Induction of Renoprotective Gene Expression by Cobalt Ameliorates Ischemic Injury of the Kidney in Rats

Experimental Protocol

All experiments were conducted in accordance with the “Guide for the Care and Use of Laboratory Animals” (DHEW Publication No. [NIH] 86-23, Revised 1985, Office of Science and Health Reports, DRR/NIH, Bethesda, MD). Male SD rats weighing 160 to 180 g were purchased from Nippon Seibutsu Zairyo Center Co. (Saitama, Japan). All rats were housed in individual cages in a temperature- and light-controlled environment in an accredited animal care. Rats in the control group (n = 9) had been drinking tap water, whereas rats in the cobalt group (n = 7) had been drinking water containing 2 mM cobalt chloride from day −10 to day 3. On the basis of the daily water intake, the total dose of cobalt chloride was estimated to be about 80 mg per animal. In some studies, animals (n = 3) were injected with cobalt chloride subcutaneously at dose of 30 mg/kg at day −1 and day 0 with 12-h interval. Twenty-four hours before induction of ischemic injury, at day 0, the right renal pedicle and the right ureter were ligated, and right nephrectomy was performed. Ischemic injury was induced by clamping of left renal artery and vein for 45 min at day 1. Core body temperature was maintained at 37°C using a homeothermic table during surgery. Twenty-four and forty-eight hours after induction of injury, blood samples were obtained via tail vein for determination of serum creatinine levels. Serum creatinine levels were determined enzymatically with a commercial kit that used the creatininase/creatinase/sarcosine oxidase (Kainos Laboratories, Tokyo, Japan). Forty-eight hours after injury, at day 3, rats were euthanized and the kidneys were removed for histologic analysis.

Renal Histologic Analyses

Tissue fixed in methyl Carnoy solution was processed and paraffin-embedded. Four-micrometer sections were stained with the periodic acid-Schiff (PAS) reagent and counterstained with hematoxylin. Vimentin was stained with murine monoclonal IgG antibody V9 (Dako, Carpinteria, CA), renal microvascular endothelial cells were identified with murine monoclonal IgG1 antibody JG-12 (Bender MedSystem, San Bruno, CA), and monocytes/macrophages were identified with murine monoclonal IgG1 antibody ED-1 (Chemicon, Temecula, CA) by an indirect immunoperoxidase method. HIF-1α was identified with monoclonal IgG HIF-1α antibody α67 (Novus Biological, Littleton, CO) at a 1/100 dilution utilizing the Tyramide Signal Amplification Systems (PerkinElmer Life Sciences, Boston, MA). For quantification of morphologic data, more than 15 low-magnification fields including both cortex and outer medulla were randomly selected. Tubular injury in terms of tubular dilation, tubular epithelial injury, debris accumulation, and cast formation was graded with an arbitrary score of 0 to 3: 0, normal; 1, mild; 2, moderate; 3, severe (8). Tubules that are vimentin-positive or are surrounded by vimentin-positive cells were counted in 20 randomly selected cortical fields with a ×20 objective. ED-1-positive cells were counted in 20 randomly selected fields including both cortex and outer medulla with an ×10 objective. Peritubular capillary loss was analyzed using rarefaction index as previously reported (9). Briefly, it was determined by counting the numbers of squares in 10 × 10 grids that did not contain JG-12-positive peritubular capillary staining, in at least ten non-overlapping sequential fields in the outer medulla. All quantification was performed in a blinded manner.

Real-Time Quantitative PCR Analyses

Total RNA was extracted from kidney homogenates with ISOGEN (Nippon gene, Tokyo, Japan). To synthesize cDNA from total RNA, SuperScript II Reverse Transcriptase was used (Life Technologies BRL, Rockville, MD). Renal mRNA levels were assessed by real-time quantitative PCR (real-time PCR) using SYBR Green PCR reagent (QIAGEN, Hilden, Germany) and iCycler PCR system (Bio-Rad Laboratories, Hercules, CA) according to manufacturer’s instructions. Briefly, amplification reactions contained 1 μl of cDNA, 12.5 μl of the Universal 2×PCR mastermix (QIAGEN), and 5 μl of each of the specific primers and the probe. Primer concentrations in the final volume of 25 μl were 500 nM. In control experiments with triplicates, no false positives were detected and the variance between each of the replicates was within 5%. After an initial hold of 15 min at 95°C, the cDNA samples were cycled 40 times at 95°C for 30 s, 55°C for 30 s and 72°C for 30 s. All reactions were performed in triplicate. Ct, or threshold cycle, was used for relative quantification of the input target number. The amount of threshold cycle for control sample was considered 1, i.e. 2⁰. The number of threshold cycles for other samples was derived by cycles of control sample and recorded as ΔCt. The amount of amplified molecules at the threshold cycle was given by: 2Δ^Ct. The mRNA levels of genes were normalized to levels of β-actin. Each genes and PCR primers are as follows; heme oxygenase-1 (HO-1) (5′-TCTATCGTGCTCGCATGAAC -3′, 5′-CAGCTCCTCAAACAGCTCAA -3′), vascular endothelial growth factor (VEGF) (5′-TTACTGCTGTACCTCCAC -3′, 5′-ACAGGACGGCTTGAAGATA -3′), erythropoietin (EPO) (5′-TACGTAGCCTCACTTCACTGCTT-3′, 5′-GCAGAAAGTATCCGCTGTGAGTGTTC-3′), glucose transporter-1 (Glut-1) (5′- CAGTTCGGCTATAACACCGGTGTC -3′, 5′-ATAGCGGTGGTTCCATGTTT-3′), and β-actin (5′-CTTTCTACAATGAGCTGCGTG -3′, 5′-TCATGAGGTAGTCTGTCAGG -3′).

