The effects of bleomycin, mitomycin C, and cytoskeletal-disrupting drugs on angiogenesis in vitro and haemangioma development in vivo

Mabeta, Peaceful Lucy

22 January 2009

Angiogenesis, the process of new vessel formation, appears to be a central mechanism that underlies the development of haemangiomas. Recently, intralesional bleomycin injection was used to treat paediatric haemangiomas with very good results. The purpose of this study was to determine whether there was significant systemic circulatory spill-over of bleomycin in haemangioma patients treated with intralesional bleomycin to determine safety of use. Furthermore, in order to elucidate bleomycin’s mechanism of action in inducing haemangioma regression, this study aimed at determining the effects of bleomycin on aspects of angiogenesis, namely, endothelial cell migration, growth and apoptosis, and comparing these effects with those of drugs previously reported to inhibit various aspects of the angiogenic process (mitomycin C, 2-methoxyestradiol, taxol, vincristine, vinblastine, colchicine, nocodazole and cytochalasin D). Lastly, the effects of bleomycin, mitomycin C, 2-methoxyestradiol, taxol, vincristine, vinblastine, colchicine, nocodazole and cytochalasin D were studied in an animal haemangioma model. A rapid and highly sensitive high performance liquid chromatographic (HPLC) method was developed. Blood samples were collected from four haemangioma patients before and after (over a 24 hour period) intralesional bleomycin (IB) therapy. As a control, blood samples were also collected at identical time intervals from four patients undergoing intravenous (IV) bleomycin chemotherapy for various malignant tumours. The HPLC method was used to quantitate bleomycin fractions in patient samples. The mean bleomycin concentration detected in plasma samples obtained from IB treated patients was 0.00 ìg/ml for both bleomycin A<Sub>2 and B2 over the 24-hour period following therapy. Plasma bleomycin A2 and B2 levels of 360.79 and 158.85 ìg/ml respectively were detected in samples obtained from cancer patients treated with bleomycin IV. These findings indicate that the low levels detected may translate to a significantly lesser risk of pulmonary fibrosis following IBI. The effect of drugs on endothelial cell migration was analyzed by wounding a confluent monolayer of cells and determining the number of cells that had migrated from the wound edge. Endothelial cell growth was determined in cells treated with various drug concentrations while apoptosis was examined using hematoxylin and eosin staining, DNA fragmentation assay and acridine orange staining. The effect of test drugs on in vitro angiogenesis was determined on endothelial cells induced to form capillary-like tubes in collagen gel. Test drugs were then evaluated for antitumour activity in an animal haemangioma model. Data demonstrated that test drugs inhibited endothelial cell migration, with the exception of mitomycin C. All test drugs induced a reduction in the percentage of viable endothelial cell in a dose-dependant manner, and also induced endothelial cell apoptosis. The drugs inhibited angiogenesis in vitro and inhibited tumour development in vivo with varying potency. In general, results from this study indicated that there was negligible systemic spill-over of bleomycin following IB administration in patients with haemangiomas, suggesting a much lesser risk of developing bleomycin-induced pulmonary fibrosis. This study also showed that test drugs inhibited angiogenesis in vitro and haemangioma development in vivo in a mouse model. Taken together, these observations demonstrate that bleomycin may inhibit haemangioma growth by inhibiting angiogenesis. In addition, mitomycin C, 2-methoxyestradiol, taxol, vincristine, vinblastine, colchicine, nocodazole and cytochalasin D may have potential in the treatment of haemangiomas of infancy, and should be investigated further in a murine haemangioma model to determine effective dose schedules. / Thesis (PhD)--University of Pretoria, 2009. / Physiology / unrestricted

Cell growth

Angiogenesis

Cell migration

Basic fibroblast growth factor

Polyoma middle t oncogene

Vascular endothelial growth factor

Cytoskeletal-disrupting agents

Vascular tumour

Haemangioma

Bleomycin

Haemangioma

Endothelial cells

UCTD

Collagen XIII as a neuromuscular synapse organizer:roles of collagen XIII and its transmembrane form, and effects of shedding and overexpression in the neuromuscular system in mouse models

Härönen, H. (Heli)

