Acute oral dose of sodium nitrite induces redox imbalance, DNA damage, metabolic and histological changes in rat intestine

Industrialization and unchecked use of nitrate/nitrite salts for various purposes has increased human exposure to high levels of sodium nitrite (NaNO2) which can act as a pro-oxidant and pro-carcinogen. Oral exposure makes the gastrointestinal tract particularly susceptible to nitrite toxicity. In this work, the effect of administration of a single acute oral dose of NaNO2 on rat intestine was studied. Animals were randomly divided into four groups and given single doses of 20, 40, 60 and 75 mg NaNO2/kg body weight. Untreated animals served as the control group. An NaNO2 dose-dependent decline in the activities of brush border membrane enzymes, increase in lipid peroxidation, protein oxidation, hydrogen peroxide levels and decreased thiol content was observed in all treated groups. The activities of various metabolic and antioxidant defense enzymes were also altered. NaNO2 induced a dose-dependent increase in DNA damage and DNA-protein crosslinking. Histopathological studies showed marked morphological damage in intestinal cells. The intestinal damage might be due to nitrite-induced oxidative stress, direct action of nitrite anion or chemical modification by reaction intermediates.


Introduction
Nitrite was once considered to be inert, but is now recognized to play varied vital functions in different tissues of the human body, at low physiological concentration. It is also a ready source of nitric oxide (NO) which plays key role in immunology, physiology and neuroscience [1]. NO improves gastrointestinal health by mediating gastric blood flow; maintaining integrity of gastric epithelium and the mucus barrier and inhibiting leukocyte adherence to the endothelium [2]. The vasodilatory and hypotensive effect of NO is also known to decrease the risk of cardiovascular diseases and improve pulmonary health [1,3]. Sodium nitrite (NaNO 2 ) is widely used in the food industry as color fixative and preservative of fish and meat products. It acts as a flavour-enhancer and retards rancidity by preventing fat oxidation. It also inhibits the growth of micro-organisms, especially Clostridium botulinum which causes botulism. NaNO 2 is used for dye synthesis, manufacture of rubber chemicals and nitroso compounds

Experimental protocol
Animal housing and handling was conducted as per the institutional guidelines (Registration number: 714/GO/Re/S/02/CPCSEA) and all experimental procedures were approved by the Institutional Ethics Committee (IEC) of Aligarh Muslim University that monitors research involving animals. All efforts were made to minimize any suffering of rats during the entire treatment period. Adult male Wistar rats weighing 160-180 gm were used in this study. Animals were acclimatized for seven days on standard rat pellet diet and water ad libitum and then divided into five groups of six animals each (one control and four NaNO 2 treated groups). Animals in each treated group received a single acute dose of NaNO 2 (given orally through gavage) at 20, 40, 60 and 75 mg/kg body weight. Animals in the control (untreated group) were given an equivalent volume of water through gavaging. No animal died during the treatment period since the doses were below the reported LD 50 value of NaNO 2 (85-150 mg/kg body weight) for rats. All animals had free access to water and food during the entire treatment period and were sacrificed 24 h after administration of NaNO 2 , under local anesthesia using diethyl ether. The entire small intestine was removed, cleaned thoroughly by flushing with icecold 0.9% NaCl and then slit open along its entire length. A glass slide was used to gently scrape the mucosal layer and the scrapings used for the preparation of homogenates and brush border membrane (BBM) vesicles. For DNA damage studies, small intact portions of the intestine were separately suspended in RPMI (for comet assay) or homogenized in suitable buffer.

