Chondroitin sulfate proteoglycan form of the Alzheimer's beta-amyloid precursor.

The Alzheimer's amyloid beta protein is derived from a family of membrane glycoproteins termed amyloid precursor proteins (APP). Here we show that APP exists as the core protein of a chondroitin sulfate (CS) proteoglycan, ranging in apparent molecular size from 140 to 250 kDa, secreted by glial cell line C6. After partial purification on ion-exchange and gel chromatography, the secreted APP proteoglycan was recognized on Western blots by several antibodies specific to different regions of APP. Chondroitinase AC or ABC treatment of our samples completely eliminated the high molecular weight proteoglycan with a concomitant increase in the APP protein. This digested product reacted with an anti-stub antibody which recognizes 4-sulfated disaccharide. Sequencing of the N terminus of the core protein of this CS proteoglycan yielded 18 residues identical to the N terminus sequence of the mature APP. Quantitative analysis showed that, in this cell line, about 90% of the secreted nexin II form of APP occurs in the proteoglycan form, suggesting that the CS chains have a role in the biological function of this protein. The close proximity of two consensus CS attachment sites to both the N terminus of the amyloid beta protein and the secretase cleavage site, suggests that the CS chains may affect the proteolysis of APP and production of the amyloid beta protein.     

Domain structure of the basement membrane heparan sulfate proteoglycan

We have used proteolytic digestions and immunological reactivity to map regional domains of the 400-kilodalton (kDa) core protein of the heparan sulfate containing basement membrane proteoglycan from the Englebreth-Holm-Swarm tumor. Digestion with V8 protease caused the rapid release of numerous large peptides ranging in size from 80 to 200 kDa and a 44-kDa peptide. The 44-kDa peptide (P44) was stable to further digestion, but the larger peptides were eventually degraded to a 46-kDa peptide (P46). Both the P44 and P46 fragments migrate slower in the presence of a reducing agent, indicating intrachain disulfide bonding, and do not have heparan sulfate side chains. Antisera to the P46 fragment, however, did not react with P44 fragment, and the amino acid compositions of P46 and P44 fragments were different. This suggests that these two fragments were unrelated. Trypsin digestion of the proteoglycan immediately released a 200-kDa peptide (P200) that also lacked heparan sulfate side chains. Digestion of the P200 fragment with V8 protease produced the P44 and P46 fragments in the same temporal sequence seen with V8 protease digestion of the proteoglycan. Antisera to the P200 fragment reacted strongly with the P44 and P46 fragments. These results show that the P44 and P46 domains are contained within the P200 domain. The rapid release of the P44 domain indicates that it is located at one end of the core protein. The large size of these proteolytic fragments suggests the core protein contains considerable conformational structure, and the absence of heparan sulfate on the P200 domain indicates that the side chains are asymmetrically located on the core.     

Visualization of the large heparan sulfate proteoglycan from basement membrane

Kleinschmidt spreading, negative staining, and rotary shadowing were used to examine the large form of (basement membrane) heparan sulfate proteoglycan in the electron microscope. Heparan sulfate proteoglycan was visualized as consisting of two parts: the core protein and, emerging from one end of the core protein, the glycosaminoglycan side chains. The core protein usually appeared as an S-shaped rod with about six globules along its length. Similar characteristics were observed in preparations of core protein in which the side chains had been removed by heparitinase treatment ("400-kDa core") as well as in a 200-kDa trypsin fragment ("P200") derived from one end of the core protein. The core protein was sensitive to lyophilization and apparently also to the method of examination, being condensed following Kleinschmidt spreading (length means = 52 nm) and extended following negative staining (length means = 83 nm) or rotary shadowing (length means = 87 nm; 400-kDa core length means = 80 nm; P200 length means = 44 nm). Two or three glycosaminoglycan side chains (length means = 146 +/- 53 nm) were attached to one end of the core protein. The side chains often appeared tangled or to merge together as one. Thus, the large heparan sulfate proteoglycan from basement membrane is an asymmetrical molecule with a core protein containing globular domains and terminally attached side chains. This structure is in keeping with that previously predicted by enzymatic digestions and with the proposed orientation in basement membranes, i.e., the core protein bound in the lamina densa and the heparan sulfate side chains in the lamina lucida arranged along the surface of the basement membranes.     

