Renato V. Iozzo

Proteoglycans of the extracellular environment: clues from the gene and protein side offer novel perspectives in molecular diversity and function.

This review focuses on the extracellular proteoglycans. Special emphasis is placed on the structural features of their protein cores, their gene organization, and their transcriptional control. A simplified nomenclature comprising two broad groups of extracellular proteoglycans is offered: the small leucine‐rich proteoglycans or SLRPs, pronounced “slurps,” and the modular proteoglycans. The first group encompasses at least five distinct members of a gene family characterized by a central domain composed of leucine‐rich repeats flanked by two cysteine‐rich regions. The second group consists of those proteoglycans whose unifying feature is the assembly of various protein modules in a relatively elongated and often highly glycosylated structure. This group is quite heterogeneous and includes a distinct family of proteoglycans, the “hyalectans,” that bind hyaluronan and contain a C‐type lectin motif that is likely to bind carbohydrates, and a less distinct group that contains structural homologies but lacks hyaluronan‐binding properties or lectin‐like domains.—Iozzo, R. V., Murdoch, A. D. Proteoglycans of the extracellular environment: clues from the gene and protein side offer novel perspectives in molecular diversity and function. FASEB J. 10, 598‐614 (1996)

The Biology of the Small Leucine-rich Proteoglycans FUNCTIONAL NETWORK OF INTERACTIVE PROTEINS

If one of the keys to biology is protein structure, then nature is an efficient operator, because it adopts a number of structurally related proteins to perform functions as diverse as maintaining the mineralized matrix of bones and teeth, the transparency of the cornea, the tensile strength of the skin and tendon, and the viscoelasticity of blood vessels. Proteoglycans play key roles in all of these fundamental biological processes and behave as potent effectors of cellular pathways. The past decade has witnessed an explosion of knowledge in the proteoglycan world, with significant advances in the genetics and cell biology of these complex macromolecules. This minireview describes recent advances in the biology of the small leucine-rich proteoglycan (SLRP) gene family with special emphasis on the biology of the archetype proteoglycan decorin. The focus is on the “functional network” created by these molecules in tissues, on genetic evidence for their functional roles during ontogeny, and on their activities as modulators of complex pathological processes such as fibrosis and cancer growth. Other more extensive reviews may serve to fill the gaps in this one (1–4).

Fibroblast growth factor-2.

Fibroblast growth factor-2 (FGF-2) is a member of a large family of proteins that bind heparin and heparan sulfate and modulate the function of a wide range of cell types. FGF-2 stimulates the growth and development of new blood vessels (angiogenesis) that contribute to the pathogenesis of several diseases (i.e. cancer, atherosclerosis), normal wound healing and tissue development. FGF-2 contains a number of basic residues (pI 9.6) and consists of 12 anti-parallel beta-sheets organized into a trigonal pyrimidal structure. FGF-2 binds to four cell surface receptors expressed as a number of splice variants. Many of the biological activities of FGF-2 have been found to depend on its receptors intrinsic tyrosine kinase activity and second messengers such as the mitogen activated protein kinases. However, considerable evidence suggest that intracellular FGF-2 might have a direct biological role particularly within the nucleus. In addition, heparan sulfate proteoglycans have been demonstrated to enhance and inhibit FGF-2 activity. The possibility that FGF-2 activity can be manipulated through alterations in heparan sulfate-binding is currently being exploited in the development of clinical applications aimed at modulating either endogenous or administered FGF-2 activity.

The family of the small leucine-rich proteoglycans : key regulators of matrix assembly and cellular growth

The focus of this review is on conceptual and functional advances in our understanding of the small leucine-rich proteoglycans. These molecules belong to an expanding gene class whose distinctive feature is a structural motif, called the leucine-rich repeat, found in an increasing number of intracellular and extracellular proteins with diverse biological attributes. Three-dimensional modeling of their prototype protein core proposes a flexible, arch-shaped binding surface suitable for strong and distinctive interactions with ligand proteins. Changes in the properties of individual proteoglycans derive from amino acid substitutions in the less conserved surface residues, changes in the number and length of the leucine-rich repeats, and/or variation in glycosylation. These proteoglycans are tissue organizers, orienting and ordering collagen fibrils during ontogeny and in pathological processes such as wound healing, tissue repair, and tumor stroma formation. These properties are rooted in their bifunctional character: the protein moiety binding collagen fibrils at strategic loci, the microscopic gaps between staggered fibrils, and the highly charged glycosaminoglycans extending out to regulate interfibrillar distances and thereby establishing the exact topology of fibrillar collagens in tissues. These proteoglycans also interact with soluble growth factors, modulate their functional activity, and bind to cell surface receptors. The latter interaction affects cell cycle progression in a variety of cellular systems and could explain the purported changes in the expression of these gene products around the invasive neoplastic cells and in regenerating tissues.

Basement membrane proteoglycans: from cellar to ceiling

The biology of basement membrane proteoglycans extends far beyond the original notion of anionic filters. These complex molecules have dual roles as structural constituents of basement membranes and functional regulators of several growth-factor signalling pathways. As such, they are involved in angiogenesis and, consequently, in tumour progression and their partial or total absence causes several congenital defects that affect the musculoskeletal, cardiovascular and nervous systems. New findings indicate a potential functional coupling between the intricate make-up of basement membrane proteoglycans and their ability to control important biological processes.

