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請用此 Handle URI 來引用此文件: http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/102164
完整後設資料紀錄
DC 欄位值語言
dc.contributor.advisor劉興華zh_TW
dc.contributor.advisorShing-Hwa Liuen
dc.contributor.author蔡瓈葶zh_TW
dc.contributor.authorLi-Ting Tsaien
dc.date.accessioned2026-03-13T16:56:16Z-
dc.date.available2026-03-14-
dc.date.copyright2026-03-13-
dc.date.issued2026-
dc.date.submitted2026-01-28-
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dc.identifier.urihttp://tdr.lib.ntu.edu.tw/jspui/handle/123456789/102164-
dc.description.abstract全球有超過十分之一的人口罹患慢性腎臟病,慢性腎臟病不僅是心血管疾病死亡的重要原因,也是導致末期腎衰竭的關鍵因素。儘管其盛行率持續上升,目前仍缺乏有效的治療策略以阻止疾病持續惡化。尿毒素的累積為慢性腎臟病的核心病理特徵,然而其對腎臟鐵代謝及細胞死亡機制的影響,至今仍未被充分闡明。本研究利用腎小管上皮細胞株NRK-52E 與 HK-2及腺嘌呤誘發之慢性腎臟病小鼠模型並配合人類基因資料庫分析及腎臟檢體染色,系統性的探討尿毒素如何破壞腎臟鐵離子平衡並促進腎臟損傷。在體外實驗中,硫酸吲哚酚誘發典型的鐵死亡特徵,包括鐵離子累積、活性氧大量生成及脂質過氧化反應,同時鐵離子的累積會伴隨著內質網壓力、細胞老化及促纖維化以共同加劇慢性腎臟病的腎損傷。值得注意的是,這些不利影響可分別透過在體外實驗使用鐵螯合劑 deferoxamine,或於體內以 AST-120 吸附尿毒素前驅物以降低腎臟病小鼠中尿毒素的含量而顯著改善,證實鐵離子是慢性腎臟病致病原因中的關鍵。我們接著進行進一步的機制探討,尿毒素所造成的鐵離子代謝干擾及由於抑制鐵自噬作用所導致的鐵利用障礙,會破壞慢性腎臟病腎臟中的血紅素合成,導致血紅素含量下降,並促使鋅原卟啉異常的累積在腎臟組織中。此外,本研究證實在腎小管上皮細胞中鋅原卟啉的累積會活化第一型血紅素加氧酶、擾亂細胞內鐵恆定,最終造成游離鐵大量沉積。與此結果一致,慢性腎臟病腎臟亦呈現血紅素加氧酶表現上升、鐵死亡活化,以及鐵代謝失衡。而上述病理變化可藉由 TPEN 進行鋅螯合而有效逆轉,不僅抑制鋅原卟啉形成、恢復鐵代謝平衡,亦可降低鐵死亡反應,並減輕腎臟纖維化與腎毒性。此外,我們的研究還發現過量的游離鐵除了會透過誘發內質網壓力、細胞老化及纖維化來加劇腎臟損傷,它甚至還會透過泛細胞凋亡,一種新被發現的整合型程序發炎性細胞死亡途徑,包含焦亡、凋亡與壞死性凋亡,共同促進腎臟損傷。綜合上述,本研究發現一條先前未被釐清的慢性腎臟病致病機制,顯示尿毒素可藉由造成鐵離子代謝及利用失調而干擾腎臟中血紅素的合成,導致鋅原卟啉累積、血紅素加氧酶活化,誘發鐵死亡與發炎性細胞死亡,最終加速慢性腎臟病的進展,並且在人類基因資料庫分析以及腎臟組織染色結果也顯示出鐵死亡與泛細胞凋亡為不同因素的慢性腎臟病患者的重要臨床特徵。 本研究結果指出,腎臟鐵恆定為慢性腎臟病治療中一個關鍵且具潛力的策略。包括鐵螯合、AST-120 尿毒素吸附劑,以及以清除鋅原卟啉為目標或鋅螯合之治療策略,皆有潛力作為未來醫學上延緩慢性腎臟病惡化與疾病進程的重要治療方向。zh_TW
dc.description.abstractOver 10% of the global population is affected by chronic kidney disease, a major contributor to cardiovascular mortality and end-stage renal failure. Despite its growing burden, effective therapeutic strategies to halt chronic kidney disease progression remain limited. Accumulation of uremic toxins is a central pathological feature of chronic kidney disease; however, their impact on renal iron metabolism and regulated cell death has not been fully elucidated. In this study, we employed renal tubular epithelial cells (NRK-52E and HK-2) and an adenine-induced chronic kidney disease mouse model, combined with human genome database analysis and kidney specimen staining, to investigate how uremic toxins disrupt renal iron homeostasis and promote kidney injury. In vitro, indoxyl sulfate triggered canonical ferroptotic features, including increased iron influx, excessive reactive oxygen species generation, and lipid peroxidation. These changes were accompanied by endoplasmic reticulum stress, cellular senescence, and profibrotic phenotypic transitions. Importantly, these deleterious effects were markedly alleviated by iron chelation with deferoxamine in vitro and by AST-120-mediated