Mapping of SPARC/BM-40/Osteonectin-binding Sites on Fibrillar Collagens

Giudici, Camilla; Raynal, Nicolas; Wiedemann, Hanna; Cabral, Wayne A.; Marini, Joan C.; Timpl, Rupert; Bächinger, Hans Peter; Farndale, Richard W.; Sasaki, Takako; Tenni, Ruggero

doi:10.1074/jbc.m710001200

Cited by 90 publications

(103 citation statements)

References 62 publications

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“…SPARC FS-EC ⌬␣C binds with high affinity to residues 564-590 of the human collagen ␣1(III) chain (corresponding to 397-423 of the triplehelical domain) (13). A 33-residue peptide containing this collagen III region preceded by 2 GPO repeats forms a stable triple-helix and a 1:1 complex with SPARC FS-EC ⌬␣C (data not shown).…”

Section: Resultsmentioning

confidence: 94%

“…The only other plausible site from sequence analysis is a GATGFO sequence (GAAGFO in collagen III) halfway between the GVMGFO motif and the C terminus. Rotary shadowing electron micrographs indeed show a secondary SPARC-binding site in this region (13). The 6 distinct mammalian collagen IV chains assemble into 3 heterotrimers, of which the [␣1(IV)] 2 ␣2(IV) heterotrimer is the most abundant; invertebrates have only 1 type of collagen IV heterotrimer (1,32).…”

Section: Prediction Of Sparc-binding Sites In Collagens I-ivmentioning

confidence: 89%

“…The detailed collagen sequence requirements for SPARC binding have not been probed biochemically (13). From our structure, we predict an absolute requirement for phenylalanine at position 23 of the trailing chain.…”

Section: Prediction Of Sparc-binding Sites In Collagens I-ivmentioning

confidence: 96%

“…Collagens II and III are homotrimers. The major SPARC-binding site in the fibrillar collagens I-III, GVMGFO, is Ϸ600 residues from the C terminus of the triple helix (13). The only other plausible site from sequence analysis is a GATGFO sequence (GAAGFO in collagen III) halfway between the GVMGFO motif and the C terminus.…”

Section: Prediction Of Sparc-binding Sites In Collagens I-ivmentioning

confidence: 99%

“…The atomic details of this important interaction were revealed by a crystal structure of the integrin ␣2 I-domain bound to a 21-residue triple helical peptide, providing the only example to date of a vertebrate protein-collagen complex (10). More recent studies have identified a GVMGFO motif, conserved in collagens I-III and situated Ϸ100 residues (Ϸ30 nm) upstream of the GFOGER motif, as a binding hotspot for 3 structurally and functionally distinct proteins: the plasma protein von Willebrand factor (VWF), whose interaction with collagen contributes to haemostasis (11); the receptor tyrosine kinase DDR2 (12); and the extracellular matrix protein SPARC (13).…”

mentioning

confidence: 99%

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Structural basis of sequence-specific collagen recognition by SPARC

Hohenester

Sasaki

Giudici

et al. 2008

Proc. Natl. Acad. Sci. U.S.A.

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Protein interactions with the collagen triple helix play a critical role in collagen fibril formation, cell adhesion, and signaling. However, structural insight into sequence-specific collagen recognition is limited to an integrin-peptide complex. A GVMGFO motif in fibrillar collagens (O denotes 4-hydroxyproline) binds 3 unrelated proteins: von Willebrand factor (VWF), discoidin domain receptor 2 (DDR2), and the extracellular matrix protein SPARC/osteonectin/BM-40. We report the crystal structure at 3.2 Å resolution of human SPARC bound to a triple-helical 33-residue peptide harboring the promiscuous GVMGFO motif. SPARC recognizes the GVMGFO motifs of the middle and trailing collagen chains, burying a total of 720 Å 2 of solvent-accessible collagen surface. SPARC binding does not distort the canonical triple helix of the collagen peptide. In contrast, a critical loop in SPARC is substantially remodelled upon collagen binding, creating a deep pocket that accommodates the phenylalanine residue of the trailing collagen chain (''Phe pocket''). This highly restrictive specificity pocket is shared with the collagenbinding integrin I-domains but differs strikingly from the shallow collagen-binding grooves of the platelet receptor glycoprotein VI and microbial adhesins. We speculate that binding of the GVMGFO motif to VWF and DDR2 also results in structural changes and the formation of a Phe pocket. extracellular matrix ͉ X-ray crystallography C ollagen, the most abundant protein in vertebrates, is characterized by a triple-helical structure of 3 polypeptide chains containing repetitive glycine-X-XЈ triplets; the X and XЈ positions, respectively, are often occupied by the imino acids proline and 4-hydroxyproline (O). The 28 human collagens have numerous essential functions in tissue formation, stability and homeostasis, and mutations in collagen genes cause many human diseases (1). Collagens I-III, V and XI form supramolecular fibrils that lend mechanical stability to the vertebrate body. Normal collagen fibrillogenesis in vivo requires a number of globular proteins interacting with the triple helix, such as small leucine-rich repeat proteoglycans (2). Cellular interactions with collagen are mediated by a diverse group of transmembrane collagen receptors, including integrins, discoidin domain receptors (DDRs) and members of the Ig superfamily (3-5). Although the structure of the collagen triple helix has been known for Ͼ50 years (6), protein-collagen interactions remain poorly understood at the atomic level.Synthetic triple-helical peptides have been invaluable in mapping specific binding sites within collagen (7). The major integrin-binding site in fibrillar collagens I and II is a GFOGER motif (8, 9). The atomic details of this important interaction were revealed by a crystal structure of the integrin ␣2 I-domain bound to a 21-residue triple helical peptide, providing the only example to date of a vertebrate protein-collagen complex (10). More recent studies have identified a GVMGFO motif, conserved in collagens I-III...

