Impact of changes in collagen construction and molecular state on integrin - binding properties.

The interaction between the integrin and collagen is important in cell adhesion and signaling. Collagen, as the main component of extracellular matrix, is a base material for tissue engineering constructs. In tissue engineering, the collagen structure and molecule state may be altered to varying degrees in the process of processing and utilizing, thereby affecting its biological properties. In this work, the impact of changes in collagen structure and molecular state on the binding properties of collagen to integrin α2ß1 and integrin specific cell adhesion were explored. The results showed that the molecular structure of collagen is destroyed under the influence of heating, freeze-grinding and irradiation, the triple helix integrity is reduced and molecular breaking degree is increased. The binding ability of collagen to integrin α2ß1 is increased with the increase of triple helix integrity and decays exponentially with the increase of molecular breaking degree. The collagen molecular state can also influences the binding ability of collagen to cellular receptor. The collagen fibrils binding to integrin α2ß1 and HT1080 cells is stronger than to collagen monomolecule. Meanwhile, the hybrid fibril exhibits a different cellular receptor binding performance from corresponding single species collagen fibril. These findings provide ideas for the design and development of new collagen-based biomaterials and tissue engineering research.

Impact of UV- and carbodiimide-based crosslinking on the integrin-binding properties of collagen-based materials.

Collagen constructs are widely used for tissue engineering. These are frequently chemically crosslinked, using EDC, to improve their stability and tailor their physical properties. Although generally biocompatible, chemical crosslinking can modify crucial amino acid side chains, such as glutamic acid, that are involved in integrin-mediated cell adhesion. Instead UV crosslinking modifies aromatic side chains. Here we elucidate the impact that EDC, in combination with UV, exerts on the activity of integrin-binding motifs. By employing a model cell line that exclusively utilises integrin α2ß1, we found that whilst EDC crosslinking modulated cell binding, from cation-dependent to cation-independent, UV-mediated crosslinking preserved native-like cell binding, proliferation and surface colonisation. Similar results were observed using a purified recombinant I-domain from integrin α1. Conversely, binding of the I-domain from integrin α2 was sensitive to UV, particularly at low EDC concentrations. Therefore, from this in vitro study, it appears that UV can be used to augment EDC whist retaining a specific subset of integrin-binding motifs in the native collagen molecule. These findings, delineating the EDC- and UV-susceptibility of cell-binding motifs, permit controlled cell adhesion to collagen-based materials through specific integrin ligation in vitro. However, in vivo, further consideration of the potential response to UV wavelength and dose is required in the light of literature reports that UV initiated collagen scission may lead to an adverse inflammatory response. STATEMENT OF SIGNIFICANCE: Recently, there has been rapid growth in the use of extracellular matrix-derived molecules, and in particular collagen, to fabricate biomaterials that replicate the cellular micro-environment. Often chemical or physical crosslinkers are required to enhance the biophysical properties of these materials. Despite extensive use of these crosslinkers, the cell-biological consequences have not been ascertained. To address this, we have investigated the integrin-binding properties of collagen after chemically crosslinking with EDC and physically crosslinking with UV-irradiation. We have established that whilst EDC crosslinking abates all of the integrin binding sites in collagen, UV selectively inhibits interaction with integrin-α2 but not -α1. By providing a mechanistic model for this behaviour, we have, for the first time, defined a series of crosslinking parameters to systematically control the interaction of collagen-based materials with defined cellular receptors.

Molecular underpinnings of integrin binding to collagen-mimetic peptides containing vascular Ehlers-Danlos syndrome-associated substitutions.

