Le potentiel thérapeutique du GDF-5 dans l’arthrose : une étude in vitro des facteurs anaboliques et cataboliques du cartilage

Brunet Maheu, Jean-Marc

09 1900

Introduction: Le principal objectif de cette étude est de mesurer l’effet du GDF-5 sur l’homéostasie du cartilage. Le GDF-5 est un gène de susceptibilité de l’OA faisant partie de la famille des BMPs et qui favorise la synthèse du cartilage. Le but de notre étude a été de déterminer l’effet du GDF-5 sur le métabolisme catabolique ainsi que sur l’équilibre global des chondrocytes, principalement au niveau de l’Aggrécan. Méthode : Des chondrocytes arthrosiques canins et humains OA ont été exposés au GDF-5. L’expression des ARNm et des protéines a été analysée afin d’évaluer la production de l’Aggrécan et le ratio Col-II/Col-I au niveau des facteurs anaboliques et du phénotype. Pour le catabolisme, l’expression et l’activité des aggrécanases ADAMTS-4 et ADAMTS-5 ont été mesurées. Les épitopes NITEGE et CTX-II ont aussi été quantifiés dans le liquide synovial canin après des injections intraarticulaires de GDF-5. Résultats : Le GDF-5 provoque une augmentation de l’activité cellulaire des chondrocytes canins et humains. Pour les ARNm et l’expression protéique, le GDF-5 augmente l’expression de l’Aggrécan alors que les facteurs cataboliques le diminuent. Le phénotype reste inchangé en présence du produit, sauf à haute dose où on augmente le ColI. L’activité des aggrécanases diminue puisque l’épitope NITEGE diminue alors que le CTX-II augmente dans l’articulation. Conclusion : En somme, les facteurs anaboliques du cartilage sont favorisés, alors que les facteurs cataboliques sont diminués par le GDF-5. Cette action double permet d’illustrer l’effet du GDF-5, le classant comme un potentiel médicament modifiant la maladie de l’OA qui mérite d’être étudiée. / Purpose: The objective of this study is to assess the effect of GDF-5 on cartilage homeostasis. GDF-5 is a susceptibility gene for OA and member of the BMP super family. Studies have shown that it can increase expression of anabolic factors in chondrocytes. Therefore, our study indentifies how GDF-5 influences this metabolism and the global homeostasis of chondrocytes, aiming mainly towards Aggrecan. Methods : Osteoarthritic (OA) chondrocytes from canine and human models were exposed to GDF-5. Protein expressions, along with mRNA expression were assessed in order to investigate Aggrecan production and the ratio of Col-II/Col-I, for the anabolic phenotype markers. The aggrecanases ADAMTS-4 and ADAMTS-5 and their global activity were assed for the catabolic factors. The NITEGE and CTX-II epitope were also measured in synovial fluid of Pond-Nuki dogs that received intraarticular GDF-5 injections. Results : GDF-5 increases chondrocyte cellular activity, in our canine and human models. Both mRNA and protein expression of the chondrocytes Aggrecan were increased and the aggrecanases expression and activity were decreased. Collagen ratio did not show a phenotype, except et high dosage where the Col-I production is induced. Aggrecanase activity was lowered while CTX-II was increased. Conclusion : In conclusion, the anabolic cellular activity of OA chondrocytes increases while the catabolic factors decrease in presence of GDF-5. This double action illustrates the global effect of GDF-5, identifying it as a potential disease modifying factor of OA that should be further investigated.

