Basement membrane structure in situ: evidence for lateral associations in the type IV collagen network

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.

Three-dimensional structure of type IV collagen in the mammalian lens capsule

The anterior lens capsule provides a thick, easily handled model system for the study of the organization of type IV collagen, the main component of basement membranes. We have used the technique of rapid freezing, deep-etch, and rotary replication to study the three-dimensional organization of the collagen skeleton in mammalian lens capsule after a variety of extraction procedures. In all cases the collagen appeared as a densely packed three-dimensional branching network of fine microfibrils. The organization of the microfibrils appears to show some regularity, with branch points approximately 40 nm apart. Most junctions are three-way and the network forms predominantly five-sided figures. This closely resembles the collagenous network described by Yurchenco and Ruben (1987, 1988) in human amniotic basement membrane and EHS tumor matrix, but extends their findings to another system for which X-ray diffraction data are available. The three-dimensional network is discussed in terms of molecular packing of type IV collagen in light of the information available from the diffraction data.

Short and long range order in basement membrane type IV collagen revealed by enzymic and chemical extraction

Oriented bovine lens capsules give X-ray diffraction patterns suggesting a considerable degree of order in the collagenous components, predominantly type IV collagen. Here we report the effects of preliminary treatment of lens capsules before orientation. Extraction with 4 M guanidinium hydrochloride or with heparinase/hyaluronidase reveals the same collagenous diffraction patterns previously seen after extraction with 1 M NaCl. There is a four-point pattern of d-spacing 3.9 nm, indicating liquid crystal cybotactic nematic organization, along with sharp streaked meridional reflections which index as orders of 21 nm. This suggests that the removal of basement membrane proteoglycans results in a reduction in diffuse scatter and clarification of the pattern. Extraction of the lens capsules with trypsin or dithiothreitol greatly reduces the intensity of the four-point pattern while leaving the meridional pattern unaffected. This strengthens the evidence that the 21 nm period has its origins in the collagen IV helix. Reduction in the four-point pattern could arise if disruption of non-helical NC1 domains or 7S overlap regions allows slippage of the collagen molecules on orientation, weakening the proposed 1 nm intermolecular stagger. Ultra-low angle diffraction patterns of extracted lens capsules show meridional reflections which index as a long-range axial repeat of approximately 95 nm. This is consistent with a model of microfibrils of type IV collagen in which the NC1 domains bind to the collagen helix at approximately 100 nm intervals, as has been previously suggested.

Cell adhesion promoting peptide GVKGDKGNPGWPGAP from the collagen type IV triple helix: cis/trans proline-induced multiple 1H NMR conformations and evidence for a KG/PG multiple turn repeat motif in the all-trans proline state

Peptide GVKGDKGNPGWPGAPY (called peptide IV-H1), derived from the protein sequence of human collagen type IV, triple-helix domain residues 1263-1277, represents an RGD-independent, cell-specific, adhesion, spreading, and motility promoting domain in type IV collagen. In this study, peptide IV-H1 has been investigated by 1H NMR (500 MHz) spectroscopy. Cis-trans proline isomerization at each of the three proline residues gives rise to a number of slowly exchanging (500-MHz NMR time scale) conformation states. At least five such states are observed, for example, for the well-resolved A14 beta H3 group, and K3, which is six residues sequentially removed from the nearest proline, i.e., P9, shows two sets. The presence of more than two sets of resonances for residues sequentially proximal to a proline, e.g., A14-cis-P15 and A14-trans-P15, and more than one set for a residue sequentially well-removed from a proline, e.g., K3, indicates long range conformation interactions and the presence of preferred structure in this short linear peptide. Many resonances belonging to these multiple species have been assigned by using mono-proline-substituted analogues. Conformational (isomer) state-specific 2D 1H NMR assignments for the combination of cis and trans proline states have been made via analysis of COSY-type, HOHAHA, and NOESY spectra. Peptide IV-H1 in the all-trans proline state ttt exists in relatively well-defined conformation populations showing numerous short- and long-range NOEs and long-lived backbone amide protons and reduced backbone NH temperature coefficients, suggesting hydrogen-bonding, and structurally informative 3J alpha N coupling constants. The NMR data indicate significant beta-turn populations centered at K3-G4, K5-G6, P9-G10, and P12-G13, and a C-terminal gamma-turn within the A14-P15-Y16 sequence. These NMR data are supported by circular dichroic studies which indicate the presence of 52% beta-turn, 10% helix, and 38% random coil structural populations. Since equally spaced KG and PG residues are found on both sides of peptide IV-H1 in the native collagen type IV sequence, this multiple turn repeat motif may continue through a longer segment of the protein. Synthetic peptide IV-H1 overlapping sequence "walk throughs" indicate that the primary biological activity is localized in the GNPGWPGAP double beta-turn domain, which contains the backbone constraining proline residues. This proline-domain conformation may suggest a collagen type IV receptor-specific, metastatic cell adhesion promoting binding domain.