Collagens carry out critical extracellular matrix (ECM) functions by interacting with numerous cell receptors and ECM components. Single glycine substitutions in collagen III, which predominates in vascular walls, result in vascular Ehlers-Danlos syndrome (vEDS), leading to arterial, uterine, and intestinal rupture and an average life expectancy of <50 years. Collagen interactions with integrin α2ß1 are vital for platelet adhesion and activation; however, how these interactions are impacted by vEDS-associated mutations and by specific amino acid substitutions is unclear. Here, we designed collagen-mimetic peptides (CMPs) with previously reported Gly → Xaa (Xaa = Ala, Arg, or Val) vEDS substitutions within a high-affinity integrin α2ß1-binding motif, GROGER. We used these peptides to investigate, at atomic-level resolution, how these amino acid substitutions affect the collagen III-integrin α2ß1 interaction. Using a multitiered approach combining biological adhesion assays, CD, NMR, and molecular dynamics (MD) simulations, we found that these substitutions differentially impede human mesenchymal stem cell spreading and integrin α2-inserted (α2I) domain binding to the CMPs and were associated with triple-helix destabilization. Although an Ala substitution locally destabilized hydrogen bonding and enhanced mobility, it did not significantly reduce the CMP-integrin interactions. MD simulations suggested that bulkier Gly → Xaa substitutions differentially disrupt the CMP-α2I interaction. The Gly → Arg substitution destabilized CMP-α2I side-chain interactions, and the Gly → Val change broke the essential Mg2+ coordination. The relationship between the loss of functional binding and the type of vEDS substitution provides a foundation for developing potential therapies for managing collagen disorders.

Dramatic and concerted conformational changes enable rhodocetin to block α2ß1 integrin selectively.

The collagen binding integrin α2ß1 plays a crucial role in hemostasis, fibrosis, and cancer progression amongst others. It is specifically inhibited by rhodocetin (RC), a C-type lectin-related protein (CLRP) found in Malayan pit viper (Calloselasma rhodostoma) venom. The structure of RC alone reveals a heterotetramer arranged as an αß and γδ subunit in a cruciform shape. RC specifically binds to the collagen binding A-domain of the integrin α2 subunit, thereby blocking collagen-induced platelet aggregation. However, until now, the molecular basis for this interaction has remained unclear. Here, we present the molecular structure of the RCγδ-α2A complex solved to 3.0 Å resolution. Our findings show that RC undergoes a dramatic structural reorganization upon binding to α2ß1 integrin. Besides the release of the nonbinding RCαß tandem, the RCγ subunit interacts with loop 2 of the α2A domain as result of a dramatic conformational change. The RCδ subunit contacts the integrin α2A domain in the "closed" conformation through its helix C. Combined with epitope-mapped antibodies, conformationally locked α2A domain mutants, point mutations within the α2A loop 2, and chemical modifications of the purified toxin protein, this molecular structure of RCγδ-α2A complex explains the inhibitory mechanism and specificity of RC for α2ß1 integrin.

The synthesis and coupling of photoreactive collagen-based peptides to restore integrin reactivity to an inert substrate, chemically-crosslinked collagen.

Collagen is frequently advocated as a scaffold for use in regenerative medicine. Increasing the mechanical stability of a collagen scaffold is widely achieved by cross-linking using 1-ethyl-3-(3-dimethylaminopropyl)carbodiimide (EDC) and N-hydroxysuccinimide (NHS). However, this treatment consumes the carboxylate-containing amino acid sidechains that are crucial for recognition by the cell-surface integrins, abolishing cell adhesion. Here, we restore cell reactivity to a cross-linked type I collagen film by covalently linking synthetic triple-helical peptides (THPs), mimicking the structure of collagen. These THPs are ligands containing an active cell-recognition motif, GFOGER, a high-affinity binding site for the collagen-binding integrins. We end-stapled peptide strands containing GFOGER by coupling a short diglutamate-containing peptide to their N-terminus, improving the thermal stability of the resulting THP. A photoreactive Diazirine group was grafted onto the end-stapled THP to allow covalent linkage to the collagen film upon UV activation. Such GFOGER-derivatized collagen films showed restored affinity for the ligand-binding I domain of integrin α2ß1, and increased integrin-dependent cell attachment and spreading of HT1080 and Rugli cell lines, expressing integrins α2ß1 and α1ß1, respectively. The method we describe has wide application, beyond collagen films or scaffolds, since the photoreactive diazirine will react with many organic carbon skeletons.

