Site-specific O-glycosylation of N-terminal serine residues by polypeptide GalNAc-transferase 2 modulates human δ-opioid receptor turnover at the plasma membrane

G protein-coupled receptors (GPCRs) are an important protein family of signalling receptors that govern a wide variety of physiological functions. The capacity to transmit extracellular signals and the extent of cellular response are largely determined by the amount of functional receptors at the cell surface that is subject to complex and fine-tuned regulation. Here, we demonstrate that the cell surface expression level of an inhibitory GPCR, the human δ-opioid receptor (hδOR) involved in pain and mood regulation, is modulated by site-specific N-acetylgalactosamine (GalNAc) -type O-glycosylation. Importantly, we identified one out of the 20 polypeptide GalNAc-transferase isoforms, GalNAc-T2, as the specific regulator of O-glycosylation of Ser6, Ser25 and Ser29 in the N-terminal ectodomain of the receptor. This was demonstrated by in vitro glycosylation assays using peptides corresponding to the hδOR N-terminus, Vicia villosa lectin affinity purification of receptors expressed in HEK293 SimpleCells capable of synthesizing only truncated O-glycans, GalNAc-T edited cell line model systems, and site-directed mutagenesis of the putative O-glycosylation sites. Interestingly, a single-nucleotide polymorphism, at residue 27 (F27C), was found to alter O-glycosylation of the receptor in efficiency as well as in glycosite usage. Furthermore, flow cytometry and cell surface biotinylation assays using O-glycan deficient CHO-ldlD cells revealed that the absence of O-glycans results in decreased receptor levels at the plasma membrane due to enhanced turnover. In addition, mutation of the identified O-glycosylation sites led to a decrease in the number of ligand-binding competent receptors and impaired agonist-mediated inhibition of cyclic AMP accumulation in HEK293 cells. Thus, site-specific O-glycosylation by a selected GalNAc-T isoform can increase the stability of a GPCR, in a process that modulates the constitutive turnover and steady-state levels of functional receptors at the cell surface.     

N-Glycosylation of Asparagine 8 Regulates Surface Expression of Major Histocompatibility Complex Class I Chain-related Protein A (MICA) Alleles Dependent on Threonine 24

NKG2D is an activating receptor expressed on several types of human lymphocytes. NKG2D ligands can be induced upon cell stress and are frequently targeted post-translationally in infected or transformed cells to avoid immune recognition. Virus infection and inflammation alter protein N-glycosylation, and we have previously shown that changes in cellular N-glycosylation are involved in regulation of NKG2D ligand surface expression. The specific mode of regulation through N-glycosylation is, however, unknown. Here we investigated whether direct N-glycosylation of the NKG2D ligand MICA itself is critical for cell surface expression and sought to identify the essential residues. We found that a single N-glycosylation site (Asn⁸) was important for MICA018 surface expression. The frequently expressed MICA allele 008, with an altered transmembrane and intracellular domain, was not affected by mutation of this N-glycosylation site. Mutational analysis revealed that a single amino acid (Thr²⁴) in the extracellular domain of MICA018 was essential for the N-glycosylation dependence, whereas the intracellular domain was not involved. The HHV7 immunoevasin, U21, was found to inhibit MICA018 surface expression by affecting N-glycosylation, and the retention was rescued by T24A substitution. Our study reveals N-glycosylation as an allele-specific regulatory mechanism important for regulation of surface expression of MICA018, and we pinpoint the residues essential for this N-glycosylation dependence. In addition, we show that this regulatory mechanism of MICA surface expression is likely targeted during different pathological conditions.     

