Synergy between Laminin-Derived Elastin-like Polypeptides (LELPs) Optimizes Cell Spreading.

A major component of the extracellular matrix (ECM), laminins, modulates cells via diverse receptors. Their fragments have emerging utility as components of "ECM-mimetics" optimized to promote cell-based therapies. Recently, we reported that a bioactive laminin peptide known as A99 enhanced cell binding and spreading via fusion to an elastin-like polypeptide (ELP). The ELP "handle" serves as a rapid, noncovalent strategy to concentrate bioactive peptide mixtures onto a surface. We now report that this strategy can be further generalized across an expanded panel of additional laminin-derived elastin-like polypeptides (LELPs). A99 (AGTFALRGDNPQG), A2G80 (VQLRNGFPYFSY), AG73 (RKRLQVQLSIRT), and EF1m (LQLQEGRLHFMFD) all promote cell spreading while showing morphologically distinct F-actin formation. Equimolar mixtures of A99:A2G80-LELPs have synergistic effects on adhesion and spreading. Finally, three of these ECM-mimetics promote the neurite outgrowth of PC-12 cells. The evidence presented here demonstrates the potential of ELPs to deposit ECM-mimetics with applications in regenerative medicine, cell therapy, and tissue engineering.

RGDX1 X2 motif regulates integrin αvß5 binding for pluripotent stem cell adhesion.

The arginine-glycine-aspartic acid (RGD) motif is a cell adhesion sequence that binds to integrins. Some RGD-containing peptides promote adhesion of both embryonic stem cells and induced pluripotent stem cells (iPSCs); however, not all such RGD-containing peptides are active. In this study, we elucidated the role of RGD-neighboring sequences on iPSC adhesion using diverse synthetic peptides and recombinant proteins. Our results indicate that iPSC adhesion requires RGDX1 X2  sequences, such as RGDVF and RGDNY, and that the X1 X2 residues are essential for the adhesion via integrin αvß5 but not αvß3. iPSCs express integrin αvß5 but not αvß3; therefore, iPSC adhesion requires the RGDX1 X2 -containing sequences. The importance of the X1 X2 residues was confirmed with both HeLa and A549 cells, which express integrin αvß5 but not αvß3. Analysis of RGD-neighboring sequences provides important insights into ligand-binding specificity of integrins. Identification of integrin αvß5-binding motifs is potentially useful in drug development, drug delivery, cell culture, and tissue engineering.

Effects of laminin-111 peptide coatings on rat neural stem/progenitor cell culture.

Neurons require adhesive scaffolds for their growth and differentiation. Laminins are a major cell adhesive component of basement membranes and have various biological activities in the peripheral and central nervous systems. Here, we evaluated the biological activities of 5 peptides derived from laminin-111 as a scaffold for mouse neuroblastoma Neuro2a cells and rat neural stem/progenitor cells (NPCs). The 5 peptides showed Neuro2a cell attachment activity similar to that of poly-d-lysine. However, when NPCs were cultured on the peptides, 2 syndecan-binding peptides, AG73 (RKRLQVQLSIRT, mouse laminin α1 chain 2719-2730) and C16 (KAFDITYVRLKF, laminin γ1 chain 139-150), demonstrated significantly higher cell attachment and neurite extension activities than other peptides including integrin-binding ones. Long-term cell culture experiments showed that both AG73 and C16 supported the growth of neurons and astrocytes that had differentiated from NPCs. Furthermore, C16 markedly promoted the expression of neuronal markers such as synaptosomal-associated protein-25 and syntaxin 1A. These results indicate that AG73 and C16 are useful for NPC cultures and that C16 can be applied to specialized research on synapses in differentiated neurons. These peptides have the potential for use as valuable biomaterials for NPC research.

Octa-arginine and Octa-lysine Promote Cell Adhesion through Heparan Sulfate Proteoglycans and Integrins.

Octa-arginine (R8) has been extensively studied as a cell-penetrating peptide. R8 binds to diverse transmembrane heparan sulfate proteoglycans (HSPGs), including syndecans, and is internalized by cells. R8 is also reported to bind to integrin ß1. In this study, we evaluated the biological activities of R8 and octa-lysine (K8), a peptide similar to R8, with a focus on cell adhesion. R8 and K8 were immobilized on aldehyde-agarose matrices via covalent conjugation, and the effect of these peptides on cell attachment, spreading, and proliferation was examined using human dermal fibroblasts. The results indicated that R8- and K8-matrices mediate cell adhesion mainly via HSPGs. Moreover, R8- and K8-matrices interacted with integrin ß1 and promote cell spreading and proliferation. These results are useful for further understanding of the R8-membrane interactions and the cellular uptake mechanisms. In addition, the R8- and K8-matrices may potentially be used as a multi-functional biomaterial to promote cell adhesion, spreading, and proliferation.

