Robert E. Burgeson

A new nomenclature for the laminins

The authors have adopted a new nomenclature for the laminins. They are numbered with arabic numerals in the order discovered. The previous A, B1 and B2 chains, and their isoforms, are alpha, beta and gamma, respectively, followed by an arabic numeral to identify the isoform. For example, the first laminin identified from the Engelbreth-Holm-Swarm tumor is laminin-1 with the chain composition alpha 1 beta 1 gamma 1. The genes for these chains are LAMA1, LAMB1 and LAMC1, respectively.

Collagen heterogeneity in human cartilage: Identification of several new collagen chains

Normal human hyaline cartilages contain five distinguishable coltagenous proteins in addition to, and different from the αl(II) chain of Type II collagen. This report describes the characterization of three of these additional proteins. By the criteria of solubility, electrophoretic mobilities, ion-exchange and sieve chromatographic properties, amino acid compositions, and cyanogen bromide peptide profiles, at least two of these proteins, and possibly the third, are structurally distinct collagen α chains different from previously reported collagen chains. These findings imply further molecular heterogeneity of vertebrate collagens, and the existence of at least 9 different structural genes for collagen chains.

The dermal-epidermal junction.

Recent insights into the structure and function of the dermal-epidermal junction have resulted from two converging lines of experimental evidence, namely, the study of inherited blistering disorders of the skin, in which mutations in genes encoding proteins of this region have been discovered, and the targeted ablation of the same genes in knockout mouse models. In addition to these studies, elegant analyses of the cell biology of the hemidesmosome/anchoring filament complex have revealed not only functionally important interactions between structural protein components, but also the role of certain of these proteins in mediating cell adhesion, migration, and signal transduction of messages from the extracellular matrix into the keratinocyte. Our current understanding of the dermal-epidermal junction forms a new model encapsulating the nature both of the hemidesmosomal attachment structures and of the interhemidesmosomal attachments that are mediated by differential cell type specific expression of proteins of the cutaneous adhesion zone.

Bone morphogenetic protein 1 is an extracellular processing enzyme of the laminin 5 gamma 2 chain

Epithelial cells maintained in culture medium containing low calcium proteolytically process laminin 5 (α3β3γ2) within the α3 and γ2 chains (1). Experiments were designed to identify the enzyme(s) responsible for the laminin 5 processing and the sites of proteolytic cleavage. To characterize the nature of laminin 5 processing, we determined the N-terminal amino acid sequences of the proteolytic fragments produced by the processing events. The results indicate that the first α3 chain cleavage (200-l65 kDa α3) occurs within subdomain G4 of the G domain. The second cleavage (l65-l45 kDa α3) occurs within the lIla domain, 11 residues N-terminal to the start of domain II. The γ chain is cleaved within the second epidermal growth factor-like repeat of domain Ill. The sequence cleaved within the γ2 chain matches the consensus sequence for the cleavage of type I, II, and III procollagens by bone morphogenetic protein-1 (BMP-1), also known as type I procollagen C-proteinase (2). Recombinant BMP-1 cleaves γ2 in vitro,both within intact laminin 5 and at the predicted site of a recombinant γ2 short arm. α3 is also cleaved by BMP-1 in vitro, but the cleavage site is yet to be determined. These results show the laminin α3 and γ2 chains to be substrates for BMP-1 in vitro. We speculate that γ2 cleavage is required for formation of the laminin 5–6 complex and that this complex is directly involved in assembly of the interhemidesmosomal basement membrane. This further suggests that BMP-1 activity facilitates basement membrane assembly, but not hemidesmosome assembly, in the laminin 5-rich dermal-epidermal junction basement membrane in vivo.

