Identification of the precursor protein to basement membrane heparan sulfate proteoglycans

Glypicans and Heparan Sulfate in Synaptic Development, Neural Plasticity, and Neurological Disorders

Heparan sulfate proteoglycans (HSPGs) are components of the cell surface and extracellular matrix, which bear long polysaccharides called heparan sulfate (HS) attached to the core proteins. HSPGs interact with a variety of ligand proteins through the HS chains, and mutations in HSPG-related genes influence many biological processes and cause various diseases. In particular, recent findings from vertebrate and invertebrate studies have raised the importance of glycosylphosphatidylinositol-anchored HSPGs, glypicans, as central players in the development and functions of synapses. Glypicans are important components of the synapse-organizing protein complexes and serve as ligands for leucine-rich repeat transmembrane neuronal proteins (LRRTMs), leukocyte common antigen-related (LAR) family receptor protein tyrosine phosphatases (RPTPs), and G-protein-coupled receptor 158 (GPR158), regulating synapse formation. Many of these interactions are mediated by the HS chains of glypicans. Neurexins (Nrxs) are also synthesized as HSPGs and bind to some ligands in common with glypicans through HS chains. Therefore, glypicans and Nrxs may act competitively at the synapses. Furthermore, glypicans regulate the postsynaptic expression levels of ionotropic glutamate receptors, controlling the electrophysiological properties and non-canonical BMP signaling of synapses. Dysfunctions of glypicans lead to failures in neuronal network formation, malfunction of synapses, and abnormal behaviors that are characteristic of neurodevelopmental disorders. Recent human genetics revealed that glypicans and HS are associated with autism spectrum disorder, neuroticism, and schizophrenia. In this review, we introduce the studies showing the roles of glypicans and HS in synapse formation, neural plasticity, and neurological disorders, especially focusing on the mouse and Drosophila as potential models for human diseases.

Hyaluronan induces the selective accumulation of matrix- and cell-associated proteoglycans by mesangial cells

Mesangial cells (MCs) are essential for normal renal function through the synthesis of their own extracellular matrix, which forms the structural support of the renal glomerulus. In many renal diseases this matrix is reorganized in response to a variety of cytokines and growth factors. This study examines proteoglycan and hyaluronan (HA) synthesis by MCs triggered by proinflammatory agents and investigates the effect of an exogenous HA matrix on matrix synthesis by MCs. Metabolic labeling, ion exchange and size exclusion chromatography, Western blotting, and immunocytochemistry were used to identify changes in matrix accumulation. When incubated with interleukin-1, platelet-derived growth factor, or fetal calf serum, MCs initiated rapid HA synthesis associated with the up-regulation of HA synthase-2 and increased the synthesis of versican, perlecan, and decorin/biglycan. HA was both released into the medium and incorporated into extensive pericellular coats. Adding exogenous HA to unstimulated cells that had undetectable pericellular coats of HA selectively reduced perlecan and versican turnover, whereas other proteoglycans were unaffected. These results suggest that high levels of HA in the mesangium in disease is a mechanism controlling the accumulation of specific mesangial matrix components. HA may thus be an attractive target for therapeutic intervention.

Vascular cell proteoglycans: evidence for metabolic modulation

Proteoglycans accumulate in the intimal layer of blood vessels during the early stages of atherosclerosis and predispose the vessel wall to further complications of this disease. Arterial endothelial and smooth muscle cell cultures have been used to study the metabolism of vessel wall proteoglycans in an attempt to determine whether cellular events associated with the genesis of this disease, such as cellular proliferation, ageing, migration and interaction with components of the extracellular matrix, influence the metabolism of arterial proteoglycans. Proteoglycan analyses of vascular cells reveal that endothelial cells synthesize multiple species of heparan sulphate proteoglycan while smooth muscle cells synthesize little heparan sulphate proteoglycan but significant quantities of chondroitin and dermatan sulphate proteoglycan. Each family of proteoglycans synthesized by each cell type differs with regard to charge density, hydrodynamic size, glycosaminoglycan type and size, oligosaccharide content and ability to form high molecular weight aggregates. A monoclonal antibody has been generated against the chondroitin sulphate proteoglycan and used to immunolocalize this antigen to the interstitial matrix of normal and diseased blood vessels. Experiments are presented to indicate that proteoglycan metabolism is modulated when cultured arterial cells are stimulated to proliferate and migrate. Other factors shown to influence proteoglycan metabolism include the age of the cell and the nature of the substratum upon which the cells are grown. These culture systems provide useful models with which to study the factors involved in the regulation of proteoglycan synthesis by vascular cells.

Biosynthesis and structure of the basement membrane proteoglycan containing heparan sulphate side-chains

Endothelial, epithelial and muscle cells produce a similar proteoglycan for deposition in basement membrane. This proteoglycan is initially synthesized as a low buoyant density proteoglycan containing 3-5 heparan sulphate side-chains (15,000-65,000 Mr each), along one half of a 400,000 Mr core protein. A portion of the population of these macromolecules is degraded to produce small high density proteoglycans containing a variable-sized core protein less than 100,000 in Mr. This biosynthetic and degradative process probably accounts for the variety of differently sized heparan sulphate proteoglycans that have been isolated from various basement membrane sources.

Structure and function of basement membrane proteoglycans

Basement membranes contain at least three different proteoglycans. These are a large, low buoyant density heparan sulphate proteoglycan and two smaller, high density proteoglycans with either heparan sulphate or chondroitin sulphate side-chains. The large (Mr 400K-600K and small (Mr 130K) heparan sulphate proteoglycans were purified from the mouse EHS tumour. These proteoglycans are immunologically related by sharing some protein core antigenic determinants (epitopes) but do not cross-react with cell-surface heparan sulphate proteoglycans or with proteoglycans from interstitial connective tissue. This indicates that they belong to a distinct family of proteoglycans. Structural models were developed, based on electron microscopy and analytical ultracentrifugation, demonstrating that the small proteoglycan contains on average four heparan sulphate chains of about 30 nm in length, while the large proteoglycan consists of three long (about 90 nm) heparan sulphate chains connected to one end of a large core protein. Single heparan sulphate chains were isolated from the EHS tumour proteoglycans and from the corresponding proteoglycans from Reichert's membrane of the mouse embryo. The heparan sulphate from Reichert's membrane bound to antithrombin with high affinity and was found to contain the unique 3-O-sulphated glucosamine residue previously identified in the antithrombin-binding region of heparin. The EHS tumour heparan sulphate showed a higher N-/O-sulphate ratio and a lower affinity for antithrombin.