Angiopoietin-like Protein 3 Inhibits Lipoprotein Lipase Activity through Enhancing Its Cleavage by Proprotein Convertases

Lipoprotein lipase (LPL)-mediated lipolysis of triglycerides is the first and rate-limiting step in chylomicron/very low density lipoprotein clearance at the luminal surface of the capillaries. Angiopoietin-like protein 3 (ANGPTL3) is shown to inhibit LPL activity and plays important roles in modulating lipoprotein metabolism in vivo. However, the mechanism by which it inhibits LPL activity remains poorly understood. Using cell-based analysis of the interaction between ANGPTL3, furin, proprotein convertase subtilisin/kexin type 5 (PCSK5), paired amino acid converting enzyme-4 (PACE4), and LPL, we demonstrated that the cleavage of LPL by proprotein convertases is an inactivation process, similar to that seen for endothelial lipase cleavage. At physiological concentrations and in the presence of cells, ANGPTL3 is a potent inhibitor of LPL. This action is due to the fact that ANGPTL3 can enhance LPL cleavage by endogenous furin and PACE4 but not by PCSK5. This effect is specific to LPL but not endothelial lipase. Both N- and C-terminal domains of LPL are required for ANGPTL3-enhanced cleavage, and the N-terminal domain of ANGPTL3 is sufficient to exert its effect on LPL cleavage. Moreover, ANGPTL3 enhances LPL cleavage in the presence of either heparan sulfate proteoglycans or glycosylphosphatidylinositol-anchored high density lipoprotein-binding protein 1 (GPIHBP1). By enhancing LPL cleavage, ANGPTL3 dissociates LPL from the cell surface, inhibiting both the catalytic and noncatalytic functions of LPL. Taken together, our data provide a molecular connection between ANGPTL3, LPL, and proprotein convertases, which may represent a rapid signal communication among different metabolically active tissues to maintain energy homeostasis. These novel findings provide a new paradigm of specific protease-substrate interaction and further improve our knowledge of LPL biology.     

Polypeptide GalNAc-transferase T3 and familial tumoral calcinosis. Secretion of fibroblast growth factor 23 requires O-glycosylation

Mutations in the gene encoding the glycosyltransferase polypeptide GalNAc-T3, which is involved in initiation of O-glycosylation, were recently identified as a cause of the rare autosomal recessive metabolic disorder familial tumoral calcinosis (OMIM 211900). Familial tumoral calcinosis is associated with hyperphosphatemia and massive ectopic calcifications. Here, we demonstrate that the secretion of the phosphaturic factor fibroblast growth factor 23 (FGF23) requires O-glycosylation, and that GalNAc-T3 selectively directs O-glycosylation in a subtilisin-like proprotein convertase recognition sequence motif, which blocks processing of FGF23. The study suggests a novel posttranslational regulatory model of FGF23 involving competing O-glycosylation and protease processing to produce intact FGF23.     

Role of Endoproteolytic Dibasic Proprotein Processing in Maturation of Secretory Proteins in Trichoderma reesei

Cell extracts of Trichoderma reesei exhibited dibasic endopeptidase activity toward the carboxylic side of KR, RR, and PR sequences. This activity was stimulated by the presence of Ca²⁺ ions and localized in vesicles of low bouyant density; it therefore exhibited some similarity to yeast Kex2. Analytical chromatofocusing revealed a single peak of activity. The dibasic endopeptidase activity was strongly and irreversibly inhibited in vitro as well as in vivo by 1 mM p-amidinophenylmethylsulfonyl fluoride (pAPMSF) but not by PMSF at concentrations up to 5 mM. We therefore used pAPMSF to study the role of the dibasic endopeptidase in the secretion of protein by T. reesei. Secretion of xylanase I (proprotein processing sequence -R-R-↓-R-↓-A-) and xylanase II (-K-R-↓-Q-) was strongly inhibited by 1 mM pAPMSF, and a larger, unprocessed enzyme form was detected intracellularly under these conditions. Secretion of cellobiohydrolase II (CBH II; -E-R-↓-Q-) was only slightly inhibited by pAPMSF, and no accumulation of unprocessed precursors was detected. In contrast, secretion of CBH I (-R-A-↓-Q-) was stimulated by pAPMSF addition, and a simultaneous decrease in the concentration of intracellular CBH I was detected. Similar experiments were also carried out with a single heterologous protein, ShBLE, the phleomycin-binding protein from Streptoalloteichus hindustanus, fused to a series of model proprotein-processing sequences downstream of the expression signals of the Aspergillus nidulans gpdA promoter. Consistent with the results obtained with homologous proteins, pAPMSF inhibited the secretion of ShBLE with fusions containing dibasic (RK and KR) target sequences, but it even stimulated secretion in fusions to LR, NHA, and EHA target sequences. Addition of 5 mM PMSF, a nonspecific inhibitor of serine protease, nonspecifically inhibited the secretion of heterologous proteins from fusions bearing the NHA and LR targets. These data point to the existence of different endoproteolytic proprotein processing enzymes in T. reesei and demonstrate that dibasic processing is obligatory for the secretion of the proproteins containing this target.     

