Dissertations / Theses on the topic 'Fibronectin Aggregation in Collagen'

Cell adhesion to the extracellular matrix through cell-surface integrin receptors is essential to development, wound healing, and tissue remodeling and therefore represents a central theme in the design of bioactive surfaces that successfully interface with the body. This is especially significant in the areas of integrative implant coatings since adhesion triggers signals that regulate cell cycle progression and differentiation in multiple cellular systems. The interactions of osteoblasts with their surrounding extracellular matrix are essential for skeletal development and homeostasis and the maintenance of the mature osteoblastic phenotype. Our objective was to engineer integrin-specific bioactive surfaces that support osteoblastic differentiation and promote osseointegration by mimicking these interactions. We target two specific integrins essential to osteoblast differentiation the type I collagen receptor alpha2beta1 and the fibronectin receptor alpha5beta1. The central hypothesis of this project was that the controlled presentation of type I collagen and fibronectin binding domains onto well-defined substrates would result in integrin-specific bioadhesive surfaces that support osteoblastic differentiation, matrix mineralization, and osseointegration. We have demonstrated that these biomimetic peptides enhance bone formation and mechanical osseointegration on titanium implants in a rat tibia cortical bone model. We have also shown that the presentation of multiple integrin-binding ligands synergize to enhance intracellular signaling and proliferation. Finally, we demonstrate the advantage of the short biomimetic peptides over the native ECM proteins. This research is significant because it addresses current orthopaedic implant limitations by specifically targeting cellular responses that are critical to osteoblastic differentiation and bone formation. This biomolecular approach provides a versatile and robust strategy for developing bioactive surfaces that enhance bone repair and osseointegration of orthopaedic implants.

Fibronectin is an extracellular multidomain glycoprotein that directs and regulates a variety of cell processes such as proliferation, development, haemostasis, embryogenesis, and wound healing. As a major component of blood, fibronectin exists as a soluble disulphide linked dimer, but it can also be incorporated into an insoluble cross-linked fibrillar network to form a major component of the extracellular matrix. Fibronectin is composed of an extended chain of module repeats termed Fn1, Fn2, and Fn3 that bind to a wide range of transmembrane receptors and extracellular matrix components, including collagen. The gelatin binding domain of fibronectin was first isolated as a 45kDa proteolytic fragment and has since been found to be composed of six modules: 6Fn1-1Fn2-2Fn2-7Fn1-8Fn1-9Fn1 (in this notation nFX represents the nth type X module in the native protein). This domain has been reported to bind to both collagen and denatured collagen (gelatin), but with 10-100 times higher affinity to the latter; it can be purified to homogeneity on a gelatin affinity column. In the work presented here, fragments of the gelatin binding domain are expressed in P. pastoris, purified to homogeneity, and investigated at the molecular level. Through a dissection approach, surface plasmon resonance (SPR) is used to characterise the recombinantly produced protein, to accumulate more information about the function of the full domain. NMR is used to assess the folding of the protein fragments at atomic resolution. In particular, the secondary structure of 8Fn1-9Fn1 is mapped using inter-strand NOEs, which suggests that the construct takes the fold of a pair of typical Fn1 modules. Gelatin affinity chromatography is used to confirm that both Fn1 and Fn2 modules contribute to gelatin binding, possibly in two clusters (1Fn2-2Fn2 and 8Fn1-9Fn1). The 7Fn1 module may perform a structural role in linking together these two interaction sites, in the same way as suggested for 6Fn1, which is thought to act in a structural manner to enhance the binding of 1Fn2-2Fn2 to gelatin. Three carbohydrate moieties are found on this domain, one on 2Fn2 and two on 8Fn1. Here, by means of expressing different protein length fragments, and by site directed mutagenesis, the role of each sugar chain is investigated independently. The sugar chain on 2Fn2 does not appear to promote binding to collagen, nor does the first sugar chain on 8Fn1 (N-linked to N497), implying another role for these sugars such as protection from proteolysis. However, the presence of at least a single GlcNAc sugar residue on the second sugar chain site on 8Fn1 (N- linked to N511) is essential for full affinity binding to collagen. Direct binding of the 8Fn1-9Fn1 module pair to collagen is assessed with a short collagen peptide and the binding is monitored by NMR. The peptide appears to bind, predominantly to the final strand of 8Fn1, the first β- strand of 9Fn1, and the linker between the two modules, with μM affinity. A model for bound peptide is proposed. The highly conserved amino acid motif Ile-Gly-Asp (IGD) is found on four of the nine N-terminal Fn1 modules of fibronectin. Tetrapeptides containing the IGD were demonstrated to promote the migration of fibroblast cells into a native collagen matrix. Two of these “bioactive” IGD motifs are found within the gelatin binding domain, one on 7Fn1 and one on 9Fn1. In this study, the motif in the 8Fn1-9Fn1 module pair is shown to be located in a tightly constrained loop within 9Fn1. By site directed mutagenesis, the IGD motifs of 7Fn1 and 9Fn1 are subjected to single amino acid substitutions, and their ability to stimulate cell migration assessed in our assay. By NMR, the fold of the IGD mutant proteins is found to be unaffected by the mutation with respect to the wild type, with the exception of small perturbations around the substitution site. While the wild type module is able to stimulate fibroblast migration, the mutant proteins show reduced or negligible bioactivity. The larger fragments show far more potency in stimulating fibroblast migration, with 8Fn1-9Fn1 (one IGD motif) 104 times more potent than the IGD peptide, and the full gelatin binding domain (two IGD motifs) 106 times more potent than the 8Fn1-9Fn1. Potential mechanisms for this enormous enhancement of the IGD potency in different contexts are discussed.

Despite our understanding of the importance of the 3D environment on the behaviour of virtually every cell, most studies are still performed within 2D engineered cell culture devices. In this project, the main goal was to design and engineer tunable three-dimensional (3D) extracellular matrix (ECM)-mimicking scaffolds made of collagen and fibronectin (namely the two major building blocks of the ECM) that recapitulate the ECM structural and mechanical properties essential for wound healing and cancer research. Two different methods were implemented to fabricate 3D scaffolds. First, 3D collagen scaffolds with a ‘porous’ structure (fabricated by a previous student via an ice-templating technique) were used. It was shown that, by increasing collagen concentration to 1.25 wt.%, homogenous scaffolds with interconnected pores (needed for cell invasion through the entire scaffold) were obtained. Fibronectin (Fn) was then incorporated using thermal and mechanical gradients to modify protein content and tune scaffolds microarchitecture. The effect of Fn coating of the collagen underlying structure on cell behaviour such as cell adhesion, invasion and matrix deposition was studied. Results showed that overall more cells adhered to Fn-coated scaffolds with respect to pure collagen scaffolds. Furthermore, our findings indicated that cells were also able to sense the conformation of the Fn coating (as assessed by Fluorescence Resonance Energy Transfer, FRET) since they deposited a more compact ECM on compact Fn coating while a more unfolded and stretched ECM was deposited on unfolded Fn coating. Second, 3D more complex physiologically relevant scaffolds with a ‘fibrillar’ structure were fabricated via a cold/warm casting technique. Pure collagen scaffolds were first generated: in cold-cast scaffolds, clear thin and long collagen fibers were observed while warm-cast scaffolds were denser and comprised shorter collagen fibers. The effect of both collagen concentration and casting temperature on scaffolds’ microstructure was studied. Our results indicate a preponderant effect of temperature. We further engineered dual-protein fibronectin-collagen fibrillar scaffolds by incorporating Fn fibers using thermal gradient. Clear Fn fibers were observed in some conditions. FRET assessment of Fn fibers also showed significant difference of Fn conformation. In this more advanced casting technique, cells were initially embedded into the scaffolds, which provided a more homogeneous cell distribution and a better tissue-mimicking setting. In each case, the effect of resulting ECM properties was tested via cell viability assays. Our data indicate that cells were viable after 72 hours, they could proliferate inside the scaffolds and were able to spread in some conditions. Collectively, our 3D ECM-mimicking scaffolds represent a new tunable platform for biological and biomaterial research with many potential applications in tissue engineering and regenerative medicine. Investigating cell behaviour in 3D ECM-mimicking environment will provide valuable insights to understand cancer progression and approaches to limit the progression and ultimately prevent metastasis.