Effect of Amino Acid Substitution on Cell Adhesion Properties of Octa-arginine.

Octa-arginine (R8) is a cell-permeable peptide with excellent cell adhesion properties. Surface-immobilized R8 mediates cell attachment via cell surface receptors, such as heparan sulfate proteoglycans and integrin ß1, and promotes cell spreading and proliferation. However, it is not clear how these properties are affected by specific peptide composition and if they could be improved. Here, we synthesized XR8 peptides, in which half of the original R8 arginine residues were replaced with another amino acid (X). We then aimed to investigate the effect of the substitution on cell adhesion and proliferation on XR8-conjugated agarose matrices. The XR8-matrix showed slightly better cell attachment when X was a hydrophobic or aromatic amino acid. However, hydrophobic XR8-matrices tended to promote cell proliferation to a less extent. Eventually, YR8-matrix most efficiently promoted cell adhesion, spreading, and proliferation among the XR8-matrices tested. Collectively, these observations indicate that the properties of residue X play a major role in the biological activity of XR8-matrices and shed light on the interaction between small peptides and the cell membrane. Further, YR8 is a promising cell-adhesive peptide for the development of cell culture substrates and biomaterials.

Structural Requirement of hA5G18 Peptide (DDFVFYVGGYPS) from Laminin α5 Chain for Amyloid-like Fibril Formation and Cell Adhesion.

The hA5G18 peptide (DDFVFYVGGYPS) identified from the human laminin α5 chain G domain promotes cell attachment and spreading when directly coated on a plastic plate, but does not show activity when it is conjugated on a chitosan matrix. Here, we focused on the structural requirement of hA5G18 for activity. hA5G18 was stained with Congo red and formed amyloid-like fibrils. A deletion analysis of hA5G18 revealed that FVFYV was a minimum active sequence for the formation of amyloid-like fibrils, but FVFYV did not promote cell attachment. Next, we designed functional fibrils using FVFYV as a template for amyloid-like fibrils. When we conjugated an integrin binding sequence Arg-Gly-Asp (RGD) to the FVFYV peptide with Gly-Gly (GG) as a spacer, FVFYVGGRGD promoted cell attachment in a plate coat assay, but a negative control sequence RGE conjugated peptide, FVFYVGGRGE, also showed activity. However, when the peptides were conjugated to Sepharose beads, the FVFYVGGRGD beads showed cell attachment activity, but the FVFYVGGRGE beads did not. These results suggest that RGD and RGE similarly contribute to cell attachment activity in amyloid-like fibrils, but only RGD contributes the activity on the Sepharose beads. Further, we conjugated a basic amino acid (Arg, Lys, and His) to the FVFYV peptide. Arg or Lys-conjugated FVFYV peptides, FVFYVGGR and FVFYVGGK, showed cell attachment activity when they were coated on a plate, but a His-conjugated FVFYV peptide FVFYVGGH did not show activity. None of the basic amino acid-conjugated peptides showed cell attachment in a Sepharose bead assay. The cell attachment and spreading on FVFYVGGR and FVFYVGGK were inhibited by an anti-integrin ß1 antibody. These results suggest that the Arg and Lys residues play critical roles in the interaction with integrins in amyloid-like fibrils. FVFYV is useful to use as a template for amyloid-like fibrils and to develop multi-functional biomaterials.

Evaluation of extracellular matrix mimetic laminin bioactive peptide and elastin-like polypeptide.

The extracellular matrix (ECM) is comprised of a large network of proteins that are essential for tissue development and repair. A bioactive RGD-containing peptide from laminin α1 chain, A99 (AGTFALRGDNPQG), promotes strong cell attachment and has demonstrated utility in cell culture and tissue engineering. Various materials can be utilized as a scaffold for bioactive peptides; however, it may be advantageous to design materials that use bioconjugation strategies that do not affect bioactivity, generate homogenous products, and can be produced at scale. This report is the first to compare the methods for preparing chemically conjugated and recombinant A99 to elastin-like polypeptides (ELPs) as the scaffold and characterize the biological and cell attachment activity using human dermal fibroblasts (HDFs). ELPs are biocompatible protein-polymers that are also thermo-responsive. Below a lower critical solution temperature (LCST), they are highly soluble. Above the LCST, ELPs phase separate into a polymer-rich liquid, known as a coacervate. Both chemically conjugated and recombinant fusion between A99 and an ELP (A99-ELP-R) show dose-dependent cell attachment. In addition, coating above the LCST provides better cell spreading compared to coating at 4°C. ELPs provide an excellent structural framework for deposition of bioactive peptides of the ECM, and their intrinsic biophysical properties make laminin peptide-ELPs promising biomaterials for cell culture and tissue engineering.