The functions of the heparan sulphate proteoglycans

Heparan sulphate (HS)-containing proteoglycans (HS-PGs) are present at the surface of nearly all adherent mammalian cells. The principal mode of attachment is by way of the protein core which is inserted into the plasma membrane. Other forms of HS-PG may be components of pericellular matrices, notably basement membranes. The core proteins of HS-PGs can be small (35K) as in hepatocytes, intermediate (50K) as in many mesenchymal cells, or very large (400K) as in basement membranes. A special case is the HS-PG synthesized by postconfluent fibroblasts. This proteoglycan has a core protein that closely resembles the transferrin receptor glycoprotein. It is possible that this HS-PG is a pro-form of the receptor. Low molecular weight, carbohydrate-rich HS-PG forms are probably derived from larger forms by partial degradation. The HS side-chains can contain 24 different disaccharides in an unknown number of arrangements. The biosynthetic machinery can impose considerable restrictions; for example, the extent of N-sulphation rarely exceeds 40-50%, whereas O-sulphation may range from 20% to 75% of potential sites. Nevertheless, the informational capacity of HS is formidable. By way of the HS chains, HS-PG at the surface of endothelial cells can interact specifically or selectively with a number of plasma proteins. HS-PG at the surface of matrix-producing cells is similarly in a position to interact with matrix proteins, notably collagen, fibronectin and laminin. As the cytoplasmic portion of the HS-PG core protein can bind actin, this proteoglycan can provide a connection between extracellular matrices and the cytoskeleton. A number of studies support a role for HS-PGs in the control of cell growth, and this could be one of their major functions. Whether the HS side-chains or the core protein or both are carrying out such a function remains to be determined.

Changes in perlecan during chondrocyte differentiation in the fetal bovine rib growth plate

Perlecan is a heparan sulfate proteoglycan present in the growth plate and essential for endochondral ossification. We evaluated the synthesis and structure of perlecan in the different zones of the growth plate. The growth plates from fetal bovine ribs were isolated and sequentially sliced into 1-mm sections containing the hypertrophic zone, lower proliferative zone, upper proliferative zone, intermediate zone, and resting zone, respectively. The slices were then either incubated in culture medium with 35SO4 to measure total sulfated proteoglycan synthesis and perlecan synthesis, extracted for perlecan core protein analysis by Western blot, or extracted for perlecan isolation and subsequent characterization of glycosaminoglycan size and disaccharide composition. 35SO4 incorporation into perlecan was three-fourfold higher in the proliferating/hypertrophic zone than the resting zone. Western blot showed perlecan content was greatest in the lower and upper proliferating zones and that a perlecan fragment lacking portions of the N- and C-terminal domains containing heparan sulfate was also present in all zones. Purified perlecan from the hypertrophic/lower proliferative zone had larger chondroitin sulfate chains and a different composition of CS and HS disaccharides than the perlecan isolated from the resting zone. These results indicate perlecan deposition is increased and is turned over during proliferation to be replaced by a perlecan with a different sulfation pattern.

Ribozyme-mediated perlecan knockdown impairs chondrogenic differentiation of C3H10T1/2 fibroblasts

Perlecan (Pln) is an abundant heparan sulfate (HS) proteoglycan in the pericellular matrix of developing cartilage, and its absence dramatically disrupts endochondral bone formation. This study examined two previously unexamined aspects of the function of Pln in mesenchymal chondrogenesis in vitro. Using the well-established high-density micromass model of chondrogenic differentiation, we first examined the requirement for endogenous Pln synthesis and secretion through the use of Pln-targeted ribozymes in murine C3H10T1/2 embryonic fibroblasts. Second, we examined the ability of the unique N-terminal, HS-bearing Pln domain I (PlnDI) to synergize with exogenous bone morphogenetic protein-2 (BMP-2) to support later stage chondrogenic maturation of cellular condensations. The results provide clear evidence that the function of Pln in late stage chondrogenesis requires Pln biosynthesis and secretion, because 60%-70% reductions in Pln greatly diminish chondrogenic marker expression in micromass culture. Additionally, these data support the idea that while early chondrocyte differentiation can be supported by exogenous HS-decorated PlnDI, efficient late stage PlnDI-supported chondrogenesis requires both BMP-2 and Pln biosynthesis.

Heparan sulfate proteoglycans: Coordinators of multiple signaling pathways during chondrogenesis

Heparan sulfate proteoglycans are abundantly expressed in the pericellular matrix of both developing and mature cartilage. Increasing evidence indicates that the action of numerous chondroregulatory molecules depends on these proteoglycans. This review summarizes the current understanding of the interactions of heparan sulfate chains of cartilage proteoglycans with both soluble and nonsoluble ligands during the process of chondrogenesis. In addition, the consequences of mutating genes encoding heparan sulfate biosynthetic enzymes or heparan sulfate proteoglycan core proteins on cartilage development are discussed.