Heparan sulfate proteoglycans: heavy hitters in the angiogenesis arena

Without new blood vessels, neoplasms cannot expand beyond a few millimeters, the point at which the diffusion of nutrients and the disposal of waste products become rate-limiting. Regulation of angiogenesis thus must be controlled at multiple levels. For instance, the VEGF family of heparin-binding proteins and their primary receptors, VEGFR-1 and VEGFR-2 (KDR), products of the flt-1 and the flk-1 gene, respectively, are required for angioblast differentiation and vasculogenesis, and specific VEGF isoforms play distinct roles in promoting endothelial growth and migration during angiogenesis. In addition, angiogenesis is profoundly affected by several members of the FGF family and their four receptors, and indeed, supplementing the media of endothelial cell cultures with basic FGF (FGF2) and heparin is now well established as a means to obtain optimal growth, migration, and capillary morphogenesis. In addition to producing proangiogenic factors, tumor cells also directly or indirectly generate negative angiogenic stimuli. The ultimate growth rate of the tumors is thus a fine balance between positive and negative angiogenic cues.

Biological Functions of the Small Leucine-rich Proteoglycans: From Genetics to Signal Transduction

The small leucine-rich proteoglycan (SLRP) family has significantly expanded in the past decade to now encompass five discrete classes, grouped by common structural and functional properties. Some of these gene products are not classical proteoglycans, whereas others have new and unique features. In addition to being structural proteins, SLRPs constitute a network of signal regulation: being mostly extracellular, they are upstream of multiple signaling cascades. They affect intracellular phosphorylation, a major conduit of information for cellular responses, and modulate distinct pathways, including those driven by bone morphogenetic protein/transforming growth factor β superfamily members, receptor tyrosine kinases such as ErbB family members and the insulin-like growth factor I receptor, and Toll-like receptors. The wealth of mechanistic insights into the molecular and cellular functions of SLRPs has revealed both the sophistication of this family of regulatory proteins and the challenges that remain in uncovering the totality of their functions. This review is focused on novel biological functions of SLRPs with special emphasis on their protein cores, newly described genetic diseases, and signaling events in which SLRPs play key functions.

Decorin Is a Biological Ligand for the Epidermal Growth Factor Receptor

Ectopic expression of decorin induces profound cytostatic effects in transformed cells with diverse histogenetic backgrounds. The mechanism of action has only recently begun to be elucidated. Exogenous decorin activates the epidermal growth factor (EGF) receptor, thereby triggering a signaling cascade that leads to phosphorylation of mitogen-activated protein (MAP) kinase, induction of p21, and growth suppression. In this study we demonstrate a direct interaction of decorin with the EGF receptor. Binding of decorin induces dimerization of the EGF receptor and rapid and sustained phosphorylation of MAP kinase in squamous carcinoma cells. In a cell-free system, decorin induces autophosphorylation of purified EGF receptor by activating the receptor tyrosine kinase and can also act as a substrate for the EGF receptor kinase itself. Using radioligand binding assays we show that both immobilized and soluble decorin bind to the EGF receptor ectodomain or to purified EGF receptor. The binding is mediated by the protein core and has relatively low affinity (K d ∼87 nm). Thus, decorin should be considered as a novel biological ligand for the EGF receptor, an interaction that could regulate cell growth during remodeling and cancer growth.

MODEL STRUCTURE OF DECORIN AND IMPLICATIONS FOR COLLAGEN FIBRILLOGENESIS

The three-dimensional structure of human decorin, a secreted proteoglycan involved in the regulation of collagen fibrillogenesis and cellular growth, has been modeled based on the crystal structure of the porcine ribonuclease inhibitor. Both proteins contain leucine-rich repeats and share 18% identical residues. This model structure of decorin has an arch shape with the single glycosaminoglycan chain and the three N-linked oligosaccharides located on the same side of the molecule. Decorin was modeled as binding to a polar sequence of collagen type I found in the d band. The inner concave surface is the appropriate size and shape to accommodate only one collagen triple helix of ∼3 nm in length. The binding of one collagen triple helix to decorin is proposed to play a major role in the formation of the staggered arrangement of collagen molecules within the microfibrils by preventing lateral fusion of collagen molecules.

The role of decorin in collagen fibrillogenesis and skin homeostasis.

Decorin, a prototype member of the growing family of the small leucine-rich proteoglycans (SLRPs), plays significant roles in tissue development and assembly, as well as playing both direct and indirect signaling roles. This review will concentrate on decorins function in collagen fibrillogenesis as determined through the study of mice with a disrupted decorin gene. The fragile skin and abnormal tendon phenotypes initially observed were found to be due to fundamental alterations in collagen fibers, highlighting the crucial role of proteoglycans in general and SLRPs in particular in collagen fibrillogenesis. The altered fibril formation within tissues in turn leads to observable and quantifiable changes at the organismal level. Research into certain fibrotic processes with concomitant upregulation or reduction of decorin makes interesting comparisons with the collagen malformations seen in Dcn−/− mice. Overall, decorin is shown to be a vital player in maintaining skin and tendon integrity at the molecular level, among other functions. Published in 2003.