Effect of nickel sulfate on testicular steroidogenesis in rats during protein restriction. (Articles).Nickel, a widely used heavy metal, exerts potent toxic effects on peripheral tissues as well as on the reproductive system. Low dietary protein coupled with exposure to this metal induces more severe changes, including biochemical defects, structural disorders, and altered physiologic functions. This study was designed to assess the effects of nickel sulfate sulfate, chemical compound containing the sulfate (SO4) radical. Sulfates are salts or esters of sulfuric acid, H2SO4, formed by replacing one or both of the hydrogens with a metal (e.g., sodium) or a radical (e.g., ammonium or ethyl). on testicular testicular /tes·tic·u·lar/ (tes-tik´u-lar) pertaining to a testis. tes·tic·u·lar adj. Of or relating to a testicle or testis. testicular pertaining to the testis. steroidogenesis steroidogenesis /ste·roi·do·gen·e·sis/ (ste-roi?do-jen´e-sis) production of steroids, as by the adrenal glands.steroidogen´ic ste·roid·o·gen·e·sis n. The biological synthesis of steroids. and to ascertain whether such alterations are reversible with normal protein and protein-restricted dietary regime. Nickel sulfate [2 mg/100 g body weight (bw)] dissolved in double-distilled water was administered on alternate days for 10 doses in a normal protein diet (18% casein casein (kā`sēn), well-defined group of proteins found in milk, constituting about 80% of the proteins in cow's milk, but only 40% in human milk. ) and a protein-restricted diet (5% casein) to Wistar male albino albino (ălbī`nō) [Port.,=white], animal or plant lacking normal pigmentation. The absence of pigment is observed in the body covering (skin, hair, and feathers) and in the iris of the eye. rats (bw 160 [+ or -] 5 g). Two groups, one with a normal protein diet and the other with a protein-restricted diet, served as controls. Twenty-four hours after the last treatment, all the animals except those in withdrawal groups were sacrificed by decapitation Decapitation See also Headlessness. Antoinette, Marie (1755–1793) queen of France beheaded by revolutionists. [Fr. Hist.: NCE, 1697] Argos lulled to sleep and beheaded by Hermes. [Gk. Myth. . We observed a significant reduction in the activities of the testicular steroidogenic enzymes and plasma testosterone concentration accompanied by a significant elevation in cholesterol and ascorbic acid level in both dietary groups. After 15 days of withdrawal from the nickel sulfate treatment, the testicular steroidogenic enzymes, along with plasma testosterone level, improved significantly in both normal protein-fed and protein-restricted dietary groups. The effects of nickel on testicular cholesterol and ascorbic acid concentration were also reduced after withdrawal. Our results indicate that nickel sulfate affects the steroidogenic enzymes, causing alteration in the formation of testosterone in both dietary groups, which was manifested in the elevated cholesterol and ascorbic acid level with decreased activities of steroidogenic enzymes in adult rats testes testes or testicles Male reproductive organs (see reproductive system). Humans have two oval-shaped testes 1.5–2 in. (4–5 cm) long that produce sperm and androgens (mainly testosterone), contained in a sac (scrotum) behind the penis. . However, these alterations were reversible in both groups of animals fed normal protein diets and protein-restricted diets. Key words: hydroxysteroid dehydrogenase, nickel sulfate, protein restriction, testes, testosterone. Environ Health Perspect 110:923-926 (2002). [Online 13 August 2002] http://ehpnet1.niehs.nih.gov/docs/2002/110p923-926das/abstract.html ********** Modern industrialization industrialization Process of converting to a socioeconomic order in which industry is dominant. The changes that took place in Britain during the Industrial Revolution of the late 18th and 19th century led the way for the early industrializing nations of western Europe and has introduced harmful metals into the environment by redistributing them from immobilized ores and minerals, thereby exposing humans and animals to more metal salts. The toxicity of a metal depends on its inherent capacity to adversely affect any biologic activity. Among the myriad environmental pollutants, nickel, a heavy metal, merits special consideration as a potential toxic element (1,2), even though it helps in hemopoiesis he·mo·poi·e·sis n. Variant of hematopoiesis. hemopoiesis (hē´mōpōē´sis), n See hematopoiesis. hemopoiesis