Bidirectional Impact of Varying Severity of Acute Kidney Injury on Calcium Oxalate Stone Formation.

IF 2.3 4区医学 Q2 PERIPHERAL VASCULAR DISEASE

Kidney & blood pressure research Pub Date : 2024-10-18 DOI:10.1159/000542077

Yu Yang, Junkai Huang, Xiaochen Ma, Haijie Xie, Linguo Xie, Chunyu Liu

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引用次数: 0

Abstract

Introduction: Acute Kidney Injury (AKI) is a prevalent renal disorder. The occurrence of AKI may promote the formation of renal calcium oxalate stones by exerting continuous effects on renal tubular epithelial cells. We aimed to delineate the molecular interplay between AKI and nephrolithiasis.

Methods: A mild (20 min) and severe (30 min) renal ischemia-reperfusion injury model was established in mice. Seven days after injury, calcium oxalate stones were induced using glyoxylate (Gly) to evaluate the impact of AKI on the formation of kidney stones. Transcriptome sequencing was performed on tubular epithelial cells (TECs) to elucidate the relationship between AKI severity and kidney stones. Key transcription factors (TF) regulating differential gene transcription levels were identified using motif analysis, and pioglitazone, ginkgetin, and fludarabine were used for targeted therapy to validate key transcription factors as potential targets for kidney stone treatment.

Results: Severe AKI led to increased deposition of calcium oxalate crystals in renal, impaired kidney function, and upregulation of kidney stone-related gene expression. In contrast, mild AKI was associated with decreased crystal deposition, preserved kidney function, and downregulation of similar gene expression. Transcriptomic analysis revealed that genes associated with inflammation and cell adhesion pathways were significantly upregulated after severe AKI, while genes related to energy metabolism pathways were significantly upregulated after mild AKI. An integrative bioinformatic analysis uncovered a TF regulatory network within TECs, pinpointing that PKNOX1 was involved in the upregulation of inflammation-related genes after severe AKI, and inhibiting PKNOX1 function with Pioglitazone could simultaneously reduce the increase of calcium oxalate crystals after severe AKI in kidney. On the other hand, motif analysis also revealed the protective role of STAT1 in the kidneys after mild AKI, enhancing the function of STAT1 with Ginkgetin could reduce kidney stone formation, while the specific inhibitor of STAT1, Fludarabine, could eliminate the therapeutic effects of mild AKI on kidney stones.

Conclusion: Inadequate repair of tubular epithelial cells after severe AKI increases the risk of kidney stone formation, with the upregulation of inflammation-related genes regulated by PKNOX1 playing a role in this process. Inhibiting PKNOX1 function can reduce kidney stone formation. Conversely, after mild AKI, effective cell repair through upregulation of STAT1 expression can protect TEC function, reduce stone formation, and activating STAT1 function can also achieve the goal of treating kidney stones.

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急性肾损伤严重程度不同对草酸钙结石形成的双向影响

简介急性肾损伤（AKI）是一种常见的肾脏疾病。AKI 的发生可能通过对肾小管上皮细胞产生持续影响而促进肾草酸钙结石的形成。我们旨在阐明 AKI 与肾结石之间的分子相互作用：方法：在小鼠体内建立了轻度（20 分钟）和重度（30 分钟）肾缺血再灌注损伤模型。损伤七天后，用乙醛酸（Gly）诱导草酸钙结石，以评估 AKI 对肾结石形成的影响。对肾小管上皮细胞（TECs）进行了转录组测序，以阐明AKI严重程度与肾结石之间的关系。利用基序分析确定了调控不同基因转录水平的关键转录因子（TF），并将吡格列酮、银杏酸和氟达拉滨用于靶向治疗，以验证关键转录因子是肾结石治疗的潜在靶点：结果：重度 AKI 导致草酸钙结晶在肾脏沉积增加，肾功能受损，肾结石相关基因表达上调。相比之下，轻度 AKI 与晶体沉积减少、肾功能保持不变以及类似基因表达下调有关。转录组分析表明，与炎症和细胞粘附途径相关的基因在重度 AKI 后显著上调，而与能量代谢途径相关的基因在轻度 AKI 后显著上调。综合生物信息学分析发现了TECs内的TF调控网络，指出PKNOX1参与了重度AKI后炎症相关基因的上调，而用吡格列酮抑制PKNOX1的功能可同时减少重度AKI后肾脏草酸钙结晶的增加。另一方面，Motif 分析还揭示了 STAT1 在轻度 AKI 后对肾脏的保护作用，用银杏黄酮增强 STAT1 的功能可以减少肾结石的形成，而 STAT1 的特异性抑制剂氟达拉滨则可以消除轻度 AKI 对肾结石的治疗作用：结论：重度 AKI 后肾小管上皮细胞修复不足会增加肾结石形成的风险，PKNOX1 调控的炎症相关基因上调在这一过程中发挥了作用。抑制 PKNOX1 的功能可减少肾结石的形成。相反，在轻度 AKI 后，通过上调 STAT1 的表达进行有效的细胞修复可以保护 TEC 功能，减少结石的形成，而激活 STAT1 的功能也可以达到治疗肾结石的目的。

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来源期刊

Kidney & blood pressure research 医学-泌尿学与肾脏学

CiteScore

4.80

自引率

3.60%

发文量

审稿时长

6-12 weeks

期刊介绍： This journal comprises both clinical and basic studies at the interface of nephrology, hypertension and cardiovascular research. The topics to be covered include the structural organization and biochemistry of the normal and diseased kidney, the molecular biology of transporters, the physiology and pathophysiology of glomerular filtration and tubular transport, endothelial and vascular smooth muscle cell function and blood pressure control, as well as water, electrolyte and mineral metabolism. Also discussed are the (patho)physiology and (patho) biochemistry of renal hormones, the molecular biology, genetics and clinical course of renal disease and hypertension, the renal elimination, action and clinical use of drugs, as well as dialysis and transplantation. Featuring peer-reviewed original papers, editorials translating basic science into patient-oriented research and disease, in depth reviews, and regular special topic sections, ''Kidney & Blood Pressure Research'' is an important source of information for researchers in nephrology and cardiovascular medicine.