Potentielle application de l’axe fibroblast growth factor 23-Klotho dans la maladie rénale chronique

Membrane Alpha Klotho (α-klotho) is expressed in the kidney and functions as a co-receptor of FGF receptors (FGFRs) to activate specific fibroblast growth factor 23 (FGF23) signal pathway. FGF23 is produced in bones and participates in mineral homeostasis. The extracellular domain of transmembrane αklotho can be cleaved by proteases and released into the circulation as soluble α-klotho. Klotho deficiency is a pathogenic factor for chronic kidney disease progression and cardiovascular diseases. The FGF23 excess may also contribute to cardiovascular diseases where its pathogenic effect acts via the FGFR4 and independently of α-klotho. The decline in serum α-klotho followed by a rise in serum FGF23 at an early stage of chronic kidney disease can serve as a robust predictor for risk of cardiovascular diseases and mortality in both CKD patients and the general population. The first randomized trials suggest the possibility to reduce FGF23 excess in chronic kidney disease by controlling the phosphate serum using phosphate binders and reducing PTH levels with calcimimetic drug. New strategies emerge, including the administration of α-klotho recombinant and the use of epidrugs in order to correct the klotho deficiency. The FGR4 inhibitors are promising to limit the development of left ventricular hypertrophy linked to FGF23 excess. Finally, a better understanding of the molecular mechanisms of FGF23/α-klotho axis will allow us to find new strategic approaches and improve the CKD patient's management and their outcomes.     

Is fibroblast growth factor 23 a harbinger of mortality in CKD?

Fibroblast growth factor 23 (FGF23) is a novel hormone produced by bone with known functions to regulate urinary phosphate excretion, as well as vitamin D and PTH production. The discovery of this hormone roughly a decade ago has revolutionized the traditional theories regarding the mechanisms responsible for the mineral metabolism abnormalities that are commonly observed in patients with chronic kidney disease. Circulating FGF23 levels begin to rise in the early stages of kidney injury and become markedly elevated as kidney disease progresses. Recent reports have emerged which link these elevations in circulating FGF23 to multiple adverse outcomes. Most notably, a strong association between increments in FGF23 and cardiovascular pathology has been suggested in patients with both normal and abnormal renal function. Despite a growing body of evidence to suggest FGF23 as a contributor to morbidity and mortality in CKD, a cause–effect relationship for this association has not been established. This review highlights our current understanding of the regulation and function of FGF23 and examines the existing literature linking FGF23 with adverse outcomes.     

Fibroblast growth factor 23 in chronic kidney disease: New insights and clinical implications

Fibroblast growth factor 23 (FGF-23) is a recently discovered regulator of phosphate and mineral metabolism. Its main physiological function is the enhancement of renal phosphate excretion. FGF-23 levels are inversely related to renal function and in patients with chronic kidney disease (CKD) elevation in FGF-23 precedes the rise of serum phosphate. Studies have demonstrated an important role for FGF-23 in the development of secondary hyperparathyroidism through an effect on parathyroid hormone and calcitriol. In cross-sectional studies FGF-23 has been associated with surrogate markers of cardiovascular disease such as endothelial dysfunction and arterial stiffness. FGF-23 has also been associated with both progression of CKD and mortality in dialysis patients. The discovery of FGF-23 has provided a profound new insight into bone and mineral metabolism, and it may become an important biomarker and therapeutic target in CKD.     

Mineral metabolism and aging: the fibroblast growth factor 23 enigma

PURPOSE OF REVIEW: The regulation of phosphate homeostasis was thought to be passively mediated by the calciotrophic hormones parathyroid hormone and 1,25(OH)2D3. This article summarizes the emerging trends that show an active regulation of phosphate homeostasis by fibroblast growth factor 23 (FGF-23) - a process fairly independent of calcium homeostasis - and how altered mineral ion metabolism may affect the aging process. RECENT FINDINGS: A major breakthrough in FGF-23 biology has been achieved by the demonstration of strikingly similar physical/biochemical phenotypes of Fgf-23(-/-) and klotho hypomorph mice, which eventually led to the identification of klotho as a cofactor in FGF-23 and its receptor interactions. Furthermore, FGF-23 has emerged as a counter regulator of the renal 1alpha(OH)ase and sodium-phosphate cotransporter activities to modulate phosphate homeostasis. Finally, studies point towards a role of dentine matrix protein 1 in affecting phosphate homeostasis, in coordination with FGF-23. SUMMARY: Recent mouse genetic studies have broadened our understanding of biochemical/molecular pathways involved in phosphate homeostasis, and linked FGF-23 to such regulation. Understanding the molecular interactions of essential calcium and phosphate regulators will enhance our knowledge of the coordinated regulation of mineral ion metabolism, and will help to redefine the molecular pathology of age-associated lesions accompanied by abnormal mineral ion metabolism such as vascular calcifications and osteoporosis.     

