FGF23 and Phosphate Wasting Disorders 被引量：9

FGF23 and Phosphate Wasting Disorders

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摘要 A decade ago, only two hormones, parathyroid hormone and 1,25（OH）2D, were widely recognized to direct-ly affect phosphate homeostasis. Since the discovery of fibroblast growth factor 23 （FGF23） in 2000 （1）, our understanding of the mechanisms of phosphate homeostasis and of bone mineralization has grown exponentially. FGF23 is the link between intestine, bone, and kidney together in phosphate regulation. However, we still do not know the complex mechanism of phosphate homeostasis and bone mineralization. The physiological role of FGF23 is to regulate serum phosphate. Secreted mainly by osteocytes and osteo- blasts in the skeleton （2-3）, it modulates kidney handling of phosphate reabsorption and calcitriol produc-tion. Genetic and acquired abnormalities in FGF23 structure and metabolism cause conditions of either hyper-FGF23 or hypo-FGF23. Hyper-FGF23 is related to hypophosphatemia, while hypo-FGF23 is related to hyperphosphatemia. Both hyper-FGF23 and hypo-FGF23 are detrimentalto humans. In this review, we will discuss the vathovhvsiology of FGF23 and hvver-FGF23 related renal vhosvhate wasting disorders （4）. A decade ago, only two hormones, parathyroid hormone and 1,25（OH）2D, were widely recognized to direct-ly affect phosphate homeostasis. Since the discovery of fibroblast growth factor 23 （FGF23） in 2000 （1）, our understanding of the mechanisms of phosphate homeostasis and of bone mineralization has grown exponentially. FGF23 is the link between intestine, bone, and kidney together in phosphate regulation. However, we still do not know the complex mechanism of phosphate homeostasis and bone mineralization. The physiological role of FGF23 is to regulate serum phosphate. Secreted mainly by osteocytes and osteo- blasts in the skeleton （2-3）, it modulates kidney handling of phosphate reabsorption and calcitriol produc-tion. Genetic and acquired abnormalities in FGF23 structure and metabolism cause conditions of either hyper-FGF23 or hypo-FGF23. Hyper-FGF23 is related to hypophosphatemia, while hypo-FGF23 is related to hyperphosphatemia. Both hyper-FGF23 and hypo-FGF23 are detrimentalto humans. In this review, we will discuss the vathovhvsiology of FGF23 and hvver-FGF23 related renal vhosvhate wasting disorders （4）.

作者 Xianglan Huang Yan Jiang Weibo Xia

机构地区 Department of Endocrinology

出处《Bone Research》 SCIE CAS 2013年第2期120-132,共13页 骨研究（英文版）

基金 supported by the National Natural Science Foundation of China (No.81070687 and 8117-0805) National Science and Technology Major Projects for"Major New Drugs Innovation and Development"(Grant No.2008ZX09312-016) Beijing Natural Science Foundation(No.7121012)

关键词 FGF23 KLOTHO hypophosphatemic rickets XLH ADHR ARHR ENS OGD NF McCune Albrightsyndrome DMP-1 PHEX FGF23 Klotho hypophosphatemic rickets XLH ADHR ARHR ENS OGD NF McCune Albrightsyndrome DMP-1 PHEX

分类号 R363 [医药卫生—病理学]