adsorption of indoxyl sulfate precursors in vivo. Further mechanistic analyses revealed that uremic toxin-induced disturbances in iron utilization progressively impair renal heme biosynthesis and lead to both reduced heme production and the accumulation of zinc protoporphyrin in chronic kidney disease kidneys. Furthermore, we demonstrate that abnormal zinc protoporphyrin accumulation in tubular epithelial cells triggers heme oxygenase-1, which upsets intracellular iron homeostasis and ultimately leads to excessive labile iron deposition. Consistent elevation of HO-1 expression, strong ferroptotic activation, and extensive iron dysregulation are features of chronic kidney disease that are consistent with our mechanistic discoveries. These abnormalities were effectively reversed by zinc chelation using TPEN, which limited zinc protoporphyrin formation, normalized iron handling, suppressed ferroptosis, and attenuated renal fibrosis and nephrotoxicity. Our research also found that in addition to exacerbating kidney damage by inducing endoplasmic reticulum stress, cellular senescence, and fibrosis, excessive labile iron can even promote kidney damage through PANoptosis, a newly discovered integrated programmed inflammatory cell death pathway that includes pyroptosis, apoptosis, and necroptosis. In conclusion, this study uncovers a previously unrecognized pathogenic mechanism in chronic kidney disease, demonstrating that uremic toxins disrupt renal heme synthesis by dysregulating iron metabolism and utilization. This interference results in zinc protoporphyrin accumulation, heme oxygenase-1 hyperactivation, induction of ferroptosis and inflammatory cell death, and consequent acceleration of disease progression. Furthermore, analyses of human genomic databases combined with immunohistochemical staining of kidney tissues revealed that ferroptosis and PANoptosis represent critical clinical features in chronic kidney disease patients, highlighting their unique contributions to renal injury. These results identify renal iron homeostasis as a critical therapeutic target in chronic kidney disease. Interventions such as iron chelation, uremic toxin adsorption with AST-120, and zinc protoporphyrin -targeted or zinc-chelating strategies may represent promising approaches to mitigate chronic kidney disease progression and delay clinical disease advancement.en
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dc.description.tableofcontents口試委員會審定書 i
誌謝 ii
中文摘要 iv
Abstract vi
List of Abbreviation viii
Contents xi
Chapter 1 Introduction 1
1.1 Chronic kidney disease 1
1.2 Uremic toxins 2
1.2.1 Indoxyl sulfate (IS) 3
1.2.2 p-Cresyl sulfate (PCS) 3
1.3 The adenine-induced CKD model 4
1.4 AST-120 5
1.5 Ferroptosis 7
1.5.1 Iron metabolism and accumulation 8
1.5.2 Lipid peroxidation 10
1.5.3 Antioxidant system depletion 12
1.6 Epithelial-mesenchymal transition (EMT) 14
