VLDL receptor

Last updated
VLDLR
PDB 1v9u EBI.jpg
Available structures
PDB Ortholog search: PDBe RCSB
Identifiers
Aliases VLDLR , CAMRQ1, CARMQ1, CHRMQ1, VLDLRCH, VLDL-R, very low density lipoprotein receptor
External IDs OMIM: 192977 MGI: 98935 HomoloGene: 443 GeneCards: VLDLR
Orthologs
SpeciesHumanMouse
Entrez
Ensembl
UniProt
RefSeq (mRNA)

NM_001018056
NM_003383
NM_001322225
NM_001322226

NM_001161420
NM_013703
NM_001347441

RefSeq (protein)

NP_001018066
NP_001309154
NP_001309155
NP_003374

NP_001154892
NP_001334370
NP_038731

Location (UCSC) Chr 9: 2.62 – 2.66 Mb Chr 19: 27.22 – 27.25 Mb
PubMed search [3] [4]
Wikidata
View/Edit Human View/Edit Mouse

The very-low-density-lipoprotein receptor (VLDLR) is a transmembrane lipoprotein receptor of the low-density-lipoprotein (LDL) receptor family. VLDLR shows considerable homology with the members of this lineage. Discovered in 1992 by T. Yamamoto, VLDLR is widely distributed throughout the tissues of the body, including the heart, skeletal muscle, adipose tissue, and the brain, but is absent from the liver. [5] This receptor has an important role in cholesterol uptake, metabolism of apolipoprotein E-containing triacylglycerol-rich lipoproteins, and neuronal migration in the developing brain. In humans, VLDLR is encoded by the VLDLR gene. Mutations of this gene may lead to a variety of symptoms and diseases, which include type I lissencephaly, cerebellar hypoplasia, and atherosclerosis.

Contents

Protein structure

VLDLR is a member of the low-density-lipoprotein (LDL) receptor family, which is entirely composed of type I transmembrane lipoprotein receptors.

The structural differences of the LDL receptor family. This image represents the similarities in structural domains among the members, as well as the extra cysteine repeat present on the VLDL receptor. Structure of LDL receptor family members.png
The structural differences of the LDL receptor family. This image represents the similarities in structural domains among the members, as well as the extra cysteine repeat present on the VLDL receptor.

All members of this family share five highly conserved structural domains: an extracellular N-terminal ligand-binding domain with cysteine-rich repeats (also called ligand-binding repeats), an epidermal growth factor (EGF), an O-linked glycosylation sugar domain, a single transmembrane sequence, and a cytoplasmic domain which contains an NPxY sequence. The NPxY motif functions in signal transduction and the targeting of receptors to coated pits and consists of the sequence Asparagine-Proline-X-Tyrosine, where X can be any amino acid. [6] Mimicking this general structure, VLDLR has eight, 40 amino acid long cysteine-rich repeats in its extracellular N-terminal ligand-binding domain. [6] This is the main difference from the main member of the LDL receptor family, LDLR, which has only seven cysteine-rich repeats which are also 40 amino acids long. [7] Each of these cysteine-rich repeats, in both VLDLR and LDLR, has three disulfide bonds and a coordinated Ca2+ ion. The N-terminus also consists of a glycine residue followed by 27 hydrophobic residues that constitute the signal peptide. [6] Following this region is an EGF repeat, a β-propeller segment that plays a role in the pH-dependent dissociation of the ligand-receptor complex, [8] and two more EGF repeats. [9] The VLDLR O-linked glycosylation domain, next in the sequence, has many threonine and serine residues and totals 46 amino acids. The transmembrane domain, which functions in anchoring the receptors to the membrane, is 22 amino acids long. [6] Final in the sequence is the 54 amino acid cytoplasmic domain, which contains the NPxY motif. [8]