see hematopoiesis. because it functions as a cofactor cofactor An atom, organic molecule, or molecular group that is necessary for the catalytic activity (see catalysis) of many enzymes. A cofactor may be tightly bound to the protein portion of an enzyme and thus be an integral part of its functional structure, or it may that facilitates the intestinal absorption of ferric ferric (fĕr`ĭk), iron in the +3 valence state. See ferrous. ion (3). Humans are exposed to nickel via food, water, and air produced from such sources as mining, extraction and refining, electroplating electroplating: see plating. electroplating Process of coating with metal by means of an electric current. Plating metal may be transferred to conductive surfaces (e.g., metals) or to nonconductive surfaces (e.g. , grinding and polishing, nickel powder metallurgy, nickel alloys, nickel cadmium batteries, the chemical industry, food processing, and nickel waste disposal (4). The primary toxic effects of nickel sulfate are expressed in the myeloid myeloid /my·eloid/ (mi´e-loid) 1. medullary; pertaining to, derived from, or resembling bone marrow or the spinal cord. 2. having the appearance of myelocytes, but not derived from bone marrow. system. Nickel causes dose-related decreases in bone marrow cellularity and in granulocyte-macrophage and pluripotent stem cell pluripotent stem cell Hematology The 'mother of all cells'–the progenitor of all hematopoietic cells–eg, platelets, RBCs, neutrophils, macrophages, lymphocytes. See Stem celll. proliferative responses (5). A number of studies on the carcinogenicity carcinogenicity /car·ci·no·ge·nic·i·ty/ (kahr?si-no-je-nis´i-te) the ability or tendency to produce cancer. carcinogenicity the ability or tendency to produce cancer. of nickel compounds in experimental animals have been reported (6,7). Generally, tumors are induced at the site of administration of the nickel compound. Several nickel compounds induce injection-site sarcomas Sarcomas Definition A sarcoma is a bone tumor that contains cancer (malignant) cells. A benign bone tumor is an abnormal growth of noncancerous cells. Description A primary bone tumor originates in or near a bone. (2). Bone, kidney, and liver are the main organs in which nickel accumulates. In addition, the skin, heart, spleen, testes, and intestine also store large amounts of nickel (8). Nickel is excreted mainly through the bile and urine. The nickel concentration in urine of normal human subjects is between 0.1 and 13.3 [micro]g/L, whereas in urine of welders, nickel was found at concentrations > 18.5 [micro]g/L (9,10). At present there is much concern about the nature of toxicity of nickel. Strict controls have been instituted, and top priority is being given to setting the safe limits to which the population may be exposed. The level of dietary protein intake can markedly influence the severity of toxicity manifestations from chronic exposure to nickel (11). Metal ions interact with amino acids and protein in the biologic system in the form of coordinate complexes and chelates, participating in biosynthesis Biosynthesis The synthesis of more complex molecules from simpler ones in cells by a series of reactions mediated by enzymes. The overall economy and survival of the cell is governed by the interplay between the energy gained from the breakdown of compounds and degradation as well as maintaining the conformation of macromolecules Macromolecules A large molecule composed of thousands of atoms. Mentioned in: Gene Therapy macromolecules . Not only do they enhance the catalytic activity of enzymes, but they also increase the stability of the protein moiety moiety: see clan. to metabolic turnover (12). In our earlier investigations, we reported infertility and varying degrees of testicular dysfunction with exposure to nickel according to dietary protein intake (13,14). As protein deficiency is widespread in most industrial and rural workers in India and in other developing countries, the present study was designed to elucidate the effect of nickel sulfate (NiS[O.sub.4] x 6[H.sub.2]O) on testicular steroidogenesis during protein restriction and also to ascertain whether these changes are permanent or reversible. Materials and Methods Animals and treatment. Adult (age 60-70 days) laboratory-bred male Wistar rats, weighing 160 [+ or -] 5 g, were initially maintained on standard laboratory stock diet and water ad libitum. They were acclimatized for 7 days to the laboratory conditions at 22-24[degrees]C