Preparation of mucosal homogenates and BBM vesicles
A 10% (w/v) homogenate of the mucosal scraping was prepared in 2 mM Tris-HCl, 50 mM mannitol buffer, pH 7.0, using an Ultra Turrex Kunkel homogenizer and glass Teflon homogenizer, by passing five pulses of 30 s each. Aliquots were immediately stored at -20˚C for the analysis of non-enzymatic parameters. The homogenates were centrifuged separately at 400 × g and 2,400 × g at 4˚C for 15 min and the supernatants collected and stored at -20˚C for the analysis of various enzymatic activities. The CaCl 2 precipitation method was used to prepare BBM vesicles from the homogenates, exactly as described by Farooq et al. [24]. The protein concentration in homogenates and BBM vesicles was determined by the method of Lowry et al. [25].
Lipid peroxidation, protein oxidation, GSH, total SH content and H 2 O 2 levels Several non-enzymatic parameters of oxidative stress were determined in crude intestinal homogenates. Lipid peroxidation was quantified from the reaction of its end product malondialdehyde with thiobarbituric acid [31] and the results are expressed as TBARS (thiobarbituric acid reactive substances). 2,4-Dinitrophenyl hydrazine was used to determine carbonyl group content which serves as an index of protein oxidation [32]. Reduced glutathione (GSH) levels were determined by fluorometric analysis, using N-ethylmaleimide and o-phthalaldehyde [33]. Total sulfhydryl (SH) content was determined using DTNB. The reaction between SH groups and DTNB gives yellow colored thionitrobenzoate, whose absorbance was determined at 412 nm [34]. Hydrogen peroxide (H 2 O 2 ) levels were quantified using FOX reagent (ferrous ammonium sulphate-xylenol orange) in the presence of 0.1 M sorbitol [35].
Acid phosphatase(ACP) and total adenosine triphosphatase (ATPase) activity ACP and total ATPase activities were determined in crude intestinal homogenates. ACP activity was measured from the enzyme catalysed hydrolysis of p-nitrophenyl phosphate, at pH 4.5, to form p-nitrophenol [36]. Total ATPase activity was assayed by quantifying the inorganic phosphate released upon ATP hydrolysis [37].

Antioxidant power
The antioxidant power was determined in intestinal homogenates by FRAP (ferric reducing/ antioxidant power) and DPPH (2,2-diphenyl-1-picrylhydrazyl) assays. These assays measure ferric reducing and free radical quenching ability of the cells using electrons donated by antioxidants in the sample. In the FRAP assay, 100 μl intestinal homogenate was incubated with 1.5 ml of FRAP reagent (containing 2,4,6-tris(2-pyridyl)-s-triazine and FeCl 3 in sodium acetate buffer, pH 3.6) at room temperature. After 5 min, the absorbance at 593 nm was noted and readings quantitated using a standard of ferrous sulphate [38]. DPPH assay was performed by mixing 0.4 ml of 10 mM sodium phosphate buffer, pH 7.4, with 0.1 ml intestinal homogenate followed by addition of 0.5 ml of 0.1 mM solution of DPPH in methanol. The reaction mixture was left in the dark for 30 min at 21˚C. After centrifugation at 12,000 × g, absorbance of the supernatants was read at 517 nm [39]. A 0.05 mM solution of DPPH was taken as reference. The DPPH scavenging capacity was calculated as: % Quenching of DPPH ¼ ½1À ðAbsorbance of sample=Absorbance of referenceÞ x 100

Enzymes involved in antioxidant defense mechanism
The supernatants of intestinal homogenates collected after centrifugation at 2,400 × g for 15 min at 4˚C were used to determine the activities of enzymes involved in free radical scavenging. Cu,Zn superoxide dismutase (SOD) was assayed from the inhibition of pyrogallol auto-oxidation by the enzyme [40] and catalase (CAT) from the decomposition of H 2 O 2 to water [41]. Glutathione reductase (GR) catalyzes the reduction of oxidized glutathione to its reduced form with concomitant conversion of NADPH to its oxidized form (NADP + ) [42]. The enzyme activity was determined by monitoring the decrease in absorbance at 340 nm. The enzyme Thioredoxin reductase (TR) was assayed from the formation of yellow colored thionitrobenzoate anion produced upon reduction of DTNB in the presence of NADPH [43]. Glutathione peroxidase activity was determined by the method of Flohé and Günzler [44] by following the decrease in absorbance at 340 nm upon conversion of NADPH to NADP + .

Enzymes of carbohydrate metabolism
The supernatants of intestinal homogenates collected after centrifugation at 400 × g for 15 min at 4˚C were used to determine the activities of enzymes involved in carbohydrate metabolism. The activities of lactate dehydrogenase (LDH), malate dehydrogenase (MDH), glucose 6-phosphatase (G6Pase), fructose 1,6-bisphosphatase (F6Pase) and malic enzyme (ME) were assayed as described by Khundmiri et al. [45]. Hexokinase (HX) activity was determined by the method of Crane and Sols [46] and G6PD was assayed using glucose 6-phosphate as substrate and monitoring the reduction of NADP + to NADPH at 340 nm [47].

