Introduction

The prevalence and incidence of chronic kidney disease (CKD), which in its later stage termed chronic renal failure (CRF), are on worldwide increase (James et al. 2010; Nugent et al. 2011). The major factors behind this apparent increase are the environmental pollution, misuse and irrational use of drugs, and the prevalence of schistosomiasis, malaria, obesity, hypertension, and diabetes mellitus (Himmelfarb 2004). The relatively poor status of the health care system in the developing countries is at strong demand for studies into the pathophysiology and mechanisms of CKD, and exploring new effective therapeutic strategies and ameliorating agents, especially for the earlier stages of CKD in order to slow its progression towards CRF and reduce the cost of dialysis, drug therapy, and kidney transplantation (Ichihara et al. 2009).

Animal models are important tools in studying the different mechanisms of CKD and exploring potential therapy on these mechanisms (Desrochers et al. 2014). Adenine-induced CKD was first reported in the 1980s as an alternative method for the surgical model which is expensive and skill requiring (Al Za’abi et al. 2015). Natural products are used as an alternative approach to ameliorate the severity of CRF and reduce the frequency of dialysis.

Gum arabic is defined as an edible, dried gummy exudate obtained from the stems and branches of Acacia senegal and Acacia seyal trees that is rich in non-viscous soluble fiber and is widely used as an emulsifier and stabilizer in pharmaceutical, cosmetic, and food industry (Ali et al. 2009). It has been used in the Middle East and North Africa as an oral hygienic substance and anti-inflammatory for intestinal mucosa and inflamed skin (Gamal el-din et al. 2003). Addition of GA to the diet has been shown to increase fecal urea nitrogen excretion, with a concomitant decrease in serum urea nitrogen concentration (Ali et al. 2008). Therefore, GA is used for some time now in traditional medicinal practice with CRF patients (Ali et al. 2014; Becker and Hewitson 2013).

Cymbopogon citratus commonly known as lemongrass is a tall, coarse grass with a strong lemon taste and has a wide range of therapeutic, nutritional, and cosmetic uses. The plant is used as an antioxidant and anti-inflammatory, anticarcinogenic, hypoglycemic, and cardioprotective agent in folk medicine (Akande et al. 2011). Nutritionally, lemongrass is used as a flavoring spice in many cuisines and confections. Its essential oil enters in many cosmetic preparations as perfumes, soaps, detergents, and body lotions. The infusions prepared from its dry or fresh leaves are extensively used in recent years as a diuretic for treatment of urinary tract disorders as cystitis, renal stones, and urine retention and for treatment of hypertension and associated cardiovascular disorders; it is also used in the treatment of gout (Mirghani et al. 2012).

The present study aimed to evaluate the biochemical effects of GA and LG on adenine-induced CKD in a rat model through investigating their antioxidant and anti-inflammatory mechanisms.

Material and method

Chemicals

Adenine was obtained from Sigma-Aldrich (St Louis, MO, USA). Gum arabic and lemongrass were obtained from a local market.

Experimental animals

A total of 40 male Wistar albino rats weighing 150–170 g were supplied from the animal house of Faculty of Veterinary Medicine, Benha University, Egypt. Animals were kept in cages under proper environmental conditions of temperature, humidity, and light and had free access to food and water. The animals were acclimatized to the laboratory conditions for 2 weeks prior to the experiment. The animal handling procedures were conducted according to the ethical norms approved by the Ethical Committee of Faculty of Veterinary Medicine, Benha University.

Experimental design

Rats were randomly and equally divided into four groups (10 animals each).

  • Group I (control group): received i.p injection of saline twice a week.

  • Group II (adenine group): received i.p injection of adenine (300 mg/kg b.w) twice a week (Al Za’abi et al. 2015).

  • Group III (adenine + GA group): received i.p injection of adenine (300 mg/kg b.w) twice a week and gum arabic (4.5 g/kg b.w daily p.o) for 4 weeks (Ali et al. 2008).

  • Group IV (adenine + LG group): received i.p injection of adenine (300 mg/kg b.w) twice a week and lemongrass (360 mg/kg b.w daily p.o) for 4 weeks (Christopher et al. 2014).

Sampling

Blood sampling

At the end of experimental period, all animals were fasted overnight and euthanized with diethyl ether. Blood samples were collected directly from the heart, and the serum was separated for biochemical analysis.

Tissue sampling

Tissue specimens from both kidneys were quickly excised, rinsed in ice-cold saline to exclude the blood cells, blotted on a filter paper, and divided into three parts. The first part was kept at − 20 °C until used for determination of oxidative stress indices. The second part was kept at − 80 °C for gene expression. The third part was placed in 10% formalin solution for histological and immunohistochemical investigations.