Cellular recognition and macropinocytosis-like internalization of nanoparticles targeted to integrin α2ß1.

Targeting nanoparticles to desired intracellular compartments is a major challenge. Integrin-type adhesion receptors are connected to different endocytosis routes in a receptor-specific manner. According to our previous observations, the internalization of an α2ß1-integrin-echovirus-1 complex takes place via a macropinocytosis-like mechanism, suggesting that the receptor could be used to target nanoparticles to this specific entry route. Here, silica-based nanoparticles, carrying monoclonal antibodies against the α2ß1 integrin as address labels, were synthesized. Studies with flow cytometry, atomic force microscopy and confocal microscopy showed the particles to attach to the cell surface via the α2ß1 integrin. Furthermore, quantitative analysis of nanoparticle trafficking inside the cell performed with the BioImageXD software indicated that the particles enter cells via a macropinocytosis-like process and end up in caveolin-1 positive structures. Thus, we suggest that different integrins can guide particles to distinct endocytosis routes and, subsequently, also to specific intracellular compartments. In addition, we show that with the BioImageXD software it is possible to conduct sensitive and complex analyses of the behavior of small fluorescent particles inside cells, using basic confocal microscopy images.

Histidine-rich glycoprotein blocks collagen-binding integrins and adhesion of endothelial cells through low-affinity interaction with α2 integrin.

The plasma protein histidine-rich glycoprotein (HRG) affects the morphology and function of both endothelial cells (ECs) and monocytes/macrophages in cancer. Here, we examined the mechanism of action of HRG's effect on ECs. HRG suppressed adhesion, spreading and migration of ECs specifically on collagen I (COL I) whereas ECs seeded on other extracellular matrix proteins were insensitive to HRG. HRG did not bind specifically to COL I or to the α-integrin binding site on collagen, GFOGER. Furthermore, HRG's inhibition of EC adhesion was not dependent upon heparan sulfate (HS) moieties as heparitinase-treated ECs remained sensitive to HRG. C2C12 cells expressing α2 integrin, the major collagen-binding α-integrin subunit in ECs, showed increased binding of HRG compared with wild type C2C12 cells lacking the α2 subunit. Recombinant α2 I-domain protein bound HRG and to a higher extent when in active conformation. However, the α2 I-domain bound weakly to HRG compared with COL I and the purified α2ß1 ectodomain complex failed to retain HRG. We conclude that HRG binds to α2 integrin through low-affinity interactions in a HS-independent manner, thereby blocking EC-adhesion to COL I.

The structure of hookworm platelet inhibitor (HPI), a CAP superfamily member from Ancylostoma caninum.

Secreted protein components of hookworm species include a number of representatives of the cysteine-rich/antigen 5/pathogenesis-related 1 (CAP) protein family known as Ancylostoma-secreted proteins (ASPs). Some of these have been considered as candidate antigens for the development of vaccines against hookworms. The functions of most CAP superfamily members are poorly understood, but one form, the hookworm platelet inhibitor (HPI), has been isolated as a putative antagonist of the platelet integrins αIIbß3 and α2ß1. Here, the crystal structure of HPI is described and its structural features are examined in relation to its possible function. The HPI structure is similar to those of other ASPs and shows incomplete conservation of the sequence motifs CAP1 and CAP2 that are considered to be diagnostic of CAP superfamily members. The asymmetric unit of the HPI crystal contains a dimer with an extensive interaction interface, but chromatographic measurements indicate that it is primarily monomeric in solution. In the dimeric structure, the putative active-site cleft areas from both monomers are united into a single negatively charged depression. A potential Lys-Gly-Asp disintegrin-like motif was identified in the sequence of HPI, but is not positioned at the apex of a tight turn, making it unlikely that it interacts with the integrin. Recombinant HPI produced in Escherichia coli was found not to inhibit the adhesion of human platelets to collagen or fibrinogen, despite having a native structure as shown by X-ray diffraction. This result corroborates previous analyses of recombinant HPI and suggests that it might require post-translational modification or have a different biological function.

