Fibroblast Growth Factor-23-A Potential Uremic Toxin.

Fibroblast growth factor-23 (FGF23) is a circulating member of the FGF family produced mainly by the osteocytes and osteoblasts that can act as a hormone. The main action of FGF23 is to lower phosphatemia via the reduction of urinary phosphate reabsorption and the decrease of 1,25(OH)2-D generation in the kidney. In the course of chronic kidney disease (CKD), plasma FGF23 concentration rises early, most probably to compensate the inability of the deteriorating kidneys to excrete an adequate amount of phosphate. However, this comes at the cost of FGF23-related target organ toxicity. Results of clinical studies suggest that elevated plasma FGF23 concentration is independently associated with the increased risk of CKD progression, occurrence of cardio-vascular complications, and mortality in different stages of CKD. FGF23 also contributes to cardiomyocyte hypertrophy, vascular calcification, and endothelial dysfunction. The impact of FGF23 on heart muscle is not dependent on Klotho, but rather on the PLCγ-calcineurin-NFAT (nuclear factor of activated T-cells) pathway. Among the factors increasing plasma FGF23 concentration, active vitamin D analogues play a significant role. Additionally, inflammation and iron deficiency can contribute to the increase of plasma FGF23. Among the factors decreasing plasma FGF23, dietary phosphate restriction, some intestinal phosphate binders, cinacalcet (and other calcimimetics), and nicotinamide can be enumerated. Anti-FGF23 antibodies have also recently been developed to inhibit the action of FGF23 in target organs. Still, the best way to normalize plasma FGF23 in maintenance hemodialysis patients is restoring kidney function by successful kidney transplantation.

Long-lasting hypoglycemic effect of modified FGF-21 analog with polyethylene glycol in type 1 diabetic mice and its systematic toxicity.

Fibroblast growth factor-21 (FGF-21) is a novel metabolic regulator and has the potential to become a powerful therapy to treat diabetes mellitus. However, we found that the clinical application of wild type FGF-21 was influenced by its low intrinsic bio-stability and poor hypoglycemic potency. In this study, The N-terminus of FGF-21 analog (mFGF-21) was PEGylated in a site-specific manner by 20kD methoxy poly-ethylene glycol-propionaldehyde (mPEG-ALD). PEGylated mFGF-21 was isolated by Capto Q anion exchange chromatography. The properties of PEGylated mFGF-21 including the in vitro bio-stability and biological activity were evaluated. As well as the anti-diabetic effect of PEGylated mFGF-21 were studied in streptozotocin (STZ)-induced type 1 diabetic mice. Results demonstrated that PEGylated mFGF-21 had a similar capacity of stimulating glucose uptake in HepG2 cells with mFGF-21 and PEGylation of mFGF-21 significantly enhanced the anti-protease ability and the long acting anti-diabetic effect in type 1 diabetic mice. Furthermore, the preliminary safety of PEGylated mFGF-21 following subcutaneously injection was assessed using healthy mice by measuring the body weight, histopathology and clinical biochemical parameters, and the results showed no subacute toxicity to major organs or tissues and no significant changes in physiological and biochemical parameters in healthy mice. Taken together, under the premise of remaining the in vitro biological activity of mFGF-21, PEGylation significantly improves the long lasting hypoglycemic effect of mFGF-21 in type 1 diabetic mice. Our valuation shows that PEGylated mFGF-21 is a potential drug for the effective treatment of type 1 diabetes.

Targeting an acid labile aspartyl-prolyl amide bond as a viable alternative to trypsin digestion to generate a surrogate peptide for LC-MS/MS analysis.

BACKGROUND: FGF21-AdPKE is a fusion protein and functionally inactivated in vivo by cleavage around the C-terminus. It is important to quantify the intact active protein in serum. RESULTS & DISCUSSION: Taking advantage of a uniquely acid-labile aspartyl-prolyl amide bond, we developed an acid hydrolysis procedure based on heating FGF21-AdPKE in dilute formic acid to generate a surrogate peptide encompassing the last 17 amino acids at the C-terminus. The monkey serum samples were extracted with an immunocapture procedure with an antibody specific for AdPKE. The calibration range was 200-50000 ng/ml. The assay accuracy and precision were between 92.8-99.8% and 3.9-14.5%, respectively. The method was applied to analyze incurred serum samples from a cynomolgus monkey toxicokinetic study involving administration of FGF21-AdPKE. CONCLUSION: A method of combining immunocapture and acid hydrolysis to quantify a therapeutic protein in biological fluids was developed.