and a 12-hr light: dark cycle. Rats were then divided into six equal groups of 10 each, and five animals were kept in each metabolic wire cage (24 in x 12 in x 8 in). Three groups were fed a normal protein diet (18% casein), and the other three groups were fed a protein-restricted isocaloric diet (5% casein; Table 1). The low-protein diet (5% casein) used in the present study was prepared by replacing a portion of the protein source (casein) in the normal stock diet with starch. After 3 weeks of acclimatization acclimatization Any of numerous gradual, long-term responses of an individual organism to changes in its environment. The responses are more or less habitual and reversible should conditions revert to an earlier state. , in the above mentioned dietary regime group 1 (18% casein) and group 4 (5% casein) served as controls and received the appropriate volume of the vehicle injected intraperitoneally. Groups 2 and 5 animals were treated with nickel sulfate (Sigma, Chemicals, St. Louis, MO) intraperitoneally in double-distilled water at a dose of 2 mg/100 g body weight (bw) on alternate days for 10 doses (15). This was an effective dose, and it does not cause any deleterious effect on the kidney because it is far below from the L[D.sub.50] value of nickel sulfate. Groups 3 and 6 animals received the same dose of nickel sulfate as groups 2 and 5, but they were given an additional recovery period of 15 days after dose 10. The dietary status was maintained by pair feeding. The chances of nickel toxicity occurring under these circumstances by the oral route are remote because a large amount of nickel is required to produce a toxic effect by ingestion ingestion /in·ges·tion/ (-chun) the taking of food, drugs, etc., into the body by mouth. in·ges·tion n. 1. The act of taking food and drink into the body by the mouth. 2. . In contrast to nickel salts administrated orally, nickel salts administered intraperitoneally or subcutaneously are highly toxic (3). Hence, nickel sulfate was administered intraperitoneally in this study. We recorded the body weights of all rats on day 1 of the dietary treatment, on day 1 of the nickel sulfate injection, and just before sacrifice. At the end of the nickel sulfate treatment, animals of all groups except those of groups 3 and 6 were fasted overnight and sacrificed by decapitation from 0700 to 1100 hr to avoid any possible diurnal diurnal /di·ur·nal/ (di-er´nal) pertaining to or occurring during the daytime, or period of light. di·ur·nal adj. 1. Having a 24-hour period or cycle; daily. 2. variation. The entire experimental protocol was approved by the Calcutta University ethical committee on animal research, and utmost care was taken during the experimental procedure as well as at the time of sacrifice as per the Helsinki Declaration, 1984 (16). At the end of a 15-day recovery period, animals of groups 3 and 6 were also sacrificed. Blood was collected in heparinized tubes, and plasma was separated by centrifugation Centrifugation A mechanical method of separating immiscible liquids or solids from liquids by the application of centrifugal force. This force can be very great, and separations which proceed slowly by gravity can be speeded up enormously in centrifugal immediately for estimation of testosterone. The testes and seminal vesicles of each group were separately dissected out, trimmed of fat, wiped clean, and weighed immediately. Study of testicular steroidogenic enzymes, cholesterol, and ascorbic acid content. We used the right testes of each animal to estimate the activity of the steroidogenic enzymes 3[beta]-hydroxysteroid dehydrogenase dehydrogenase /de·hy·dro·gen·ase/ (de-hi´dro-jen-as?) an enzyme that catalyzes the transfer of hydrogen or electrons from a donor, oxidizing it, to an acceptor, reducing it. de·hy·dro·gen·ase n. (3[beta]-HSD) and 17[beta]-hydroxysteroid dehydrogenase (17[beta]-HSD) and to estimate cholesterol and ascorbic acid content. For enzymatic study, testicular tissue was homogenized ho·mog·e·nize v. ho·mog·e·nized, ho·mog·e·niz·ing, ho·mog·e·niz·es v.tr. 1. To make homogeneous. 2. a. To reduce to particles and disperse throughout a fluid. b. (20% glycerol glycerol, glycerin, glycerine, or 1,2,3-propanetriol (prō`pāntrī'ŏl), CH2OHCHOHCH2OH, colorless, odorless, sweet-tasting, syrupy liquid. , 5 mM potassium phosphate, 1 mM EDTA EDTA: see chelating agents. ) and then centrifuged at 10,000 rpm at 4[degrees]C for 30 min. The supernatant was decanted. Enzyme activities were measured by optical measurement (absorbance absorbance /ab·sor·bance/ (-sor´bans) 1. in analytical chemistry, a measure of the light that a solution does not transmit compared to a pure solution. Symbol . 