Abstract Type XIII collagen is an integral membrane protein in type II orientation. In cells and tissues type XIII collagen has been located in various adhesive structures, like focal adhesions. Due to this, its biological role has been implicated in cell adhesion. This collagen also exists as a soluble protein due to the release of the ectodomain from the plasma membrane. In this thesis, ectodomain shedding, i.e. enzymatic release of the extracellular domain, was studied in detail, focusing on the phenomenon as it occurs in mammalian cells. It was found that the ectodomain is released by members of the mammalian proprotein convertase family, e.g. furin. Shedding was shown to take place at the cell surface, but based on additional observations, this cleavage may also take place intracellularly in the Golgi apparatus. Various intracellular mechanisms, depending on cell type, were found to be involved in the regulation of ectodomain shedding. Apparently, due to the liberation of the ectodomain, the level of type XIII collagen on the plasma membrane is maintained at a relatively even amount. The released ectodomain was shown to retain biological activity. It showed distinct matrix-specificity so that on vitronectin its influence on cell functions was anti-adhesive, anti-migratory, anti-proliferative and non-supportive of cell spreading. It was also demonstrated to affect the fibronectin matrix assembly in a manner that resulted in reduced amounts of the fibrillar fibronectin matrix. A large collection of human epithelial and mesenchymal cancer samples were screened for type XIII collagen mRNA expression and compared to the expression levels of pre-malignant and normal samples. It was discovered that malignant transformation upregulates the expression of type XIII collagen in mesenchymal cancers and particularly in the stroma of epithelial cancers, more so than in cancer epithelia. TGF-β1 was demonstrated as one factor contributing to the stimulation of expression. Based on cell culture experiments in this study, it was also deduced that the upregulated expression of type XIII collagen and the concomitant shedding of the ectodomain can remodel the tumour stroma, making it inauspicious for adhesion-dependent cell functions, particularly in vitronectin-rich milieu.

The fundamental principle of tissue engineering is to use appropriate cell source, combined with scaffolds and bioactive factors to develop tissue constructs which restore, maintain or improve tissue function. There is increasing data emphasizing the importance of mechanical signals and extracellular matrix (ECM) proteins presented by the scaffold in determining stem cell fate/functions which are critical to tissue construct maturation and success of stem cell-based therapies. Cell-matrix adhesions are one of the major mechanosensing machineries cells use to convert information provided by ECM ligands and mechanical signals presented by scaffolds into intracellular biochemical signaling cascades which lead to particular functional responses. Therefore, understanding how ECM ligands and mechanical signals regulate cell-matrix adhesion formation and activation of associated intracellular signaling proteins is fundamental to rational design of biomaterial and loading protocol for optimal cell functional responses in tissue constructs. In this study, we attempted to understand the regulatory effects of external mechanical signal and exogenous ECM protein on cell-matrix adhesion formation and associated intracellular signaling proteins of human mesenhymal stem cells, and in particular, to test the hypothesis that mechanical stimulation or exogenous ECM protein can lead to adhesion maturation into 3D-matrix adhesions in 3D collagen environment. We used microencapsulation technique to embed cells in 3D collagen environment, forming disc-shaped hMSC-collagen constructs. By immunofluorescent staining and confocal microscopy, we visualized changes in size, morphologies and molecular composition of the adhesions. First of all, 2D adhesions of hMSCs were characterized. We showed that hMSCs form well-organized αv integrin-based focal adhesions and fibrillar adhesions in 2D culture. To investigate the regulatory effects of mechanical signals on adhesion signaling and maturation, we used micromanipulator-based loading device to impose dynamic compression to hMSC-collagen constructs. We found that dynamic compression lead to enlargement of integrin αv adhesions which recruit focal adhesion kinase (FAK), vinculin and extracellular signal-regulated kinase (ERK). In addition, FAK was activated at enlarged integrin αv adhesions and translocated to peri-nuclear region after compression, suggesting that loading induces activation of FAK signaling pathways through increased integrin αv clustering. Moreover, we demonstrated that dynamic compression can induce 3D-matrix adhesion formation, indicating the role of external force in integrin α5-based adhesion maturation in 3D collagen environment. We explored the effect of exogenous ECM proteins on adhesion maturation of hMSCs by adding fibronectin into cell-collagen mixture during fabrication of collagen constructs. Our results demonstrated that the exogenous fibronectin can induce α5 integrin-based adhesion maturation into 3D-matrix adhesions in our collagen constructs in a dose-dependent manner. This study demonstrated that the effect of external mechanical signals and exogenous ECM ligands on adhesion signaling and maturation of hMSCs in 3D collagen environment. Our findings contribute towards mechanobiology of hMSCs in 3D context. In particular, our results showed that exogenous proteins or external loading can lead to 3D-matrix adhesion formation, which may serve as a potential way to enhance biological functions of hMSCs in collagen constructs, facilitating stem cell-based therapies.
published_or_final_version
Mechanical Engineering
Doctoral
Doctor of Philosophy

Human embryonic stem cells are pluripotent cells that have indefinite replicative potential and ability to differentiate into derivatives of three germ layers. HESCs are conventionally derived and grown on mitotically inactivated mouse embryonic fibroblasts and there are some alternative feeder types of human origin that have been used to replenish hESCs while trying to prevent cross-species contamination. The trophic factors that are secreted by the feeders are found to be important for long-term pluripotency but there are also supportive culture systems for hESCs lacking feeder cells which might suggest that not only the interactions with the feeders affect the behaviour of hESCs but also the components of the niche may take part in the decision of self-renewal or differentiation. Extracellular matrix components are known to exert their stimulatory or inhibitory effects by localising cells into a specific microenvironment in natural niches but have been relatively little investigated for hESCs. The aim of this study was to investigate ECM components which might have a role in the maintenance of hESCs. I have first investigated human placental stromal fibroblasts and immortalised human placental stromal fibroblasts for the support hESC pluripotency as an anlternative feeder type to conventional mouse embryonic fibroblasts. Secondly, the matrices derived from hPSFs and ihPSFs were assessed for their ability to support hESC pluripotency. Tandem mass spectrometry was used to identify ECM components released by human feeders in order to characterise the range of extracellular matrix proteins that support the growth of self-renewing hESCs. The majority of the molecules was shared between the cell types irrespective of hPSF cell derived matrix was not being supportive for hESC pluripotency, with some ECM components being unique ihPSFs. Collagen VI, tenascin C and versican were tested for hESC attachment and as substrates for feeder-free culture system in order to develop an optimised feeder-free system. Furthermore, integrin receptor profile of different hESC lines was also determined in order to identify the mechanisms of substrate attachment. Integrin attachment was shown to be vital for hESC engagement to fibronectin and vitronectin in feeder-free systems. The components of the integrin signalling machinery were identified in hESCs and the significance of integrin-mediated signalling in hESC self-renewal was demonstrated by blocking integrin β1 on fibronectin and integrin aVβ5 on vitronectin. Moreover, intracellular signalling mediator c-Src was shown to involve in ECMregulated signalling by affecting the phosphorylation of Focal Adhesion Kinase. Inhibition of Src led to a decrease in the expression of pluripotency-associated markers. Finally, the effects of growth factor supplementation on the maintenance of pluripotency in defined feeder-free conditions were studied by withdrawal of growth factors and blocking FGF Receptors. FGF-2 was shown to be essential for long-term self-renewal while the effects on pluripotency deteriorated in the absence of both FGF-2 and Activin A. Taken together this project highlighted the importance of substrate attachment and growth factors on the regulation of hESC self-renewal.