Fibroblast growth factor 23 and uremic vascular calcification: is it time to escalate from biomarker status to pathogenic agent?

Although epidemiologic associations have been informative, the elucidation of the role of fibroblast growth factor 23 (FGF23) in chronic kidney disease (CKD) requires testing with robust experimental models. Jimbo et al. used animal and cell-culture models to query whether FGF23 is a direct 'vasculotoxin.' We discuss the interpretation of their findings. At this juncture, much remains unanswered about the significance of FGF23 elevation in CKD.

Fibroblast growth factor 23 accelerates phosphate-induced vascular calcification in the absence of Klotho deficiency.

Fibroblast growth factor 23 (FGF23) is a phosphate-regulating hormone that acts primarily on the kidney and parathyroid. With declining kidney function there is an increase in circulating FGF23 levels, which is associated with vascular calcification and mortality in chronic kidney disease. Whether FGF23 exerts direct effects on vasculature is unclear. We evaluated the expression of Klotho and FGF receptors in rat aortic rings and rat aorta vascular smooth muscle cells maintained in culture by reverse transcription-PCR, western blotting, and immunostaining. Signaling pathways underlying FGF23 effects were assessed by western blotting, and effects of FGF23 on osteogenic markers and phosphate transporters were assessed by real-time reverse transcription-PCR. We detected Klotho and FGFR1 in total aorta but not in vascular smooth muscle cells. FGF23 augmented phosphate-induced vascular calcification in the aortic rings from uremic rats and dose dependently increased ERK1/2 phosphorylation in Klotho-overexpressing but not naive vascular smooth muscle cells. FGF23-induced ERK1/2 phosphorylation was inhibited by SU5402 (FGFR1 inhibitor) and U0126 (MEK inhibitor). FGF23 enhanced phosphate-induced calcification in Klotho-overexpressing vascular smooth muscle cells and increased osteoblastic marker expression, which was inhibited by U0126. In contrast, phosphate transporter expression was not affected by phosphate or FGF23. Thus, FGF23 enhances phosphate-induced vascular calcification by promoting osteoblastic differentiation involving the ERK1/2 pathway.

FGF23-induced hypophosphatemia persists in Hyp mice deficient in the WNT coreceptor Lrp6.

Deregulated phosphate homeostasis can lead to a wide range of disorders, including myopathy, cardiac dysfunction, and skeletal abnormalities. Therefore, characterization of the molecular regulation of phosphate metabolism is of pathophysiological and clinical significance. Hyp mouse is the model for human X-linked hypophosphatemia which is due to mutations that inactivate the endopeptidases of the X chromosome (PHEX). PHEX inactivation leads to increased serum levels of fibroblast growth factor 23 (FGF23), a phosphaturic hormone that induces excessive renal phosphate excretion and severe hypophosphatemia. The expression of WNT signaling components is increased in Hyp mice. To determine the potential role of WNT signaling in FGF23-mediated hypophosphatemia, we cross-bred Hyp mice with mice deficient in the WNT coreceptor low-density lipoprotein receptor-related protein 6 (Lrp6) to generate Hyp and Lrp6 double mutant mice (Hyp/Lrp6). Like Hyp mice, Hyp/Lrp6 double mutants maintained high serum levels of FGF23, and accordingly exhibited hypophosphatemia to the same degree as the Hyp mice did, indicating that genetically reducing WNT signaling does not impact FGF23-induced phosphaturia. Moreover, similar to Hyp mice, the Hyp/Lrp6 double mutants also exhibited reduced mineralization of the bone, further supporting that reduced WNT signaling does not affect the chronic phosphate wasting caused by excess FGF23 in these mice. In further support of our finding, injection of bioactive FGF23 protein into Lrp6 mutant mice reduced serum phosphate levels to a similar degree as FGF23 injection into wild-type mice. Our in vivo studies provide genetic and pharmacological evidence for a WNT-independent function of FGF23 in the regulation of phosphate homeostasis.