Fibulin-7 C-terminal fragment and its active synthetic peptide suppress choroidal and retinal neovascularization.

Wet age-related macular degeneration (AMD) and diabetic retinopathy are the leading causes of blindness through increased angiogenesis. Although VEGF-neutralizing proteins provide benefit, inconsistent responses indicate a need for new therapies. We previously identified the Fibulin-7 C-terminal fragment (Fbln7-C) as an angiogenesis inhibitor in vitro. Here we show that Fbln7-C inhibits neovascularization in vivo, in both a model of wet AMD involving choroidal neovascularization (CNV) and diabetic retinopathy involving oxygen-induced ischemic retinopathy. Furthermore, a short peptide sequence from Fbln7-C is responsible for the anti-angiogenic properties of Fbln7-C. Our work suggests Fbln7-C as a therapeutic candidate for wet AMD and ischemic retinopathy.

Development of Three-Dimensional Cell Culture Scaffolds Using Laminin Peptide-Conjugated Agarose Microgels.

Three-dimensional (3D) cell scaffolds are essential for tissue engineering. So far, various polymer hydrogels have been utilized to design 3D scaffolds as a biomaterial. In this study, we focused on a biocompatible polysaccharide, agarose, as a potential biomaterial candidate. We have previously established a laminin-derived cell adhesive peptide library, and these peptides are useful for incorporating cell adhesiveness into inert materials. We synthesized aldehyde-functionalized agarose (CHO-agarose) by (2,2,6,6-tetramethylpiperidin-1-yl)oxyl (TEMPO) oxidation of agarose and developed peptide-agarose scaffolds using two laminin peptides, CGG-A99 (CGGAGTFALRGDNPQG, binds to αvß3 integrin) and CGG-AG73 (CGGRKRLQVQLSIRT, binds to syndecan). The peptides were effectively loaded onto the CHO-agarose gels via thiazolidine formation without coupling reagents. Two-dimensional (2D) cell culture assay using human dermal fibroblasts (HDFs) showed that the peptide-agarose gels have potent cell adhesion activity and promoted cell proliferation. Furthermore, we developed a simple preparation method of 3D cell culture scaffolds using peptide-agarose microgels. HDFs cultured in a 3D environment of the A99-agarose microgel scaffold exhibited cell spreading morphology and proliferated significantly. These results suggest that 3D cell culture systems using peptide-agarose microgel scaffolds are promising as a biomaterial for tissue engineering.

Conformational dependence of integrin-binding peptides derived from homologous loop regions in the laminin α chains.

Laminin α chains (α1-α5 chains) are expressed in a tissue- and developmental stage-specific manner and have diverse chain-specific biological functions. Especially, laminin globular (LG) modules (LG1-LG5) located at the C-terminus of the α chains play a critical role in the biological activities of laminins. Each LG module is composed of a 14-stranded ß-sheet (A-N) sandwich structure. We previously screened cell attachment activity of the loop regions between the E and F strands in the LG modules using 17 homologous peptides (EF peptides) and found that four active EF peptides bind to integrin α2ß1. One of the four peptides, G4EF1 demonstrated improved cell attachment activity when cyclized. Here, we focused on the remaining three integrin α2ß1-binding EF peptides (G5EF1, G3EF3, and G5EF5) and analyzed the relationship between their peptide conformation and cell attachment activity. First, we determined their active core sequences and found that G5EF1z (IGLEIVDGKVLFHVNN), G3EF3z (LLVTLEDGHIALST), and G5EF5z (KVLTEQVL) are the core sequences. Cyclic peptides of the core sequences (cycloG5EF1z, cycloG3EF3z, and cycloG5EF5z) enhanced integrin-mediated cell adhesion activity compared with their linear peptides. The results indicated that cell adhesion activity of the integrin α2ß1-binding EF peptides is conformation dependent and that the loop structure is critical for their activity. This suggests that conformation of the loop regions plays an important role for the activities of the LG modules.

