Hydrophobic domains of human tropoelastin interact in a context-dependent manner

Tropoelastin is the soluble precursor of elastin, the major component of the extracellular elastic fiber. Tropoelastin undergoes self-association via an inverse temperature transition termed coacervation, which is a crucial step in elastogenesis. Coacervation of tropoelastin takes place through multiple intermolecular interactions of its hydrophobic domains. Previous work has implicated those hydrophobic domains located near the center of the polypeptide as playing a dominant role in coacervation. Short constructs of domains 18, 20, 24, and a mutated form of domain 26 were largely disordered at 20 degrees C but displayed increased order on heating that was consistent with the formation of beta-structures. However, their conformational transitions were not sensitive to physiological temperature in contrast to the observed behavior of the native domain 26. A polypeptide consisting of domains 17-27 of tropoelastin coacervated at temperatures above 60 degrees C, whereas individually expressed hydrophobic regions were not capable of coacervation. We conclude that coacervation depends on the hydrophobicity of the molecule and, by inference, the number of hydrophobic domains. Tropoelastin mutants were constructed to contain a Pro --> Ala mutation in domain 26, separate deletions of domains 18 and 26, and a displacement of domain 26. These constructs displayed unequal capacities for coacervation, even when they contained the same number of hydrophobic regions and comparable levels of secondary structure. Thus, the capability for coacervation is determined by contributions from individual hydrophobic domains for which function should be considered in the context of their positions in the intact tropoelastin molecule.     

Glycosaminoglycans mediate the coacervation of human tropoelastin through dominant charge interactions involving lysine side chains.

Following cellular secretion into the extracellular matrix, tropoelastin is transported, deposited, and cross-linked to make elastin. Assembly by coacervation was examined for an isoform of tropoelastin that lacks the hydrophilic domain encoded by exon 26A. It is equivalent to a naturally secreted form of tropoelastin and shows similar coacervation performance to its partner containing 26A, thereby generalizing the concept that splice form variants are able to coacervate under comparable conditions. This is optimal under physiological conditions of temperature, salt concentration, and pH. The proteins were examined for their ability to interact with extracellular matrix glycosaminoglycans. These negatively charged molecules interacted with positively charged lysine residues and promoted coacervation of tropoelastin in a temperature- and concentration-dependent manner. A testable model for elastin-glycosaminoglycan interactions is proposed, where tropoelastin deposition during elastogenesis is encouraged by local exposure to matrix glycosaminoglycans. Unmodified proteins are retained at approximately 3 microM dissociation constant. Following lysyl oxidase modification of tropoelastin lysine residues, they are released from glycosaminoglycan interactions, thereby permitting those residues to contribute to elastin cross-links.     

The hydrophobic domain 26 of human tropoelastin is unstructured in solution

Elastin is the protein responsible for the elastic properties of vertebrate tissue. Very little is currently known about the structure of elastin or of its soluble precursor tropoelastin. We have used high-resolution solution NMR methods to probe the conformational preferences of a conserved hydrophobic region in tropoelastin, domain 26 (D26). Using a combination of homonuclear, 15N-separated and triple resonance experiments, we have obtained essentially full chemical shift assignments for D26 at 278K. An analysis of secondary chemical shift changes, as well as NOE and 15N relaxation data, leads us to conclude that this domain is essentially unstructured in solution and does not interact with intact tropoelastin. D26 does not display exposed hydrophobic clusters, as expected for a fully unfolded protein and commensurate with an absence of flexible structural motifs, as identified by lack of binding of the fluorescent probe 4,4'-dianilino-1,1'-binaphthyl-5,5'-disulfonic acid. Sedimentation equilibrium data establish that this domain is strictly monomeric in solution. NMR spectra recorded at 278 and 308K indicate that no significant structural changes occur for this domain over the temperature range 278-308K, in contrast to the characteristic coacervation behavior that is observed for the full-length protein.     

Deficient coacervation of two forms of human tropoelastin associated with supravalvular aortic stenosis.