Structural and functional relationships between type II pneumocytes and components of extracellular matrices

Type II pneumocytes of the pulmonary alveolus are dynamic cells with multiple functional capabilities in vivo, including secretion of surface-active lipoproteins and cell renewal of the epithelial lining of the alveolus, involving its differentiation into another cell type (the type I pneumocyte). The factors that influence and control these processes, which are vital to the function of the alveolus, have begun to be more clearly understood in recent years, in large part because of the development of adequate in vitro systems, which permit the manipulation of relevant variables. These appear to be a complex interaction between insoluble components of extracellular matrices, principally of the basement membrane, and soluble factors that include hormones and growth factors. This review focuses particularly on those components of extracellular matrices that specifically and nonspecifically impact on type II cell function, and it attempts to bring together the diverse technical approaches used to define and examine these relationships cytochemically and functionally.

Distribution of collagens type V and VI in the normal human alveolar mucosa: an immunoelectronmicroscopic study using ultrathin frozen sections

The ultrastructural localization of collagens type V and VI in normal human gingival mucosa was investigated by immunoelectron microscopy. Twenty biopsies were fixed in dimethylsuberimidate and shock-frozen in slush nitrogen. Collagen type V was mainly located to meshworks of uniform nonstriated microfibrils of 12 to 20 nm width, which preferentially appeared in larger spaces between cross-striated major collagen fibrils. Occasionally single microfibrils of collagen type V fanned out from the ends of major collagen fibrils, which may indicate a role as a core fibril. Collagen type V was not found in the subepithelial basement membrane and the immediately adjacent stroma. Collagen type VI was detected in a loose reticular network of unbanded microfilaments that were morphologically distinguishable by knoblike protrusions every 100-110 nm. These microfilaments were found in the vicinity, but not as an intrinsic component, of the subepithelial basement membrane. Single filaments of collagen type VI filaments appeared to form bridges between neighboring cross-striated major collagen fibrils, suggesting an interconnecting role for this collagen type. The method presented appears to be excellently suited to study the normal and pathological supramolecular organization of the oral extracellular matrix.

A novel chain of basement membrane-associated collagen as revealed by biochemical and immunohistochemical characterizations of the epitope recognized by a monoclonal antibody against human placenta basement membrane collagen

Biochemical and immunohistochemical characterizations of the epitope recognized by a monoclonal antibody, JK-132, originally produced against human type IV collagen showed that it was distinct from the previously reported monoclonal antibody, JK-199 (Kino et al, J Biochem 1988, 103:829-835). The bound fraction of a crude pepsin extract of human placenta on JK-132 antibody-coupled resin showed close similarity to type IV collagen in a triple-helical conformation in terms of the amino acid composition and circular dichroism spectrum. Sodium dodecyl sulfate polyacrylamide gel electrophoresis analysis of the fraction showed six peptide bands with molecular weights of 50,000 or below, both before and after reduction. Four of the peptides reacted with JK-132 on immunoelectroblotting, but none reacted with JK-199. JK-132 reacted with two additional bands with molecular weights of 100,000 and 120,000, which were not visible on direct staining with Coomassie Brilliant Blue R-250. Two peptides (molecular weights 40,000 and 15,000) bound on a JK-199 antibody affinity column were sequenced, and both contained the same amino-terminal sequences as alpha 1(IV) chain. Conversely the sequences of three of the peptides (molecular weights 50,000, 32,000, and 23,000) eluted from a JK-132 antibody affinity column did not match either the alpha 1(IV) or the alpha 2(IV) sequence reported. Immunohistochemically, JK-132 reacted strongly with basement membranes of blood capillaries in skeletal muscle tissues but not with the basement membranes of muscle fibers in frozen sections of periodate-lysine-paraformaldehyde-fixed tissue, suggesting heterogeneity or tissue specificity of basement membrane collagen. By immunoelectron microscopy, the reaction products were found on the basal laminae of endothelium and of smooth muscle cells around blood vessels. These findings suggest the presence of a new collagen chain associated with basal laminae.

