Ultrastructural changes in the kidneys of rabbits treated with lead acetate

Curcumin Ameliorates Lead (Pb(2+))-Induced Hemato-Biochemical Alterations and Renal Oxidative Damage in a Rat Model

This study aims to evaluate the protective role of curcumin (Curc) against hematological and biochemical changes, as well as renal pathologies induced by lead acetate [Pb (CH3COO)2·3H2O] treatment. Male albino rats were intraperitoneally treated with Pb(2+) (25 mg of lead acetate/kg b.w., once a day) alone or in combination with Curc (30 mg of Curc/kg b.w., twice a day) for 7 days. Exposure of rats to Pb(2+) caused significant decreases in hemoglobin (Hb) content, hematocrit (Ht) value, and platelet (Plt) count, while Pb(2+)-related leukocytosis was accompanied by absolute neutrophilia, monocytosis, lymphopenia, and eosinopenia. A significant rise in lipid peroxidation (LPO) and a marked drop of total antioxidant capacity (TAC) were evident in the kidney, liver, and serum of Pb(2+) group compared to that of control. Furthermore, significantly high levels of total cholesterol (TC), triglycerides (TGs), and low-density lipoprotein cholesterol (LDL-C), and a sharp drop in serum high-density lipoprotein (HDL-C) level were also seen in blood after injection of Pb(2+). Additionally, hepatorenal function tests were enhanced. Meanwhile, Pb(2+) produced marked histo-cytological alterations in the renal cortex. Co-administration of Curc to the Pb(2+)-treated animals restored most of the parameters mentioned above to near-normal levels/features. In conclusion, Curc appeared to be a promising agent for protection against Pb(2+)-induced toxicity.

Alterations in rabbit kidney protein expression following lead exposure as analyzed by two-dimensional gel electrophoresis

It was recently reported that low blood lead levels impaired kidney function in men. To develop a set of molecular markers of renal lead exposure and effect, we investigated changes in renal protein expression while approximating occupational lead exposure at subchronic, low blood levels. Lead was administered to male Dutch Belted rabbits as a lead acetate solution adjusted weekly to achieve and maintain the target blood lead levels of 0, 20, 40, and 80 microg/dL for 15 weeks. Lead exposure did not affect kidney or body weights. The effect of increasing blood lead on protein expression was evaluated in rabbit kidney by large-scale two-dimensional electrophoresis (2-DE). Significant quantitative changes (p < 0.05) occurred in a dose-related manner in 12 proteins at 20 microg/dL exposure, 25 at 40 microg/dL, and 102 at 80 microg/dL. At a higher level of significance (p < 0.001), 40 microg/dL blood lead resulted in one protein alteration and 80 microg/dL affected 14 proteins. A set of quantitatively altered charge variants was tentatively identified as glutathione-S-transferase (GST), based on similar observations in rodents subjected to short-term, very high lead exposure. The significance of the protein alterations observed as markers of toxicity awaits their conclusive identification. Investigation of the kidney 2-DE profile in lead-exposed rabbit may be useful in understanding the mechanism of lead nephrotoxicity in humans.

Treatments with lead expedite hyperthermia-induced thromboembolism in mouse pial microvessels

Three trials were carried out to study the influence of acute and chronic treatments with lead on hyperthermia-induced thromboembolic activity in pial microvessels of adult male mice. Each trial consisted of four groups, 10 mice (approximately 33 g) per group. Three groups were injected with lead acetate dissolved in a 5% glucose solution (vehicle) at doses of 0.1, 0.5 and 1.0 mg/kg and the control group received only the vehicle. Acute treatments were by a single injection made 1 h (i.p.) in one trial and 24 h (i.p.) in another, prior to the a hyperthermic exposure at 45 degrees C. In the third trial, a single injection was given daily (s.c.) for 7 days. Mice were anesthetized by urethane (1-2 mg/kg, i.p.), the trachea was intubated, a craniotomy was performed and the mouse was placed on the microscope stage of an intravital microscopy set-up. Core body and brain surface temperatures were raised first to 37 degrees C, the animal was stabilized for 30 min then only the brain surface temperature was raised to 45 degrees C by heating the irrigating artificial cerebrospinal fluid. The hyperthermic exposure lasted for 45 min. In all trials, lead at the three doses given (low, medium and high) significantly reduced (p < 0.001) the time of initial thromboembolic activity seen. Lead exerted its influence as quickly as in 1 h, even with the low dose administered. Neither the acute nor chronic treatments affected the degree of arteriolar constriction observed or caused venular diameter change. Arteriolar patency rate at the end of experiment was higher for control than for all lead-treated groups. Data evidenced the rapidity of the adverse influence of lead on the susceptibility to thrombosis, in vivo. The enhanced initiation of thrombotic activity may be attributed to facilitated damage to the microvascular endothelium caused by lead, when challenged by hyperthermia.

