Collagens, modifying enzymes and their mutations in humans, flies and worms

Collagens and proteins with collagen-like domains form large superfamilies in various species, and the numbers of known family members are increasing constantly. Vertebrates have at least 27 collagen types with 42 distinct polypeptide chains, >20 additional proteins with collagen-like domains and approximately 20 isoenzymes of various collagen-modifying enzymes. Caenorhabditis elegans has approximately 175 cuticle collagen polypeptides and two basement membrane collagens. Drosophila melanogaster has far fewer collagens than many other species but has approximately 20 polypeptides similar to the catalytic subunits of prolyl 4-hydroxylase, the key enzyme of collagen synthesis. More than 1300 mutations have so far been characterized in 23 of the 42 human collagen genes in various diseases, and many mouse models and C. elegans mutants are also available to analyse the collagen gene family and their modifying enzymes.     

Molecular and biochemical aspects of nematode collagens.

Collagens are major structural proteins of nematode cuticles and basement membranes (basal laminae). The collagen proteins that form these structures differ in their biochemical and physical properties and are encoded by distinct gene families. Nematode basement membrane collagens are large proteins that show strong homology to basement membrane collagens of vertebrates. There appear to be 2 nonidentical basement membrane collagen genes in nematodes. Cuticle collagens are about one-sixth the size of basement membrane collagens and are encoded by a large family of 20-150 nonidentical genes. Cuticle collagens can be subdivided into 4 families based upon certain structural features in the proteins. The mature, extracellular forms of both types of collagen proteins are extensively cross-linked by disulfide bonds and are largely insoluble in the absence of a thiol-reducing agent. Cuticle collagens also are cross-linked by nonreducible covalent bonds that involve tyrosine residues. The experimental studies that have led to our current understanding of the structures of basement membrane and cuticle collagens are reviewed. Some previous questions about the physical properties of these proteins are reexamined in light of the primary sequence information now available for the proteins.     

The collagen family members as cell adhesion proteins

The collagen family of extracellular matrix proteins has played a fundamental role in the evolution of multicellular animals. At the present, 28 triple helical proteins have been named as collagens and they can be divided into several subgroups based on their structural and functional properties. In tissues, the cells are anchored to collagenous structures. Often the interaction is indirect and mediated by matrix glycoproteins, but cells also express receptors, which have the ability to directly bind to the triple helical domains in collagens. Some receptors bind to sites that are abundant in all collagens. However, increasing evidence indicates that the coevolution of collagens and cell adhesion mechanisms has given rise to receptors that bind to specific motifs in collagens. These receptors may also recognize the different members of the large collagen family in a selective manner. This review summarizes the present knowledge about the properties of collagen subtypes as cell adhesion proteins.     

Nematode collagen genes

The collagen genes of nematodes encode proteins that have a diverse range of functions. Among their most abundant products are the cuticular collagens, which include about 80% of the proteins present in the nematode cuticle. The structures of these collagens have been found to be strikingly similar in the free-living and parasitic nematode species studied so far, and the genes that encode them appear to constitute a large multigene family whose expression is subject to developmental regulation. Collagen genes that may have a role in cell-cell interactions and collagen genes that correspond to the vertebrate type IV collagen genes have also been identified and studied in nematodes.     

Cuticle collagen genes. Expression in Caenorhabditis elegans

Collagen is a structural protein used in the generation of a wide variety of animal extracellular matrices. The exoskeleton of the free-living nematode, Caenorhabditis elegans, is a complex collagen matrix that is tractable to genetic research. Mutations in individual cuticle collagen genes can cause exoskeletal defects that alter the shape of the animal. The complete sequence of the C. elegans genome indicates upwards of 150 distinct collagen genes that probably contribute to this structure. During the synthesis of this matrix, individual collagen genes are expressed in distinct temporal periods, which might facilitate the formation of specific interactions between distinct collagens.     

Two sets of interacting collagens form functionally distinct substructures within a Caenorhabditis elegans extracellular matrix

A ubiquitous feature of collagens is protein interaction, the trimerization of monomers to form a triple helix followed by higher order interactions during the formation of the mature extracellular matrix. The Caenorhabditis elegans cuticle is a complex extracellular matrix consisting predominantly of cuticle collagens, which are encoded by a family of approximately 154 genes. We identify two discrete interacting sets of collagens and show that they form functionally distinct matrix substructures. We show that mutation in or RNA-mediated interference of a gene encoding a collagen belonging to one interacting set affects the assembly of other members of that set, but not those belonging to the other set. During cuticle synthesis, the collagen genes are expressed in a distinct temporal series, which we hypothesize exists to facilitate partner finding and the formation of appropriate interactions between encoded collagens. Consistent with this hypothesis, we find for the two identified interacting sets that the individual members of each set are temporally coexpressed, whereas the two sets are expressed approximately 2 h apart during matrix synthesis.     