Biochemical analysis

Evaluation of kidney function tests

Urea, creatinine, and uric acid concentrations were spectrophotometrically determined following the procedures of Coulombe and Favreau (1963), Larsen (1972), and Young et al. (1975) respectively.

Assessments of oxidative stress indices

The kidney tissues were cut, weighed, homogenized in 4 mL physiological saline, and centrifuged at 5000 rpm for 20 min at 4 °C. The supernatant was used for determination of oxidative stress parameters. L-MDA as a marker for lipid peroxidation (Mesbah et al. 2004); reduced glutathione (non-enzymatic antioxidant, GSH) (Moron et al. 1979), catalase (CAT) (Aebi 1984), and superoxide dismutase (SOD) (Kakkar et al. 1984) activities; and total antioxidant capacity (TAC) (Benzie and Strain 1996) were determined using diagnostic kits obtained from Laboratory Biodiagnostics Co. (Cairo, Egypt).

Determination of renal endothelin-1 (ET-1)

Endothelin-1 was determined according to the method described by Rolinski et al. (1994).

Measurement of TNF-α, IL-10, and vascular endothelial growth factor (VEGF) gene expression

Total RNA was extracted from rat kidneys using a Gene JET RNA Purification Kit (Thermo Scientific, # K0731, USA) according to the manufacturer’s protocol. Complementary DNA was synthesized using 5 μg of total RNA by RevertAid H Minus Reverse Transcriptase (Thermo Scientific, #EP0451, USA). The primer sequences used for amplification are summarized in Table 1. Quantitative RT-PCR for TNF-α, IL-10, and VEGF genes was performed using a StepOnePlus RT-PCR system (Applied Biosystems, USA) with initial denaturation at 95 °C for 10 min, 40–45 amplification cycles at 95 °C for 15 s, annealing at 60 °C for 30 s, and extension at 72 °C for 30 s. At the end of the last cycle, the temperature was increased from 63 to 95 °C for melting curve analysis. The cycle threshold (Ct) values were calculated for target genes and the β-actin as housekeeping gene, and relative gene expression was determined using the 2−∆∆Ct method (Livak and Schmittgen 2001).

Table 1 Forward and reverse primer sequences for qRT-PCR

Histological and immunohistochemical analysis

Parts of the removed rat kidneys were fixed in 10% buffered formalin, embedded into paraffin blocks using conventional paraffin-embedding techniques, processed to obtain 5-μm-thick sections, stained with hematoxylin and eosin (H&E), and examined under a light microscope.

For immunostaining, paraffin-embedded renal sections were de-paraffinized (in xylene) and dehydrated sequentially in graded ethyl alcohol, followed by antigen unmasking in citrate buffer (pH 6.0); 5% normal goat or rabbit serum in phosphate buffered saline was used to block non-specific binding sites. Later, sections were incubated with primary antibodies against γ-H2AX (Neo Markers/Lab vision, Fremont, CA, USA), followed by specific biotin-conjugated secondary antibodies. For color development, streptavidin-peroxidase kits were added to the slides and sections were counterstained with Mayer’s hematoxylin.

Statistical analysis

The results were expressed as mean ± SE of studied groups using the analysis of variance test (one-way ANOVA) followed by Duncan’s multiple range test to determine the differences between the averages with statistical significance at P ≤ 0.05. All statistical analyses were performed by Statistical Package for the Social Sciences Software (Version 18, SPSS Inc., Chicago, IL, USA).

Results

Biochemical results

Data in Table 2 show that intraperitoneal injection of adenine induced a significant increase in serum concentration of urea, creatinine, and uric acid versus the normal control rats. On the other hand, oral administration of GA and LG significantly but not completely restored these alterations. Interestingly, the serum concentrations of these parameters were restored near to the normal ranges after administration of the LG group when compared to the adenine + GA group.

Table 2 Effect of GA and LG oral administration on serum urea, creatinine, and uric acid (UA)

As illustrated in Table 3, we noticed that MDA concentration was significantly increased while GSH concentration, CAT and SOD activities, and TAC were significantly decreased after adenine injection in comparison with the control group. Meanwhile, oral administration of GA and LG significantly decreased MDA concentration and increased GSH concentration, antioxidant enzyme activities, and TAC when compared to the adenine group. Moreover, LG administration exhibited a significant improvement in renal indices of oxidative stress in comparison with the adenine + GA group.

Table 3 Effect of GA and LG oral administration on kidney oxidative stress indices

Concerning the cytokines, there is a marked upregulation in TNF-α and downregulation in the IL-10 gene expression in kidneys of rats injected with adenine. However, oral administration of GA and LG significantly restores these alterations. Moreover, LG administration showed better results when compared to the adenine + GA group. Intraperitoneal injection of adenine significantly increased renal ET-1 with downregulation of the VEGF gene as showed in Table 4 comparing to the control group. GA and LG were able to significantly decrease renal ET-1 and upregulate the VEGF gene.

