Characterization of α1(IV) Collagen Mutations in Caenorhabditis elegans and the Effects of α1 and α2(IV) Mutations on Type IV Collagen Distribution

Type IV collagen is a major component of basement membranes. We have characterized 11 mutations in emb-9, the α1(IV) collagen gene of Caenorhabditis elegans, that result in a spectrum of phenotypes. Five are substitutions of glycines in the Gly-X-Y domain and cause semidominant, temperature-sensitive lethality at the twofold stage of embryogenesis. One is a glycine substitution that causes recessive, non–temperature-sensitive larval lethality. Three putative null alleles, two nonsense mutations and a deletion, all cause recessive, non–temperature-sensitive lethality at the threefold stage of embryogenesis. The less severe null phenotype indicates that glycine substitution containing mutant chains dominantly interfere with the function of other molecules. The emb-9 null mutants do not stain with anti–EMB-9 antisera and show intracellular accumulation of the α2(IV) chain, LET-2, indicating that LET-2 assembly and/or secretion requires EMB-9. Glycine substitutions in either EMB-9 or LET-2 cause intracellular accumulation of both chains. The degree of intracellular accumulation differs depending on the allele and temperature and correlates with the severity of the phenotype. Temperature sensitivity appears to result from reduced assembly/secretion of type IV collagen, not defective function in the basement membrane. Because the dominant interference of glycine substitution mutations is maximal when type IV collagen secretion is totally blocked, this interference appears to occur intracellularly, rather than in the basement membrane. We suggest that the nature of dominant interference caused by mutations in type IV collagen is different than that caused by mutations in fibrillar collagens.     

Differential expression of type IV collagen isoforms, α5(IV) and α6(IV) chains, in basement membranes surrounding smooth muscle cells

 Smooth muscle is composed of cigar-shaped, non-striated cells, each of which is encapsulated by a basement membrane and forms the contractile portion of tubular organs such as the gastrointestinal tract, pulmonary tract, genitourinary tract, and vasculature, in which slow and sustained contractions are needed. We examined basement membranes produced by smooth muscle cells and, using α(IV) chain-specific monoclonal antibodies, analyzed type IV collagens in these organs. Detailed distribution analysis of the α chains in normal and Alport cases by use of specific antibodies indicated that there are at least three molecular forms of type IV collagen, [α1(IV)]₂α2(IV), α3(IV)α4(IV)α5(IV), and α5(IV)/α6(IV). Smooth muscle cells in the urinary bladder and uterus were enclosed by basement membranes composed of α1, α2, α5, and α6 chains. The same α chains were present around smooth muscle cells in the muscular layer of the fundus of the stomach, whereas those in the antrum and further distal side of the gastrointestinal tract expressed mostly α1 and α2 chains. In addition, immunostaining analysis of the vasculature also showed that most of the smooth muscle cells were positive for α1 and α2 chains; however, α5 and α6 chains were also expressed by smooth muscle cells in the aorta and some arteries where blood pressure changes significantly. These results suggest that the smooth muscle cells enclosed by α5/α6-containing basement membranes might have some particular function related to mechanical stress or tensile strength during the characteristic contractile activity of tubular organs. Accepted: 23 March 1998     

The let-268 locus of Caenorhabditis elegans encodes a procollagen lysyl hydroxylase that is essential for type IV collagen secretion

Basement membranes are thin sheets of specialized extracellular matrix molecules that are important for supplying mechanical support and for providing an interactive surface for cell morphology. Prior to secretion and assembly, basement membrane molecules undergo intracellular processing, which is essential for their function. We have identified several mutations in a procollagen processing enzyme, lysyl hydroxylase (let-268). The Caenorhabditis elegans lysyl hydroxylase is highly similar to the vertebrate lysyl hydroxylase, containing all essential motifs required for enzymatic activity, and is the only lysyl hydroxylase found in the C. elegans sequenced genome. In the absence of C. elegans lysyl hydroxylase, type IV collagen is expressed; however, it is retained within the type IV collagen-producing cells. This observation indicates that in let-268 mutants the processing and secretion of type IV collagen is disrupted. Our examination of the body wall muscle in these mutant animals reveals normal myofilament assembly prior to contraction. However, once body wall muscle contraction commences the muscle cells separate from the underlying epidermal layer (the hypodermis) and the myofilaments become disorganized. These observations indicate that type IV collagen is required in the basement membrane for mechanical support and not for organogenesis of the body wall muscle.     