Temporal reiteration of a precise gene expression pattern during nematode development.

The nematode Caenorhabditis elegans is contained within a multifunctional exoskeleton, the cuticle, that contains a large number of distinct collagens. As the nematode proceeds from the egg through four larval stages to the adult, transition between larval stages is marked by synthesis of a new cuticle and subsequent moulting of the old one. This is a cyclically repeated developmental event, frequently described as the moulting cycle. We have examined the temporal expression of a group of six genes encoding distinct cuticular collagens. As expected, mRNA abundance for each of the six genes tested is found to oscillate, peaking once during each larval stage. Unexpectedly, the periods of abundance for each gene do not coincide, different genes being expressed at different times relative to one another within the moulting cycle. We detect a programme of temporally distinct waves of collagen gene expression, the precise pattern of which is repeated during each of the four larval stages. This multiphasic pattern of oscillating cuticular collagen gene expression indicates an unexpected complexity of temporal control during the nematode moulting cycle and has implications for collagen trimerization and cuticle synthesis.     

Collagen types XII and XIV are present in basement membrane zones during human embryonic development

The collagens constitute a large group of proteins in the extracellular matrix that can be divided into several distinct families. Collagen types XII and XIV belong to a subgroup of non-fibrillar-collagens termed (fibril-associated collagens with interrupted triple-helices) (FACIT) and may be involved in basement membrane regulation providing specific molecular bridges between fibrils and other matrix components. However, the tissue distribution of the two proteins during human embryogenesis is still unclear. As a first step toward the elucidation of their possible cell biological functions, we compared the distribution of the two collagens during human organogenesis at the light microscopical level. We detected specific differences between the expression patterns of the two molecules, which may be related to their respective function within the basement membrane zones during human embryonic development. For example, in the developing intestine, collagen type-XII was present in the basement membrane zones of epithelia and endothelia. However, collagen type-XIV was restricted to the mesothelial basement membrane zones. We conclude that both collagens might well be able to serve different functions during human embryonic development although their structures are highly similar.     

The complete primary structure of type XII collagen shows a chimeric molecule with reiterated fibronectin type III motifs, von Willebrand factor A motifs, a domain homologous to a noncollagenous region of type IX collagen, and short collagenous domains with an Arg-Gly-Asp site

Extracellular matrix molecules are generally categorized as collagens, elastin, proteoglycans, or other noncollagenous structural/cell interaction proteins. Many of these extracellular proteins contain distinctive repetitive modules, which can sometimes be found in other proteins. We describe the complete primary structure of an alpha 1 chain of type XII collagen from chick embryonic fibroblasts. This large, structurally chimeric molecule identified by cDNA analysis combines previously unrelated molecular domains into a single large protein 3,124 residues long (approximately 340 kD). The deduced chicken type XII collagen sequence starts at the amino terminus with one unit of the type III motif of fibronectin, which is followed by one unit homologous to the von Willebrand factor A domain, then one more fibronectin type III module, a second A domain from von Willebrand factor, 6 units of type III motif and a third A domain, 10 consecutive units of type III motif and a fourth A domain, a domain homologous to the NC4 domain peptide of type IX collagen, and finally two short collagenous regions previously described as part of the partially sequenced collagen type XII molecule; an Arg-Gly-Asp potential cell adhesive recognition sequence is present in a hydrophilic region at the terminus of one collagenous domain. Antibodies raised to type XII collagen synthesized in a bacterial expression system recognized not only previously reported bands (220 kD et cetera) in tendons, but also bands with apparently different molecular sizes in fibroblasts and 4-d embryos. The antibodies stained a wide variety of extracellular matrices in embryos in patterns distinct from those of fibronectin or interstitial collagens. They prominently stained extracellular matrix associated with certain neuronal tissues, such as axons from dorsal root ganglia and neural tube. These studies identify a novel chimeric type of molecule that contains both adhesion molecule and collagen motifs in one protein. Its structure blurs current classification schemes for extracellular proteins and underscores the potentially large diversity possible in these molecules.     

