1.2.1    Synthetic Peptides Derived from Fibronectin, Laminin, and Collagen

The fibronectin-derived RGD peptide sequence is among the most studied peptide sequences for cell adhesion, and has been reviewed extensively [17,24,25]. Fibronectin is a ubiquitous protein that binds to different integrin receptors and promotes cell adhesion and cell survival. Immobilizing this sequence to biomaterials using bond-forming chemistries such as 1-ethyl-3-dimethylaminopropylcarbodiimide and N-hydroxysuccinimide (EDC/NHS) is problematic because the carboxylate-containing aspartic acid (D) participates in a competing reaction with the C-terminal carboxylate, thereby complicating the orientation of the sequence immobilized [26]. Bio-orthogonal conjugation chemistries have been used to overcome this problem and have resulted in effective adhesion for a variety of cell types to different types of modified biomaterials (Table 1.1) [17,27,28].

Derivatives of the linear RGD sequence have been synthesized in efforts to increase its binding to integrin receptors. Studies show that the RGD sequence in native fibronectin resides at the tip of a loop, which provides it with structural rigidity and a favorable conformation for integrin binding [29,30]. These structural characteristics have inspired the synthesis of cyclic RGD sequences [31,32]. Synthetic cyclic RGD peptides provide comparable conformational characteristics to facilitate integrin binding, and their conjugation to biomaterials have shown greater bioactivity compared with linear RGD sequences [33,34]. For example, cyclic RGD was recently conjugated to poly(4-methylpent-1-ene) (TPX) membranes for use as artificial lung supports. Endothelial cells cultured on this material showed significant cell adhesion, which is important for hemostasis use in these devices [35].

Another consideration for improved integrin interaction with immobilized RGD peptides is the distance between the peptide and the polymer backbone. A peptide that is bound too close to the polymer backbone may be hindered by steric interactions to efficiently bind with the receptors. Wilson et al. recently reported RGD peptides with a PEG linker containing greater than 27 ethylene oxide, repeat units showed significant adhesion of telomerase-immortalized human corneal epithelial cells (hTCEpi) [36].

Another ECM protein that has been extensively studied is laminin. Similar to fibronectin, laminin plays important roles in the ECM such as facilitating cell adhesion, differentiation, and migration. The most widely studied synthetic peptides for laminin are YIGSR [37] and IKVAV [38]. YIGSR has been shown to promote cell adhesion to the laminin-binding receptors, while IKVAV has been shown to promote primarily adhesion and neurite outgrowth of dorsal root ganglia (DRGs) [39], as well as differentiation of neural progenitor cells (NPCs) [40].

Collagens are another important class of proteins found in the ECM. Collagens provide structural support and also interact with receptors to mediate cell adhesion, migration, and proliferation [41,42]. The general structure of collagen consists of a triple helix, formed by three polypeptide strands, which can further assemble to supramolecular structures such as planar sheet-like networks, fibrils, and fibers [42]. There are 28 isoforms of collagen, with types I and IV being the most predominant in the ECM. Early collagen-mimetic synthetic sequences included the repeating tripeptide unit (Gly-X-Y), where X and Y were pre-dominantly conformationally rigid prolines to facilitate the formation of a triple helix. Subsequent work by Farndale and coworkers showed that the synthetic sequence (GFOGER, where O is hydroxyproline) derived from collagen I has high affinity for the α₂β₁ integrin. Garcia et al. have also synthesized a peptide with the GFOGER hexapeptide flanked with the triple helical sequence (GPP)₅ to promote the formation of the triple helix [43]. On conjugating to various surfaces, HT1080 cells showed dose-dependent cell adhesion, and MC3T3-E1 cells showed vinculin staining, which suggests focal adhesion through integrin binding. Conjugation of a similar peptide to PEG resulted in increased chondrogenic differentiation of human mesenchymal stem cells compared with cells cultured in controls of PEG alone [44].

1.2.2    Carbohydrate-Binding Peptides

Carbohydrates play a significant role in cell recognition and binding. The chemical structures of carbohydrate complexes (glycans) are diverse and complex. They consist of numerous monosaccharide units (up to 200 total units) covalently bonded to each other linearly or as branched structures, with each structure providing a unique binding affinity to other molecules [45]. GAGs are a class of linear anionic polysaccharides that can be posttranslationally conjugated to proteins in the Golgi complex to form glycoproteins. Glycoproteins that are transported to the cell membrane function as transmembrane proteins, whereby the glycan is exposed to the extracellular space and participates in cellular recognition and protein binding [46].