Isoforms

The full-length human VLDLR genome is located on locus 9p24 on chromosome 9. It consists of a 40 kb segment that includes 19 exon-coding sequences, which is one more exon than encoded by LDLR. This extra exon in the VLDLR gene accounts for the extra cysteine-binding repeat not found in LDLR. [7] Together, the exons making up the VLDLR gene encode a protein that is 873 amino acid residues long. VLDLR is known to exist as four different protein isoforms: type I, II, III, and IV. These different isoforms result from variations in alternative splicing. The transcript of type I VLDLR (VLDLR-I) is composed of all 19 exons. VLDLR-II, on the other hand, lacks exon 16, which encodes for the O-glycosylation domain between sugar regions. VLDLR-III lacks exon 4 that encodes the third ligand-binding repeat. Finally, VLDLR-IV transcripts lack both exon 16 and exon 4. It has been shown that 75% of VLDLR transcripts exist as isoform type II in mouse brain models. This shows that most VLDLRs in the brain are not glycosylated, as type II lacks exon 16 which encodes the O-glycosylation domain. Isoform type IV is known to be the second most prominent. [6]

Evolutionary conservation

There is a high level of conservation within the LDL receptor family. In particular, there is 50% overall sequence homology between VLDLR and ApoER2, another lipoprotein receptor of this family. [6] Comparing LDLR and VLDLR, it was found that their primary structures are 55% identical within their ligand-binding regions. The modular structures of these two proteins are almost superimposable, with the only difference being the additional cysteine-rich repeat in VLDLR. This is demonstrated through the alignment of the two receptors according to their linker region; in LDLR, the linker region is located between cysteine-rich repeats four and five of its seven repeats while in VLDLR, the linker region appears to be between repeats five and six of its eight repeats. [10]

VLDLR also shows high homology among various species. VLDLR of humans, mice, rats, and rabbits have been identified as 95% identical. Furthermore, there is approximately 84% conservation with the respective protein in chickens. This level of homology between species is much higher than that found for LDLR. Hence, these gene comparisons suggest that VLDLR and LDLR diverged before the LDLRs did among vertebrates. [10]

Ligand binding

VLDLR binds compounds containing apolipoprotein E (apoE). These ligands attach to the cysteine binding repeats in the N-terminus end. The difference in cysteine-rich repeats between the members of the LDL receptor family lead to the differences in binding affinity. VLDLR, in particular, binds VLDL and intermediate-density lipoprotein (IDL), but not LDL. This inability to bind LDL is due to VLDLR's incapability to bind apolipoprotein B (apoB), which is present in LDL. [11]

Inhibitors

Receptor-associated protein (RAP) and thrombospondin-1 (THBS1) have been identified as compounds that bind VLDLR. In many cases, these compounds exhibit inhibitory effects. THBS1 binds VLDLR and blocks ligand binding. [11] This plays an important role in the reelin pathway, as THBS1 can block the attachment of reelin, while simultaneously stimulating the transcription factors normally activated by reelin. This binding of THBS1, however, does not induce the subsequent degradation of these transcription factors, as reelin does, and can thus lead to greatly amplified effects. [6] The RAP protein acts similarly by blocking reelin from binding VLDLR. However, in this case phosphorylation of transcription factors, usually performed by reelin, is also blocked. [12]

Tissue distribution and expression

VLDLR is found throughout the body, with particularly high expression in fatty acid tissues due to their high level of triglycerides, VLDLR’s primary ligand. These tissues include those of the heart, skeletal muscle, and adipose layer. In addition, the receptor is found in macrophages, endothelial cells of capillaries, [8] and in the brain, where it has a very different function from that found in the rest of the body. There is a preferred expression for VLDLR type I in the heart, skeletal muscle and brain, as opposed to type II, which is mainly expressed in non-muscular tissues including the cerebrum, cerebellum, kidney, spleen, and aortic endothelial cells. [7] [11] The highest expression of VLDLR is found in the brain. Although VLDLR is found in almost all regions of the brain, its highest expression is restricted to the cortex and cerebellum. Here, the receptor can be found on resting or activated microglia that are associated with senile plaques and cortical neurons, neuroblasts, matrix cells, Cajal-Retzius cells, glioblasts, astrocytes, oligodendrocytes, and region-specific pyramidal neurons. [6] Despite its major role in cholesterol and fatty acid metabolism, VLDLR is not found in the liver. This phenomenon is mainly attributed to the very high levels of LDLR in these areas. [7] In addition, it has been uncovered that this receptor is found, sub-cellularly, in the non-lipid raft sections of cell membranes. [6]