Abstract This study was undertaken to identify mechanisms of adhesion of intraocular lenses (IOLs) to the capsular bag after cataract surgery and IOL implantation. It was also done to challenge the sandwich theory presented for posterior capsular opacification (PCO): If the IOL is made of a bioactive material it would allow a single lens epithelial cell layer to bond both to the IOL and the posterior capsule at the same time. This would produce a sandwich pattern including the IOL, the cell monolayer and the posterior capsule. The sealed sandwich structure would prevent further epithelial ingrowth. The degree of bioactivity of the IOL could explain the basic difference in the incidence of PCO and capsulotomy rates with different IOL materials. The sandwich theory was put forward on the basis of a search for a keratoprosthesis material, which would allow maximal adhesion of the prosthesis to corneal tissue. Titanium and glass-ceramic coated titanium were found to develop better adhesion than poly (methyl methacrylate) (PMMA). The adhesion of PMMA to the corneal stromal tissue was loose, and down growth of corneal epithelial cells was seen around the prosthesis. The differences between various IOL materials were first tested with rabbit corneal tissue cultures. There was better adhesion of corneal tissue to soft, hydrophobic acrylate than to PMMA, heparin surface modified (HSM)-PMMA, silicone or hydrogel IOLs. To assess differences in protein adhesion to IOL surfaces, different IOLs were incubated for 24 hours with radioactive iodine labeled fibronectin. Soft hydrophobic acrylate (AcrySof®) showed the highest binding of fibronectin, and the differences relative to all the other materials were significant (p < 0.01-0.001), except to PMMA (p = 0.31). The sandwich theory and the results with rabbit corneal tissue cultures and the protein adhesion study in vitro were evaluated against the results found in pseudophakic autopsy eyes. Altogether, 70 autopsy eyes were analyzed. From 38 autopsy eyes containing PMMA, silicone, soft hydrophobic acrylate or hydrogel IOLs histological sections were prepared from the capsular bag and immunohistochemical analyses were performed for fibronectin, vitronectin, laminin and collagen type IV. A total of 152 specimens were analyzed. From 32 autopsy eyes containing IOLs made of PMMA, silicone, acrylate or hydrogel, IOLs were explanted from the capsular bag and immunohistochemical analysis was done on both sides of the IOLs for fibronectin, vitronectin, laminin or collagen type IV. Soft hydrophobic acrylate IOLs had significantly more adhesion of fibronectin to their surfaces than PMMA or silicone IOLs. Also, more vitronectin was attached to acrylate IOLs than to the other IOL materials. Silicone IOLs had more collagen type IV adhesion in comparison to the other IOL materials studied. In histologic sections a sandwich-like structure (anterior or posterior capsule-fibronectin-one cell layer-fibronectin-IOL surface) was seen significantly more often in eyes with acrylate IOLs than in PMMA, silicone or hydrogel IOL eyes. These studies support the sandwich theory for posterior capsule opacification after cataract surgery with IOLs. The results suggest that fibronectin may be the major extracellular protein responsible for the attachment of acrylate IOLs to the capsular bag. This may represent a true bioactive bond between the IOL and the lens epithelial cells, and between the IOL and the capsular bag. This may explain the reason for clinical observations of less posterior capsular opacification and lower capsulotomy rates with the soft hydrophobic acrylate material of AcrySof® IOLs compared to the other IOL materials studied.

This thesis aimed at studying mechanisms involved in control of tissue fluid homeostasis during inflammation.

The interstitial fluid pressure (P_IF) is of importance for control of tissue fluid balance. A lowering of P_IF in vivo will result in a transport of fluid from the circulation into the tissue, leading to edema. Loose connective tissues that surround blood vessels have an intrinsic ability to take up fluid and swell. The connective tissue cells exert a tension on the fibrous network of the tissues, thereby preventing the tissues from swelling. Under normal homeostasis, the interactions between the cells and the fibrous network are mediated by β1 integrins. Connective tissue cells are in this way actively controlling P_IF.

Here we show a previously unrecognized function for the integrin αVβ3, namely in the control of P_IF. During inflammation the β1 integrin function is disturbed and the connective tissue cells release their tension on the fibrous network resulting in a lowering of P_IF. Such a lowering can be restored by platelet-derived growth factor (PDGF) -BB. We demonstrated that PDGF-BB restored P_IF through a mechanism that was dependent on integrin αVβ3. This was shown by the inability of PDGF-BB to restore a lowered P_IF in the presence of anti-integrin β3 IgG or a peptide inhibitor of integrin αVβ3. PDGF-BB was in addition unable to normalize a lowered P_IF in β3 null mice. Furthermore, we demonstrated that extracellular proteins from Streptococcus equi modulated αVβ3-mediated collagen gel contraction. Because of the established concordance between collagen gel contraction in vitro and control of P_IF in vivo, a potential role for these proteins in control of tissue fluid homeostasis during inflammation could be assumed. Sepsis and septic shock are severe, and sometimes lethal, conditions. Knowledge of how bacterial components influence P_IF and the mechanisms for tissue fluid control during inflammatory reactions is likely to be of clinical importance in treating sepsis and septic shock.

O estudo de macrointeraçães na matriz extracelular (ECM) foi abordado em três modelos; a interação colágeno/colagenase, a interação colágeno/fibronectina e finalmente, a evolução da família enzimática das metaloproteinases de matriz (MMP). As MMP se caracterizam por sua notável especificidade contra componentes da ECM. As colagenases intersticiais, os membros mais estudados, clivam os colágenos intersticiais em um único ponto da molécula produzindo dois fragmentos característicos. Usando a hipótese da hidropaticidade complementar, a qual estipula que peptídeos codificados por sequências nucleotídicas complementares podem interagir entre si, foi possível caracterizar a sequência SQNPVQP em colagenase de fibroblasto ou SSNPIQP em colagenase de neutrófilo como importantes na interação das respectivas enzimas com o colágeno nativo. O fato da fibronectina, outro componente da ECM, ligar-se no mesmo domínio do colágeno clivado pelas colagenases possibilitou a utilização da mesma abordagem acima (hidropaticidade complementar) no estudo da interação colágeno/fibronectina. Sendo assim, foi possível caracterizar a sequência TNEGVMY da fibronectina como importante na interação com o colágeno. Adjacente a este sítio na fibronectina, existe uma sequência (AAHEEIC) que é homóloga ao sítio de ligação ao zinco presente nas MMP. Isto originou a possibilidade de que zinco pudesse modular a interação colágeno/fibronectina. De fato, zinco aumentou especificamente a ligação entre colágeno e fibronectina. Finalmente, abordou-se alguns aspectos filogenéticos da família das MMP. Foi caracterizada uma relação filogenética entre o núcleo enzimático das MMP e o domínio correspondente tanto na protease de Serratia como na protease B de Erwinia chrysanthemi, membros da mesma família de metaloproteinases bacterianas. Sendo assim, a atividade catalítica das MMP pode ter sido herdada das metaloproteinases bacterianas, enquanto a especificidade ao substrato talvez se constitua em uma aquisição das MMP eucarióticas.
The study of extracellular matrix (ECM) macrointeractions was approached in three models: the collagen/collagenase interaction, the collagen/fibronectin interaction and the molecular evolution of the matrix metalloproteinase (MMP) family of enzymes. MMP is characterized by its remarkable specificity against ECM components. Interstitial collagenases, the best studied members, attack interstitial collagens at a unique site producing two fragments. Using the complementary hydropathy hypothesis that states that peptides encoded by complementary nucleotide sequence can interact one to another, it was possible to characterize the sequence SQNPVQP (in fibroblast collagenase) or SSNPIQP (in neutrophil collagenase) as important in the interaction of the respective enzymes with collagen. The fact that fibronectin, another ECM component, binds at the same domain on collagen that is cleaved by collagenases arose the possibility of using the same approach (complementary hydropathy) in the study of collagen/fibronectin interaction. It was possible to characterize the fibronectin sequence TNEGVMY as important in the interaction with collagen. Adjacent to this site, there is a sequence (AAHEEIC) that shows an homology to the zinc-binding site present in several MMP. Therefore, zinc could be a modulator the collagen/fibronectin interaction. Finnaly, some phylogenetic aspects of the MMP family were studied. It was characterized a phylogenetic relationship between the catalytic core of MMP and the corresponding domain in Serratia protease and protease B from E. chrysanthemi, members of the same family of bacterial metalloproteinases. The catalytic activity of MMP can have evolved from the bacterial metaloproteinases whereas the substrate specificity is an acquisition of eukaryotic MMP