Heparin is a GAG that is commonly found either in the ECM or conjugated to a transmembrane protein (proteoglycan). Heparin binds with high affinity to a variety of proteins such as antithrombin III (AT III) [47], bFGF [48], VEGF [49], and BMP-2 [50], and presents the proteins for enhanced bioactivity [51]. Thus, the conjugation of heparin to biomaterials is useful for applications that require interactions with heparin-binding proteins (HBPs). Sakiyama-Elbert and Hubbell reported that covalent conjugation of the AT III-derived sequence K(βA)FAKLAARLYRKA to fibrin matrices strongly bound to heparin [52]. A short peptide sequence (NQEQVSP) was also incorporated into the N-terminus to enable enzymatic peptide ligation to the fibrin hydrogel by transglutaminase factor XIIIa [53].

Another important role of transmembrane GAGs is to recognize chemical signals from the surrounding environment. Keissling et al. have discovered that the vitronectin-derived peptide sequence CGKKQRFRHRNRKG binds to GAGs expressed on the cell surface of human embryonic stem cells (hESCs), and can maintain their expression of pluripotent markers after 3 months [54]. Moreover, hESCs cultured on polyacrylamide hydrogels conjugated with this sequence both proliferated and maintained greater pluripotency than cells cultured on gels containing the integrin-binding sequence CRGDS [55].

1.2.3    Glycomimetic Peptides

As described earlier, carbohydrates play a significant role in cell recognition and binding. Efforts to study the interaction between glycans and cells using chemical analogs have been limited by the inability to readily and efficiently chemically synthesize complex polysaccharides, which are challenging synthetic targets due to the multiple glycosylation steps, and the need to preserve the numerous carbohydrate stereocenters. While antibodies can be used to bind to carbohydrate receptors, their size and stability have limited large-scale use.

Interestingly, synthetic peptides have been discovered that mimic the chemical structures of several complex polysaccharides. These peptides occupy a similar chemical space as the parent polysaccharides, and therefore can bind to similar polysaccharide receptors. For example, a peptide sequence (FLHTRLFV) that mimics glycans found on the cell surface of human natural killer cells (HNKCs) was discovered using phage display and antibody-binding assays [56]. Motor neurons cultured in the presence of the HNKC glycomimetic peptide showed significantly longer neurite outgrowth compared with those cultured in the absence of HNKC-peptides [56]. Masand et al. recently conjugated this peptide to collagen hydrogels using EDC chemistry, and as demonstrated, these hydrogels also increased neurite outgrowth and length of motor neurons compared with cells cultured on collagen alone.

Another important glycan group is polysialic acid (PSA), which is naturally found conjugated to a variety of different transmembrane proteins including neural cell adhesion molecules (NCAMs). The PSA is hypothesized to be involved in cell migration of neural cells and cancer cells. Novel PSA-mimetic peptides have been discovered, and delivery of these PSA-mimetic peptides into the brain and spinal cord showed improved functional recovery and tissue regeneration in various injury models [57–59]. Masand et al. have also conjugated this PSA-mimetic peptide to collagen hydrogels, and demonstrated an increase in neurite length of cultured dorsal root ganglion and motor neurons, and increased Schwann cell proliferation compared with cells cultured on collagen alone [60]. However, a mixture of both PSA and HNKC peptides to collagen hydrogels yielded neither an additive effect for neurite outgrowth nor proliferation, emphasizing the importance of understanding the underlying mechanism for synergistic effects.

1.2.4    Growth Factors

Recently, larger molecules such as proteins and growth factors have been conjugated to biomaterials in a site-specific manner. Previous methods used nonspecific conjugation of large proteins to hydrogel scaffolds through amide linkage chemistry, such as EDC coupling. This approach is problematic due to the presence of multiple amines and carboxylates found in many proteins; random amide bond formation may decrease or even block protein activity. The limitation of nonspecific amidation has been overcome by exploiting site-specific modification, including protein modification to include click moieties discussed earlier [61], or by noncovalently incorporating proteins through high-affinity binding with complementary peptides/proteins immobilized to the hydrogel [62,63].

Various genetic modifications have enabled the site-specific incorporation of sequences and functional groups that can interact with bio-orthogonal partners. Protein biotinylation is a widely studied posttranslational modification and can be selectively incorporated into a protein that has been modified with the biotin-ligase recognition sequence (GLNDIFEAQKIEWHE) [64]. Biotin ligase selectively and covalently binds a biotin moiety to the primary amine of the lysine (K) residue in this sequence. The biotinylated protein is subsequently immobilized to streptavidin-containing biomaterials through high-affinity binding (K_D∼ 10⁻¹⁵ M). Tam et al. recently reported a thiolated derivative of methylcellulose conjugated to maleimide–streptavidin, followed by immobilization of biotin-containing platelet-derived growth factor (PDGF) [65]. This material was shown to increase the differentiation of rat neural stem/progenitor cells into oligodendrocytes in vitro, and also promote functional and tissue repair in rat models of spinal cord injury [66].

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