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参考文献52

1Liu S,Tang W,Zhou J,Stubbs JR Luo Q Pi M Quarles LD. Fibroblast growth factor 23 is a counter-regulatory phosphaturic hormone for vitamin D[J].Journal of the American Society of Nephrology,2006,(5):1305-1315.doi:10.1681/ASN.2005111185.
2Quarles LD. Endocrine functions of bone in mineral metabolism regulation[J].Journal of Clinical Investigation,2008.3820-3828.
3Lorenz-Depiereux B,Bastepe M,Benet-Pages A,Amyere M Wagenstaller J Muller-Barth U Badenhoop K Kaiser SM Rittmaster RS Shlossberg AH Olivares JL Loris C Ramos FJ Glorieux F Vikkula M Juppner H Strom TM. DMP1 mutations in autosomal recessive hypophosphatemia implicate a bone matrix protein in the regulation of phosphate homeostasis[J].Nature Genetics,2006,(11):1248-1250.doi:10.1038/ng1868.
4Gattineni J,Baum M. Genetic disorders of phosphate regulation[J].Pediatric Nephrology,2012.1477-1487.
5Kuro-o M,Matsumura Y,Aizawa H,Kawaguchi H Suga T Utsugi T Ohyama Y Kurabayashi M Kaname T Kume E Iwasaki H Iida A Shiraki-Iida T Nishikawa S Nagai R Nabeshima YI. Mutation of the mouse klotho gene leads to a syndrome resembling ageing[J].Nature,1997.45-51.
6Bianchine JW,Stambler AA,Harrison HE. Familial hypophospha-temic rickets showing autosomal dominant inheritance[J].Birth Defects Original Article Series,1971.287-295.
7Hruska KA,Rifas L,Cheng SL,Gupta A Halstead L Avioli L. X-linked hypophosphatemic rickets and the murine Hyp homologue[J].American Journal of Physiology,1995.F357-F362.
8Hu MC,Shi M,Zhang J,Pastor J Nakatani T Lanske B Razzaque MS Rosenblatt KP Baum MG Kuro-o M Moe OW. Klotho:a novel phosphaturic substance acting as an autocrine enzyme in the renal proximal tubule[J].Federation of America Societies for Experimental Biology Journal,2010.3438-3450.
9Econs MJ,Drezner MK. Tumor-induced osteomalacia--unveiling a new hormone[J].New England Journal of Medicine,1994.1679-1681.
10Fukumoto S,Shimizu Y. Fibroblast growth factor 23 as a phosphotropic hormone and beyond[J].Journal of Bone and Mineral Metabolism,2011.507-514.

二级参考文献22

1DiMeglio LA,White KE,Econs MJ.Disorders of phosphate metabolism.Endocrinol Metab Clin North Am 2000; 29:591-609.
2Shimada T,Mizutani S,Muto T,Yoneya T,Hino R,Takeda S,et al.Cloning and characterization of FGF23 as a causative factor of tumor-induced osteomalacia.Proc Natl Acad Sci U S A 2001; 98:6500-6505.
3Xia W,Meng X,Jiang Y,Li M,Xing X,Pang L,et al.Three novel mutations of the PHEX gene in three Chinese families with X-linked dominant hypophosphatemic rickets.Calcif Tissue Int 2007; 81:415-420.
4Walton RJ,Bijvoet OL.Nomogram for derivation of renal threshold phosphate concentration.Lancet 1975; 2:309-310.
5Sommer S,Berndt T,Craig T,Kumar R.The phosphatonins and the regulation of phosphate transport and vitamin D metabolism.J Steroid Biochem Mol Biol 2007; 103:497-503.
6Shaikh A,Berndt T,Kumar R.Regulation of phosphate homeostasis by the phosphatonins and other novel mediators.Pediatr Nephrol 2008; 23:1203-1210.
7Riminucci M,Collins MT,Fedarko NS,Cherman N,Corsi A,White KE,et al.FGF-23 in fibrous dysplasia of bone and its relationship to renal phosphate wasting.J Clin Invest 2003; 112:683-692.
8Yamazaki Y,Okazaki R,Shibata M,Hasegawa Y,Satoh K,Tajima T,et al.Increased circulatory level of biologically active full-length FGF-23 in patients with hypophosphatemic rickets/osteomalacia.J Clin Endocrinol Metab 2002; 87:4957-4960.
9Jonsson KB,Zahradnik R,Larsson T,White KE,Sugimoto T,Imanishi Y,et al.Fibroblast growth factor 23 in oncogenic osteomalacia and X-linked hypophosphatemia.N Engl J Med 2003:348:1656-1663.
10Shimada T,Urakawa I,Yamazaki Y,Hasegawa H,Hino R,Yoneya T,et al.FGF-23 transgenic mice demonstrate hypophosphatemic rickets with reduced expression of sodium phosphate cotransporter type Ila.Biochem Biophys Res Commun 2004; 314:409-414.

