Role of the Kidney in Iron Balance

肾脏在铁平衡中的作用

• 批准号: 9247896
• 负责人: Katherine Xu
• 金额: $ 4.4万
• 依托单位: COLUMBIA UNIVERSITY HEALTH SCIENCES
• 依托单位国家: 美国
• 财政年份: 2015
• 资助国家: 美国
• 起止时间: 2015-04-01 至 2018-03-31
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/9247896
• 关键词: ATP phosphohydrolase; Acute; Acute Renal Failure with Renal Papillary Necrosis; Adult; Affect; Anemia; Apical; Appearance; Back; Binding; Biological Availability; Biology; Blood; Blood Circulation; Bone Marrow; Bowman' s space; Brain Hypoxia-Ischemia; Bypass; Cell membrane; Cells; Chelating Agents; Chemistry; Chronic; Complex; Data; Development; Distal; Duct (organ) structure; Duodenum; Energy Metabolism; Enterocytes; Environment; Equilibrium; Erythroblasts; Failure; Food; Genes; Genetic; Hand; Hemochromatosis; Hepatocyte; Hormones; Host Defense; Human; Impairment; Injury; Iron; Iron Chelating Agents; Iron Overload; Kidney; Knock-out; LCN2 gene; LDL-Receptor Related Protein 2; Limb structure; Liver; Location; LoxP-flanked allele; Lysosomes; Maps; Mediating; Membrane; Micronutrients; Modeling; Molecular; Mus; Nephrons; Oxidants; Oxygen; Pathway interactions; Pattern; Pharmacology; Phosphate Buffer; Physiology; Play; Polymers; Proteins; Public Health; Reactive Oxygen Species; Recycling; Reducing Agents; Research; Role; SLC11A2 gene; Series; Serum; Source; TFRC gene; Testing; Thick; TimeLine; Tissues; Tracer; Transferrin; Tubular formation; Urine; Vesicle; Water; Woman; cell injury; cell type; chelation; hepcidin; inorganic phosphate; intrinsic factor-cobalamin receptor; iron deficiency; macrophage; metal transporting protein 1; mutant; novel; nucleotide metabolism; nutrition; organ growth; oxidation; oxygen transport; protein transport; public health relevance; symporter; tool; trafficking; urinary

 DESCRIPTION (provided by applicant): The biology of iron transport is dictated by the chemistry of iron. Free iron is present around 10-10M in water at neutral pH (in an oxygenated solution) and around 10-19M in the presence of phosphate buffers, concentrations too low to support cellular viability. Consequently, from the moment iron is liberated from food sources, to its final distribution in the cell, iron must be "handed-off" from one chelator to another chelator Failure of chelation, which is tantamount to the presentation of iron to reducing or oxidizing agents, results in reactive chemistry, while appropriate chelation solubilizes and protects iron from changes in oxidation state. In the past decade, a series of iron chelators, carriers and transporters (both proteins and organic molecules) have been identified which affect the exchange of iron from the gut lumen to nearly every cell of the body, even at neutral pH, in the presence of oxygen. These proteins and organic molecules provide both short range transport (across cell membranes) and long range transport (through the circulation) to deliver adequate amounts of iron to target cells and recycle iron from damaged cells. Almost no iron is lost to the environment meaning that the steady state can be maintained with limited replacement (approximately 1mg per day in humans). This means the capture and trafficking pathways are efficient and export of iron to the environment is contained. Mechanisms that capture and recycle iron have been described and have been most importantly studied in duodenal enterocytes or macrophages. Yet, a number of proteins which carry iron are filtered into the nephron, and acute and chronic kidney injury is well known to result in the appearance of iron in the urine, resulting in catalytic iron mediated damage. To understand iron trafficking in the kidney requires an analysis of iron trafficking proteins in many cell types along the course of the nephron. I have identified both canonical and non-cannonical localizations of these proteins in the nephron and I propose to understand how they remove iron from the urinary space and transport it safely to the blood. My lab has the expertise and all of the standard tools required fr these studies, such as a series of floxed-iron transporter genes, novel Cre Drivers, and tracers loaded with iron, to detect the location of cellular and urinary iron when different transporters ae deleted. Our preliminary results suggest that both proximal and distal nephron mechanisms are at play to capture iron including entirely unexpected mechanisms of luminal iron traffic. The preliminary results also suggest that renal iron traffic may be under control of hepcidin, meaning that like the liver, duodenum, and macrophage, the kidney is engaged not only in local iron trafficking but is likely to be a contributor to systemic iron balance. Results from the proposed study will provide molecular implications for iron-mediated damage in acute kidney injury.

 描述（由申请人提供）：铁转运的生物学特性由铁的化学性质决定。在中性 pH 值的水中（含氧溶液），游离铁的含量约为 10-10M，在磷酸盐缓冲液存在的情况下，游离铁的含量约为 10-19M。 ，浓度太低，无法支持细胞活力，从铁从食物来源释放到细胞中的最终分布，铁必须从一种螯合剂“传递”到另一种螯合剂失败。在过去的十年中，铁与还原剂或氧化剂的螯合反应、反应化学以及适当的溶解和保护铁免受氧化态变化的影响，出现了一系列铁螯合剂、载体和转运蛋白（蛋白质和有机分子）。 ）已经证实，在这些蛋白质和有机分子存在的情况下，铁从肠腔到几乎每个细胞的 RAL PH 的交换都提供了两者。短程运输（跨细胞膜）将足够量的铁输送到目标并从受损细胞中回收 Cle 铁，几乎没有铁流失到环境中，这意味着可以通过有限的补充（每天约 1 毫克）来维持稳定状态。在人类中），这种途径是在十二指肠肠细胞中捕获和记录并进行了最重要研究的机制。然而，众所周知，巨噬细胞中的许多蛋白质会导致铁进入肾单位，并导致尿液中出现铁，从而导致催化铁介导的损伤。要了解肾脏中的铁运输，需要进行分析。铁转运蛋白在许多细胞类型中的作用 我已经确定了肾单位中蛋白质的规范和非规范，并且我建议将铁 M 排除在尿路空间并将其安全地输送到血液中。当不同的转运蛋白被删除时，驱动程序和示踪剂装载有铁拉尔和尿铁。我们的初步结果表明，近端和远端肾单位机制都在捕获铁，包括意外的管腔铁运输。初步结果还表明，肾铁运输可能和巨噬细胞一样，肾脏不仅参与局部铁运输，而且还参与肾内铁运输。可能是全身铁平衡的一个贡献者，拟议研究的结果将为急性肾损伤中铁介导的损伤提供分子意义。