[ES] El mieloma múltiple es una neoplasia hematológica caracterizada por una expansión descontrolada de células plasmáticas monoclonales (mPCs) en medula ósea que producen, en la mayoría de los casos, un componente monoclonal secretado en el suero y/o en orina. En la actualidad, se sigue considerando una enfermedad incurable con la constante aparición de recaídas en los pacientes. Una de las causas que condicionan esta situación, radica en la generación de resistencia frente a fármacos por parte de las mPCs. Este mecanismo de resistencia a fármacos (DR) se ha visto que no solo depende de factores intracelulares, sino que la propia interacción de las mPCs con el microambiente medular juega un papel fundamental para su supervivencia, crecimiento y desarrollo de DR. Entre los componentes del microambiente tumoral, destaca la adhesión de las mPCs a componentes de la matriz extracelular (ECM) que se ha visto relacionada con la generación de DR. Por este motivo el desarrollo de esta tesis doctoral consistió en la elaboración y validación de una plataforma de cultivo 3D basado en la síntesis de un microgel. Este sistema estará constituido por microesferas funcionalizadas con componentes de la ECM como son la fibronectina (FN), colágeno tipo I (COL), heparina (Hep), heparan sulfato (HS) y ácido hialurónico (HA), generando un entorno 3D biomimético con la capacidad de poder analizar la respuesta celular desencadenada por la interacción de las mPCs con los componentes de la ECM, así como la DR generada por la adhesión de las mPCs a estas biomoléculas. El primer estudio consistió en la realización y puesta a punto de varios protocolos para la síntesis de distintos microgeles; un primer sistema se produjo mediante la polimerización por vía radical en bloque de co-polímeros de poliacrilato de etilo (EA) y polimetacrilato de etilo (EMA) o bien por EA, EMA y ácido acrílico (AAc). Mediante una emulsión del tipo aceite en agua se consiguió producir con estos copolímeros, microesferas de un tamaño próximo al de las mPCs. Un segundo sistema se basó en microesferas de alginato. Estas microesferas se obtuvieron en un dispositivo de microfluidica produciéndose la gelificación externa de las micro-gotas con la incorporación de iones de calcio consiguiendo microesferas de un tamaño medio de 177 µm. Debido a la gran variedad de microesferas sintetizadas con diferentes grupos químicos en sus superficies, se consiguió establecer protocolos de funcionalización similares a los establecidos en la literatura, teniendo en cuenta la estabilidad de la biomolécula a lo largo del tiempo del cultivo celular. Este enfoque, permitió la funcionalización con una gran variedad de biomoléculas disponiendo así de microgeles funcionalizados con FN, COL, Hep, HS y HA. Una vez desarrollados los microgeles, en un segundo estudio se procedió a evaluar la respuesta celular en un entorno 3D basado en microgel, valorando la interacción con los componentes de la ECM. Entre los resultados observados se pudo determinar como el tamaño de las microesferas afecta al crecimiento celular incluso en ausencia de cualquier funcionalización. Con los microgeles constituidos por microesferas de un tamaño próximo al de las mPCs se obtuvo un mayor crecimiento celular que con los microgeles formados por partículas de mayor tamaño, y en ambos el crecimiento fue superior al del cultivo en suspensión. Se plantea la hipótesis de que la presencia de las microesferas favorece en gran medida que se produzca un mayor contacto célula-célula que se ve incrementado cuanto mayor es la superficie específica del microgel. Entre los componentes de la ECM estudiados, mientras que el COL no genera ninguna respuesta celular diferente al control (microgel no funcionalizado), el HA favorece la proliferación celular. La adhesión de las mPCs a la FN condiciona el bloqueo de las células en la fase G0-G1 del ciclo celular. Esta adhesión está mediada
[CA] El mieloma múltiple és una neoplàsia hematològica caracteritzada per una expansió descontrolada de cèl·lules plasmàtiques monoclonals (mPCs) en medul·la òssia que produeixen, en la majoria dels casos, un component monoclonal secretat en el sèrum i/o en orina. En l'actualitat, es continua considerant una malaltia incurable, amb la constant aparició de recaigudes en els pacients. Una de les causes que condicionen aquesta situació, radica en la generació de resistència enfront de fàrmacs per part de les mPCs. Aquest mecanisme de resistència a fàrmacs (DR) s'ha vist que no sols depèn de factors intracel·lulars, sinó que la mateixa interacció de les mPCs amb el microambient medul·lar juga un paper fonamental per a la seua supervivència, creixement i desenvolupament de DR. Entre els components del microambient tumoral, destaca l'adhesió de les mPCs a components de la matriu extracel·lular (ECM) que s'ha vist relacionada amb la generació de DR. Per aquest motiu, el desenvolupament d'aquesta tesi doctoral va consistir en l'elaboració i validació d'una plataforma de cultiu 3D basada en la síntesi d'un microgel. Aquest sistema estarà constituït per microesferes funcionalitzades amb components de l'ECM com són la fibronectina (FN), col·lagen tipus I (COL), heparina (Hep), heparan sulfat (HS) i àcid hialurònic (HA), generant un entorn 3D biomimètic amb la capacitat de poder analitzar la resposta cel·lular desencadenada per la interacció de les mPCs amb els components de la ECM, així com la DR generada per l'adhesió de les mPCs a aquestes biomolècules. El primer estudi va consistir en la realització i posada a punt de diversos protocols per a la síntesi de diferents microgels; un primer sistema es va produir mitjançant la polimerització per via radical en bloc de copolímers de poliacrilat d'etil (EA) i polimetacrilat d'etil (EMA), o bé per EA, EMA i àcid acrílic (AAc). Mitjançant una emulsió del tipus oli en aigua es va aconseguir produir amb aquests copolímers, microesferes d'una grandària pròxima al de les mPCs. Un segon sistema es va basar en microesferes d'alginat. Aquestes microesferes es van obtenir en un dispositiu de microfluidica produint-se la gelificació externa de les microgotes amb la incorporació d'ions de calci aconseguint microesferes d'una grandària mitjana de 177 ¿m. A causa de la gran varietat de microesferes sintetitzades amb diferents grups químics en les seues superfícies, es va aconseguir establir protocols de funcionalització similars als establerts en la literatura, tenint en compte l'estabilitat de la biomolècula al llarg del temps del cultiu cel·lular. Aquest enfocament va permetre la funcionalització amb una gran varietat de biomolècules disposant així de microgels funcionalitzats amb FN, COL, Hep, HS y HA. Una vegada desenvolupats els microgels, en un segon estudi es va procedir a avaluar la resposta cel·lular en un entorn 3D basat en microgel, valorant la interacció amb els components de l'ECM. Entre els resultats observats es va poder determinar com la grandària de les microesferes afecta el creixement cel·lular fins i tot en absència de qualsevol funcionalització. Amb els microgels constituïts per microesferes d'una grandària pròxima al de les mPCs es va obtenir un major creixement cel·lular que amb els microgels formats per partícules de major grandària, i en tots dos el creixement va ser superior al del cultiu en suspensió. Es planteja la hipòtesi que la presència de les microesferes afavoreix en gran manera que es produïsca un major contacte cèl·lula-cèl·lula que es veu incrementat com més gran és la superfície específica del microgel. Entre els components de l'ECM estudiats, mentre que el COL no genera cap resposta cel·lular diferent del control (microgel no funcionalitzat), l'HA afavoreix la proliferació cel·lular. L'adhesió de les mPCs a la FN condiciona el bloqueig de les cèl·lules en la fase G0-G1 del cic
[EN] Multiple myeloma is a haematological neoplasm characterized by an uncontrolled expansion of monoclonal plasma cells (mPCs) in bone marrow that produce, in most cases, a monoclonal component secreted in serum and/or urine. At present, it is still considered an incurable disease with the constant appearance of relapses in patients. One of the causes that condition this situation lies in the generation of drug resistance by the mPCs. This mechanism of drug resistance (DR) has been seen to depend not only on intracellular factors, but the very interaction of mPCs with the medullary microenvironment plays a fundamental role in their survival, growth and development of DR. Among the components of the tumor microenvironment, the adhesion of the mPCs to components of the extracellular matrix (ECM) stands out, which has been related to the generation of DR. For this reason, the development of this doctoral thesis consisted in the elaboration and validation of a 3D culture platform based on the synthesis of a microgel. This system will be made up of micropsheres functionalized with the components of the ECM such as fibronectin (FN), collagen type I (COL), heparin (Hep), heparan sulphate (HS) and hyaluronic acid (HA), generating a 3D biomimetic environment with the ability to analyse the cellular response triggered by the interaction of mPCs with the ECM components, as well as the DR generated by the adhesion of the mPCs to these biomolecules. The first study consisted in the realization and development of several protocols for the synthesis of different microgels. A first system was produced by the radical block polymerization of polyethylene acrylate (EA) and polymethacrylate (EMA) co-polymers or by EA, EMA and acrylic acid (AAc). By means of an oil-in-water emulsion technique, it was possible to produce, with these copolymers, microspheres of a size close to that of the mPCs. A second system was based on alginate microspheres. These microspheres were obtained in a microfluidic device producing the external gelification of the micro-drops with the incorporation of calcium ions, obtaining microspheres with an average size of 177 µm. Due to the great variety of microspheres synthesized with different chemical groups on their surfaces, it was possible to establish functionalization protocols similar to those established in the literature, taking into account the stability of the biomolecule along with the time of cell culture. This approach allowed for functionalization with a great variety of biomolecules, having in this way functionalized microgels with FN, COL, Hep, HS and HA. Once the microgels were developed, a second study was carried out to evaluate the cell response in a 3D microgel-based environment, assessing the interaction with the components of the ECM. Among the results observed, it was possible to determine how the size of the microspheres affects cell growth even in the absence of any functionalization. With the microgels constituted by microspheres close to the size of the mPCs, a greater cellular growth was obtained than with the microgels formed by larger particles, and in both the growth was higher than in suspended culture. It is hypothesized that the presence of microspheres greatly favours a greater cell-cell contact, which is increased the larger the specific surface area of the microgel. Among the components of the ECM studied, while the COL does not generate any cellular response different from the control (non-functionalized microgel), HA favours cell proliferation. The adhesion of mPCs to FN conditions the blocking of cells in the G0-G1 phase of the cell cycle. This adhesion is mediated by the integrin ¿4ß1.
La presente tesis doctoral no se podría haber realizado sin la financiación del proyecto PROMETEO/2016/063, trabajo que también estuvo parcialmente financiado con fondos FEDER (CIBERONC (CB16/12/00284)). La iniciativa CIBER-BBN está financiada por el proyecto VI National R&D&I Plan 2008-2011, Iniciativa Ingenio 2010, Consolider Program. Las acciones CIBER están financiadas por el Instituto de Salud Carlos III con ayuda del Fondo Europeo de Desarrollo Regional.
Marin Paya, JC. (2021). 3D Culture o Multiple Myeloma Cell Line Using Microgel Environments [Tesis doctoral]. Universitat Politècnica de València. https://doi.org/10.4995/Thesis/10251/167427
TESIS