Self-assembly of Laminin Isoforms

The α, β, and γ subunits of basement membrane laminins can combine into different heterotrimeric molecules with either three full short arms (e.g. laminins-1–4), or molecules containing one (laminins-6–9) or more (laminin-5) short arm truncations. Laminin-1 (α1β1γ1), self-assembles through a calcium-dependent thermal gelation requiring binding interactions between N-terminal short arm domains, forming a meshwork polymer thought to contribute to basement membrane architecture (Yurchenco, P. D., and Cheng, Y. S. (1993) J. Biol. Chem. 268, 17286–17299). However, it has been unclear whether other isoforms share this property, and if so, which ones. To begin to address this, we evaluated laminin-2 (α2β1γ1), laminin-4 (α2β2γ1), laminin-5 (α3Aβ3γ2), and laminin-6 (α3Aβ1γ1). The first two isoforms were found to self-aggregate in a concentration- and temperature-dependent manner and a close self-assembly relationship among laminins-1, -2, and -4 were demonstrated by: (a) polymerization of all three proteins was inhibited by EDTA and laminin-1 short arm fragments, (b) polymerization of laminin-1 was inhibited by fragments of laminins-2 and -4, (c) laminin-2 and, to a lesser degree, laminin-4, even well below their own critical concentration, co-aggregated with laminin-1, evidence for co-polymerization. Laminin-5, on the other hand, neither polymerized nor co-polymerized with laminin-1. Laminin-6 failed to co-aggregate with laminin-1 at all concentrations evaluated, evidence for a lack of a related self-assembly activity. The data support the hypothesis that all three short arms are required for self-assembly and suggest that the short arm domain structure of laminin isoforms affect their architecture-forming properties in basement membranes.

Type I and Type III Collagen Interactions during Fibrillogenesisa

There is some evidence that type I and type III collagens may be present in the same fibril. In order to demonstrate this, double labeling immunofluorescence microscopy and immunoelectron microscopy were performed with antibodies directed against the collagen molecule and the aminopropeptide domains of type I and type III procollagens using embryonic (postabortion) and adult human skin. Double indirect and protein A immunoelectron microscopy were carried out with 5- and 15-nm gold particles. Skin extracts were also studied by immunoblotting. Double immunofluorescence microscopy with antibodies against type I and type III collagen molecules revealed patterns of fluorescence that were identical in both fetal and adult skins. Immunofluorescence microscopy using an antibody directed against the aminopropeptide of type III procollagen labeled the entire dermis in both embryonic and adult skins. In contrast, although the aminopropeptide of type I procollagen was present throughout embryonic dermis, it was markedly reduced in adult dermis, except for the epidermo-dermal junction. Double immunoelectron microscopy of fetal skin revealed labeling of the aminopropeptide of type I and type III procollagens on the same thin (20-30 nm) fibrils. Large type I fibrils (90-100 nm) were coated with type III collagen molecules and their corresponding aminopropeptide but not with the aminopropeptide of type I procollagen. The aminopropeptide of type I procollagen was present on thin fibrils only at the epidermo-dermal junction in adult skin. Immunoblotting of skin extracts revealed the presence of both pN-type III procollagen (collagen plus the aminopropeptide) and pN-type I procollagen in fetal skin, but only pN-type III in adult skin. This study demonstrates that type I and type III collagens coexist within the same fibril and that the aminopropeptide of type III procollagen is present at the surface of type I collagen fibrils that apparently have reached full growth.

Abnormalities of the extracellular matrix in keratoconus corneas.

Purpose To study alterations of the extracellular matrix (ECM) and basement membrane (BM) components in human keratoconus corneas. Methods Fifteen normal and 13 keratoconus corneas were characterized by immunofluorescence with antibodies to 23 ECM and BM components. Results Keratoconus staining patterns for posterior non-scarred regions and Descemets membrane were normal. We focused on three areas of keratoconus corneas: (a) nonscarred anterior corneal regions, (b) scarred anterior and posterior corneal regions, and (c) gaps in Bowmans layer. In each of these areas, consistent ECM and BM changes could be found. Nonscarred regions showed decreased staining of the epithelial BM for entactin/nidogen, fibronectin, α3-α5 chains of type IV collagen, and chains of laminin-1. In contrast, scarred regions had greater than normal staining of the epithelial BM for these same components and also for laminin-5, perlecan, and type VII collagen. In the Bowmans layer gaps/breaks, focal fibrotic deposits containing type VIII collagen, fibrillin-1, tenascin-C, α1-α2 type IV collagen, and normal stromal ECM and epithelial BM components were seen. Fibrotic regions were largely restricted to areas where, because of the lack of Bowmans layer, the epithelium was in contact with the stroma. Conclusions In a single keratoconus cornea, abnormalities in the ECM/BM patterns were not uniform. This may reflect locally increased protease activity (where few if any BM components are found) and ongoing wound healing (where more BM or ECM components or both are found).