Lead nephrotoxicity and associated disorders: biochemical mechanisms

Lead may exert toxic effects on several organ systems, but those in the kidney are the most insidious. Acute lead nephropathy is characterized by proximal tubular dysfunction with the development of a Fanconi-type syndrome, alterations in mitochondrial structure and the development of cytosolic and nuclear inclusion bodies. Intracellular lead is associated with specific high affinity proteins and can also bind to metallothionein. Chronic lead nephropathy is irreversible and is typically accompanied by interstitial fibrosis, both hyperplasia and atrophy of the tubules, glomerulonephritis and, ultimately, renal failure. In addition, lead produces renal neoplasms in experimental animals. Chronic lead exposure is also implicated in the development of saturnine gout and hypertension. The metal interacts with renal membranes and enzymes and disrupts energy production, calcium metabolism, glucose homeostasis, ion transport processes and the renin-angiotensin system. This review summarizes the biochemical effects of lead on the kidney to understand the mechanisms of lead-induced nephropathy and other associated disorders.

The small intestinal enterocytes of rats during lead poisoning: the application of the Timm sulphide silver method and an ultrastructural study

Young male rats were divided into 3 groups which received approximately 100 mg of a lead acetate/kg b.w. per day in their drinking water during 2, 30 and 60 d, respectively. Samples from the jejunum were processed for transmission electron microscopy (TEM), and after 60 d of exposure blocks of tissue were also processed to evaluating the Timm sulphide silver reaction sites in the epithelial absorptive cells in TEM according to Dancher and Zimmer (5). The ultrastructure of enterocytes in poisoned rats at 2 days was similar to the controls. A marked feature of about one third of the rat enterocytes exposed to lead for 30 d was the presence of numerous, small rough-membraned vesicles and prominent, dilated Golgi complexes in their cytoplasm. Most of the enterocytes at the 60th d of lead-exposed rats had a vacuolated cytoplasm associated with the prominent Golgi complexes and vacuoles of various size. They also had pleomorphic rough-membraned vesicles and dilated cisternae of the RER. The presence of the Timm reaction deposits has been observed on the microvillar surface of the brush border in connection with the enterocyte plasma membrane, and in the extracellular space between epithelial cells. Furthermore, Timm precipitates were found in extravascular spaces surrounding capillaries, between endothelial cells, and in the capillary lumen.

Lead induced ultrastructural changes in the testis of rats

Oral lead administration (250 ppm lead acetate through drinking water) to weaning male rats for 70 days resulted in the marked accumulation of this metal in blood and testicular tissue. No marked changes were evident in light microscopy. Ultrastructural changes were revealed in the form of vacuolisation of Sertoli cell cytoplasm and increase in the number and size of lysosomes. Some of the vacuoles contained vesicle like structures. Although there was no impairment of spermatogenesis, the changes in the Sertoli cells may lead to changes in spermatogenesis after chronic exposure.

Toxicity of lead acetate to female rabbits after chronic subcutaneous administration. 1. Biochemical and clinical effects

The effect of chronic subcutaneous administration of lead acetate was studied in female rabbits. The low-dose group (15 animals) received three times a week 0.10-0.20 microgram/kg body weight and the high-dose group (15 animals) 0.80-1.20 micrograms/kg. The control group received the vehicle only. Concentrations of lead in blood in the low-dose group increased to ca. 400 micrograms/l after 70 days and in the high-dose group to ca. 900 micrograms/l after 110 days. After 7.5 months eight animals of each group were sacrificed. The remaining rabbits were kept for an additional 4 months without treatment. Blood lead concentrations decreased with a half-time of 60-70 days. During exposure the gain in body weight was lower in the high-dose group than in the control group and the low-dose group. The high-dose group developed slight anaemia and low MCV, MCH and MCHC, and basophilic stippling of erythrocytes. These effects disappeared during recovery. ALAD activity in erythrocytes was very low during exposure in both exposed groups and did not reach control values during recovery. During exposure the concentrations of ZPP and ALA-U increased, but only ALA-U returned to normal during recovery. No other effects of lead on the composition of the urine were observed.(ABSTRACT TRUNCATED AT 250 WORDS)

Absence of an effect of lead acetate on sperm morphology, sister chromatid exchanges or on micronuclei formation in rabbits

The influence of lead on sperm morphology, sister chromatid exchanges or on micronuclei formation was studied on male rabbits after exposure to doses of 0, 0.25, and 0.50 mg lead acetate/kg body weight subcutaneously injected three times a week during 14 weeks, each on a group of five rabbits. At the end of exposure phase the lead in blood concentrations of the three groups of rabbits were 0.32, 2.57, and 2.97 mumol/l respectively. The results did not show any evidence of treatment related effects on sperm count or on morphologic abnormalities of the sperms, neither on the histopathology of the testis. Statistical analysis of the number of sister chromatid exchanges per metaphase in lymphocytes indicated no differences between the groups. Also no dose dependent effect was observed on the relative number of micronuclei in bone marrow erythrocytes. The different susceptibility to lead in different organ systems of the rabbits was discussed.