Site-specific protein O-glycosylation modulates proprotein processing — Deciphering specific functions of the large polypeptide GalNAc-transferase gene family

Background

Posttranslational modifications (PTMs) greatly expand the function and regulation of proteins, and glycosylation is the most abundant and diverse PTM. Of the many different types of protein glycosylation, one is quite unique; GalNAc-type (or mucin-type) O-glycosylation, where biosynthesis is initiated in the Golgi by up to twenty distinct UDP-N-acetyl-α-d-galactosamine:polypeptide N-acetylgalactosaminyltransferases (GalNAc-Ts). These GalNAc-Ts are differentially expressed in cells and have different (although partly overlapping) substrate specificities, which provide for both unique functions and considerable redundancy. Recently we have begun to uncover human diseases associated with deficiencies in GalNAc-T genes (GALNTs). Thus deficiencies in individual GALNTs produce cell and protein specific effects and subtle distinct phenotypes such as hyperphosphatemia with hyperostosis (GALNT3) and dysregulated lipid metabolism (GALNT2). These phenotypes appear to be caused by deficient site-specific O-glycosylation that co-regulates proprotein convertase (PC) processing of FGF23 and ANGPTL3, respectively.

Scope of review

Here we summarize recent progress in uncovering the interplay between human O-glycosylation and protease regulated processing and describes other important functions of site-specific O-glycosylation in health and disease.

Major conclusions

Site-specific O-glycosylation modifies pro-protein processing and other proteolytic events such as ADAM processing and thus emerges as an important co-regulator of limited proteolytic processing events.

General significance

Our appreciation of this function may have been hampered by our sparse knowledge of the O-glycoproteome and in particular sites of O-glycosylation. New strategies for identification of O-glycoproteins have emerged and recently the concept of SimpleCells, i.e. human cell lines made deficient in O-glycan extension by zinc finger nuclease gene targeting, was introduced for broad O-glycoproteome analysis.     

O-mannosylation precedes and potentially controls the N-glycosylation of a yeast cell wall glycoprotein

Secretory proteins in yeast are N- and O-glycosylated while they enter the endoplasmic reticulum. N-glycosylation is initiated by the oligosaccharyl transferase complex and O-mannosylation is initiated by distinct O-mannosyltransferase complexes of the protein mannosyl transferase Pmt1/Pmt2 and Pmt4 families. Using covalently linked cell-wall protein 5 (Ccw5) as a model, we show that the Pmt4 and Pmt1/Pmt2 mannosyltransferases glycosylate different domains of the Ccw5 protein, thereby mannosylating several consecutive serine and threonine residues. In addition, it is shown that O-mannosylation by Pmt4 prevents N-glycosylation by blocking the hydroxy amino acid of the single N-glycosylation site present in Ccw5. These data prove that the O- and N-glycosylation machineries compete for Ccw5; therefore O-mannosylation by Pmt4 precedes N-glycosylation.     