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Financiadora de Estudos e Projetos
The aim of this study was to evaluate the effect of a strength exercise protocol on articular cartilage in animal model of osteoarthritis (OA). Thirty-six rats were divided in 6 groups: Control (C, n = 6), Osteoarthritis (OA, n = 6), Sham (S, n = 6), Control with exercise (E n = 6), Osteoarthritis with exercise (OAE, n = 6) and Sham with exercise (SE, n = 6). The animal model of osteoarthritis was anterior cruciate ligament transection (ACLT) in rats. After 2 weeks of ACLT, groups E, OAE and SE started the strength exercise protocol, three times a week for 8 weeks. We used the Mankin Histologic Grading System, measured the density of chondrocytes, the density of collagen fibers and the expression of collagen type II, chondroitin sulfate and fibronectin. The groups subjected to strength exercise protocol, OAE and SE, had lower values for the Mankin score, chondrocyte density and fibronectin expression and higher values for collagen fibers density, type II collagen expression and chondroitin sulfate expression when compared with OA and S, respectively. Group E was different from group C only in chondrocyte density and fibronectin expression. Therefore, strength exercise changes the content and expression of different articular cartilage constituent, having influence on our animal model of osteoarthritis and provides benefits to the cartilaginous tissue.
O objetivo desse estudo foi avaliar o efeito de um protocolo de exercício resistido na cartilagem articular de modelo animal de osteoartrite (OA). Trinta e seis ratos foram divididos em 6 grupos: Controle (C), Osteoartrite (OA); Sham (S), Exercício (E), Osteoartrite e Exercício (OAE), Sham e Exercício (SE). Os grupos OA, OAE, S e SE foram submetidos à transecção cirúrgica do ligamento cruzado anterior (LCA) do joelho esquerdo, sendo que somente os grupos OA e OAE tiveram o LCA seccionado. Após 2 semanas da cirurgia, os grupos E, OAE e SE iniciaram o protocolo de exercício resistido, 3 vezes por semana, durante 8 semanas. Foi aplicado o sistema de graduação histológica de Mankin, mensurado a densidade de condrócitos, a densidade de fibras colágenas e a expressão de colágeno tipo II, sulfato de condroitina e fibronectina. Os grupos submetidos ao protocolo de exercício resistido, OAE e SE, apresentaram menores valores para o sistema de graduação de Mankin, densidade de condrócitos e expressão de fibronectina e maiores valores para densidade de fibras colágenas, expressão de colágeno tipo II e sulfato de condroitina quando comparados aos grupos OA e S, respectivamente. O Grupo E apresentou diferença do grupo C somente na avaliação da densidade de condrócitos e na expressão de fibronectina. Portanto, o exercício resistido promove modificações no conteúdo e na expressão de diferentes constituintes da cartilagem articular, exercendo influência em nosso modelo de osteoartrite e trazendo benefícios para o tecido cartilaginoso.

Grading osteoarthritic tissue has, until now, been a laboratory process confined to research activities. This thesis establishes a scientific protocol that extends osteoarthritic tissue ranking to surgical practice. The innovative protocol, which now incorporates the structural degeneration of collagen, enhances the traditional Modified Mankin ranking system, enabling its application to real time decision during surgery. Because it is fast and without time consuming laboratory process, it would potentially enable the cataloguing of tissues in osteoarthritic joints in all compartments of diseased joints during surgery for epistemological study and insight into the manifestation of osteoarthritis across age, gender, occupation, physical activities and race.

Le cancer du rein compte parmi les 10 types de cancers les plus fréquents chez l’Homme. Il n’existe aujourd’hui aucun marqueur biomoléculaire dans ce type de cancer, et dans le cas d’un cancer métastatique, l’arsenal thérapeutique aujourd’hui disponible manque d’efficacité. Les différents processus mis en jeu lors de la progression tumorale sont encore mal connus. La connaissance de ces processus pourrait permettre de mettre en évidence de nouvelles cibles thérapeutiques, ainsi que des marqueurs biomoléculaires pronostiques ou diagnostiques de la maladie. Dans un premier projet, et afin de mieux comprendre les mécanismes de la progression tumorale et d’identifier de nouvelles cibles thérapeutiques potentielles et de nouveaux marqueurs biomoléculaires dans le cancer du rein, un nouveau modèle innovant a été généré à partir d’une lignée tumorale de RCC murine. Ce modèle de réimplantations successives de cellules tumorales issues de tumeur primaire ou de métastases a permis de générer différentes lignées cellulaires montrant une agressivité accrue au cours des passages. En utilisant une stratégie de biologie des systèmes, ce modèle pourra permettre de mettre en évidence des cibles d’études prometteuses qui pourraient être de nouvelles cibles thérapeutiques ou de nouveaux marqueurs biomoléculaires dans le RCC. L’interleukine-34 est l’exemple d’une cible d’étude d’ores et déjà été sélectionnée, mettant en évidence la puissance du modèle généré. Dans un second projet, les rôles de certains membres de la matrice extracellulaire tumorale ont été évalués en utilisant cette même lignée de RCC murine (collagène de type I, fibronectine, matrigel). Cette étude a permis de mettre en évidence le potentiel pro-invasif et pro-métastatique du dépôt de collagène de type I dans les tumeurs. Des récepteurs activés par le collagène sont proposés comme potentiellement impliqués dans les effets induits par le collagène de type I dans le modèle. Ces deux projets permettent et permettront de mieux comprendre certains mécanismes de la progression tumorale, ainsi que de mettre en évidence des marqueurs biomoléculaires et de nouvelles cibles thérapeutiques
Kidney cancer is one of the 10 commonest human cancers. To date, no biomolecular markers are available in this type of cancer, and in the case of metastatic cancer, the therapeutic arsenal is still inefficient. The different processes involved in cancer progression are still poorly understood. Understanding those processes could highlight new therapeutic targets, and new prognostic or diagnostic biomolecular markers of this disease. For a first project, a new innovative model has been generated from a murine RCC cell line as a tool to understand cancer progression mechanisms and to identify new therapeutic target and new biomolecular markers in kidney cancer. This model of sequential reimplantation of cancer cells isolated from primary tumours or metastases allowed us to generate different cell lines showing increased aggressiveness after passages. Using a systems biology strategy, this model will allow us to identify new potential therapeutic targets and new biomolecular markers in RCC. Interleukin-34 is an example of an already selected target, showing the power of the model generated. For a second project, the role of some members of extracellular matrix (collagen type I, fibronectin, matrigel).was studied using this same murine RCC cell line. This study demonstrated the potential pro-invasive and pro-metastatic roles of collagen type I deposition in tumors. Collagen-activated receptors are proposed as mediators of the effect induced by collagen type I in this model. Those two projects have and will continue to contribute to a better understanding of cancer progression mechanisms, and will bring out new biomolecular markers and new therapeutic targets

