Joshua A Walker1,2, Sean Richards1, Stephen A Whelan3, Sung Bok Yoo1, Teresa L Russell1, Nkiruka Arinze4, Saran Lotfollahzadeh1, Marc A Napoleon1, Mostafa Belghasem5, Norman Lee3, Laura M Dember6,7, Katya Ravid2,8, Vipul C Chitalia9,10,11. 1. Renal Section, Department of Medicine, Boston University School of Medicine, Boston, Massachusetts. 2. Whitaker Cardiovascular Institute, Boston University, Boston, Massachusetts. 3. Chemical Instrumentation Center, Boston University, Boston, Massachusetts. 4. Department of Surgery, Boston University School of Medicine, Boston, Massachusetts. 5. Department of Pathology and Laboratory Medicine, Boston University School of Medicine, Boston, Massachusetts. 6. Renal-Electrolyte and Hypertension Division, Center for Clinical Epidemiology and Biostatistics, Philadelphia, Pennsylvania. 7. Department of Biostatistics, Epidemiology and Informatics, Perelman School of Medicine at the University of Pennsylvania, Philadelphia, Pennsylvania. 8. Department of Medicine, Boston University School of Medicine, Boston, Massachusetts. 9. Renal Section, Department of Medicine, Boston University School of Medicine, Boston, Massachusetts vichital@bu.edu. 10. Institute of Medical Engineering and Science, Massachusetts Institute of Technology, Cambridge, Massachusetts. 11. Veteran Affairs Boston Healthcare System, Boston, Massachusetts.
Abstract
BACKGROUND: CKD, characterized by retained uremic solutes, is a strong and independent risk factor for thrombosis after vascular procedures . Urem ic solutes such as indoxyl sulfate (IS) and kynurenine (Kyn) mediate prothrombotic effect through tissue factor (TF). IS and Kyn biogenesis depends on multiple enzymes, with therapeutic implications unexplored. We examined the role of indoleamine 2,3-dioxygenase-1 (IDO-1), a rate-limiting enzyme of kynurenine biogenesis, in CKD-associated thrombosis after vascular injury. METHODS: IDO-1 expression in mice and human vessels was examined. IDO-1-/- mice, IDO-1 inhibitors, an adenine-induced CKD, and carotid artery injury models were used. RESULTS: Both global IDO-1-/- CKD mice and IDO-1 inhibitor in wild-type CKD mice showed reduced blood Kyn levels, TF expression in their arteries, and thrombogenicity compared with respective controls. Several advanced IDO-1 inhibitors downregulated TF expression in primary human aortic vascular smooth muscle cells specifically in response to uremic serum. Further mechanistic probing of arteries from an IS-specific mouse model, and CKD mice, showed upregulation of IDO-1 protein, which was due to inhibition of its polyubiquitination and degradation by IS in vascular smooth muscle cells. In two cohorts of patients with advanced CKD, blood IDO-1 activity was significantly higher in sera of study participants who subsequently developed thrombosis after endovascular interventions or vascular surgery. CONCLUSION: Leveraging genetic and pharmacologic manipulation in experimental models and data from human studies implicate IS as an inducer of IDO-1 and a perpetuator of the thrombotic milieu and supports IDO-1 as an antithrombotic target in CKD.
BACKGROUND: CKD, characterized by retained uremic solutes, is a strong and independent risk factor for thrombosis after vascular procedures . Urem ic solutes such as indoxyl sulfate (IS) and kynurenine (Kyn) mediate prothrombotic effect through tissue factor (TF). IS and Kyn biogenesis depends on multiple enzymes, with therapeutic implications unexplored. We examined the role of indoleamine 2,3-dioxygenase-1 (IDO-1), a rate-limiting enzyme of kynurenine biogenesis, in CKD-associated thrombosis after vascular injury. METHODS: IDO-1 expression in mice and human vessels was examined. IDO-1-/- mice, IDO-1 inhibitors, an adenine-induced CKD, and carotid artery injury models were used. RESULTS: Both global IDO-1-/- CKD mice and IDO-1 inhibitor in wild-type CKD mice showed reduced blood Kyn levels, TF expression in their arteries, and thrombogenicity compared with respective controls. Several advanced IDO-1 inhibitors downregulated TF expression in primary human aortic vascular smooth muscle cells specifically in response to uremic serum. Further mechanistic probing of arteries from an IS-specific mouse model, and CKD mice, showed upregulation of IDO-1 protein, which was due to inhibition of its polyubiquitination and degradation by IS in vascular smooth muscle cells. In two cohorts of patients with advanced CKD, blood IDO-1 activity was significantly higher in sera of study participants who subsequently developed thrombosis after endovascular interventions or vascular surgery. CONCLUSION: Leveraging genetic and pharmacologic manipulation in experimental models and data from human studies implicate IS as an inducer of IDO-1 and a perpetuator of the thrombotic milieu and supports IDO-1 as an antithrombotic target in CKD.
Authors: L A Szczech; P J Best; E Crowley; M M Brooks; P B Berger; V Bittner; B J Gersh; R Jones; R M Califf; H H Ting; P J Whitlow; K M Detre; D Holmes Journal: Circulation Date: 2002-05-14 Impact factor: 29.690
Authors: Madison C Cuffy; Amanda M Silverio; Lingfeng Qin; Yinong Wang; Raymond Eid; Gerald Brandacher; Fadi G Lakkis; Dietmar Fuchs; Jordan S Pober; George Tellides Journal: J Immunol Date: 2007-10-15 Impact factor: 5.422