Klotho as a regulator of fibroblast growth factor signaling and phosphate/calcium metabolism

PURPOSE OF REVIEW: This review summarizes the most recent findings on Klotho in the regulation of fibroblast growth factor-23 (FGF23) signaling and phosphate/calcium homeostasis. RECENT FINDINGS: The klotho gene encodes a single-pass transmembrane protein and functions as an aging-suppressor gene, which extends life span when overexpressed and accelerates the development of aging-like phenotypes when disrupted in mice. FGF23 is a hormone that suppresses phosphate reabsorption in renal proximal tubules. Recent studies have shown that Klotho mice and Fgf23 mice exhibit identical phenotypes including hyperphosphatemia and hypercalcemia in addition to the aging-like syndrome. This may be explained by the fact that Klotho binds to multiple FGF receptors and increases their affinity to FGF23. Another Klotho protein function is to activate transient receptor potential vanilloid-5 - a calcium channel involved in calcium reabsorption in the kidney. Klotho protein can modify sugar chains on transient receptor potential vanilloid-5 through its activity as a beta-glucuronidase, preventing the calcium channel from internalization and inactivation. SUMMARY: Klotho protein binds to fibroblast growth factor receptors and functions as a regulator of FGF23 signaling. It also functions as an enzyme that modifies sugar chains of transient receptor potential vanilloid-5 and regulates its activity. Klotho is a multi-functional protein that regulates phosphate/calcium metabolism as well as aging.     

Anti‐FGF23 Neutralizing Antibodies Show the Physiological Role and Structural Features of FGF23

Fibroblast growth factor (FGF)23 is proposed to play a physiological role in the regulation of phosphate and vitamin D metabolism; deranged circulatory levels of FGF23 cause several diseases with abnormal mineral metabolism. This paper presents a novel approach to analyze the mechanism of action of FGF23 using anti‐FGF23 monoclonal antibodies that can neutralize FGF23 activities both in vitro and in vivo. We developed two antibodies (FN1 and FC1) that recognize the N‐ and C‐terminal regions of FGF23, respectively. Both FN1 and FC1 inhibited FGF23 activity in a cell‐based Klotho‐dependent reporter assay. Their administration caused marked increases in serum phosphate and 1,25D levels in normal mice. These changes were accompanied by altered expression in the kidney of type IIa sodium‐phosphate cotransporter, 25‐hydroxyvitamin‐D‐1α‐hydroxylase, and 24‐hydroxylase. Thus, this study using neutralizing antibodies confirms that FGF23 is a physiological regulator of phosphate and vitamin D metabolism. We addressed the mechanism of action for these neutralizing antibodies. Structural analysis of the FGF23/FN1‐Fab complex showed that FN1 masked putative FGF receptor‐binding sites in the N‐terminal domain of FGF23, whereas biochemical analyses showed that FC1 interfered with the association between FGF23 and Klotho by binding to the C‐terminal domain of FGF23. Taken together, our results suggest that the N‐ and C‐terminal domains of FGF23 are responsible for association with cognate FGF receptors and Klotho, respectively, and that these interactions are indispensable for FGF23 activity.     