2. at 340 nm) of the rate of reduction of pyridine pyridine (pĭr`ĭdēn) or azine (ăz`ēn), C5H5N, colorless, flammable, toxic liquid with a putrid odor. It melts at −42°C; and boils at 115.5°C;. nucleotides (NAD NAD: see coenzyme. or NADP NADP: see coenzyme. ) according to the method of Talalay (17) and Jarabak (18). The assay system contained 1 mL sodium pyrophosphate buffer, 0.5 mL of 5% bovine serum albumin, 0.04 mL steroid (dehydroepiandrosterone for 3[beta]-HSD and testosterone for 17[beta]-HSD), and 1 mL of the supernatant fluid. All chemicals were purchased from Sigma Chemicals, except the steroid (Organon or·ga·non or or·ga·num n. pl. or·ga·nons or or·ga·nums or or·ga·na 1. An organ. 2. A set of principles for use in scientific investigation. organon pl. organa [Gr.] organ. India Ltd., Kolkata, India). Duplicate samples and blanks (without steroid) were run each time. One unit of enzyme activity is the amount that causes a change in absorbance of 0.001 U/min using the steroids as substrate. We measured testicular protein by the method of Lowry et al. (19). The enzyme activity was expressed in units per milligram milligram /mil·li·gram/ (mg) (mil´i-gram) one thousandth (10-3) of a gram. mil·li·gram n. Abbr. mg A metric unit of mass equal to one thousandth (10-3) of a gram. of protein. We estimated the cholesterol (20) and ascorbic acid (21) content spectrophotometrically. Study of plasma testosterone. We carried out radioimmunoassay of plasma testosterone according to the method of Coombs Coombs can refer to:
n. An instrument that produces a chromatogram. tr.v. chro·mat·o·graphed, chro·mat·o·graph·ing, chro·mat·o·graphs To separate and analyze by chromatography. purification of the samples was not performed, the testosterone values are the sum of testosterone and dehydrotestosterone (plasma levels of dehydrotestosterone are only about 1/10 of testosterone levels, and the cross-reactivity is typically less than 5%). The coefficient of variance within the assay was 6.2%. Between-assay variance was not determined because all samples were measured in a single assay. The average sensitivity of the assay was 7.5 pg testosterone/tube at the 95% confidence level. The blank plasma value was 40 pg testosterone/mL of plasma (n = 20), as determined by the assay of a pool of adult male rat plasma after treatment twice with 0.2 mL dextran-coated charcoal (2% charcoal, 0.5% dextran dextran /dex·tran/ (dek´stran) a high-molecular-weight polymer of d-glucose, produced by enzymes on the cell surface of certain lactic acid bacteria. )/mL plasma. We determined the accuracy of the assay by adding 1 mg testosterone/mL (nonradioactive) to 20 plasma samples. Statistical analysis. We calculated the mean [+ or -] SEM values for each group. To determine the significance of the intergroup in·ter·group adj. Being or occurring between two or more social groups: intergroup relations; intergroup violence. differences, each parameter was analyzed separately and one-way analysis of variance (ANOVA anova see analysis of variance. ANOVA Analysis of variance, see there ) was carried out at 5% of Fisher's distribution. To find out which of the groups differed among themselves, we applied Duncan's multiple range test with the level of significance fixed at p < 0.05 (24). Results The nickel sulfate-treated rats showed a significant decrease in the growth rate, as indicated by the body weights (Table 2) of the treated rats in both the normal protein-fed and protein-restricted groups. In case of withdrawal groups (groups 3 and 6), marked improvement in body weights were observed. Table 3 shows that the relative weights of testes significantly decreased in all the experimental groups (groups 2, 3, 5, 6) compared to their respective controls (groups 1 and 4). Withdrawal groups in both dietary regimes showed a significant improvement in testicular weight. An insignificant decrease of seminal vesicle weights was observed after nickel sulfate treatment in all the experimental groups. The percent changes in testicular weight in both normal protein-fed and protein-restricted groups after nickel sulfate treatment are depicted in Figure 1. Table 4 depicts the changes in the testicular cholesterol and ascorbic acid concentration after nickel sulfate treatment in the same experimental condition. Significant