Regulation

Unlike LDLR, VLDLR does not exhibit any feedback mechanism, and hence intracellular lipoproteins are incapable of regulating it. This phenomenon is due to a difference in the sterol regulatory element-1 (SRE-1) of VLDLR. Normal SRE-1 sequences, like those found in LDLR, are characterized by two repeats of the codon CAC separated by two intervening C nucleotides (5’-CACCCCAC-3’). The sterol regulatory element-binding protein-1 (SREBP-1), a transcription factor, targets the CAC repeats of SRE-1 to regulate the protein’s transcription. However, the VLDLR gene is encoded by two SRE-1-like sequences that contain single nucleotide polymorphisms. These polymorphisms disrupt the SREBP-1 binding to the CAC repeats, and hence eliminate the feedback mechanism seen in other proteins. [7]

VLDLR expression is regulated by peroxisome proliferator-activated receptor-gamma (PPAR-γ). A 2010 study showed that the prescription drug Pioglitazone, an agonist of PPAR-γ, increases VLDLR mRNA expression and protein levels in experiments using mouse fibroblasts. The Pioglitazone treated mice exhibited a higher conversion rate of plasma triglycerides into epididymal fats. As expected, mice deficient in VLDLR did not show this same response. [8] These results suggest that VLDLR is important in fat accumulation. [8]

Many other hormones and dietary factors also regulate VLDLR expression. Thyroid hormone positively regulates VLDLR expression in skeletal muscles of rats, but not in adipose or heart tissues. In rabbits, VLDLR expression in heart muscle is up-regulated by estrogen and down-regulated by granulocyte-macrophage colony-stimulating factor. In trophoblast-derived cell lines, up-regulated VLDLR expression occurs when cells are incubated with hypolipidemic agents such as insulin and clofibrate. In contrast, 8-bromoadenosine 3',5'-cyclic monophosphate (8-bromo-cAMP) down-regulates VLDLR expression. Finally, VLDLR is affected by the presence of apoE and LDLR. The presence of apoE is required for VLDLR expression regulation, while the absence of LDLR alters the sterol-regulatory-element-1-like sequences of VLDLR to make them functional in only heart and skeletal muscle. [7]

Function

Beyond the nervous system

VLDLR is a peripheral lipoprotein receptor that functions in lipoprotein metabolism, cardiac fatty acid metabolism, and fat deposition. In effect, VLDLR will allow cholesterol to reach tissues from the bloodstream, where it may be used in cellular membranes. In addition, it will allow fatty acids to get into cells where they may be used as an energy source. [7] Overall, VLDLR primarily modulates the extra-hepatic metabolism of triglyceride-rich lipoproteins. [8]

Lipoprotein uptake

VLDLR only plays a discrete role in lipid metabolism, but is more significant in stressed situations. Mice with double knockouts in VLDLR and LDLR have higher serum triglyceride levels than those with only a knockout in the LDLR gene. In addition, LDLR knockout mice overexpressing VLDLR have decreased serum triglyceride levels. Although fat deposition is close to normal without VLDLR, its role gains importance when LDLR is deficient. Despite this knowledge on its role in lipoprotein uptake, the complete mechanism of lipid metabolism performed by VLDLR is not fully understood. [11]

Endocytosis

VLDLR is known to employ endocytosis, although the exact mechanism of this process is unknown for this protein. Endocytosis is mediated through NPxY sequences known to signal for receptor internalization through clathrin-coated pits. The presence of this sequence in the cytoplasmic tail of VLDLR makes endocytosis possible. [11] In general, lipoprotein receptors undergo a process by which they are endocytosed with their ligand into clathrin-coated pits. From here, they are together transported to early and late endosomes until reaching the lysosome. At this point, hydrolysis occurs and lipoprotein is released into the cytoplasm while the receptors are recycled back to the cell surface. It is not yet confirmed if VLDLR follows this exact mechanism, but one closely related to it is likely. [8]

In the nervous system

The reelin pathway, representing VLDLR's role in the process. Reelin pathway in protection from Cerebral Malaria PMID 18062806.jpg
The reelin pathway, representing VLDLR’s role in the process.

