Chong A S, Huang W, Liu W, Luo J, Shen J, Xu W, Ma L, Blinder L, Xiao F, Xu X, Clardy C, Foster P, Williams J A
Department of General Surgery, Rush-Presbyterian-St. Luke's Medical Center, Chicago, Illinois 60612, USA.
Transplantation. 1999 Jul 15;68(1):100-9. doi: 10.1097/00007890-199907150-00020.
Leflunomide is an experimental drug with demonstrated ability to prevent and reverse acute allograft and xenograft rejection. The two biochemical activities reported for the active metabolite of leflunomide, A77 1726, are inhibition of tyrosine phosphorylation and inhibition of dihydroorotate dehydrogenase, an enzyme necessary for de novo pyrimidine synthesis. These activities can be distinctly separated in vitro by the use of uridine, which reverses the anti-proliferative effects of A77 1726 caused by inhibition of de novo pyrimidine synthesis. We report the effect of uridine on the in vivo immunosuppressive activities of leflunomide.
We first quantified the serum levels of A77 1726, the active metabolite of leflunomide, after a single treatment of leflunomide (5, 15, and 35 mg/kg). Additionally, we quantified the levels of serum uridine and of nucleotide triphosphates in the liver, spleen, and lymph nodes of Lewis rats after the administration of a single dose of uridine (500 mg/kg; i.p.). Lewis rats heterotopically transplanted with brown Norway or Golden Syrian hamster hearts were treated for 50 or 75 days with leflunomide (5, 15, and 35 mg/kg/day; gavage) alone or in combination with uridine (500 mg/ kg/day; i.p.). Hematocrits were determined and the levels of alloreactive or xenoreactive immunoglobulin (Ig)M and IgG were determined by flow cytometric analysis. The allograft and xenografts, small bowel, liver, kidney, and spleen were subjected to pathological examination.
A linear relationship was observed between the serum A77 1726 concentrations in Lewis rats and the dose of leflunomide administered. Peak A77 1726 concentrations were 20.9, 71.8 and 129.3 mg/l (77.5, 266.1 and 478.8 microM) for the 5, 15, and 35 mg/kg doses of leflunomide, respectively. The concentration of uridine in the serum of normal Lewis rats is 6.5 microM; after i.p. administration of 500 mg/kg uridine, the serum uridine concentrations peaked at 384.1 microM in 15-30 min. The rapid elimination of uridine was not reflected in the lymphoid compartments, and the pharmacokinetics of pyrimidine nucleotides in the spleen resembled that of A77 1726. This dose of uridine, when administered daily (500 mg/kg/day, i.p.), weakly antagonized the immunosuppressive activities of leflunomide (5, 15, and 35 mg/kg/day) in the allotransplantation model. In contrast, in the xenotransplantation model, the same concentration of uridine completely antagonized the immunosuppressive activities of low-dose leflunomide (15 mg/kg/day) and partially antagonized the immunosuppressive activities of high-dose leflunomide (35 mg/kg/day). Toxicities associated with high-dose leflunomide (35 mg/kg/day) were anemia, diarrhea, and pathological changes in the small bowel and liver. These toxicities were significantly reduced by uridine co-administration.
These studies reveal that the blood levels of A77 1726 in Lewis rats satisfy in vitro requirements for both inhibition of de novo pyrimidine synthesis and protein tyrosine kinase activity. Our data also illustrate that the in vivo mechanism of immunosuppression by leflunomide is complex and is affected by at least the following four factors: type and vigor of the immune response, availability of uridine for salvage by proliferating lymphocytes, species being investigated, and concentration of serum A77 1726.
来氟米特是一种实验性药物,已证明其具有预防和逆转急性同种异体移植和异种移植排斥反应的能力。来氟米特的活性代谢产物A77 1726具有两种生化活性,即抑制酪氨酸磷酸化和抑制二氢乳清酸脱氢酶,后者是从头合成嘧啶所必需的一种酶。通过使用尿苷,这些活性在体外可以明显区分,尿苷可逆转由抑制从头嘧啶合成引起的A77 1726的抗增殖作用。我们报告了尿苷对来氟米特体内免疫抑制活性的影响。
我们首先在单次给予来氟米特(5、15和35mg/kg)后,对来氟米特的活性代谢产物A77 1726的血清水平进行了定量。此外,我们在给予单剂量尿苷(500mg/kg;腹腔注射)后,对Lewis大鼠肝脏、脾脏和淋巴结中的血清尿苷和三磷酸核苷酸水平进行了定量。将棕色挪威或金色叙利亚仓鼠心脏异位移植的Lewis大鼠,单独或与尿苷(500mg/kg/天;腹腔注射)联合使用来氟米特(5、15和35mg/kg/天;灌胃)治疗50或75天。测定血细胞比容,并通过流式细胞术分析测定同种反应性或异种反应性免疫球蛋白(Ig)M和IgG的水平。对同种异体移植和异种移植的小肠、肝脏、肾脏和脾脏进行病理检查。
在Lewis大鼠中观察到血清A77 1726浓度与给予的来氟米特剂量之间呈线性关系。来氟米特剂量为5、15和35mg/kg时,A77 1726的峰值浓度分别为20.9、71.8和129.3mg/l(77.5、266.1和478.8μM)。正常Lewis大鼠血清中尿苷浓度为6.5μM;腹腔注射500mg/kg尿苷后,血清尿苷浓度在15 - 30分钟内达到峰值384.1μM。尿苷的快速消除在淋巴组织中未得到体现,脾脏中嘧啶核苷酸的药代动力学与A77 1726相似。在同种异体移植模型中,当每天给予该剂量的尿苷(500mg/kg/天,腹腔注射)时,对来氟米特(5、15和35mg/kg/天)的免疫抑制活性有微弱的拮抗作用。相比之下,在异种移植模型中,相同浓度的尿苷完全拮抗低剂量来氟米特(15mg/kg/天)的免疫抑制活性,并部分拮抗高剂量来氟米特(35mg/kg/天)的免疫抑制活性。与高剂量来氟米特(35mg/kg/天)相关的毒性包括贫血、腹泻以及小肠和肝脏的病理变化。尿苷联合给药可显著降低这些毒性。
这些研究表明,Lewis大鼠中A77 1726的血药水平满足体外抑制从头嘧啶合成和蛋白酪氨酸激酶活性的要求。我们的数据还表明,来氟米特的体内免疫抑制机制是复杂的,至少受以下四个因素影响:免疫反应的类型和强度、增殖淋巴细胞用于补救合成的尿苷可用性、所研究的物种以及血清A77 1726的浓度。