DNA damage studies
Alkaline comet assay. The assay was performed as described by Singh et al. [48] with slight modifications. The suspension of intestinal mucosal cells in RPMI medium was mixed with 0.1 ml of 1% molten low-melting-agarose and immediately pipetted onto agarose precoated slides. A second layer of agarose was applied over the cell suspension layer and allowed to solidify properly. Cells were lysed by immersing the slides in lysing solution (2.5 M NaCl, 100 mM EDTA, 10 mM Tris-HCl, 1% Triton X-100, pH 10.0) for 3 hours at 4˚C. To allow DNA unwinding, slides were incubated for 30 min in alkaline electrophoresis buffer (1 mM EDTA, 300 mM NaOH, pH 13.0). Electrophoresis was carried out at 0.7 V/cm and 300 mA for 30 min at 4˚C. The slides were then neutralized with cold 0.4 M Tris-HCl, pH 7.5. The cells were stained with ethidium bromide and analysed under a CX41 fluorescent microscope equipped with the image analysis system, Komet 5.5, Kinetic Imaging, Liverpool, UK. The comets were scored at a magnification of 100x and images of 50 cells (25 from each replicate slide) per sample were scored. Tail-lengths were recorded.
Quantitative DNA fragmentation. DNA fragmentation was assayed by the colorimetric diphenylamine method of Burton [49]. Results are expressed as percentage of fragmented DNA to total DNA. Isolation of DNA and electrophoresis. Whole genomic DNA was isolated from mucosal tissue as described by Evans et al. [50]. Intestinal cells were lysed using lysis buffer (10 mM Tris-HCl, 0.1 M EDTA, 0.5% sodium dodecyl sulfate, pH 8.0) and equal volumes of phenol: chloroform: isoamyl alcohol solution (25: 24: 1) was added. The samples were centrifuged at 10,000 x g at 4˚C and the aqueous layer containing DNA transferred to sterile micro-centrifuge tubes. The DNA was precipitated with ethanol, washed and resuspended in TE buffer (100 mM Tris-HCl, 10 mM EDTA, pH 8.0). The DNA was first treated with DNase free pancreatic RNase (20 μg/ml final concentration) and then with proteinase K (0.1 mg/ml final concentration). Contaminating proteins were again removed by phenol: chloroform extraction and DNA precipitated with ethanol, washed with ice-cold 70% ethanol. The pellet of DNA was finally resuspended in TE buffer. The isolated DNA was electrophoresed on 0.7% agarose gels, stained with ethidium bromide and visualized under UV light.

Statistical analysis
All experiments were done three times to document reproducibility. The results of one set of experiments are presented here and are expressed as mean ± standard error of mean. Analysis of variance (ANOVA) was used in combination with Post-Hoc test (Bonferroni comparison test) using Origin Pro 8 software (USA) to evaluate the data. For clarity, the results of treatment groups were compared to the control group. Statistical significance is indicated at a probability level of p <0.05.

