Covalent Capture of Collagen Triple Helices Using Lysine-Aspartate and Lysine-Glutamate Pairs.

Collagen mimetic peptides (CMPs) self-assemble into a triple helix reproducing the most fundamental aspect of the collagen structural hierarchy. They are therefore important for both further understanding this complex family of proteins and use in a wide range of biomaterials and biomedical applications. CMP self-assembly is complicated by a number of factors which limit the use of CMPs including their slow rate of folding, relatively poor monomer-trimer equilibrium, and the large number of competing species possible in heterotrimeric helices. All of these problems can be solved through the formation of isopeptide bonds between lysine and either aspartate or glutamate. These amino acids serve two purposes: they first direct self-assemble, allowing for composition and register control within the triple helix, and subsequently can be covalently linked, fixing the composition and register of the assembled structure without perturbing the triple helical conformation. This self-assembly and covalent capture are demonstrated here with four different triple helices. The formation of an isopeptide bond between lysine and glutamate (K-E) is shown to be a faster and higher yielding reaction than lysine with aspartate (K-D). Additionally, K-E amide bonds increase the thermal stability, improve the refolding capabilities, and enhance the triple helical structure as compared to K-E supramolecular interactions, observed by circular dichroism. In contrast, covalent capture of triple helices with K-D amide bonds occurs slower, and the captured triple helices do not have enhanced helical structure. The crystal structure of a triple helix captured through the formation of three K-E isopeptide bonds unequivocally demonstrates the connectivity of the amide bonds formed while also confirming the preservation of the canonical triple helix. The rate of reaction and yield for covalently captured K-E triple helices along with the excellent preservation of triple helical structure demonstrate that this approach can be used to effectively capture and stabilize this important biological motif for biological and biomedical applications.

Chain alignment of collagen I deciphered using computationally designed heterotrimers.

The most abundant member of the collagen protein family, collagen I (also known as type I collagen; COL1), is composed of one unique (chain B) and two similar (chain A) polypeptides that self-assemble with one amino acid offset into a heterotrimeric triple helix. Given the offset, chain B can occupy either the leading (BAA), middle (ABA) or trailing (AAB) position of the triple helix, yielding three isomeric biomacromolecules with different protein recognition properties. Despite five decades of intensive research, there is no consensus on the position of chain B in COL1. Here, three triple-helical heterotrimers that each contain a putative von Willebrand factor (VWF) and discoidin domain receptor (DDR) recognition sequence from COL1 were designed with chain B permutated in all three positions. AAB demonstrated a strong preference for both VWF and DDR, and also induced higher levels of cellular DDR phosphorylation. Thus, we resolve this long-standing mystery and show that COL1 adopts an AAB register.

Covalent Capture of a Heterotrimeric Collagen Helix.

Stabilizing the three-dimensional structure of supramolecular materials can be accomplished through covalent capture of the assembled system. The lysine-aspartate charge pairs designed to direct the self-assembly of a collagen triple helix were subsequently used to covalently capture the helix through proximity-directed amide bond formation using EDC/HOBT activation. The triple helix thus stabilized maintains its folded structure and can now be used for applications previously inaccessible due to problematic folding equilibria.

Drug-triggered and cross-linked self-assembling nanofibrous hydrogels.

Self-assembly of multidomain peptides (MDP) can be tailored to carry payloads that modulate the extracellular environment. Controlled release of growth factors, cytokines, and small-molecule drugs allows for unique control of in vitro and in vivo responses. In this study, we demonstrate this process of ionic cross-linking of peptides using multivalent drugs to create hydrogels for sustained long-term delivery of drugs. Using phosphate, heparin, clodronate, trypan, and suramin, we demonstrate the utility of this strategy. Although all multivalent anions result in good hydrogel formation, demonstrating the generality of this approach, suramin led to the formation of the best hydrogels per unit concentration and was studied in greater detail. Suramin ionically cross-linked MDP into a fibrous meshwork as determined by scanning and transmission electron microscopy. We measured material storage and loss modulus using rheometry and showed a distinct increase in G' and G″ as a function of suramin concentration. Release of suramin from scaffolds was determined using UV spectroscopy and showed prolonged release over a 30 day period. Suramin bioavailability and function were demonstrated by attenuated M1 polarization of THP-1 cells compared to positive control. Overall, this design strategy has allowed for the development of a novel class of polymeric delivery vehicles with generally long-term release and, in the case of suramin, cross-linked hydrogels that can modulate cellular phenotype.

Comparative NMR analysis of collagen triple helix organization from N- to C-termini.

