A glycoproteomic approach to the structural characterization of acidic glycoproteins

Estrella, Ruby Poblete, Graduate School of Biomedical Engineering, Faculty of Engineering, UNSW

January 2009

Glycoproteins, and their subset proteoglycans, are an important group of molecules in joint tissues, providing crucial functions such as cartilage structural integrity and lubrication at cartilage surfaces. The functionality of these glycoproteins is attributable to their oligosaccharide components, however surprisingly little is known about their fine structural details. With the use of glycoproteomic methods, this thesis presents the development and incorporation of mass spectrometric, biochemical and immunological methods to elucidate glycoprotein structures in synovial fluids, chondrocytes and synoviocytes in order to provide insight into how their structures may contribute to their functions. Initially, anion exchange chromatography was used to extract the acidic fraction containing glycoproteins and proteoglycans in arthritic synovial fluid (SF) samples, followed by proteomic analysis to identify the main glycoproteins in 1D-SDS-PAGE gels. To complement these findings, an in-gel enzymatic digest method for glycosaminoglycan (GAG) and oligosaccharide analysis was developed for analysis of glycoproteins by graphitised carbon liquid chromatography mass spectrometry (LC-MS). Further characterization of the major glycoprotein, lubricin, was pursued by investigating its interactions with the surrounding extracellular matrix (ECM) from its cellular sources and characterising the secreted lubricin with Western blot and proteomic analysis. Finally, the graphitised carbon LC-MS method was applied to analyse the overall glycosylation profiles of lubricin. The major glycoprotein found in arthritic synovial fluid was lubricin, as identified by peptide LC-MS and Western blot. Graphitised carbon LC-MS identified the major chondroitin sulfate (CS) repeat region disaccharides and linkage region oligosaccharides of aggrecan with confirmation through tandem mass spectra and Western blots using CS linkage region stub antibodies. Application of this method to lubricin led to the discovery of O-linked oligosaccharide structures which were previously undescribed for lubricin. A higher proportion of sialylated oligosaccharide structures were detected in the rheumatoid arthritis (RA) samples compared to the osteoarthritic (OA) samples, which signifies a diagnostic difference between these diseases. Sulfated oligosaccharide structures were also detected on synovial fluid lubricin, correlated with Western blot reactivity with the MECA-79 antibody, thus suggesting a role for lubricin in inflammation. Overall the results demonstrated that glycosylation structure indicates additional functional properties for the glycoproteins such as lubricin.

Proteoglycans

Glycoproteomics

Mass spectrometry

Lubricin

A glycoproteomic approach to the structural characterization of acidic glycoproteins

Estrella, Ruby Poblete, Graduate School of Biomedical Engineering, Faculty of Engineering, UNSW

January 2009

Glycoproteins, and their subset proteoglycans, are an important group of molecules in joint tissues, providing crucial functions such as cartilage structural integrity and lubrication at cartilage surfaces. The functionality of these glycoproteins is attributable to their oligosaccharide components, however surprisingly little is known about their fine structural details. With the use of glycoproteomic methods, this thesis presents the development and incorporation of mass spectrometric, biochemical and immunological methods to elucidate glycoprotein structures in synovial fluids, chondrocytes and synoviocytes in order to provide insight into how their structures may contribute to their functions. Initially, anion exchange chromatography was used to extract the acidic fraction containing glycoproteins and proteoglycans in arthritic synovial fluid (SF) samples, followed by proteomic analysis to identify the main glycoproteins in 1D-SDS-PAGE gels. To complement these findings, an in-gel enzymatic digest method for glycosaminoglycan (GAG) and oligosaccharide analysis was developed for analysis of glycoproteins by graphitised carbon liquid chromatography mass spectrometry (LC-MS). Further characterization of the major glycoprotein, lubricin, was pursued by investigating its interactions with the surrounding extracellular matrix (ECM) from its cellular sources and characterising the secreted lubricin with Western blot and proteomic analysis. Finally, the graphitised carbon LC-MS method was applied to analyse the overall glycosylation profiles of lubricin. The major glycoprotein found in arthritic synovial fluid was lubricin, as identified by peptide LC-MS and Western blot. Graphitised carbon LC-MS identified the major chondroitin sulfate (CS) repeat region disaccharides and linkage region oligosaccharides of aggrecan with confirmation through tandem mass spectra and Western blots using CS linkage region stub antibodies. Application of this method to lubricin led to the discovery of O-linked oligosaccharide structures which were previously undescribed for lubricin. A higher proportion of sialylated oligosaccharide structures were detected in the rheumatoid arthritis (RA) samples compared to the osteoarthritic (OA) samples, which signifies a diagnostic difference between these diseases. Sulfated oligosaccharide structures were also detected on synovial fluid lubricin, correlated with Western blot reactivity with the MECA-79 antibody, thus suggesting a role for lubricin in inflammation. Overall the results demonstrated that glycosylation structure indicates additional functional properties for the glycoproteins such as lubricin.

