Low-density lipoprotein receptor-related protein 5 is a protein that in humans is encoded by the LRP5 gene. [5] [6] [7] LRP5 is a key component of the LRP5/ LRP6/ Frizzled co-receptor group that is involved in canonical Wnt pathway. Mutations in LRP5 can lead to considerable changes in bone mass. A loss-of-function mutation causes osteoporosis pseudoglioma syndrome with a decrease in bone mass, while a gain-of-function mutation causes drastic increases in bone mass.
LRP5 is a transmembrane low-density lipoprotein receptor that shares a similar structure with LRP6. In each protein, about 85% of its 1600- amino-acid length is extracellular. Each has four β-propeller motifs at the amino terminal end that alternate with four epidermal growth factor (EGF)-like repeats. Most extracellular ligands bind to LRP5 and LRP6 at the β-propellers. Each protein has a single-pass, 22-amino-acid segment that crosses the cell membrane and a 207-amino-acid segment that is internal to the cell. [8]
LRP5 acts as a co-receptor with LRP6 and the Frizzled protein family members for transducing signals by Wnt proteins through the canonical Wnt pathway. [8] This protein plays a key role in skeletal homeostasis. [7]
The LRP5 promoter contains binding sites for KLF15 and SP1. [9] In addition, 5' region of the LRP5 gene contains four RUNX2 binding sites. [10] LRP5 has been shown in mice and humans to inhibit expression of TPH1, the rate-limiting biosynthetic enzyme for serotonin in enterochromaffin cells of the duodenum [11] [12] [13] [14] [15] [16] and that excess plasma serotonin leads to inhibition in bone. On the other hand, one study in mouse has shown a direct effect of Lrp5 on bone. [17]
LRP5 has been shown to interact with AXIN1. [18] [19]
Canonical WNT signals are transduced through Frizzled receptor and LRP5/ LRP6 coreceptor to downregulate GSK3beta ( GSK3B) activity not depending on Ser-9 phosphorylation. [20] Reduction of canonical Wnt signals upon depletion of LRP5 and LRP6 results in p120- catenin degradation. [21]
The Wnt signaling pathway was first linked to bone development when a loss-of-function mutation in LRP5 was found to cause osteoporosis-pseudoglioma syndrome. [22] Shortly thereafter, two studies reported that gain-of-function mutations in LRP5 caused high bone mass. [23] [24] Many bone density related diseases are caused by mutations in the LRP5 gene. There is controversy whether bone grows through Lrp5 through bone or the intestine. [25] The majority of the current data supports the concept that bone mass is controlled by LRP5 through the osteocytes. [26] Mice with the same Lrp5 gain-of-function mutations as also have high bone mass. [27] The high bone mass is maintained when the mutation only occurs in limbs or in cells of the osteoblastic lineage. [17] Bone mechanotransduction occurs through Lrp5 [28] and is suppressed if Lrp5 is removed in only osteocytes. [29] There are promising osteoporosis clinical trials targeting sclerostin, an osteocyte-specific protein which inhibits Wnt signaling by binding to Lrp5. [26] [30] An alternative model that has been verified in mice and in humans is that Lrp5 controls bone formation by inhibiting expression of TPH1, the rate-limiting biosynthetic enzyme for serotonin, a molecule that regulates bone formation, in enterochromaffin cells of the duodenum [11] [12] [13] [14] [15] [16] and that excess plasma serotonin leads to inhibition in bone. Another study found that a different Tph1-inhibitor decreased serotonin levels in the blood and intestine, but did not affect bone mass or markers of bone formation. [17]
LRP5 may be essential for the development of retinal vasculature, and may play a role in capillary maturation. [31] Mutations in this gene also cause familial exudative vitreoretinopathy. [7]
A glial-derived extracellular ligand, Norrin, acts on a transmembrane receptor, Frizzled4, a coreceptor, Lrp5, and an auxiliary membrane protein, TSPAN12, on the surface of developing endothelial cells to control a transcriptional program that regulates endothelial growth and maturation. [32]
LRP5 knockout in mice led to increased plasma cholesterol levels on a high-fat diet because of the decreased hepatic clearance of chylomicron remnants. When fed a normal diet, LRP5-deficient mice showed a markedly impaired glucose tolerance with marked reduction in intracellular ATP and Ca2+ in response to glucose, and impairment in glucose-induced insulin secretion. IP3 production in response to glucose was also reduced in LRP5—islets possibly caused by a marked reduction of various transcripts for genes involved in glucose sensing in LRP5—islets. LRP5-deficient islets lacked the Wnt-3a-stimulated insulin secretion. These data suggest that WntLRP5 signaling contributes to the glucose-induced insulin secretion in the islets. [33]
In osteoarthritic chondrocytes the Wnt/beta-catenin pathway is activated with a significant up-regulation of beta-catenin mRNA expression. LRP5 mRNA and protein expression are also significantly up-regulated in osteoarthritic cartilage compared to normal cartilage, and LRP5 mRNA expression was further increased by vitamin D. Blocking LRP5 expression using siRNA against LRP5 resulted in a significant decrease in MMP13 mRNA and protein expressions. The catabolic role of LRP5 appears to be mediated by the Wnt/beta-catenin pathway in human osteoarthritis. [34]
The polyphenol curcumin increases the mRNA expression of LRP5. [35]
Mutations in LRP5 cause polycystic liver disease. [36]
This article incorporates text from the United States National Library of Medicine, which is in the public domain.