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Universidade Federal de Sao Carlos
The function of articular cartilage depends on the chondrocytes and on the components of the extracellular matrix, which in turn may be regulated by mechanical stimuli. Thus, changes in load support may affect its composition or its structure and interfere with their functional ability to sustain and distribute loads and minimize the stresses of contact. Thus, investigations of articular cartilage components, such as chondrocyte and or matrix components are essential for prevention and treatment of arthritic disease. A greater understanding of the relationship of use / disuse and degeneration as well as the consequences of situations such as shear stress, static load or unloading can generate in this tissue. The aim of this study was to evaluate the response of chondrocytes, proteoglycan, collagen and fibronectin in articular cartilage after application of a protocol of immobilization, stretching and joint remobilization. Material and Methods: We used 36 animals divided into six groups (n = 6): immobilized (I), immobilized and stretched seven days per week (IS7), immobilized and stretched three days per week (IS3), stretched seven days per week (S7), stretched three days per week (S3) and control (C). Groups I, IS3 and AS7 underwent four weeks of immobilization of the left hind limbs. Groups IS7 and IS3, after immobilization, were subjected to three weeks of the posterior muscle stretching of the left hind leg daily or three times per week, respectively. The S3 and S7 groups remained free in the cage for 4 weeks and subsequently underwent three weeks of posterior muscle stretching of the left hind limb daily or three times per week, respectively. After these procedures, the left ankle were collected, decalcified, processed in paraffin and stained with H&E, Safranin-O, Picrossiruius Red and immunostained with fibronectin and chondroitin sulfate 4 for further analysis. Two observers evaluated parameters such as chondrocyte cloning, loss of proteoglycan content, thin and thick fibrils collagen content, intensity of staining for fibronectin and chondroitin sulfate 4. For statistical analysis we used the following tests: Kruskal Wallis and post hoc Newman Keuls: cloning and the proteoglycan content of the different groups); Duncan multiple comparison: morphometric evaluation of cellularity; ANOVA and post hoc Tukey: proportion of thin and thick fibrils of collagen. For analysis of the immunohistochemistry reactions of fibronectin and chondroitin sulfate 4 it was used nonparametric test Kruscal Wallis and post hoc Newman Keuls. In all tests the significance level was p ≤ 0.05. Results: With respect to the cellularity IS7 group showed significant increase in cellularity compared to groups I and C. The IS3 group also showed significant celullar change with the formation of chondrocyte cloning compared to groups S7, S3 and C. The most significant loss of proteoglycan was in IS7 group compared to all other groups. The I group also lost significantly more proteoglycan than the others, except for IS7 group. With respect to collagen fibrils was observed that immobilization (I) significantly reduced the thin fibrils in relation to groups IS3, S7, S3 and C. The quantity of thick fibrils was influenced by mechanical overload, as there was a significant decrease of it in all groups compared to control. With respect to the findings of the fibronectin, the groups immobilized and stretched (IS3 and IS7) had significantly higher intensity staining of fibronectin than other groups. There was no statistical difference of chondroitin sulfate 4 immunostaining among the different groups. Conclusion: The protocols of muscle stretching after immobilization, applied on alternate days and daily provoked distinct adaptive responses in articular cartilage. The immobilization stimulated tissue atrophy that when stimulated by muscle stretching on alternate days, kept some matrix components, such as fine fibrils of collagen and proteoglycan, unlike the protocol used daily. Thus we can conclude that muscle stretching applied in previously immobilized joints should be applied with caution, on alternate days of mechanical stimulation.
A função da cartilagem articular é dependente do condrócito e dos componentes de sua matriz extracelular, que por sua vez, podem ser regulados por estímulos mecânicos. Assim, alterações no suporte de carga podem afetar sua composição ou sua estrutura e interferir na sua capacidade funcional de sustentar e distribuir cargas e minimizar os estresses de contato. Desta forma, investigações dos componentes da cartilagem articular, como o condrócito e ou componentes da matriz são essenciais para prevenção e tratamento de doenças articulares. É necessário um maior entendimento das relações de uso/desuso e degeneração, assim como das conseqüências que situações como estresse de cisalhamento, carga estática prolongada ou ausência de carga possam gerar neste tecido. O objetivo do presente estudo foi avaliar a resposta do condrócito, proteoglicana, colágeno e fibronectina da cartilagem articular, após aplicação de um protocolo de imobilização, alongamento e remobilização articular. Material e Métodos: foram utilizados 36 animais divididos em 6 grupos (n=6): imobilizado (I), imobilizado e alongado 7 dias por semana (IA7), imobilizado e alongado 3 dias por semana (IA3), alongado 7 dias por semana (A7), alongado 3 dias por semana (A3), e controle (C). Os grupos I, IA7 e IA3 foram submetidos a 4 semanas de imobilização da pata traseira esquerda. Os grupos IA7 e IA3, após a imobilização, foram submetidos a 3 semanas de alongamento da musculatura posterior da pata traseira esquerda diariamente ou 3 vezes por semana, respectivamente. Os grupos A7 e A3 permaneceram livres na gaiola por 4 semanas e posteriormente foram submetidos a 3 semanas de alongamento da musculatura posterior da pata traseira esquerda diariamente ou em dias alternados, respectivamente. Após esses procedimentos, os tornozelos esquerdos foram coletados, descalcificados, processados em parafina e corados com H&E, Safranina, Picrossiruius Red e imunomarcados para fibronectina e sulfato de condroitina 4 para posterior análise. Foram avaliados por dois observadores parâmetros como: celularidade, contagem de clones, perda de proteoglicanos, conteúdo de fibrilas finas e grossas de colágeno e expressão de fibronectina e sulfato de condroitina 4. Para comparação destes parâmetros entre os diferentes grupos foram utilizados os seguintes testes estatísticos: Kruskal Wallis com post hoc Newman Keuls: formação de clones e conteúdo de proteoglicanas; Comparações múltiplas de Duncan: avaliação morfométrica de celularidade e Anova com post hoc de Tukey: proporção das fibrilas finas e grossas de colágeno. Para análise das reações de imunohistoquímica para fibronectina e sulfato de condroitina 4 foi utilizado o teste não paramétrico de Kruscal Wallis e post hoc Newman Keuls. Em todos os testes o nível de significância foi de p≤0,05. Resultados: com relação a celularidade o grupo IA7 apresentou aumento significativo da celularidade em relação aos grupos I e C. O grupo IA3 também apresentou alteração celular significativa com formação de clones em relação aos grupos A7, A3 e C. A maior perda significativa de proteoglicanas foi do grupo IA7 em relação a todos os outros grupos. O grupo I também perdeu significativamente mais proteoglicanas que os demais, somente não com relação ao grupo IA7. Com relação às fibrilas colágenas foi observado que a imobilização (I) reduziu significativamente as fibrilas finas em relação aos grupos IA3, A7, A3 e C. Já a quantidade de fibrilas grossas sofreu influência da sobrecarga mecânica, pois que houve diminuição significativa das mesmas em todos os grupos em relação ao controle. Com relação aos achados de fibronectina, os grupos imobilizados e alongados (IA7 e IA3) apresentaram significativamente maior intensidade de marcação desta que os outros grupos. Não houve diferença estatística das imunomarcações para sulfato de condroitina 4 entre os diferentes grupos. Conclusão: Os protocolos de alongamento muscular, após imobilização, realizados em dias alternados e diariamente, provocaram respostas adaptativas distintas na cartilagem articular. A imobilização desencadeou um quadro de atrofia tecidual que quando estimulada por alongamentos musculares em dias alternados, manteve alguns componentes da matriz, como fibrilas finas de colágeno e proteoglicana. Esta resposta foi agravada quando o mesmo protocolo foi aplicado diariamente. Desta forma, podemos concluir que o alongamento muscular aplicado em articulações previamente imobilizadas deve ser aplicado com cautela, respeitando períodos intercalados de estímulo mecânico.

Migration of T-lymphocytes on a surface coated with extracellular matrix (ECM) components (two-dimensional (2-D) migration) and migration (infiltration) into a matrix (Three-dimesional (3-D) migration) are complex events and the underlying mechanisms are not yet fully understood. Here 2-D and 3-D migration were studied by use of seven leukemic T-cell lines representing discrete differentiation stages, a non-leukemic T-cell clone, and normal peripheral blood T cells. peripheral blood lymphocytes and the T-cell clone produced nanogram quantities of various chemokines, as compared to a production of ≤ 0.05 ng/ml by the T leukemia cell lines. In a Boyden chamber system, the leukemic T-cell lines showed haptotactic migration on fibronectin. The migration was augmented bu exposure to chemokines, including RANTES, MIP-1α, MIP-1β, and IL-8. The T-cell lines showed a peak response at a chemokine concentration of 10-50 ng/ml, whereas the T-cell clone responded optimally at 100 ng/ml. In contrast to a general capability of T-cells to migrate on 2-D ECM, only some of the T-cell lines were capable of 3-D migration into Matrigel or a collagen matrix. The infiltrative capacity was unrelated to the capacity to migrate on or adhere to the substrata. T-cell lines with a capacity to infiltrate produced matrix metalloproteinase-9 (MMP-9) and tissue inhibitor of matrix metalloproteinases-1 (TIMP-1), whereas non-infiltrating cell lines did not produce MMP-9. T-cell lines capable of infiltrating Matrigel or collagen responded to chemokines exposure with increased infiltration, but the chemokines did not render non-infiltrative cell lines infiltrative. Stimulation of infiltration of T-cell lines into collagen by the chemokine SDF-1α was inhibited by somatostatin, a neuropeptide with immunosuppressive properties. In conclusion, the ability to migrate on 2-D substrata and to infiltrate into 3.D substrata was found to be distinguishable properties of T cells. failure of some T-cell lines to infiltrate correlated with the lack of expression of MMP-9. Chemokines stimulated infiltration of infiltrative T-cell lines into collagen and Matrigel but did not render non-infiltrative T-cell lines infiltrative. Finally, a possible physiological mechanism for modulation of the chemokine-stimulated 3-D migration was demonstrated.