Structural and mechanistic insights into the interaction of cytochrome P4503A4 with bromoergocryptine, a type I ligand

Cytochrome P4503A4 (CYP3A4), a major human drug-metabolizing enzyme, is responsible for the oxidation and clearance of the majority of administered drugs. One of the CYP3A4 substrates is bromoergocryptine (BEC), a dopamine receptor agonist prescribed for the inhibition of prolactin secretion and treatment of Parkinson disease, type 2 diabetes, and several other pathological conditions. Here we present a 2.15 Å crystal structure of the CYP3A4-BEC complex in which the drug, a type I heme ligand, is bound in a productive mode. The manner of BEC binding is consistent with the in vivo metabolite analysis and identifies the 8′ and 9′ carbons of the proline ring as the primary sites of oxidation. The crystal structure predicts the importance of Arg²¹² and Thr²²⁴ for binding of the tripeptide and lysergic moieties of BEC, respectively, which we confirmed experimentally. Our data support a three-step BEC binding model according to which the drug binds first at a peripheral site without perturbing the heme spectrum and then translocates into the active site cavity, where formation of a hydrogen bond between Thr²²⁴ and the N1 atom of the lysergic moiety is followed by a slower conformational readjustment of the tripeptide group modulated by Arg²¹².     

O-Glycosylation as a Novel Control Mechanism of Peptidoglycan Hydrolase Activity

Acm2, the major autolysin of Lactobacillus plantarum, is a tripartite protein. Its catalytic domain is surrounded by an O-glycosylated N-terminal region rich in Ala, Ser, and Thr (AST domain), which is of low complexity and unknown function, and a C-terminal region composed of five SH3b peptidoglycan (PG) binding domains. Here, we investigate the contribution of these two accessory domains and of O-glycosylation to Acm2 functionality. We demonstrate that Acm2 is an N-acetylglucosaminidase and identify the pattern of O-glycosylation (21 mono-N-acetylglucosamines) of its AST domain. The O-glycosylation process is species-specific as Acm2 purified from Lactococcus lactis is not glycosylated. We therefore explored the functional role of O-glycosylation by purifying different truncated versions of Acm2 that were either glycosylated or non-glycosylated. We show that SH3b domains are able to bind PG and are responsible for Acm2 targeting to the septum of dividing cells, whereas the AST domain and its O-glycosylation are not involved in this process. Notably, our data reveal that the lack of O-glycosylation of the AST domain significantly increases Acm2 enzymatic activity, whereas removal of SH3b PG binding domains dramatically reduces this activity. Based on this antagonistic role, we propose a model in which access of the Acm2 catalytic domain to its substrate may be hindered by the AST domain where O-glycosylation changes its conformation and/or mediates interdomain interactions. To the best of our knowledge, this is the first time that O-glycosylation is shown to control the activity of a bacterial enzyme.     

GPIHBP1 stabilizes lipoprotein lipase and prevents its inhibition by angiopoietin-like 3 and angiopoietin-like 4

Glycosylphosphatidylinositol-anchored HDL-binding protein (GPIHBP1) binds both LPL and chylomicrons, suggesting that GPIHBP1 is a platform for LPL-dependent processing of triglyceride (TG)-rich lipoproteins. Here, we investigated whether GPIHBP1 affects LPL activity in the absence and presence of LPL inhibitors angiopoietin-like (ANGPTL)3 and ANGPTL4. Like heparin, GPIHBP1 stabilized but did not activate LPL. ANGPTL4 potently inhibited nonstabilized LPL as well as heparin-stabilized LPL but not GPIHBP1-stabilized LPL. Like ANGPTL4, ANGPTL3 inhibited nonstabilized LPL but not GPIHBP1-stabilized LPL. ANGPTL3 also inhibited heparin-stabilized LPL but with less potency than nonstabilized LPL. Consistent with these in vitro findings, fasting serum TGs of Angptl4^−/−/Gpihbp1^−/− mice were lower than those of Gpihbp1^−/− mice and approached those of wild-type littermates. In contrast, serum TGs of Angptl3^−/−/Gpihbp1^−/− mice were only slightly lower than those of Gpihbp1^−/− mice. Treating Gpihbp1^−/− mice with ANGPTL4- or ANGPTL3-neutralizing antibodies recapitulated the double knockout phenotypes. These data suggest that GPIHBP1 functions as an LPL stabilizer. Moreover, therapeutic agents that prevent LPL inhibition by ANGPTL4 or, to a lesser extent, ANGPTL3, may benefit individuals with hyperlipidemia caused by gene mutations associated with decreased LPL stability.     