BBM enzymes
The specific activities of four BBM enzymes were determined in intestinal mucosal homogenates and isolated BBM vesicles. NaNO 2 administration resulted in significant decrease in the activities of all enzymes in intestinal homogenates. An NaNO 2 dose-dependent decrease was evident with the lowest activity present in the highest dose group of 75 mg/kg body weight. The percentage decrease in the activities of the enzymes, compared to the control group, were-LAP, 62.3; GGT, 45; ALP, 53.3 and sucrase, 40.2 (Table 1). A similar trend was observed in BBM vesicles, the extent of decrease being almost the same in all BBM enzymes. In BBM vesicles from the highest dose group, the observed percentage decrease was-LAP, 59.5; GGT, 48.2; ALP, 55.4 and sucrase, 42.5 when compared to the control group (Table 2).
Since there was significant inhibition (40-60%) of all BBM enzymes, kinetic studies were done by assaying them at different substrate concentrations and analysing the data by double reciprocal Lineweaver-Burk plots. These kinetic studies used isolated BBM vesicles and suggest non-competitive inhibition of all four enzymes by nitrite. For each enzyme, K M (Michaelis constant) value remained same while V max (maximum velocity) decreased in an NaNO 2 dosedependent manner (Fig 1).
The probability of enzyme inhibition through direct interaction with nitrite was checked by performing an in vitro experiment. Isolated BBM vesicles from control animals were incubated with different concentrations of NaNO 2 at 37˚C and the activity of each enzyme determined at different time intervals. All four enzymes showed significant direct inhibition by nitrite. Under these conditions, LAP activity was the most affected, showing 61% inhibition, followed by sucrase (38% inhibition), ALP (29% inhibition) and GGT (24% inhibition). No loss of any enzyme activity was observed in untreated BBM vesicle samples incubated at 37˚C, ruling out thermal inactivation of the enzymes (Fig 2). Increase in lipid peroxidation, protein oxidation and H 2 O 2 levels was observed in NaNO 2administered rats, in a dose-dependent manner. GSH levels and total SH content were both lowered concomitantly indicating decreased reducing ability of the cell. In the highest NaNO 2 dose group, the change in these parameters were-total SH content, -44.7%; GSH, -55%; lipid peroxidation, +163.6%; protein oxidation, +132.3% and H 2 O 2 , +117%, when compared to the control group (Table 3).
ACP and total ATPase activity NaNO 2 differently altered the activities of ACP and total ATPase. The activity of ACP, a lysosomal marker enzyme, was found to decrease, while the activity of total ATPase, a membrane bound enzyme, was found to increase with increasing dose of NaNO 2 . The alterations in enzyme activities in intestinal homogenates of the highest dose group were-ACP, +157% and total ATPase, -56%, as compared to control group (Table 4).

Antioxidant power
Antioxidants in sample can serve as donors of electron which can quench free radicals or reduce metal ions to lower oxidation states. This was determined by employing the widely used FRAP and DPPH assays which serve as indicators of antioxidant power of cell. Both assays showed that the antioxidant capacity of NaNO 2 -administered animals decreased dosedependently as compared to control animals. FRAP values were lowered by 54.2% and DPPH by 31.6% in the highest dose group, as compared to control values ( Table 5).

Enzymes of antioxidant defense
The activities of all major antioxidant defense enzymes decreased upon NaNO 2 administration. The trend observed was dose-dependent with the extent of decline in the highest dose group being-SOD, 55%; CAT, 58.6%; TR, 57.1%; GR, 61.8% and GPx, 53.9% as compared to control group ( Table 6).

Enzymes of carbohydrate metabolism
Enzymes of glycolysis, pentose phosphate pathway, gluconeogenesis and NADPH production were assayed in mucosal homogenates. Significant alterations in the activities of enzymes involved in carbohydrate metabolism and energy production were observed. The changes were again dose-dependent with maximum alterations evident in the highest dose group, HX, -45.1%; LDH-+152.6%; MDH, -55%; G6Pase, -35.7%; F6Pase, -44.1%; G6PD, -70.7% and ME, +187%, as compared to control group (Table 7). Results are mean ± standard error of six different preparations.