Evaluation of prognostic integrin α2ß1 PET tracer and concurrent targeting delivery using focused ultrasound for brain glioma detection.

The ability to early detect and assess the treatment response of recurrent and/or disseminated metastatic glioblastoma is critical for the effective management of this group of patients. Accumulating experimental evidence indicates that integrin α2ß1 might be a prognostic biomarker for advanced phenotype of cancers. In this study, a novel (68)Ga-labeled integrin α2ß1-targeted PET tracer (68)Ga-NOTA-PEG4-cyclo (GDGEAyK) ((68)Ga-A2B1) was designed and evaluated for the potential prognostic imaging of glioblastoma tumor in preclinical model. To prospectively verify the prognostic value of integrin α2ß1, the in vitro Western blot and flow cytometry studies were performed to validate the integrin expression level of human glioblastoma (U87MG) cells. Extremely high expression level of integrin α2ß1 justifies its role as a potential targeting marker. Thus, (68)Ga-A2B1 positron emission tomography was performed in subcutaneous U87MG tumor bearing athymic mice at 15 min postinjection after injection of 7-8MBq tracers. The receptor targeting specificity was confirmed in a competition blocking experiment. The tumor uptake of (68)Ga-A2B1 in the control and blockage groups was 1.57 ± 0.13 %ID/g (n = 3) and 0.96 ± 0.23 %ID/g** (n = 3), respectively. However, because of the quick renal washout rate and labile nature of peptide tracers in circulation conditions, the focus ultrasound (FUS) mediated delivery method was adopted to enhance tumor uptake and retention of tracers. To test the FUS delivery efficacy in vivo, three experimental arms were designed as follows: tumor bearing mice were administrated with (68)Ga-A2B1 only or microbubbles (MBs) with FUS treatment ((68)Ga-A2B1 + FUS + MBs) or embedded (68)Ga-A2B1-microbubbles ((68)Ga-A2B1-MBs + FUS) followed with FUS sonication. The average radioactivity accumulation within a tumor was quantified from the multiple region of interest volumes using the %ID/g value and was analyzed in accordance with the ex vivo autoradiographic and pathologic data. The significant tumor uptake in (68)Ga-A2B1 + FUS +MBs group (n = 6) and (68)Ga-A2B1-MBs + FUS group (n = 4) following FUS treatment were calculated as 2.25 ± 0.50 %ID/g* and 2.6 ± 0.49 %ID/g**, comparing with (68)Ga-A2B1 only group 1.48 ± 0.42 %ID/g (n = 10). These results suggest that there is significant difference in (68)Ga-A2B1 tumor uptake by FUS treatment either with or without tracer integration with microbubbles, which demonstrate a promising delivery strategy and critical multimodal setting for phenotyping imaging of aggressive glioma tumor. In conclusion, (68)Ga labeled (68)Ga-A2B1 allows noninvasive imaging of tumor-associated α2ß1 expression and can be embedded in MB lipid shell for enhanced delivery and controlled release by sonoporation.

Integrin α2ß1 targeted GdVO4:Eu ultrathin nanosheet for multimodal PET/MR imaging.