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1WANG Xian-ling MU Yi-ming.Emphasis should be placed on the diagnosis and therapy of tumor induced osteomalacia[J].Chinese Medical Journal,2011(2):163-165. 被引量：3
2夏维波.磷稳态的调节与骨骼矿化[J].中华骨质疏松和骨矿盐疾病杂志,2011,4(4):217-223. 被引量：10
3张楠楠,王晓红,何苗,赵依娜,张晓艳.肿瘤诱发低磷性骨软化症1例并文献复习[J].中华骨质疏松和骨矿盐疾病杂志,2011,4(4):281-284. 被引量：8
4赵永强,田德增,金楠.低磷骨软化症11例分析[J].疑难病杂志,2014,13(1):88-89. 被引量：6
5林芝,李志辉,张良,段翠蓉.儿童低血磷性佝偻病12例临床特征分析[J].中国中西医结合儿科学,2014,6(1):59-61.
6谭屾,柏楠,张自琴,崔爱民.肿瘤相关低磷性骨软化症1例并文献复习[J].山西医科大学学报,2014,45(3):242-243. 被引量：2
7杨云建,陈继营,杨帆,张振东,李恒.11例瘤源性骨软化症的临床诊治分析[J].解放军医学院学报,2014,35(7):707-709. 被引量：5
8许莉军,姜艳,邢小平,李梅,王鸥,袁涛,孟迅吾,夏维波.McCune-Albright综合征合并低血磷性佝偻病4例并文献复习[J].中华骨质疏松和骨矿盐疾病杂志,2014,7(3):213-220. 被引量：6
9张丛,黄香兰,夏维波.成纤维细胞生长因子23相关的低磷性佝偻病/骨软化症[J].中华内科杂志,2015,54(9):817-820. 被引量：4
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2夏维波.磷稳态的调节与骨骼矿化[J].中华骨质疏松和骨矿盐疾病杂志,2011,4(4):217-223. 被引量：10
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7洪琼,徐建华,徐胜前,张锐,张明铭,邹延峰.类风湿关节炎患者骨质疏松症的危险因素分析[J].安徽医科大学学报,2013,48(9):1083-1087. 被引量：16
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10Paul D Miller.Chronic kidney disease and the skeleton[J].Bone Research,2014,2(4):205-217. 被引量：1

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2张丛,黄香兰,夏维波.成纤维细胞生长因子23相关的低磷性佝偻病/骨软化症[J].中华内科杂志,2015,54(9):817-820. 被引量：4
3潘英,陈东,李娜.血清中25-OH-D、FGF23因子对骨质疏松患者糖皮质激素治疗疗效的评估价值分析[J].中国医学创新,2016,13(18):26-29. 被引量：3
4夏维波,章振林,林华,金小岚,余卫,付勤.维生素D及其类似物临床应用共识[J].中华骨质疏松和骨矿盐疾病杂志,2018,11(1):1-19. 被引量：212
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6维生素D及其类似物的临床应用共识[J].中华内分泌代谢杂志,2018,34(3):187-200. 被引量：52
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1Yu-Chen Guo,Quan Yuan.Fibroblast growth factor 23 and bone mineralisation[J].International Journal of Oral Science,2015,7(1):8-13. 被引量：3
2Sheng-yu Wang,Wei Wu,Xuan Ma.Recurrent Seizures Manifestations in a Case of Congenital Hypoparathyroidism:a Case Report[J].Chinese Medical Sciences Journal,2013,28(4):242-244.
3Paul D Miller.Chronic kidney disease and the skeleton[J].Bone Research,2014,2(4):205-217. 被引量：1
4李国江,于洪青,赵悦,宋文庭.奶牛低磷血症的临床症状探析[J].中国奶牛,1998(4):18-19. 被引量：1
5赵锡荣,闵友贵,赵悦,于洪青,张强,马秀霞,王淑贤,王军成.奶牛低磷血症诊断与治疗[J].中国兽医科技,1991,21(10):38-41. 被引量：2
6李佐平,张景阳.奶牛低磷血症病诊治[J].黑龙江畜牧科技,1993(1):41-42.
7方必春,吴正发,宫胜家.奶牛生产诱发代谢性低磷血症的诊治[J].中国奶牛,1999(5):45-45.
8Qian Zhang,Michele Doucet,Ryan E Tomlinson,Xiaobin Han,L Darryl Quarles,Michael T Collins,Thomas L Clemens.The hypoxia-inducible factor-1α activates ectopic production of fibroblast growth factor 23 in tumor-induced osteomalacia[J].Bone Research,2016,4(2):85-90. 被引量：8
9拉毛吉.奶牛低磷血症的综合诊治[J].畜牧与饲料科学,2014,35(10):118-118.
10高进伟,王路军.奶牛低磷血症的鉴别诊断及综合防治[J].养殖技术顾问,2010(1):78-79. 被引量：1

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