Kadlubar F F, Dooley K L, Teitel C H, Roberts D W, Benson R W, Butler M A, Bailey J R, Young J F, Skipper P W, Tannenbaum S R
National Center for Toxicological Research, Jefferson, Arkansas 72079.
Cancer Res. 1991 Aug 15;51(16):4371-7.
The human urinary bladder carcinogen, 4-aminobiphenyl (ABP), is known to undergo hepatic metabolism to an N-hydroxy arylamine and its corresponding N-glucuronide. It has been proposed that these metabolites are both transported through the blood via renal filtration to the urinary bladder lumen where acidic pH can facilitate the hydrolysis of the N-glucuronide and enhance the conversion of N-hydroxy-4-aminobiphenyl (N-OH-ABP) to a reactive electrophile that will form covalent adducts with urothelial DNA. Blood ABP-hemoglobin adducts, which have been used to monitor human exposure to ABP, are believed to be formed by reactions within the erythrocyte involving N-OH-ABP that has entered the circulation from the liver or from reabsorption across the urothelium. To test these hypotheses directly, experimental data were obtained from female beagles given [3H]ABP (p.o., i.v., or intraurethrally). [3H]N-OH-ABP (i.v. or intraurethrally), or [3H]N-OH-ABP N-glucuronide (i.v.). Analyses included determinations of total ABP in whole blood and plasma, ABP-hemoglobin adducts in blood erythrocytes, ABP and N-OH-ABP levels (free and N-glucuronide) in urine, urine pH, frequency of urination (controlled by urethral catheter), rates of reabsorption of ABP and N-OH-ABP across the urothelium, and apparent volumes of distribution in the blood/tissue compartment. The major ABP-DNA adduct, N-(guan-8-yl)-4-aminobiphenyl, was also measured in urothelial and liver DNA using a sensitive immunochemical method. An analog/digital hybrid computer was then utilized to construct a multicompartmental pharmacokinetic model for ABP and its metabolites that separates: (a) absorption; (b) hepatic metabolism and distribution in blood and tissues; (c) ABP-hemoglobin adduct formation; (d) hydrolysis and reabsorption in the urinary bladder lumen; and (e) excretion. Using this model, cumulative exposure of the urothelium to free N-OH-ABP was simulated from the experimental data and used to predict ABP-DNA adduct formation in the urothelium. The results indicated that exposure to N-OH-ABP and subsequent ABP-DNA adduct formation are directly dependent on voiding frequency and to a lesser extent on urine pH. This was primarily due to the finding that, after p.o. dosing of ABP to dogs, the major portion of the total N-OH-ABP entering the bladder lumen was free N-OH-ABP (0.7% of the dose), with much lower amounts as the acid-labile N-glucuronide (0.3% of the dose).(ABSTRACT TRUNCATED AT 400 WORDS)
已知人类膀胱致癌物4-氨基联苯(ABP)在肝脏中代谢为N-羟基芳胺及其相应的N-葡萄糖醛酸苷。有人提出,这些代谢产物都通过血液经肾滤过转运至膀胱腔,在膀胱腔中酸性pH可促进N-葡萄糖醛酸苷的水解,并增强N-羟基-4-氨基联苯(N-OH-ABP)向活性亲电试剂的转化,该亲电试剂会与尿路上皮DNA形成共价加合物。血液中的ABP-血红蛋白加合物已被用于监测人类对ABP的暴露,据信它是由红细胞内涉及从肝脏进入循环或从尿路上皮重吸收而来的N-OH-ABP的反应形成的。为了直接验证这些假设,从经口、静脉或尿道内给予[3H]ABP的雌性比格犬获取了实验数据。给予[3H]N-OH-ABP(静脉或尿道内)或[3H]N-OH-ABP N-葡萄糖醛酸苷(静脉)。分析包括全血和血浆中总ABP的测定、血液红细胞中ABP-血红蛋白加合物的测定、尿液中ABP和N-OH-ABP水平(游离和N-葡萄糖醛酸苷形式)的测定、尿液pH值、排尿频率(通过尿道导管控制)、ABP和N-OH-ABP跨尿路上皮的重吸收率以及血液/组织隔室中的表观分布容积。还使用灵敏的免疫化学方法测定了尿路上皮和肝脏DNA中的主要ABP-DNA加合物N-(鸟嘌呤-8-基)-4-氨基联苯。然后利用模拟/数字混合计算机构建了一个多隔室药代动力学模型,用于ABP及其代谢产物,该模型区分:(a)吸收;(b)肝脏代谢以及在血液和组织中的分布;(c)ABP-血红蛋白加合物的形成;(d)膀胱腔内的水解和重吸收;(e)排泄。利用该模型,根据实验数据模拟了尿路上皮对游离N-OH-ABP的累积暴露,并用于预测尿路上皮中ABP-DNA加合物的形成。结果表明,暴露于N-OH-ABP以及随后ABP-DNA加合物的形成直接取决于排尿频率,在较小程度上取决于尿液pH值。这主要是由于以下发现:给狗经口给予ABP后,进入膀胱腔的总N-OH-ABP的主要部分是游离N-OH-ABP(占剂量的0.7%),而酸不稳定的N-葡萄糖醛酸苷形式的量要低得多(占剂量的0.3%)。(摘要截取自400字)