Collagen XXVIII, a novel von Willebrand factor A domain-containing protein with many imperfections in the collagenous domain

Here we describe a novel collagen belonging to the class of von Willebrand factor A (VWA) domain-containing proteins. This novel protein was identified by screening the EST data base and was subsequently recombinantly expressed and characterized as an authentic tissue component. The COL28A1 gene on human chromosome 7p21.3 and on mouse chromosome 6A1 encodes a novel protein that structurally resembles the beaded filament-forming collagens. The collagenous domain contains several very short interruptions arranged in a repeat pattern. As shown for other novel minor collagens, the expression of collagen XXVIII protein in mouse is very restricted. In addition to small amounts in skin and calvaria, the major signals were in dorsal root ganglia and peripheral nerves. By immunoelectron microscopy, collagen XXVIII was detected in the sciatic nerve, at the basement membrane of certain Schwann cells surrounding the nerve fibers. Even though the protein is present in the adult sciatic nerve, collagen XXVIII mRNA was only detected in sciatic nerve of newborn mice, indicating that the protein persists for an extended period after synthesis.     

Regulation of collagen VI expression in fibroblasts. Effects of cell density, cell-matrix interactions, and chemical transformation

Collagen VI expression was studied in cultured human skin fibroblasts and mouse 3T3 cells using cDNA probes specific for alpha 1(VI), alpha 2(VI), and alpha 3(VI) chains. A 2-3-fold increase of these mRNAs was observed when fibroblasts were grown at increasing densities while only minimal changes occurred for the mRNA levels of collagens I and III, fibronectin, and beta-actin. Changes in mRNA correlated well with an increased production of corresponding proteins as determined by immunological assays. A comparable increase of alpha 1(VI) and alpha 2(VI) but not of alpha 3(VI) chain mRNAs was found for fibroblasts grown in a three-dimensional collagen gel after gel contraction. These conditions resulted, however, in a decrease of steady-state levels of collagens I and III and actin mRNAs. Transformation of 3T3 cells by phorbol ester did not change collagen VI mRNAs but caused a 3-5-fold reduction in mRNA levels for the other extracellular matrix proteins. These data strongly imply different regulatory mechanisms for the expression of collagen VI compared with collagens I and III and fibronectin. The differences may be correlated to changes in cell shape and reflect the requirement for collagen VI as a cell-binding protein.     

Cuvier meets Watson and Crick: the utility of molecules as classical homologies

Much phylogenetic information has been derived from the analysis of sequence similarity in genes and proteins. These data are generally considered to be more reliable than an examination of the phylogenetic distribution of similar biologically active molecules. However, molecules can provide significant phylogenetic information when accompanied by a careful analysis of their structure, synthesis, genetics and function. Molecules may be highly structurally and functionally constrained. Thus, similar or even chemically identical molecules may be unrelated, and this may be discernible only by examination of information beyond the simple structure of the molecule. Phylogenetic variation in the synthesis of tyrosine and lysine demonstrates that chemical identity of molecules may be brought about by unrelated synthetic pathways. The widespread distribution of collagen triple helices is shown to result from convergence under structural and functional constraints. This is demonstrated by an examination of the steric constraints upon collagens and the presence of several independent families of collagen genes. Lysyl oxidase crosslinking occurs in several unrelated proteins, indicating that similarity in the post-translational modification of proteins is not evidence of homology.     

Making recombinant extracellular matrix proteins

A variety of approaches to understand extracellular matrix protein structure and function require production of recombinant proteins. Moreover, the expression of heterologous extracellular matrix proteins, in particular collagens, using the recombinant technology is of major interest to the biomedical industry. Although extracellular matrix proteins are large, modular and often multimeric, most of them have been successfully produced in various expression systems. This review provides important factors, including the design of the construct, the cloning strategies, the expression vectors, the transfection method and the host cell systems, to consider in choosing a reliable and cost-effective way to make recombinant extracellular matrix proteins. Advantages and drawbacks of each system have been appraised. Protocols that may ease efficient recombinant production of extracellular matrix are described. Emphasis is placed on the recombinant collagen production. Members of the collagen superfamily exhibit specific structural features and generally require complex post-translational modifications to retain full biological activity that make more arduous their recombinant production.