Fibroblast growth factor 23 as a phosphotropic hormone and beyond

Fibroblast growth factor 23 (FGF23) is produced by bone and reduces serum phosphate by inhibiting proximal tubular phosphate reabsorption and intestinal phosphate absorption. Excess actions of FGF23 cause several kinds of hypophosphatemic rickets/osteomalacia while deficient actions of FGF23 result in hyperphosphatemic tumoral calcinosis. In addition, FGF23 has been shown to prevent the development of hyperphosphatemia during the progression of chronic kidney disease−mineral and bone disorder. Epidemiological studies have indicated that high FGF23 levels are associated with unfavorable events including higher mortality, cardiovascular events, progression of CKD and fracture; however, these associations are not observed unequivocally and it is not evident why they are present. While FGF23 has been shown to be a hormone that regulates phosphate metabolism, it remains to be established whether FGF23 has roles other than regulating mineral homeostasis.     

What would we like to know, and what do we not know about fibroblast growth factor 23?

Recently, a new view of the molecular mechanisms of phosphate homeostasis and secondary hyperparathyroidism pathogenesis has been proposed, with fibroblast growth factor 23 (FGF23) as a novel player in the field. FGF23 is a 32-kDa peptide secreted by the osteocytes involved in the control of phosphate homeostasis and calcitriol metabolism. FG23 is constantly elevated in advanced chronic kidney disease (CKD) patients, and recent studies have indicated that high levels are associated with the progression of CKD and with higher mortality rates in hemodialysis patients. In the CKD population, high serum FGF23 concentration seems to predict the occurrence of refractory secondary hyperparathyroidism, by inducing a resistance of the parathyroid glands to FGF23, and to be associated with higher mortality risk in incident hemodialysis patients. FGF23 appears to be involved in bone metabolism, but a direct effect of FGF23 on bone disease in humans has not yet been elucidated, even if the inhibitory effect of FGF23 on osteoblast activity that has been described in animal models and hereditary rickets is clearly connected with FGF23 deficiency. The association between altered levels of FGF23 and bone disease could be mainly due to the dysregulation of phosphate-handling and vitamin D metabolism, more than to a direct antiosteoblastic activity of FGF23. FGF23 appears to be a new biomarker, which is independently associated with several cardiovascular risk factors such as endothelial dysfunction, arterial stiffness and left ventricular hypertrophy, in the general population as well as in early CKD. All of the above have been related to cardiovascular and general mortality. Until now, we know that elevated FGF23 levels in dialysis patient are associated with several cardiovascular adverse outcomes mentioned above; the clinical relevance of high FGF23 values in dialysis patients remains unclear, because therapy with active vitamin D sterols further increases FGF23 levels but, on the other hand, is associated with a survival benefit in dialysis patients. This paradox highlights the need for future prospective randomized trials to evaluate the correlation between vitamin D therapy and FGF23 levels in dialysis patients. In the clinical setting, there are still different FGF23 actions that need investigation. In this sense, increased knowledge of mineral metabolism disorder alterations in CKD may be used to improve diagnostics and select future treatments.     

Therapeutic Effects of FGF23 c‐tail Fc in a Murine Preclinical Model of X‐Linked Hypophosphatemia Via the Selective Modulation of Phosphate Reabsorption

Fibroblast growth factor 23 (FGF23) is the causative factor of X‐linked hypophosphatemia (XLH), a genetic disorder effecting 1:20,000 that is characterized by excessive phosphate excretion, elevated FGF23 levels and a rickets/osteomalacia phenotype. FGF23 inhibits phosphate reabsorption and suppresses 1α,25‐dihydroxyvitamin D (1,25D) biosynthesis, analytes that differentially contribute to bone integrity and deleterious soft‐tissue mineralization. As inhibition of ligand broadly modulates downstream targets, balancing efficacy and unwanted toxicity is difficult when targeting the FGF23 pathway. We demonstrate that a FGF23 c‐tail‐Fc fusion molecule selectively modulates the phosphate pathway in vivo by competitive antagonism of FGF23 binding to the FGFR/α klotho receptor complex. Repeated injection of FGF23 c‐tail Fc in Hyp mice, a preclinical model of XLH, increases cell surface abundance of kidney NaPi transporters, normalizes phosphate excretion, and significantly improves bone architecture in the absence of soft‐tissue mineralization. Repeated injection does not modulate either 1,25D or calcium in a physiologically relevant manner in either a wild‐type or disease setting. These data suggest that bone integrity can be improved in models of XLH via the exclusive modulation of phosphate. We posit that the selective modulation of the phosphate pathway will increase the window between efficacy and safety risks, allowing increased efficacy to be achieved in the treatment of this chronic disease. © 2017 American Society for Bone and Mineral Research.     