Extracellular chloride signals collagen IV network assembly during basement membrane formation

Basement membranes are defining features of the cellular microenvironment; however, little is known regarding their assembly outside cells. We report that extracellular Cl⁻ ions signal the assembly of collagen IV networks outside cells by triggering a conformational switch within collagen IV noncollagenous 1 (NC1) domains. Depletion of Cl⁻ in cell culture perturbed collagen IV networks, disrupted matrix architecture, and repositioned basement membrane proteins. Phylogenetic evidence indicates this conformational switch is a fundamental mechanism of collagen IV network assembly throughout Metazoa. Using recombinant triple helical protomers, we prove that NC1 domains direct both protomer and network assembly and show in Drosophila that NC1 architecture is critical for incorporation into basement membranes. These discoveries provide an atomic-level understanding of the dynamic interactions between extracellular Cl⁻ and collagen IV assembly outside cells, a critical step in the assembly and organization of basement membranes that enable tissue architecture and function. Moreover, this provides a mechanistic framework for understanding the molecular pathobiology of NC1 domains.     

Characterization of muscle epimysium, perimysium and endomysium collagens

In the past it has been proven difficult to separate and characterize collagen from muscle because of its relative paucity in this tissue. The present report presents a comprehensive methodology, combining methods previously described by McCollester [(1962) Biochim. Biophys. Acta 57, 427-437] and Laurent, Cockerill, McAnulty & Hastings [(1981) Anal. Biochem. 113, 301-312], in which the three major tracts of muscle connective tissue, the epimysium, perimysium and endomysium, may be prepared and separated from the bulk of muscle protein. Connective tissue thus prepared may be washed with salt and treated with pepsin to liberate soluble native collagen, or can be washed with sodium dodecyl sulphate to produce a very clean insoluble collagenous product. This latter type of preparation may be used for quantification of the ratio of the major genetic forms of collagen or for measurement of reducible cross-link content to give reproducible results. It was shown that both the epimysium and perimysium contain type I collagen as the major component and type III collagen as a minor component; perimysium also contained traces of type V collagen. The endomysium, the sheaths of individual muscle fibres, was shown to contain both type I and type III collagen as major components. Type V collagen was also present in small amounts, and type IV collagen, the collagenous component of basement membranes, was purified from endomysial preparations. This is the first biochemical demonstration of the presence of type IV collagen in muscle endomysium. The preparation was shown to be very similar to other type IV collagens from other basement membranes on sodium dodecyl sulphate/polyacrylamide-gel electrophoresis and was indistinguishable from EHS sarcoma collagen and placenta type IV collagen in the electron microscope after rotary shadowing.     

Assembly of type IV collagen. Insights from alpha3(IV) collagen-deficient mice

Type IV collagen includes six genetically distinct polypeptides named alpha1(IV) through alpha6(IV). These isoforms are speculated to organize themselves into unique networks providing mammalian basement membranes specificity and inequality. Recent studies using bovine and human glomerular and testis basement membranes have shown that unique networks of collagen comprising either alpha1 and alpha2 chains or alpha3, alpha4, and alpha5 chains can be identified. These studies have suggested that assembly of alpha5 chain into type IV collagen network is dependent on alpha3 expression where both chains are normally present in the tissue. In the present study, we show that in the lens and inner ear of normal mice, expression of alpha1, alpha2, alpha3, alpha4, and alpha5 chains of type IV collagen can be detected using alpha chain-specific antibodies. In the alpha3(IV) collagen-deficient mice, only the expression of alpha1, alpha2, and alpha5 chains of type IV collagen was detectable. The non-collagenous 1 domain of alpha5 chain was associated with alpha1 in the non-collagenous 1 domain hexamer structure, suggesting that network incorporation of alpha5 is possible in the absence of the alpha3 chain in these tissues. The present study proves that expression of alpha5 is not dependent on the expression of alpha3 chain in these tissues and that alpha5 chain can assemble into basement membranes in the absence of alpha3 chain. These findings support the notion that type IV collagen assembly may be regulated by tissue-specific factors.     

