHRSP are shown in Table 1. The body weight of the SHRSP was significantly (P < 0.05) less at the ages of 10 and 15 weeks than that of the WKY rats. In the SHRSP, the SBP rapidly increased as the rats grew and was significantly (P < 0.05) high during the entire experimental period compared with that in the WKY rats. Although the renal function, estimated as the serum creatinine concentration (SCr) and creatinine clearance (CCr)/100-g body weight (BW), did not change during the period in the WKY rats, it significantly declined in the SHRSP at 15 weeks of age. The UAE progressively increased only in the SHRSP. The urinary TXB2 excretion was significantly greater in the SHRSP than in the WKY rats (22.6 ± 2.5 ng/day vs. 11.3 ± 1.0 ng/day, respectively, P < 0.05). Light microscopy showed high GSI in the SHRSP at ≥ 10 weeks of age. In addition, when we estimated each rat’s glomerular injury, a substantially higher GSI was observed in the juxtamedullary glomeruli than in the superficial glomeruli (Fig. 1a). The TXAS mRNA expression was enhanced in both the superficial and juxtamedullary glomeruli in the SHRSP compared with that in the age-matched WKY rats (Fig. 1b). In the superficial glomeruli, this increase nearly doubled at 10 weeks of age and remained at this level until 15 weeks of age. Moreover, in the juxtamedullary glomeruli, a progressive enhancement occurred and became 3.1-fold at 15 weeks of age. Immunohistochemical analysis indicated greater numbers of 8-OHdG-positive cells in both the glomerulus and tubules in the 15-week-old SHRSP than in the age-matched WKY rats (Fig. 2a and b). Moreover, as expected, the urinary 8-OHdG excretion was significantly greater in the SHRSP than in the WKY rats (830.7 ± 26.6 ng/kg/day vs. 602.3 ± 40.9 ng/kg/day; Fig. 2c). The HO-1 mRNA expression was also markedly increased in both the superficial and juxtamedullary glomeruli (8.7-fold and 11.6-fold, respectively) in the SHRSP at 15 weeks of age compared with that in the age-matched WKY rats (Fig. 2d), although the difference was greater in the juxtamedullary glomeruli than in the superficial glomeruli.

Table 1 The characteristics of WKY rats and SHRSP at 5, 10, and 15 weeks of age
Fig. 1
figure 1

Histological analysis and TXAS mRNA expression in superficial and juxtamedullary glomeruli. a GSI of superficial and juxtamedullary glomeruli in WKY rats and SHRSP at 5, 10, and 15 weeks of age. b Comparison of TXAS mRNA expression between WKY rats and SHRSP in superficial and juxtamedullary glomeruli. *P < 0.05 vs. WKY rats at the same age, P < 0.05 vs. superficial glomeruli at the same age

Fig. 2
figure 2

Oxidative stress in the kidneys. a, b Immunohistochemical staining for 8-OHdG in WKY rats a and SHRSP b at 15 weeks of age. Original magnification × 100. c Urinary 8-OHdG excretion in WKY rats and SHRSP at 15 weeks of age. d Comparison of the HO-1 mRNA expression between WKY rats and SHRSP in superficial and juxtamedullary glomeruli at 15 weeks of age. *P < 0.05

Pathological roles of TXA2 together with oxidative stress

Tempol or ozagrel did not have an effect on the BW, SBP, SCr, or CCr/100 g BW in the SHRSP (Table 2). In contrast, both tempol and ozagrel exacerbated the UAE (tempol: 17.4 ± 0.2 mg/day, ozagrel: 8.4 ± 1.3 mg/day; Fig. 3a), although they reduced the urinary 8-OHdG excretion (tempol: 532.3 ± 38.9 ng/kg/day, ozagrel: 616.8 ± 39.2 ng/kg/day; Fig. 3b). Ozagrel significantly reduced the urinary TXB2 excretion, whereas tempol did not induce changes (tempol: 20.0 ± 1.7 ng/day, ozagrel: 12.9 ± 1.3 ng/day; Fig. 3c). The exacerbation of the UAE was substantially stronger in the tempol-treated rats than in the ozagrel-treated rats. In addition, ozagrel, but not tempol, improved the histological lesions (Fig. 4a) and GSI in both the superficial and juxtamedullary glomeruli (Fig. 4b). Quantitative morphometric analysis of the glomeruli showed that the MGV of the superficial or juxtamedullary glomeruli was 29% or 18% greater, respectively, in the tempol-treated group than in the untreated group. In contrast, no difference was observed in the ozagrel-treated group in the superficial or juxtamedullary glomeruli (Fig. 4c). The treatments did not have a significant effect on the HO-1 mRNA expression in the superficial or juxtamedullary glomeruli (Fig. 4d), although both treatments reduced the urinary 8-OHdG excretion, as previously discussed (Fig. 3b). The TXAS mRNA expression is shown in Fig. 4e. Tempol significantly increased the TXAS mRNA expression in the superficial glomeruli (1.4-fold), but not in the juxtamedullary glomeruli, whereas ozagrel suppressed it. The TXAS mRNA expression was significantly less in both the superficial and juxtamedullary glomeruli (0.7-fold and 0.7-fold, respectively) in the ozagrel-treated rats compared with that in the tempol-treated rats.