increases in ascorbic acid and cholesterol level occurred after nickel sulfate administration in all the experimental groups compared to their respective controls, whereas the withdrawal groups in both dietary regimes showed significant reductions compared to control groups. Nickel sulfate treatment significantly reduced the activities of the two testicular steroidegenic enzymes 3[beta]-HSD and 17[beta]-HSD and plasma testosterone level (Table 4) in both dietary experimental groups. In contrast, 15 days after withdrawing nickel sulfate from rats in both dietary regimes (groups 3 and 6), the two steroidogenic enzymes and plasma testosterone level showed a significant recovery compared to nickel sulfate-treated groups. Percent changes in testicular cholesterol, ascorbic acid, 3[beta]-HSD, 17[beta]-HSD, and plasma testoserone level in both normal protein-fed and protein-restricted groups after nickel treatment are depicted in Figures 2 and 3. We also observed that protein restriction itself produced a deleterious effect on body weight, organ weight, concentration of cholesterol, ascorbic acid, 3[beta]-HSD, and plasma testosterone, but not on 17[beta]-HSD activities (Tables 2-4). Discussion Our results indicate that nickel sulfate has an adverse effect on total body weight and on weights of testes under both normal and protein-restricted conditions, but a partial recovery took place in withdrawal groups under both dietary conditions. Loss of body weight after nickel sulfate administration indicates the interference of protein metabolism, presumably pre·sum·a·ble adj. That can be presumed or taken for granted; reasonable as a supposition: presumable causes of the disaster. by inhibiting enzymatic pathways (1). The reduction in weights of testes and accessory glands is likely caused by lowered production of testicular androgen, possibly as a result of loss of mass of Leydig cells (27,28). Nickel sulfate induced a decrease in testicular weight, with decreased sperm concentration and motility motility /mo·til·i·ty/ (mo-til´ite) the ability to move spontaneously.mo´tile Motility Motility is spontaneous movement. (14). Nickel sulfate degenerated the germinal epithelium of testes and reduced testicular weight (29). Steroidogenesis in the testes is under the physiologic control of two dehydrogenases. A constant supply of cholesterol and ascorbic acid is required for the synthesis of steroid hormones (30). Both dehydrogenases are directly involved in biosynthesis of testosterone from pregnenolone as well as androstenedione androstenedione /an·dro·stene·di·one/ (-di-on) an androgenic steroid produced by the testis, adrenal cortex, and ovary; converted metabolically to testosterone and other androgens. . Any alteration in the activity of these two enzymes affects androgen production. Reduced activities of these steroidogenic enzymes in mature testes of adults rats indicate reduced steroidogenesis (30). The role of cholesterol as a precursor molecule in the synthesis of steroids hormones is well established (31). In this study, the cholesterol content in the testes of experimental groups of rats showed significant increases compared to their respective dietary control groups. This high accumulation of cholesterol may suggest that cholesterol is not used in testosterone biosynthesis and thereby corroborate To support or enhance the believability of a fact or assertion by the presentation of additional information that confirms the truthfulness of the item. The testimony of a witness is corroborated if subsequent evidence, such as a coroner's report or the testimony of other nickel sulfate-induced reduction in steroidogenesis. Ascorbic acid, an easily diffusible diffusible /dif·fus·ible/ (di-fuz´i-b'l) susceptible of becoming widely spread. water-soluble biologic reductant reductant /re·duc·tant/ (re-duk´tant) the electron donor in an oxidation-reduction (redox) reaction. re·duc·tant n. A reducing agent. , is found in abundance in testes (32), where it plays an important role in testicular hormonogenesis (33). Nickel sulfate induced an increase in ascorbic acid concentration in both normal and protein-restricted groups, reflecting that ascorbic acid is not used in the process of testicular steroidogenesis (33). Nickel might have some influence on the distribution and concentration of ascorbic acid, which in turn influences the physiologic fate of the metallic ions by a separate type of mechanism (34). The alteration of testicular steroidogenic activities