Chitosan nanoparticles as a dual growth factor delivery system for tissue engineering applications.

Growth factors are essential in cellular signaling for migration, proliferation, differentiation and maturation. Sustainable delivery of therapeutic as well as functional proteins is largely required in the pharmacological and regenerative medicine. Here we have prepared chitosan nanoparticles (CNP) and incorporated growth factors such as epidermal growth factor (EGF) and fibroblast growth factor (FGF), either individually or in combination, which could ultimately be impregnated into engineered tissue construct. CNP was characterized by Fourier transform infrared (FTIR) spectroscopy, Zeta sizer and high resolution transmission electron microscope (HRTEM). The particles were in the size range of 50-100 nm with round and flat shape. The release kinetics of both EGF and FGF incorporated CNP showed the release of growth factors in a sustained manner. Growth factors incorporated nanoparticles did not show any toxicity against fibroblasts up to 4 mg/ml culture medium. Increased proliferation of fibroblasts in vitro evidenced the delivery of growth factors from CNP for cellular signaling. Western blotting results also revealed the poor inflammatory response showing less expression of proinflammatory cytokines such as IL-6 and TNFα in the macrophage cell line J774 A-1.

Topical application of methotrexate for inhibition of corneal angiogenesis.

PURPOSE: Methotrexate (MTX) is a folic acid antagonist used in chemotherapy regimens. Additional therapeutic applications have been suggested based on effect as an immuno-modulating drug in systemic rheumatoid disease and associated uveitis. Since chronic inflammatory disease is often associated with a neovascular response, we investigated the use of MTX for treatment of corneal angiogenesis. METHODS: Neovascularizations were induced by fibroblast growth factor in a corneal pocket model. Vessels were examined biomicroscopically. MTX was applied topically to rabbit corneas in a concentration of 0.2 mg/day. MTX level was measured in aqueous humor and plasma. RESULTS: On day 9 the vascularized area was 12.0+/-6.9 mm(2) in control eyes and significantly smaller, 2. 2+/-1.86 mm(2), in treated eyes. Treated animals showed no local side effects such as epithelial defects. Although therapeutic levels were measured in the aqueous humor, MTX could not be detected in the serum of treated animals. CONCLUSION: The antiangiogenic mechanism of MTX might be due to inhibition of both macrophage invasion during early angiogenesis and endothelial cell proliferation. The high levels in the aqueous humor indicate a possible application of topical MTX for inflammations of the anterior segment of the eye.

Fibroblast-growth-factor-induced additional limbs in the study of initiation of limb formation, limb identity, myogenesis, and innervation.

In this review, we focus on the additional limb induced by members of the fibroblast growth factor (FGF) family in the flank of chick embryos. The "additional limb" was first reported 73 years ago by Balinsky in 1925. He grafted otic vesicle to the flank of newt embryos and observed the formation of the "additional limb." In 1995, formation of an additional limb was found to be induced by FGF in the chick embryo. This finding subsequently led to the recent understanding of how the limb bud is initially formed, how the limb position is determined, and how the limb identity is determined. Thus, the additional limb has been recognized as a useful experimental system for the study of limb development and its relation to the regionalization of the body. Furthermore, since limb muscles are formed from cells which have migrated from somites and innervation to them takes place from the spinal cord, the additional limb would also be a powerful tool with which to study the relation of limb morphogenesis to developmental processes of the spinal cord and somites. This review consists of five sections: (1) "Introduction," (2) "How to make additional limbs," (3) "Characteristics of the additional limb," (4) "Studies with the additional limb," and (5) "Concluding remarks." In the second section, techniques to make additional limbs are reviewed, showing that additional limbs can be made by fairly easy manipulation of the chick embryo. In the third section, the characteristics analyzed so far of the additional limb are summarized, focusing on its morphology. In the fourth section, recent studies on the use of the additional limb are reviewed: experiments on the additional limb have been performed to elucidate the mechanisms governing determination of limb identity by Hox codes and the Tbx family and initiation of limb formation by FGF10. In addition, the roles of SF/HGF in the formation of limb muscles have also been investigated using the additional limb. In the near future, the additional limb will be also used in the study of innervation from the spinal cord, and probably migration of neural crest cells.