Human tropoelastin associates by coacervation and is subsequently cross-linked to make elastin. In Williams syndrome, defective elastin deposition is associated with hemizygous deletion of the tropoelastin gene in supravalvular aortic stenosis (SVAS). Remarkably, point-mutation forms of SVAS correspond to incomplete forms of tropoelastin which include in-frame termination by nonsense mutations, yet the resulting phenotype of these disorders is not explained because expression variably occurs from both normal and mutant alleles. Proteins corresponding to two truncated tropoelastin mutants were expressed and purified to homogeneity. Coacervation of these proteins occurred as expected with increasing temperature, but substantially contrasted with that of the performance of a normal tropoelastin. Significantly, association by coacervation of the truncated SVAS tropoelastin molecules was negligible at 37 degrees C, which contrasted with the substantial coacervation seen for normal tropoelastin. Furthermore their midpoints of coacervation increased and correlated with the extent of deletion, in accord with the loss of hydrophobic regions required for tropoelastin association. Their secondary structures are similar, as evidenced by CD studies. We propose a model for point-mutation SVAS in which aberrant tropoelastin molecules are incompetent and are mainly excluded from participation in coacervation and consequently in elastogenesis. These forms of SVAS may consequently be considered functionally similar to a hemizygous deletion, and mark point-mutation SVAS as a disorder of defective coacervation.     

Sequence and structure determinants for the self-aggregation of recombinant polypeptides modeled after human elastin

Elastin is a polymeric structural protein that imparts the physical properties of extensibility and elastic recoil to tissues. The mechanism of assembly of the tropoelastin monomer into the elastin polymer probably involves extrinsic protein factors but is also related to an intrinsic capacity of elastin for ordered assembly through a process of hydrophobic self-aggregation or coacervation. Using a series of simple recombinant polypeptides based on elastin sequences and mimicking the unusual alternating domain structure of native elastin, we have investigated the influence of sequence motifs and domain structures on the propensity of these polypeptides for coacervation. The number of hydrophobic domains, their context in the alternating domain structure of elastin, and the specific nature of the hydrophobic domains included in the polypeptides all had major effects on self-aggregation. Surprisingly, in polypeptides with the same number of domains, propensity for coacervation was inversely related to the mean Kyte-Doolittle hydropathy of the polypeptide. Point mutations designed to increase the conformational flexibility of hydrophobic domains had the unexpected effect of suppressing coacervation and promoting formation of amyloid-like fibers. Such simple polypeptides provide a useful model system for understanding the relationship between sequence, structure, and mechanism of assembly of polymeric elastin.     

Exon 26-coded polypeptide: An isolated hydrophobic domain of human tropoelastin able to self-assemble in vitro

Hydrophobic domains of human tropoelastin are able to aggregate in a variegated manner. Some aggregates have typical features of the whole protein while others show peculiar self-assembling profiles. Among these hydrophobic domains, an important role in the self-assembling properties of tropoelastin in vitro could be assigned to the peptide encoded by exon 26 of the human tropoelastin gene, that, although unstructured in solution, has great tendency to self-assemble in an ordered manner. The present report describes the aggregation properties of this hydrophobic domain of human tropoelastin analysed by different ultra-structural approaches. Transmission electron microscopy shows that the peptide is able to form different aggregation entities from short rods to very long and flexible fibers, depending on the temperature and on the incubation time. At a microm scale, very long fibers as well as fractal aggregation patterns were observed. Data show that the isolated domain encoded by exon 26 of the tropoelastin gene is able to aggregate in a manner very similar to the whole tropoelastin protein. The aggregation properties are due to the peculiar sequence of EX26, and not to its amino acid composition, as evidenced by the supramolecular analysis of a scrambled sequence of exon 26-coded domain of human tropoelastin, showing a quite different aggregation patterns. These findings confirm that specific sequences can play a driving role in the aggregation process of tropoelastin molecule, at least in vitro, and indicate exon 26-encoded domain among these sequences.     