and concentration of cholesterol and ascorbic acid in the protein-restricted condition is higher than that in normal protein condition, which indicates that the toxic effects of nickel were aggravated by protein restriction. Our investigation further revealed that nickel sulfate induced a decreased plasma testosterone level in both dietary experimental groups. Nickel also affects the hypothalamic-pituitary-testicular axis (29). Metal exposure decreased the neurotransmitter content in anterior and mediobasal hypothalamus hypothalamus (hī'pəthăl`əməs), an important supervisory center in the brain, rich in ganglia, nerve fibers, and synaptic connections. It is composed of several sections called nuclei, each of which controls a specific function. and decreased circulating levels of lutenizing hormone (LH) and testosterone (35). Our investigations show that nickel sulfate affects the hormonal milieu of the testes in both dietary groups. The hormonal milieu originates in the hypothalamus, which releases gonadotropin-releasing hormone in a pulsatile pulsatile /pul·sa·tile/ (pul´sah-til) characterized by a rhythmic pulsation. pul·sa·tile adj. Undergoing pulsation. pulsatile characterized by a rhythmic pulsation. manner. This results in secretion of LH, which in turn stimulates the Leydig cell production of testosterone. The production of testicular testosterone requires cholesterol and ascorbic acid, along with 3[beta]-HSD and 17[beta]-HSD (36). Low level of plasma testosterone may be due to a direct effect of nickel on the testicular hormonogenesis, which is supported by the decrease in steroidogenic enzyme activities with a concomitant increase in cholesterol and ascorbic acid levels (Table 4, Figures 2 and 3). The decrease in plasma testosterone level in protein-restricted experimental groups after nickel sulfate treatment is higher than in the normal dietary protein experimental groups (Table 4). Possibly, the low level of dietary protein intake decreases synthesis of testicular enzymes, lowering the testosterone level, which is further aggravated by exposure of nickel (37). After 15 days of withdrawal from the nickel sulfate treatment, the effects of nickel on testicular cholesterol, ascorbic acid, 3[beta]-HSD, 17[beta]-HSD, and plasma testosterone content were reduced in normal protein-fed as well as protein-restricted dietary groups. This may be explained by the fact that withdrawal from nickel sulfate causes an improvement of testicular steroidogenesis. Simple dietary protein restriction induced reduction of body weight, organ weight, testicular 3[beta]-HSD, and plasma testosterone level with a concomitant increase of testicular cholesterol and ascorbic acid concentration reflecting biochemical defects, structural disorders, and altered physiologic function. The organism depends essentially on dietary protein that directly or indirectly regulates biochemical processes (38). It has been reported that nickel sulfate adversely affects the expression of genetic information by reducing DNA DNA: see nucleic acid. DNA or deoxyribonucleic acid One of two types of nucleic acid (the other is RNA); a complex organic compound found in all living cells and many viruses. It is the chemical substance of genes. , RNA RNA: see nucleic acid. RNA in full ribonucleic acid One of the two main types of nucleic acid (the other being DNA), which functions in cellular protein synthesis in all living cells and replaces DNA as the carrier of genetic , and protein concentration in the testes of albino rats fed normal protein and protein-restricted diets (14). A relationship between the threshold level of nickel toxicity and dietary protein levels may be considered (14). Nickel sulfate appears to adversely affect the biochemical microenvironment microenvironment /mi·cro·en·vi·ron·ment/ (-en-vi´ron-ment) the environment at the microscopic or cellular level. of the testes of albino rats fed a normal protein diet, which is further aggravated in protein-restricted diets. However, all these alterations may be reversible.
Table 1. Composition of normal and
protein-restricted diets.
Protein-
Dietary Normal restricted
components diet (%) diet (%)
Carbohydrate (amylum IP) 70 83
Fat (peanut oil) 7 7
Protein (casein) 18 5
Salt mixture (a) 4 4
Vitamin mixture (b) 1 1
IP, industrial production.
(a) Data from U.S. Pharmacopeia (25). (b) Data from the
American Institute of Nutrition (26).
Table 2. Changes in body weight after nickel
sulfate treatment (2 mg/100 g bw, for 10 days).