Proteoglycans

Glycoproteomics

Mass spectrometry

Lubricin

Cartilage Lubrication and Joint Protection by the Glycoprotein PRG4 Studied on the Microscale

Coles, Jeffrey Michael

January 2010

<p>Human joints are able to withstand millions of loading cycles with loads regularly more than 3 times an individual's body weight in large part due to the unique bearing properties of articular cartilage, a strong, slippery tissue that covers the ends of long bones. PRG4 is a boundary lubricating glycoprotein present on the cartilage surface and in the synovial fluid surrounding it. While evidence that PRG4 lubricates and preserves normal joint function is strong, little is known of its effect on cartilage surface properties, the mechanism by which it lubricates, or its postulated role of preventing wear on joints. The effect of PRG4 on cartilage friction, wear, structure, morphology, and the mechanisms by which it mediates these factors are studied here. Methods to study these parameters at the microscale using atomic force microscopy are also developed. </p><p>Cartilage of mice with the Prg4 gene (which expresses PRG4) deleted is shown to be different in a number of ways from wild type cartilage. The uppermost layer is thicker and less uniform and the surface is rougher and softer. There is also a loss of proteoglycans, structural components of cartilage, from the underlying superficial tissue, and apparent tissue damage in some cases. Wear in the presence of PRG4 in shown to be significantly lower than in its absence, a finding which may have direct implications for prevention and treatment of osteoarthritis. It appears that PRG4 needs to be present in solution, not merely on the cartilage surface to have this effect, indicating that adsorption properties are important for wear prevention.</p> / Dissertation

Biomedical Engineering

Cartilage

Friction

Lubrication

Lubricin

PRG4

Wear

Feasibility of intra-articular adeno-associated virus-mediated proteoglycan-4 gene therapy to prevent osteoarthritis

Choe, Hyeong Hun

01 July 2015

Lubricin, or proteoglycan 4 (PRG4), is a secreted, glycosylated protein that binds to cartilage surfaces, which functions as a boundary lubricant. The loss of lubricin from cartilage is identified as a major pathogenic factor in post-traumatic osteoarthritis (PTOA) that has now been the aim of therapeutic intervention. Intra-articular injection of PRG4 protein provides short-term benefits that might be extended using sustained delivery methods such as in gene therapy. Here we describe the development and testing of such therapy using adeno-associated virus (AAV) as a vector for the transfer of PRG4-green fluorescent protein (GFP) fusion gene. Our recombinant PRG4 gene produces a PRG4-GFP fusion protein to facilitate tracking of its expression and distribution on joint surfaces. We hypothesized that PRG4-GFP is fully functional as a cartilage lubricant and that PRG4-GFP produced in vivo is expressed by synoviocytes and other joint cells, and cartilage surfaces remained coated for several weeks up to months after intra-articular injection of the virus. PRG4-GFP showed lubricin-like cartilage binding in vitro, and lubrication immunoblot analysis confirmed that purified PRG4-GFP from cultured media conditioned by PRG4-GFP-transduced synoviocytes was heavily glycosylated, while confocal microscopy revealed binding of the fluorescent fusion protein to cartilage surfaces. Metal-on-cartilage friction tests showed that PRG4-GFP reduced friction coefficients to a degree comparable to that of synovial fluid and had strong chondro-protective effects in explanted cartilage exposed to shear loading. The chondrocyte viability after shear loading showed that PRG4-GFP had a strong chondro-protective effect on par with that of the synovial fluid. Confocal microscopy and immunohistology confirmed that cartilage surfaces in the stifle joints of mice injected with viruses were coated with PRG4-GFP for up to 2 or 4 weeks after the treatment. The overexpression of PRG4-GFP and coating of cartilage surfaces in the stifle joints of mice injected with Adeno-Associated Virus for the transfer of PRG4-GFP fusion gene (AAV-PRG4-GFP) was confirmed by confocal microscopy and immunohistology for up to 2 or 4 weeks post-injection. The μCT imaging and immunohistology in AAV-PRG4-GFP injected rabbit knees showed stronger inhibition in degeneration of damaged tissues than in AAV-GFP injected control group. Collectively these findings indicate that AAV-PRG4-GFP transduction is a valuable new tool for evaluating the effects of long-term lubricant supplementation on PTOA in animal models.