Identification of active sequences in human laminin α5 G domain.

Human laminin-511 (α5ß1γ1) and its truncated protein, laminin-511 E8 fragment, bind to integrin α6ß1 and have been widely used for embryonic stem cell and induced pluripotent stem cell culture under feeder-free conditions. In this study, we focused on human laminin α5 chain G domain, which is thought to be critical for the biological functions of laminin-511, and screened its biologically active sequences using a synthetic peptide library. We synthesized 115 peptides (hA5G1-hA5G115) covering the entire laminin α5 chain G domain and evaluated cell attachment activity using both the peptide-coated plate and peptide-chitosan matrix (peptide-ChtM) assays. Seventeen peptides demonstrated cell attachment activity in the assays. Both hA5G18 and hA5G26-coated plates and hA5G74-ChtMs promoted integrin ß1-mediated cell attachment. These findings are useful for the study of molecular mechanisms of laminin-511, and the active peptides have a potential for use as a molecular probe for cell adhesion receptors.

Biological activities of laminin-111-derived peptide-chitosan matrices in a primary culture of rat cortical neurons.

Cell adhesive biomaterials have been used for various cells in culture, especially for primary cultures of neurons. Here we examined laminin-111 and its active peptides conjugated to chitosan matrices (ChtMs) for primary culture of rat cortical neurons. Laminin-111 on poly-d-lysine substrate promoted neuronal cell attachment and differentiation. The biological activity of six active laminin-111-derived peptides was examined using a peptide-ChtM construct. When the syndecan-binding peptides, AG73 (RKRLQVQLSIRT, mouse laminin α1 chain 2719-2730) and C16 (KAFDITYVRLKF, laminin γ1 chain 139-150), were conjugated to chitosan, AG73-ChtM and C16-ChtM showed potent neuronal cell attachment activity and promoted axon extension by primary cultured rat cortical neurons. However, the remaining peptides, including integrin-binding peptides, did not show activity when conjugated to ChtM. AG73-ChtM and C16-ChtM also supported neuron survival for at least 4 weeks in serum-free medium without a glia feeder layer. These data suggest that AG73-ChtM and C16-ChtM are useful for primary cultures of central nervous system neurons and have a potential for use as functional biomaterials for tissue engineering in the central nervous system.

Development of a Screening System for Targeting Carriers Using Peptide-Modified Liposomes and Tissue Sections.

Liposomes have been used as targeting carriers for drug delivery systems (DDSs), and the carriers are able to be modified with targeting ligands, such as antibodies and peptides. To evaluate the targetability of DDS carriers modified with a targeting ligand, culture cells expressing the targeting molecules as well as small animals are used. Furthermore, in vitro and in vivo screening analyses must be repeatedly performed. Therefore, it is important to establish an easy and high-precision screening system for targeting carriers. With this aim, we focused that whether this ex vivo system could easily support assessment of interaction between targeting ligand and its receptor under physiological environment and further screen the DDS carrier-modified with targeting moiety. We examined targeting ability via in vitro, ex vivo, and in vivo analyses using integrin αvß3-targeting C16Y-L. For the in vitro analysis, the cellular uptake of C16Y-L was higher than that of control liposomes in colon26 cells. For the ex vivo analysis, we performed an immunohistochemical analysis using colon26 tumor sections. C16Y-L was specifically attached to the tumor sections, as found in the in vitro analysis. Moreover, to evaluate the ex vivo-in vivo correlation, we examined the intratumoral localization of C16Y-L. This result showed that C16Y-L was accumulated not only in the tumor tissue but also in the tumor vasculature after the intravenous injection of C16Y-L, suggesting that the ex vivo peptide-modified liposomal analysis was correlated with the in vivo analysis. Thus, the ex vivo peptide-modified liposomal analysis may be an easy and rapid screening system with high-precision and for consideration in in vivo conditions.

Mixed Peptide-Conjugated Chitosan Matrices as Multi-Receptor Targeted Cell-Adhesive Scaffolds.