Immunological characterization of basement membrane types of heparan sulfate proteoglycan

Antibodies were raised against a small high-density and a large low-density form of heparan sulfate proteoglycan from a basement membrane-producing mouse tumor and were characterized by radioimmunoassays, immunoprecipitation and immunohistological methods. Antigenicity was due to the protein cores and included epitopes unique to the low density form as well as some shared by both proteoglycans. The antibodies did not cross-react with other basement membrane proteins or with chondroitin sulfate proteoglycans from interstitial connective tissues. The heparan sulfate proteoglycans occurred ubiquitously in embryonic and adult basement membranes and could be initially detected at the 2-4 cell stage of mouse embryonic development. Low levels were also found in serum. Biosynthetic studies demonstrated identical or similar proteoglycans in cultures of normal and carcinoembryonic cells and in organ cultures of fetal tissues. They could be distinguished from liver cell membrane heparan sulfate proteoglycan, indicating that the basement membrane types of proteoglycans represent a unique class of extracellular matrix proteins.     

Identification of the precursor protein to basement membrane heparan sulfate proteoglycans

The precursor protein of a basement membrane specific heparan sulfate proteoglycan has been identified as a 400,000 Mr polypeptide. Antibodies against large and small forms of this proteoglycan, isolated from a basement membrane (Engelbreth-Holm-Swarm, EHS) tumor, immunoprecipitated the same 400,000 protein from pulse-labeled EHS cells. The proteoglycan precursor protein was not recognized by antibodies against other basement membrane components or by antibodies to the cartilage proteoglycan. Furthermore, heparan sulfate proteoglycan purified from the EHS tumor blocked the immunoprecipitation of the precursor protein. Pulse-chase studies with [35S]methionine showed the precursor protein was converted to a proteoglycan. Pulse-chase studies with 35SO4 showed the large, low density proteoglycan appeared first and was degraded to a smaller, high density proteoglycan. We propose that the precursor protein is used after very little or no modification in the assembly of a large, low density heparan sulfate proteoglycan and that a portion of the population of these macromolecules are subsequently degraded to a smaller form.     

Origin and deposition of basement membrane heparan sulfate proteoglycan in the developing intestine

The deposition of intestinal heparan sulfate proteoglycan (HSPG) at the epithelial-mesenchymal interface and its cellular source have been studied by immunocytochemistry at various developmental stages and in rat/chick interspecies hybrid intestines. Polyclonal heparan sulfate antibodies were produced by immunizing rabbits with HSPG purified from the Engelbreth-Holm-Swarm mouse tumor; these antibodies stained rat intestinal basement membranes. A monoclonal antibody (mAb 4C1) produced against lens capsule of 11-d-old chick embryo reacted with embryonic or adult chick basement membranes, but did not stain that of rat tissues. Immunoprecipitation experiments indicated that mAb 4C1 recognized the chicken basement membrane HSPG. Immunofluorescent staining with these antibodies allowed us to demonstrate that distribution of HSPG at the epithelial-mesenchymal interface varied with the stages of intestinal development, suggesting that remodeling of this proteoglycan is essential for regulating cell behavior during morphogenesis. The immunofluorescence pattern obtained with the two species-specific HSPG antibodies in rat/chick epithelial/mesenchymal hybrid intestines developed as grafts (into the coelomic cavity of chick embryos or under the kidney capsule of adult mice) led to the conclusion that HSPG molecules located in the basement membrane of the developing intestine were produced exclusively by the epithelial cells. These data emphasize the notion already gained from previous studies, in which type IV collagen has been shown to be produced by mesenchymal cells (Simon- Assmann, P., F. Bouziges, C. Arnold, K. Haffen, and M. Kedinger. 1988. Development (Camb.). 102:339-347), that epithelial-mesenchymal interactions play an important role in the formation of a complete basement membrane.     