Ontogenesis of glomerular basement membrane: structural and functional properties

Protein A-gold immunocytochemistry was applied in combination with morphometrical approaches to reveal the alpha 1(IV), alpha 2(IV), and alpha 3(IV) chains of type IV collagen as well as entactin on renal basement membranes, particularly on the glomerular one, during maturation. The results have indicated that a heterogeneity between renal basement membranes appears during the maturation process. In the glomerulus at the capillary loop stage, both the epithelial and endothelial cell basement membranes were labeled for the alpha 1(IV) and alpha 2(IV) chains of type IV collagen and entactin. After fusion, both proteins were present on the entire thickness of the typical glomerular basement membrane. At later stages, the labeling for alpha 1(IV) and alpha 2(IV) chains of type IV collagen decreased and drifted towards the endothelial side, whereas the labeling for the alpha 3(IV) chain increased and remained centrally located. Entactin remained on the entire thickness of the basement membrane during maturation and in adult stage. The distribution of endogenous serum albumin in the glomerular wall was studied during maturation, as a reference for the functional properties of the glomerular basement membrane. This distribution, dispersed through the entire thickness of the basement membrane at early stages, shifted towards the endothelial side of the lamina densa with maturation, demonstrating a progressive acquisition of the permselectivity. These results demonstrate that modifications in the content and organization of the different constituents of basement membranes occur with maturation and are required for the establishment of the filtration properties of the glomerular basement membrane.     

Interactions of basement membrane components

The binding of laminin, type IV collagen, and heparan sulfate proteoglycan to each other was assessed. Laminin binds preferentially to native type IV (basement membrane) collagen over other collagens. A fragment of laminin (M_r 600 000) containing the three short chains (M_r 200 000) but lacking the long chain M_r 400 000) showed the same affinity for type IV collagen as the intact protein. The heparan sulfate proteoglycan binds well to laminin and to type IV collagen. These studies show that laminin, type IV collagen and heparan sulfate proteoglycan interact with each other. Such interactions in situ may determine the structure of basement membranes.     

Epitope-defined monoclonal antibodies against multiplexin collagens demonstrate that type XV and XVIII collagens are expressed in specialized basement membranes

Type XV and type XVIII collagens are classified as part of multiplexin collagen superfamily and their C-terminal parts, endostatin and restin, respectively, have been shown to be anti-angiogenic in vivo and in vitro. The alpha1(XV) and alpha1(XVIII) collagen chains are reported to be localized mainly in the basement membrane zone, but their distributions in blood vessels and nonvascular tissues have yet to be thoroughly clarified. In the present study, we raised monoclonal antibodies against synthetic peptides of human alpha1(XV) and alpha1(XVIII) chains and used them for extensive investigation of the distribution of these chains. We came to the conclusion that nonvascular BMs contain mainly one of two types: subepithelial basement membranes that contained type XVIII in general, or skeletal and cardiac muscles that harbored mainly type XV. But basement membranes surrounding smooth muscle cells in vascular tissues contained one or both of them, depending on their locations. Interestingly, continuous capillaries contained both type XV and type XVIII collagens in their basement membranes; however, fenestrated or specialized capillaries such as glomeruli, liver sinusoids, lung alveoli, and splenic sinusoids expressed only type XVIII in their basement membranes, lacking type XV. This observation could imply that different functions of basement membranes in various tissues and organs use different mechanisms for the endogenous control of angiogenesis.     

An embryonal carcinoma cell line as a model system to study developmentally regulated genes during myogenesis

We have established conditions to efficiently differentiate embryonic carcinoma stem cells of the line P19 into myogenic cells. As inducers for differentiation, a combination of embryoid body formation in conjunction with treatment with dimethyl sulfoxide and retinoic acid proved to be most efficient. Under these conditions we detected an accumulation of myosin- and actin-specific RNA. Also, large amounts of type IV collagen RNA were produced. Type IV collagen is a component of the muscle basement membrane. In analogy to the F-9 system, we found a drastic decrease in stable p53 mRNA under the differentiation conditions used.     

Reduction of Type IV Collagen by Upregulated miR-29 in Normal Elderly Mouse and klotho-Deficient,Senescence-Model Mouse

MicroRNA (miRNA), a small non-coding RNA that functions as a mediator in gene silencing, plays important roles in gene regulation in various vital functions and activities. Here we show that the miR-29 members are upregulated in klotho-deficient [klotho(−/−)] mice, a senescence-model animal, and also in normal elderly ICR mice relative to wild-type littermates and young ICR mice. In addition, levels of type IV collagen, a major component of basement membranes and a putative target of miR-29, were lower in klotho(−/−) and elderly ICR mice than in wild-type littermates and young ICR mice. RNA degradation mediated by miR-29 may participate in the suppression of type IV collagen, both in vivo and in vitro. Taken together, our current findings suggest that the miR-29 upregulated in aging may be involved in the downregulation of type IV collagen, leading to a possible weakening of the basal membrane in senescent tissues, and miR-29 may be a useful molecular marker of senescence.     