publicabstract

Friction coefficient

Gene therapy

Green fluorescent protein

Lubricin

Osteoarthritis

PRG4

Using a Lubricin Reporter Cell to Test Current vs. Optimized Media Compositions

Kennedy, Sean M

01 January 2021

Osteoarthritis is a joint disease characterized by the breakdown of articular cartilage. The field of tissue engineering is interested in developing methods to produce biological alternatives to current orthopedic procedures. Lubricin is a molecule which is important in the proper lubrication of articular cartilage. It is a challenge in the field of tissue engineering to produce cartilage with sufficient lubricin expression. Developing a reporter cell for lubricin allowed for a more efficient investigation of the conditions wh­­­ich may influence its expression. By comparing "optimized" and traditional media solutions, it was determined that the use of a previously reported type II collagen optimized media would negatively affect the expression of lubricin. This information indicates the need to further evaluate the conditions which are conducive to producing cartilage with both sufficient types of type II collagen and lubricin.

Lubricin

PRG4

Tissue Engineering

Reporter Cell

Luciferase

Cartilage

Musculoskeletal Diseases

Synergies in Biolubrication

Raj, Akanksha

January 2017

The objective of this thesis was to advance understanding in the field of biolubrication, finding inspiration from the human synovial joints. This was addressed by investigating the association of key biolubricants and the resulting lubrication performance. Techniques employed during the course of this work were Atomic force microscopy (AFM), Quartz crystal microbalance with dissipation monitoring (QCM-D), X-ray reflectivity (XRR). Key synovial fluid and cartilage components like dipalmitoylphosphatidylcholine (DPPC), hyaluronan (HA), lubricin, and cartilage oligomeric matrix protein (COMP) have been used in the investigations. Focus was towards two lubrication couples; DPPC-hyaluronan and COMP-lubricin. DPPC-hyaluronan mixtures were probed on hydrophilic silica surfaces and COMP-lubricin association structures were explored on weakly hydrophobic poly (methyl methacrylate) (PMMA) surfaces. Investigations of the COMP-lubricin pair revealed that individually these components are unable to reach desired lubrication. However in combination, COMP facilitates firm attachment of lubricin to the PMMA surface in a favourable confirmation that imparts low friction coefficient. DPPC and hyaluronan combined impart lubrication advantage over lone DPPC bilayers. Hyaluronan provides a reservoir of DPPC on the surface and consequently self-healing ability. Other factors like temperature, presence of calcium ions, molecular weight of hyaluronan, and pressure were also explored. DPPC bilayers at higher temperature had higher load bearing capacity. Association between DPPC Langmuir layers and hyaluronan was enhanced in the presence of calcium ions, and lower molecular weight hyaluronan had a stronger tendency to bind to DPPC. At high pressures, DPPC-hyaluronan layers were more stable compared to lone DPPC bilayers. / <p>QC 20170210</p>

Biolubrication

Synergies

Adsorption

Surface Force

Friction

Load Bearing Capacity

Self Healing

Phospholipids

DPPC

Hyaluronan

COMP

Lubricin

QCM-D

AFM

XRR.