Primary structural requirements for N- and O-glycosylation of yeast mannoproteins

Primary structural requirements both for N- and O-glycosylation have been studied using a series of synthetic peptides and a membrane fraction from Saccharomyces cerevisiae. N-Glycosylation: the tripeptide sequence Asn-Xaa-Thr/Ser was found to be necessary for the transfer of saccharide units from oligosaccharide-lipid to asparagine. Substitution of asparagine by aspartic acid or glutamine, or replacement of threonine by valine in the hexapeptide Tyr-$\text{Asn}$-Leu-$\text{Thr}$-Ser-Val prevents its glycosylation. Also, a proline residue in the position of Xaa makes the peptide unable to function as an acceptor. Transfer onto asparagine occurs only efficiently if both the α-amino group of asparagine and the α-carboxyl moiety of the hydroxy amino acid are blocked. Yield of glycosylation improves with increasing peptide chain length. With regard to the glycosyl donor dolichyl diphosphate-bound GlcNAc₂Man₉Glc₃ is the preferred substrate. Non-glucosylated glycolipid Dol-PP-GlcNAc₂Man₉ is a poor donor, whereas smaller precursors Dol-PP-GlcNAc₂ and Dol-PP-GlcNAc₂Man₁ allow reasonable transfer. O-Glycosylation: no marker sequence can be derived for the formation of an O-glycosidic linkage via Dol-P-Man. Introduction of a proline residue in vicinity to the hydroxy amino acid leads to a significant improvement of glycosyl transfer. It is postulated that accessibility of potential O-glycosylation sites rather than a specific sequence may be a prerequisite for O-glycosylation.     

A Novel Familial Mutation in the PCSK1 Gene That Alters the Oxyanion Hole Residue of Proprotein Convertase 1/3 and Impairs Its Enzymatic Activity

Four siblings presented with congenital diarrhea and various endocrinopathies. Exome sequencing and homozygosity mapping identified five regions, comprising 337 protein-coding genes that were shared by three affected siblings. Exome sequencing identified a novel homozygous N309K mutation in the proprotein convertase subtilisin/kexin type 1 (PCSK1) gene, encoding the neuroendocrine convertase 1 precursor (PC1/3) which was recently reported as a cause of Congenital Diarrhea Disorder (CDD). The PCSK1 mutation affected the oxyanion hole transition state-stabilizing amino acid within the active site, which is critical for appropriate proprotein maturation and enzyme activity. Unexpectedly, the N309K mutant protein exhibited normal, though slowed, prodomain removal and was secreted from both HEK293 and Neuro2A cells. However, the secreted enzyme showed no catalytic activity, and was not processed into the 66 kDa form. We conclude that the N309K enzyme is able to cleave its own propeptide but is catalytically inert against in trans substrates, and that this variant accounts for the enteric and systemic endocrinopathies seen in this large consanguineous kindred.     

Mucin-type O-Glycosylation during Development

Mucin-type O-glycosylation is an evolutionarily conserved protein modification present on membrane-bound and secreted proteins. Aberrations in O-glycosylation are responsible for certain human diseases and are associated with disease risk factors. Recent studies have demonstrated essential roles for mucin-type O-glycosylation in protein secretion, stability, processing, and function. Here, we summarize our current understanding of the diverse roles of mucin-type O-glycosylation during eukaryotic development. Appreciating how this conserved modification operates in developmental processes will provide insight into its roles in human disease and disease susceptibilities.     