Klotho: an antiaging protein involved in mineral and vitamin D metabolism

Klotho gene mutation leads to a syndrome strangely resembling chronic kidney disease patients undergoing dialysis with multiple accelerated age-related disorders, including hypoactivity, sterility, skin thinning, muscle atrophy, osteoporosis, vascular calcifications, soft-tissue calcifications, defective hearing, thymus atrophy, pulmonary emphysema, ataxia, and abnormalities of the pituitary gland, as well as hypoglycemia, hyperphosphatemia, and paradoxically high-plasma calcitriol levels. Conversely, mice overexpressing klotho show an extended existence and a slow aging process through a mechanism that may involve the induction of a state of insulin and oxidant stress resistance. Two molecules are produced by the klotho gene, a membrane bound form and a circulating form. However, their precise biological roles and molecular functions have been only partly deciphered. Klotho can act as a circulating factor or hormone, which binds to a not yet identified high-affinity receptor and inhibits the intracellular insulin/insulin-like growth factor-1 (IGF-1) signaling cascade; klotho can function as a novel beta-glucuronidase, which deglycosylates steroid beta-glucuronides and the calcium channel transient receptor potential vallinoid-5 (TRPV5); as a cofactor essential for the stimulation of fibroblast growth factor (FGF) receptor by FGF23. The two last functions have propelled klotho to the group of key factors regulating mineral and vitamin D metabolism, and have also stimulated the interest of the nephrology community. The purpose of this review is to provide a nephrology-oriented overview of klotho and its potential implications in normal and altered renal function states.     

Role of fibroblast growth factor 23 in phosphate homeostasis and pathogenesis of disordered mineral metabolism in chronic kidney disease

The discovery of fibroblast growth factor 23 (FGF23), a novel bone-derived hormone that inhibits phosphate reabsorption and calcitriol production by the kidney, has uncovered primary regulatory pathways and new systems biology governing bone mineralization, vitamin D metabolism, parathyroid gland function and renal phosphate handling. This phosphaturic hormone, which is made predominately by osteocytes in bone, appears to have a physiologic role as a counter-regulatory hormone for vitamin D. Evidence has also emerged to support the existence of a bone-kidney axis to coordinate the mineralization of bone with renal handling of phosphate. Pathologically, high circulating levels of FGF23 result in hypophosphatemia, decreased production of 1,25(OH)(2)D, elevated parathyroid hormone and rickets/osteomalacia in patients with functioning kidneys, whereas low levels are associated with tumoral calcinosis, hyperphosphatemia and elevated 1,25(OH)(2)D. In addition, patients with chronic kidney disease (CKD) exhibit marked elevations of circulating FGF23. While the significance of increased FGF23 levels in CKD remains to be defined, it might contribute to phosphate excretion and suppression of 1,25(OH)(2)D levels in CKD stages 3 and 4, as well as potentially contribute to secondary hyperparathyroidism through direct actions on the parathyroid gland in more advanced renal failure. As our knowledge expands regarding the regulation and functions of FGF23, the assessment of FGF23 will become an important diagnostic marker as well as a therapeutic target for management of disordered mineral metabolism in a variety of acquired and hereditary disorders.     

Emerging role of fibroblast growth factor 23 in a bone-kidney axis regulating systemic phosphate homeostasis and extracellular matrix mineralization