Reduced synthesis of basement membrane heparan sulfate proteoglycan in streptozotocin-induced diabetic mice

In diabetes, certain basement membranes become thicker yet more porous than normal. To identify possible changes in the basement membrane, we have grown the Engelbreth-Holm-Swarm tumor, a tissue that produces quantities of basement membrane in normal mice and in streptozotocin-treated, insulin-deficient, diabetic mice. The level of laminin, a basement membrane-specific glycoprotein, and the level of total protein were slightly elevated in the diabetic tissue. In contrast, the level of the basement membrane specific heparan sulfate proteoglycan was only 20% of control. The synthesis of this proteoglycan was also reduced in the diabetic animals, while the synthesis of other proteoglycans by tissues such as cartilage was normal. The synthesis of the heparan sulfate proteoglycan in diabetic animals was inversely related to plasma glucose levels showing an abrupt decrease above the normal range of plasma glucose. Insulin restored synthesis to normal but this required doses of insulin that maintained plasma glucose at normal levels for several hours. Since the heparan sulfate proteoglycan in the basement membrane restricts passage of proteins, its absence could account for the increased porosity of basement membrane in diabetes. A compensatory synthesis of other components could lead to their increased deposition and the accumulation of basement membrane in diabetes.     

Heterogeneous distribution of a basement membrane heparan sulfate proteoglycan in rat tissues

A heparan sulfate proteoglycan (HSPG) synthesized by murine parietal yolk sac (PYS-2) cells has been characterized and purified from culture supernatants. A monospecific polyclonal antiserum was raised against it which showed activity against the HSPG core protein and basement membrane specificity in immunohistochemical studies on frozen tissue sections from many rat organs. However, there was no reactivity with some basement membranes, notably those of several smooth muscle types and cardiac muscle. In addition, it was found that pancreatic acinar basement membranes also lacked the HSPG type recognized by this antiserum. Those basement membranes that lacked the HSPG strongly stained with antisera against laminin and type IV collagen. The striking distribution pattern is possibly indicative of multiple species of basement membrane HSPGs of which one type is recognized by this antiserum. Further evidence for multiple HSPGs was derived from the finding that skeletal neuromuscular junction and liver epithelia also did not contain this type of HSPG, though previous reports have indicated the presence of HSPGs at these sites. The PYS-2 HSPG was shown to be antigenically related to the large, low buoyant density HSPG from the murine Engelbreth-Holm swarm tumor. It was, however, confirmed that only a single population of antibodies was present in the serum. Despite the presence of similar epitopes on these two proteoglycans of different hydrodynamic properties, it was apparent that the PYS-2 HSPG represents a basement membrane proteoglycan of distinct properties reflected in its restricted distribution in vivo.     

Lack of heparan sulfate proteoglycan in a discontinuous and irregular placental basement membrane

A discontinuous basement membrane of variable width that surrounds spongiotrophoblast cells of rat placenta was examined for the presence of type IV collagen, laminin, a heparan sulfate proteoglycan, entactin, and fibronectin using monospecific antibodies or antisera and the indirect peroxidase technique. At the level of the light microscope, the basement membrane was immunostained for type IV collagen, laminin, entactin, and fibronectin. Heparan sulfate proteoglycan immunostaining, however, was virtually absent even after pretreatment of sections with 0.1 N acetic acid, pepsin (0.1 microgram/ml) or 0.13 M sodium borohydride. Examination in the electron microscope confirmed the lack of immunostaining for heparan sulfate proteoglycan, whereas the other substances were mainly localized to the lamina densa part of the basement membrane. The absence of heparan sulfate proteoglycan in this discontinuous and irregular basement membrane even though type IV collagen, laminin, entactin, and fibronectin are present, suggests that heparan sulfate proteoglycan may have a structural role in the formation of basement membrane.     