Multifunctional nanoprobes open exciting possibilities for accurate diagnosis and therapy. In this research, we developed a (64)Cu-labeled GdVO4:4%Eu two-dimension (2D) tetragonal ultrathin nanosheets (NSs) that simultaneously possess radioactivity, fluorescence, and paramagnetic properties for multimodal imaging. The carboxyl-functionalized Eu(3+)-doped GdVO4 NSs were synthesized by a facile solvothermal reaction, followed by ligand exchange with polyacrylic acid (PAA). With ultrathin thickness of ∼5 nm and width of ∼150 nm, the carboxyl-functionalized NSs were further modified by DOTA chelator for (64)Cu labeling and Asp-Gly-Glu-Ala (DGEA) peptide for integrin α2ß1 targeting. After initial evaluation of the cytotoxicity and targeting capability with PC-3 cells, the obtained multifunctional nanoprobes ((64)Cu-DOTA-GdVO4:4%Eu-DGEA) were further explored for targeted positron emission tomography (PET) and T1-weighted magnetic resonance imaging (MRI) of PC-3 tumor (prostate cancer, high integrin α2ß1 expression) in vivo. Based on the strong fluorescence of the NSs, the particle distribution in mouse tissues was also determined by fluorescent microscopy. In summary, GdVO4:4%Eu NS is a potential multimodal multiscale nanoprobe that could not only be used for in vivo imaging, but also be tracked in cellular scale and ex vivo due to its fluorescent property.

α2ß1 Integrin.

The α2ß1 integrin, also known as VLA-2, GPIa-IIa, CD49b, was first identified as an extracellular matrix receptor for collagens and/or laminins [55, 56]. It is now recognized that the α2ß1 integrin serves as a receptor for many matrix and nonmatrix molecules [35, 79, 128]. Extensive analyses have clearly elucidated the α2 I domain structural motifs required for ligand binding, and also defined distinct conformations that lead to inactive, partially active or highly active ligand binding [3, 37, 66, 123, 136, 137, 140]. The mechanisms by which the α2ß1 integrin plays a critical role in platelet function and homeostasis have been carefully defined via in vitro and in vivo experiments [76, 104, 117, 125]. Genetic and epidemiologic studies have confirmed human physiology and disease states mediated by this receptor in immunity, cancer, and development [6, 20, 21, 32, 43, 90]. The role of the α2ß1 integrin in these multiple complex biologic processes will be discussed in the chapter.

Bone regeneration using an alpha 2 beta 1 integrin-specific hydrogel as a BMP-2 delivery vehicle.

Non-healing bone defects present tremendous socioeconomic costs. Although successful in some clinical settings, bone morphogenetic protein (BMP) therapies require supraphysiological dose delivery for bone repair, raising treatment costs and risks of complications. We engineered a protease-degradable poly(ethylene glycol) (PEG) synthetic hydrogel functionalized with a triple helical, α2ß1 integrin-specific peptide (GFOGER) as a BMP-2 delivery vehicle. GFOGER-functionalized hydrogels lacking BMP-2 directed human stem cell differentiation and produced significant enhancements in bone repair within a critical-sized bone defect compared to RGD hydrogels or empty defects. GFOGER functionalization was crucial to the BMP-2-dependent healing response. Importantly, these engineered hydrogels outperformed the current clinical carrier in repairing non-healing bone defects at low BMP-2 doses. GFOGER hydrogels provided sustained in vivo release of encapsulated BMP-2, increased osteoprogenitor localization in the defect site, enhanced bone formation and induced defect bridging and mechanically robust healing at low BMP-2 doses which stimulated almost no bone regeneration when delivered from collagen sponges. These findings demonstrate that GFOGER hydrogels promote bone regeneration in challenging defects with low delivered BMP-2 doses and represent an effective delivery vehicle for protein therapeutics with translational potential.

Identification of cell adhesive sequences in the N-terminal region of the laminin α2 chain.