02 January 2018

Abstract Collagen XIII is a transmembrane protein consisting of intracellular, transmembrane and extracellular domains. The latter can be cleaved by proteases of the furin family at the plasma membrane and in the trans-Golgi network. Both the transmembrane and shed collagen XIII are expressed at the neuromuscular junctions of mice and humans. Such motor synapse passes the contraction signal from the central nervous system to the muscles and brings about all voluntary movements. Loss of both forms of collagen XIII in mice and loss-of-function mutations in the COL13A1 gene in humans leads to congenital myasthenic syndrome characterized by decreased neuromuscular transmission and muscle weakness. To study the roles of the two collagen XIII forms, a novel mouse line was engineered to harbor only the transmembrane collagen XIII by mutating the furin cleavage site. Transmembrane collagen XIII was discovered to be sufficient to prevent adhesion defects, Schwann cell invagination, the ineffective vesicle accumulation and dispersion of both acetylcholinesterase and acetylcholine receptors, phenotypes seen in the complete lack of collagen XIII. On the other hand, lack of shedding led to acetylcholine receptor fragmentation, aberrantly increased neurotransmission and presynaptic complexity. Remarkably, in vivo and in vitro interaction of collagen XIII and acetylcholinesterase-anchoring ColQ was detected. Furthermore, muscle and neuromuscular junction phenotype in the lack of both forms of collagen XIII closely resembled those in the human patients harboring mutations in the COL13A1 gene and these mice were validated as a good model for studying the human disease. Misexpression of collagen XIII was studied with mice exhibiting transgenic overexpression of the protein. Overexpression of collagen XIII was detected to be mostly extrasynaptic in the muscles of such mice. Exogenous collagen XIII was found at the myotendinous junctions, tenocytes and fibroblast-like cells, in addition to some localization in the near vicinity of the neuromuscular junctions. Collagen XIII expression was found, for the most part, to be normal at the neuromuscular junctions, although some were devoid of collagen XIII. The neuromuscular junction phenotype resembled in many ways the findings made in the lack of collagen XIII. Furthermore, acetylcholine receptor and nerve pattern was discovered to be widened. / Tiivistelmä Kollageeni XIII on solukalvoproteiini, jonka rakenne koostuu solunsisäisestä, solukalvon läpäisevästä ja solun ulkoisesta osasta, joka pystytään entsymaattisesti irrottamaan solukalvoilta. Täten se esiintyy kahdessa eri muodossaan; solukalvomuotoisena ja soluvälitilan lihasperäisenä proteiinina hiirten ja ihmisten hermolihasliitoksessa. Tässä motorisessa synapsissa keskushermostosta peräisin oleva lihaksen supistumiskäsky välittyy lihakseen ja aikaan saa tahdonalaiset liikkeet. Molempien kollageeni XIII:n muotojen puute hiirillä ja COL13A1 geenin mutaatiot ihmisillä johtavat synnynnäiseen myasteeniseen oireyhtymään, jossa heikentynyt hermolihasliitoksen toiminta johtaa lihasheikkouteen. Kollageeni XIII:n eri muotojen hermolihasliitosvaikutusten selvittämiseksi luotiin hiirilinja, jossa kollageeni XIII ilmenee geneettisen manipulaation seurauksena ainoastaan solukalvomuodossaan. Tutkimukset osoittivat solukalvomuotoisen kollageeni XIII:n tarvittavan hermon ja lihaksen kiinnittymiseen toisiinsa, hermovälittäjäainerakkuloiden ankkuroimiseen hermopäätteeseen, estämään Schwannin solujen tunkeutuminen synapsirakoon, asetyylikoliiniesteraasin sitomiseen ja asetyylikoliinireseptorien vakaantumiseen. Soluvälitilan kollageeni XIII:n puutos puolestaan johti lihaksen puolen liitoksen pirstaloitumiseen sekä hermopäätteiden liialliseen kasvuun ja aktiivisuuteen. Kollageeni XIII todettiin sitoutuvan asetyylikoliiniesteraasia hermolihasliitokseen ankkuroivan kollageeni Q:n kanssa. Lisäksi molempien kollageeni XIII:n muotojen suhteen poistogeenisten hiirten hermolihas- ja lihaslöydökset todettiin muistuttavan COL13A1 geenin mutaatioista kärsivien ihmisten vastaavia löydöksiä todistaen nämä hiiret hyväksi tautimalliksi tulevaisuuden hoitomuotojen suunnitteluun. Kollageeni XIII:n ylimäärän vaikutusta hermolihasliitokseen ja lihaskudokseen tutkittiin kollageeni XIII:a ylenmäärin ilmentävillä hiirillä. Kollageeni XIII todettiin ilmentyvän ylenmäärin lihaksessa fibroblastinkaltaisissa soluissa, lihasjänneliitoksessa ja hermolihasliitoksen lähettyvillä, mutta ei hermolihasliitoksessa. Osa hermolihasliitoksista näissä hiirissä ilmensi jopa vähemmän kollageeni XIII:a kuin normaalisti. Asetyylikoliinireseptorien ja hermojen valtaama alue todettiin leventyneeksi ja hermolihasliitoslöydökset muistuttivat molempien kollageeni XIII:n muotojen suhteen poistogeenisien hiirten löydöksiä.