Response of primary rabbit kidney proximal tubule cells to estrogens

The effects of estrogens on the growth and function of primary rabbit kidney proximal tubule (RPT) cells have been examined in hormonally defined phenol red-free medium. 17beta-estradiol was observed to stimulate growth at dosages as low as 10(-10) M. The growth stimulatory effects of 17beta-estradiol were mitigated in the presence of hydrocortisone, suggesting that these two steroid hormones acted at least in part by common mechanisms. The effects of other steroids known to interact with the estrogen receptor were examined. Alpha estradiol was found to be growth stimulatory over a concentration range of 10(-9) to 10(-8) M, albeit to a lower extent than beta estradiol. In addition, the anti-estrogen tamoxifen was also growth stimulatory (unlike the case with the human mammary tumor cell line MCF-7). The effects of several metabolic precursors of 17beta-estradiol were examined, including testosterone, which was growth stimulatory, and progesterone, which was growth inhibitory. The growth stimulatory effects of 17beta-estradiol, alpha estradiol, and tamoxifen could possibly be explained by their interaction with an estrogen receptor. Indeed, metabolic labelling and immunoprecipitation studies indicated the presence of such an estrogen receptor in the primary cultures. The rate of biosynthesis of the estrogen receptor was found to be affected by the presence of exogenously added 17beta-estradiol. 17beta-estradiol was also observed to increase the activity of two brush border enzymes, alkaline phosphatase and gamma glutamyl transpeptidase, during the growth phase of the primary cultures.

Non-glycosaminoglycan bearing domains of perlecan and aggrecan influence the utilization of sites for heparan and chondroitin sulfate synthesis

Perlecan and aggrecan are proteoglycans that receive primarily heparan sulfate and chondroitin sulfate side chains, respectively. Their large multidomained core proteins have little or no homology to each other and their glycosaminoglycan (GAG) attachment sites are restricted to certain domains only. We examined the involvement of the non-GAG bearing domains in designating the GAG type added to the GAG attachment domain by preparing cDNA constructs that expressed perlecan/aggrecan chimeras as recombinant products in COS-7 cells and then determining the size and GAG composition of the recombinant products. The results showed that domain I of perlecan receives primarily (73-81%) heparan sulfate when coupled with domain II and III of perlecan, but when coupled with the G3 domain of aggrecan, it receives primarily (59-63%) chondroitin sulfate. Furthermore, the chondroitin sulfate attachment region of aggrecan received GAG side chains more readily when coupled to the G3 domain of aggrecan than when coupled to domains II and III of perlecan. The GAG side chains on all these recombinant products were small and similar in size. These findings indicate that the utilization of attachment sites for heparan and chondroitin sulfate or the sulfation of these GAGs can be influenced, in part, by non-GAG bearing domains.

Expression of perlecan, a proteoglycan that binds myogenic inhibitory basic fibroblast growth factor, is down regulated during skeletal muscle differentiation

Heparan sulfate proteoglycans (HSPG) have been shown to be involved in the activation of tyrosine kinase receptors by basic fibroblasts growth factor (bFGF), a strong inhibitor of skeletal muscle differentiation. Skeletal muscle fibers contact extracellular matrix (ECM) that surrounds individual fibers (endomysium) and bundles of several fibers (perimysium). Perlecan is a HSPG present in the majority of basement membranes. In this study we evaluated the expression and localization of perlecan during differentiation of C2C12 skeletal muscle cells. C2C12 myoblasts incubated with [35S]Na2SO4 synthesize a HSPG that can be specifically immunoprecipitated with antibodies against murine perlecan. The immunoprecipitated HSPG eluted from a Sepharose CL-4B with a Kav of 0.44. Analysis of the core protein of the HSPG immunoprecipitated from [35S]methionine-labeled C2C12 after treatment with heparitinase revealed two polypeptides of 170 and over 300 kDa. The amount of polypeptides immunoprecipitated decreased with muscle differentiation. Immunocytolocalization studies indicate that perlecan is localized on the myoblast surface and by immunogold staining we have demonstrated that it is associated with patches of incipient extracellular matrix. The expression of perlecan mRNA decreased substantially during skeletal muscle differentiation, in contrast to the increase in transcripts for specific skeletal muscle proteins such as myogenin and creatine kinase. By immunofluorescence microscopy almost no perlecan staining associated with the surface of myotubes was observed. All these results suggests that perlecan, a HSPG that binds myogenic inhibitory bFGF, normally associated with basement membranes in adult tissues is present on the surface of myoblasts and its expression is down regulated during skeletal muscle differentiation.

Identification of sites in domain I of perlecan that regulate heparan sulfate synthesis

Perlecan is primarily a heparan sulfate containing proteoglycan found in all basement membranes. Rotary shadowed images of perlecan show it to contain three glycosaminoglycan (GAG) side chains extending from one end of its core protein. Domain I is at the N terminus of perlecan and contains three closely spaced Ser-Gly-Asp sequences that may serve in GAG attachment. We evaluated the serines in these three sequences for GAG attachment by preparing a cDNA construct encoding for the N-terminal half (domains I, II, and III) of perlecan and then a series of constructs containing deletions and mutations within domain I of the domain I/II/III construct, expressing these constructs in COS-7 cells, and then analyzing the recombinant product for GAG side chains and GAG type. The results showed that all three serine residues in the Ser-Gly-Asp sequences in domain I can accept both chondroitin and heparan sulfate side chains but that a cluster of acidic residues N-terminal to these sequences is the primary determinant responsible for targeting these sites for heparan sulfate. Furthermore, there are two elements that can enhance heparan sulfate synthesis at a targeted site: 1) the presence of a the SEA module in the C-terminal region of domain I and 2) the presence of multiple acceptors in close proximity. These results indicate that the proportion of heparan and chondroitin sulfate at any one site in domain I of perlecan is regulated by multiple factors.