Western Blot Analyses

Isolation of whole protein from nephrectomized kidney was performed by tissue homogenization in Tris-glycine buffer. Forty micrograms of protein of each animal was resolved on 10% SDS-polyacrylamide gels and transferred to nitrocellulose membrane. Western blot analysis was performed as described previously (10). Briefly, anti HO-1 antibody (StressGen, Victoria, Canada) was used at a 1/2000 dilution; horseradish peroxidase-conjugated secondary antibody (Jackson ImmunoResearch, West Grove, PA) was used at a 1/2000 dilution. The ECL Western blotting systems (Amersham Bioscience, Upsala, Sweden) was used for detection.

Statistical Analyses

Data are reported as mean ± SEM. Statistical analyses were performed using the t test. The relationships between variables were assessed by Pearson correlation analysis. Nonparametric data were analyzed with the Mann-Whitney test when appropriate. Differences with P < 0.05 were considered significant.

Improvement of Ischemic Renal Injury by Treatment with Cobalt Chloride

Cobalt chloride treatment was started at day −10 and continued until the end of the experiments at day 3. A dose of cobalt chloride employed in our experiments was confirmed not to be toxic for rats previously (11). PAS-stained sections obtained at day 0, before ischemic insult, showed no morphologic changes by cobalt administration (data not shown). Cobalt administration into rats significantly prevented an increase in serum creatinine induced by ischemia as compared with that of the rats drinking tap water (Co treatment group, 2.23 ± 0.19 mg/dl versus control, 2.95 ± 0.18 mg/dl at 24 h; P < 0.05; Co treatment group, 2.14 ± 1.21 mg/dl versus control, 3.69 ± 1.43 mg/dl at 48 h; P < 0.05). To determine the effects of cobalt administration on tubulointerstitial injury, we performed histopathologic analysis. We observed severe tubular damages in terms of tubular dilation, tubular epithelial injury, debris accumulation, and cast formation in our control animals 48 h after the ischemic insult (Figure 1A). Cobalt administration improved tubulointerstitial damage induced by ischemia (Figure 1B). Semiquantitative scoring analysis revealed protective effects of cobalt administration with a statistically marginal significance (Co treatment group, 1.58 ± 0.14; control, 2.18 ± 0.24; P = 0.08). We observed a good correlation between serum creatinine levels and tubular damages for individual rats (r² =0.83, P < 0.001; Figure 1C).

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Figure 1. Cobalt chloride treatment conferred functional and morphological protection against ischemic tubulointerstitial injury. (A) Tubular injury, tubular dilation, tubular epithelial injury, debris accumulation, and cast formation were apparent in controls. (B) Damage was less severe in cobalt-treated rats. Periodic acid-Schiff staining. Magnification, ×200. (C) There was a significant positive correlation between the morphological severity and serum creatine levels.

Expression of Vimentin, a Marker of Tubulointerstitial Damage, Was Ameliorated by Cobalt Administration

To confirm the beneficial effects donated by cobalt in the histologic analysis, we performed immunohistochemical studies using a marker of tubulointerstitial injury, vimentin. We observed no vimentin staining in the tubulointerstitium before ischemia in both groups (data not shown). While expression of vimentin in tubular cells or in cells surrounding tubules was obviously increased by ischemia in controls, cobalt administration significantly prevented vimentin expression (Co treatment group, 0.71 ± 0.11 vimentin-positive tubules per field; control, 3.26 ± 0.92; P < 0.05; Figure 2).

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Figure 2. Immunohistochemical analysis of markers of tubulointerstitial injury, vimentin, in controls (A) and cobalt-treated (B) rats was induced after ischemic injury. While photomicrographs of controls demonstrated expression of vimentin intermediate filaments in tubular cells and in cells surrounding tubules, vimentin-positive cells disappeared in cobalt-treated rats. Magnification, ×200.

Macrophage Infiltration Was Reduced by Cobalt Treatment

Ischemic injury was associated with macrophage infiltration in the tubulointerstitium as determined by an increase in ED-1-positive cells. The number of infiltrating macrophages was significantly reduced in animals treated with cobalt (Co treatment group, 65.4 ± 11.2 ED-1 positive cells per field; control, 160.9 ± 62.4; P < 0.05; Figure 3).