ColQ

acetylcholine receptor

acetylcholinesterase

collagen XIII

congenital myasthenic syndrome

fibroblast

myotendinous junction

neuromuscular junction

asetyylikoliiniesteraasi

asetyylikoliinireseptori

fibroblasti

hermolihasliitos

kollageeni Q

kollageeni XIII

lihasheikkous

lihasjänneliitos

synnynnäinen myasteeninen oireyhtymä

Le fibroblaste gingival : une cellule à potentiel thérapeutique pour l’anévrisme aortique / Gingival fibroblast : a possible therapeutic cell for aortic aneurysm

Cherifi, Hafida

25 November 2014

Introduction.Le fibroblaste gingival (FG) est la cellule majoritaire de la gencive. Cette dernière fait face constamment aux agressions physico-chimiques, infectieuses et thermiques. L'une des caractéristiques de la gencive est sa réparation quasi-parfaite suite à une lésion ponctuelle. Ce n'est pas le cas pour d'autres tissus comme la paroi aortique. L'anévrisme aortique (AA) est un affaiblissement de la paroi aortique provoqué par une sécrétion exhaustive de métalloprotéases (MMPs) et en particulier de MMP-9. Il en résulte une dilatation de l'artère. Dans un modèle d'anévrisme de lapin, Durand et al (2012) avait montré que le FG pouvait ralentir, voire réparer un anévrisme. Dans notre étude, nous avons mis en place un modèle de coculture FG/AA d'origine humaine.Chez l'homme, la localisation de la pathologie peut être au niveau abdominal (Anévrisme Aortique Abdominale : AAA) ou thoracique (Anévrisme Aortique Thoracique : AAT). Etant donné que leur étiologie sont différentes, nous avons souhaité savoir s'il existait des différences selon les lésions. Cela nous permettrait en effet de mieux appréhender la prise en charge. Nous avons réalisé une étude comparative histo et physiopathologique entre les AAA et AAT. L'une des différences soulevée, est la présence d'un facteur infectieux au niveau des AAA. C'est un élément à prendre en compte pour une thérapie cellulaire et ainsi nous avons mis en culture des FG en présence de LPS, une endotoxine bactérienne.De plus pour approfondir notre travail sur l'utilisation du FG dans la thérapie cellulaire, nous avons initié une étude sur la plasticité de la sous-population souche des FG en étudiant, notamment leur orientation en cellules vasculaires (cellules endothéliales).Résultats/discussionLe FG, grâce à sa secrétion de TIMP-1, contribue à l'inhibition de la MMP-9 anévrismale. La sécrétion de MMP-9 est plus importante dans les lésions avec athérome (AAA) que celles sans athérome (AAT dans notre étude). Ceci est en corrélation avec la dégradation qui est plus importante dans les AAA que dans les AAT. La MMP-9 est une protéine sécrétée entre autre par les cellules inflammatoires. Une inflammation est présente dans les AAA et pas dans les lésions thoraciques. Ceci pourrait expliquer la différence de sécrétion de MMP-9 et donc de dégradation. Concernant l'origine de cette inflammation, nous avons recherché une cause infectieuse. Porphyromonas gingivalis (Pg) qui est une bactérie importante dans le développement de la parodontite (maladie inflammatoire des tissus de soutien de la dent) a été détectée dans les AAA. Une relation pathologique existerait entre la parodontite et l'AAA mais l'étude devrait être plus poussée pour connaître le mécanisme physiopathologique de ce phénomène. Toutefois, en ce qui concerne la thérapie cellulaire, le LPS qui est une endotoxine du Pg, n'affecte pas la capacité du FG à secréter du TIMP-1.En plus de la possibilité du FG à neutraliser la MMP-9 anévrismale, nous avons souhaité savoir si le FG avait des compétences de différentiation en cellule vasculaire. Un début d'exploration de la plasticité cellulaire de la souche multipotente de FG en cellule endothéliale, donnent des résultats préliminaires encourageants.Conclusion. Le FG pourrait être une cellule prometteuse pour une thérapie cellulaire de l'anévrisme aortique mais des explorations plus poussées sont encore nécessaires pour une telle application. / IntroductionGingival fibroblast (GF) is the main cell in gingiva which is constantly facing infectious, thermal and physico-chemical attacks. When a lesion occurs, the repair of gingiva is almost perfect. It is not the case for other tissues as the aortic wall. The aortic aneurysm (AA) is a pathologic expansion of aorta due to a weakening of the wall with an exhaustive secretion of metalloproteinases (MMPs) and particularly of MMP-9. In an aneurysm rabbit model, Durand and al (2012) have showed that GF could slow down or repair the aneurysm. In our study, we have established a co-culture model of human GF and human AA.For human, the location of the aortic disease may be at abdominal level (Abdominal Aortic Aneurysm: AAA) and thoracic level (Thoracic Aortic Aneurysm: TAA). Since the aetiologies are different, we wondered if histo and physiopathologic differences would existe between the both. It is impotant to know that for better supporting the disease. One of the difference between AAA and TAA is the presence of an infectious factor in AAA. This is an element to consider for cell therapy, so we studied the behavior of GF in presence of an endotoxin, the LPS.In addition, to further our work on the use of GF in cell therapy, we have initiated a study of the plasticity of the GF multipotente subpopulation including the differentiation into vascular cells (endothelial cell in particular).Results/DiscussionThanks to its TIMP-1 secretion, GF could contribute to the inhibition of MMP-9 activity in aneurysm. The secretion of MMP-9 in AA with atheroma (AAA) is highter than in TAA (without atheroma in our study). It is correlated to the degradation of AAA which is more important than the degradation of TAA. Inflammatory cells may secrete MMP-9. Inflammation is present in AAA and not in TAA. This, could explain the highter secretion of MMP-9 in abdominal lesion and also the degradation which is more important in AAA than in TAA. As for the origin of this inflammation, we researched an infectious factor. We isolated Porphyromonas gingivalis (Pg) in AAA, which might trigger or aggravate inflammation. This is an important bacterium in the development of periodontitis (inflammatory disease of the tissues supporting the tooth). A pathological relationship may exist between periodontitis and the AAA. The study should be further to know the pathophysiology of AAA related to Pg. But as regards the cell therapy, LPS, which is an endotoxin of Pg would not affect the secretion of TIMP-1 by the GF.In addition to its abilities to inhibate MMP-9 in aneurysm, we wondered if GF would be able to differentiate into vascular cell. An early exploration of GF multipotent subpopulation plasticity reveals a possible opportunity to go further in a the cell therapy.Conclusion.GF might be a promising cell for treating aortic aneurysm but further explorations are still necessary for its application.