Ultrastructure of glomerular basement membrane by quick-freeze and deep-etch methods

The glomerular basement membrane of rat kidneys were three-dimensionally observed by quick-freeze and deep-etch replica methods at high resolution. The middle layer (lamina densa) was composed of 6 to 10 nm fibrils which formed a meshwork structure. The space between the fibrils had polygonal shape. The average long dimension of the space between fibrils was 17 nm and the short one was 13 nm. At the outer layer (lamina rara externa), fibrils connected podocytes perpendicularly with the meshwork of the middle layer. At the inner layer (lamina rara interna), similar perpendicular fibrils also connected endothelial cells with the meshwork of the middle layer. This is the first report to visualize the three-dimensional meshwork structure of the middle layer (the lamina densa) in situ. The function of anchoring podocytes to the lamina densa was suggested in the perpendicularly arranged fibrils of the outer layer. The quick-freeze and deep-etch method is useful in analyzing filamentous ultrastructure in glomeruli, and will be applied to clarifying pathological ultrastructure in kidney diseases.

Embryonic lethality caused by mutations in basement membrane collagen of C. elegans

Basement membranes are specialized forms of extracellular matrix with important functions in development. A major structural component of basement membranes is type IV collagen, a heterotrimer of two alpha 1(IV) and one alpha 2(IV) chains, which forms a complex, polygonal network associated with other basement membrane components. Here we report that the alpha 1(IV) collagen chain of Caenorhabditis elegans is encoded by the genetic locus emb-9. Mutations in emb-9 cause temperature-sensitive lethality during late embryogenesis. We have identified single nucleotide alterations that substitute glutamic acid for glycine in the triple-helical Gly-X-Y repeat region of the alpha 1(IV) collagen in three emb-9 mutant strains. These results are direct evidence that defects in basement membranes can disrupt embryonic development and form a basis for the genetic analysis of basement membrane function.

Immunogold studies of monomeric elements from the globular domain (NC1) of type IV collagen in renal basement membranes during experimental diabetes in the rat

The protein A-gold immunocytochemical technique was applied to reveal the monomeric elements M1, M2* and M3 from the non-collagenous globular domain (NC1) of type IV collagen over various renal basement membranes from control and long-term streptozotocin-induced diabetic rats. This study includes the basement membranes of the proximal tubule, the Bowman's capsule and the glomerulus as well as the extracellular matrix of the mesangium. The labellings obtained were confined to basement membrane material. The quantitative analysis demonstrated changes in labelling intensities and distribution between tissues from normal and diabetic animals. Increased labelling intensities were observed for M1 and M2* monomers in all the basement membranes studied except for the mesangial matrix which remained unchanged. In addition, the labelling for M1 monomers, present on the endothelial side of the glomerular basement membrane of control animals, was found to be distributed throughout the entire thickness of the basement membrane of diabetic animals. In contrast, neither the intensity of the labelling, nor the distribution of M3 monomers were altered in diabetic animals. Since M1 monomers are markers of the alpha 1(IV) and alpha 2(IV) chains of type IV collagen while M2* and M3 mark alpha 3(IV) and alpha 4(IV) chains respectively, the present results demonstrate changes in the nature of the collagenous elements of basement membranes during diabetes. Furthermore, the results indicate that the alpha 3(IV) and the alpha 4(IV) chains are not necessarily present in the same molecule. The modifications of the collagenous elements of the basement membranes during diabetes must alter the structural characteristics of these matrices which in turn might influence their functional properties.