Mechanical and Tribological Study of a Stimulus Responsive Hydrogel, pNIPAAm, and a Mucinous Glycoprotein, Lubricin

Chang, Debby Pei-Shan

January 2009

<p>Friction is the resistive force that arises when two contacting surfaces move relative to each other. Frictional interactions are important from both engineering and biological perspectives. In this research I focus on the fundamental understanding of friction on polymeric and biological surfaces in aqueous environments. First, I examine the frictional properties of a stimulus-responsive hydrogel, poly-N-isopropylacrylamide (pNIPAAm), to understand how different phase states affect its tribological properties. My measurements indicate that gels in a collapsed conformation at low shear rates, exhibit significantly larger friction than swollen gels. These differences arise from changes in surface roughness, adhesive interactions, and chain entanglements of the gel surfaces associated with the phase transition. Importantly, I show that the changes in friction, triggered by an external stimulus, are reversible. </p><p>Second, I examine details of the boundary lubrication mechanism involved in mediating friction and wear in diarthrodial joints. Specifically, I looked at the constituents of the synovial fluid, lubricin and hyaluronic acid (HA) and examined their interactions on model substrates, (1) to determine the effect of surface chemistry on adsorption using surface plasmon resonance (SPR), and (2) to study normal force interactions between these surfaces using colloidal probe microscopy (CPM). I found that lubricin is highly surface-active, adsorbed strongly onto hydrophobic, hydrophilic and also collagen surfaces. Overall, lubricin develops strong repulsive interactions. This behavior is in contrast to that of HA, which does not adsorb appreciably, nor does it develop significant repulsive interactions. I speculate that in mediating interactions at the cartilage surface, an important role of lubricin is one of providing a protective coating on cartilage surfaces that maintains the contacting surfaces in a sterically repulsive state.</p> / Dissertation

Engineering, Materials Science

Engineering, Biomedical

Engineering, Mechanical

cartilage lubrication

friction force microscopy

joint lubrication

lubricin

PRG

stimulus responsive hydrogel

Análise da estrutura e padrão de expressão de lubricina, SMAD2 fosforilada na cadeia de ligação e colágeno tipo I na cartilagem articular da mandíbula durante o envelhecimento / Analysis of the structure and expression of lubricin, SMAD2 phosphorylated at linker regions and type I collagen in mandibular condylar cartilage in aging

Bautz, Willian Grassi

30 January 2018

A cartilagem articular da cabeça da mandíbula (CAM) é constituída por uma cartilagem secundária recoberta por tecido conjuntivo fibroso e, portanto, definida como fibrocartilagínea. Ela é constantemente submetida a forças de compressão e cisalhamento decorrentes da mastigação necessitando de lubrificação e capacidade de reparo. O envelhecimento é considerado um dos principais fatores para o aparecimento de alterações degenerativas nas articulações sinoviais. A lubricina é reconhecidamente um proteoglicano encontrado nas cartilagens articulares cuja função primordial é a lubrificação limítrofe. A via SMAD2, tem sido associada à capacidade de manutenção e reparo da cartilagem, e a sua fosforilação na cadeia de ligação (p-SMAD2L) foi relacionada ao aumento no tempo de fosforilação na cadeia C-terminal (p-SMAD2) e da transcrição gênica. Objetivo: Estudar as alterações morfológicas da CAM e as expressões da lubricina, p-SMAD2L e do colágeno tipo I no envelhecimento. Métodos: cortes coronais da CAM de ratos wistar com 2, 12 e 24 meses de vida foram corados pelas técnicas da hematoxilina e eosina, azul de toluidina e safranina-O. A imuno-histoquímica foi usada para detectar a localização da lubricina, p-SMAD2L e colágeno tipo I. Resultados: Notou-se modificações estruturais atribuídas ao processo natural do envelhecimento da CAM. Ainda, se verificou um aumento do colágeno tipo I nas camadas mais profundas e cartilaginificação da matriz extracelular (MEC) nas camadas superficiais. No grupo idoso, houve redução na concentração de proteoglicanos, na expressão da lubricina e na densidade e porcentagem de células p-SMAD2L. Conclusões: a CAM sofre modificações com o envelhecimento, inclusive degenerativas, e diminui sua capacidade de lubrificação e reparo em virtude da menor expressão da lubricina e p-SMAD2L. Sugere-se que a p-SMAD2L está envolvida na produção e acúmulo da lubricina na CAM / The mandibular condylar cartilage (MCC) consists of a secondary cartilage covered by fibrous connective tissue and, therefore, defined as fibrocartilage. It is constantly subjected to compression and shear forces resulting from chewing requiring lubrication and repair capability. Aging is considered one of the main factors for the appearance of degenerative changes in synovial joints. Lubricin is a proteoglycan found in articular cartilages whose primary function is boundary lubrication. SMAD2 signaling pathway has been associated with cartilage maintenance and repair, and its phosphorylation in the linker region (p-SMAD2L) was related to the increase in half-life of C-terminal phospho-SMAD2 (p-SMAD2) and gene transcription. Objective: To study the morphological alterations of MCC and the expressions of the lubricin, p-SMAD2L and type I collagen in aging. Methods: Coronal sections of the MCC from wistar rats with 2, 12 and 24 months old were stained with hematoxylin and eosin, toluidine blue and safranin-O. Immunohistochemistry were used for detection of lubricin, p-SMAD2L and type I collagen. Also, the total cell density, p-SMAD2L cells density and percentage were determined. Results: Structural modifications of the MCC related with natural aging process were observed. An increase in the expression of type I collagen in the deeper layers and \"cartilaginification\" of the extracellular matrix (ECM) in the superficial layers were detected. In the old group, it was observed a reduction in proteoglycan content, in the expression of the lubricin and in the density and percentage of positive cells for the p-SMAD2L. Conclusion: MCC undergoes structural and degenerative modifications with aging and decreases its lubrication and repair capacity due to the lower expression of the lubricin and p-SMAD2L. This study suggests that p-SMAD2L is involved in the production and accumulation of the lubricin in MCC