Identification of cDNA clones encoding different domains of the basement membrane heparan sulfate proteoglycan

We have used antibodies to the basement membrane proteoglycan to screen lambda gt11 expression vector libraries and have isolated two cDNA clones, termed BPG 5 and BPG 7, which encode different portions of the core protein of the heparan sulfate basement membrane proteoglycan. These clones hybridize to a single mRNA species of approximately 12 kilobases. Amino acid sequences obtained on peptides derived from protease digests of the core protein were found in the deduced sequence, confirming the identity of these clones. BPG 5 spanned 1986 base pairs and has an open reading frame of 662 amino acids. The amino acid sequence deduced from BPG 5 contains two cysteine-rich domains and two internally homologous domains lacking cysteine. The cysteine-rich domains show homology to the cysteine-rich domains of the laminin chains. A globule-rod structure, similar to that of the short arms of the laminin chains, is proposed for this region of the proteoglycan. The other clone, BPG 7, is 2193 base pairs long and has an open reading frame of 731 amino acids. The deduced sequence contains eight internal repeats with 2 cysteine residues in each repeat. These repeats show homology to the neural-cell adhesion molecule N-CAM and the plasma alpha 1B-glycoprotein. Looping structures similar to these proteins and to other proteins of the immunoglobulin gene superfamily are proposed for this region of the proteoglycan. The sequence DSGEY was found four times in this domain and could be heparan sulfate attachment sites.     

Structure of low density heparan sulfate proteoglycan isolated from a mouse tumor basement membrane

A large heparan sulfate proteoglycan of low buoyant density (p = 1.32 to 1.40 g/cm3 in 6 M-guanidine.HCl) was extracted from a tumor basement membrane with denaturing solvents and purified by chromatography and CsCl gradient centrifugation. Chemical, immunological, physical and electron microscopical analyses have demonstrated a high degree of purity and have allowed us to propose a structural model for this proteoglycan. It is composed of an 80 nm long protein core formed from a single polypeptide chain (Mr about 500,000) with intrachain disulfide bonds. This core is folded into a row of six globular domains of variable size as shown by electron microscopy after rotary shadowing and negative staining. A multidomain structure was confirmed by protease digestion experiments that allowed the isolation of a single heparan sulfate-containing peptide segment representing less than 5% of the total mass of the protein core. Electron microscopy has visualized generally three heparan sulfate chains in each molecule close to each other at one pole of the protein core. The molecular mass and length (100 to 170 nm) of the heparan sulfate chains were found to vary consistently between different preparations. The mass per length ratio (350 nm-1) indicated an extended conformation for the heparan sulfate side-chains. These structural features are distinctly different from those of the high density proteoglycan, suggesting that both forms of basement membrane heparan sulfate proteoglycan are genetically distinct and not derived from a common precursor.     

Self-assembly of a high molecular weight basement membrane heparan sulfate proteoglycan into dimers and oligomers

A high molecular weight basement membrane heparan sulfate proteoglycan, isolated from murine Englebreth-Holm-Swarm tumor, is seen in platinum replicas as an elongated flexible core (Mr = 450,000) consisting of a series of tandem globular domains from which extend, at one end, two to three heparan sulfate chains (average Mr = 80,000 each). This macromolecule will self-assemble into dimers and lesser amounts of oligomers when incubated in neutral isotonic buffer. These molecular species can be separated by zonal velocity sedimentation and assembly is seen to be time- and concentration-dependent. In rotary-shadowed platinum replicas the binding region is found at or near the end of the core at the pole opposite the origin of the heparan sulfate chains. Dimers are double-length structures and oligomers are seen as stellate clusters: in both, the heparan sulfate chains appear peripherally oriented. While isolated cores self-assemble, isolated heparan sulfate chains do not bind intact proteoglycans. Furthermore, proteolytic removal of a non-heparan sulfate containing core moiety destroys the ability of the proteoglycan monomer to form larger species or bind intact proteoglycan, further supporting the binding topography determined morphologically. These negatively charged macromolecular complexes may be important contributors to basement membrane structure and function.     