Fibroblaste gingival

Anévrisme aortique

Thérapie cellulaire

Mmp-9

Porphyromonas gingivalis

Stem cell

Gingival fibroblast

Aortic aneurysm

Cell therapy

Mmp-9

Porphyromonas gingivalis

Stem cell

610

Clonagem e expressão de &#946-ficocianina em amostras de Escherichia coli. / Cloning and expression of &#946-phycocyanin in Escherichia coli strains.

Tatiane Marques Porangaba de Oliveira

20 April 2010

C-ficocianina (C-PC) é um pigmento solúvel em água e está presente em Arthrospira platensis. Este pigmento é constituído por duas subunidades, &#945 e &#946, com massas moleculares de 16 e 17 kDa, respectivamente. Recentemente foi demonstrado que a subunidade &#946 da C-PC de Anabaena tem atividade antitumoral. Os principais objetivos deste estudo foram clonar e expressar a subunidade &#946 de C-PC de A. platensis em amostras de Escherichia coli e verificar a capacidade da proteína recombinante e da proteína C-PC em induzir ou não apoptose em células tumorais (HEp-2) e não tumorais (fibroblastos). As células foram tratadas com 100 µg das proteínas recombinante e C-PC por 6 h. Após tratamento, as células foram coradas com azul de toluidina (Metódo: Concentração Crítica de Eletrólitos - CCE). As células em apoptose foram detectadas pela coloração e por alterações morfológicas. Os resultados obtidos demonstram que ambas as proteínas, &#946-PC recombinante e C-PC, são capazes de induzir apotose em células HEp-2 e não induzi-la em células fibroblásticas. / C-phycocyanin (C-PC) is a water soluble pigment and is present in Arthrospira platensis. It is consisted of two subunits, &#945 and &#946, with molecular masses of 16 and 17 kDa, respectively. Recently it was shown that the &#946 subunit of C-PC Anabaena has antitumor activity. The main objectives of this study were cloning and expression the &#946 subunit of C-PC (&#946-PC) of A. platensis in Escherichia coli and check the ability of the C-PC and recombinant proteins in apoptotic induction in cancer (HEp-2) and non-cancer (fibroblasts) cells. The fibroblasts and HEp-2 cells were treated with 100 µg of recombinant and C-PC, proteins respectively for 6 h. After treatment, the cells were stained with toluidine blue (Critical Electrolyte Concentration Method - CEC). Apoptosis cells were detected by staining and morphological changes. The results show that the recombinant &#946-PC and C-PC proteins are able to induce apotosis in HEp-2 cells and dont induce it in fibroblasts cells.