Identification of a multifunctional, cell-binding peptide sequence from the a1(NC1) of type IV collagen

We have previously identified three distinctive amino acid sequences from type IV collagen which specifically bound to heparin and also inhibited the binding of heparin to intact type IV collagen. One of these chemically synthesized domains, peptide Hep-I, has the sequence TAGSCLRKFSTM and originates from the a1(noncollagenous [NC1]) chain of type IV collagen (Koliakos, G. G., K. K. Koliakos, L. T. Furcht, L. A. Reger, and E. C. Tsilibary. 1989. J. Biol. Chem. 264:2313-2323). We describe in this report that this same peptide also bound to intact type IV collagen in solid-phase assays, in a dose-dependent and specific manner. Interactions between peptide Hep-I and type IV collagen in solution resulted in inhibition of the assembly process of this basement membrane glycoprotein. Therefore, peptide Hep-I should represent a major recognition site in type IV collagen when this protein polymerizes to form a network. In addition, solid phase-immobilized peptide Hep-I was able to promote the adhesion and spreading of bovine aortic endothelial cells. When present in solution, peptide Hep-I competed for the binding of these cells to type IV collagen- and NC1 domain-coated substrata in a dose-dependent manner. Furthermore, radiolabeled peptide Hep-I in solution also bound to endothelial cells in a dose-dependent and specific manner. The binding of radiolabeled Hep-I to endothelial cells could be inhibited by an excess of unlabeled peptide. Finally, in the presence of heparin or chondroitin/dermatan sulfate glycosaminoglycan side chains, the binding of endothelial cells to peptide Hep-I and NC1 domain-coated substrates was also inhibited. We conclude that peptide Hep-I should have a number of functions. The role of this type IV collagen-derived sequence in such diverse phenomena as self-association, heparin binding and cell binding and adhesion makes Hep-I a crucial domain involved in the determination of basement membrane ultrastructure and cellular interactions with type IV collagen-containing matrices.

Agrin-induced reorganization of extracellular matrix components on cultured myotubes: relationship to AChR aggregation

Agrin, an extracellular matrix-associated protein extracted from synapse-rich tissues, induces the accumulation of acetylcholine receptors (AChRs) and other synaptic components into discrete patches on cultured myotubes. The appearance of agrin-like molecules at neuromuscular junctions suggests that it may direct synaptic organization in vivo. In the present study we examined the role of extracellular matrix components in agrin-induced differentiation. We used immunohistochemical techniques to visualize the spatial and temporal distribution of laminin, a heparan sulfate proteoglycan (HSPG), fibronectin, and type IV collagen on cultured chick myotubes during agrin-induced aggregation of AChRs. Myotubes displayed significant amounts of laminin and HSPG, lesser amounts of type IV collagen, and little, if any, fibronectin. Agrin treatment caused cell surface laminin and HSPG to patch, while collagen and fibronectin distributions were generally unaffected. Many of the agrin-induced laminin and HSPG patches colocalized with AChR patches, raising the possibility of a causal relationship between matrix patching and AChR accumulations. However, patching of AChRs (complete within a few hours) preceded that of laminin or HSPG (not complete until 15-20 h), making it unlikely that matrix accumulations initiate AChR patching at agrin-induced sites. Conversely, when AChR patching was blocked by treatment with anti-AChR antibody mAb 35, agrin was still able to effect patching of laminin and HSPG. Taken together, these findings suggest that agrin-induced accumulations of AChR and laminin/HSPG are not mechanistically linked.

Human keratinocytes adhere to a unique heparin-binding peptide sequence within the triple helical region of type IV collagen

The present studies were aimed at further characterizing the interaction between basement membrane molecules and normal cultured human keratinocytes because of the intimate association between basal keratinocytes and the basement membrane. The studies show that keratinocytes adhere to type IV collagen-coated substrata to a greater degree than substrata coated with similar concentrations of fibronectin and laminin. To further define cell-binding regions within type IV collagen, studies were performed using purified pepsin-generated triple helical fragments of type IV collagen and show that keratinocytes bind to sites within the triple-helical region of type IV collagen. To delineate specific cell adhesion promoting sequences, we studied a series of chemically synthesized peptides derived from the triple-helical region of type IV collagen. One peptide, designated Hep III, which is thirteen amino acids in length and binds heparin, was active in directly promoting keratinocyte adhesion. Furthermore, in competition assays, this peptide in solution was shown to inhibit keratinocyte adhesion to substrata coated with Hep III or intact type IV collagen. These studies show that keratinocytes bind directly to type IV collagen and chemically define a major cell-adhesion-promoting site within the triple helical region.