A proteoglycan that activates fibroblast growth factors during early neuronal development is a perlecan variant

Cells in the early embryonic vertebrate nervous system are dependent on members of the fibroblast growth factor (FGF) family for their proliferation and subsequent differentiation. These growth factors will only bind to their specific high affinity cell surface receptors after formation of a ternary complex with the glycosaminoglycan heparan sulfate. Such specific heparan sulfates are secreted as proteoglycans from neural precursor cells and localise to their surfaces. One such proteoglycan, HSPG-PRM (Perlecan-related molecule), was isolated through its ability to potentiate neural cell responses to either FGF-1 or FGF-2. In this study, we have verified the relative molecular mass of the core protein of PRM as 45,000 and obtained partial amino acid sequence from it. The sequences bore significant homology to native perlecan. A probe generated by reverse transcriptase polymerase chain reaction using oligonucleotides designed from the protein sequence used on northern blots of RNA from a neuroepithelial cell line detected perlecan at 12.6 kilobases, as well as novel transcripts at 6.5 and 3.5 kilobases. The latter species appears by virtue of its size and abundance to be the novel PRM transcript. PRM appears to be encoded by the same gene as perlecan, as genomic Southern blotting only detected a single gene. Polyclonal antibodies raised against the PRM molecule detected a single proteoglycan species at 290x10(3) with a core protein of 45x10(3). Polyclonal anti-perlecan antibodies cross-reacted with PRM confirming their relatedness, although immunohistochemical studies revealed a differential staining pattern for PRM as compared to perlecan within the developing nervous system. The PRM molecule was shown to be localised to several different tissues of the developing embryo, indicating that it plays a broad role. We conclude that PRM is a variant of perlecan that is differentially glycosylated in a manner that confers highly specific functions at critical stages of neural development and tissue growth.

Regulation of basement membrane heparan sulfate proteoglycan, perlecan, gene expression in glomerular epithelial cells by high glucose medium

Proteinuria in diabetic nephropathy has been correlated with reduction in heparan sulfate proteoglycan (HSPG) content of the glomerular basement membrane. We have previously shown that the underlying mechanism probably involves reduction in the synthesis by glomerular epithelial cells. In this study we explored whether high glucose medium regulates basement membrane HSPG gene expression. Northern analysis demonstrated that rat glomerular epithelial cells in vitro constitutively express mRNA for basement membrane HSPG, similar to that observed in rat kidney glomerulus. RNase protection assay showed that incubation of glomerular epithelial cells with 30 mM glucose for 24 h and 7 days resulted in reduction in HSPG mRNA abundance. The decrease in mRNA abundance correlated with reduction in the synthesis of 35SO4-labeled basement membrane HSPG as measured by immunoprecipitation. Reduction in synthesis of HSPG could not be entirely accounted for by decrease in mRNA abundance, suggesting both transcriptional and posttranscriptional mechanisms may be involved in reduction of glomerular basement membrane HSPG synthesis by glomerular epithelial cells in diabetic nephropathy.

Effects of the N-terminal cysteine mutation on prolactin expression and secretion in transfected cells

We developed an experimental cell model to look for motif(s) of rat PRL sequence encoding a sorting signal to secretory granules. An efficient expression vector (pCMV-rPRL) was used to transfect several eukaryotic cell lines in culture, i.e., one neuronal cell line (C6) and three glandular pituitary derived cell lines (AtT20, GC, GH3CDL). Despite the ubiquitous transcription of pCMV-rPRL, the synthesis and secretion of rPRL were detected primarily in GH3CDL cells that derived from lactotrophs, suggesting a cell-specific post-transcriptional control of rPRL expression. During transient expression, exogenous native PRL was transported through intracellular compartments of the secretory pathway and underwent regulated release. Abolition by mutagenesis (C4S) of the N-terminal disulfide bond increased by 50% the PRL secretion rate (medium to cell ratio) and multiplied by 5 the specific activity of medium PRL from pulse-labeled cells. These results support the hypothesis that N-terminal disulfide bond plays a role in the control of PRL intracellular transit and storage.

Family study of atypical nevi with investigation of heparin sulfate proteoglycan

BACKGROUND

The epidemiology of atypical nevi (AN) is currently obscure; however the diagnosis must be made early in order to follow these individuals and treat any melanomas that may arise at an early stage, thus preventing premature death.

MATERIALS AND METHODS

Following the guidelines of the NIH on clinical and histologic features of ANS, 38 adult members in 8 families were investigated. Twenty-seven were physically examined and 25 biopsied. Biopsies from ANS and junctional nevi from unrelated persons were also stained with antibodies against heparan sulfate proteoglycan (HSPG).

RESULTS

At least 21 of 38 members had ANS. Staining with HSPG antibodies did not differentiate between ANS and benign junctional nevi, all showing slightly irregular staining. In seven of eight families, two or more family members were affected by ANS.

CONCLUSIONS

Although it is not known whether or not HSPG plays a role in melanomas becoming invasive, or the potential of melanoma developing in ANS there were no differentiating features of staining in ANS, and junctional nevi to help in the differential-diagnosis of the two.

Perlecan is a component of cartilage matrix and promotes chondrocyte attachment

Aggrecan, a chondroitin/keratan sulfate-containing proteoglycan, is a major component of cartilaginous tissues. Immunolocalization studies, using antibodies directed to perlecan, a heparan sulfate proteoglycan first detected in basement membranes, and laminin (another major component of basement membranes), indicate that perlecan and laminin are also present in the matrices of hyaline cartilage in the nasal septum, the articular surface of the bone and the growth plate of the developing bone. Consequently, we used antibodies to both aggrecan and perlecan to characterize their synthesis and secretion by primary cultures of chondrocytes derived from the rat chondrosarcoma. Chondrocytes were pulsed for 20 minutes with [35S]methionine and then chased for up to six hours. The radiolabeled perlecan and aggrecan were immunoprecipitated and analyzed by SDS-PAGE. The results show that chondrocytes synthesize precursor proteins to both proteoglycans, but that only the aggrecan precursor protein is secreted as a proteoglycan. Perlecan was also secreted but with less posttranslational modifications than aggrecan. Northern blot analyses of the RNAs from immortalized rat chondrocytes indicated that the major mRNA encoding for perlecan was approximately 13 kb in length, similar in size to that expressed by other cell types, which synthesize 400 kDa core protein perlecan. Analyses of the proteoglycan fractions from the extracts of bovine articular surface indicated that perlecan in this tissue contains both chondroitin and heparan sulfate side-chains. Purified perlecan and laminin were found to promote attachment of immortalized rat chondrocytes in vitro. These studies indicated that perlecan, once thought to be a unique component of the basement membranes, is more widely distributed and is an important component of the cartilage matrix, where it may provide for cell adhesion to the matrix.