The laminin α2 chain is specifically expressed in the basement membrane surrounding muscle and nerve. We screened biologically active sequences in the mouse laminin N-terminal region of α2 chain using 216 soluble peptides and three recombinant proteins (rec-a2LN, rec-a2LN+, and rec-a2N) by both the peptide- or protein-coated plate and the peptide-conjugated Sepharose bead assays. Ten peptides showed cell attachment activity in the plate assay, and 8 peptides were active in the bead assay. Seven peptides were active in the both assays. Five peptides promoted neurite outgrowth with PC12 cells. To clarify the cellular receptors, we examined the effects of heparin and EDTA on cell attachment to 11 active peptides. Heparin inhibited cell attachment to 10 peptides, and EDTA significantly affected only A2-8 peptide (YHYVTITLDLQQ, mouse laminin α2 chain, 117-128)-mediated cell attachment. Cell attachment to A2-8 was also specifically inhibited by anti-integrin ß1 and anti-integrin α2ß1 antibodies. These results suggest that A2-8 promotes an integrin α2ß1-mediated cell attachment. The rec-a2LN protein, containing the A2-8 sequence, bound to integrin α2ß1 and cell attachment to rec-a2LN was inhibited by A2-8 peptide. Further, alanine substitution analysis of both the A2-8 peptide and the rec-a2LN+ protein revealed that the amino acids Ile-122, Leu-124, and Asp-125 were involved in integrin α2ß1-mediated cell attachment, suggesting that the A2-8 site plays a functional role as an integrin α2ß1 binding site in the LN module. These active peptides may provide new insights on the molecular mechanism of laminin-receptor interactions.

Fluorescent small molecule probe to modulate and explore α2ß1 integrin function.

Collagen binding integrins are an important family of cell surface receptors that mediate bidirectionally signals between the interior of the cell and the extracellular matrix. The protein-protein interactions between cells and collagen are necessary for many physiological functions, but also promote diseases. For example, the interaction of α2ß1 integrin and collagen has been shown to have an important role in thrombus formation and cancer spread. The fact that the discovery of small molecules that can block such protein-protein interactions is highly challenging has significantly hindered the discovery of pharmaceutical agents to treat these diseases. Here, we present a rationally designed novel fluorescent molecule that can be synthesized in just a few minutes from commercially available starting materials. This molecule blocks the protein-protein interaction between α2ß1 integrin and collagen, and due to its fluorescent properties, it can be employed in wide variety of biological applications.

Biological stability evaluation of the α2ß1 receptor imaging agents: diamsar and DOTA conjugated DGEA peptide.

Robust chelating stability under biological condi-tions is critical for the design of copper-based radiopharmaceuticals. In this study, the stabilities of (64)Cu-DOTA and diamsar (two bifunctional Cu-64 chelators (BFCs)) conjugated DGEA peptides were evaluated. The in vitro stabilities of (64)Cu-DOTA-DGEA, (64)Cu-DOTA-Ahx-DGEA, and (64)Cu-Z-E(diamsar)-Ahx-DGEA were evaluated in PBS. A carboxyl-protected DOTA-DGEA was also synthesized to study the potential inter- and intramolecular interactions between DOTA and the carboxylate groups of DGEA peptide. microPET imaging of (64)Cu-DOTA-DGEA and (64)Cu-Z-E(diamsar)-Ahx-DGEA were performed in PC-3 prostate tumor model to further investigate the in vivo behavior of the tracers. DOTA-DGEA, DOTA-Ahx-DGEA, Z-E(diamsar)-Ahx-DGEA, and protected DOTA-DGEA peptides were readily obtained, and their identities were confirmed by MS. (64)Cu(2+) labeling was performed with high radiochemical yields (>98%) for all tracers after 1 h incubation. Stability experiments revealed that (64)Cu-DOTA-DGEA had unexpectedly high (64)Cu(2+) dissociation when incubated in PBS (>55% free (64)Cu(2+) was observed at 48 h time point). The (64)Cu(2+) dissociation was significantly reduced in the carboxyl-protected (64)Cu-DOTA-DGEA complex but not in the (64)Cu-DOTA-Ahx-DGEA complex, which suggests the presence of competitive binding for (64)Cu(2+) between DOTA and the carboxyl groups of the DGEA peptide. In contrast, no significant (64)Cu(2+) dissociation was observed for (64)Cu-Z-E(diamsar)-Ahx-DGEA in PBS. For microPET imaging, the PC-3 tumors were clearly visualized with both (64)Cu-DOTA-DGEA and (64)Cu-Z-E(diamsar)-Ahx-DGEA tracers. However, (64)Cu-DOTA-DGEA demonstrated 5× higher liver uptake than (64)Cu-Z-E(diamsar)-Ahx-DGEA. This biodistribution variance could be attributed to the chelating stability difference between these two tracers, which correlated well with the PBS stability experiments. In summary, the in vitro and in vivo evaluations of (64)Cu-Z-E(diamsar)-Ahx-DGEA and (64)Cu-DOTA-DGEA have demonstrated the significantly superior Cu-chelation stability for the diamsar derivative compared with the established DOTA chelator. The results also suggest that diamsar may be preferred for Cu chelation especially when multiple carboxylic acid groups are present. Free carboxyl groups may naturally compete with DOTA for (64)Cu(2+) binding and therefore reduce the complex stability.

