The Bi-Functional Organization of Human Basement Membranes (original) (raw)
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The Bi-Functional Organization of Human Basement
The current basement membrane (BM) model proposes a single-layered extracellular matrix (ECM) sheet that is predominantly composed of laminins, collagen IVs and proteoglycans. The present data show that BM proteins and their domains are asymmetrically organized providing human BMs with side-specific properties: A) isolated human BMs roll up in a side-specific pattern, with the epithelial side facing outward and the stromal side inward. The rolling is independent of the curvature of the tissue from which the BMs were isolated. B) The epithelial side of BMs is twice as stiff as the stromal side, and C) epithelial cells adhere to the epithelial side of BMs only. Side-selective cell adhesion was also confirmed for BMs from mice and from chick embryos. We propose that the bi-functional organization of BMs is an inherent property of BMs and helps build the basic tissue architecture of metazoans with alternating epithelial and connective tissue layers.
Molecular architecture of basement membranes
FASEB journal : official publication of the Federation of American Societies for Experimental Biology, 1990
Basement membranes are specialized extracellular matrices with support, sieving, and cell regulatory functions. The molecular architectures of these matrices are created through specific binding interactions between unique glycoprotein and proteoglycan protomers. Type IV collagen chains, using NH2-terminal, COOH-terminal, and lateral association, form a covalently stabilized polygonal framework. Laminin, a four-armed glycoprotein, self-assembles through terminal-domain interactions to form a second polymer network, Entactin/nidogen, a dumbbell-shaped sulfated glycoprotein, binds laminin near its center and interacts with type IV collagen, bridging the two. A large heparan sulfate proteoglycan, important for charge-dependent molecular sieving, is firmly anchored in the basement membrane and can bind itself through a core-protein interaction to form dimers and oligomers and bind laminin and type IV collagen through its glycosaminoglycan chains. Heterogeneity of structure and function ...
Structural heterogeneity of the noncollagenous domain of basement membrane collagen
Journal of Biological Chemistry
The noncollagenous domain of collagen from three different basement membranes of bovine origin (glomerular, lens capsule, and placental) was excised with bacterial collagenase, purified under nondenaturing conditions, and characterized. In each case the domain existed as a hexamer comprised of four distinct subunits (al(IV)NCl, aZ(IV)NCl, M2*, and M3). Each subunit exists in both monomeric and dimeric (disulfide-cross-linked) forms. Certain dimers also exist which contain nonreducible cross-links. The hexamers from the three membranes differ with respect to stoichiometry of subunits and subunit isoforms and to the degree of cross-linking of monomers into dimers. The minor subunits, M2* and M3, vary in quantity over a 20-fold range relative to the major ones among the three hexamers. The results indicate that: 1) at least two populations of triple-helical collagen molecules, differing in chain composition, exist in each membrane and that their relative proportions are tissue-specific; and 2) the chemical nature of the noncollagenous domain of these populations is tissue-specific with regard to subunit isoforms and relative proportion of reducible and nonreducible cross-links in dimers.
New concepts in basement membrane biology
FEBS Journal, 2015
Basement membranes (BMs) are thin sheets of extracellular matrix that outline epithelia, muscle fibers, blood vessels and peripheral nerves. The current view of BM structure and functions is based mainly on transmission electron microscopy imaging, in vitro protein binding assays, and phenotype analysis of human patients, mutant mice and invertebrata. Recently, MS-based protein analysis, biomechanical testing and cell adhesion assays with in vivo derived BMs have led to new and unexpected insights. Proteomic analysis combined with ultrastructural studies showed that many BMs undergo compositional and structural changes with advancing age. Atomic force microscopy measurements in combination with phenotype analysis have revealed an altered mechanical stiffness that correlates with specific BM pathologies in mutant mice and human patients. Atomic force microscopy-based height measurements strongly suggest that BMs are more than two-fold thicker than previously estimated, providing greater freedom for modelling the large protein polymers within BMs. In addition, data gathered using BMs extracted from mutant mice showed that laminin has a crucial role in BM stability. Finally, recent evidence demonstrate that BMs are bi-functionally organized, leading to the proposition that BM-sidedness contributes to the alternating epithelial and stromal tissue arrangements that are found in all metazoan species. We propose that BMs are ancient structures with tissue-organizing functions and were essential in the evolution of metazoan species.