Coacervation is promoted by molecular interactions between the PF2 segment of fibrillin-1 and the domain 4 region of tropoelastin

In forming elastic fibers, microfibrils act as the scaffold sites for depositing the elastin precursor tropoelastin. We examined key binding interactions that promote massive tropoelastin association through coacervation. Using a segment of the microfibril protein fibrillin-1, PF2, known to bind full-length tropoelastin, we mapped its interaction site to the N-terminal region of tropoelastin bounded by domains 2 and 18. Precise contact residues between domain 4 of tropoelastin and domain 16 of fibrillin-1 were discovered through a novel combination of transglutaminase cross-linking and mass spectroscopy, with contact sites at residues K38 of tropoelastin and Q669 of fibrillin-1. This is the first report of a role for this region of tropoelastin in microfibril interactions. The addition of PF2 thermodynamically facilitated the coacervation of tropoelastin, resulting in smaller changes in entropy and enthalpy values for the coacervating system. A novel multicomponent in vitro tropoelastin assembly reaction system demonstrated that amassed tropoelastin was spatially and preferentially directed to surfaces coated with PF2 as expected for organized three-dimensional distribution during tissue elastogenesis. This study underscores the role of this part of fibrillin-1 as an anchor point for tropoelastin at the microfibril-elastin junction during the initial stages of elastic fiber assembly.     

Glycosaminoglycan-mediated coacervation of tropoelastin abolishes the critical concentration, accelerates coacervate formation, and facilitates spherule fusion: implications for tropoelastin microassembly

Elastogenesis and elastin repair depend on the secretion of tropoelastin from the cell, yet cellular production is low in the many biological systems that have been studied. To address the apparent paradox of a paucity of tropoelastin for cell surface microassembly, we examined the effects of the glycosaminoglycans heparin, heparan sulfate, and chondroitin sulfate B, on tropoelastin aggregate formation through coacervation. We found a significant effect, particularly of heparin, on the minimum or critical concentration of tropoelastin, which was required for microassembly, lowering critical concentration to a point that it was no longer detectable. The assemblies resulted in protein droplet formation that was visually indistinguishable from the spherules that typify coacervation. The spherules readily coalesced in the presence of heparin and higher concentrations of tropoelastin, resulting in an almost continuous layer of coacervated tropoelastin. Four stages of droplet behavior were observed: early droplet formation, approximately 6 mum droplet formation, and fusion of droplets followed by the formation of a coalesced layer. We conclude that glycosaminoglycans in the extracellular matrix have the capacity to promote coacervation at low concentrations of tropoelastin.     

Characterization of the molecular interaction between tropoelastin and DANCE/fibulin-5

Fibulin-5 is believed to play an important role in the elastic fiber formation. The present experiments were carried out to characterize the molecular interaction between fibulin-5 and tropoelastin. Our data showed that the divalent cations of Ca(2+), Ba(2+) and Mg(2+) significantly enhanced the binding of fibulin-5 to tropoelastin. In addition, N-linked glycosylation of fibulin-5 does not require for the binding to tropoelastin. To address the fibulin-5 binding site on tropoelastin constructs containing, exons 2-15 and exons 16-36, of tropoelastin were used. Fibulin-5 binding was significantly reduced to either fragment and also to a mixture of the two fragments. These results suggested that the whole molecule of tropoelastin was required for the interaction with fibulin-5. In co-immunoprecipitation experiments, tropoelastin binding to fibulin-5 was enhanced by an increase of temperature and sodium chloride concentration, conditions that enhance the coacervation of tropoelastin. The binding of tropoelastin fragments to fibulin-5 was directly proportional to their propensity to coacervate. Furthermore, the addition of fibulin-5 to tropoelastin facilitated coacervation. Taken together, the present study shows that fibulin-5 enhances elastic fiber formation in part by improving the self-association properties of tropoelastin.     

Structural changes and facilitated association of tropoelastin

Circular dichroism studies of tropoelastin secondary structure show 4+/-1% alpha-helix in aqueous solutions. This is in contrast to the substantially higher amounts (up to 23+/-7%) of alpha-helix predicted by computer algorithms, which propose that regions of alpha-helix are limited to the alanine-rich cross-linking domains. Through the addition of trifluoroethanol, the amount of alpha-helix increased to 17+/-1%, equivalent to that expected on the basis of primary structure. The physiological ability of the protein to coacervate and the critical concentration of monomer required for coacervation were unaffected by levels of alpha-helix. However, the temperature required for coacervation decreased linearly with increasing alpha-helical structure, which correlates with the participation of alpha-helices in association. We propose that the alanine-rich cross-linking domains exist as nascent helices in tropoelastin in aqueous solution. We further suggest a novel mechanism for coacervation whereby formation of alpha-helices and subsequent helical side chain interactions limit the conformational flexibility of the polypeptide, to facilitate associations between hydrophobic domains during elastogenesis.     