Que o envenenamento pela serpente Bothrops jararaca causa distúrbios hemorrágicos sistêmicos, com alteração da coagulação e fibrinólise sangüíneas, é notório. Contudo, pouco se sabe sobre a ação in vivo desse veneno sobre as plaquetas. Em estudos recentes, demonstrou-se que esse veneno causa trombocitopenia, distúrbios da agregação e diminuição do número de corpos densos plaquetários, que, dessarte, sugeriam a ativação das plaquetas circulantes. Com o escopo de comprovar esta hipótese e melhor caracterizar as ações in vivo desse veneno sobre as plaquetas, serviu-se de um modelo experimental que empregava coelhos para o envenenamento pela B. jararaca. No grupo experimental, os animais foram injetados i.v. com o veneno da B. jararaca (60 µg/kg) e no grupo controle com salina. Previamente à administração de salina ou veneno, os coelhos tiveram suas plaquetas marcadas ex vivo com NHS-biotina. Para a avaliação das alterações plaquetárias, amostras de sangue foram coletadas seqüencialmente, em intervalos de tempo que variaram de 1 a 144 horas após a administração do veneno ou salina. Durante o envenenamento, houve trombocitopenia, hipofibrinogenemia, elevação dos níveis plasmáticos do fator de von Willebrand, diminuição da função plaquetária no sangue total induzida pela botrocetina e pelo colágeno e diminuição da secreção de ATP. Não obstante, os níveis plasmáticos de fator plaquetário 4, um marcador específico da ativação plaquetária in vivo, e os níveis intraplaquetários de serotonina se mantiveram constantes. Pela citometria de fluxo, observou-se um decréscimo significativo da expressão do epítopo da GPIIb-IIIa reconhecido pelo anticorpo monoclonal P2, porém isso não foi observado ao utilizar-se anticorpos policlonais. A expressão de fibrinogênio ou dos produtos de degradação do fibrinogênio/fibrina (PDF) na membrana plaquetária também não sofreu alteração significativa ao longo do tempo. Houve, todavia, elevações significativas da P-selectina plaquetária, um receptor cuja expressão é indicativa de ativação plaquetária, e do epítopo induzido por ligantes (LIBS1) da GPIIIa. A porcentagem de plaquetas reticuladas na circulação, assim como os tempos de sobrevivência plaquetária, não foram estatisticamente diferentes entre os dois grupos. As análises histológicas e imuno-histoquímicas dos órgãos dos coelhos mostraram que as plaquetas circulantes são retidas entre redes de fibrina nos capilares pulmonares. Os resultados obtidos sugerem que a trombina engendrada pelos componentes pró-coagulantes deste veneno desempenha uma função essencial na patogenia dos distúrbios da coagulação e plaquetários observados neste modelo de envenenamento. O aumento da expressão de P-selectina no grupo experimental comprovou a hipótese inicial de que as plaquetas dos coelhos envenenados são verdadeiramente ativadas na circulação. Os dados ora apresentados demonstram definitivamente que a diminuição do fibrinogênio ou o aumento dos PDF não são a causa fundamental da disfunção plaquetária observada no envenenamento botrópico e que outro(s) composto(s) parece(m) estar envolvido(s) com estes distúrbios plaquetários.
In spite of being well established that Bothrops jararaca snake venom causes blood coagulation and fibrinolysis disturbances in patients, scant information about blood platelet disorders during envenomation is available. In recent investigations, thrombocytopenia, platelet aggregation disturbances and decreased numbers of platelet dense bodies were observed following venom administration, suggesting that circulating platelets had been activated. In order to prove this hypothesis and to gain a better characterization of the in vivo role of this venom on platelets, an experimental model of B. jararaca envenomation was utilized. Rabbits were injected i.v. either with B. jararaca venom (60 µg/kg) (experimental group) or saline (control group). Previously to saline or venom administration, rabbit platelets were labeled ex vivo with NHS-biotin. To evaluate platelet disturbances, blood samples were collected consecutively, at time intervals that varied from 1 to 144 hours after venom or saline administration. During envenomation, there were thrombocytopenia, hypofibrinogenemia, elevation of von Willebrand factor plasma levels, reduced botrocetin- and collagen-induced platelet aggregation in whole blood, and decreased ATP secretion. However, plasma levels of platelet factor 4, a specific marker of in vivo platelet activation, and intraplatelet serotonin levels remained constant. By flow cytometry, a significant decrease on the expression of GPIIb-IIIa epitope recognized by P2 monoclonal antibody was observed; however, this was not observed when polyclonal antibodies were employed. Fibrinogen or fibrin(ogen) degradation product (FDP) expression on platelet surface showed no significant alteration. Nonetheless, significant elevations of platelet P-selectin, a receptor whose expression is indicative of platelet activation, and of ligand-induced binding sites (LIBS1) of GPIIIa were noted. The percentage of circulating reticulated platelets, as well as platelet survival times, were not statistically different between the two groups. Histopathological and immunohistochemical analyses of rabbit organs demonstrated that circulating platelets were sequestered among fibrin deposits in pulmonary capillaries. These results suggest that thrombin generated by procoagulating components of B. jararaca venom has an essential role in the pathogenesis of platelet and coagulation disorders in this experimental model. Increased expression of P-selectin in the experimental group proves the initial hypothesis that platelets of envenomed rabbits are indeed activated in the circulation. The data presented herein demonstrate definitively that decreased fibrinogen or increased FDP levels are not the primary cause of the platelet dysfunction observed in bothropic envenomation, but other substances seem to be responsible for it.

碩士
國立成功大學
生理學研究所
89
The interactions of extracellular matrix (ECM) and cell play important roles in cell proliferation, differentiation, and survival. Previous studies in our laboratory showed that MDCK cells lost the microvilli when cultured on type I collagen gel, whereas they formed cystic structures and exhibited microvilli formation on apical membrane when cultured in type I collagen gel. Interestingly, there was a thick layer of fibronectin deposited around MDCK cysts. We hypothesized that the property of fibronectin matrix might affect collagen fibril-induced loss of microvilli in MDCK cells. In this study, we found that total content of fibronectin and the level of assembled fibronectin matrix were enhanced in cells cultured on collagen gel-coated dish than on normal dish within 24 h. The nature of fibronectin was assessed by the treatment of the cells with collagenase. This treatment abolished collagen gel-coating induced increase in fibronectin content within one day. However, cells cultured on collagen gel-coated dish and in collagen gel exhibited markedly higher levels of collagenase-resistant fibronectin than cells cultured on normal dish and collagen gel within 2-6 days. We also detected significant increase of degraded fibronectin fragments in cells cultured on collagen gel-coated dish and in collagen gel, but the degree of fibronectin degradation seemed to be higher in the former than the latter conditions. Treatment of different fibronectin fragments also induced partial loss of microvilli in MDCK cells cultured on normal dish. In addition, rhodostomin induced disappearance of microvilli, but did not alter total content or assembled matrix of fibronectin in MDCK cells. Taken together, assembled and collagenase-resistant fibronectin matrix should be important for prevention of collagen gel-induced loss of microvilli.