Structure and affinity for antithrombin of heparan sulfate chains derived from basement membrane proteoglycans

Metabolically 35S- or 3H-labeled heparan sulfate was isolated from murine Reichert's membrane, an extraembryonic basement membrane produced by parietal endoderm cells, and from the basement membrane-producing Engelbreth-Holm-Swarm mouse tumor. The polysaccharides were subjected to structural analysis involving identification of products formed on deamination of the polysaccharides with nitrous acid. The polysaccharide from Reichert's membrane contained N- and O-sulfate groups in approximately equal proportions. It bound almost quantitatively and with high affinity to antithrombin. A high proportion of antithrombin-binding sequence was also indicated by the finding that 3-O-sulfated glucosamine residues accounted for about 10% of the total O-sulfate groups. In contrast, at least 80% of the sulfate residues in the heparan sulfate isolated from the mouse tumor were N-substituents. Only a minor proportion of this polysaccharide bound with high affinity to antithrombin, and no 3-O-sulfated glucosamine residues were detected. These results are discussed in relation to the possible functional role of heparan sulfate in basement membranes.     

Structure and interactions of heparan sulfate proteoglycans from a mouse tumor basement membrane

Various forms of heparan sulfate proteoglycan were solubilized from the mouse Engelbreth-Holm-Swarm (EHS) sarcoma by extraction with 0.5 M NaCl, collagenase digestion and extraction with 4 M guanidine. They could be separated into high (greater than or equal to 1.65 g/ml) and low (1.38 g/ml) buoyant density variants. The high-density form from the NaCl extract and collagenase digest had Mr = 130000 and So20,W = 4.5 S and contained 4-10% protein, indicating Mr = 5 000-12 000 for the protein core. This proteoglycan exhibited polydispersity as shown by rotary shadowing electron microscopy and ultracentrifugation. An average molecule consisted of four heparan sulfate chains (Mr = 29 000) each with a length of 32 +/- 10 nm. The low-density form (Mr about 400 000) could not be completely purified and contained about 50% protein. As shown by radioimmunoassay, the various proteoglycans shared similar protein cores. Labeling of the tumor in vivo or in vitro demonstrated preferential incorporation of radioactive sulfate in the high-density form. The high-density proteoglycan interacted in affinity chromatography by virtue of its heparan sulfate chains with laminin, fibronectin, the globular domain NC1 and the triple helix of collagen IV. These interactions were abolished at moderate concentrations of NaCl (0.1-0.2 M) and in the presence of heparin, chondroitin sulfate or dextran sulfate. Interactions with the globule NC1 could also be demonstrated by velocity band centrifugation in sucrose gradients and a binding constant of about 10(6) M-1 was derived.     

Deletion of the basement membrane heparan sulfate proteoglycan type XVIII collagen causes hypertriglyceridemia in mice and humans

Background

Lipoprotein lipase (Lpl) acts on triglyceride-rich lipoproteins in the peripheral circulation, liberating free fatty acids for energy metabolism or storage. This essential enzyme is synthesized in parenchymal cells of adipose tissue, heart, and skeletal muscle and migrates to the luminal side of the vascular endothelium where it acts upon circulating lipoproteins. Prior studies suggested that Lpl is immobilized by way of heparan sulfate proteoglycans on the endothelium, but genetically altering endothelial cell heparan sulfate had no effect on Lpl localization or lipolysis. The objective of this study was to determine if extracellular matrix proteoglycans affect Lpl distribution and triglyceride metabolism.