Role of tyrosine phosphatase SHP-1 in the mechanism of endorepellin angiostatic activity.

Endorepellin, the C-terminal domain of perlecan, is a powerful angiogenesis inhibitor. To dissect the mechanism of endorepellin-mediated endothelial silencing, we used an antibody array against multiple tyrosine kinase receptors. Endorepellin caused a widespread reduction in phosphorylation of key receptors involved in angiogenesis and a concurrent increase in phosphatase activity in endothelial cells and tumor xenografts. These effects were efficiently hampered by function-blocking antibodies against integrin alpha2beta1, the functional endorepellin receptor. The Src homology-2 protein phosphatase-1 (SHP-1) coprecipitated with integrin alpha2 and was phosphorylated in a dynamic fashion after endorepellin stimulation. Genetic evidence was provided by lack of an endorepellin-evoked phosphatase response in microvascular endothelial cells derived from integrin alpha2beta1(-/-) mice and by response to endorepellin in cells genetically engineered to express the alpha2beta1 integrin, but not in cells either lacking this receptor or expressing a chimera harboring the integrin alpha2 ectodomain fused to the alpha1 intracellular domain. siRNA-mediated knockdown of integrin alpha2 caused a dose-dependent reduction of SHP-1. Finally, the levels of SHP-1 and its enzymatic activity were substantially reduced in multiple organs from alpha2beta1(-/-) mice. Our results show that SHP-1 is an essential mediator of endorepellin activity and discover a novel functional interaction between the integrin alpha2 subunit and SHP-1.

Scl1-dependent internalization of group A Streptococcus via direct interactions with the alpha2beta(1) integrin enhances pathogen survival and re-emergence.

The molecular pathogenesis of infections caused by group A Streptococcus (GAS) is not fully understood. We recently reported that a recombinant protein derived from the collagen-like surface protein, Scl1, bound to the human collagen receptor, integrin alpha(2)beta(1). Here, we investigate whether the same Scl1 variant expressed by GAS cells interacts with the integrin alpha2beta(1) and affects the biological outcome of host-pathogen interactions. We demonstrate that GAS adherence and internalization involve direct interactions between surface expressed Scl1 and the alpha2beta(1) integrin, because (i) both adherence and internalization of the scl1-inactivated mutant were significantly decreased, and were restored by in-trans complementation of Scl1 expression, (ii) GAS internalization was reduced by pre-treatment of HEp-2 cells with anti-alpha2 integrin-subunit antibody and type I collagen, (iii) recombinant alpha2-I domain bound the wild-type GAS cells and (iv) internalization of wild-type cells was significantly increased in C2C12 cells expressing the alpha2beta(1) integrin as the only collagen-binding integrin. Next, we determined that internalized GAS re-emerges from epithelial cells into the extracellular environment. Taken together, our data describe a new molecular mechanism used by GAS involving the direct interaction between Scl1 and integrins, which increases the overall capability of the pathogen to survive and re-emerge.