Table 2 Changes in parameters after treatment
Fig. 3
figure 3

Effects of tempol or ozagrel administration on urinary albumin a, 8-OHdG b, and TXB2 excretion c. *P < 0.05

Fig. 4
figure 4

Effects of tempol or ozagrel on histological injury and HO-1 and TXAS mRNA expression. a Representative photomicrographs of renal cortex stained with PAS. Original magnification × 100. b Glomerular injury estimated by GSI after tempol and ozagrel treatments. Original magnification × 100. *P < 0.05 vs. untreated group, P < 0.05 vs. tempol-treated group. c Morphometric analysis using the two-profile method (described in the Methods). *P < 0.05 vs. superficial glomeruli, P < 0.05 vs. untreated group. d, e Comparisons of HO-1 d and TXAS e mRNA expression between untreated SHRSP and tempol- or ozagrel-treated SHRSP in superficial and juxtamedullary glomeruli. *P < 0.05

Discussion

Studies have demonstrated that hypertensive glomerular sclerosis develops early in the juxtamedullary cortex and subsequently extends toward the superficial cortex in rats and humans [6,7,8]. Although it has been proposed that differences in the perfusion pressure or oxidative states between the juxtamedullary and superficial glomeruli are responsible for this regional heterogeneity, the precise mechanisms that underlie this effect are unclear. Thus, in the present study, using an animal model of severe essential hypertension, we examined the potential involvements of TXA2 together with oxidative stress in the pathophysiology of hypertensive glomerular injury. We confirmed this heterogeneity and identified increased oxidative stress together with preferentially enhanced TXAS mRNA expression in the juxtamedullary glomeruli in SHRSP. To our knowledge, this investigation is the first report to demonstrate the potential involvement of TXA2 in regional heterogeneity in hypertensive glomerular injury. We also found that TXA2 production can be affected by antioxidant therapy and may affect the degree of UAE.

The importance of oxidative stress in the pathogenesis of hypertensive organ damage has been extensively studied [16, 26,27,28,29]. The excessive production or decreased metabolism of ROS, such as superoxide anion (O2), hydrogen peroxide (H2O2), and hydroxyl anion (OH), can lead to oxidative stress that alters the redox state and causes the redirection of redox-regulated signaling pathways and cellular dysfunction or damage [30]. It is well recognized that RAAS and vascular inflammation induce renal oxidative stress [9, 10]. However, antihypertensive treatment with RAAS blockers may not be completely effective at preventing the progression of hypertensive renal injury to ESKD. Thus, for better antihypertensive treatment, there is a need to determine other factors involved in the pathogenesis of hypertensive glomerular injury. In the present study, we investigated the potential involvement of TXA2 in the pathophysiology of hypertensive glomerular injury as it has been reported that the renal synthesis of TXA2 increases in SHRSP [31]. TXA2 is an arachidonic acid metabolite converted by TXAS, which by acting on its receptor [thromboxane prostanoid receptor (TPR)] causes platelet aggregation, the contraction of vascular smooth muscle cells and increases the expression of adhesion molecules in endothelial cells [32, 33]. In the kidneys, TXAS and TPR are expressed in endothelial cells and glomerular mesangial cells, and TXA2 decreases the glomerular filtration rate (GFR) under pathological conditions [34,35,36]. Gelosa et al. [37] have reported that terutroban, a selective TPR antagonist, prevented vascular hypertrophy and improved the development of proteinuria without affecting blood pressure in SHRSP. These findings imply that the TXA2–TPR pathway mediates glomerular injury through a blood pressure-independent mechanism in severe hypertension. Interestingly, the TXA2–TPR pathway and oxidative stress form a vicious circle, i.e., TXA2 stimulates the generation of ROS and O2 [11, 12], which, in turn, stimulate TXA2 synthesis by TXAS upregulation [38]. This background prompted us to examine their potential associations with the pathogenesis of hypertensive glomerular injury, which we identified in diverse forms.