Body weight (g)
Day of Day of Percent
Group 1st injection sacrifice p-Value change
1 190 [+ or -] 34 (a) 203 [+ or -] 4.2 (a) < 0.01 +6.84
2 195 [+ or -] 4.8 (a) 162 [+ or -] 3.4 (b) < 0.001 -16.92
3 194 [+ or -] 5.4 (a) 174 [+ or -] 4.8 (c) < 0.001 -10.30
4 160 [+ or -] 3.4 (b) 150 [+ or -] 4.2 (d) < 0.01 -6.25
5 165 [+ or -] 4.2 (b) 128 [+ or -] 4.2 (e) < 0.001 -22.42
6 170 [+ or -] 3.8 (b) 144 [+ or -] 3.8 (f) < 0.001 -15.29
Each value is mean [+ or -] SEM of 10 observations in each
group. In each column, values with different superscripts
were significantly different from each other (p < 0.05).
Group 1: normal protein diet (18% casein); group 2: normal
protein diet + NiS[O.sub.4]; group 3: normal protein diet +
iS[O.sub.4] + withdrawal; group 4: protein-restricted diet
5% casein); group 5: protein-restricted diet + NiS[O.sub.4];
group 6: protein-restricted diet + NiS[O.sub.4] + withdrawal.
Table 3. Changes in wet weight to testicular and
seminal vesicular tissues after nickel sulfate
treatment (2 mg/100 g bw for 10 days).
Testes Seminal vesicle
Group weight (g) weight (mg)
1 1.741 [+ or -] 0.082 (a) 274.61 [+ or -] 24.24 (a)
2 1.502 [+ or -] 0.075 (b) 270.22 [+ or -] 25.32 (a)
3 1.632 [+ or -] 0.081 (c) 273.43 [+ or -] 22.48 (a)
4 1.320 [+ or -] 0.082 (d) 180.32 [+ or -] 24.32 (b)
5 1.024 [+ or -] 0.081 (e) 178.41 [+ or -] 25.4 (b)
6 1.220 [+ or -] 0.074 (f) 174.30 [+ or -] 20.47 (b)
Each value is mean [+ or -] SEM of 10 observations in each
group. In each column, values with different superscripts
are significantly different from each other (p < 0.05). Group
1: normal protein diet (18% casein); group 2: normal protein
diet + NiS[O.sub.4]; group 3: normal protein diet + NiS[O.sub.4] +
withdrawal; group 4: protein-restricted diet (5% casein);
group 5: protein-restricted diet + NiS[O.sub.4]; group 6:
protein-restricted diet + NiS[O.sub.4] + withdrawal.
Table 4. Effect of nickel (2 mg/100 g bw) on testicular cholesterol,
ascorbic acid, 3[beta] and 17[beta]-hydroxysteroid dehydrogenase,
and plasma testosterone concentration in rats.
Cholesterol Ascorbic acid
Group (mg/g tissue) (mg/g tissue protein)
1 86.35 [+ or -] 4.80 (a) 147.42 [+ or -] 8.32 (a)
2 142.48 [+ or -] 8.34 (b) 194.32 [+ or -] 9.48 (b)
3 100.28 [+ or -] 7.32 (c) 175.32 [+ or -] 9.21 (c)
4 105.34 [+ or -] 8.28 (c) 170.46 [+ or -] 6.78 (c)
5 168.32 [+ or -] 9.40 (d) 205.48 [+ or -] 10.41 (d)
6 138.48 [+ or -] 10.30 (b) 188.32 [+ or -] 7.81 (b)
3[beta]-HSD 17[beta]-HSD
Group (U/mg) (U/mg protein)
1 8.97 [+ or -] 0.18 (a) 6.50 [+ or -] 0.29 (a)
2 6.57 [+ or -] 0.23 (b) 5.10 [+ or -] 0.21 (b)
3 7.83 [+ or -] 0.21 (c) 6.04 [+ or -] 0.22 (a)
4 7.51 [+ or -] 0.22 (c) 6.10 [+ or -] 0.21 (a)
5 4.21 [+ or -] 0.18 (d) 4.04 [+ or -] 0.11 (c)
6 6.20 [+ or -] 0.21 (b) 5.34 [+ or -] 0.28 (b)
Testosterone
Group (ng/mL)
1 3.27 [+ or -] 0.06 (a)
2 2.43 [+ or -] 0.10 (b)
3 2.84 [+ or -] 0.07 (c)
4 2.97 [+ or -] 0.11 (c)
5 2.17 [+ or -] 0.28 (d)
6 2.52 [+ or -] 0.12 (b)
Each value is mean [+ or -] SEM of 10 observations in each group.