The interaction of vascular endothelial cells and dorsal root ganglion neurites is mediated by vitronectin and heparan sulfate proteoglycans

The interaction of peripheral nerve and blood vessels during development was studied by using DRG explant culture plated on confluent monolayer of vascular endothelial cells (VEC). The comparison of neurite length on various substrates showed a preference of DRG neurites in the following order; thrombospondin > laminin, vitronectin > fibronectin, VEC monolayer > collagen I, rat astrocyte monolayer. On layers of fibroblasts (3T3) or gliomas (C6), neurite extension was not observed. To identify the neurite outgrowth promoting adhesion molecules on VEC surface, several antibodies and synthetic peptides were added to the culture medium of DRG. With vitronectin antibody or with peptides containing the Arg-Gly-Asp (RGD) sequence, 30-40% of neurite outgrowth was inhibited and these two effects were not additive. Therefore, a part of neurite outgrowth in this system is mediated by vitronectin in RGD dependent manner. Another molecule which promotes neurite outgrowth on VEC was identified by a new monoclonal antibody (MAb) EC1. In the Western blot analysis, the immunoreactive band which was over 400 kDa was intensified by guanidine HCl extraction. EC1 immunoreactive band disappeared after the treatment of heparitinase but not with other glycolyases, indicating that EC1 antigen is heparan sulfate proteoglycan(s). The DRG neurite outgrowth was inhibited by MAb EC1 by about 30-40%. By the combination of MAb EC1 and RGD peptide, the neurite outgrowth in explant culture was inhibited by about 50%, and in DRG dissociated culture nearly 100% inhibition was observed. Thus, for the DRG neurite elongation on VEC, vitronectin and heparan sulfate proteoglycan(s) are playing crucial roles.

Recombinant domain III of perlecan promotes cell attachment through its RGDS sequence

Perlecan has been previously been shown to support attachment of a wide variety of cells through interactions of its core protein with the cell surface. The core protein domains involved in cell adhesion are, however, unknown. The laminin-like domain III of murine perlecan contains an RGDS sequence and is a likely candidate for supporting integrin-mediated cell attachment. We made a cDNA construct corresponding to domain III and containing an in frame signal peptide at the 5' end as well as in frame a stop codon at the 3' end by using cDNA clones to perlecan. The construct was inserted into the pRC/CMV vector and transfected into HT1080 cells, and the secreted recombinant domain III, a 130-kDa protein, was purified from the medium. The size of proteolytic fragments produced by digestion with V8 protease as well as analysis of the rotary shadowed image of the recombinant protein indicated it was produced in a native conformation. Recombinant domain III coated on tissue culture dishes, supports adhesion of an epithelial-like mouse mammary tumor cell line MMT 060562 in a dose-dependent manner. This interaction was inhibited specifically by the RGDS synthetic peptide and intact perlecan, but not laminin. This domain III RGD-dependent cell attachment activity indicates a role for perlecan in integrin-mediated signaling.

Morphology of the basement membrane

The aim of this contribution is to summarize our knowledge of the morphology of the basement membrane (BM). The first step in this direction is the attempt to define this term. The BM is composed of the Lamina lucida, densa, and fibroreticularis. Subsequently, the historical development of this term is discussed. Our main interest is, of course, focused on the description of the BM-structure up to the macromolecular level and the special forms of this structure. This is supplemented by discussing its chemical composition and establishing a relationship between morphology and biochemistry. The obtained findings yielded some indications as to the molecular composition of the BM which may serve for the construction of "models." The composition of the Lamina lucida (L.l.) and the Lamina or Pars fibroreticularis (L.f.) must be discussed separately, since, if present, they show a different and strongly varying structure (L.f.). An important aspect is the function of this extracellular layer which comprises mechanical tasks up to inductive effects. Finally, the concepts of the formation of the BM, especially of the Lamina densa (L.d.), are summarized. It obviously consists of a sequence of individual steps which starts with expression and secretion of the L.d.-components and is followed by an induction of integrin expression.

Proteoglycans of basement membranes

Proteoglycans carrying either heparan sulfate and/or chondroitin sulfate side chains are typical constituents of basement membranes. The most prominent proteoglycan (perlecan) consists of a 400-500 kDa core protein and three heparan sulfate chains. Electron microscopy and cDNA sequencing show a complex and elongated domain structure for the core protein which in part is homologous to that of the laminin A chain. This structure may be varied by alternative splicing and proteolysis. Integration into basement membranes probably occurs by heparan sulfate binding to laminin and collagen IV, core protein binding to nidogen and by limited self assembly. The proteoglycan is in addition a cell-adhesive protein which is recognized by beta 1 integrins. Several more proteoglycans with smaller core proteins (10-160 kDa) apparently exist in basement membranes but are less well characterized. Biological functions include control of filtration through basement membranes and binding of growth factors and protease inhibitors.

Perlecan gene expression precedes laminin gene expression during differentiation of F9 embryonal carcinoma cells

F9 embryonal cells can be induced to differentiate and synthesize basement membrane proteins. Perlecan and laminin are two basement membrane constituents that have extensive regions of homology. Expression of perlecan and laminin B1 genes was followed during differentiation of F9 cells by measurements of transcription rate and mRNA abundance using nuclear run on assays and Northern hybridizations, respectively. The rate of precursor protein synthesis was determined by immunoprecipitation from lysates of pulse-labeled F9 cells. The results showed that perlecan gene expression responds more rapidly after induction than does laminin B1 gene expression but is ultimately expressed at a substantially lower level than laminin. Thus, the perlecan and laminin genes appear to be regulated by different mechanisms and their gene products are not made in stoichiometric amounts.