Aging

Articulação temporomandibular

Cartilage articular

Cartilagem articular

Colágeno tipo I

Collagen type I

Envelhecimento

Lubricin

Lubricina

Proteínas Smad

Proteoglicano 4

Proteoglycan 4

Smad protein

Temporomandibular joint

Análise da estrutura e padrão de expressão de lubricina, SMAD2 fosforilada na cadeia de ligação e colágeno tipo I na cartilagem articular da mandíbula durante o envelhecimento / Analysis of the structure and expression of lubricin, SMAD2 phosphorylated at linker regions and type I collagen in mandibular condylar cartilage in aging

Willian Grassi Bautz

30 January 2018

A cartilagem articular da cabeça da mandíbula (CAM) é constituída por uma cartilagem secundária recoberta por tecido conjuntivo fibroso e, portanto, definida como fibrocartilagínea. Ela é constantemente submetida a forças de compressão e cisalhamento decorrentes da mastigação necessitando de lubrificação e capacidade de reparo. O envelhecimento é considerado um dos principais fatores para o aparecimento de alterações degenerativas nas articulações sinoviais. A lubricina é reconhecidamente um proteoglicano encontrado nas cartilagens articulares cuja função primordial é a lubrificação limítrofe. A via SMAD2, tem sido associada à capacidade de manutenção e reparo da cartilagem, e a sua fosforilação na cadeia de ligação (p-SMAD2L) foi relacionada ao aumento no tempo de fosforilação na cadeia C-terminal (p-SMAD2) e da transcrição gênica. Objetivo: Estudar as alterações morfológicas da CAM e as expressões da lubricina, p-SMAD2L e do colágeno tipo I no envelhecimento. Métodos: cortes coronais da CAM de ratos wistar com 2, 12 e 24 meses de vida foram corados pelas técnicas da hematoxilina e eosina, azul de toluidina e safranina-O. A imuno-histoquímica foi usada para detectar a localização da lubricina, p-SMAD2L e colágeno tipo I. Resultados: Notou-se modificações estruturais atribuídas ao processo natural do envelhecimento da CAM. Ainda, se verificou um aumento do colágeno tipo I nas camadas mais profundas e cartilaginificação da matriz extracelular (MEC) nas camadas superficiais. No grupo idoso, houve redução na concentração de proteoglicanos, na expressão da lubricina e na densidade e porcentagem de células p-SMAD2L. Conclusões: a CAM sofre modificações com o envelhecimento, inclusive degenerativas, e diminui sua capacidade de lubrificação e reparo em virtude da menor expressão da lubricina e p-SMAD2L. Sugere-se que a p-SMAD2L está envolvida na produção e acúmulo da lubricina na CAM / The mandibular condylar cartilage (MCC) consists of a secondary cartilage covered by fibrous connective tissue and, therefore, defined as fibrocartilage. It is constantly subjected to compression and shear forces resulting from chewing requiring lubrication and repair capability. Aging is considered one of the main factors for the appearance of degenerative changes in synovial joints. Lubricin is a proteoglycan found in articular cartilages whose primary function is boundary lubrication. SMAD2 signaling pathway has been associated with cartilage maintenance and repair, and its phosphorylation in the linker region (p-SMAD2L) was related to the increase in half-life of C-terminal phospho-SMAD2 (p-SMAD2) and gene transcription. Objective: To study the morphological alterations of MCC and the expressions of the lubricin, p-SMAD2L and type I collagen in aging. Methods: Coronal sections of the MCC from wistar rats with 2, 12 and 24 months old were stained with hematoxylin and eosin, toluidine blue and safranin-O. Immunohistochemistry were used for detection of lubricin, p-SMAD2L and type I collagen. Also, the total cell density, p-SMAD2L cells density and percentage were determined. Results: Structural modifications of the MCC related with natural aging process were observed. An increase in the expression of type I collagen in the deeper layers and \"cartilaginification\" of the extracellular matrix (ECM) in the superficial layers were detected. In the old group, it was observed a reduction in proteoglycan content, in the expression of the lubricin and in the density and percentage of positive cells for the p-SMAD2L. Conclusion: MCC undergoes structural and degenerative modifications with aging and decreases its lubrication and repair capacity due to the lower expression of the lubricin and p-SMAD2L. This study suggests that p-SMAD2L is involved in the production and accumulation of the lubricin in MCC