O-Linked Glycosylation of the Mucin Domain of the Herpes Simplex Virus Type 1-specific Glycoprotein gC-1 Is Temporally Regulated in a Seed-and-spread Manner

The herpes simplex virus type 1 (HSV-1) glycoprotein gC-1, participating in viral receptor interactions and immunity interference, harbors a mucin-like domain with multiple clustered O-linked glycans. Using HSV-1-infected diploid human fibroblasts, an authentic target for HSV-1 infection, and a protein immunoaffinity procedure, we enriched fully glycosylated gC-1 and a series of its biosynthetic intermediates. This fraction was subjected to trypsin digestion and a LC-MS/MS glycoproteomics approach. In parallel, we characterized the expression patterns of the 20 isoforms of human GalNAc transferases responsible for initiation of O-linked glycosylation. The gC-1 O-glycosylation was regulated in an orderly manner initiated by synchronous addition of one GalNAc unit each to Thr-87 and Thr-91 and one GalNAc unit to either Thr-99 or Thr-101, forming a core glycopeptide for subsequent additions of in all 11 GalNAc residues to selected Ser and Thr residues of the Thr-76–Lys-107 stretch of the mucin domain. The expression patterns of GalNAc transferases in the infected cells suggested that initial additions of GalNAc were carried out by initiating GalNAc transferases, in particular GalNAc-T2, whereas subsequent GalNAc additions were carried out by followup transferases, in particular GalNAc-T10. Essentially all of the susceptible Ser or Thr residues had to acquire their GalNAc units before any elongation to longer O-linked glycans of the gC-1-associated GalNAc units was permitted. Because the GalNAc occupancy pattern is of relevance for receptor binding of gC-1, the data provide a model to delineate biosynthetic steps of O-linked glycosylation of the gC-1 mucin domain in HSV-1-infected target cells.     

Proprotein Convertases Process and Thereby Inactivate Formylglycine-generating Enzyme

Formylglycine-generating enzyme (FGE) post-translationally converts a specific cysteine in newly synthesized sulfatases to formylglycine (FGly). FGly is the key catalytic residue of the sulfatase family, comprising 17 nonredundant enzymes in human that play essential roles in development and homeostasis. FGE, a resident protein of the endoplasmic reticulum, is also secreted. A major fraction of secreted FGE is N-terminally truncated, lacking residues 34–72. Here we demonstrate that this truncated form is generated intracellularly by limited proteolysis mediated by proprotein convertase(s) (PCs) along the secretory pathway. The cleavage site is represented by the sequence RYSR⁷²↓, a motif that is conserved in higher eukaryotic FGEs, implying important functionality. Residues Arg-69 and Arg-72 are critical because their mutation abolishes FGE processing. Furthermore, residues Tyr-70 and Ser-71 confer an unusual property to the cleavage motif such that endogenous as well as overexpressed FGE is only partially processed. FGE is cleaved by furin, PACE4, and PC5a. Processing is disabled in furin-deficient cells but fully restored upon transient furin expression, indicating that furin is the major protease cleaving FGE. Processing by endogenous furin occurs mostly intracellularly, although also extracellular processing is observed in HEK293 cells. Interestingly, the truncated form of secreted FGE no longer possesses FGly-generating activity, whereas the unprocessed form of secreted FGE is active. As always both forms are secreted, we postulate that furin-mediated processing of FGE during secretion is a physiological means of higher eukaryotic cells to regulate FGE activity upon exit from the endoplasmic reticulum.     

Akt1 Intramitochondrial Cycling Is a Crucial Step in the Redox Modulation of Cell Cycle Progression

Akt is a serine/threonine kinase involved in cell proliferation, apoptosis, and glucose metabolism. Akt is differentially activated by growth factors and oxidative stress by sequential phosphorylation of Ser⁴⁷³ by mTORC2 and Thr³⁰⁸ by PDK1. On these bases, we investigated the mechanistic connection of H₂O₂ yield, mitochondrial activation of Akt1 and cell cycle progression in NIH/3T3 cell line with confocal microscopy, in vivo imaging, and directed mutagenesis. We demonstrate that modulation by H₂O₂ entails the entrance of cytosolic P-Akt1 Ser⁴⁷³ to mitochondria, where it is further phosphorylated at Thr³⁰⁸ by constitutive PDK1. Phosphorylation of Thr³⁰⁸ in mitochondria determines Akt1 passage to nuclei and triggers genomic post-translational mechanisms for cell proliferation. At high H₂O₂, Akt1-PDK1 association is disrupted and P-Akt1 Ser⁴⁷³ accumulates in mitochondria in detriment to nuclear translocation; accordingly, Akt1 T308A is retained in mitochondria. Low Akt1 activity increases cytochrome c release to cytosol leading to apoptosis. As assessed by mass spectra, differential H₂O₂ effects on Akt1-PDK interaction depend on the selective oxidation of Cys³¹⁰ to sulfenic or cysteic acids. These results indicate that Akt1 intramitochondrial-cycling is central for redox modulation of cell fate.     