Proteoglycans of basement membranes

Proteoglycans carrying either heparan sulfate and/or chondroitin sulfate side chains are typical constituents of basement membranes. The most prominent proteoglycan (perlecan) consists of a 400-500 kDa core protein and three heparan sulfate chains. Electron microscopy and cDNA sequencing show a complex and elongated domain structure for the core protein which in part is homologous to that of the laminin A chain. This structure may be varied by alternative splicing and proteolysis. Integration into basement membranes probably occurs by heparan sulfate binding to laminin and collagen IV, core protein binding to nidogen and by limited self assembly. The proteoglycan is in addition a cell-adhesive protein which is recognized by beta 1 integrins. Several more proteoglycans with smaller core proteins (10-160 kDa) apparently exist in basement membranes but are less well characterized. Biological functions include control of filtration through basement membranes and binding of growth factors and protease inhibitors.

Purification of a basic fibroblast growth factor-binding proteoglycan from bovine cardiac plasma membrane

A heparan sulfate proteoglycan (HSPG) from bovine cardiac plasma membrane was purified to homogeneity using either isoelectric focusing or anion-exchange chromatography, followed by affinity chromatography on immobilized basic fibroblast growth factor (bFGF). Fractions were assayed for bFGF-binding activity using 125I-bFGF as a probe. Purified proteoglycan ran as a broad band on SDS-PAGE, spanning an apparent molecular mass range of 100-200 kDa, and could be incorporated into liposomes. Digestion of radioiodinated proteoglycan with heparitinase yielded a product of 73 kDa, while digestion with chondroitinase ABC did not change the apparent molecular mass. Monoclonal antibody directed against the ectodomain of another plasma membrane HSPG, syndecan, failed to recognize the purified cardiac proteoglycan on immunoblots. We conclude that adult bovine myocardium contains a membrane-associated bFGF-binding heparan sulfate proteoglycan containing little or no chondroitin sulfate and that this HSPG may be distinct from those of the syndecan family of heparan sulfate proteoglycans.

Perlecan, the large low-density proteoglycan of basement membranes: structure and variant forms

The complete primary structure of perlecan, the large low-density proteoglycan of basement membranes, has been deduced by cDNA cloning for the mouse and more recently the human gene products. Mouse perlecan contains a 396 kDa core protein with five distinct domains: a heparan sulfate attachment domain, a LDL receptor-like domain, two different laminin-like domains and an N-CAM-like domain. These domains are conserved to a striking degree between mouse and human, including alternate splicing of the N-CAM domain to generate variations of perlecan. These variant sequences also appear to be highly conserved between mouse and human. The strong conservation of these domains, including highly repetitive elements and potential alternative splices, suggest they have vital functions.

Transfection of murine P19S18 embryonal carcinoma cells with the oncogene neu induces an epithelioid phenotype* *This work was supported in part by American Cancer Society grant number IN-168

An embryonal carcinoma cell line, P19S18, was transfected with the rat oncogene neu to investigate the function of its protein product, p185*, in a multipotential cellular environment. Levels of message for p185* were determined by in situ hybridization analysis and two highly expressing clones, PnnA and PnnB, were isolated. As demonstrated by indirect immunofluorescence and immunoprecipitation, these neu-transfected cells synthesized a full length rat p185*. The transfectants do not resemble typical embryonal carcinoma cells either before or after differentiation is induced by retinoic acid treatment. They are much larger, flatter, "epithelioid" cells. These cells have lost the expression of stage specific embryonic antigen-1 (SSEA-1), but do synthesize and assemble the basement membrane components laminin and fibronectin. These results suggest that expression of the neu oncogene in a multipotential cell line may induce the synthesis of proteins indicative of an epithelioid phenotype due to the presence of p185*.

Interaction of basic fibroblast growth factor with bovine growth plate chondrocytes

The basic fibroblast growth factor (bFGF) family of peptides influences a wide range of cellular actions. To better understand the possible role of bFGF in the growth plate, we have characterized the interaction of this growth factor with isolated bovine growth plate chondrocytes. Basic FGF interacts with two classes of binding sites on these cells. One is consistent with high-affinity bFGF receptors and the other with low-affinity heparin-like binding sites on the chondrocyte surface. Radiolabeled bFGF binding studies revealed approximately 4 x 10(6) binding sites per cell, with a Kd of approximately 42 nM. Graded concentrations of heparin or NaCl competed with [125I]-labeled bFGF in a dose-dependent fashion, reducing [125I]-labeled bFGF binding by 75 and 97%, respectively. The data suggest the presence of a high-capacity, low-affinity class of binding sites with the properties of a heparin-like moiety. Affinity cross-linking of [125I]-labeled bFGF to chondrocytes labeled two principal species with apparent molecular masses of 135 and 160 kDa. Labeled bFGF was specifically displaced from both species by subnanomolar concentrations of unlabeled bFGF. These high-affinity, low-capacity binding sites are characteristic of classical bFGF receptors. Binding of [125I]-labeled bFGF to these sites was also influenced by heparin, consistent with coregulation of binding to the two classes of binding sites. The data suggest that bFGF participates in the regulation of skeletal growth at the growth plate and that this regulation may involve bFGF interaction with at least two distinct classes of binding sites.