DNA damage
NaNO 2 administration increased DNA degradation and DNA-protein crosslinking in intestinal mucosal cells of animals in a dose dependent manner. DNA degradation was assessed by comet assay, agarose gel electrophoresis and colorimetric assay for release of free nucleotides.
The diphenylamine assay showed that treatment with NaNO 2 induced DNA damage in a dose-dependent manner in the intestinal cells of rats (Fig 3). DNA degradation was almost two times the control value in the group treated with the highest concentration of NaNO 2 (75 mg/ kg body weight). This observation was further confirmed by agarose gel electrophoresis and the comet assay.
In the comet assay, a dose-responsive increase in tail length was observed in NaNO 2 treated groups as compared to control group (Fig 4). This is indicative of DNA degradation and strand breaks. Migration length is considered to be directly related to fragment size and proportional to the level of single stranded breaks and alkali-labile sites [52].
Agarose gel electrophoresis of DNA from intestinal cells of rats showed significant smearing in a dose-dependent manner in NaNO 2 treated groups as compared to control group ( Fig  5). Smearing of DNA bands is a clear indication of DNA fragmentation and strand breaks. The highest dose group exhibited maximum smearing and hence, maximum damage. No evidence of 200 bp ladder formation, characteristic of apoptosis, was seen in any group.
An increase in DPCs induced by NaNO 2 was clearly evident from the K + -SDS assay ( Table 8). The percentage of DPC formation in the highest dose group was 3.4 times the value in the control group. Histopathology Histological examination of duodenal sections of rat intestine from control and treated groups revealed morphological alterations in NaNO 2 -treated groups (Fig 6). The changes were more prominent at higher dose and included swelling of villi, alteration in the contour, congestion, increased lymphocytic infiltration in the lamina propria with focal necrosis of enterocytes especially those located on the luminal half (apical) of villi. However, no obvious change in the crypt-to-villus ratio was observed.