Domains 17-27 of tropoelastin contain key regions of contact for coacervation and contain an unusual turn-containing crosslinking domain.

The central region of tropoelastin including domains 19-25 of human tropoelastin forms a hot-spot for contacts during the inter-molecular association of tropoelastin by coacervation [Wise, S.G., Mithieux, S.M., Raftery, M.J. and Weiss, A.S (2005). "Specificity in the coacervation of tropoelastin: solvent exposed lysines." Journal of Structural Biology 149: 273-81.]. We explored the physical properties of this central region using a sub-fragment bordered by domains 17-27 of human tropoelastin (SHEL 17-27) and identified the intra- and inter-molecular contacts it forms during coacervation. A homobifunctional amine reactive crosslinker (with a maximum reach of 11 A, corresponding to approximately 7 residues in an extended polypeptide chain) was used to capture these contacts and crosslinked regions were identified after protease cleavage and mass spectrometry (MS) with MS/MS verification. An intermolecular crosslink formed between the lysines at positions 353 of each strand of tropoelastin at the lowest of crosslinker concentrations and was observed in all samples tested, suggesting that this residue forms an important initial contact during coacervation. At higher crosslinker concentrations, residues K425 and K437 showed the highest levels of involvement in crosslinks. An intramolecular crosslink between these K425 and K437, separated by 11 residues, indicated that a structural bend must serve to bring these residues into close proximity. These studies were complemented by small angle X-ray scattering studies that confirmed a bend in this important subfragment of the tropoelastin molecule.     

Spectroscopic and electron micrographic studies on the repeat tetrapeptide of tropoelastin: (Val-Pro-Gly-Gly)n

The polytetrapeptide repeat of tropoelastin, Val₁-Pro₂-Gly₃-Gly₄, coacervates from aqueous solution as temperature increases. The coacervation is a cooperative process which is concentration dependent, moving the temperature profile of coacervation curves to lower temperature with high concentrations. Electron micrographs of uranyl acetate or uranyl acetate-oxalic acid negatively stained coacervated samples are characterized by filamentous structures whose center-to-center diameter is approximately 50 Å as measured with optical diffraction. Coacervation thus results in increased intermolecular order. Circular dichroism spectra in methanol and trifluoroethanol solutions are significantly different from the spectrum in water. Once coacervated, though, the polytetrapeptide gave a CD spectrum very similar to that seen in these organic solvents. The data support the point of view that coacervation is the result of hydrophobic association attending an inverse temperature transition.     

Specificity in the coacervation of tropoelastin: solvent exposed lysines

Tropoelastin protein monomers associate by coacervation and are cross-linked in vivo to form elastin macro-assemblies. We provide evidence for specific protein domain contact points between tropoelastin monomers during association by coacervation. The homobifunctional cross-linker bis(sulfosuccinimidyl) suberate served as a rapid reporter of adjacent lysines and preferentially exposed domains. Intact cross-linked peptide pairs were identified after protease digestion and high-resolution electrospray mass spectrometry followed by MS/MS sequencing. Mapping of the assigned sequences indicated that the region in the monomer spanning domains 19-25 was readily accessible to solvent and enriched in cross-linking. Domains 12 and 36 were also prevalent, where these two regions were not previously thought to play a major role in the formation of mature elastin. A specificity for particular lysines allowed for the construction of a model for the first close contacts between domains and the first detailed study of the cross-linking of tropoelastin.     

