Jerome S. Perlish

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.

Decorin interacts with fibrillar collagen of embryonic and adult human skin

Biglycan (PG-I, BGN) and decorin (PG-II, DCN) are small proteoglycans that have been isolated in cartilage, skin, and bone. Although the function of biglycan is unknown, there is biochemical evidence that decorin interacts with fibrillar collagens (type I, type II). The purpose of this study was to perform immunofluorescence and immunoelectron microscopy and immunoblotting of human embryonic and adult skin with antibodies directed against biglycan and decorin. These antibodies were developed against synthetic peptides of the core proteins of biglycan (amino acid sequence 11-24) and decorin (amino acid sequence 5-17). Immunofluorescence microscopy showed that decorin stained embryonic and adult collagen fibrils. Biglycan did not stain collagen, but it appeared to stain the pericellular matrix of embryonic mesenchymal cells. Immunoelectron microscopy revealed labeling of all collagen fibrils with decorin antibodies regardless of their diameter, often at 60-nm periodicity. Positive stains suggest that most of the labeling was in the gap of the D-period (d and e bands) and also in one of the steps (c band). Decorin was identified by immunoblotting in fetal and adult skin. Also, significant amounts of core protein was identified lacking the dermatan sulfate chain. This study suggests that the core protein of decorin interacts with collagen fibrils although its specific function remains unknown.

COLLAGEN ALTERATIONS IN CHRONICALLY SUN-DAMAGED HUMAN SKIN

Abstract The major histological characteristic of sun‐damaged skin is the accumulation of an elastotic material that appears to replace collagen. This elastotic material consists primarily of elastin and histological studies suggest a large loss of collagen in the dermis of chronically sun‐damaged skin. In this study, we examine the content and distribution of collagen and procollagen in sun‐damaged human skin. The total collagen content of sun‐damaged skin was 20% less than nonsolar‐exposed skin (524 μg collagen per mg total protein in sun‐damaged skin and 667 μg collagen per mg total protein in nonsolar‐exposed skin). In addition, there was a 40% decrease in the content of intact amino propeptide moiety of type III procollagen in sun‐damaged skin (0.68 U per 50 mg wet weight) as compared to nonsolar‐exposed skin (1.12 U per 50 mg wet weight). The data suggest that this change in collagen content is due to increased degradation. The distribution of collagen in sun‐damaged skin was examined by indirect immunofluo‐rescence. Mild digestion of sun‐damaged skin with elastase removed the elastin and revealed the presence of collagen in the elastotic material. Therefore, the elastin appears to mask the presence of collagen fibers in the dermis of sun‐damaged skin.

Dermal collagen fibrils are hybrids of type I and type III collagen molecules

It has been suggested that dermal collagen fibrils with 67-nm periodicity consist of hybrids of type I and type III collagens. This is based on the assumption that all these banded fibrils are coated with type III collagen regardless of their diameter. However, conclusive evidence for this form of hybridization is lacking. In order to clarify this problem dermal collagen fibrils were disrupted into microfibrils using 8 M urea. Single and double indirect immunoelectron microscopy showed type III collagen at the periphery of intact collagen fibrils but no labeling with type I collagen antibodies, suggesting that the epitopes for this collagen were masked. Disrupted collagen fibrils revealed type I collagen throughout the fibril except for the periphery which was coated with type III collagen. Almost no type III collagen was noted in the interior of the collagen fibrils. Since type III collagen is present only at the periphery it suggests that this collagen has a different role than type I collagen and may have a regulatory function in fibrillogenesis.

Immunochemistry of a keratinocyte-fibroblast co-culture model for reconstruction of human skin.

Our purpose was to determine differentiation markers of an in vitro co-culture model in which fibroblasts grown in a three-dimensional nylon mesh were recombined with human keratinocytes. The cultures were kept for 5 weeks and then processed for electron microscopy and immunochemistry. The specimens revealed an epidermis, a basal lamina, an anchoring zone, and a dermis. Epidermal differentiation was confirmed by the presence of K10-keratin, trichohyalin, and filaggrin. The basal lamina contained Type IV collagen, laminin, nidogen, and heparan sulfate. Type IV collagen, laminin, and nidogen were also noted in the extracellular matrix. Type VI collagen was present in the anchoring zone and also gave a reticulated pattern in the rest of the dermis. There was a heavy signal for tenascin and fibronectin throughout the dermis. Osteonectin was restricted to the epidermis and dermal fibroblasts. Fibrillin stained at the anchoring zone and dermis but elastin and vitronectin were negative, suggesting early formation of elastic fibrils. Collagen fibrils stained for Types I, III, and V, as well as the amino propeptide of Types I and III procollagen, suggesting newly synthesized collagen. Decorin was present throughout the dermis. The model described appears suitable for in vitro reconstruction of the skin and may be useful to study the development of various supramolecular skin structures.