Discussion
Industrialization has contributed immensely to human development but at the same time has increased human exposure to many harmful pollutants and toxicants. NaNO 2 is among one of these noxious contaminants which affects human and animal health across the globe. Rampant use of nitrogenous fertilizers to increase crop yield and improper waste disposal has mainly contributed to the nitrite load of the environment. Overexposure to nitrite has been reported to cause various health problems including cancer with contaminated water being the main source [53]. Nitrite acts as a pro-oxidant and pro-carcinogen at high doses. Nitrite intake through the oral route results in its rapid absorption through the gastrointestinal tract and entry into the bloodstream from where it is made available to other tissues. Once inside the cell, it is readily interconvertible to nitrate and/or NO through cellular oxidation/reduction processes [1]. Reactive oxygen species (ROS), generated by intracellular redox reactions, together with the formation of harmful compounds such as nitryl chloride, results in cytotoxicity and tissue damage [54]. In this work, we have investigated the effect of a single acute oral dose of NaNO 2 on various biochemical aspects and morphology of rat intestine. The BBM plays a key role in the digestive and absorptive functions of the intestine as it contains various digestive enzymes and transporters. A marked decrease (40-60%) in the activities of all BBM enzymes was evident in intestinal homogenates and isolated BBM vesicles from NaNO 2 treated rats. The extent of decrease was almost the same in both preparations. This is clearly indicative of damage to the epithelial cell lining of the intestine. Kinetic studies performed show that the decline in enzyme activities was due to decrease in V max with no Results are mean ± standard error of six different preparations. * Significantly different at p < 0.05 from control.
significant alteration in K M values for all the enzymes. Thus, nitrite administration did not affect the affinity of these enzymes for their substrates. The decline in the activity of BBM enzymes can be attributed to a number of factors. Firstly, nitrite-generated ROS can cause oxidative modification of lipids and proteins which in turn will disrupt membrane integrity. This might cause loss of enzyme molecules from the epithelial cell lining. Secondly, ROS can directly oxidize enzyme molecules and decrease their activity. Higher protein oxidation was seen in mucosa of NaNO 2 -treated animals. Thirdly, nitrite anion itself can directly interact with enzymes resulting in their inhibition. This probability was inferred from the in vitro experiments performed with the enzymes.
The intestinal epithelial cells are constantly exposed to xenobiotics which makes them susceptible to oxidant attack and damage. As a defense, enterocytes are well-equipped with robust enzymatic and non-enzymatic antioxidant defenses which are important for their normal functioning [55]. NaNO 2 administration led to a dose-dependent increase in levels of H 2 O 2 , a non-radical ROS. H 2 O 2 can generate the vastly more damaging hydroxyl radical upon reaction with transition metals like iron. Increase in lipid peroxidation can be attributed to increase in the levels of superoxide radical and H 2 O 2 , since the activities of the enzymes that use them as Nitrite causes genotoxicity and alters rat intestinal metabolism Nitrite causes genotoxicity and alters rat intestinal metabolism  substrates, SOD and CAT, were decreased. A two-fold increase in protein carbonyl content was observed in the highest NaNO 2 dose group. ROS attack amino acids and form carbonyl groups; introduction of carbonyl groups is commonly used as an index of protein oxidation. NaNO 2 -induced protein oxidation and nitration of meat products has been reported earlier [56]. A profound decrease in levels of GSH and total SH content represents weakening of the first line of defense against oxidative damage of the cells. A reduction in GR activity, which reduces GSSG to GSH, could have resulted in lowered GSH levels. Direct oxidation of SH groups (of proteins and GSH) by ROS or formation of nitrosothiols upon reaction with NO could be another reason [57]. The thiol status of intestinal mucosa was, therefore, greatly affected upon NaNO 2 administration. The activities of all major antioxidant defense enzymes were found to dose-dependently decrease in all NaNO 2 -treated groups as compared to the control. ROS and free radicals are known to inactivate both SOD and CAT [58] which are metalloenzymes containing bound copper and iron, respectively. NO forms complexes with transition metal ions and can thus directly interact with these enzymes and interfere in their activity. Direct inhibition of CAT by nitrite in presence of specific anions has also been reported [59]. A decrease in the activities of TR, GR and GPx could also be due to oxidative modification of these enzymes. Peroxynitrite and superoxide radicals are specifically known to inhibit GPx activity [60].
A decrease in GSH content and inhibition of antioxidant enzymes can impair the antioxidant power of cells. A dose-dependent decrease in antioxidant capacity was observed in all NaNO 2 -treated groups. This strongly suggests oxidative damage by NaNO 2 and inhibition of endogenous defense system of the cell. The lowered antioxidant capacity will make the cells more susceptible to oxidative damage by ROS, since the ROS quenching ability will be greatly compromised. Although antioxidant property of NaNO 2 at low doses has been reported, it does not act as a direct antioxidant. Montenegro et al. [61] have shown the inability of nitrite to scavenge superoxide radicals or ameliorate iron-induced lipid peroxidation under in vitro Nitrite causes genotoxicity and alters rat intestinal metabolism conditions. The reported cellular antioxidant effect can probably be explained by NADPH oxidase downregulation and/or alterations in activities of enzymes involved in antioxidant defense [62,63].
