Tropoelastin bridge region positions the cell-interactive C terminus and contributes to elastic fiber assembly

Abstract: The tropoelastin monomer undergoes stages of association by coacervation, deposition onto microfibrils, and cross-linking to form elastic fibers. Tropoelastin consists of an elastic N-terminal coil region and a cell-interactive C-terminal foot region linked together by a highly exposed bridge region. The bridge region is conveniently positioned to modulate elastic fiber assembly through association by coacervation and its proximity to dominant cross-linking domains. Tropoelastin constructs that either modify o… Show more

“…[30] [31] Over the past few years, we and others have found that, in vitro, these molecules are not needed for the spatial and temporal elastin assembly of tropoelastin. [9,15,20,26,32,33] This may be due to the fact that elastin is over nine times more abundant than microfibrillar components, and therefore tropoelastin-tropoelastin interactions dominate. [34] The observed tropoelastin and aggregate structures are similar to those found in natural tissues, as evidenced by electron microscopy, which supports the concept of an aggregation unit corresponding to tropoelastin assemblies.…”

“…[37] By exploring the functional roles of domains by systematically introducing mutations at selected sites across tropoelastin, in concert with SAXS and allied methods including SANS, NMR, and molecular dynamics on these constructs, we have solved the solution structures for the normal and a panel of mutant forms of tropoelastin. [9,10,20,26] In each of the mutant cases, there is altered assembly. This has facilitated mapping of these effects onto specific parts of the molecule, together with comparison of the assembly performance of wild-type and mutant forms in vitro and in concert with elastogenic cells.…”

“…We discovered that tropoelastin has a defined monomer shape in solution that is needed for assembly, [9,10,13] but also displays a large percentage of flexible, disordered regions needed for molecular elasticity. [14,15] The tertiary structure of human tropoelastin represents an ensemble of elastic conformers, [10,16] yet occasional conserved sequence elements hint at requirements for functional demands in one or more key parts of this molecule. [17][18][19] Tropoelastin is a 20-nm-long asymmetric protein monomer with a slightly curved nanospring shaft that extends from its N-terminus to a bifurcating hinged foot region towards the C-terminus.…”

“…This model of tropoelastin dynamics describes a characteristic scissors-like motion between the hinge and foot regions, as well as a twisting motion in the N-terminal coil region, in which the N-terminus experiences highest displacement. [9,10,13,20] The geometric distribution of the tropoelastin molecular volume intrinsically prompts a cohesive motion pattern between the upper and lower regions of the molecule, giving rise to local regions of conformational flexibility thought to be responsible for elastic deformation, while maintaining a defined tertiary shape with distinct functional segments for protein and cellular interactions. Despite the intrinsic flexibility of tropoelastin as a supposedly disordered elastomeric protein, [21] local changes to its native shape, manifested by a perturbed hinge region in human tropoelastin, can have a substantial impact on function, including its assembly into larger-scale structures.…”

“…[7] Although other proteins are present, elastic tissue is predominantly made of one protein, tropoelastin, [8] which dominates molecular contributions to the architecture and function of elastin. [9,10] For this reason, the present review considers the perspective of tropoelastin.…”

Perspectives on the Molecular and Biological Implications of Tropoelastin in Human Tissue Elasticity

“…[30] [31] Over the past few years, we and others have found that, in vitro, these molecules are not needed for the spatial and temporal elastin assembly of tropoelastin. [9,15,20,26,32,33] This may be due to the fact that elastin is over nine times more abundant than microfibrillar components, and therefore tropoelastin-tropoelastin interactions dominate. [34] The observed tropoelastin and aggregate structures are similar to those found in natural tissues, as evidenced by electron microscopy, which supports the concept of an aggregation unit corresponding to tropoelastin assemblies.…”

“…[37] By exploring the functional roles of domains by systematically introducing mutations at selected sites across tropoelastin, in concert with SAXS and allied methods including SANS, NMR, and molecular dynamics on these constructs, we have solved the solution structures for the normal and a panel of mutant forms of tropoelastin. [9,10,20,26] In each of the mutant cases, there is altered assembly. This has facilitated mapping of these effects onto specific parts of the molecule, together with comparison of the assembly performance of wild-type and mutant forms in vitro and in concert with elastogenic cells.…”

“…We discovered that tropoelastin has a defined monomer shape in solution that is needed for assembly, [9,10,13] but also displays a large percentage of flexible, disordered regions needed for molecular elasticity. [14,15] The tertiary structure of human tropoelastin represents an ensemble of elastic conformers, [10,16] yet occasional conserved sequence elements hint at requirements for functional demands in one or more key parts of this molecule. [17][18][19] Tropoelastin is a 20-nm-long asymmetric protein monomer with a slightly curved nanospring shaft that extends from its N-terminus to a bifurcating hinged foot region towards the C-terminus.…”

“…This model of tropoelastin dynamics describes a characteristic scissors-like motion between the hinge and foot regions, as well as a twisting motion in the N-terminal coil region, in which the N-terminus experiences highest displacement. [9,10,13,20] The geometric distribution of the tropoelastin molecular volume intrinsically prompts a cohesive motion pattern between the upper and lower regions of the molecule, giving rise to local regions of conformational flexibility thought to be responsible for elastic deformation, while maintaining a defined tertiary shape with distinct functional segments for protein and cellular interactions. Despite the intrinsic flexibility of tropoelastin as a supposedly disordered elastomeric protein, [21] local changes to its native shape, manifested by a perturbed hinge region in human tropoelastin, can have a substantial impact on function, including its assembly into larger-scale structures.…”

“…[7] Although other proteins are present, elastic tissue is predominantly made of one protein, tropoelastin, [8] which dominates molecular contributions to the architecture and function of elastin. [9,10] For this reason, the present review considers the perspective of tropoelastin.…”

Perspectives on the Molecular and Biological Implications of Tropoelastin in Human Tissue Elasticity

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