Table 4 Effect of GA and LG on expression of TNF-α, IL-10, and VEGF genes and ET-1

Immunohistochemical results

Intraperitoneal adenine injection significantly increased the protein expression of γ-H2AX within the renal tubules (Fig. 1b) in comparison with the control group which revealed mild or absent immunoreactivity (Fig. 1a). Adenine-injected rats that received either GA (Fig. 1c) or LG (Fig. 1d) showed significant reductions in the expression of γ-H2AX in comparison to the adenine group.

Fig. 1
figure 1

γ-H2AX immunohistochemical expression in the renal cortex. a Control group showed minimal γ-H2AX expression. b Adenine group showed many γ-H2AX-positive cells (arrowhead). c Adenine + GA group showed moderate reduction in γ-H2AX-positive cells (arrowhead). d Adenine + LG group showed minimal γ-H2AX expression (arrowhead)

Histopathological changes in the renal cortex

Control rats showed normal renal histology (Fig. 2a), whereas those injected with adenine exhibited marked pathological alterations as degeneration of the renal glomeruli and renal tubules with loss of architecture and disorganization (Fig. 2b). On the other hand, oral administration of GA (Fig. 2c) and LG (Fig. 2d) preserves to a large extent the normal architecture of the renal cortex except for slight degeneration and cystic dilatation of some renal tubules.

Fig. 2
figure 2

Renal cortex; Rat. a Control group showing normal histological architecture. b Adenine group showing degeneration to renal glomeruli (black arrow), degenerative changes (blue arrow) and loss of architecture in PCTs and DCTs. c Adenine + GA group showing moderate histopathologic changes (blue arrow). d Adenine + LG group showing mild morphologic changes (arrow). HE stain, × 400

Discussion

The increasing incidence of CKD and the limitation of renal replacement therapy, either by transplantation or dialysis, especially in developing countries due to a lack of financial and clinical resources requires exploring new strategies to delay the onset of dialysis or to attenuate uremia (Jain et al. 2012). In the current study, we assessed the effects of GA and LG oral administration on several biochemical, antioxidant, and inflammatory parameters in an adenine-induced CKD model in rats. The results indicated that concomitant treatment with GA and LG ameliorated the adverse effects induced by adenine.

Induction of CRF by adenine in rats is a standard method for simulating a metabolic abnormality which occurs in humans suffering from renal failure (Ali et al. 2013b). It was reported that adenine-rich diets suppress the excretion of nitrogenous compounds due to renal tubular occlusion. Adenine becomes a target, when present in excess, for xanthine dehydrogenase and oxidized to 2,8–dihydroxyadenine crystals. Adenine and its metabolite (DHA) precipitate in the renal tubules leading to their occlusion (Adachi et al. 1998). Our results came in accordance with this theory as shown in (Table 1). Moreover, there is evidence on inflammation and oxidative stress of renal tissues observed in adenine-induced CKD (Al Za’abi et al. 2015) as seen in the present study (Tables 3 and 4). This is consistent with previous observations of Carrero and Stenvinkel (2010) as well as Kinugasa (2011) who found that CKD patients have high plasma concentration of inflammatory and oxidative stress markers. Also, lipid peroxidation as an oxidative stress marker and C reactive protein (CRP) as an inflammatory marker are reported by other studies to be increased (Annuk et al. 2001; Shlipak et al. 2003).

Remarkably, in the current study, a significant reduction in serum concentration of urea, creatinine, and uric acid was observed in adenine-induced CKD rats receiving a daily oral dose of gum arabic. GA has been used recently in several developing countries to treat CKD since it has been reported to decrease serum urea nitrogen concentration and increase fecal nitrogen excretion by utilizing the bowl as a substitute kidney (Ali et al. 2009). It has been assumed that GA increases the available energy to the intestinal bacteria which ferment dietary fibers and obtain their nitrogen requirement from the nitrogen waste product of the host (Ali et al. 2004; Ali et al. 2009). They also degrade urea to ammonia, which is excreted with some of the body nitrogen waste in feces (Younes et al. 1995; Bliss et al. 1996). Moreover, a considerable cecum enlargement, by increasing its contents, wall thickness, and blood flow, was observed after consuming fermentable fibers. These changes decrease plasma urea concentration by 30% through enhancement of urea nitrogen uptake into the cecum (Younes et al. 2006).