Identification of the cleavage sites by a hemorrhagic metalloproteinase in type IV collagen

Type IV collagen, solubilized from Engelbreth-Holm-Swarm (EHS) tumor basement membranes is digested by a hemorrhagic metalloproteinase, Ht-e, isolated from the crude venom of the Western Diamondback rattlesnake, Crotalus atrox. The major proteolytic products have Mr 141,000, 132,000, 87,000, 71,000, 33,000 and approximately 18,000 as estimated by SDS-gel electrophoresis of pepsinized type IV collagen fragments. Sequence analysis of the digestion products reveal that the Mr 141,000, 71,000 and approximately 18,000 band are derived from the alpha 1(IV) chains and the Mr 132,000, 87,000 and 33,000 bands are derived from the alpha 2(IV) chain. The products are stable over 72-hour incubation periods. The cleavage sites on the alpha 1(IV) and alpha 2(IV) chains are not identical. The alpha 1(IV) chains are cleaved in a pepsin susceptible triplet interruption region of the triple helix at position Ala258-Gln259. The alpha 2(IV) chain is cleaved in the triple helical region near the NC2 domain at the Gly191-Leu192 peptide bond. Isolated hexameric NC1 globular domains of type IV collagen are not digested by Ht-e. The present study demonstrates that the venom hemorrhagic metalloproteinase Ht-e has type IV collagenolytic activity. The triple helix of the type IV collagen molecule is cleaved in a region located immediately carboxyl to the flexible NC2 domain. The degradation by Ht-e of type IV collagen, a major component of basement membranes which forms the scaffold of this extracellular structure, may account in part for the hemorrhagic activity of this toxin.

Crystals of the NC1 domain of human type IV collagen

Crystals of the non-collagenous C-terminal region (NC1) of type IV collagen have been obtained from human placenta. These crystals diffract to 2.0 A, and belong to space group P22(1)2(1), with cell dimensions a = 81 A, b = 158 A, c = 138 A, alpha = beta = gamma = 90 degrees. The crystals contain one hexamer in the asymmetric unit; they are very stable with respect to X-rays.

Rat kidney glomerular basement membrane visualized in situ by embedment-free sectioning and subsequent platinum-carbon replication

Following the removal of polyethylene glycol (PEG) from thin sections, and viewing through the endothelial fenestrae and/or the interpedicel spaces, the rat renal glomerular basement membrane in situ was revealed to consist of meshworks and to be electron-transparent when examined at right angles to the plane of the membrane. By subsequent platinum replication of the embedment-free sections, the lamina densa of the basement membrane appeared as a veil composed of rather closely packed particles. The architecture of the split diaphragm and the surface morphology of the endothelial cell membrane were also clearly revealed. The present results indicate that the PEG method, with or without replication, can provide valuable information on basement membrane morphology.

Ultrathin (1 nm) vertically shadowed platinum-carbon replicas for imaging individual molecules in freeze-etched biological DNA and material science metal and plastic specimens

Single molecule resolution in beam-sensitive, uncoated, noncrystalline materials has heretofore not been possible except in thin (less than or equal to 150 A) platinum-carbon (Pt-C) replicas, which are resistant to electron beam destruction. Previously, the granularity of metal film replicas limited their resolution to greater than or equal to 20 A. This paper demonstrates that Pt-C film granularity and resolution are a function of the method of replication and other controllable factors. Low-angle 20 degrees rotary, 45 degrees unidirectional, and vertical 9.7 +/- 1 A Pt-C films deposited on mica under the same conditions were compared. Vertical replication had a 5 A granularity, the highest resolution, and evenly coated the whole surface. A 45 degrees replication had a 9.5 A granularity, a slightly poorer resolution, and a discontinuous surface coating. The use of 20 degrees rotary replication proved to be unsuitable for high-resolution imaging, with 20-25 A granularity and resolution two to three times poorer. Vertical and 45 degrees Pt-C replicas can visualize the deep-etched DNA helix and the 13.3 A 3(2) helix of pectin in a gel. The DNA double helix, the complex structures of sol-gel glasses, Immobilon filters (polyvinylidene fluoride), a polymethacrylate plastic, the metal oxide surfaces of 440c stainless steel, and aluminum are illustrated. This high-resolution vertical Pt-C replica technique can image in the context of solutions, gels, or solids, single molecular chains 3-7 A wide, their associations, and their conformation. Included in the present article are first time descriptions for removing replicas from metals and plastics and for making high-magnification photographic prints of normal contrast using a reversal rephotographic process.