1.7 Senescence 15
1.8 ER stress 16
1.9 Chronic kidney disease-related anemia 17
1.10 Zinc protoporphyrin 18
1.11 PANoptosis 19
1.11.1 Apoptosis 20
1.11.2 Pyroptosis 22
1.11.3 Necroptosis 24
1.12 Relationship between PANoptosis and ferroptosis 25
1.13 Aim of this study 26
Chapter 2 Materials and methods 28
2.1 Chemicals and Reagents 28
2.2 Cell culture and Treatments 28
2.3 Animal Model and Treatment Strategies 29
2.3.1 Adenine-Induced CKD with AST-120 Intervention 29
2.3.2 Adenine-Induced CKD with TPEN-Mediated Zinc Chelation 30
2.4 Biochemical Measurements 31
2.5 Histological Analysis 31
2.6 Immunohistochemistry (IHC) Staining 32
2.7 Iron Stain 33
2.8 Measurement of ZnPP Levels 33
2.9 Measurement of Heme Levels 33
2.10 Western Blot Analysis and Antibodies 34
2.11 MTT Assay 35
2.12 Reactive Oxygen Species (ROS) Detection 35
2.13 Senescence-Associated β-Galactosidase (SA-β-gal) Staining 36
2.14 Cellular Iron Content Assay 36
2.15 Detection of Fe2+ Using Fluorescent Probes 37
2.16 Assessment of Intracellular Lipid Peroxidation 37
2.17 Assessment of Total and Reduced Glutathione Levels 37
2.18 Cell Viability Assay 38
2.19 Measurement of HO-1 expression by ELISA 38
2.20 Real-Time Quantitative Polymerase Chain Reaction (qRT-PCR) Analysis 38
2.21 Heme Oxygenase (HO) Activity Measurement 39
2.22 siRNA Transfection 40
2.23 Data Collection from the GEO Database 40
2.24 Human Kidney Tissue Samples 41
2.25 Statistical Analysis 41
Chapter 3 Results and Discussion 42
3.1 Modulation of indoxyl sulfate-induced ferroptosis mitigates renal cells injury and CKD progression 42
3.1.1 Results 42
3.1.1.1 IS induced senescence in the renal tubular cells 42
3.1.1.2 IS-induced senescence through ROS signaling in the renal tubular cells 43
3.1.1.3 IS triggers renal tubular cell senescence via ROS-dependent 43
3.1.1.4 IS induced ER stress and ferroptosis through ROS signaling in the renal tubular cells 44
3.1.1.5 DFO mitigates IS-induced EMT signaling in renal tubular cells 45
3.1.1.6 IS induces the accumulation of intracellular iron and causes ferroptosis in renal tubular cells 45
3.1.1.7 IS induced lipid peroxidation, ROS production, and disruption of the antioxidant system in the renal tubular cells 46
3.1.1.8 DFO attenuated IS-induced senescence in renal tubular cells 47
3.1.1.9 DFO attenuated IS-induced ER stress, ferroptosis, and iron metabolism alteration in renal tubular cells 47
3.1.1.10 IS accumulation causes renal injury in adenine-induced CKD mice 48
3.1.1.11 IS induces renal aging in adenine-induced CKD mice 49
3.1.1.12 IS triggers ER-stress in the kidneys of CKD mice 50
3.1.1.13 IS contributes to ferroptosis in CKD kidneys 50
3.1.1.14 IS induces iron accumulation in the kidneys of CKD mice 51
3.1.1.15 IS alternates iron metabolism in the kidneys of CKD mice 51
3.1.1.16 IS alternates in Nrf2/HO-1 signaling in the kidneys of CKD mice 52