Arthrospira platensis

Escherichia coli

Apoptose

Biotecnologia

Clonagem

Expressão gênica

Fibroblastos

Ficocianina

Arthrospira platensis

Escherichia coli

Apoptosis

Biotechnology

Cloning

Fibroblast

Gene expression

Phycocyanin

Regulation of Zebrafish Hindbrain Development by Fibroblast Growth Factor and Retinoic Acid: A Dissertation

Roy, Nicole Marie

01 October 2003

Fibroblast growth factor (Fgf) and Retinoic acid (RA) are known to be involved in patterning the posterior embryo. Work has shown that Fgf can convert anterior tissue into posterior fates and that embryos deficient in Fgf signaling lack posterior trunk and tail structures. Likewise, studies performed on RA have shown that overexpression of RA posteriorizes anterior tissue, while disrupting RA signaling yields a loss of posterior fates. While it appears these signals are necessary for posterior development, the role Fgf and RA play in development of the hindbrain is still enigmatic. A detailed study of the requirements for Fgf and RA in the early vertebrate hindbrain are lacking, namely due to a deficiency in gene markers for the presumptive hindbrain at early developmental stages. In this study, we make use of recently isolated genes, which are expressed in the presumptive hindbrain region at early developmental stages, to explore Fgf and RA regulation of the early vertebrate hindprain. We employed both overexpression and loss of function approaches to explore the role of Fgf in early vertebrate development with an emphasis on the presumptive hindbrain region in zebrafish embryos. By loss of function analysis, we show that Fgf regulates genes expressed exclusively in the hindbrain region (meis3 and hoxbla) as well as genes whose expression domains encompass both the hindbrain and more caudal regions (nlz and hoxb1b), thus demonstrating a requirement for Fgf signaling throughout the anteroposterior axis of the hindbrain (rostral to caudal hindbrain) by mid-gastrula stages. To further characterize early gene regulation by Fgf, we utilized an in vitro system and found that Fgf is sufficient to induce nlz directly and hoxb1b indirectly, while it does not induce meis3 or hoxb1a. Furthermore, in vivo work demonstrates that Fgf soaked beads can induce nlz and hoxb1b adjacent to the bead and meis3at a distance. Given the regulation of these genes in vitro and in vivo by Fgf and their position along the rostrocaudal axis of the embryo, our results suggest an early acting Fgf resides in the caudal end of the embryo and signals at a distance to the hindbrain. We detect a similar regulation of hindbrain genes by RA at gastrula stages as well, suggesting that both factors are essential for early hindbrain development. Interestingly however, we find that the relationship between Fgf and RA is dynamic throughout development. Both signals are required at gastrula stages as disruption of either pathway alone disrupts hindbrain gene expression, but a simultaneous disruption of both pathways at later stages is required to disrupt the hindbrain. We suggest that Fgf and RA are present in limiting concentrations at gastrula stages, such that both factors are required for gene expression or that one factor is necessary for activation of the other. Our results also reveal a changing and dynamic relationship between Fgf and RA in the regulation of the zebrafish hindbrain, suggesting that at segmentation stages, Fgf and RA may no longer be limiting or that they are no longer interdependent. As we have demonstrated that an early Fgf signal is required for gastrula stage hindbrain development, we next questioned which Fgf performed this function. We have demonstrated that the early Fgf signal required for hindbrain development is not Fgf3 or Fgf8, two Fgfs known to be involved in signaling centers at the mid-hindbrain boundary (MHB) and rhombomere (r) 4. We further show that two recently identified Fgfs, Fgf4 and Fgf24 are also insufficient alone or in combination with other known Fgfs to regulate hindbrain gene expression. However, as Fgfs may act combinatorially, we do not rule out the possibility of their involvement in early hindbrain gene regulation. However, as time passes and additional Fgfs are isolated and cloned, the elusive Fgf signal required for early hindbrain development will likely be identified. Taken together, we propose that an early acting Fgf residing in the caudal end of the embryo regulates hindbrain genes together with RA at gastrula stages. We suggest that both Fgf and RA are required for gene expression at gastrula stages, but this requirements changes over time as Fgf and RA become redundant. We also demonstrate that the Fgf required for gastrula stage hindbrain development has yet to be identified.

Fibroblast Growth Factors

Gastrula

Gene Expression Regulation

Rhombencephalon

Tretinoin

Zebrafish

Animal Experimentation and Research

Biological Factors

Cells

Embryonic Structures

Genetic Phenomena

Nervous System

Organic Chemicals

Tissues

Úloha buněčného metabolismu v karcinogenezi. Molekulární patofyziologie chemorezistence karcinomu močového měchýře / The Role of Cellular Metabolism in Carcinogenesis. Molecular Pathophysiology of Bladder Cancer Chemoresistance