Collagen Synthesis by Scleroderma Fibroblasts

Scleroderma is a disease of connective tissue occurring in a localized and a systemic form.’ Progressive systemic scleroderma (PSS) involves the skin and several internal organs, e.g., the lung, esophagus, kidney, and hea1t.2.~ Several attempts have been made to classify systemic scleroderma on the basis of the clinical picture and the presence of autoantibodies in the serum of patients.’.’ In the acral type of scleroderma, fibrosis usually starts in the extremities and the face and then slowly progresses towards the trunk. Patients with the CREST (calcinosis, Raynaud’s phenomenon, esophagusinvolvement, sclerodactyly, teleangiectasia) syndrome seem to run a more benign course of the disease. A high incidence of internal involvement is characteristic for the diffuse form of scleroderma, which therefore has a serious prognosis. The pathogenesis of scleroderma is poorly understood. A review of the literature suggests at least three hypotheses, which are thought to account for a primary event of the disease: (1) vascular damage and alterations of endothelial cells3“; (2) primary disturbance of collagen metabolism (for review see ref. 9); and (3) an autoimmune response (for review see ref. 10). Nevertheless, regardless of the primary or secondary events, excessive accumulation of connective tissue is generally believed to be responsible for the main clinical symptoms.’ In this review we shall therefore focus on the alterations of connective tissue metabolism in both the systemic and localized form of scleroderma. Fibrosis in scleroderma skin can easily be demonstrated by routine histology (FIGURE 1). Examination of the deep reticular layer of the dermis and of the sub-

Procollagen intermediates during tendon fibrillogenesis.

The purpose of this study was to correlate ultrastructural features of tendon collagen fibrils at various stages of development with the presence of procollagen, pN-collagen, pC-collagen, and the free amino propeptides and carboxyl propeptide of type I procollagen. Tendons from 10-, 14-, and 18-day chicken embryos reveal small, well-defined intercellular compartments containing collagen fibrils with diameters showing a unimodal distribution. At 21 days (hatching) and 9 days (post hatching) and at 5 weeks (post hatching), the compartments are larger, less well-defined, and there is multimodal distribution of tendon fibril diameters. Procollagen and the intermediates pN-collagen and pC-collagen are present in tendons up to 18 days. Thereafter there is a marked reduction in procollagen, whereas the intermediates persist throughout all stages of development. Similarly, free amino propeptides and carboxyl propeptides of type I procollagen were found at all stages. The amino propeptide of type III procollagen was restricted to the peritendineum until 7 weeks post hatching. At that time, a network of fibrils containing the amino propeptide of type III procollagen was seen delineating well-circumscribed compartments of collagen fibrils throughout the entire tendon. This study supports the notion that pN- and pC-collagen have an extracellular role and participate in collagen fibrillogenesis.

Collagen synthesis in scleroderma: selection of fibroblast populations during subcultures

SummaryIn progressive systemic scleroderma, excessive deposition of collagen leads to fibrosis of several tissues including the skin. It has been found that different populations of fibroblasts are present in scleroderma skin; these can be obtained by establishing cell cultures from different layers of the involved skin. Excessive overproduction of collagen was noted in primary cultures of cells obtained from deeper layers of the skin of patients in an early stage of the disease, whereas control fibroblasts did not manifest significant variations dependent on the layers of skin used to initiate the cultures. The synthesis of type-I and-III collagen was found to be altered concomitantly. The production of collagen and collagenous proteins was then followed during subcultivations of overproducing fibroblasts. In many cell strains, increased synthesis of collagen and/or noncollagenous proteins had already been lost after the first subcultivation, whereas overproduction was stable in others. However, after five passages, most of the cultures showed normal collagen synthesis, which probably indicates a loss of phenotype due to successive subcultures or overgrowth by another population of fibroblasts.

Self Reactive Repertoire of Tight Skin Mouse: Immunochemical and Molecular Characterization of Anti-Topoisomerase I Autoantibodies

Tight skin (TSK) mice develop cutaneous hyperplasia accompanied by histopathological alterations of skin and collagen metabolism similar to those described in human scleroderma. Diffuse scleroderma, the most severe form of progressive systemic sclerosis, is associated with the production of autoantibodies specific for Scleroderma 70 antigen (topoisomerase I). Our studies show that there is an increase in the level of serum anti-topoisomerase I (topo I) autoantibodies in aged TSK mice. The monoclonal antibodies isolated from TSK mice bind to epitopes which interact with autoantibodies from scleroderma patients. A significant number of TSK monoclonal anti-topo I antibodies and serum immunoglobulin (Ig) from aged TSK mice bear a cross reactive idiotype (Id) recognized by a syngeneic monoclonal anti-Id antibody obtained from a 2 month-old TSK mouse. Analysis of V gene usage by monoclonal anti-topo I antibodies showed that the majority of these antibodies are encoded by VH genes derived from VHJ558 family pairing with VK genes from various families in a stochastic manner.

Amino and carboxyl propeptides in bone collagen fibrils during embryogenesis

SummaryCollagen fibrillogenesis was studied in tibiae of chick embryos, 9, 11, and 14 days old. Specimens were incubated with antibodies against the amino and the carboxyl propeptides of type-I collagen and subjected to ferritin-la-belling immuno-electron microscopy. The amino propeptide was found in thin fibrils, 20–40 nm in diameter, distributed at 60-nm periodicity. The carboxyl propeptide antibody labelled a wide spectrum of fibrils, although the majority were in the range of 40–100 nm, distinctly larger than those labelled with the amino propeptide antibody. The presence of pN (amino propeptide plus collagen) and pC (carboxyl propeptide plus collagen) collagen was also demonstrated by Western blotting in all specimens. This study suggests that the sequence of propeptide removal may regulate collagen fibril diameter.