Embryonic brain-derived heparan sulfate inhibits cellular membrane binding and biological activity of basic fibroblast growth factor

We have investigated the ability of glycosaminoglycans from embryonic chick brain (15 days old) to interact with basic fibroblast growth factor (bFGF). 35SO4 metabolically labeled glycosaminoglycans were purified and separated on DEAE-cellulose chromatography. Material which eluted between 0.20 and 0.35 M NaCl displaced the binding of [125I]bFGF to brain membrane. This activity was dose-dependent and on the basis to its heparinase sensitivity and chondroitinase insensitivity, has been attributed to heparan sulfate. CL-6B-Sepharose chromatography of this material revealed two glycosaminoglycans of molecular masses of about 15,000 and 65,000. Incubation with [125I]bFGF followed or not by heparinase and chondroitinase treatment of electrotransfert from SDS-PAGE revealed that both of these forms correspond to heparan sulfate chains and bind bFGF. In vitro, embryonic brain-derived heparan sulfate inhibited both bFGF induced [3H]thymidine incorporation in CCL39 cells and neurite outgrowth in PC12 cells. These results suggest that heparan sulfate play an important function in the control of the biological activity of bFGF during brain development.

Establishment of a cell line from the EHS tumor: biosynthesis of basement membrane constituents and characterization of a hybrid proteoglycan containing heparan and chondroitin sulfate chains

We have established a continuous cell line from the Engelbreth-Holm-Swarm (EHS) tumor, a transplantable murine neoplasm that has been extensively utilized to investigate basement membrane constituents. The EHS-derived cells, designated BAM cells, have been subcultured for over 40 passages and have maintained phenotypic and biological properties of the parent EHS tumor cells. BAM cells have retained an epithelioid morphology and the ability to induce EHS-like tumors in mice. Biochemical and immunochemical studies demonstrated that BAM cells synthesize laminin A and B chains, collagen type IV, entactin and the basement membrane specific heparan sulfate proteoglycan. Interestingly, the proteoglycan synthesized by BAM cells was a hybrid molecule containing 2-3 heparan sulfate chains of 25-35 kDa and 1 chondroitin sulfate chain of approximately 17 kDa attached to a 400-kDa protein core. This cell line will be useful to investigations concerning biosynthesis of basement membrane constituents and will be a valuable source of extracellular matrix for testing cellular properties such as attachment, locomotion and differentiation.

Basement membrane proteins: structure, assembly, and cellular interactions

Basement membranes are thin layers of a specialized extracellular matrix that form the supporting structure on which epithelial and endothelial cells grow, and that surround muscle and fat cells and the Schwann cells of peripheral nerves. One common denominator is that they are always in close apposition to cells, and it has been well demonstrated that basement membranes do not only provide a mechanical support and divide tissues into compartments, but also influence cellular behavior. The major molecular constituents of basement membranes are collagen IV, laminin-entactin/nidogen complexes, and proteoglycans. Collagen IV provides a scaffold for the other structural macromolecules by forming a network via interactions between specialized N- and C-terminal domains. Laminin-entactin/nidogen complexes self-associate into less-ordered aggregates. These two molecular assemblies appear to be interconnected, presumably via binding sites on the entactin/nidogen molecule. In addition, proteoglycans are anchored into the membrane by an unknown mechanism, providing clusters of negatively charged groups. Specialization of different basement membranes is achieved through the presence of tissue-specific isoforms of laminin and collagen IV and of particular proteoglycan populations, by differences in assembly between different membranes, and by the presence of accessory proteins in some specialized basement membranes. Many cellular responses to basement membrane proteins are mediated by members of the integrin class of transmembrane receptors. On the intracellular side some of these signals are transmitted to the cytoskeleton, and result in an influence on cellular behavior with respect to adhesion, shape, migration, proliferation, and differentiation. Phosphorylation of integrins plays a role in modulating their activity, and they may therefore be a part of a more complex signaling system.

Identification of chick corneal keratan sulfate proteoglycan precursor protein in whole corneas and in cultured corneal fibroblasts

The precursor protein to the chick corneal keratan sulfate proteoglycan was identified by immunoprecipitation with antiserum to its core protein from lysates of [35S]methionine-pulsed corneas and corneal fibroblasts in cell culture. Antiserum to the keratan sulfate proteoglycan immunoprecipitated a doublet of Mr 52,000 and 50,000 and minor amounts of a Mr 40,000 protein from pulsed corneas. Pulse-chase experiments, which permitted the conversion of the precursor proteins to proteoglycans and digestion of the glycosaminoglycans on immunoprecipitated proteoglycans with keratanase or chondroitinase ABC, showed that the Mr 52,000-50,000 doublet was converted to a keratan sulfate proteoglycan and the Mr 40,000 protein was converted to a chondroitin sulfate proteoglycan. Chick corneal fibroblasts in cell culture primarily produced the smaller (Mr50,000) precursor protein, and in the presence of tunicamycin the precursor protein size was reduced to Mr35,000, which indicates that the core protein contains approximately five N-linked oligosaccharides. Pulse-chase experiments with corneal fibroblasts in culture showed that the precursor protein was processed and secreted into the medium. However, its sensitivity to endo-beta-galactosidase and resistance to keratanase indicate that the precursor protein was converted to a glycoprotein with large oligosaccharides and not to a proteoglycan. This suggests that, although the precursor protein for the proteoglycan is produced in cultured corneal fibroblasts, the sulfation enzymes for keratan sulfate may be absent.

Cloning of human heparan sulfate proteoglycan core protein, assignment of the gene (HSPG2) to 1p36.1----p35 and identification of a BamHI restriction fragment length polymorphism

We have isolated a cDNA coding for the core protein of the large basement membrane heparan sulfate proteoglycan (HSPG) from a human fibrosarcoma cell (HT1080) library. The library was screened with a mouse cDNA probe and one clone obtained, with a 1.5-kb insert, was isolated and sequenced. The sequence contained an open reading frame coding for 507 amino acid residues with a 84% identity to the corresponding mouse sequence. This amino acid sequence contained several cysteine-rich internal repeats similar to those found in component chains of laminin. The HSPG cDNA clone was used to assign the gene (HSPG2) to the p36.1----p35 region of chromosome 1 using both somatic cell hybrid and in situ hybridization. In the study of the polymorphisms of the locus, a BamHI restriction fragment length polymorphism was identified in the gene. This polymorphism displayed bands of 23 and 12 kb with allele frequencies of 76 and 24%, respectively.