碩士
國立成功大學
生理學研究所
100
The maintenance of tissue integrity is mainly controlled by the environmental cues, such as chemical signals and physical inputs, i.e., tissue stiffness. However, by using in vitro culture technique, cells are always cultured on plastic dish which may not be relevent to the in vivo physical property of tissue. Recent studies have developed several hydrogel systems, such as collagen gel to mimic physiological stiffness of tissue. It has been shown that collagen gel induces three-dimensional tissue-like multicellular structures which are more relevent to in vivo system. Uterine leiomyoma is a benign tumor grown in myometrium. Smooth muscle cells that derived from leiomyomal form ball-like aggregates whereas normal myometrial cell does not, suggesting that the formation of aggregation is one the major characteristics of leiomyomal cell in vitro. While much effort has been focused on the soluble/genetic factors in the formation of ball-like aggregrates, little is known on ECM stiffness in the regulation of the ball-like aggregrates in leiomyomal cells. Thus, my project is to investigate the role of ECM stiffness in the regulation of ball-like aggregrates in leiomymal cells. First I investigated whether collagen gel culture system induces aggregations of leiomyomal cell. The results showed that leiomyomal cell formed more aggregates when cells were grown on collagen gel but not collagen-coated dish. To further investigate the degree of collagen rigidity affected formation of aggregates, I performed different collagen gels from different origins. The results showed that leiomyomal cell developed cell aggregates on softer collagen gel earlier than stiff one. Leiomyomal cell contracted and resulted in shrinkage of collagen gel, suggesting the involvement of cell contractility in leiomyomal cell aggregation on collagen gel. Pharmacologic inhibition of myosin-II related contractility inhibited the leiomyomal cell aggregation on collagen gel. These results suggest that physical property of substratum and cell contractility regulated formation of leiomyomal cell aggregation.

碩士
國立清華大學
化學系
102
Abstract Alzheimer's disease ( AD ) is one of the most fatal neurodegenerative disease .The major pathogenesis of Alzheimer's disease ( AD ) is neurofibrillary tangles and enile plaques , and the aggregation of the A 40 plays a crucial role in the pathogenesis of the senile plaques of Alzheimer's disease (AD) . Although the amyloid -protein has been studied extensively , the mechanisms of A aggregation in brain remain unclear . In this study , we investigate the influence of the collagen related peptides on A aggregation. Here we chose the most important region of amyloid -protein responsible for aggregation , residues 16-22 (KLVFFAE) , as our study model . We incorporated the collagen sequence (POG)n into Aβ(16-22) and synthesized eight peptides: WT-A(16-22) , A(16-22)-(POG)6 , A(16-22)-(POG)7, A(16-22)-(POG)10 , (POG)7-A(16-22) and (POG)10-A(16-22).Two collagen peptides (POG)7 and (POG)10 were synthesized as the control peptides for comparison.We used fluorescence spectroscopy, TEM , CD , FT-IR and DLS to study whether the collagen sequence can inhibit A aggregation . CD measurements indicate that the Aβ(16-22) sequence at the N-terminus of (POG)n does not stabilize the triple-helical structure of collagen and such peptides have a weaker thermal stability than (POG)n .In contrast,when the Aβ(16-22) sequence is attached to the C-terminus of (POG)n, it can stablize the triple-helical structure of collagen. From aggregation studies, we found that the amyloid aggregation did not occur when (POG)7 was incorporated into A(16-22) but the aggregation was enhanced when (POG)10 incorporated into A(16-22).The mixing experiments indicate that (POG)7A cannot inhibit the aggregation of WT-A(16-22) while A(POG)6 and A(POG)7 can.The inhibition effect may not be due to the triple-helical structure of collagen but the PPⅡ structure.

Modular tissue engineering is a novel approach to creating scalable, self-assembling three-dimensional tissue constructs with inherent vascularisation. Under initial methods, the subcutaneous implantation of human umbilical vein endothelial cell (HUVEC)-covered collagen modules in immunocompromised mice resulted in significant host inflammation and limited HUVEC survival. Subsequently, a minimally-invasive injection technique was developed to minimize surgery-related inflammation, and cell death was attributed to extensive apoptosis within 72 hours of implantation. In confirmation of in vitro results, coating collagen modules with fibronectin (Fn) was shown in vivo to reduce short-term HUVEC apoptosis by nearly 40%, while increasing long-term HUVEC survival by 30% to 45%. Consequently, a 100% increase in the number of HUVEC-lined vessels was observed with Fn-coated modules, as compared to collagen-only modules, at 7 and 14 days post-implantation. Furthermore, vessels appeared to be perfused with host erythrocytes by day 7, and vessel maturation and stabilization was evident by day 14.

The matrix metalloproteinase (MMP) family of endopeptidases can collectively degrade many components of the extracellular matrix. Their proteolytic activities have been implicated in normal processes such as extracellular matrix turnover and certain pathological conditions such as periodontitis, arthritis, and tumour metastasis. Based upon domain composition gelatinase A is separated from the other MMPs by the insertion of three contiguous fibronectin type II modules into its catalytic domain. Since it was determined that a recombinant domain consisting of the three fibronectin type II modules bound to native type I collagen this domain was termed the collagen binding domain (CBD). The function of the CBD is to donate substrate binding exosites to allow for broader enzyme specificity. Considering that the CBD contains exosites for binding native/denatured collagen, this domain was subjected to site-directed mutagenic studies to elucidate essential residues involved in collagen binding. The binding properties of the collagen binding domain to denatured type I collagen (gelatin) was investigated using a recombinant protein constructed of the second and third fibronectin type II module (rCBD23). Ten mutations were performed within the rCBD23 protein. Since the binding of substrate to the CBD is via a hydrophobic pocket, the mutations F264A, F264Y, F266A, F266Y, F322A, F324A, F322Y, F324Y, F264A/F322A, and F266A/F324A were introduced into rCBD23 in order to determine the effect of removing hydrophobic character. It was found that there was a decrease in the binding of the mutant proteins that was proportional to the distance between the mutated residue side chain and a strictly conserved tryptophan at the base of the hydrophobic pocket. Complete abrogation of gelatin binding was observed in the double mutant F266A/F324A. The observed effect was proposed to be the result of destabilisation of the strictly conserved tryptophan that forms the base of the hydrophobic pocket. These studies have furthered our knowledge and understanding of the interactions of CBD with substrate. The present study, combined with results from other studies, could be used to synthesize compounds that are specific to the CBD and are able to irreversibly inhibit the binding of CBD to substrate. A drug that would preferentially block binding of the CBD to collagen is proposed to reduced the metastasis of tumour cells by abolishment of type IV collagen binding. The overall effect is decreased tumour migration from the primary site of development and therefore substantially decreasing tumour progression.

The extracellular matrix (ECM) provides mechanical and biochemical support to tissues and cells. It is crucial for cell attachment, differentiation, and migration, as well as for ailment-associated processes such as angiogenesis, metastases and cancer development. An approach to study these phenomena is through emulation of the ECM by synthetic gels constructed of natural polymers, such as collagen and fibronectin, or simple but tunable materials such as poly(ethylene glycol) (PEG) crosslinked with short peptide sequences susceptible to digestion by metalloproteases and cell-binding domains. Our lab uses PEG gels to study cell behavior in three dimensions (3D). Although this system fosters cell attachment and crosslinking peptides mentioned, the regenerative process of the ECM has not been mimicked yet in 3D synthetic gels. In an attempt to build in this functionality to PEG-based gels, I performed phage display to identify short oligopeptides that bind either collagen or fibronectin to assess them as potential nucleation points for crosslinking elements in order to emulate the in vivo reconstitution process. A phage display is a library of random oligopeptides expressed on a M13 bacteriophage that allows identification of a phenotype and a genotype with a single screening step. This inexpensive strategy could yield a short oligopeptide with high specificity. I identified the conditions under which phage display is compatible with our targets, and I isolated and identified five peptide candidates for fibronectin binding and two for collagen. Future work includes assessing whether these candidates could facilitate the formation of cell-created crosslinking in 3D synthetic hydrogels.

Yes
Studies have been conducted to highlight the anti-inflammatory and immunosuppressive properties of synthetic cannabinoids as well as their potential for cartilage repair. Various wound healing techniques can be used to investigate the mechanisms of chondrocyte repair in monolayers or three dimensional tissues constructs. In this work the effect of WIN55, 212-2 (WIN-2) on nitric oxide (NO) and matrix metalloproteinase-2 (MMP-2) expressed by wounded chondrocyte monolayers was investigated. Moreover, expression of collagen type-I and type-II, fibronectin and S100 proteins were detected using immunofluorescence and quantitatively verified using ELISA based techniques following treatment with 1 μM and 2 μM of WIN-2. Treating chondrocytes with 1 μM of WIN-2 significantly increased expression of collagen type-II, fibronectin and S100, and significantly reduced collagen type-I expressions as compared to the control groups. On the other hand, both concentrations of WIN-2 significantly reduced the expression of the inflammation markers NO and MMP-2 in a dose dependent manner. These findings highlight the potential use of the synthetic cannabinoids for improving cartilage healing properties as well as acting as an anti-inflammatory agent which could be used to enhance tissue engineering protocols aimed at cartilage repair.