Connective tissue of rat lung. II: Ultrastructural localization of collagen types III, IV, and VI

We localized collagen types III, IV, and VI in normal rat lung by light and electron immunohistochemistry. Type IV collagen was present in every basement membrane examined and was absent from all other structures. Although types III and VI had a similar distribution, being present in the interstitium of major airways, blood vessels, and alveolar septa, as in other organs, they had different morphologies. Type III collagen formed beaded fibers, 15-20 nm in diameter, whereas type VI collagen formed fine filaments, 5-10 nm in diameter. Both collagen types were found exclusively in the interstitium, often associated with thick (30-35 nm) cross-banded type I collagen fibers. Occasionally, type III fibers and type VI filaments could be found bridging from the interstitium to the adventitial aspect of some basement membranes. Furthermore, the association of collagen type VI with types I and III and basement membranes suggests that type VI may contribute to integration of the various components of the pulmonary extracellular matrix into a functional unit.     

Localization of Type IV Collagen in the Myotome Cells during the Somite Differentiation in the Chick Embryo

Type IV collagen is a major structural component of basement membranes which play various roles upon their adjacent cells. In order to better understand roles of type IV collagen during the somite differentiation, we produced anti-rat type IV collagen polyclonal antibodies and demonstrated spacial and temporal distribution of type IV collagen in somites of the chick embryo by immunohistochemical procedure. Type IV collagen was detected in the basal surface and the cytoplasm of epithelial dermatome cells at early stage of the somite differentiation, and then detected in myotome cells overlying apical surface of dermatomes, but not in migratory mesenchymal dermatome cells. With the appearance of type IV collagen-expressing myotome cells, epithelial dermatome cells showed the decrease in immunoreaction with anti-type IV collagen antibodies, the disappearance of their basal-apical polarity and their epithelial shape. From these results, it was suggested that type IV collagen is an early marker for myotome cells, and that type IV collagen and/or other factors co-expressed by myotome cells might provide an accelerative signal for epithelial/mesenchymal conversion of dermatome cells.     

DCg1 αIV collagen chain of Drosophila melanogaster is synthesized during embryonic organogenesis by mesenchymal cells and is deposited in muscle basement membranes

We report the purification and characterization of three sequence-specific polyclonal antibodies raised against specific portions of the Drosophila αIV collagen chain produced from the gene DCg1. These antibodies were used for immunolocalization experiments on tissue sections from embryonic organogenesis stages (13–17) and first larval stages. This analysis was paralleled by in situ hybridization experiments with a labeled fragment of the gene DCg1. We demonstrated that, by late embryogenesis, the DCg1 αIV chain was synthesized by individual mesoblasts and deposited in basement membranes of skeletal and visceral muscles. These sites of αIV collagen deposition were the same, by first and second instars, but the protein was then synthesized by fat body cells. Our results were reminiscent of those obtained for vertebrate in vitro myogenesis, they suggested, moreover, a tissue-specific composition of basement membranes in Drosophila melanogaster.     

The incubation of laminin, collagen IV, and heparan sulfate proteoglycan at 35 degrees C yields basement membrane-like structures

Three basement membrane components, laminin, collagen IV, and heparan sulfate proteoglycan, were mixed and incubated at 35 degrees C for 1 h, during which a precipitate formed. Centrifugation yielded a pellet which was fixed in either potassium permanganate for ultrastructural studies, or in formaldehyde for Lowicryl embedding and immunolabeling with protein A-gold or anti-rabbit immunoglobulin-gold. Three types of structures were observed and called types A, B, and C. Type B consisted of 30-50-nm-wide strips that were dispersed or associated into a honeycomb-like pattern, but showed no similarity with basement membranes. Immunolabeling revealed that type B strips only contained heparan sulfate proteoglycan. The structure was attributed to self-assembly of this proteoglycan. Type A consisted of irregular strands of material that usually accumulated into semisolid groups. Like basement membrane, the strands contained laminin, collagen IV, and heparan sulfate proteoglycan, and, at high magnification, they appeared as a three-dimensional network of cord-like elements whose thickness averaged approximately 3 nm. But, unlike the neatly layered basement membranes, the type A strands were arranged in a random, disorderly manner. Type C structures were convoluted sheets composed of a uniform, dense, central layer which exhibited a few extensions on both surfaces and was similar in appearance and thickness to the lamina densa of basement membranes. Immunolabeling showed that laminin, collagen IV, and proteoglycan were colocalized in the type C sheets. At high magnification, the sheets appeared as a three-dimensional network of cords averaging approximately 3 nm. Hence, the organization, composition, and ultrastructure of type C sheets made them similar to the lamina densa of authentic basement membranes.     