Retinoic acid inhibits basement membrane protein biosynthesis while stimulating dome formation by Madin Darby canine kidney cells in hormonally defined serum-free medium

The effect of retinoic acid on basement membrane protein biosynthesis and dome formation by Madin Darby canine kidney cells was examined. Retinoic acid inhibited the biosynthesis of laminin, collagen IV, and heparan sulfate proteoglycan by confluent MDCK monolayers in a hormonally defined serum-free medium. Retinoic acid inhibited laminin biosynthesis by as much as 70% after an 8 day incubation period. The inhibitory effect of retinoic acid on laminin biosynthesis preceded temporally the stimulatory effect of retinoic acid on dome formation. This observation is consistent with the existence of a causal relationship between these two phenomena. Not only did retinoic acid inhibit the biosynthesis of laminin, but in addition the biosynthesis of the cellular 67 kd laminin binding protein was inhibited.

Influence of sulphate ions on the structure of AA amyloid fibrils

To explore the possible interaction of sulphated GAG with AA amyloid peptides, human AA amyloid fibrils were exposed to buffers containing various salts, and the accessibility of free amino groups on the peptides to reductive methylation was examined. Sodium chloride had little effect except at concentrations of 1 M, where it reduced the accessibility of AA peptides to labelling. In contrast 70 mM Na2SO4 led to a significant increase in peptide accessibility to labelling. The results suggest that, at least in part, GAG interact with AA peptides through their sulphate moieties.

Altered basement membrane protein biosynthesis by primary cultures of cpk/cpk mouse kidney

Previously, kidneys from three-week-old cpk/cpk C57/B16 mice were found to contain elevated mRNA levels for the basement membrane components collagen IV and laminin [1]. Here primary cultures of kidney epithelial cells derived from cpk/cpk C57/B16 mice were established and the production of these proteins in culture was studied. Primary cultures of cpk/cpk mouse kidney epithelial cells were observed to have a more polygonal, flattened morphology than cells from unaffected littermate kidneys. The rate of collagen IV and laminin biosynthesis was determined by means of [35S] labelling studies followed by immunoprecipitation. Collagen IV and laminin biosynthesis are elevated by approximately twofold or more in primary cultures derived from 20-day-old cpk/cpk mice, as compared with parallel primary cultures derived from their unaffected littermates. Similarly, laminin B1 chain mRNA is elevated in primary cultures derived from 20-day-old cpk/cpk mice. In primary cultures derived from younger (day 11) mice, similar differences in the rates of both collagen and laminin biosynthesis were not observed between the two culture types. These observations are consistent with the previously reported age-dependent differences observed in laminin and in collagen IV gene expression in both cpk/cpk and wild-type mouse kidneys, and suggest that the regulation of overproduction of these proteins is due to an alteration in the kidney cells and not due to systemic factors.

Distribution of two basement membrane proteoglycans through hair follicle development and the hair growth cycle in the rat

The distribution of two distinct populations of basement membrane proteoglycans has been monitored through hair growth development in the rat embryo and subsequent hair growth cycle. An antiserum against a small heparan sulfate proteoglycan uniformly stained the dermal-epidermal junction of embryonic rats throughout the period of hair follicle formation. On the other hand, monoclonal antibodies recognizing a basement membrane-specific chondroitin sulfate proteoglycan only weakly stained 16-d embryo dermal-epidermal junction, but strong staining was associated with hair follicle buds as they developed. Through the hair growth cycle, it was found that the heparan sulfate proteoglycan persisted around the follicles, while the chondroitin sulfate proteoglycan decreased in amount through catagen until it was undetectable at the base and dermal papilla of the telogen follicle. As anagen commenced, expression of the chondroitin sulfate proteoglycan was again demonstrated. It therefore appears that a basement membrane-specific proteoglycan shows variation in its distribution in rat skin, expression correlating with morphogenetic activity in hair follicles. It is possible that this newly described basement membrane component is involved in the complex processes of dermal-epidermal interaction that lead to skin appendage formation and growth.

Increased proteoglycan synthesis following the differentiation of F9 embryonal carcinoma cells: formation of a differentiation-specific proteoheparan sulfate

We have examined changes in proteoglycan synthesis by F9 embryonal carcinoma cells after the cells have been treated with retinoic acid or retinoic acid plus cholera toxin. Retinoic acid is known to stimulate the differentiation of this cell type to a primitive endoderm-like cell characterized by the production of basement membrane components such as type IV collagen, laminin and proteoglycans. We have now demonstrated that proteoglycan synthesis and secretion were further stimulated when cholera toxin was added in addition to retinoic acid. Moreover, media of these fully differentiated cells was found to contain a different species of proteoheparan sulfate not produced by stem cells or retinoic acid-treated cells. This proteoheparan sulfate had a high density upon CsCl gradient centrifugation. The protein core of this proteoheparan sulfate was estimated by SDS gel electrophoresis to be approximately 15,000 daltons.

Mammalian tissue distribution of a large heparan sulfate proteoglycan detected by monoclonal antibodies

A panel of nine monoclonal antibodies has been characterized, all of which have reactivity with the core protein of a large heparan sulfate proteoglycan derived from the murine EHS tumor matrix. These rat monoclonal antibodies stained mouse basement membranes intensely, including those of all muscle, endothelia, peripheral nerve fibers and epithelia so far examined. In addition, two of the monoclonal antibodies show cross-species reactivity, staining bovine and human basement membranes, and immunoprecipitating proteoglycans from human endothelial cell cultures. These antibodies do not, however, cross-react with avian tissues. These results show the ubiquitous distribution of a heparan sulfate proteoglycan in mammalian tissues, which will be useful in vitro and in vivo for studies on the biology of basement membrane proteoglycans and investigations of possible roles of these molecules in human disease processes.