Collagen types. Molecular structure and tissue distribution.

The collagens are products of a superfamily of closely related genes. Currently, there are 13 described collagens encompassing at least 25 separate genes. The collagen molecules can be categorized into four classes. Class I consists of molecules that form the banded collagen fibers that are readily seen by routine electron microscopy. The banded fibers are heterogenous with respect to collagen type, containing at least two and often three collagen types in each fibril. This multiplicity is believed to effect the rate of fibril growth and the final fibril diameter. Class II contains collagens that adhere to the surface of the banded fibrils. The function of these molecules is not yet known. The third Class consists of molecules that form independent fiber systems. These include the basement membrane, beaded filaments, anchoring fibrils, and the network surrounding hypertrophic chondrocytes. The last class contains several collagens with unknown fiber forms, and whose functions are unclear. Tissues contain multiple fiber forms and therefore many individual collagen types. Bone is no different, and there are presently four known collagens in the bone cortex. This article summarizes knowledge of the structures and functions of the collagen superfamily.

Basement membrane abnormalities in human eyes with diabetic retinopathy.

Vascular and parenchymal basement membranes (BMs) are thickened in diabetes, but alterations in individual BM components in diabetic eyes, especially in diabetic retinopathy (DR), are obscure. To identify abnormalities in the distribution of specific constituents, we analyzed cryostat sections of human eyes obtained at autopsy (seven normal, five diabetic without DR, and 13 diabetic with DR) by immunofluorescence with antibodies to 30 BM and extracellular matrix components. In non-DR eyes, no qualitative changes of ocular BM components were seen. In some DR corneas, epithelial BM was stained discontinuously for laminin-1, entactin/nidogen, and alpha3-alpha4 Type IV collagen, in contrast to non-DR corneas. Major BM alterations were found in DR retinas compared to normals and non-DR diabetics. The inner limiting membrane (retinal BM) of DR eyes had accumulations of fibronectin (including cellular) and Types I, III, IV (alpha1-alpha2), and V collagen. The BM zone of new retinal blood vessels in neovascularized areas accumulated tenascin and Type XII collagen, whereas normal, diabetic, and adjacent DR retinas showed only weak and irregular staining. In preretinal membranes, perlecan, bamacan, and Types VI, VIII, XII, and XIV collagen were newly identified. Diabetic BM thickening appears to involve qualitative alterations of specific BM markers at an advanced disease stage, with the appearance of DR.

Human bone contains type III collagen, type VI collagen, and fibrillin: type III collagen is present on specific fibers that may mediate attachment of tendons, ligaments, and periosteum to calcified bone cortex.

We evaluated the distribution of Type III collagen, Type VI collagen, and fibrillin in human bone, using monoclonal antibodies (MAb) of proven specificity. All three molecules are present in developing and remodeling bone. Type III collagen is present in discrete fiber bundles throughout the bone cortex but is concentrated at the Haversian canal surface and in the fibers at the bone-periosteal interface. The collagen fibrils in these bundles are of uniform diameter. Type III-containing collagen fibers are detected at all ages examined, from 30 fetal weeks to 80 years. Type VI collagen is present in fetal bone in discrete fibrils separate from Type III collagen, and becomes restricted to the margins of bone cells and the bone surface by 7 years. The distribution of fibrillin resembles that of Type III collagen in the fetus, but at 7 years is absent from the interior of the cortex except for the canaliculi and cement lines, and remains concentrated in discrete fibers at the bone surface.