Biomaterials are important for cell and tissue engineering. Chitosan is widely used as a scaffold because it is easily modified using its amino groups, can easily form a matrix, is stable under physiological conditions, and is inactive for cell adhesion. Chitosan is an excellent platform for peptide ligands, especially cell adhesive peptides derived from extracellular matrix (ECM) proteins. ECM proteins, such as collagen, fibronectin, and laminin, are multifunctional and have diverse cell attachment sites. Various cell adhesive peptides have been identified from the ECM proteins, and these are useful to design functional biomaterials. The cell attachment activity of peptides is influenced by the solubility, conformation, and coating efficiency to solid materials, whereas immobilization of peptides to a polysaccharide such as chitosan avoids these problems. Peptide⁻chitosan matrices promote various biological activities depending on the peptide. When the peptides are immobilized to chitosan, the activity of the peptides is significantly enhanced. Further, mixed peptide⁻chitosan matrices, conjugated with more than one peptide on a chitosan matrix, interact with multiple cellular receptors and promote specific biological responses via receptor cross-talk. Receptor cross-talk is important for mimicking the biological activity of ECM and the proteins. The mixed peptide⁻chitosan matrix approach is useful to develop biomaterials as a synthetic ECM for cell and tissue engineering.

Biological activity of peptide-conjugated polyion complex matrices consisting of alginate and chitosan.

Peptide-conjugated polysaccharide matrices using bioactive laminin-derived peptides are useful biomaterials for tissue and cell engineering. Here, we demonstrate an easy handling preparation method for peptide-polysaccharide matrices using polyion complex with both alginate and chitosan. First, aldehyde-alginate was synthesized by oxidization of alginate using NaIO4 , and then, reacted with Cys-peptides. Next, the peptide-alginate solution was added to a chitosan-coated plate, and the peptide-polyion complex matrices (peptide-PCMs) were prepared. The peptide-PCMs using an integrin αvß3-binding peptide (A99a: ALRGDN, mouse laminin α1 chain 1145-1150) and an integrin α2ß1-binding peptide (EF1XmR: RLQLQEGRLHFXFD, X = Nle, mouse laminin α1 chain 2751-2763) showed strong cell attachment activity in a dose-dependent manner. When we examined the effect of various spacers on the biological activity of A99a-PCM, hydrophobic and long spacers enhanced the cell attachment activity. Further, the A99a-PCM with the spacers strongly promoted neurite outgrowth. The polyion complex method is an easy way to obtain insolubilized matrix and is widely applicable for various polysaccharides. The peptide-PCM is useful as a biomaterial for cell and tissue engineering.

Identification of laminin α5 short arm peptides active for endothelial cell attachment and tube formation.

Laminin-511, a major component of endothelial basement membrane, consists of α5, ß1, and γ1 chains. The short arm region of the α5 chain is a structural feature of endothelial laminins. In this study, we identified active sequences for human umbilical vein endothelial cells (HUVECs) using recombinant proteins and synthetic peptides. The short arm of the α5 chain contains three globular domains [laminin N-terminal globular domain, laminin 4 domain a, and laminin 4 domain b (LN, L4a, and L4b)] and three rod-like elements [laminin epidermal growth factor-like domain a, b, and c (LEa, LEb, and LEc)]. The cell attachment assay using recombinant proteins showed that RGD-independent cell attachment sites were localized in the α5LN-LEa domain. Further, we synthesized 70 peptides covering the amino acid sequences of the α5LN-LEa domain. Of the 70 peptides, A5-16 (mouse laminin α5 230-243: LENGEIVVSLVNGR) potently exhibited endothelial cell attachment activity. An active sequence analysis using N-terminally and C-terminally truncated A5-16 peptides showed that the nine-amino acid sequence IVVSLVNGR was critical for the endothelial cell attachment activity. Cell adhesion to the peptides was dependent on both cations and heparan sulfate. Further, the A5-16 peptide inhibited the capillary-like tube formation of HUVECs with the cells forming small clumps with short tubes. The eight-amino acid sequence EIVVSLVN in the A5-16 peptide was critical to inhibit HUVEC tube formation. This amino acid sequence could be useful for grafts and thus modulate endothelial cell behavior for vascular surgery. Copyright © 2017 European Peptide Society and John Wiley & Sons, Ltd.

Down-regulation of cell adhesion via rho-associated protein kinase (ROCK) pathway promotes tumor cell migration on laminin-511.