Molecular organization of type IV collagen: polymer liquid crystal-like aspects

A new X-ray diffraction pattern from type IV collagen is described, which can be interpreted on the basis of crystalline and liquid crystalline origins of the reflections. Bovine anterior lens capsules extracted with 1 M NaCl and oriented by extension of 60% under constant load gave medium angle X-ray diffraction patterns showing many of the characteristics typical of liquid crystals. Prominent features, apart from those wide angle features attributable to the collagen triple helix, are (1) a four-point pattern of broad reflections at d-spacing 3.9 nm, and layer line spacing near 5 nm. (2) A broad intense equatorial peak centred at 1.24 nm, indicative of liquid-like lateral molecular associations. (3) A set of five sharp, streaked meridional reflections (previously obscured by the broad peak near 5 nm in unextracted capsules). (4) A further six higher angle reflections of a diffuse, arced and broad appearance on the meridian. The sharp streaked meridional reflections emanate from a long-range periodicity of units 8-9 nm in diameter. These features form a self-consistent system if interpreted on the basis of a staggered liquid crystal-like array of collagen molecules, in which case the first five meridionals and remaining broad reflections, sampled on the meridian, can all be indexed as orders of 21 nm.

Binding of nidogen and the laminin-nidogen complex to basement membrane collagen type IV

The laminin-nidogen complex and purified nidogen both bind collagen IV but not other collagens, as shown by solid-state ligand-binding and inhibition assays. Laminin purified from the dissociated complex and a variety of laminin proteolytic fragments failed to bind collagen IV. Complexes formed in solution between nidogen or laminin-nidogen and collagen IV were visualized by rotary shadowing which identified one major binding site about 80 nm away from the C-terminus of the collagen triple helix. A second, weaker binding site may exist closer to its N-terminus. Binding sites of nidogen were assigned to its C-terminal globular domain which also possesses laminin-binding structures. A more diverse collagen-IV-binding pattern was observed for the laminin nidogen complex, whereby interactions may involve both nidogen and short-arm structures of laminin.

Structure, composition, and assembly of basement membrane

Basement membranes are thin layers of matrix separating parenchymal cells from connective tissue. Their ultrastructure consists of a three-dimensional network of irregular, fuzzy strands referred to as "cords"; the cord thickness averages 3-4 nm. Immunostaining reveals that the cords are composed of at least five substances: collagen IV, laminin, heparan sulfate proteoglycan, entactin, and fibronectin. Collagen IV has been identified as a filament of variable thickness persisting after the other components have been removed by plasmin digestion or salt extraction. Heparan sulfate proteoglycan appears as sets of two parallel lines, referred to as "double tracks," which run at the surface of the cords. Laminin is detected in the cords as diffuse material within which thin wavy lines may be distinguished. The entactin and fibronectin present within the cords have not been identified as visible structures. The ability of laminin, heparan sulfate proteoglycan, fibronectin, and entactin to bind to collagen IV has been demonstrated by visualization with rotary shadowing and/or biochemical studies. Incubation of three of these substances-collagen IV, laminin (with small entactin contamination), and proteoglycan-at 35 degrees C for 1 hr resulted in a precipitate that was sectioned for electron microscopic examination and processed for gold immunolabeling for each of the three incubated substances. Three structures are present in the precipitate: 1) a lacework, exclusively composed of heparan sulfate proteoglycan in the form of two parallel lines, similar to double tracks; 2) semi-solid, irregular accumulations, composed of the three initial substances distributed on a cord network; and 3) convoluted sheets, which are also composed of the three initial substances distributed on a cord network but which, in addition, have the uniform appearance and thickness of the lamina densa of basement membrane. Hence these sheets are closely similar to the main component of authentic basement membranes.