Arthrose (OA)

Chondrocytes

Aggrecan

GDF-5

ADAMTS-4

ADAMTS-5

Pond-Nuki

NITEGE

CTX-II

Osteoarthritis (OA)

Aggrecanase

Chondrodysplasia-Like Dwarfism in the Miniature Horse

Eberth, John E

01 January 2013

Dwarfism is considered one of the most recognized congenital defects of animals and humans and can be hereditary or sporadic in cause and expression. There are two general morphologic categories within this vastly diverse disease. These categories are disproportionate and proportionate dwarfism and within each of these there are numerous phenotypes which have been extensively described in humans, and to a lesser extent in dogs, cattle, mice, chickens, and other domestic species. Ponies and Miniature horses largely differ from full size horses only by their stature. Ponies are often defined as those whose height is not greater than 14.2 hands; however the maximum height for Miniature horses is constitutionally defined as 8.2 hands. Dwarfism is not considered a desirable genetic trait for Miniature horses. A majority of these conformationally inferior horses showed consistent physical abnormalities typical of disproportionate dwarfisms as seen in other mammal species. A whole genome scan with the Illumina Equine SNP50 chip clearly implicated a region on ECA1 as being associated with dwarfism of horses. The region implicated on the horse chromosome 1 (Equus Caballus; ECA1) contained a candidate gene for dwarfism, aggrecan (ACAN). Mutations were found in Exons 2, 6, 11 and 15 with each mutation associated with a distinct type of dwarfism. These mutations are independently transmitted throughout the population. Absence of normal homozygotes for these mutations and absence of normal horses which were heterozygous for these mutations indicated that these alleles caused dwarfism in those genotypes. These genotypes did not explain all observed dwarves in this population.

Dwarfism

Aggrecan

Equus Caballus

Miniature Horse

Genetics

Animal Diseases

Animal Structures

Large or Food Animal and Equine Medicine

Musculoskeletal System

Veterinary Anatomy

The effect of electric fields on hyaline cartilage: an in vitro and in silico study