Modulated growth,stability and interactions of liquid-like coacervate assemblies of elastin

Elastin self-assembles from monomers into polymer networks that display elasticity and resilience. The first major step in assembly is a liquid–liquid phase separation known as coacervation. This process represents a continuum of stages from initial phase separation to early growth of droplets by coalescence and later “maturation” leading to fiber formation. Assembly of tropoelastin-rich globules is on pathway for fiber formation in vivo. However, little is known about these intermediates beyond their size distribution. Here we investigate the contribution of sequence and structural motifs from full-length tropoelastin and a set of elastin-like polypeptides to the maturation of coacervate assemblies, observing their growth, stability and interaction behavior, and polypeptide alignment within matured globules. We conclude that maturation is driven by surface properties, leading to stabilization of the interface between the hydrophobic interior and aqueous solvent, potentially through structural motifs, and discuss implications for droplet interactions in fiber formation.     

Cooperativity between the hydrophobic and cross-linking domains of elastin

The principal protein component of the elastic fiber found in elastic tissues is elastin, an amorphous, cross-linked biopolymer that is assembled from a high molecular weight monomer. The hydrophobic and cross-linking domains of elastin have been considered separate and independent, such that changes to one region are not thought to affect the other. However, results from these solid-state 13C NMR experiments demonstrate that cooperativity in protein folding exists between the two domain types. The sequence of the EP20-24-24 polypeptide has three hydrophobic sequences from exons 20 and 24 of the soluble monomer tropoelastin, interspersed with cross-linking domains constructed from exons 21 and 23. In the middle of each cross-linking domain is a "hinge" sequence. When this pentapeptide is replaced with alanines, as in EP20-24-24[23U], its properties are changed. In addition to the expected increase in alpha-helical content and the resulting increase in rigidity of the cross-linking domains, changes to the organization of the hydrophobic regions are also observed. Using one-dimensional CPMAS (cross-polarization with magic angle spinning) techniques, including spectral editing and relaxation measurements, evidence for a change in dynamics to both domain types is observed. Furthermore, it is likely that the methyl groups of the leucines of the hydrophobic domains are also affected by the substitution to the hinge region of the cross-linking sequences. This cooperativity between the two domain types brings new questions to the phenomenon of coacervation in elastin polypeptides and strongly suggests that functional models for the protein must include a role for the cross-linking regions.     

Study on coacervation of the repeat pentapeptide model of tropoelastin: effect of cations

The effects of various cations on coacervation of the polypentapeptide (Val-Pro-Gly-Val-Gly)n, a sequential model of tropoelastin, were studied by following the turbidity at 300 nm and the fluorescence intensity due to the interaction between the polypentapeptide and a hydrophobic probe (4-benzoylamido-4'-aminostilbene-2,2'-disulfonic acid). In the absence of cations, as the polypentapeptide concentration was increased, the turbidity curves shifted to lower temperatures and became much steeper, while the fluorescence intensity increased markedly. This suggests that a conformational change is induced by the association of the polypentapeptide molecules and indicates that coacervation occurs predominantly by intermolecular hydrophobic association. In the presence of Mg2+, the temperature profile of the coacervation curve of the polypentapeptide obtained by turbidity measurement moved to higher temperature and the fluorescence intensity decreased significantly. This suggests that Mg2+ inhibits the hydrophobic interaction of the polypentapeptide molecules on coacervation but does not induce conformational change on association of the molecules. In the presence of Ca2+, Na+, and K+, the temperature profile of the coacervation curve of the polypentapeptide was not affected appreciably, but the fluorescence intensity was decreased by these cations in the order of Na+, K+, and Ca2+. Circular dichroism spectra of the polypentapeptide in 80% trifluoroethanol in the presence of cations showed a less ordered state of the polypentapeptide. This less ordered state implies inhibition by the cations of the hydrophobic interaction between the molecules.     

Elastin cross-linking in vitro. Studies on factors influencing the formation of desmosines by lysyl oxidase action on tropoelastin.

The formation of isodesmosine and desmosine in vitro by the action of lysyl oxidase on tropoelastin was studied. The synthesis of desmosines occurred in the absence of additional substances. The formation of desmosines was not affected by removal of molecular O2 from the reaction medium nor was it affected by the lack of proline hydroxylation in tropoelastin. However, there was virtually no desmosine formation at 15 degrees C, a temperature not conducive to coacervation, indicating that coacervation is an important prerequisite for cross-linking.     