In addition to its role throughout the body, VLDLR has a unique role in the brain. It is a key component of the reelin pathway, which functions on one hand side in neuronal migration during the development of the brain, on the other hand in the retention of new memory traces in the hippocampal formation. [13] [14] VLDLR links the reelin protein to an intracellular signaling protein, Dab1, that tells the individual neurons where to go within the anatomy of the brain. Mutations in VLDLR often do not lead to major disorganization as seen in reelin mutations. However, a VLDLR mutation does lead to some disorganization primarily located in the cerebellum, where VLDLR is believed to be most prominent. [6]

Neuronal migration

VLDLR is expressed on migrating neurons to help guide them to their proper location in the brain. This process is part of the reelin pathway, which is responsible for the inside-out formation of the six-layered neocortex. [6] Despite the discovery of this pathway, many of the specifics and molecular mechanisms of this process are still being debated. The presence of two reelin receptors, VLDLR and ApoER2, has made it difficult to distinguish each protein’s specific function. [15]

Organization of the six layered neocortex. In the absence of VLDLR, the neuroblasts of the cortical plate invade the marginal zone above. Corticogenesis in a wild-type mouse with captions in english copy.png
Organization of the six layered neocortex. In the absence of VLDLR, the neuroblasts of the cortical plate invade the marginal zone above.

VLDLR is primarily responsible for the correct layering of pyramidal cells into layer 1 of the cerebral cortex. In particular, the absence of VLDLR may lead to ectopic accumulation of pyramidal cells in this region. [15] VLDLR does not affect the migration of early born cells into an organized layer, but since its absence results in the invasion of these neuroblasts into the marginal zone, it is theorized that VLDLR may encode a “stop signal.” This is supported by the fact that VLDLR is primarily expressed in the cortical plate adjacent to reelin-expressing cells, Cajal–Retzius cells, and in the intermediate zone. However, definitive evidence has not yet been found. [6] In general, reelin binds VLDLR and undergoes endocytosis via clathrin-coated vesicles. [6] Meanwhile, an intracellular protein, Dab1, has a PI/PTB domain that interacts with the NPxY sequence found in the cytoplasmic tail of VLDLR. [12] As a result, Dab1 is tyrosine phosphorylated and reelin is degraded. Finally, phosphorylated Dab1 activates an intracellular signaling cascade that directs neuroblasts to their proper location through the alteration of the cytoskeleton. [12] [16] Many of the specifics of this pathway are still being investigated. It is not yet known if Dab1 is phosphorylated as a result of the endocytosis of reelin, or if there is another mechanism at play. In addition to the organization of the neocortex, VLDLR also plays a role in neuronal migration of the hippocampus and the Purkinje cells of the cerebellum. Yet, much information on this process is still unknown. [6]

Associated disorders

Mutations within the VLDLR gene lead to a multitude of disorders of varying severities. These disorders are usually associated with cholesterol homeostasis or a disorganization of neuron ordering in the brain due to disruption of the reelin pathway. The most prominent of these diseases are type I lissencephaly, VLDR-associated cerebellar hypoplasia, and atherosclerosis. In contrast to causing diseases, VLDLR has also been identified as a possible remedy for some disorders. Implementation of VLDLR into the liver may cure familial hypercholesterolemia (FH) in patients who either have defective LDLR or have defective immune systems that attack this protein. Since VLDLR is non-immunogenic it does not initiate an immune response, thus it is able to function normally under defective immune systems. [7] In addition, being that apoE, a major ligand of VLDLR, is a leading genetic risk factor for Alzheimer’s disease, VLDLR may play a role in modulating the risk of this disorder [6] which is explained by the fact that a decrease in reelin signaling in the fascia dentata is supposed to initiate Alzheimer's disease. [17] VLDLR has also been shown to reduce the chances of premature heart disease and stroke because VLDLR clears out lipoprotein A (Lp(a)), a major inherited risk factor for these diseases. [7]

Type 1 lissencephaly

Type I lissencephaly, or agyria-pachygyria, is a rare developmental disorder characterized by the absence of gyri and sulci in the brain. These severe malformations are a result of aberrant neuronal migration. In classical type I lissencephaly, neuronal migration begins but is unable to continue to completion. This process is likely disrupted by alterations to several genes, including the VLDLR, DCX , ARX , TUBA1A , RELN and LIS1 . The severity of type I lissencephaly therefore varies with the mutation type. A homozygous deletion affecting the VLDLR gene results in a low degree of cortical thickening and absence of a cell-sparse zone. The cell-sparse zone describes the region between the outer and inner cortical layers of arrested neurons. [18] In addition, type 1 lissencephaly is closely associated with cerebellar hypoplasia.