Glomerular basement membrane as a compressible ultrafilter

The ultrafiltration properties of isolated glomerular basement membrane were studied in vitro by forming membrane fragments into thin films for use as ultrafiltration membranes. The filtration properties of the films were examined using cytochrome c, myoglobin, lysozyme, ovalbumin, lactoglobulin, and serum albumin. The films behaved as compressible filters showing size-dependent rejection of the proteins. The behavior of the films was modelled using the fiber matrix hypothesis which gave good prediction of film behavior. The membrane behaved as a random fiber matrix composed of fibers of 0.8-1.0 nm in radius.

Disruption of the subendothelial basement membrane during neutrophil diapedesis in an in vitro construct of a blood vessel wall

To examine the course of physiologic interactions between extravasating neutrophils and the subendothelial basement membrane, a model of the venular vessel wall was constructed by culturing human umbilical vein endothelial cells on a collagen matrix. After 21 d in culture, the endothelial cell monolayer displayed in vivo-like intercellular borders and junctions, deposited a single-layered, continuous basement membrane that was impenetrable to colloidal particles, and supported neutrophil extravasation in a physiologic manner. Using this model, we demonstrate that neutrophil transmigration in a plasma milieu was associated with a significant disruption of the retentive properties of the basement membrane in the absence of discernable morphologic changes. The loss of basement membrane integrity associated with neutrophil diapedesis was not dependent on neutrophil elastase or cathepsin G and was resistant to inhibitors directed against neutrophil collagenase, gelatinase, and heparanase. Despite the fact that this loss in matrix integrity could not be prevented, basement membrane defects were only transiently expressed before they were repaired by the overlying endothelium via a mechanism that required active protein and RNA synthesis. These data indicate that neutrophil extravasation and reversible basement membrane disruption are coordinated events that occur as a consequence of vessel wall transmigration.

Structure and biological activity of basement membrane proteins

Collagen type IV, laminin, heparan sulfate proteoglycans, nidogen (entactin) and BM-40 (osteonectin, SPARC) represent major structural proteins of basement membranes. They are well-characterized in their domain structures, amino acid sequences and potentials for molecular interactions. Such interactions include self-assembly processes and heterotypic binding between individual constituents, as well as binding of calcium (laminin, BM-40) and are likely to be used for basement membrane assembly. Laminin, collagen IV and nidogen also possess several cell-binding sites which interact with distinct cellular receptors. Some evidence exists that those interactions are involved in the control of cell behaviour. These observations have provided a more defined understanding of basement membrane function and the definition of new research goals in the future.

In vitro angiogenesis on the human amniotic membrane: requirement for basic fibroblast growth factor-induced proteinases

The role of basic fibroblast growth factor-(bFGF) induced proteinases in basement membrane (BM) invasion by bovine capillary endothelial (BCE) cells was studied using a quantitative in vitro assay previously described (Mignatti et al., 1986). 125I-iododeoxyuridine-labeled BCE cells were grown for 72 h on the human amnion BM, and cell invasion was determined by measuring the radioactivity associated with the tissue after removal of the noninvasive cell layer. BCE cells were noninvasive under normal conditions. Addition of human bFGF to either the BM or to the stromal aspect of the amnion induced BCE cell invasion with a dose-dependent response. This effect was maximal in the presence of 70 ng/ml bFGF, and was inhibited by anti-FGF antibody. Transforming growth factor beta, as well as plasmin inhibitors and anti-tissue type plasminogen activator antibody inhibited BCE cell invasion. The tissue inhibitor of metalloproteinases, 1-10 phenanthroline, anti-type IV and anti-interstitial collagenase antibodies had the same effect. On the contrary, anti-stromelysin antibody and Eglin, an inhibitor of elastase, were ineffective. The results obtained show that both the plasminogen activator-plasmin system and specific collagenases are involved in the invasive process occurring during angiogenesis.

