Chang Shu-Ching, Thibodeaux Julie R, Eastvold Mary L, Ehresman David J, Bjork James A, Froehlich John W, Lau Christopher, Singh Ravinder J, Wallace Kendall B, Butenhoff John L
Medical Department, 3M Company, St. Paul, MN 55144, United States.
Toxicology. 2008 Jan 20;243(3):330-9. doi: 10.1016/j.tox.2007.10.014. Epub 2007 Oct 26.
Perfluorooctanesulfonate (PFOS) is widely distributed and persistent in humans and wildlife. Prior toxicological studies have reported decreased total and free thyroid hormones in serum without a major compensatory rise in thyrotropin (TSH) or altered thyroid gland histology. Although these animals (rats, mice and monkeys) might have maintained an euthyroid state, the basis for hypothyroxinemia remained unclear. We undertook this study to investigate the causes for the PFOS-induced reduction of serum total thyroxine (TT4) in rats.
We hypothesized that exposure to PFOS may increase free thyroxine (FT4) in the rat serum due to the ability of PFOS to compete with thyroxine for binding proteins. The increase in FT4 would increase the availability of the thyroid hormone to peripheral tissues for utilization, metabolic conversation, and excretion. We also hypothesized that PFOS does not directly interfere with the regulatory functions of the hypothalamic-pituitary-thyroid (HPT) axis in rats.
Three experimental designs were employed to test these hypotheses. (1) Female Sprague-Dawley (SD) rats were given a single oral dose of 15 mg potassium PFOS/kg body weight. At intervals of 2, 6, and 24h thereafter, measurements were made for serum FT4, TT4, triiodothyronine (TT3), reverse triiodothyronine (rT3), thryrotropin (TSH), and PFOS concentrations, as well as liver PFOS concentrations, UDP-glucuronosyltransferase 1A (UGT1A) family mRNA transcripts, and malic enzyme (ME) mRNA transcripts and activity. (2) To provide evidence for increased uptake and metabolism of thyroxine (T4), 125 I-T4 was given to male and female SD rats by intravenous injection, followed in 2h by a single oral dose of 15 mg potassium PFOS/kg body weight. 125 I radioactivity was determined in urine and feces collected over a 24-h period and in serum and liver collected at 24h. (3) To assess the potentials effect of PFOS on the hypothalamic-pituitary-thyroid axis, over an 8-day period, groups of male SD rats were given PFOS (3mg/kg-d), propyl thiouracil (PTU, 10 microg/mL in water), or PTU and PFOS in combination, with controls receiving 0.5% Tween 20 vehicle. On days 1, 3, 7, and 8, TT4, TT3, and TSH were monitored. On day 8, pituitaries were removed and placed in static culture for assessment of thyrotropin releasing hormone (TRH)-mediated release of TSH.
(1) PFOS transiently increased FT4 and decreased TSH within 6h, with values returning to control levels by 24h. TT4 was decreased by 55% over a 24-h period. TT3 and rT3 were decreased at 24h to a lesser extent than TT4. ME mRNA transcripts were increased at 2h and activity was increased at 24h. UGT1A mRNA transcripts were increased at 2 and 6h. (2) 125 I decreased in serum and liver relative to controls and consistent with a reduction in serum TT4. Concomitantly, 125 I activity was increased in urine and feces collected from PFOS-treated rats. (3) During the 8 days of dosing with PFOS, TSH was not elevated in male rats, while TT4 and TT3 were decreased. Pituitary response to TRH-mediated TSH release was not diminished after 8-daily oral doses of PFOS.
These findings suggest that oral dosing in rats with PFOS results in transiently increased tissue availability of the thyroid hormones and turnover of T4 with a resulting reduction in serum TT4. PFOS does not induce a classical hypothyroid state under dosing conditions employed nor does it alter HPT activities.
全氟辛烷磺酸(PFOS)在人类和野生动物中广泛分布且持久存在。先前的毒理学研究报告称,血清中总甲状腺激素和游离甲状腺激素减少,促甲状腺激素(TSH)没有明显的代偿性升高,甲状腺组织学也未改变。尽管这些动物(大鼠、小鼠和猴子)可能维持了甲状腺功能正常的状态,但甲状腺素血症的原因仍不清楚。我们进行这项研究以调查PFOS诱导大鼠血清总甲状腺素(TT4)降低的原因。
我们假设,由于PFOS能够与甲状腺素竞争结合蛋白,暴露于PFOS可能会增加大鼠血清中的游离甲状腺素(FT4)。FT4的增加会增加甲状腺激素向周围组织的可利用性,用于利用、代谢转化和排泄。我们还假设PFOS不会直接干扰大鼠下丘脑-垂体-甲状腺(HPT)轴的调节功能。
采用三种实验设计来检验这些假设。(1)给雌性斯普拉格-道利(SD)大鼠单次口服15mg全氟辛烷磺酸钾/kg体重。此后在2、6和24小时的间隔时间测量血清FT4、TT4、三碘甲状腺原氨酸(TT3)、反三碘甲状腺原氨酸(rT3)、促甲状腺激素(TSH)和PFOS浓度,以及肝脏PFOS浓度、尿苷二磷酸葡萄糖醛酸转移酶1A(UGT1A)家族mRNA转录本、苹果酸酶(ME)mRNA转录本和活性。(2)为了提供甲状腺素(T4)摄取和代谢增加的证据,给雄性和雌性SD大鼠静脉注射125I-T4,2小时后单次口服15mg全氟辛烷磺酸钾/kg体重。在24小时内收集尿液和粪便中的125I放射性,并在24小时时收集血清和肝脏中的125I放射性。(3)为了评估PFOS对下丘脑-垂体-甲状腺轴的潜在影响,在8天的时间里,给雄性SD大鼠组分别给予PFOS(3mg/kg·天)、丙基硫氧嘧啶(PTU,水中10μg/mL)或PTU与PFOS的组合,对照组接受0.5%吐温20载体。在第1、3、7和8天监测TT4、TT3和TSH。在第8天,取出垂体并置于静态培养中,以评估促甲状腺激素释放激素(TRH)介导的TSH释放。
(1)PFOS在6小时内使FT4短暂升高,TSH降低,到24小时时数值恢复到对照水平。在24小时内TT4降低了55%。TT3和rT3在24小时时降低程度小于TT4。ME mRNA转录本在2小时时增加,活性在24小时时增加。UGT1A mRNA转录本在2和6小时时增加。(2)与对照组相比,血清和肝脏中的125I减少,与血清TT4的降低一致。同时,从PFOS处理的大鼠收集的尿液和粪便中的125I活性增加。(3)在给予PFOS的8天中,雄性大鼠的TSH没有升高,而TT4和TT3降低。在每日口服PFOS 8天后,垂体对TRH介导的TSH释放的反应没有减弱。
这些发现表明,给大鼠口服PFOS会导致甲状腺激素的组织可利用性短暂增加和T4周转,从而导致血清TT4降低。在所用的给药条件下,PFOS不会诱导典型的甲状腺功能减退状态,也不会改变HPT活性。