3.1.1.17 IS accumulation promotes renal fibrosis in the kidneys of CKD mice 52
3.1.2 Discussion 53
3.1.3 Figures 57
[Figure 1] 58
[Figure 2] 59
[Figure 3] 60
[Figure 4] 61
[Figure 5] 63
[Figure 6] 64
[Figure 7] 66
[Figure 8] 67
[Figure 9] 68
[Figure 10] 70
[Figure 11] 71
[Figure 12] 72
[Figure 13] 73
[Figure 14] 74
[Figure 15] 75
[Figure 16] 76
[Figure 17] 77
[Figure 18] 78
3.2 Zinc protoporphyrin-induced ferroptosis serves a vital role in renal tubular cells injury and the progression of chronic kidney disease 79
3.2.1 Results 79
3.2.1.1 The adverse pathological features were observed in the kidneys of CKD mice 79
3.2.1.2 Ferroptotic signatures in kidneys of adenine-induced CKD mice 79
3.2.1.3 Renal injury and ZnPP accumulation in the kidneys of CKD mice 80
3.2.1.4 ZnPP-mediated induction of HO-1 expression in renal tubular cells 81
3.2.1.5 ZnPP-induced upregulation of HO-1 mRNA and activity in renal tubular cells 81
3.2.1.6 ZnPP promotes ferrous iron build-up in renal tubular cells 82
3.2.1.7 ZnPP dysregulates iron homeostasis in renal tubular cells 83
3.2.1.8 ZnPP induces ferroptosis in renal tubular cells 83
3.2.1.9 ZnPP induces ferroptosis in renal tubular cells via ferrous。iron accumulation 84
3.2.1.10 HO-1 knockdown alleviates ZnPP-induced ferroptosis in HK-2 cells 85
3.2.1.11 Zinc chelation with TPEN ameliorates adenine-induced physiological disturbances in CKD mice 85
3.2.1.12 Zinc chelation with TPEN alleviates renal injury in CKD mice 86
3.2.1.13 Zinc chelation with TPEN improves renal dysfunction and serum biochemical abnormalities in CKD mice 87
3.2.1.14 Zinc chelation with TPEN attenuates renal fibrosis in CKD mice 87
3.2.1.15 Effects of ZnPP on HO-1 induction and HO activity in CKD mice 88
3.2.1.16 Zinc chelation with TPEN attenuates ferroptosis and iron accumulation in CKD mice 89
3.2.2 Discussion 89
3.2.3 Figures 93
[Figure 1] 94
[Figure 2] 95
[Figure 3] 96
[Figure 4] 97
[Figure 5] 98
[Figure 6] 99
[Figure 7] 100
[Figure 8] 101
[Figure 9] 102
[Figure 10] 104
[Figure 11] 106
[Figure 12] 107
[Figure 13] 108
[Figure 14] 109
[Figure 15] 110
[Figure 16] 111
[Figure 17] 113
3.3 Uremic toxin-induced heme dysregulation triggers ferroptosis and PANoptosis in the kidneys during chronic kidney disease 114
3.3.1 Results 114
3.3.1.1 Activation of ferroptosis and PANoptosis in the kidneys of interstitial nephritis patients 114
3.3.1.2 Dysregulation of ferroptosis and inflammatory cell death pathways in kidneys biopsies from various form of CKD patients 115
3.3.1.3 Progressive CKD is associated with enhanced ferroptosis and PANoptotic signaling 116
3.3.1.4 AST-120 attenuates physiological and renal morphological abnormalities in CKD mice 117
3.3.1.5 AST-120 reduces uremic toxins accumulation and improves renal function in CKD mice 117
3.3.1.6 AST-120 improves serum biochemical markers and renal function in CKD mice 118