PURPOSE OF REVIEW: To describe emerging understanding of fibroblast growth factor 23 (FGF23) - a bone-derived hormone that inhibits phosphate reabsorption and calcitriol production by kidney and participates as the principle phosphaturic factor in a bone-kidney axis coordinating systemic phosphate homeostasis and bone mineralization. RECENT FINDINGS: FGF23 (a circulating factor made by osteocytes in bone) inhibits phosphate reabsorption and 1,25(OH)2D production by kidney. Physiologically, FGF23 is a counter-regulatory phosphaturic hormone for vitamin D and coordinates systemic phosphate homeostasis with skeletal mineralization. Pathologically, high circulating FGF23 levels cause hypophosphatemia, decreased 1,25(OH)2D production, elevated parathyroid hormone and rickets/osteomalacia. FGF23 mutations impairing its degradation cause autosomal dominant hypophosphatemic rickets. Respective loss-of-function mutations of osteocyte gene products DMP1 and Phex cause autosomal recessive hypophosphatemic rickets and X-linked hypophosphatemic rickets, initiating increased FGF23 production. Low FGF23 levels lead to hyperphosphatemia, elevated 1,25(OH)2D, and soft-tissue calcifications. FGF23 is markedly increased in chronic renal disease, but its role remains undefined. SUMMARY: FGF23 discovery has uncovered primary regulatory pathways and new systems biology governing bone mineralization, vitamin D metabolism, parathyroid gland function, and renal phosphate handling. FGF23 assessment will become important in diagnosing hypophosphatemic and hyperphosphatemic disorders, for which pharmacological regulation of FGF23 levels may provide novel treatments.     

FGF-23 and vitamin D: don't shoot the messenger?

The discovery of fibroblast growth factor-23 (FGF-23) as a key regulator of phosphate and vitamin D metabolism has forced a rethink about the mineral and bone disorder of chronic kidney disease (CKD). FGF-23 powerfully predicts adverse cardiovascular outcomes in patients with CKD and an important question is whether treatment regimens should now be tailored to address FGF-23 levels in addition to those of calcium, phosphate, parathyroid hormone and vitamin D. Nevertheless, despite the known action of active vitamin D therapies to increase FGF-23, this should probably still form an important part of the management of patients with hyperparathyroidism and perhaps at low doses of essentially all patients with advanced renal disease.     

Effets pléïotropes du sévélamer,précurseur d’agent chélateur de la voie intestinale

The number of patients with chronic kidney disease (CKD) with its associated complications has increased dramatically worldwide in recent years. Therefore, many experimental and clinical studies have examined over the last decade the mechanisms involved, in order to explain the sharp increase in cardiovascular mortality. Hyperphosphatemia is a major problem in these patients especially at advanced stages of CKD, and it is associated with cardiovascular and mineral complications in these patients. Sevelamer is a phosphate binder that allows a better control of hyperphosphatemia, like other phosphate binder agents, but it has additional pleiotropic effects such as correcting certain abnormalities of lipid metabolism and clearance of several uremic toxins. These effects of sevelamer, restricted to the intestinal lumen, underline the importance of intestinal pathway in CKD and open the way to new therapeutic strategies for the management of the CKD and its complications.     

Rationale and Approaches to Phosphate and Fibroblast Growth Factor 23 Reduction in CKD

Patients with CKD often progress to ESRD and develop cardiovascular disease (CVD), yet available therapies only modestly improve clinical outcomes. Observational studies report independent associations between elevated serum phosphate and fibroblast growth factor 23 (FGF23) levels and risks of ESRD, CVD, and death. Phosphate excess induces arterial calcification, and although elevated FGF23 helps maintain serum phosphate levels in the normal range in CKD, it may contribute mechanistically to left ventricular hypertrophy (LVH). Consistent epidemiologic and experimental findings suggest the need to test therapeutic approaches that lower phosphate and FGF23 in CKD. Dietary phosphate absorption is one modifiable determinant of serum phosphate and FGF23 levels. Limited data from pilot studies in patients with CKD stages 3–4 suggest that phosphate binders, low phosphate diets, or vitamin B3 derivatives, such as niacin or nicotinamide, may reduce dietary phosphate absorption and serum phosphate and FGF23 levels. This review summarizes current knowledge regarding the deleterious systemic effects of phosphate and FGF23 excess, identifies questions that must be addressed before advancing to a full-scale clinical outcomes trial, and presents a novel therapeutic approach to lower serum phosphate and FGF23 levels that will be tested in the COMBINE Study: The CKD Optimal Management With BInders and NicotinamidE study.     

Hypophosphatemic Rickets: Revealing Novel Control Points for Phosphate Homeostasis

Rapid and somewhat surprising advances have recently been made toward understanding the molecular mechanisms causing heritable disorders of hypophosphatemia. The results of clinical, genetic, and translational studies have interwoven novel concepts underlying the endocrine control of phosphate metabolism, with far-reaching implications for treatment of both rare Mendelian diseases as well as common disorders of blood phosphate excess such as chronic kidney disease (CKD). In particular, diseases caused by changes in the expression and proteolytic control of the phosphaturic hormone fibroblast growth factor-23 (FGF23) have come to the forefront in terms of directing new models explaining mineral metabolism. These hypophosphatemic disorders as well as others resulting from independent defects in phosphate transport or metabolism will be reviewed herein, and implications for emerging therapeutic strategies based upon these new findings will be discussed.     