Vaca González, Juan Jairo

02 May 2019

Tesis por compendio / [ES] El cartílago hialino es un tejido conectivo denso con poca capacidad de auto regeneración cuando es afectado por patologías degenerativas. Por lo tanto, la estimulación eléctrica se ha propuesto como una terapia alternativa no invasiva para mejorar la reparación del cartílago hialino. De acuerdo con esto, este trabajo presenta un enfoque computacional y experimental combinado para entender mejor la biología del cartílago hialino y su respuesta a la estimulación eléctrica usando diferentes modelos in vitro. En primer lugar, se ha desarrollado un modelo mecanobiológico para simular el proceso de osificación endocondral. Por otro lado, se ha evaluado el efecto de la estimulación eléctrica sobre el cartílago hialino en tres escenarios diferentes. Inicialmente se ha analizado la proliferación celular y la síntesis de glicosaminoglicanos de condrocitos cultivados en monocapa y estimulados con campos eléctricos. Luego, se ha realizado un análisis histomorfométrico a explantes de condroepífisis que fueron estimulados eléctricamente. Por último, se ha evaluado el efecto de los campos eléctricos sobre la diferenciación condrogénica de células madre mesenquimales cultivadas en hidrogeles. Los resultados indican que la estimulación eléctrica es un estímulo biofísico prometedor, ya que este tipo de estimulación mejora la viabilidad y la proliferación celular, induce cambios morfológicos en los condrocitos, y estimula la síntesis de las principales moléculas que componen el cartílago hialino, tales como SOX-9, glicosaminoglicanos y agrecan. Además, este proyecto es el primer paso hacia la implementación de un estímulo biofísico alternativo que modifica la dinámica celular de los condrocitos de la placa de crecimiento en condiciones ex vivo. Adicionalmente, este estudio resalta el efecto potencial de los campos eléctricos para inducir el proceso de condrogénesis de células madre mesenquimales cultivadas en condiciones basales. En general, la evaluación de la estimulación eléctrica sobre condrocitos, tejidos y andamios es una herramienta útil que puede contribuir al conocimiento actual de las terapias regenerativas enfocadas en la regeneración del cartílago hialino. / [CA] El cartílag hialí és un teixit connectiu dens amb poca capacitat d'auto regeneració quan es veu afectat per patologies degeneratives. Per tant, l'estimulació elèctrica s'ha proposat com una teràpia alternativa no invasiva per millorar la reparació del cartílag articular. D'acord amb això, aquest treball presenta un enfoc computacional i experimental combinat per entendre millor la biologia del cartílag hialí i la seva resposta a l'estimulació elèctrica usant diferents models in vitro. En primer lloc, s'ha desenvolupat un model mecanobiològic per simular el procés d'ossificació endocondral. D'altra banda, s'ha avaluat l'efecte de l'estimulació elèctrica sobre el cartílag hialí en tres escenaris diferents. Inicialment s'ha analitzat la proliferació cel·lular i la síntesi de glicosaminoglicans de condròcits cultivats en monocapa i estimulats amb camps elèctrics. Després, s'ha realitzat una anàlisi histomorfomètrica a explants de condroepífisis que van ser estimulats elèctricament. Finalment, s'ha avaluat l'efecte dels camps elèctrics sobre la diferenciació condrogénica de cèl·lules mare mesenquimals cultivades en hidrogels. Els resultats indiquen que l'estimulació elèctrica és un estímul biofîsic prometedor, ja que aquest tipus d'estimulació millora la viabilitat i la proliferació cel·lular, indueix canvis morfològics en els condròcits, i estimula la síntesi de les principals molècules que componen el cartílag hialí, com ara SOX-9, glicosaminoglicans i agrecan. A més, aquest projecte és el primer pas cap a la implementació d'un estímul biofísic alternatiu que modifica la dinàmica cel·lular dels condròcits de la placa de creixement en condicions ex vivo. Addicionalment, aquest estudi ressalta l'efecte potencial dels camps elèctrics per induir el procés de condrogènesi de cèl·lules mare mesenquimals cultivades en condicions basals. En general, l'avaluació de l'estimulació elèctrica sobre condròcits, teixits i scaffolds és una eina útil que pot contribuir al coneixement actual de les teràpies regeneratives enfocades a la regeneració del cartílag hialí. / [EN] Hyaline cartilage is a dense connective tissue with low self-healing capacity when is affected by degenerative pathologies. Therefore, electrical stimulation has been proposed as a possible non-invasive alternative therapy to enhance the restoration of the cartilaginous tissue. Accordingly, this work presents a combined computational and experimental approach to understand better the hyaline cartilage biology and its response to electrical stimulation using different in vitro models. On the one hand, a mechanobiological model was developed to simulate the endochondral ossification process. On the other hand, the electrical stimulation on hyaline cartilage was evaluated in three different scenarios. Initially, cell proliferation and glycosaminoglycans synthesis of chondrocytes, cultured in monolayer and stimulated with electric fields, was analyzed. Then, a histomorphometric analysis was performed to chondroepiphysis explants that were electrically stimulated. Finally, the effects of the electric fields on chondrogenic differentiation of mesenchymal stem cells cultured in hydrogels was assessed. The results indicated that electrical stimulation is a promising biophysical stimulus, due to the fact that this type of stimulation enhances the viability and the proliferation of cells, induces morphological changes in the chondrocytes, and stimulates the synthesis of the main molecules that compose the hyaline cartilage, such as SOX-9, glycosaminoglycans and aggrecan. Moreover, this project is the first step towards the implementation of an alternative biophysical stimulus that modifies the cellular dynamics of growth plate chondrocytes in ex vivo conditions. Additionally, this study highlights the potential effect of electric fields to induce the chondrogenesis process of mesenchymal stem cells cultured in basal conditions. Overall, the assessment of electrical stimulation on chondrocytes, tissues and scaffolds is a useful tool that may contribute to the current knowledge of regenerative therapies focused on hyaline cartilage healing. / To the financial support from COLCIENCIAS – COLFUTURO through the fellowship No. 647 for national doctorates. To the financial support from COLCIENCIAS through the research grant 712-2015 No. 50457. To the financial support from the Spanish Ministry of Economy and Competitiveness through the MAT2016-76039-C4-1-R project. / Vaca González, JJ. (2019). The effect of electric fields on hyaline cartilage: an in vitro and in silico study [Tesis doctoral]. Universitat Politècnica de València. https://doi.org/10.4995/Thesis/10251/120023 / TESIS / Compendio