OGP: A Repository of Experimentally Characterized O-glycoproteins to Facilitate Studies on O-glycosylation

Numerous studies on cancers, biopharmaceuticals, and clinical trials have necessitated comprehensive and precise analysis of protein O-glycosylation. However, the lack of updated and convenient databases deters the storage of and reference to emerging O-glycoprotein data. To resolve this issue, an O-glycoprotein repository named OGP was established in this work. It was constructed with a collection of O-glycoprotein data from different sources. OGP contains 9354 O-glycosylation sites and 11,633 site-specific O-glycans mapping to 2133 O-glycoproteins, and it is the largest O-glycoprotein repository thus far. Based on the recorded O-glycosylation sites, an O-glycosylation site prediction tool was developed. Moreover, an OGP-based website is already available (https://www.oglyp.org/). The website comprises four specially designed and user-friendly modules: statistical analysis, database search, site prediction, and data submission. The first version of OGP repository and the website allow users to obtain various O-glycoprotein-related information, such as protein accession Nos., O-glycosylation sites, O-glycopeptide sequences, site-specific O-glycan structures, experimental methods, and potential O-glycosylation sites. O-glycosylation data mining can be performed efficiently on this website, which will greatly facilitate related studies. In addition, the database is accessible from OGP website (https://www.oglyp.org/download.php).     

Genetic Variation in ANGPTL4 Provides Insights into Protein Processing and Function