DNA/Lipid complex incorporated with fibronectin to cell adhesion enhances transfection efficiency in prostate cancer cells and xenografts.

Previously we have described the development and applications of lipid-based nanoparticles for gene delivery vector. In an attempt to improve transfection efficiency using the cell adhesion of extracellular matrix (ECM) to DNA/lipid complex (nanoplex), the mRNA expression of integrin alpha2beta1 and CD44 in prostate cancer cells was detected as adhesion molecules for fibronectin (Fn), collagen I (Col) and laminin (Lam) using a commercially available cDNA array (GEArray) system. These ECM proteins could enhance DNA transfection activity in cells when coated on the nanoplex. Among the ECM proteins, Fn-coating nanoplexes significantly increased transfection activity 2-fold in prostate cancer PC-3 cells, and exhibited higher DNA transfection activities to PC-3 xenografts, compared with commercially available cationic polymer in vivo jetPEI. These results indicated that Fn-coating nanoplexes could facilitate efficient transfection of prostate tumor cells.

Rapid synthesis of a register-specific heterotrimeric type I collagen helix encompassing the integrin alpha2beta1 binding site.

We report a rapid method to synthesize cystine cross-linked heterotrimeric collagenous peptides. They can be engineered to favour one particular axial alignment of the strands, called the register of the helix. Here, the sequence of the constituent peptides contains 18 residues of "guest" collagen type I sequence flanked by N and C-terminal (Gly-Pro-Pro)5 "host" modules which ensure helicity. Further C-terminal residues include appropriately spaced cysteine residues and alanine to provide the necessary flexibility for helix formation. The cross-linking reaction and subsequent separation protocols have been designed for any inserted collagen sequence that does not contain a cysteine residue. Mass spectrometry and ion-exchange chromatography allow us to distinguish between different disulphide-bonded species and to monitor the formation of side-products. Starting peptide can be recovered simply from the reaction mixture by reduction and separation. Yields are typically 30%, working on a 10 mg scale. 15N-1H NMR and platelet adhesion studies show that the peptide heterotrimers presented here can reshuffle to cover all three axial registers. Less flexible spacers between the disulphide linkages and the helix will restrict each heterotrimer to one register only.

Use of synthetic peptides to locate novel integrin alpha2beta1-binding motifs in human collagen III.

A set of 57 synthetic peptides encompassing the entire triplehelical domain of human collagen III was used to locate binding sites for the collagen-binding integrin alpha(2)beta(1). The capacity of the peptides to support Mg(2+)-dependent binding of several integrin preparations was examined. Wild-type integrins (recombinant alpha(2) I-domain, alpha(2)beta(1) purified from platelet membranes, and recombinant soluble alpha(2)beta(1) expressed as an alpha(2)-Fos/beta(1)-Jun heterodimer) bound well to only three peptides, two containing GXX'GER motifs (GROGER and GMOGER, where O is hydroxyproline) and one containing two adjacent GXX'GEN motifs (GLKGEN and GLOGEN). Two mutant alpha(2) I-domains were tested: the inactive T221A mutant, which recognized no peptides, and the constitutively active E318W mutant, which bound a larger subset of peptides. Adhesion of activated human platelets to GER-containing peptides was greater than that of resting platelets, and HT1080 cells bound well to more of the peptides compared with platelets. Binding of cells and recombinant proteins was abolished by anti-alpha(2) monoclonal antibody 6F1 and by chelation of Mg(2+). We describe two novel high affinity integrin-binding motifs in human collagen III (GROGER and GLOGEN) and a third motif (GLKGEN) that displays intermediate activity. Each motif was verified using shorter synthetic peptides.