We found that both the TXAS mRNA expression and oxidative stress increased in SHRSP particularly in the juxtamedullary glomeruli, which showed more severe hypertensive injury than that in the superficial glomeruli. These findings support the idea that TXA2 together with oxidative stress contribute to the development of hypertensive glomerular injury. However, tempol showed a tendency to cause marked increases in the UAE and significantly reduced renal oxidative stress as estimated by the urinary 8-OHdG excretion (Fig. 3b), although it may reflect interstitial and glomerular oxidative stress. These results are completely consistent with those of Sugama et al. [39], who reported that tempol aggravated renal injury in advanced-stage SHRSP. In addition, clinical and experimental studies have reported conflicting results with antioxidant therapies [40, 41]. Moreover, the increase in the UAE was substantially smaller when TXAS was inhibited with ozagrel, although it reduced renal oxidative stress to an extent similar to that by tempol. Thus, it is possible that antioxidant therapy through TXA2 inhibition is a better therapeutic target than ROS inhibition to inhibit the aggravation of hypertensive glomerular injury at an advanced stage.

The reason why tempol exacerbated UAE remains unclear. Sugama et al. [39] hypothesized that tempol aggravates renal injury in advanced-stage hypertension by inducing glomerular hypertension in residual nephrons (mostly superficial nephrons) through an inadequate increase in regional blood flow or an attenuation of the tubuloglomerular feedback (TGF) response. It has been reported that increased O2 production in SHR enhances the TGF response, which is blunted by tempol, leading to the development of glomerular hypertension [42]. It has also been demonstrated that increased mechanical stress on glomeruli, such as glomerular hypertension, upregulates TXAS mRNA, which results in increased TXA2 production and a further increase in the glomerular capillary pressure [43]. These findings may be the mechanism by which tempol upregulates TXAS mRNA. Consistent with this hypothesis, we found that tempol but not ozagrel increased the MGV in both the superficial and juxtamedullary cortices (particularly the superficial cortex) without improving histological lesions and GSI. Thus, tempol may exacerbate UAE by increasing the glomerular capillary pressure, whereas ozagrel does not cause glomerular hypertension. In addition to this possibility, TXAS upregulation induced by tempol (particularly in superficial glomeruli) may be responsible for the exacerbation of the UAE because TXA2 is known to accelerate glomerular injury through the activation of adhesion molecules or the stimulation of mesangial cell proliferation under pathological conditions [32, 44, 45]. However, this possibility is not consistent with our finding that ozagrel significantly (but substantially less than tempol) increased the UAE. Because ozagrel does not increase the glomerular capillary pressure or cause glomerular histological injury (as previously discussed), the inhibition of TXA2 synthesis with ozagrel may increase the UAE via the elevation of the glomerular ultrafiltration coefficient under conditions with advanced hypertensive glomerular injury. Consistent with this concept, TXA2 is known to decrease the ultrafiltration coefficient and GFR [44]. Alternatively, ozagrel might influence the metabolism of other arachidonates, which may lead to the exacerbation of UAE. Although the reason ozagrel did not increase the CCr/BW remains unclear, it may be that an increased glomerular ultrafiltration coefficient could compensate but not surpass the remaining severe glomerular damage. Further studies exploring the precise pathological roles and underlying mechanisms of the involvement of the TXA2–TPR pathway in the pathophysiology of hypertensive renal injury are clearly required.

Our study has several limitations. First, although we selected the concentration of tempol and ozagrel based on the reasons described, the dose-dependent effects of these drugs must be elucidated. Second, the potential involvement of other prostanoids, such as prostacyclin, in hypertensive glomerular injury must also be verified.

In conclusion, the TXA2–TPR pathway and oxidative stress participate and interact together to promote hypertensive glomerular injury. Our results indicated that antioxidant therapy through TXA2 inhibition may be a better therapeutic target than ROS inhibition to inhibit the aggravation of hypertensive glomerular injury at an advanced stage.