Articulação temporomandibular

Cartilagem articular

Colágeno tipo I

Envelhecimento

Lubricina

Proteínas Smad

Proteoglicano 4

Aging

Cartilage articular

Collagen type I

Lubricin

Proteoglycan 4

Smad protein

Temporomandibular joint

Biolubricants and Biolubrication

Wang, Min

January 2014

The main objective of this thesis work was to gain understanding of the principles of biolubrication, focusing on synergistic effects between biolubricants. To this end surface force and friction measurements were carried out by means of Atomic Force Microscopy, using hydrophilic and hydrophobic model surfaces in salt solutions of high ionic strength (≈ 150 mM) in presence of different biolubricants. There was also a need to gain information on the adsorbed layers formed by the biolubricants. This was achieved by using a range of methods such as Atomic Force Microscopy PeakForce imaging, Quartz Crystal Microbalance with Dissipation, Dynamic Light Scattering and X-Ray Reflectometry. By combining data from these techniques, detailed information about the adsorbed layers could be obtained.The biolubricants that were chosen for investigation were a phospholipid, hyaluronan, lubricin, and cartilage oligomeric matrix protein (COMP) that all exist in the synovial joint area. First the lubrication ability of these components alone was investigated, and then focus was turned to two pairs that are known or assumed to associate in the synovial area. Of the biolubricants that were investigated, it was only the phospholipid 1,2-dipalmitoyl-sn-glycero-3-phosphocholine (DPPC) that was found to be an efficient lubricant on its own. Deposited DPPC bilayers on silica surfaces were found to be able to provide very low friction coefficients (≈ 0.01) up to high pressures, ≈ 50 MPa. A higher load bearing capacity was found for DPPC in the liquid crystalline state compared to in the gel state.The first synergy pair that was explored was DPPC and hyaluronan, that is known to associate on the cartilage surface, and we also noticed association between hyaluronan and DPPC vesicles as well as with adsorbed DPPC bilayers. By combining these two components a lubrication performance similar to that of DPPC alone could be achieved, even though the friction coefficient in presence of hyaluronan was found to be slightly higher. The synergy here is thus not in form of an increased performance, but rather that the presence of hyaluronan allows a large amount of the phospholipid lubricant to accumulate where it is needed, i.e. on the sliding surfaces.The other synergy pair was lubricin and COMP that recently has been shown to be co-localized on the cartilage surface, and thus suggested to associate with each other. Lubricin, as a single component, provided poor lubrication of PMMA surfaces, which we utilized as model hydrophobic surfaces. However, if COMP first was allowed to coat the surface, and then lubricin was added a low friction coefficient (≈ 0.03) was found. In this case the synergy arises from COMP facilitating strong anchoring of lubricin to the surface in conformations that provide good lubrication performance. / Huvudsyftet med