Epithelial cells, both normal and precancerous, stably anchor to basement membranes, whereas malignant tumors pass through them to achieve metastasis. Of basement membrane components, laminin-511 (α5, ß1, γ1; LM-511) has been found to be a major isoform in many adult basement membranes. Several studies have shown that LM-511 promotes not only cell adhesion but also tumor cell migration. Thus, LM-511 can be viewed like two distinct molecules in normal vs. tumor cells; tumor cells seem to be able to alter their response (adhesive vs. migratory) to LM-511. In this study we examined the effects of biologically active molecules on A549 lung adenocarcinoma cell adhesion to LM-511. Of them, phorbol 12-myristate 13-acetate (PMA) induced transition to a rounded cell shape and significantly promoted cell migration on LM-511. The attachment of PMA-treated A549 cells to LM-511 was weaker than that of control cells. PMA-stimulated signaling pathway reduced the binding of integrin α3ß1 to LM-511. Cell migration assays using inhibitors for signal transduction and cytoskeletal organization showed that suppression of cell adhesion via the rho-associated protein kinase (ROCK) pathway promoted tumor cell migration on LM-511. Our results suggest that the ROCK pathway is involved in the transition from static to migratory cell behaviors on LM-511.

Production of Single-Chain Fv Antibodies Specific for GA-Pyridine, an Advanced Glycation End-Product (AGE), with Reduced Inter-Domain Motion.

Due to their lower production cost compared with monoclonal antibodies, single-chain variable fragments (scFvs) have potential for use in several applications, such as for diagnosis and treatment of a range of diseases, and as sensor elements. However, the usefulness of scFvs is limited by inhomogeneity through the formation of dimers, trimers, and larger oligomers. The scFv protein is assumed to be in equilibrium between the closed and open states formed by assembly or disassembly of VH and VL domains. Therefore, the production of an scFv with equilibrium biased to the closed state would be critical to overcome the problem in inhomogeneity of scFv for industrial or therapeutic applications. In this study, we obtained scFv clones stable against GA-pyridine, an advanced glycation end-product (AGE), by using a combination of a phage display system and random mutagenesis. Executing the bio-panning at 37 °C markedly improved the stability of scFvs. We further evaluated the radius of gyration by small-angle X-ray scattering (SAXS), obtained compact clones, and also visualized open.

Effect of spacer length and type on the biological activity of peptide-polysaccharide matrices.

Peptide-polysaccharide matrices can mimic extracellular matrix structure and function and are useful for tissue and cell engineering. The spacer between the peptide and the polysaccharide is important for both peptide conformation and the interaction between the peptide and receptors. Here, the effect of a spacer on the biological activity of peptide-polysaccharide matrices using various lengths of spacers consisting of glycine, ß-alanine, and ε-aminocaproic acid has been examined. Active laminin-derived peptides, including a syndecan-binding peptide (AG73: RKRLQVQLSIRT), an integrin αvß3-binding peptide (A99a: ALRGDN), and an integrin α6ß1-binding peptide (A2G10: SYWYRIEASRTG), were used as the peptide ligands and chitosan was used as a polysaccharide matrix. The spacers did not influence the biological activity of the AG73-chitosan matrix. In contrast, the integrin-binding peptide-chitosan matrices showed spacer-dependent activity. Hydrophobic spacers enhanced the cell attachment activity of the A99a-chitosan matrix. A four-glycine spacer showed the strongest effect for the biological activity of the A2G10-chitosan matrix. These results suggested that spacer-optimization for each peptide is important for designing effective peptide-polysaccharide matrices. © 2015 Wiley Periodicals, Inc. Biopolymers (Pept Sci) 106: 512-520, 2016.

Identification of peptides derived from the C-terminal domain of fibulin-7 active for endothelial cell adhesion and tube formation disruption.

Despite the research done on pathological angiogenesis, there is still a need for the development of new therapies against angiogenesis-related diseases. Fibulin-7 (Fbln7) is a member of the extracellular matrix fibulin protein family. The Fbln7 C-terminal fragment, Fbln7-C, binds to endothelial cells and inhibits their tube formation in culture. In this study, we screened 12 synthetic peptides, covering the fibulin-globular domain of Fbln7-C, to identify active sites for endothelial cell adhesion and in vitro antiangiogenic activity. Three peptides, fc10, fc11, and fc12, promoted Human Umbilical Vein Endothelial Cells (HUVECs) adhesion, and the morphology of HUVECs on fc10 was similar to that on Fbln7-C. EDTA and the anti-integrin ß1 function-blocking antibody inhibited HUVECs adhesion to both fc10 and fc12, and heparin inhibited HUVECs adhesion to both fc11 and fc12. fc10 and fc11 inhibited HUVECs tube formation. Our results suggest that three peptides from Fbln7-C are biologically active for endothelial cell adhesion and disrupt the tube formation, suggesting a potential therapeutic use of these peptides for angiogenesis-related diseases. © 2015 Wiley Periodicals, Inc. Biopolymers (Pept Sci) 106: 184-195, 2016.