VLDLR-associated cerebellar hypoplasia

Disequilibrium syndrome (DES) was first described in the 1970s as a non-progressive, neurological disorder. [19] In a 2005 study, DES was renamed as VLDLR-associated cerebellar hypoplasia (VLDLRCH) after its cause was linked to a disruption in the VLDLR gene. [20] At least six mutations affecting the homozygous recessive allele of the VLDLR gene have been identified and found to cause VLDLRCH. Several of these mutations have been localized to specific exons encoding the gene. One such mutation is a cytosine to thymine transition at base pair 1342 in exon 10 that causes a substitution at Arg448 for a termination signal. Likewise, there is evidence of a cytosine to thymine transition at base pair number 769 in exon 5 that causes a substitution at Arg257 for a termination signal. A third known mutation is caused by a homozygous 1-base pair deletion in exon 17 that causes a frameshift and premature termination in the O-linked sugar domain. [21] All such alterations to the VLDLR gene prevent the production of VLDLR and are therefore termed loss-of-function mutations. The recognized symptoms of VLDLRCH are moderate-to-severe intellectual disability, seizures, dysarthria, strabismus and delayed locomotion. In some cases, children with VLDLRCH learn to walk very late in development after the age of six years, or never learn to walk independently. The frequency of this disorder is unknown because early diagnosis of VLDLRCH is difficult using imaging techniques. It is associated with parental consanguinity and found in secluded communities such as the Hutterites and inbred families from Iran and Turkey. [22]

Atherosclerosis

Atherosclerosis is marked by an excessive accumulation of cholesterol by macrophages, leading to their transformation into foam cells. This accumulation of cholesterol is caused by dysregulation of cholesterol influx and efflux. Since macrophages do not have the ability to limit the influx of cholesterol, the balance is completely dependent on efflux pathways. VLDLR is expressed by macrophages, and functions in the uptake of native lipoproteins. Uniquely, VLDLR does not respond to cholesterol loading, likely due to its lack of feedback mechanisms. The inability to control its uptake of native lipoproteins makes VLDLR a pro-atherogenic factor. [23] This characteristic is supported by results from a 2005 study, in which reintroduction of VLDLR into VLDLR knockout mice led to greatly increased atherosclerotic lesion development. [23]

See also

Related Research Articles

<span class="mw-page-title-main">Reelin</span> Large secreted extracellular matrix glycoprotein involved in neuronal migration

Reelin, encoded by the RELN gene, is a large secreted extracellular matrix glycoprotein that helps regulate processes of neuronal migration and positioning in the developing brain by controlling cell–cell interactions. Besides this important role in early development, reelin continues to work in the adult brain. It modulates synaptic plasticity by enhancing the induction and maintenance of long-term potentiation. It also stimulates dendrite and dendritic spine development and regulates the continuing migration of neuroblasts generated in adult neurogenesis sites like the subventricular and subgranular zones. It is found not only in the brain but also in the liver, thyroid gland, adrenal gland, Fallopian tube, breast and in comparatively lower levels across a range of anatomical regions.

<span class="mw-page-title-main">Lipoprotein</span> Biochemical assembly whose purpose is to transport hydrophobic lipid molecules

A lipoprotein is a biochemical assembly whose primary function is to transport hydrophobic lipid molecules in water, as in blood plasma or other extracellular fluids. They consist of a triglyceride and cholesterol center, surrounded by a phospholipid outer shell, with the hydrophilic portions oriented outward toward the surrounding water and lipophilic portions oriented inward toward the lipid center. A special kind of protein, called apolipoprotein, is embedded in the outer shell, both stabilising the complex and giving it a functional identity that determines its role.

Intermediate-density lipoproteins (IDLs) belong to the lipoprotein particle family and are formed from the degradation of very low-density lipoproteins as well as high-density lipoproteins. IDL is one of the five major groups of lipoproteins that enable fats and cholesterol to move within the water-based solution of the bloodstream. Each native IDL particle consists of protein that encircles various lipids, enabling, as a water-soluble particle, these lipids to travel in the aqueous blood environment as part of the fat transport system within the body. Their size is, in general, 25 to 35 nm in diameter, and they contain primarily a range of triglycerides and cholesterol esters. They are cleared from the plasma into the liver by receptor-mediated endocytosis, or further degraded by hepatic lipase to form LDL particles.