Angiopoietin-like protein 4 (ANGPTL4) is a secreted protein that modulates the disposition of circulating triglycerides (TG) by inhibiting lipoprotein lipase (LPL). Here we examine the steps involved in the synthesis and post-translational processing of ANGPTL4, and the effects of a naturally occurring sequence variant (E40K) that is associated with lower plasma TG levels in humans. Expression of the wild-type and mutant proteins in HEK-293A cells indicated that ANGPTL4 formed dimers and tetramers in cells prior to secretion and cleavage of the protein. After cleavage at a canonical proprotein convertase cleavage site (¹⁶¹RRKR¹⁶⁴), the oligomeric structure of the N-terminal domain was retained whereas the C-terminal fibrinogen-like domain dissociated into monomers. Inhibition of cleavage did not interfere with oligomerization of ANGPTL4 or with its ability to inhibit LPL, whereas mutations that prevented oligomerization severely compromised the capacity of the protein to inhibit LPL. ANGPTL4 containing the E40K substitution was synthesized and processed normally, but no monomers or oligomers of the N-terminal fragments accumulated in the medium; medium from these cells failed to inhibit LPL activity. Parallel experiments performed in mice recapitulated these results. Our findings indicate that oligomerization, but not cleavage, of ANGPTL4 is required for LPL inhibition, and that the E40K substitution destabilizes the protein after secretion, preventing the extracellular accumulation of oligomers and abolishing the ability of the protein to inhibit LPL activity.Angiopoietin-like protein 4 (ANGPTL4)⁴ is a 50-kDa protein that is synthesized and secreted from several metabolically active tissues and has been implicated in the trafficking of circulating TG (1, 2). Triglycerides, either acquired from the diet or synthesized endogenously, circulate in blood as constituents of chylomicrons and very low density lipoproteins (VLDL). As these lipoproteins circulate in tissues they encounter lipoprotein lipase (LPL) at the vascular endothelial surfaces. LPL hydrolyzes the TG, producing free fatty acids that are taken up by the surrounding tissues. ANGPTL4 inhibits the activity of LPL, thereby limiting the uptake of TG-derived fatty acids by the underlying cells (3, 4). Overexpression of ANGPTL4 in mice causes severe hypertriglyceridemia, whereas mice lacking ANGPTL4 have increased LPL activity and low plasma levels of TG (5, 6). In mice, ANGPTL4 is predominantly expressed in adipose tissue and is strongly induced by fasting (2). Accordingly it has been proposed that ANGPTL4 inhibits LPL activity in adipose tissue to reroute fatty acids away from fat to muscle and other tissues when food intake is low (3, 4).ANGPTL4 belongs to a family of seven structurally similar secreted proteins (ANGPTL1-ANGPTL7) that contain a signal sequence followed by an α-helical region predicted to form a coiled-coil, and a globular fibrinogen-like domain at the C terminus (1). Gel filtration studies of recombinant ANGPTL4 indicate that the protein assembles into oligomers that are stabilized by disulfide bonds (7). Substitution of two highly conserved cysteine residues at positions 76 and 80 in the α-helical domain prevents oligomerization of ANGPTL4 and impairs the ability of the recombinant protein to increase plasma TG levels when overexpressed in the livers of rats (7).Upon secretion into the circulation, ANGPTL4 is cleaved into an N-terminal domain and a C-terminal fibrinogen-like domain (8). The N-terminal peptide circulates as an oligomer, and the fibrinogen-like domain circulates as a monomer (8). The N-terminal helical region of ANGPTL4 is necessary and sufficient for inhibition of LPL (9). A peptide corresponding to amino acids 1-187 of the protein binds LPL with high affinity and converts the enzyme from catalytically active dimers to inactive monomers, thereby inhibiting LPL activity (10). After disrupting the LPL dimer, ANGPTL4 is released. The LPL monomers remain folded and stable but fail to re-form active dimers. These data suggest that the N-terminal domain of ANGPTL4 interacts directly but transiently with LPL, triggering a stable conformational switch in LPL that irreversibly inactivates the enzyme.Recently, we used a population-based resequencing strategy to examine the metabolic role of ANGPTL4 in humans (11). Resequencing the coding region of ANGPTL4 in a large (n = 3,501), multiethnic sample revealed multiple rare sequence variations that alter an amino acid in the protein and are associated with low plasma TG levels. In addition, we identified a more common variant (E40K), that was present in ∼3% of European-Americans and was associated with significantly lower plasma levels of TG and low density lipoprotein-cholesterol (LDL-C), and higher levels of high density lipoprotein (HDL)-C in two large epidemiological studies (11). These association studies confirmed that ANGPTL4 is involved in TG metabolism in humans, and also revealed additional roles in humans in the metabolism of HDL and LDL, which were not apparent from studies in genetically modified mice.Here we examined the synthesis, secretion, and processing of ANGPTL4 and determine the mechanism by which substitution of a basic (lysine) for an acidic (glutamate) residue at residue 40 affects the function of the protein.     

An Intracellular Threonine of Amyloid-β Precursor Protein Mediates Synaptic Plasticity Deficits and Memory Loss

Mutations in Amyloid-ß Precursor Protein (APP) and BRI2/ITM2b genes cause Familial Alzheimer and Danish Dementias (FAD/FDD), respectively. APP processing by BACE1, which is inhibited by BRI2, yields sAPPß and ß-CTF. ß-CTF is cleaved by gamma-secretase to produce Aß. A knock-in mouse model of FDD, called FDD_KI, shows deficits in memory and synaptic plasticity, which can be attributed to sAPPß/ß-CTF but not Aß. We have investigated further the pathogenic function of ß-CTF focusing on Thr⁶⁶⁸ of ß-CTF because phosphorylation of Thr⁶⁶⁸ is increased in AD cases. We created a knock-in mouse bearing a Thr⁶⁶⁸Ala mutation (APP^TA mice) that prevents phosphorylation at this site. This mutation prevents the development of memory and synaptic plasticity deficits in FDD_KI mice. These data are consistent with a role for the carboxyl-terminal APP domain in the pathogenesis of dementia and suggest that averting the noxious role of Thr⁶⁶⁸ is a viable therapeutic strategy for human dementias.