Kripnerová, Michaela

January 2019

Therapeutic resistance of tumours represents an important clinical issue. We can classify the therapeutic tumour resistance in two ways. According to the clinical course, tumours can behave either as primary resistant, i.e. from the very beginning not responsive, or they can display a secondary (also called acquired) resistance, whereby an initial clinical response is lost and the tumour develops into chemo-, radio- or immunoresistant disease. An alternative classification distinguishes cell autonomous resistance mechanisms from resistance that relies on complex interactions within the context of tumour microenvironment. From the research perspective, modelling therapeutic resistance frequently involves experimental treatment of sensitive cancer cells and selection of daughter resistant cell lines. The Ph.D. thesis includes derivation of two unique models of urothelial bladder carcinoma therapeutic resistance. The first model involves newly established urothelial carcinoma cell lines BC44 and BC44DoxoR, which resulted from a prolonged doxorubicin exposure of the mother cell line. The daughter chemoresistant cell line exhibits multidrug resistant phenotype, which extends beyond the selecting drug - doxorubicin - to four additional chemotherapeutic drugs (cisplatin, methotrexate, vinblastine, and...

Signaling mechanisms and developmental function of fibroblast growth factor receptors in zebrafish

Kolanczyk, Maria Elzbieta

11 May 2009

Fibroblast growth factor (Fgf) signaling plays multiple inductive roles during development of vertebrates (Itoh 2007). Some Fgfs, such as Fgf8, are locally secreted and signal over a long range to provide positional information in the target tissue (Scholpp and Brand 2004). Fgf ligands signal in a receptor-dependent manner via tyrosine kinase receptors, four of which have been so far identified. Fgf8 signaling was shown to depend both on receptor activation as well as endocytosis. The specificity of Fgf ligands and receptors as well as the function of receptors in the control of the Fgf signaling range have been, however, largely unclear. In this study, we show that the putative Fgf8 receptor Fgfr1 is duplicated in zebrafish and that it acts redundantly in the formation of the posterior mesoderm. Also, in overexpression studies we confirm the notion that receptor endocytosis influences Fgf8 signaling range. Through TILLING mutant recovery and morpholino knockdown studies we also show that Fgfr2 is required for growth and skeletal development in zebrafish, whereas Fgfr4 is required for pectoral fin specification and growth.

info:eu-repo/classification/ddc/570

ddc:570

Rôle de MTORC2 dans la sénescence et la différenciation myofibroblastique induites par l'autophagie