Recently, GA has been found to act as an antioxidant and anti-inflammatory agent in addition to its beneficial effects on kidney function (Ali et al. 2013a; Ali et al. 2013b). Our data explored the antioxidant effect of GA as confirmed by the significant reduction in MDA and increase in GSH, TAC, and antioxidant enzyme activities in kidney tissue of the adenine + GA group. These results are consistent with the previous record of Al Za’abi et al. (2015) who suggested the main mechanism for the beneficial action of GA in adenine-induced CKD via its antioxidant properties.

Moreover, anti-inflammatory properties of GA was observed in maintaining, to some extent, the balance between renal expression of pro-inflammatory (TNF-α) and anti-inflammatory (IL-10) cytokines in rats received daily oral dose of GA concomitant with i.p injection of adenine when compared to the adenine group as illustrated in Table 4. Adenine-induced CKD was proven to induce inflammatory reaction in kidney tissue in the form of increased serum CRP and increased TNF-α in CRF subjects while using GA in both studies mitigated this action (Mahmoud et al. 2012; Ali et al. 2013a). A possible contributing mechanism to the effect of GA on nitric oxide (NO) metabolites, which consequently affect the level of TNF-α, in rats with renal failure might result from the antioxidant and anti-inflammatory properties of GA (Al Suleimani et al. 2015). On the other hand, GA has been reported to suppress gut inflammation in IL-10-deficient mice (Bassaganya-Riera et al. 2011).

It is important to highlight that oxidative stress played an important role in the pathogenesis of CKD and its complications including impairment of protein and DNA synthesis and cellular repair mechanisms (Perazella and Moeckel 2010). As far as we know, there are few reports on DNA damage in kidney disease. Ali et al. (2013a) and Schupp et al. (2011) attributed the DNA damage, single- and double-strand breaks, in there models to the increased oxidative stress. The first step in recruiting and localizing DNA repair proteins is γ-H2AX, a newly phosphorylated histone observed in nucleosomes after DNA damage (Kuo and Yang 2008). Decreasing superoxide anions and oxidative stress through oral administration of GA in the present study lowered the incidence of DNA double-strand breaks to a certain extent.

Furthermore, a previous study ascribed the positive effect of GA in lowering the hypertension, a complication of CKD, observed in adenine-treated rats to its antioxidant power since reactive oxygen species (ROS) increased in animals with hypertension (Ali et al. 2011). The significant increase in endothelin-1 (ET-1), a vasoconstrictor secreted by endothelial cells (Marasciulo et al. 2006), in the adenine group may be attributed to the high level of free radicals and cytokines (Ali et al. 2013a). Vascular endothelial growth factor (VEGF), an angiogenic inducer, is downregulated by ET-1 as previously reported (Ferrara 2004). On the other hand, Al Suleimani et al. (2015) examined the effect of adenine-induced CKD on angiogenesis and found no significant difference in plasma level of ET-1 and VEGF in spite of the previous study of Ali et al. (2011) which revealed several vascular changes including blood pressure and heart rate in rats with adenine-induced CRF.

Oral administration of LG to adenine-injected rats exhibited a significant decrease in serum urea, creatinine, and uric acid indicating an effective role of LG on kidney function which may be attributed to its diuretic effect. The phytochemical constituents of LG interfere with electrolyte and water reabsorption through renal tubules which consequently enhance the excretion of nitrogenous compounds (Christopher et al. 2014) as recorded in the present study.

Our data explored the antioxidant effect of LG as confirmed by decreased MDA level and increased antioxidant enzyme activities in kidney tissue of the adenine + LG group. This is supported by the previous finding of Arhoghro et al. (2014) who noted that aqueous leaf extract of LG ameliorated cisplatin-induced oxidative damage on the liver via its antioxidant and free radical-scavenging properties. Moreover, the renal protective effect of LG against gentamicin-induced toxicity could be attributed to its strong flavonoid content and antioxidant properties (Ullah et al. 2013) which consequently affect ET-1 and VEGF as shown in (Table 4).

We consistently observed that LG administration inhibits TNF-α expression that coincides with the record by Francisco et al. (2013) who attributed the anti-inflammatory effect of LG to its phenolic content and inhibition of nuclear factor-κβ pathway and cytokine expression. In addition, scavenging the ROS, which act as potential contributors to inflammation in CKD (Cachofeiro et al. 2008), plays an important role in its anti-inflammatory effect.

These biochemical findings were further confirmed by evidences of microscopic examinations. In this study, degenerative changes to renal glomeruli induced by i.p injection of adenine markedly attenuated by oral administration of GA and LG which might be attributed to their free radical-scavenging activities.

Conclusion

Oral administration of GA and LG daily for 4 weeks successfully ameliorated the adenine renal damaging as evidenced by biochemical, immunohistochemical, and histopathological examination. The possible mechanisms of this action might be ascribed to their antioxidant and anti-inflammatory properties.