Molecular orientation of tropoelastin is determined by surface hydrophobicity

Tropoelastin is the precursor of the extracellular protein elastin and is utilized in tissue engineering and implant technology by adapting the interface presented by surface-bound tropoelastin. The preferred orientation of the surface bound protein is relevant to biointerface interactions, as the C-terminus of tropoelastin is known to be a binding target for cells. Using recombinant human tropoelastin we monitored the binding of tropoelastin on hydrophilic silica and on silica made hydrophobic by depositing a self-assembled monolayer of octadecyl trichlorosilane. The layered organization of deposited tropoelastin was probed using neutron and X-ray reflectometry under aqueous and dried conditions. In a wet environment, tropoelastin retained a solution-like structure when adsorbed on silica but adopted a brush-like structure when on hydrophobized silica. The orientation of the surface-bound tropoelastin was investigated using cell binding assays and it was found that the C-terminus of tropoelastin faced the bulk solvent when bound to the hydrophobic surface, but a mixture of orientations was adopted when tropoelastin was bound to the hydrophilic surface. Drying the tropoelastin-coated surfaces irreversibly altered these protein structures for both hydrophilic and hydrophobic surfaces.     

Effect of FKBP65, a putative elastin chaperone, on the coacervation of tropoelastin in vitro

FKBP65 is a protein of the endoplasmic reticulum that is relatively abundant in elastin-producing cells and is associated with tropoelastin in the secretory pathway. To test an earlier suggestion by Davis and co-workers that FKBP65 could act as an intracellular chaperone for elastin, we obtained recombinant FKBP65 (rFKBP65) by expressing it in E.?coli and examined its effect on the coacervation characteristics of chicken aorta tropoelastin (TE) using an in vitro turbidimetric assay. Our results reveal that rFKBP65 markedly promotes the initiation of coacervation of TE without significantly affecting the temperature of onset of coacervation. This effect shows saturation at a 1:2 molar ratio of TE to rFKBP65. By contrast, FKBP12, a peptidyl prolyl isomerase, has a negligible effect on TE coacervation. Moreover, the effect of rFKBP65 on TE coacervation is unaffected by the addition of rapamycin, an inhibitor of peptidyl prolyl isomerase (PPIase) activity. These observations rule out the involvement of the PPIase activity of rFKBP65 in modulating the coacervation of TE. Additional experiments using a polypeptide model of TE showed that rFKBP65, while promoting coacervation, may retard the maturation of this model polypeptide into larger aggregates. Based on these results, we suggest that FKBP65 may act as an elastin chaperone in vivo by controlling both the coacervation and the maturation stages of its self-assembly into fibrils.     

Contribution of domain 30 of tropoelastin to elastic fiber formation and material elasticity

Elastin is a fibrous structural protein of the extracellular matrix that provides reversible elastic recoil to vertebrate tissues such as arterial vessels, lung, and skin. The elastin monomer, tropoelastin, contains a large proportion of intrinsically disordered and flexible hydrophobic sequences that collectively are responsible for the initial phase separation of monomers during assembly, and are essential for driving elastic recoil. While structural disorder of hydrophobic sequences is controlled by a high proline and glycine residue composition, hydrophobic domain 30 of human tropoelastin is atypically proline‐poor, and forms β‐sheet amyloid‐like fibrils as an individual peptide. We explored the contribution of confined regions of secondary structure at the location of domain 30 in human tropoelastin to fiber assembly and mechanical properties using a set of mutations designed to inhibit or enhance the propensity of β‐sheet formation at this location. Our data support a dual role for confined β‐sheet secondary structure in domain 30 of tropoelastin in guiding the formation of fibers, and as a determinant of stiffness and viscoelastic properties of cross‐linked materials. Together, these results suggest a mechanism for specificity in fiber assembly, and elucidate structure‐function relationships for the rational design of elastomeric biomaterials with defined mechanical properties. © 2016 Wiley Periodicals, Inc. Biopolymers 105: 267–275, 2016.