<span class="mw-page-title-main">Lipoprotein lipase</span> Mammalian protein found in Homo sapiens

Lipoprotein lipase (LPL) (EC 3.1.1.34, systematic name triacylglycerol acylhydrolase (lipoprotein-dependent)) is a member of the lipase gene family, which includes pancreatic lipase, hepatic lipase, and endothelial lipase. It is a water-soluble enzyme that hydrolyzes triglycerides in lipoproteins, such as those found in chylomicrons and very low-density lipoproteins (VLDL), into two free fatty acids and one monoacylglycerol molecule:

<span class="mw-page-title-main">Apolipoprotein</span> Proteins that bind lipids to transport them in body fluids

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<span class="mw-page-title-main">Michael Stuart Brown</span> American geneticist and Nobel laureate

Michael Stuart Brown ForMemRS NAS AAA&S APS is an American geneticist and Nobel laureate. He was awarded the Nobel Prize in Physiology or Medicine with Joseph L. Goldstein in 1985 for describing the regulation of cholesterol metabolism.

<span class="mw-page-title-main">LDL receptor</span> Mammalian protein found in Homo sapiens

The low-density lipoprotein receptor (LDL-R) is a mosaic protein of 839 amino acids that mediates the endocytosis of cholesterol-rich low-density lipoprotein (LDL). It is a cell-surface receptor that recognizes apolipoprotein B100 (ApoB100), which is embedded in the outer phospholipid layer of very low-density lipoprotein (VLDL), their remnants—i.e. intermediate-density lipoprotein (IDL), and LDL particles. The receptor also recognizes apolipoprotein E (ApoE) which is found in chylomicron remnants and IDL. In humans, the LDL receptor protein is encoded by the LDLR gene on chromosome 19. It belongs to the low density lipoprotein receptor gene family. It is most significantly expressed in bronchial epithelial cells and adrenal gland and cortex tissue.

<span class="mw-page-title-main">Apolipoprotein E</span> Cholesterol-transporting protein most notably implicated in Alzheimers disease

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<span class="mw-page-title-main">Apolipoprotein B</span> Protein-coding gene in the species Homo sapiens

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<span class="mw-page-title-main">DAB1</span> Protein-coding gene in the species Homo sapiens

The Disabled-1 (Dab1) gene encodes a key regulator of Reelin signaling. Reelin is a large glycoprotein secreted by neurons of the developing brain, particularly Cajal-Retzius cells. DAB1 functions downstream of Reln in a signaling pathway that controls cell positioning in the developing brain and during adult neurogenesis. It docks to the intracellular part of the Reelin very low density lipoprotein receptor (VLDLR) and apoE receptor type 2 (ApoER2) and becomes tyrosine-phosphorylated following binding of Reelin to cortical neurons. In mice, mutations of Dab1 and Reelin generate identical phenotypes. In humans, Reelin mutations are associated with brain malformations and mental retardation. In mice, Dab1 mutation results in the scrambler mouse phenotype.

<span class="mw-page-title-main">Reeler</span> Mouse mutant

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<span class="mw-page-title-main">Low-density lipoprotein receptor gene family</span>

The low-density lipoprotein receptor gene family codes for a class of structurally related cell surface receptors that fulfill diverse biological functions in different organs, tissues, and cell types. The role that is most commonly associated with this evolutionarily ancient family is cholesterol homeostasis. In humans, excess cholesterol in the blood is captured by low-density lipoprotein (LDL) and removed by the liver via endocytosis of the LDL receptor. Recent evidence indicates that the members of the LDL receptor gene family are active in the cell signalling pathways between specialized cells in many, if not all, multicellular organisms.

<span class="mw-page-title-main">Familial hypercholesterolemia</span> Genetic disorder characterized by high cholesterol levels

Familial hypercholesterolemia (FH) is a genetic disorder characterized by high cholesterol levels, specifically very high levels of low-density lipoprotein, in the blood and early cardiovascular disease. The most common mutations diminish the number of functional LDL receptors in the liver. Since the underlying body biochemistry is slightly different in individuals with FH, their high cholesterol levels are less responsive to the kinds of cholesterol control methods which are usually more effective in people without FH. Nevertheless, treatment is usually effective.