Methods and Findings

We examined mutant mice defective in collagen XVIII (Col18), a heparan sulfate proteoglycan present in vascular basement membranes. Loss of Col18 reduces plasma levels of Lpl enzyme and activity, which results in mild fasting hypertriglyceridemia and diet-induced hyperchylomicronemia. Humans with Knobloch Syndrome caused by a null mutation in the vascular form of Col18 also present lower than normal plasma Lpl mass and activity and exhibit fasting hypertriglyceridemia.

Conclusions

This is the first report demonstrating that Lpl presentation on the lumenal side of the endothelium depends on a basement membrane proteoglycan and demonstrates a previously unrecognized phenotype in patients lacking Col18.     

Isolation, characterization and immunological determination of basement membrane-associated heparan sulfate proteoglycan

Basement membrane-associated heparan sulfate proteoglycan (HSPG) was extracted from isolated porcine glomerular basement membranes and purified by ion-exchange chromatography. The proteogycan was characterized by specific enzymatic digestions, by amino-acid analysis, by SDS-polyacrylamide gel electrophoresis and by density gradient centrifugation. Polyclonal antibodies were raised against the purified HSPG in rabbits. Antibodies were characterized by enzyme immunoassays, immunoprecipitation and immunohistological methods. They were shown to recognize specifically the core protein of HSPG from porcine, human and rat glomerular basement membrane but did not recognize HSPG from guinea pig or rabbit kidney. The affinity-purified antibodies did not cross-react with other basement membrane proteins like laminin, fibronectin or collagen type IV nor with chondroitin sulfate-rich or keratan sulfate-rich proteoglycans from human or bovine tissue. Using these antibodies an enzyme immunoassay was developed for determination of HSPG in the range of 1-100 ng/ml. Studies with cultured porcine endothelial cells showed that subendothelial basement membrane-associated HSPG may be determined with the enzyme immunoassay.     

High concentrations of low density lipoprotein decrease basement membrane-associated heparan sulfate proteoglycan in cultured endothelial cells

The effect of increasing low density lipoprotein (LDL) concentrations on the synthesis of basement membrane components was investigated in proliferating porcine aortic endothelial cells (PAEC) in culture. Basement membrane-associated heparan sulfate proteoglycan (HSPG) and fibronectin were determined by enzyme immunoassay. Low extracellular LDL-levels increase, high extracellular LDL-levels decrease the HSPG content of PAEC. Fibronectin synthesis was only slightly affected while proliferation and metabolic activity as assessed by lactate production were constant. Insulin or high extracellular glucose did not influence the effect of LDL on basement membrane components.     

Collagen XVIII,a basement membrane heparan sulfate proteoglycan,interacts with L-selectin and monocyte chemoattractant protein-1

Leukocyte infiltration during inflammation is mediated by the sequential actions of adhesion molecules and chemokines. By using a rat ureteral obstruction model, we showed previously that L-selectin plays an important role in leukocyte infiltration into the kidney. Here we report the purification, identification, and characterization of an L-selectin-binding heparan sulfate proteoglycan (HSPG) expressed in the rat kidney. Partial amino acid sequencing and Western blotting analyses showed that the L-selectin-binding HSPG is collagen XVIII, a basement membrane HSPG. The binding of L-selectin to isolated collagen XVIII was specifically inhibited by an anti-L-selectin monoclonal antibody, EDTA, treatment of the collagen XVIII with heparitinase or heparin but not by chemically desulfated heparin. A cell binding assay showed that the L-selectin-collagen XVIII interaction mediates cell adhesion. Interestingly, collagen XVIII also interacted with a chemokine, monocyte chemoattractant protein-1, and presented it to a monocytic cell line, THP-1, which enhanced the alpha(4)beta(1) integrin-mediated binding of the THP-1 cells to vascular cell adhesion molecule-1. Thus, collagen XVIII may provide a link between selectin-mediated cell adhesion and chemokine-induced cellular activation and accelerate the progression of leukocyte infiltration in renal inflammation.