Uptake of glucose from the diet and delivery to other tissues is mediated by the small intestine. The gut plays a key role in maintaining glucose homeostasis. The effect of NaNO 2 administration on the activities of various enzymes involved in glucose utilization was examined. The activity of LDH was increased while MDH activity was decreased in all NaNO 2 treated groups. LDH, an enzyme of anaerobic glycolysis, catalyzes the interconversion of pyruvate to lactate. Although lactate is a dead-end metabolite, necessitating reconversion to pyruvate, lactate production generates NAD + which is required for glycolysis. MDH reversibly catalyzes malate oxidation to oxaloacetate which is an intermediate of the tricarboxylic acid (TCA) cycle and leads to energy production through the aerobic mode. Inhibition of MDH activity and increased LDH activity suggests a shift in energy production from aerobic to anaerobic mode of glycolysis. The first step in glucose utilization, whether by the aerobic, anaerobic or pentosephosphate pathway, is catalyzed by HX. A decrease in HX activity in all NaNO 2 treated groups indicates decreased cellular energy production. The role of intestine in gluconeogenesis has been recently discovered. Although liver is the main site of gluconeogenesis in normal state, intestinal gluconeogenesis is important during starvation and anhepatic conditions [64]. G6Pase is an endoplasmic reticulum-associated enzyme which catalyzes the final step of gluconeogenesis and glycogenolysis. F6Pase is involved in gluconeogenesis and the Calvin cycle both of which are anabolic pathways. Intestinal G6Pase and F6Pase, therefore, play key role in the homeostatic regulation of blood glucose levels and NaNO 2 decreased the activities of both enzymes. Membrane disruption and oxidative modification could be possible reasons. Lowered G6PD activity and increased ME activity was found in NaNO 2 treated groups. G6PD is the first and an indispensable enzyme of the pentose phosphate pathway. It generates NADPH which is the major cellular reducing equivalent. A decrease in G6PD activity makes the cell more susceptible to oxidant attack. Increased activity of ME, which also generates reducing equivalents, can be considered as an adaptive response to compensate the decrease in G6PD activity.
Increased carbonyl content of proteins can lead to their enhanced crosslinking with DNA. A DPC is created when a protein becomes covalently bound to DNA. These lesions interfere in DNA replication, transcription and repair which might lead to permanent DNA damage [65]. A dose-dependent increase in DPC formation in all NaNO 2 -treated groups was observed. DPCs greatly interfere in DNA-repair mechanisms resulting in strand breaks, fragmentation and other genetic lesions. NaNO 2 -mediated DNA damage could be due to several mechanisms: direct chemical modification by free radicals [66] or indirectly through free radical induced lipid oxidation products like unsaturated aldehydes and malondialdehyde that can bind to DNA to generate mutagenic lesions [67]. Our results comply with previous reports which showed that nitrite and its related metabolized products cause DNA damage and genotoxicity [68,69]. Nitrite can cross membranes, probably as nitrous acid, a known mutagenic compound that can damage DNA through several mechanisms [70,71]. Nitrite itself has been shown to damage DNA under in vitro conditions in human respiratory tract cell lines and calfthymus DNA [72,73]. NO also causes dose-responsive DNA damage [74,75], while peroxynitrite and other higher oxides of nitrogen are also known to readily attack and damage DNA [76]. Several reactive nitrogen species have been implicated in the multistage carcinogenesis process associated with chronic inflammation and infections [77,78].
Lowered ATPase activity in NaNO 2 treated animals suggests that the basolateral membrane of intestinal cells was damaged. The establishment of an electrochemical gradient of sodium ions across the epithelial cell boundary of the lumen is probably the most important process that aids absorption. To maintain low intracellular levels of sodium, a large number of Na,K-ATPases, highly conserved integral membrane proteins, are present in the basolateral membrane of enterocytes [79]. ATPases maintain a gradient of both sodium concentration and charge facilitating absorption of sugar, oligopeptide and amino acids [80]. A decline in the activity of this enzyme would lead to derangement of the primary function of absorption of enterocytes which would impair overall balance of solutes and ions in the body. ACP is a lysosomal marker enzyme and an increase in its activity is indicative of intestinal damage. These changes may be attributed to free radical attack or nitrosation of essential sulfhydryl groups (ATPase) by NO. Lipid and protein oxidation might have also contributed to membrane damage and consequent enzyme inhibition.
The nitrite-induced intestinal damage suggested by the biochemical changes observed above was confirmed by histological studies. Morphological changes in the intestinal epithelial cells were studied by microscopic examination of stained sections of duodenum of control and NaNO 2 treated groups. In the higher dose groups, marked changes were obvious, including lymphocytic infiltration and congestion in the lamina propria and focal necrosis of enterocytes located in the apical region of villi (Fig 6).
Thus, nitrite administration caused marked changes in various biochemical parameters and morphology of rat intestinal cells. The NaNO 2 -induced damage to intestinal epithelial cells can affect overall physiology in several ways. 1. Decreased activities of BBM enzymes and total ATPase will reduce absorption of nutrients, especially sugars and amino acids, into the epithelial cells of the small intestine. This will reduce the pool of essential building blocks of the body which will, in turn, greatly hamper energy production. 2. Alterations in the activities of Nitrite causes genotoxicity and alters rat intestinal metabolism enzymes of carbohydrate metabolism will affect glucose utilization by enterocytes and impair intestinal gluconeogenesis which plays key role in energy homeostasis [81]. 3. Decreased antioxidant capacity of enterocytes due to impairment of its enzymatic and non-enzymatic components will increase susceptibility to oxidant attack. 4) DNA lesions of various nature may cause genotoxic and/or mutagenic effects which may lead to cancer development. Oxidative stress condition is considered to be a major etiologic factor in several intestinal diseases [82]. A cumulative effect of all these factors might have led to intestinal damage in NaNO 2 -treated rats as observed in our study. A schematic representation of the damaging effects of NaNO 2 on rat intestine, based on our experimental observations, is shown in Fig 7. An over view of the damaging effects of NaNO 2 on intestinal cells, as presented in this study, will be helpful in deciphering the mechanism of nitrite toxicity in greater detail, understanding the role that nitrite plays in cancer development and other pathologies and in the choice of protective/ therapeutic agents to counter its deleterious effects.