Phosphate in early chronic kidney disease: associations with clinical outcomes and a target to reduce cardiovascular risk

There is an intimate association between mineral and bone disorders in chronic kidney disease (CKD) and the extensive burden of cardiovascular disease (CVD) in this population. High phosphate levels in CKD have been associated with increased all-cause mortality and cardiovascular morbidity and mortality. Observational studies have also shown a consistent relationship between serum phosphate in the normal range and all-cause and cardiovascular mortality, left ventricular hypertrophy (LVH) and decline in renal function. Furthermore, fibroblast growth factor-23 (FGF-23), a phosphaturic hormone, increases very early in the course of CKD and is strongly associated with death and CVD, including LVH and vascular calcification. Few studies have addressed outcomes using interventions to reduce serum phosphate in a randomized controlled fashion; however, strategies to address cardiovascular risk in early CKD are imperative and phosphate is a potential therapeutic target. This review outlines the epidemiological and experimental evidence highlighting the relationship between excess phosphate and adverse outcomes, and discusses clinical studies required to address this problem.     

Pathophysiology of Calcium,Phosphorus, and Magnesium Dysregulation in Chronic Kidney Disease

Calcium, phosphorus, and magnesium homeostasis is altered in chronic kidney disease (CKD). Hypocalcemia, hyperphosphatemia, and hypermagnesemia are not seen until advanced CKD because adaptations develop. Increased parathyroid hormone (PTH) secretion maintains serum calcium normal by increasing calcium efflux from bone, renal calcium reabsorption, and phosphate excretion. Similarly, renal phosphate excretion in CKD is maintained by increased secretion of fibroblast growth factor 23 (FGF23) and PTH. However, the phosphaturic effect of FGF23 is reduced by downregulation of its cofactor Klotho necessary for binding FGF23 to FGF receptors. Intestinal phosphate absorption is diminished in CKD due in part to reduced levels of 1,25 dihydroxyvitamin D. Unlike calcium and phosphorus, magnesium is not regulated by a hormone, but fractional excretion of magnesium increases as CKD progresses. As 60–70% of magnesium is reabsorbed in the thick ascending limb of Henle, activation of the calcium‐sensing receptor by magnesium may facilitate magnesium excretion in CKD. Modification of the TRPM6 channel in the distal tubule may also have a role. Besides abnormal bone morphology and vascular calcification, abnormalities in mineral homeostasis are associated with increased cardiovascular risk, increased mortality and progression of CKD.     

慢性肾脏病患者心血管钙化的影响因素分析

慢性肾脏病(chronic kidney disease,CKD)患者因高龄、高血压、高血脂、糖尿病、吸烟、男性等传统心血管钙化危险因素,加上CKD特有因素:矿物质代谢紊乱、含钙磷结合剂及活性维生素D的不合理使用、微炎症状态、氧化应激等常引起严重的心血管钙化,病情进一步发展会加速心血管事件的发生,影响CKD患者的预后。使用磷结合剂、活性维生素D及其类似物、西那卡塞等药物控制高钙、高磷、高PTH对预防心血管钙化至关重要。药物治疗无效或在治疗过程中出现不能控制的矿物质代谢异常,则要考虑手术切除甲状旁腺。甲状旁腺切除术(parathyroidectomy,PTX)作为难治性继发性甲状旁腺功能亢进患者的有效治疗之一,可迅速降低甲状旁腺素(parathyroid hormone,PTH)和血清钙磷水平,减少活性维生素D等药物的使用,缓解骨痛、瘙痒、肌无力等症状,但PTX后是否可以减轻心血管钙化?术后长期的低PTH状态与心血管钙化的关系如何?目前还没有明确的结论,本文就CKD患者心血管钙化的影响因素,尤其是PTX对CKD患者心血管钙化的影响作一综述。