The collagen triple helix consists of three supercoiled solvent-exposed polypeptide chains, and by dry weight it is the most abundant fold in mammalian tissues. Many factors affecting the structure and stability of collagen have been determined through the use of short synthetically prepared peptides, generally called collagen-mimetic peptides (CMPs). NMR (nuclear magnetic resonance spectroscopy) investigations into the molecular structure of CMPs have suffered from large amounts of signal overlap and degeneracy because of collagen's repetitive primary sequence, the close and symmetric packing of the three chains and the identical peptide sequences found in homotrimers. In this paper a peptide library is prepared in which a single isotopic (15)N-Gly label is moved sequentially along the peptide backbone. Our approach allows for a more explicit examination of local topology than available in past reports. This reveals larger regions of disorder at the C-terminus than previously detected by crystallographic or NMR studies, and here C-terminal fraying is seen to extend for six amino acids in a (POG)10 sequence. Furthermore, small sequence changes at the N-terminus greatly influence the degree of this localized disorder and may be useful in the future design of CMPs to maximize collagen's interstrand hydrogen bonding pattern. Our approach and data serves as a reference for future CMP characterizations to determine the quality and extent of folding.

Highly angiogenic peptide nanofibers.

Major limitations of current tissue regeneration approaches using artificial scaffolds are fibrous encapsulation, lack of host cellular infiltration, unwanted immune responses, surface degradation preceding biointegration, and artificial degradation byproducts. Specifically, for scaffolds larger than 200-500 µm, implants must be accompanied by host angiogenesis in order to provide adequate nutrient/waste exchange in the newly forming tissue. In the current work, we design a peptide-based self-assembling nanofibrous hydrogel containing cell-mediated degradation and proangiogenic moieties that specifically address these challenges. This hydrogel can be easily delivered by syringe, is rapidly infiltrated by cells of hematopoietic and mesenchymal origin, and rapidly forms an extremely robust mature vascular network. Scaffolds show no signs of fibrous encapsulation and after 3 weeks are resorbed into the native tissue. These supramolecular assemblies may prove a vital paradigm for tissue regeneration and specifically for ischemic tissue disease.

Keplerate cluster (Mo-132) mediated electrostatic assembly of nanoparticles.

The electrostatic assembly between a series of differently charged Mo-132-type Keplerates present in the compounds (NH4)42[{(Mo(VI))Mo(VI)5O21(H2O)6}12 {Mo(V)2O4(CH3COO)}30].ca. {300 H2O+10 CH3COONH4} (Mo-132a), (NH4)72-n[{(H2O)81-n+(NH4)n} {(Mo(VI))Mo(VI)5O21(H2O)6}12 {Mo(V)2O4(SO4)}30].ca. 200 H2O (Mo-132b), and Na10(NH4)62[{(Mo(VI))Mo(VI)5O21(H2O)6}12 {Mo(V)2O4(HPO4)}30]. ca. {300H2O+2Na(+)+2NH4(+)+4H2PO4(-)} (Mo-132c) with cationic gold nanoparticles (AuNPs) was investigated for the first time. The rapid electrostatic assembly from nanoscopic entities to micron scale aggregates was observed upon precipitation, which closely matched the point of aggregate electroneutrality. Successful assembly was demonstrated using UV-vis, DLS, TEM, and zeta-potential analysis. Results indicate that the point at which precipitation occurs is related to charge balance or electroneutrality, and that counterions at both the Mo-132 and AuNP play a significant role in assembly.

Rational design of a non-canonical "sticky-ended" collagen triple helix.

In a canonical collagen triple helix, three peptides self-assemble into a supercoiled motif with a one-amino-acid offset between the peptide chains. Design of triple helices that contain more than one residue offset is lucrative, as it leaves the non-covalent interactions unsatisfied at the termini and renders the termini "sticky" to further self-assemble into collagen-like nanofibers. Here we use lysine-glutamate axial salt-bridges to design a heterotrimeric collagen triple helix, ABC-1, containing a non-canonical offset of four residues between the peptide chains. The four-residue offset is necessary to prevent aggregation, which would prevent characterization of the non-canonical chain arrangement at the molecular level by NMR spectroscopy. A second heterotrimer, ABC-2, also stabilized by axial salt-bridges, is designed containing a canonical one-amino-acid offset to facilitate comparison of structure and stability by CD and NMR. ABC-1 and ABC-2 demonstrate our ability to modulate chain offset in a collagen triple helix. This lays the groundwork to design longer, and therefore stickier, offsets allowing access to a new class of collagen-related nanostructures.

A nanostructured synthetic collagen mimic for hemostasis.

Collagen is a major component of the extracellular matrix and plays a wide variety of important roles in blood clotting, healing, and tissue remodeling. Natural, animal derived, collagen is used in many clinical applications but concerns exist with respect to its role in inflammation, batch-to-batch variability, and possible disease transfection. Therefore, development of synthetic nanomaterials that can mimic the nanostructure and properties of natural collagen has been a heavily pursued goal in biomaterials. Previously, we reported on the design and multihierarchial self-assembly of a 36 amino acid collagen mimetic peptide (KOD) that forms nanofibrous triple helices that entangle to form a hydrogel. In this report, we utilize this nanofiber forming collagen mimetic peptide as a synthetic biomimetic matrix useful in thrombosis. We demonstrate that nanofibrous KOD synthetic collagen matrices adhere platelets, activate them (indicated by soluble P-selectin secretion), and clot plasma and blood similar to animal derived collagen and control surfaces. In addition to the thrombotic potential, THP-1 monocytes incubated with our KOD collagen mimetic showed minimal proinflammatory cytokine (TNF-α or IL-1ß) production. Together, the data presented demonstrates the potential of a novel synthetic collagen mimetic as a hemostat.

