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Solution Structure and Dynamics of Cartilage Aggrecan

Profile image of Aristeidis PapagiannopoulosAristeidis Papagiannopoulos

2006, Biomacromolecules

https://doi.org/10.1021/BM060287D
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11 pages

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Abstract

We studied the structure and dynamics of porcine laryngeal aggrecan in solution using a range of noninvasive techniques: dynamic light scattering (DLS), small-angle neutron scattering (SANS), video particle tracking (VPT) microrheology, and diffusing wave spectroscopy (DWS). The data are analyzed within the framework of a combined static and dynamic scaling model, and evidence is found for reptation of the comb backbones with unentangled side-chain dynamics. Small-angle neutron scattering indicated standard polyelectrolyte scaling of the mesh size ( ) with concentration (c) in semidilute solutions for the whole aggrecan aggregate, ) Ac -0.47(0.04 , with the prefactor (A) implying there is on average 60 nm between the aggrecan subunits along the backbone. VPT demonstrated large exponents for the power law dependence of the intrinsic viscosity (η) on the polymer concentration in the semidilute concentration regime, η ∼ c R ; with R equal to 2.04 ( 0.06 and 1.95 ( 0.08 for the assembled and disassembled aggrecan aggregates, respectively. DWS at high frequencies (10 4 -10 5 Hz) gave evidence for internal Rouse modes of the aggrecan monomers, independent of the degree of self-assembly of the molecules. Figure 1. Schematic diagram of the process of self-assembly of aggrecan aggregate from monomer and hyaluronic acid.

Key takeaways
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  1. Aggrecan exhibits reptation dynamics with unentangled side-chain behavior across concentrations of 0.2-50 mg/mL.
  2. The correlation length scales as ∼c^(-0.47), consistent with linear flexible polyelectrolytes in semidilute solutions.
  3. Intrinsic viscosity shows a strong dependence on polymer concentration: η ∼ c^(2.04) for aggregates and η ∼ c^(1.95) for monomers.
  4. The study employs DLS, SANS, VPT microrheology, and DWS to analyze aggrecan's structure and dynamics noninvasively.
  5. Aggrecan's viscoelasticity is crucial for understanding its role in cartilage and potential treatments for osteoarthritis.

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    Peter Basser

    The Journal of Chemical Physics, 2009

    Hyaluronic acid ͑HA͒ is an anionic biopolymer that is almost ubiquitous in biological tissues. An attempt is made to determine the dominant features that account for both its abundance and its multifunctional role, and which set it apart from other types of biopolymers. A combination of osmotic and scattering techniques is employed to quantify its dynamic and static properties in near-physiological solution conditions, where it is exposed both to mono-and divalent counterions. An equation of state is derived for the osmotic pressure ⌸ in the semidilute concentration region, in terms of two variables, the polymer concentration c and the ionic strength J of the added salt, according to which ⌸ = 1.4ϫ 10 3 c 9/4 / J 3/4 kPa, where c and J are expressed in mole. Over the physiological ion concentration range, the effect of the sodium chloride and calcium chloride on the osmotic properties of HA solutions is fully accounted for by their contributions to the ionic strength. The absence of precipitation, even at high CaCl 2 concentrations, distinguishes this molecule from other biopolymers such as DNA. Dynamic light scattering measurements reveal that the collective diffusion coefficient in HA solutions exceeds that in aqueous solutions of typical neutral polymers by a factor of approximately 5. This property ensures rapid adjustment to, and recovery from, stress applied to HA-containing tissue. Small angle x-ray scattering measurements confirm the absence of appreciable structural reorganization over the observed length scale range 10-1000 Å, as a result of calcium-sodium ion exchange. The scattered intensity in the transfer momentum range q Ͼ 0.03 Å −1 varies as 1 / q, indicating that the HA chain segments in semidilute solutions are linear over an extended concentration range. The osmotic compression modulus c ‫ץ‬ ⌸ / ‫ץ‬c, a high value of which is a prerequisite in structural biopolymers, is several times greater than in typical neutral polymer solutions.

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    Glycosaminoglycan and Proteoglycan Biotherapeutics in Articular Cartilage Protection and Repair Strategies: Novel Approaches to Visco-supplementation in Orthobiologics
    James Melrose

    Advanced Therapeutics

    The aim of this study is to review developments in glycosaminoglycan and proteoglycan research relevant to cartilage repair biology and in particular the treatment of osteoarthritis (OA). Glycosaminoglycans decorate a diverse range of extracellular matrix and cell associated proteoglycans conveying structural organization and physico-chemical properties to tissues. They play key roles mediating cellular interactions with bioactive growth factors, cytokines, and morphogenetic proteins, and structural fibrillar collagens, cell interactive and extracellular matrix proteoglycans, and glycoproteins which define tissue function. Proteoglycan degradation detrimentally affects tissue functional properties. Therapeutic strategies have been developed to counter these degenerative changes. Neo-proteoglycans prepared from chondroitin sulfate or hyaluronan and hyaluronan or collagen-binding peptides emulate the interactive, water imbibing, weight bearing, and surface lubricative properties of native proteoglycans. Many neo-proteoglycans outperform native proteoglycans in terms of water imbibition, matrix stabilization, and resistance to proteolytic degradation. The biospecificity of recombinant proteoglycans however, provides precise attachment to native target molecules. Visco-supplements augmented with growth factors/therapeutic cells, hyaluronan, and lubricin (orthobiologicals) have the capacity to lubricate and protect cartilage, control inflammation, and promote cartilage repair and regeneration of early cartilage lesions and may represent a more effective therapeutic approach to the treatment of mild to moderate OA and deserve further study.

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    Rheological Properties of Cartilage Glycosaminoglycans and Proteoglycans
    Ferenc Horkay

    Macromolecules, 2021

    Glycosaminoglycans (GAGs) are molecules that govern the load-bearing and frictional properties of cartilage and the lubricating properties of synovial fluid of joints. Most GAGs in the body form proteoglycans (PGs), and the dominant PG in cartilage is the bottlebrush-shaped aggrecan, comprised of a protein core decorated by GAG side chains consisting mainly of chondroitin sulfate (CS) and keratan sulfate. Additionally, hyaluronic acid (HA) induces aggrecan to self-assemble into complexes having up to 100 aggrecan molecules attached to each HA chain "backbone". Here, we report the rheological properties of CS, HA, aggrecan, and aggrecan−HA complexes in water and salt solutions. We find that CS solutions are viscous liquids, while HA solutions exhibit viscoelasticity and shear thinning. Specifically, in the case of HA, the storage modulus G′ exceeds the loss modulus G″ at high frequencies (ω) while the reverse is true at low ω. Thus, the rheologies of CS and HA exhibit somewhat distinct viscoelastic properties. Aggrecan, on the other hand, shows a rheology consistent with an incipient "weak gel" in which G′ and G″ cross at a specific ω and follow a power-law scaling over a wide ω range. Moreover, aggrecan samples do not attain an observable plateau in the viscosity under steady shear and low shear rates. Finally, the complexation of aggrecan and HA over a period of 48 h results in a slow evolution ("aging") in measured rheological properties, with G′ at low ω progressively increases in time, while G″ remains essentially unchanged. This suggests that aggrecan and HA gradually form a macroscopic network in which molecular complexes act as physical cross-links.

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