The stimulation of neo-angiogenesis in the ischemic heart by the human growth factor FGF.

BACKGROUND: The present article deals with the conduct of our animal experiments with the human growth factor FGF (fibroblast growth factor) and the results obtained therefrom. METHODS: In order to establish the angiogenetic potential of FGF, this factor was first obtained from a genetically transformed strain of E. Coli, and then isolated and highly purified. Afterwards the growth factor FGF has been used in several in vitro- and in vivo experiments in order to prove its influence on neo-angiogenesis in ischemic tissue. RESULTS: In cultures of endothelial cells from the human great saphenous vein it has been possible to stimulate growth successfully with FGF obtained in this way, and a further increase in its action was brought about by the addition of heparin. In tritium-thymidine assays, the endothelial cell stimulating action of FGF was confirmed. It could also be shown angiographically that administering FGF to the ischemic myocardium of these animals initiates the development of new vessels, and we could demonstrate that a myocardial capillary network sprouting directly from the coronary vessels themselves can establish an alternative blood flow. These results were confirmed histologically by the significantly greater capillary density which appeared following the use of the growth factor. CONCLUSIONS: By using the human growth factor FGF, we have been able for the first time to understand the physiological processes of angiogenesis as they come into play during wound healing or the development of collaterals following tissue ischemia, and to use this knowledge for the production of new vessels in the ischemic hearts of rats and rabbits. Decisive for the future use of the factor in human patients -- particularly for the treatment of coronary heart disease (CHD) are the results of experimental investigations designed to exclude the possibility of the growth factor initiating or stimulating neoplasia.

Chemotaxis of human osteoblasts. Effects of osteotropic growth factors.

The in vitro chemotactic response of human osteoblasts was investigated towards the following growth factors: TGF-beta, PDGFs, FGFs and IGFs. Human osteoblasts grown from trabecular bone after enzymatic digestion were studied. TGF-beta stimulated the migration of human osteoblasts in a dose-dependent manner with a four-fold increase in migrated cells at 100 pg/ml, which was the optimum concentration. PDGF-BB also stimulated migration four-fold in a dose-dependent manner with a maximum response at 10 ng/ml. PDGF-AA, IGF-I and IGF-II stimulated migration two-fold at 100 ng/ml. The results show that TGF-beta and PDGF-BB are important regulators of human osteoblast migration, but other growth factors IGF-I, IGF-II and PDGF-AA may also stimulate osteoblast migration. Our results additionally suggest that TGF-beta and PDGF-BB may participate in the recruitment of osteoblasts during bone remodeling since both TGF-beta and PDGF-BB are found in bone matrix and could be released during osteoclastic bone resorption. They furthermore support a possible use of TGF-beta and PDGF-BB in growth factor-induced osteogenesis.

Biological and chemical characterization of basic FGF-saporin mitotoxin.

Basic fibroblast growth factor (FGF) and saporin-6, a ribosome-inactivating protein, were chemically conjugated and characterized as a cytotoxin to cells expressing the basic FGF receptor. Structural and Western blot analysis of the conjugate showed that it contained saporin and basic FGF in equimolar amounts. The conjugate inhibited protein synthesis in a cell-free system and had potent cytotoxic activity (ID50 = 25pM) for cells expressing the basic FGF receptor. It is equipotent with basic FGF in radioreceptor assays and elutes from heparin Sepharose columns with 2M NaCl. The activity of the mitotoxin can be inhibited by competition with an excess of basic FGF but not nerve growth factor. The possibility that this mitotoxin can be used as an anti-angiogenic factor in paradigms that involve basic FGF is discussed.