Pairwise interactions in collagen and the design of heterotrimeric helices.

A comprehensive survey of single amino acid substitutions in the canonical Xaa-Yaa-Gly repeat has laid the ground work for our understanding of the collagen triple helix. Building upon this foundation requires understanding pairwise amino acid interactions which will allow us to prepare heterotrimeric helices with great specificity in addition to an overall improved control over helix structure and stability. Furthermore, detailed studies on these interactions will help us understand collagen's n structure, assembly mechanism and stability. The most important pairwise interaction so far identified in the collagen triple helix is the axial charge pair that can be formed between properly placed Lysine and either Aspartate or Glutamate residues. This review will summarize our understanding of this interaction and other charged pair interactions and how they have been successfully used to control collagen triple helix self-assembly.

Hydroxyproline-free single composition ABC collagen heterotrimer.

Hydroxyproline plays a major role in stabilizing collagenous domains in eukaryotic organisms. Lack of this modification is associated with significant lowering in the thermal stability of the collagen triple helix and may also affect fibrillogenesis and folding of the peptide chains. In contrast, even though bacterial collagens lack hydroxyproline, their thermal stability is comparable to that of fibrillar collagen. This has been attributed to the high frequency of charged amino acids found in bacterial collagen. Here we report a thermally stable hydroxyproline-free ABC heterotrimeric collagen mimetic system composed of decapositive and decanegative peptides and a zwitterionic peptide. None of the peptides contain hydroxyproline, and furthermore the zwitterionic peptide does not even contain proline. The heterotrimer is electrostatically stabilized via multiple interpeptide lysine-aspartate and lysine-glutamate salt bridges and maintains good thermal stability with a melting temperature of 37 °C. The ternary peptide mixture also populates a single composition ABC heterotrimer as confirmed by circular dichroism (CD) and nuclear magnetic resonance (NMR) spectroscopy. This system illustrates the power of axial salt bridges to direct and stabilize the self-assembly of a triple helix and may be useful in analogous designs in expression systems where the incorporation of hydroxyproline is challenging.

Simultaneous control of composition and register of an AAB-type collagen heterotrimer.

Control over composition and register of the peptide chains in AAB-type collagen mimetic heterotrimers is critical in developing systems that show fidelity to native collagen. However, their design is challenging due to the eight competing states possible for a mixture of nonidentical peptides A and B. Interpeptide salt-bridges have been used previously as keystone interactions to bias the population of competing states to favor a target heterotrimer. The designed heterotrimers were electroneutral and relied on pairing of acidic and basic residues but could not differentiate between all of the competing states and reported systems populated either multiple heterotrimer compositions or registers. Here our design methodology includes both positive and negative elements. First, an excess of acidic or basic residues, which always remain unpaired, introduces a negative design component to destabilize the competing triple helical compositions and registers. Second, charge pairs introduce a positive design component and stabilize the target assembly. These antagonistic factors are optimized in the target heterotrimer that forms the maximum number of charge pairs and minimizes unpaired charged residues. Additionally, we find that not just the number of paired and unpaired residues are important, but also the type. By a systematic study of different types of charge pairs and unpaired residues, we are able to populate a single composition-single register AAB heterotrimer. The insights gained here may be useful in designing composition and register specific heterotrimeric ligands with domains that recognize collagen-binding proteins.

Rational design of single-composition ABC collagen heterotrimers.

Design of heterotrimeric ABC collagen triple helices is challenging due to the large number of competing species that may be formed. Given the required one amino acid stagger between adjacent peptide strands in this fold, a ternary mixture of peptides can form as many as 27 triple helices with unique composition or register. Previously we have demonstrated that electrostatic interactions can be used to bias the helix population toward a desired target. However, homotrimeric assemblies have always remained the most thermally stable species in solution and therefore comprised a significant component of the peptide mixture. In this work we incorporate complementary modifications to this triple-helical design strategy to destabilize an undesirable competing state while compensating for this destabilization in the desired ABC composition. The result of these modifications is a new ABC triple-helical system with high thermal stability and control over composition, as observed by NMR. An additional set of modifications, which exchanges aspartate for glutamate, results in an overall lowering of stability of the ABC triple helix yet shows further improvement in the system's specificity. This rationally designed system helps to elucidate the rules governing the self-assembly of synthetic collagen triple helices and sheds light on the biological mechanisms of collagen assembly.