Folding of collagen IV

Collagen IV dimers of two collagen IV molecules connected by their C-terminal globular NC1 domains were isolated by limited digestion with bacterial collagenase from mouse Engelbreth-Holm-Swarm (EHS) sarcoma tissue. The collagenous domains were only 300 nm long as compared to 400 nm of intact collagen IV but the disulfide bonds in the N-terminal region of the major triple helix were retained. Unfolding of the collagenous domains as monitored by circular dichroism occurred in a temperature range of 30 to 44 degrees C with a midpoint at 37 degrees C. The transition is significantly broader than that of the continuous triple helices in collagens I, II and III, a feature which can be explained by the frequent non-collagenous interruptions in the triple-helical domain of collagen IV. Refolding at 25 degrees C following complete unfolding at 50 degrees C was monitored by circular dichroism, selective proteolytic digestion of non-refolded segments and by a newly developed method in which the recovered triple-helical segments were visualized by electron microscopy. Triple-helix formation was found to proceed in a zipper-like fashion from the C-terminal NC1 domains towards the N-terminus, indicating that this domain is essential for nucleations. For collagen IV dimers with intact NC1 domains the rate of triple-helix growth was of comparable magnitude to that of collagen III, demonstrating that the non-collagenous interruptions do not slow down the refolding process where the rate-limiting step is the cis-trans isomerization of proline peptide bonds. Refolding was near to 100% and the refolding products were similar to the starting material as judged by thermal stability and electron microscopic appearance. Removal of the NC1 domains by pepsin or dissociation of their hexametric structures by acetic acid led to a loss of the refolding ability. Instead products with randomly dispersed short triple-helical segments were formed in a slow reaction. In no case, even when the disulfide bonds in the N-terminal region of the triple-helical domain were intact, was refolding from the N- towards the C-terminus observed. Taken together with results in other collagens, this suggests that C to N directionality might be an intrinsic property of triple-helix folding.

High resolution immunoelectron microscopic localization of functional domains of laminin, nidogen, and heparan sulfate proteoglycan in epithelial basement membrane of mouse cornea reveals different topological orientations

Thin and ultrathin cryosections of mouse cornea were labeled with affinity-purified antibodies directed against either laminin, its central segments (domain 1), the end of its long arm (domain 3), the end of one of its short arms (domain 4), nidogen, or low density heparan sulfate proteoglycan. All basement membrane proteins are detected by indirect immunofluorescence exclusively in the epithelial basement membrane, in Descemet's membrane, and in small amorphous plaques located in the stroma. Immunoelectron microscopy using the protein A-gold technique demonstrated laminin domain 1 and nidogen in a narrow segment of the lamina densa at the junction to the lamina lucida within the epithelial basement membrane. Domain 3 shows three preferred locations at both the cellular and stromal boundaries of the epithelial basement membrane and in its center. Domain 4 is located predominantly in the lamina lucida and the adjacent half of the lamina densa. The low density heparan sulfate proteoglycan is found all across the basement membrane showing a similar uniform distribution as with antibodies against the whole laminin molecule. In Descemet's membrane an even distribution was found with all these antibodies. It is concluded that within the epithelial basement membrane the center of the laminin molecule is located near the lamina densa/lamina lucida junction and that its long arm favors three major orientations. One is close to the cell surface indicating binding to a cell receptor, while the other two are directed to internal matrix structures. The apparent codistribution of laminin domain 1 and nidogen agrees with biochemical evidence that nidogen binds to this domain.

Type IV collagen lateral associations in the EHS tumor matrix. Comparison with amniotic and in vitro networks

The macromolecular structural organization of the type IV collagen network in the extracellular matrix of the EHS tumor has been investigated using a stereoscopic freeze-dry Pt/C replication technique. This network, which can be specifically decorated with type IV collagen antibody, is formed in great part by the lateral joining of narrow filaments (2.7 nm average metal coated diameter) to form a complex three-dimensional irregular polygonal array of variable diameter branching strands. Globular domains, similar to the C-terminal globular domains of purified type IV dimers, can be identified in the network. In many regions of the network the filaments appear to twist around each other along the strand axis. The network is similar to that visualized in the human amnion as well as to a reconstituted network formed in vitro. These data strongly suggest that the laterally and end-domain-associated network is a widespread supramolecular architecture of type IV collagen in basement membranes.