3.3.1.7 AST-120 attenuates IS-induced fibrotic remodeling and renal aging in CKD mice 119
3.3.1.8 Uremic toxin accumulation disrupts iron metabolism in adenine-induced CKD mice 120
3.3.1.9 Uremic toxin disrupts iron metabolism in renal tubular cells 121
3.3.1.10 Uremic Toxin-induced functional iron deficiency leads to impaired heme biosynthesis and accumulation of znpp in CKD kidneys 121
3.3.1.11 CKD-driven ferroptosis and iron accumulation in the kidney are reversed following AST-120 administration 122
3.3.1.12 Lipid peroxidation is exacerbated in CKD kidneys and ameliorated by AST-120 123
3.3.1.13 AST-120 attenuates the activation of PANoptotic cell death pathways in the kidneys of CKD mice 124
3.3.1.14 AST-120 protects against IHC indicators of PANoptotic activation in CKD kidneys 125
3.3.1.15 Uremic toxins induce ferroptosis in HK-2 cells, which is attenuated by DFO 125
3.3.1.16 Uremic toxins induce ferroptosis in NRK-52E cells, which is attenuated by DFO 126
3.3.1.17 IS induces inflammatory cell death-PANoptosis, whereas in HK-2 cells 126
3.3.1.18 IS induces inflammatory cell death-PANoptosis, whereas PCS primarily triggers apoptosis in NRK-52E cells 127
3.3.1.19 Iron chelator DFO protects against IS-induced PANoptosis in HK-2 cells 128
3.3.1.20 Iron chelator DFO protects against IS-induced PANoptosis in NRK-52E cells 128
3.3.2 Discussion 129
3.3.3 Figures 132
[Figure 1] 133
[Figure 2] 134
[Figure 3] 136
[Figure 4] 138
[Figure 5] 139
[Figure 6] 140
[Figure 7] 141
[Figure 8] 142
[Figure 9] 143
[Figure 10] 144
[Figure 11] 146
[Figure 12] 147
[Figure 13] 148
[Figure 14] 149
[Figure 15] 151
[Figure 16] 152
[Figure 17] 153
[Figure 18] 154
[Figure 19] 155
[Figure 20] 156
[Figure 21] 157
Chapter 4 Conclusion and Future perspectives 158
Chapter 5 References 160
Chapter 6 Appendix 192
6.1 Lists of publications 192		-
dc.language.isoen-
dc.subject硫酸吲哚酚、鐵離子、鐵死亡、活性氧物質、慢性腎臟病、鋅原卟啉、血紅素加氧酶、血紅素、泛細胞凋亡-
dc.subjectindoxyl sulfate; iron; ferroptosis; ROS; chronic kidney disease; zinc protoporphyrin; heme; ho-1; PANoptosis-
dc.title鋅原卟啉在慢性腎臟病進程中之角色: 對鐵離子代謝及細胞死亡影響及機制之探討zh_TW
dc.titleRoles of Zinc Protoporphyrin in Chronic Kidney Disease Progression: Impacts on Iron Metabolism and Regulated Cell Deathen
dc.typeThesis-
dc.date.schoolyear114-1-
dc.description.degree博士-
dc.contributor.oralexamcommittee許美鈴;吳鎮天;趙家德;​姜至剛zh_TW
dc.contributor.oralexamcommitteeMeei-Ling Sheu;Cheng-Tien Wu;Chia-Ter Chao;Chih-Kang Chiangen
dc.subject.keyword硫酸吲哚酚、鐵離子、鐵死亡、活性氧物質、慢性腎臟病、鋅原卟啉、血紅素加氧酶、血紅素、泛細胞凋亡,zh_TW
dc.subject.keywordindoxyl sulfate; iron; ferroptosis; ROS; chronic kidney disease; zinc protoporphyrin; heme; ho-1; PANoptosis,en
dc.relation.page192-
dc.identifier.doi10.6342/NTU202600336-
dc.rights.note未授權-
dc.date.accepted2026-01-29-
dc.contributor.author-college醫學院-
dc.contributor.author-dept毒理學研究所-
dc.date.embargo-liftN/A-
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