det här avhandlingsarbetet var att öka förståelsen för den låga friktion som finns i vissa biologiska system, med fokus på synergistiska effekter mellan de smörjande molekylerna. För detta ändamål studerades ytkrafter och friktion med hjälp av atomkraftsmikroskopi. Mätningarna utfördes med hydrofila och hydrofoba modellytor i lösningar med hög salthalt (≈ 150 mM) i närvaro av smörjande biomolekyler. Det var också nödvändigt att få information om de adsorberade skikten av biomolekyler. Det åstadkoms med hjälp av en rad tekniker så som AFM PeakForce avbildning, kvartskristallmikrovåg, dynamisk ljusspridning och röntgen reflektometri. Genom att kombinera data från dessa tekniker erhölls detaljerad information om de smörjande skikten.De smörjande biomolekyler som valdes ut för studierna var en fosfolipid, hyaluronan, lubricin, and cartilage oligomeric matrix protein (COMP) vilka alla finns i synovialledsområdet. Först undersöktes den smörjande förmågan hos dessa komponenter var för sig, och sedan fokuserade vi på två par av biomolekyler som man vet eller antar bildar associationsstrukturer i synovialleder. Av de enskilda biomolekyler som undersöktes var det endast fosfolipiden 1,2-dipalmitoyl-sn-glycero-3-fosfokoline (DPPC) som visade sig vara en effektivt smörjande molekyl. Deponerade biskikt av DPPC på silikaytor gav upphov till mycket låga friktionskoefficienter (≈ 0.01) upp till höga pålagda tryck, ≈ 50 MPa. DPPC bilager i flytande kristallin fas visade sig ha högre lastbärande förmåga än DPPC bilager i geltillstånd.Det första synergistiska par som undersöktes var DPPC och hyaluronan vilka man vet associerar på broskytan, och vi visade att hyaluronan associerar med såväl DPPC vesiklar som med DPPC bilager. Genom att kombinera dessa två komponenter uppmättes en smörjande förmåga som var jämförbar med den som DPPC ensam uppvisar. Även om friktionskoefficienten var något högre i närvaro av hyaluronan. Synergieffekten här består inte av en bättre smörjande förmåga, utan istället gör närvaron av hyaluronan att de smörjande fosfolipiderna kan ansamlas i stora mängder där de behövs, dvs. på de glidande ytorna.Det andra synergiparet var lubricin och COMP vilka nyligen har visats vara lokaliserade på samma platser på broskytan, vilket tyder på att de associerar med varandra. På egen hand var lubricins smörjande förmåga av PMMA, våra hydrofoba modellytor, dålig. Emellertid, om COMP först adsorberades på PMMA och sedan lubricin tillsattes uppmättes en låg friktionskoefficient (≈ 0.03). I det här fallet består synergin av att COMP möjliggör en stark inbindning till ytan av lubricin i konformationer som ger god smörjande förmåga. / <p>QC 20141202</p> / Stiftelsen för strategisk forskning - SSF

Hyaluronan

Phospholipid

Lubricin

Cartilage Oligomeric Matrix Protein

COMP

Adsorption

Surface Force

Friction

Biolubrication

Boundary Lubrication

Load Bearing Capacity

Synergistic Effects

DLS

QCM-D

AFM.

Hyaluronan

Fosfolipid

Lubricin

Cartilage Oligomeric Matrix Protein

COMP

Adsorption

Ytkraft

Friktion

Biologisk smörjning

Gränsskiktssmörjning

Lastbärande förmåga

Synergieffekter

DLS

QCM-D

AFM.