Hyaline cartilage

Articular cartilage

Growth plate

Chondrocyte

Electric Field

Hydrogel

Hyaluronic acid

Gelatin

Glycosaminoglycan

Aggrecan

Sox9

Collagen type II

MAQUINAS Y MOTORES TERMICOS

The Use of Biopolymers for Tissue Engineering

Nelda Vazquez-Portalatin (7424441)

17 October 2019

<p>Osteoarthritis (OA) is a degenerative joint disease characterized by cartilage damage and loss in the joints that affects approximately 27 million adults in the US. Tissue that is damaged by OA is a major health concern since cartilage tissue has a limited ability to self-repair due to the lack of vasculature in cartilage and low cell content. Tissue engineering efforts aim towards the development of cartilage repair strategies that mimic articular cartilage and are able to halt the progression of the disease as well as restore cartilage to its normal function.</p><p>This study harnesses the biological activity of collagen type II, present in articular cartilage, and the superior mechanical properties of collagen type I by characterizing gels made of collagen type I and II blends (1:0, 3:1, 1:1, 1:3, and 0:1). The collagen blend hydrogels were able to incorporate both types of collagen and retain chondroitin sulfate (CS) and hyaluronic acid (HA). Cryoscanning electron microscopy images showed that the 3:1 ratio of collagen type I to type II gels had a lower void space percentage (36.4%) than the 1:1 gels (46.5%) and the complex modulus was larger for the 3:1 gels (G*=5.0 Pa) compared to the 1:1 gels (G*=1.2 Pa). The 3:1 blend consistently formed gels with superior mechanical properties compared to the other blends and has the potential to be implemented as a scaffold for articular cartilage engineering.</p> <p>Following the work done to characterize the collagen scaffolds, we studied whether an aggrecan mimic, CS-GAHb, composed of CS and HA binding peptides, GAH, and not its separate components, is able to prevent glycosaminoglycan (GAG) and collagen release when incorporated into chondrocyte-embedded collagen gels. Bovine chondrocytes were cultured and embedded in collagen type I scaffolds with CS, GAH, CS and GAH, or CS-GAHb molecules. Gels composed of 3:1 collagen type I and II with CS or CS-GAHb were also studied. The results obtained showed CS-GAHb is able to decrease GAG and collagen release and increase GAG retention in the gels. CS-GAHb also stimulated cytokine production during the initial days of scaffold culture. However, the addition of CS-GAHb into the chondrocyte-embedded collagen scaffolds did not affect ECM protein expression in the gels. The incorporation of collagen type II into the collagen type I scaffolds did not significantly affect GAG and cytokine production and ECM protein synthesis, but did increase collagen release. The results suggest the complex interaction between CS-GAHb, the chondrocytes, and the gel matrix make these scaffolds promising constructs for articular cartilage repair.</p> <p>Finally, we used Dunkin Hartley guinea pigs, a commonly used animal model of osteoarthritis, to determine if high frequency ultrasound can ensure intra-articular injections of the aggrecan mimic are accurately positioned in the knee joint. A high-resolution small animal ultrasound system with a 40 MHz transducer was used for image-guided injections. We assessed our ability to visualize important anatomical landmarks, the needle, and anatomical changes due to the injection. From the ultrasound images, we were able to visualize clearly the movement of anatomical landmarks in 75% of the injections. The majority of these showed separation of the fat pad (67.1%), suggesting the injections were correctly delivered in the joint space. The results demonstrate this image-guided technique can be used to visualize the location of an intra-articular injection in the joints of guinea pigs and we are able to effectively inject the aggrecan mimic into knee joints.</p><p>All of the work presented here suggests that the addition of the aggrecan mimic to collagen I and collagen I and II scaffolds has shown that this type of construct could be useful for treating cartilage damage in the future.</p>

Biochemistry

Organic Chemistry

Biological Engineering

articular cartilage

tissue engineering

collagen

chondroitin sulfate

osteoarthritis

chondrocytes

hydrogels

aggrecan

ultrasound

intra-articular injections

elastin