LRP5 | |||||||||||||||||||||||||||||||||||||||||||||||||||
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Aliases | LRP5, BMND1, EVR1, EVR4, HBM, LR3, LRP-5, LRP7, OPPG, OPS, OPTA1, VBCH2, LDL receptor related protein 5, PCLD4, LRP-7 | ||||||||||||||||||||||||||||||||||||||||||||||||||
External IDs | OMIM: 603506 MGI: 1278315 HomoloGene: 1746 GeneCards: LRP5 | ||||||||||||||||||||||||||||||||||||||||||||||||||
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Low-density lipoprotein receptor-related protein 5 is a protein that in humans is encoded by the LRP5 gene. [5] [6] [7] LRP5 is a key component of the LRP5/ LRP6/ Frizzled co-receptor group that is involved in canonical Wnt pathway. Mutations in LRP5 can lead to considerable changes in bone mass. A loss-of-function mutation causes osteoporosis pseudoglioma syndrome with a decrease in bone mass, while a gain-of-function mutation causes drastic increases in bone mass.
LRP5 is a transmembrane low-density lipoprotein receptor that shares a similar structure with LRP6. In each protein, about 85% of its 1600- amino-acid length is extracellular. Each has four β-propeller motifs at the amino terminal end that alternate with four epidermal growth factor (EGF)-like repeats. Most extracellular ligands bind to LRP5 and LRP6 at the β-propellers. Each protein has a single-pass, 22-amino-acid segment that crosses the cell membrane and a 207-amino-acid segment that is internal to the cell. [8]
LRP5 acts as a co-receptor with LRP6 and the Frizzled protein family members for transducing signals by Wnt proteins through the canonical Wnt pathway. [8] This protein plays a key role in skeletal homeostasis. [7]
The LRP5 promoter contains binding sites for KLF15 and SP1. [9] In addition, 5' region of the LRP5 gene contains four RUNX2 binding sites. [10] LRP5 has been shown in mice and humans to inhibit expression of TPH1, the rate-limiting biosynthetic enzyme for serotonin in enterochromaffin cells of the duodenum [11] [12] [13] [14] [15] [16] and that excess plasma serotonin leads to inhibition in bone. On the other hand, one study in mouse has shown a direct effect of Lrp5 on bone. [17]
LRP5 has been shown to interact with AXIN1. [18] [19]
Canonical WNT signals are transduced through Frizzled receptor and LRP5/ LRP6 coreceptor to downregulate GSK3beta ( GSK3B) activity not depending on Ser-9 phosphorylation. [20] Reduction of canonical Wnt signals upon depletion of LRP5 and LRP6 results in p120- catenin degradation. [21]
The Wnt signaling pathway was first linked to bone development when a loss-of-function mutation in LRP5 was found to cause osteoporosis-pseudoglioma syndrome. [22] Shortly thereafter, two studies reported that gain-of-function mutations in LRP5 caused high bone mass. [23] [24] Many bone density related diseases are caused by mutations in the LRP5 gene. There is controversy whether bone grows through Lrp5 through bone or the intestine. [25] The majority of the current data supports the concept that bone mass is controlled by LRP5 through the osteocytes. [26] Mice with the same Lrp5 gain-of-function mutations as also have high bone mass. [27] The high bone mass is maintained when the mutation only occurs in limbs or in cells of the osteoblastic lineage. [17] Bone mechanotransduction occurs through Lrp5 [28] and is suppressed if Lrp5 is removed in only osteocytes. [29] There are promising osteoporosis clinical trials targeting sclerostin, an osteocyte-specific protein which inhibits Wnt signaling by binding to Lrp5. [26] [30] An alternative model that has been verified in mice and in humans is that Lrp5 controls bone formation by inhibiting expression of TPH1, the rate-limiting biosynthetic enzyme for serotonin, a molecule that regulates bone formation, in enterochromaffin cells of the duodenum [11] [12] [13] [14] [15] [16] and that excess plasma serotonin leads to inhibition in bone. Another study found that a different Tph1-inhibitor decreased serotonin levels in the blood and intestine, but did not affect bone mass or markers of bone formation. [17]
LRP5 may be essential for the development of retinal vasculature, and may play a role in capillary maturation. [31] Mutations in this gene also cause familial exudative vitreoretinopathy. [7]
A glial-derived extracellular ligand, Norrin, acts on a transmembrane receptor, Frizzled4, a coreceptor, Lrp5, and an auxiliary membrane protein, TSPAN12, on the surface of developing endothelial cells to control a transcriptional program that regulates endothelial growth and maturation. [32]
LRP5 knockout in mice led to increased plasma cholesterol levels on a high-fat diet because of the decreased hepatic clearance of chylomicron remnants. When fed a normal diet, LRP5-deficient mice showed a markedly impaired glucose tolerance with marked reduction in intracellular ATP and Ca2+ in response to glucose, and impairment in glucose-induced insulin secretion. IP3 production in response to glucose was also reduced in LRP5—islets possibly caused by a marked reduction of various transcripts for genes involved in glucose sensing in LRP5—islets. LRP5-deficient islets lacked the Wnt-3a-stimulated insulin secretion. These data suggest that WntLRP5 signaling contributes to the glucose-induced insulin secretion in the islets. [33]
In osteoarthritic chondrocytes the Wnt/beta-catenin pathway is activated with a significant up-regulation of beta-catenin mRNA expression. LRP5 mRNA and protein expression are also significantly up-regulated in osteoarthritic cartilage compared to normal cartilage, and LRP5 mRNA expression was further increased by vitamin D. Blocking LRP5 expression using siRNA against LRP5 resulted in a significant decrease in MMP13 mRNA and protein expressions. The catabolic role of LRP5 appears to be mediated by the Wnt/beta-catenin pathway in human osteoarthritis. [34]
The polyphenol curcumin increases the mRNA expression of LRP5. [35]
Mutations in LRP5 cause polycystic liver disease. [36]
This article incorporates text from the United States National Library of Medicine, which is in the public domain.