Bernard, Monique

05 1900

Il a été suggéré que l’autophagie pouvait participer au processus fibrotique en favorisant la différenciation du fibroblaste en myofibroblaste. La sénescence cellulaire a aussi été montrée comme impliquée dans la réparation tissulaire et la fibrose. Des liens ont été établis entre autophagie et sénescence. Cette étude a pour but d’investiguer les liens possibles entre autophagie, sénescence et différenciation myofibroblastique afin de mieux comprendre les mécanismes moléculaires régulant la réparation tissulaire et la fibrose. Les fibroblastes carencés en sérum pendant quatre jours montrent des ratios LC3B-II/-I élevés et des niveaux de SQSTM1/p62 diminués. L’augmentation de l’autophagie est accompagnée d’une augmentation de l’expression des marqueurs de différenciation myofibroblastique ACTA2/αSMA et collagènes de type 1 et 3 et de la formation de fibres de stress. Les fibroblastes autophagiques expriment les marqueurs de sénescence CDKN1A (p21) et p16INK4a (p16) et montrent une augmentation de l’activité beta-galactosidase associée à la sénescence. L’inhibition de l’autophagie à l’aide de différents inhibiteurs de phosphoinositide 3-kinase de classe I et de phosphatidylinositol 3-kinase de classe III (PtdIns3K) ou par inhibition génique à l’aide d’ARN interférant ATG7 bloquent l’expression des marqueurs de différenciation et de sénescence. L’expression et la sécrétion de CTGF (connective tissue growth factor) sont augmentées chez les fibroblastes autophagiques. L’inhibition de l’expression du CTGF par interférence génique prévient la différenciation myofibroblastique, démontrant l’importance de ce facteur pro-fibrotique pour la différenciation induite par l’autophagie. La phosphorylation de la kinase RPS6KB1/p70S6K, cible du complexe MTORC1, est abolie dans les fibroblastes autophagiques. La phosphorylation d’AKT à la Ser473, une cible du complexe MTORC2, diminue lors de la carence en sérum des fibroblastes mais est suivie d’une rephosphorylation après 2 jours. Ce résultat suggère la réactivation de MTORC2 lors d’une autophagie prolongée. Ceci a été vérifié par inhibition de l’autophagie dans les fibroblastes carencés en sérum. Les inhibiteurs de PtdIns3K et le siRNA ATG7 bloquent la rephosphorylation d’AKT. L’inhibition de la réactivation de MTORC2, et donc de la rephosphorylation d’AKT, est aussi obtenue par exposition des fibroblastes à la rapamycine, le Torin 1 ou par inhibition génique de RICTOR. Ces traitements inhibent l’augmentation de l’expression du CTGF ainsi que des marqueurs de différenciation et de sénescence, démontrant le rôle central joué par MTORC2 dans ces processus. Le stress oxydant peut induire la sénescence et la carence en sérum est connue pour augmenter la quantité de ROS (reactive oxygen species) dans les cellules. Afin d’investiguer le rôle des ROS dans la différenciation et la sénescence induites par l’autophagie, nous avons incubés les fibroblastes carencés en sérum en présence de N-acetyl-L-cysteine (NAC). Le NAC diminue la production de ROS, diminue les marqueurs d’autophagie, de sénescence et de différenciation myofibroblastique. Le NAC inhibe aussi la phosphorylation d’AKT Ser473. L’ensemble de ces résultats identifient les ROS en association avec une autophagie prolongée comme des nouveaux activateurs du complexe MTORC2. MTORC2 est central pour l’activation subséquente de la sénescence et de la différenciation myofibroblastique. / Recent evidence suggests that autophagy may favor fibrosis through enhanced differentiation of fibroblasts in myofibroblasts. Cellular senescence is also involved in tissue repair and fibrosis. Autophagy has been linked with senescence. This study focuses on understanding the molecular mechanisms linking autophagy, senescence and myofibroblast differentiation and the roles they could play in wound healing and fibrosis. Fibroblasts, serum starved for up to 4 days, showed increased LC3B-II/-I ratios and decreased SQSTM1/p62 levels. Autophagy was associated with acquisition of markers of myofibroblast differentiation including increased protein levels of ACTA2/αSMA (actin, α 2, smooth muscle, aorta), enhanced gene and protein levels of COL1A1 (collagen, type I, α 1) and COL3A1, and the formation of stress fibers. Autophagic fibroblasts showed expression of the senescence markers CDKN1A (p21) and p16INK4a (p16) and also exhibit increase in Senescence Associated-beta-galactosidase activity. Inhibiting autophagy with different class I phosphoinositide 3-kinase and class III phosphatidylinositol 3-kinase (PtdIns3K) inhibitors or through ATG7 silencing prevented myofibroblast differentiation and senescence markers expression. Autophagic fibroblasts showed increased expression and secretion of CTGF (connective tissue growth factor), and CTGF silencing prevented myofibroblast differentiation. Phosphorylation of the MTORC1 target RPS6KB1/p70S6K kinase was abolished in starved fibroblasts. Phosphorylation of AKT at Ser473, a MTORC2 target, was reduced after initiation of starvation but was followed by spontaneous rephosphorylation after 2 d of starvation, suggesting the reactivation of MTORC2 with sustained autophagy. Importantly, inhibition of autophagy with PtdIns3K inhibitors or ATG7 silencing blocked AKT rephosphorylation. Inhibiting MTORC2 activation with long-term exposure to rapamycin, Torin 1 or by silencing RICTOR, a central component of the MTORC2 complex, abolished AKT rephosphorylation. RICTOR silencing, Torin 1 and rapamycin treatments prevented CTGF and ACTA2 upregulation and induction of senescence markers demonstrating the central role of MTORC2 activation in CTGF and senescence induction for myofibroblast differentiation. Since oxidative stress is a known inducer of senescence, we investigated the role of reactive oxygen species (ROS) in autophagy-induced myofibroblast differentiation and senescence markers induction. Exposing fibroblasts to N-acetyl-L-cysteine (NAC) decreased production of ROS during serum starvation, inhibited autophagy and significantly decreased the expression of senescence and myofibroblast differentiation markers. NAC also inhibited the phosphorylation of AKT Ser473, establishing the importance of ROS in fuelling MTORC2 activation. Collectively, these results identify ROS production in association with sustained autophagy as novel inducers of MTORC2 signaling which in turn concomitantly activate senescence and myofibroblast differentiation.

Autophagie

CTGF

Différenciation

Fibroblaste

Fibrose

MTORC2

Myofibroblaste

Rapamycine

ROS

Sénescence

Autophagy

CTGF

Differentiation

Fibroblast

Fibrosis

MTORC2

Myofibroblast

Rapamycin

ROS

Senescence

Mast Cell Regulation of Cardiovascular Inflammation I: Cognate and Non-Cognate Interactions

Negi, Smita, Halawa, Ahmad, Chi, David S., Miller, Christopher, Hossler, Fred E., Youngberg, George, Johnson, David A., Krishnaswamy, Guha