<span class="mw-page-title-main">LDL-receptor-related protein-associated protein</span> Protein-coding gene in the species Homo sapiens

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<span class="mw-page-title-main">Low-density lipoprotein receptor-related protein 8</span> Cell surface receptor, part of the low-density lipoprotein receptor family

Low-density lipoprotein receptor-related protein 8 (LRP8), also known as apolipoprotein E receptor 2 (ApoER2), is a protein that in humans is encoded by the LRP8 gene. ApoER2 is a cell surface receptor that is part of the low-density lipoprotein receptor family. These receptors function in signal transduction and endocytosis of specific ligands. Through interactions with one of its ligands, reelin, ApoER2 plays an important role in embryonic neuronal migration and postnatal long-term potentiation. Another LDL family receptor, VLDLR, also interacts with reelin, and together these two receptors influence brain development and function. Decreased expression of ApoER2 is associated with certain neurological diseases.

<span class="mw-page-title-main">Hepatic lipase</span> Mammalian protein found in Homo sapiens

Hepatic lipase (HL), also called hepatic triglyceride lipase (HTGL) or LIPC (for "lipase, hepatic"), is a form of lipase, catalyzing the hydrolysis of triacylglyceride. Hepatic lipase is coded by chromosome 15 and its gene is also often referred to as HTGL or LIPC. Hepatic lipase is expressed mainly in liver cells, known as hepatocytes, and endothelial cells of the liver. The hepatic lipase can either remain attached to the liver or can unbind from the liver endothelial cells and is free to enter the body's circulation system. When bound on the endothelial cells of the liver, it is often found bound to HSPG, heparan sulfate proteoglycans (HSPG), keeping HL inactive and unable to bind to HDL (high density lipoprotein) or IDL (intermediate density lipoprotein). When it is free in the bloodstream, however, it is found associated with HDL to maintain it inactive. This is because the triacylglycerides in HDL serve as a substrate, but the lipoprotein contains proteins around the triacylglycerides that can prevent the triacylglycerides from being broken down by HL.

<span class="mw-page-title-main">OLR1</span> Protein-coding gene in the species Homo sapiens

Oxidized low-density lipoprotein receptor 1 also known as lectin-type oxidized LDL receptor 1 (LOX-1) is a protein that in humans is encoded by the OLR1 gene.

<span class="mw-page-title-main">LRP1</span> Mammalian protein found in Homo sapiens

Low density lipoprotein receptor-related protein 1 (LRP1), also known as alpha-2-macroglobulin receptor (A2MR), apolipoprotein E receptor (APOER) or cluster of differentiation 91 (CD91), is a protein forming a receptor found in the plasma membrane of cells involved in receptor-mediated endocytosis. In humans, the LRP1 protein is encoded by the LRP1 gene. LRP1 is also a key signalling protein and, thus, involved in various biological processes, such as lipoprotein metabolism and cell motility, and diseases, such as neurodegenerative diseases, atherosclerosis, and cancer.

<span class="mw-page-title-main">PCSK9</span> Mammalian protein found in humans

Proprotein convertase subtilisin/kexin type 9 (PCSK9) is an enzyme encoded by the PCSK9 gene in humans on chromosome 1. It is the 9th member of the proprotein convertase family of proteins that activate other proteins. Similar genes (orthologs) are found across many species. As with many proteins, PCSK9 is inactive when first synthesized, because a section of peptide chains blocks their activity; proprotein convertases remove that section to activate the enzyme. The PCSK9 gene also contains one of 27 loci associated with increased risk of coronary artery disease.

YWTD repeats are four-stranded beta-propeller repeats found in low-density lipoprotein receptors (LDLR). The six YWTD repeats together fold into a six-bladed beta-propeller. Each blade of the propeller consists of four antiparallel beta-strands; the innermost strand of each blade is labeled 1 and the outermost strand, 4. The sequence repeats are offset with respect to the blades of the propeller, such that any given 40-residue YWTD repeat spans strands 24 of one propeller blade and strand 1 of the subsequent blade. This offset ensures circularization of the propeller because the last strand of the final sequence repeat acts as an innermost strand 1 of the blade that harbors strands 24 from the first sequence repeat. The repeat is found in a variety of proteins that include, vitellogenin receptor from Drosophila melanogaster, low-density lipoprotein (LDL) receptor, preproepidermal growth factor, and nidogen (entactin).

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Further reading