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Figure 3. Immunohistochemical analysis of markers of monocytes/macrophages, ED-1. In controls (A), ischemic injury caused massive macrophages infiltration. In contrast, fewer ED-1-positive cells were recruited in the kidneys of cobalt-administrated animals (B). Magnification, ×200.

Cobalt Chloride Induced Renoprotective Gene Expression

We speculated that the beneficial effects of cobalt treatment might be mediated by increasing the expression level of genes that work as an adaptive mechanism against hypoxia. To determine expression of renoprotective genes stimulated by cobalt administration, we performed real-time quantitative PCR using kidneys obtained before and after ischemic insult.

Real-time PCR analysis allowed us to perform relative quantification based on the difference in threshold cycles (Ct) of target and control samples (=ΔCt) in cobalt and control groups, respectively. The variance between each of the replicates was within 5%. Cobalt administration increased mRNA levels of HO-1, EPO, Glut-1, and VEGF before ischemic insult. Fold increases of each mRNA expression compared with control were 9.43-, 6.93-, 2.77-, and 1.46-fold, respectively (Figure 4A). Even after ischemic surgery, mRNA levels of HO-1, Glut-1, and VEGF remained higher in the cobalt-treated group compared with the control at the same time point. The fold increases were 2.47-, 1.31-, and 1.36-fold respectively (Figure 4B). On the other hand, EPO expression dropped down to undetectable level after ischemia in both cobalt-treated and control groups.

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Figure 4. Cobalt chloride increased expression levels of renoprotective genes. Expression of mRNA for each gene in the whole kidney of rats drinking cobalt chloride or controls drinking tap water at day 0 (A) and at day 3 (B). Three controls and two cobalt-treated animals were analyzed. mRNA expression was determined by real-time quantitative reverse transcription-PCR. Expression was normalized to the housekeeping β-actin gene and was shown as a ratio to control animals. One percent of the total cDNA was analyzed in triplicate; comparative controls without reverse transcription were negative for each gene. (C) Western blot analysis of HO-1. In controls (n = 2 different animals), no signal was detected. HO-1 protein was induced by cobalt administration (n = 2 different animals). Molecular weight markers are shown on the left (in kD).

To confirm upregulation of protein products of renoprotective genes, we performed Western blot analysis of HO-1. The expression level of HO-1 protein in kidneys was not detectable in a control group, but it was clearly increased in a cobalt-treated group (Figure 4C).

Cobalt Administration Prevented Peritubular Capillary Loss Induced by Ischemic Insult

The increase in VEGF expression in cobalt-treated kidneys raised a possibility that protection of the kidneys against ischemic insult may be mediated by structural changes of the microvasculature. However, before ischemic insult, at day 0, capillary endothelial cells stained with JG-12 antibody were well maintained without any changes of the density of peritubular capillaries by cobalt administration (Rarefaction index score: Co treatment group [n = 2], 1.06 ± 0.44%; control [n = 3], 1.68 ± 0.16%). Cobalt administration into rats significantly prevented peritubular capillary loss by ischemia compared with that of the rats drinking tap water (rarefaction index score: Co treatment group, 9.34 ± 1.30% versus control, 17.2 ± 2.17%; P < 0.05; Figure 5).

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Figure 5. Immunohistochemical analysis of marker of microvascular endothelial cell, JG-12. Peritubular capillaries were well maintained before ischemic insult in controls (A) and in cobalt-treated animals (B). Photomicrographs at day 3 showed that ischemic insult diminished the density of peritubular capillary both in controls (C) and in cobalt-treated animals (D), although the loss was more severe in controls. Magnification, ×200.

Short-Term Cobalt Administration also Ameliorated Ischemic Insult as well as Long-Term Administration

To verify whether the efficacy observed in 13-d-adiministarated animals was due to the primary effect of cobalt, we employed short-term cobalt administration against ischemic injury. Subcutaneous cobalt chloride injection at a dose of 30 mg/kg twice diminished the rise of serum creatinine by ischemia as well as the long-term administration (Co treatment group, 1.54 ± 1.08 mg/dl; control, 3.12 ± 0.20 mg/dl at day 3). The improvement of renal function was associated with less severe damage shown in PAS-stained sections (Figure 6, A and B). To test our hypothesis that a protective effect of cobalt is attributed to hypoxia-related genes induced via HIF-1α stabilization, immunohistochemical study using anti-HIF-1α antibody was performed. Staining for HIF-1α was observed in some tubules of the medulla after 6 h of the last subcutaneous injection of cobalt. In contrast, no staining was seen in control animals (Figure 6, C and D).

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Figure 6. The short-term cobalt administration caused HIF-1α stabilization and ameliorated ischemic tubular damage. (A) Tubular injury, tubular dilation, tubular epithelial injury, debris accumulation, and cast formation were apparent in controls. (B) Damage was less severe in rats subcutaneously injected with cobalt twice. Periodic acid-Schiff staining. Magnification, ×200. Expression of HIF-1α in kidney 6 h after second cobalt injection. (C) No staining was seen in control. (D) Positive staining was seen in some tubules in the medulla. Magnification, ×400.