Enhanced synthesis of type IV collagen in cultured arterial smooth muscle cells associated with phenotypic modulation by dimethyl sulfoxide

The effect of dimethyl sulfoxide (DMSO) on synthesis of basement membrane collagen in cultured smooth muscle cells was evaluated. DMSO promoted phenotypic modulation of cells from the synthetic state to the contractile state accompanied by formation of basement membranes. By immunofluorescence using monospecific antibody against type IV collagen, type IV collagen was identified not only in the cell cytoplasms but intensely along the cell surfaces in the cultures treated with DMSO for 7 days, as compared with untreated cultures. Electron microscopic immunohistochemistry revealed the presence of type IV collagen both in the basement membrane region and in the rough endoplasmic reticulum of DMSO-treated cells. Such an enhancement of type IV collagen synthesis appears to be expressed as a result of the phenotypic changes of smooth muscle cells to the contractile state modulated by DMSO.     

The multiple functions of collagen XVIII in development and disease

Collagen XVIII is a heparan sulphate proteoglycan which is expressed ubiquitously in different basement membranes throughout the body. Its C-terminal fragment, endostatin, has been found to inhibit angiogenesis and tumor growth by restricting endothelial proliferation and migration and inducing apoptosis of endothelial cells. Collagen XVIII has three variants, of which the shortest one is found in most vascular and epithelial BM structures, whereas the longer variants are found especially in the liver. The longest or frizzled variant has a cysteine-rich domain in its N-terminus that has been shown to inhibit Wnt signaling in vitro. The presence of collagen XVIII homologues in organisms such as C. elegans, Xenopus laevis, zebrafish and chick suggests a fundamental role for this BM collagen. Mutations in the collagen XVIII gene lead to the Knobloch syndrome, which is characterized by high myopia, vitreoretinal degeneration with retinal detachment, macular abnormalities and occipital encephalocele. Mice lacking collagen XVIII also show several ocular abnormalities. This suggests that in physiological conditions collagen XVIII is mostly needed for the proper development of the eye. Moreover, it appears to be needed for the structural stability of basement membranes in several other organs, and increasing evidence shows its importance for other organs in non-physiological situations such as atherosclerosis, glomerulonephritis or other type of tissue damage. This review focuses on clarifying the roles of collagen XVIII and its variants and domains in various physiological and pathological conditions.     

Basement Membrane Proteins: Structure,Assembly, and Cellular Interactions

Abstract

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.     

Immunofluorescent localization of type IV collagen and laminin during endochondral bone differentiation and regulation by pituitary growth hormone

Vascularization and the influence of growth hormone on this process were studied during endochondral bone differentiation. Vascular invasion was monitored by immunofluorescent localization of two vascular basement membrane proteins, type IV collagen and laminin, a recently described glycoprotein. In addition, endothelial cell invasion was identified by localization of Factor VIII. New bone formation was induced by subcutaneous implantation of a coarse powder of demineralized rat bone matrix. On days 1 through 9, no vascular elements were detected in the plaque. Mesenchymal cells appeared on day 3, proliferated, and differentiated into cartilage on day 7, while the capillaries proliferated at the periphery of the plaque. Beginning on day 9 with capillary incursion into the center of the plaque, type IV collagen, laminin, and Factor VIII were localized in the invading vascular endothelial cells. Type IV collagen and laminin appeared synchronously in the capillary basement membranes and later in the endothelial lining of cavernous sinusoids. Their distribution pattern was identical. The vascular invasion was prominent by day 14. In hypophysectomized rats, cartilage differentiated normally but vascularization was delayed and reduced. Bone formation was scanty as indicated by ⁴⁵Ca incorporation. Administration of bovine growth hormone to hypophysectomized recipients restored vascularization and bone formation to the level observed in controls.