Basement membranes in skin: unique matrix structures with diverse functions?
Histochemistry and Cell Biology, 2009
The view of extracellular matrix (ECM) has evolved from a merely scaVolding and space Wlling tissue element to an interface actively controlling cellular activities and tissue functions. A highly specialized form of ECM is the basement membrane (BM), an ubiquitous sheet-like polymeric structure composed of a set of distinct glycoproteins and proteoglycans. In this review we are largely focusing on function and assembly of BM in skin (1) at the dermo-epidermal interface and (2) in the resident microvasculature. The role of the non-polymeric components perlecan and particularly nidogen is exempliWed by reviewing experiments based on genetic approaches and adequate experimental skin models in vivo and in vitro. While in mice total deWciency of one of these components is eventually developmentally lethal, the severity of the defects varies drastically between tissues and also the skin models recapitulating BM formation in vitro. There is accumulating evidence that this relies on the mechanical properties, the molecular composition of the BM, the adjacent ECM or connective tissue, the dynamics of molecular assembly, and 'minor' tissue-speciWc modiWer or adapter components. Though the role of nidogen or perlecan is still remaining a controversial issue, the statements 'being essential for BM/or not' should be consequently referred to the developmental, tissue, and functional (e.g., repair) context.
The role of laminins in basement membrane function
Journal of Anatomy, 1998
Laminins are a family of multifunctional macromolecules, ubiquitous in basement membranes, and represent the most abundant structural noncollagenous glycoproteins of these highly specialised extracellular matrices. Their discovery started with the difficult task of isolating molecules produced by cultivated cells or extracted from tissues. The development of molecular biology techniques has facilitated and accelerated the identification and the characterisation of new laminin variants making it feasible to identify full-length polypeptides which have not been purified. Further, genetically engineered laminin fragments can be generated for studies of their structure-function relationship, permitting the demonstration that laminins are involved in multiple interactions with themselves, with other components of the basal lamina, and with cells. It endows laminins with a central role in the formation, the architecture, and the stability of basement membranes. In addition, laminins may both separate and connect different tissues, i.e. the parenchymal and the interstitial connective tissues. Laminins also provide adjacent cells with a mechanical scaffold and biological information either directly by interacting with cell surface components, or indirectly by trapping growth factors. In doing so they trigger and control cellular functions. Recently, the structural and biological diversity of the laminins has started to be elucidated by gene targeting and by the identification of laminin defects in acquired or inherited human diseases. The consequent phenotypes highlight the pivotal role of laminins in determining heterogeneity in basement membrane functions.
2020
In vivo, cells are surrounded by extracellular matrix (ECM). To build organs from single cells, it is generally believed that ECM serves as a large-scale scaffold to coordinate cell positioning and differentiation. Nevertheless, how cells utilize cell-ECM interactions to spatiotemporally coordinate their positioning and differentiation to different ECM at the whole-tissue scale is not fully understood. Here, using in vitro assay with engineered MDCK cells co-expressing H2B-mCherry (nucleus) and gp135 (Podocalyxin)-GFP (apical marker), we show that such spatiotemporal coordination for epithelial morphogenesis and polarization can be initiated and determined by cell-soluble ECM interaction in the fluidic phase. The coordination depends on the native topology of ECM components such as sheet-like basement membrane (BM, mimicked by Matrigel in experiments) and linear fiber-like type I collagen (COL). Two types of coordination are found: scaffold formed by BM (COL) facilitates a close-end...