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Section: Resultsmentioning

confidence: 94%

Section: Prediction Of Sparc-binding Sites In Collagens I-ivmentioning

confidence: 89%

Section: Prediction Of Sparc-binding Sites In Collagens I-ivmentioning

confidence: 96%

Section: Prediction Of Sparc-binding Sites In Collagens I-ivmentioning

confidence: 99%

mentioning

confidence: 99%

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Structural basis of sequence-specific collagen recognition by SPARC

Hohenester

Sasaki

Giudici

et al. 2008

Proc. Natl. Acad. Sci. U.S.A.

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124

115

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The Influence of the Extracellular Matrix in Inflammation: Findings from the SPARC‐Null Mouse

Riley

Bradshaw

2019

The Anatomical Record

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Matricellular proteins are secreted proteins that, among other functions, can contribute to extracellular matrix (ECM) assembly including modulation of cell:ECM interactions. Recent discoveries have indicated a fundamental role for the ECM in the regulation of inflammatory responses including cell extravasation and recruitment, immune cell differentiation, polarization, activation, and retention in tissues. Secreted protein acidic and rich in cysteine (SPARC) is a matricellular collagen-binding protein implicated in fibrillar collagen assembly in the ECM of connective tissue as well as in basal lamina organization. Functions of SPARC in modulating cell adhesion events are also reported. Studies of phenotypic responses observed in SPARC-null mice to a variety of injury models have yielded interesting insight into the functional importance of SPARC production and aberrations in ECM structure that occur in the absence of SPARC that influence immune cell behavior and inflammatory pathways. In this review, we will discuss several examples from different tissues in which SPARC-null mice exhibited an inflammatory response distinct from those of SPARC expressing mice and provide insight into novel ECM-dependent mechanisms that influence these responses.

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Aging‐related alterations in the extracellular matrix modulate the microenvironment and influence tumor progression

Sprenger

Plymate

Reed

2010

Intl Journal of Cancer

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Age is the greatest risk factor for the development of epithelial cancers. In this minireview, we will examine key extracellular matrix and matricellular components, their changes with aging, and discuss how these alterations might influence the subsequent progression of cancer in the aged host. Because of the tight correlation between advanced age and the prevalence of prostate cancer, we will use prostate cancer as the model throughout this minireview.Most tissues undergo significant modification with age. For the purposes of this review, the term aged refers to hosts that have reached greater than 75% of their species life expectancy and that generally have a larger percentage of cells (relative to young hosts) defined as senescent in many of their tissues.1-4 Senescent cells, which have ceased replicating but remain metabolically active, as well as normal aged cells influence the microenvironment of tissues. The relative contribution of senescent cells versus normal aged cells in remodeling the microenvironment is speculative, especially in regard to the effect of specific cell types (e.g., endothelial, epithelial, fibroblasts). In this review, we will explore the possible effects of senescent cells as just one of many factors that can alter the microenvironment in an aged host, thereby influencing tumor progression.Whereas cells have been the focus of most research in tissue aging, it is increasingly appreciated that pervasive changes also occur in the components of the extracellular space. [5][6][7][8] Modifications in the local environment, in turn, impact cellular functions. As an example, loss of tissue architecture is a defining characteristic of epithelial cancer initiation and progression. Thus an extracellular environment that provides the correct cues can serve as a powerful tumor suppressor-placing cells containing preneoplastic as well as oncogenic mutations into a normal tissue architecture reverts those cells back to a normal phenotype (e.g., polarization of epithelial cancer cells) despite the continued presence of oncogenic mutations. Conversely an environment that is rich in growth promoting mediators can spur on cells containing mutations to develop into cancer.6-8 These processes continually alter the composition of the microenvironment and subsequently influence tumor progression in the aged host.Within this extracellular environment, the influence of various growth factors has been at the core of cancer research. However, there is increasing interest in the roles of other components during tumor progression. The term Ó microenvironmentÓ now includes the extracellular matrix (e.g., collagens, laminins), matricellular components, soluble factors (hormones, cytokines, growth factors, enzymes) that are released by resident and circulating cells or transmitted by other organs, and a myriad of cell types (e.g., various immune cell populations, endothelial cells, fibroblasts, epithelial cells).6,9 Cells use membrane receptors, such as integrins and syndecans, to physically attach to components ...

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Mapping of SPARC/BM-40/Osteonectin-binding Sites on Fibrillar Collagens

Cited by 90 publications

References 62 publications

Structural basis of sequence-specific collagen recognition by SPARC

Structural basis of sequence-specific collagen recognition by SPARC

The Influence of the Extracellular Matrix in Inflammation: Findings from the SPARC‐Null Mouse

Aging‐related alterations in the extracellular matrix modulate the microenvironment and influence tumor progression

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