In each column, values with different superscripts were significantly
different from each other (p < 0.05). Group 1: normal protein diet
(18% casein); group 2: normal protein diet + NiS[O.sub.4]; group 3:
normal protein diet + NiS[O.sub.4] + withdrawal; group 4:
protein-restricted diet (5% casein); group 5: protein-restricted
diet + NiS[O.sub.4]; group 6: protein-restricted diet + NiS[O.sub.4]
+ withdrawal.
Figure 1. Percentage change in testicular cholesterol
weight after nickel treatment. E1, group 1 vs.
group 2; E2, group 1 vs. group 3; E3, group 1 vs.
group 4; E4, group 1 vs. group 5; E5, group 1 vs,
group 6.
Percent
change
E1 -13.72
E2 -6.26
E3 -24.18
E4 -41.18
E5 -29.92
Note: Table made from line graph.
Figure 2. Percent change in testicular cholesterol
and ascorbic acid concentration after nickel treatment.
E1, group 1 vs. group 2; E2, group 1 vs. group
3; E3, group 1 vs. group 4; E4, group 1 vs. group 5;
E5, group 1 vs. group 6.
Percent change
Cholesterol Ascorbic acid
E1 65 31.81
E2 16.13 18.92
E3 21.99 15.63
E4 94.92 39.38
E5 60.37 27.74
Note: Table made from bar graph.
Figure 3. Percent change in testicular 3[beta]-hydroxysteroid
dehydrogenase and 17[beta]-hydroxysteroid
dehydrogenase and plasma testosterone concentration
after nickel treatment. E1, group 1 vs. group
2; E2, group 1 vs. group 3; E3, group 1 vs. group 4;
E4, group 1 vs. group 5; E5, group 1 vs. group 6.
Percent change
3[beta]-HSD 17[beta]-HSD Testosterone
E1 -26.75 -21.53 -25.68
E2 -12.71 -7.07 -13.15
E3 -16.27 -6.15 -9.17
E4 -53.06 -37.85 -33.64
E5 -30.88 -17.85 -22.94
Note: Table made from bar graph.
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Cadmium effects on hypothalamic hypothalamic pertaining to the hypothalamus. hypothalamic hormones see hypothalamus. hypothalamic-pituitary-adrenocortical axis pituitary testicular axis in male rats. Exp Biol Med 226(6):605-611 (2001). (36.) Crinnion WJ, Environmental medicine. I. The human burden of environmental toxins and their common health effects. Altern Med Rev 5(1):52-63 (2000). (37.) Chatterjee S, Ray A, Bagchi P, Deb C. Suppression of testicular steroidogenisis in rats by organochlorine or·gan·o·chlo·rine n. Any of various hydrocarbon pesticides, such as DDT, that contain chlorine. insecticide aldrin aldrin (ôl`drĭn): see insecticides. . Environ Pollut 51:87-94 (1988). (38.) Underwood EJ. Trace Elements in Human and Animal Nutrition. New York: Academic Press, 1977. Kusal K. Das (1) and Shakuntala Dasgupta (2) (1) Department of Physiology, Al-Ameen Medical College, Bijapur, Karnataka, India; (2) Department of Physiology, University of Calcutta Formally established on the 24 January 1857, the University of Calcutta (also known as Calcutta University) (Bengali: কলকাতা বিশ্ববিদ্যালয়), located in , Calcutta, India Address correspondence to K. K. Das, Department of Physiology, Al-Ameen Medical College, Bijapur 586108, Karnataka, India. Telephone: 91-8352-70055 (extension nos. 224, 225). Fax: 91-8352-70184. E-mail: kusaldas@yahoo.com We thank S. A. Dhundasi, Department of Physiology, Al-Ameen Medical College, for his kind cooperation and valuable suggestions. We also acknowledge the help of B. S. Patil, S. R. Choudhury, and V. T. Shakunthala of Al-Ameen Medical College. Received 12 December 2001; accepted 20 February 2002. |
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