01 January 2010

The paradigm shift in cardiovascular biology has been the understanding that atherosclerosis involves not just a mechanical deposition of lipids in the vessel wall, but a dynamic process involving the inflammatory response with cellular infiltration and inflammatory mediator expression. Typical cellular elements that have been studied include endothelial cells, vascular smooth muscle, T lymphocyte and the macrophage. Recent data suggests a role for the human mast cell. The human mast cell is a tissuedwelling cell, typically perivascular in distribution. This multifunctional cell responds rapidly to challenge with the release of inflammatory mediators that can orchestrate an immune response and may have relevance to atherogenesis. Mast cells have been shown to modulate various aspects of cardiovascular disease such as atherogenesis (endothelial activation, cytokine generation and foam cell formation) as well as rupture of an unstable atheromatous plaque. Mast cell activation in the context of cardiovascular disease may occurby cognate cell-cell interactions (interactions with macrophages, T cells, endothelial cells or smooth muscle) or by non-cognate means (such as lipoproteins and other proatherogenic components). More studies are required in order to better understand the molecular role of mast cells in vascular inflammatory disease.

arteriosclerosis

chemokines

coronary artery disease

cytokine

fibroblast

IgE

inflammation

macrophage

mast cell

receptors

signaling

smooth muscle

Biomedical Sciences

Internal Medicine

Pathology

A PILOT STUDY EXPLORING THE ROLE OF IRAP IN SENESCENT CELLS

Tawfik, Dalya

January 2020

Insulin regulated aminopeptidase (IRAP) was first identified in fat and muscle cells where it is believed to regulate GLUT4 translocation. It has since been found to be behind a variety of functions, many not yet fully understood. Preliminary research from Monash University suggested that IRAP may play a role in cellular senescence. Senescence is a term that describes arrested cell division and is a tumor repressive mechanism. Senescent cells have been shown to secrete, among other things, the growth hormone TGFβ1, which in turn plays an important role in the cell differentiation of fibroblasts to myofibroblasts. The potential link between IRAP and senescence was the basis of this work. Senescent fibroblasts from three different passages (n=3) in the BJ3 cell-line were cultured and treated with different IRAP inhibitors; ANG-4, AL06 and HFI-419 which were all compared to an untreated control group. They were marked with a β-galactosidase stain, a senescent cellmarker, and imaged. The study demonstrated that the IRAP inhibitors led to a certain decrease in % of senescent cells compared to the control groups. However, this reduction was not considered statistically significant. Similarly, inhibition of the enzyme did not indicate any influence over the differentiation of the cells. The lack of effect could be due to chance based on the low number of sample size, or the condition of the cells used in the trial as they were partially immortalized BJ fibroblasts well beyond the passage of their intended use. In order to further demonstrate an association between IRAP and senescence, further trials are required. / Insulin reglerad aminopeptidas (IRAP) introducerades till en början som ett markörprotein. Man har sedan dess funnit att den står bakom en rad olika funktioner, många ännu inte  fullt klarlagda. Preliminär forskning från laboratoriet i Monash University tydde på att IRAP kan ha en koppling till senescerande fibroblaster. Senescence är en term som beskriver upphörd celldelning och är en tumörrepressiv mekanism. Senescerande celler har påvisats utsekrera bland annat tillväxthormonet TGFβ1, som i sin tur spelar en viktig roll i celldifferentieringenav fibroblaster till myofibroblaster. Den potentiella kopplingen mellan IRAP och senescence låg som grund till detta arbete. Senescerande fibroblaster från tre olika kulturer (n=3) i BJ3-cellinjen odlades och behandlades med olika IRAP-inhibitorer; ANG-4, AL06 och HFI-419 som alla jämfördes med en kontrollgrupp. Därefter markerades de med en β-galaktosidas-markör, en markör för senescerande celler, och mikroskoperades. Studien påvisade att IRAP-inhibitorerna ledde till en viss procentuell minskning av senescerande celler jämfört med kontrollgrupperna. Dock bedömdes inte denna minskning som statistiskt signifikant i studien. Likväl fann man ingen procentuell minskning av differentierade fibroblaster. Hypotetiskt sett skulle man vilja se att reduktionen av senescerande celler motsvarade en nedreglering av TGFβ1-proteiner. Eftersom närvaron av TGFβ1 tros spela en ledande roll i celldifferentiering till myofibroblastfenotypen, bör den procentuella mängden differentierade cellerna minska med inhibitorbehandlingarna. Den bristande påverkan av enzyminhibitionen kan bero på en rad olika faktorer. Cellerna som användes under försökets gång var väl bortom deras brukliga användningscykel. För att vidare påvisa ett potentiellt samband mellan IRAP och senescence behöver vidare försök utföras.

Senescence

IRAP

BJ3

IRAP-inhibitors

fibroblast

ang-4

hfi-419

al0-6

TGF-β

Immunocytochemistry

physiology

pharmacology

b-galactosidase

phibrosis

Medical and Health Sciences

Medicin och hälsovetenskap

Physiology

Fysiologi