Your search keyword '"Aydınlı, Fatmagül İlayda"' showing total 4 results

1. Two phases of macrophages: Inducing maturation and death of oligodendrocytes in vitro co-culture

Author

Aydınlı, Fatmagül İlayda, primary, Er, Sezgin, additional, and Kerman, Bilal Ersen, additional

Published

2022

2. Myelin disorders and stem cells: As therapies and models

Author

Aydınlı, Fatmagül İlayda, Çelik, Eşref, Kurt Vatandaşlar, Burcu, and Kerman, Bilal Ersen

Subjects

Multiple Sclerosis, Myelin, Stem Cells, Induced Pluripotent Stem Cells, Subacute Sclerosing Panencephalitis, Pelizaeus–Merzbacher Disease, Adrenoleukodystrophy

Abstract

Myelin disorders burden millions of people around the world, yet existing therapies are inadequate to cure them. Current remedies commonly treat the symptoms with minimal to no effect on the actual cause of the disorder. The basis and/or the mechanism of demyelination is not known for many of the disorders either. In recent years, stem cells of variable origin have been used in clinical trials as transplant agents to restore the defective biochemical process or the damaged tissue. We summarize the outcomes of these trials for demyelination disorders. The capability of reprograming mature cells into stem cells equips researchers with a new tool to replicate disease phenotypes in cell culture dishes for basic research and therapeutic screens. The applications of in vitro myelination disorder models are also discussed. The combined outcome of the discussed studies offers a promising future as stem cell transplantation generally results in decreased symptoms and improved quality of life. However, the mechanism of action of the interventions is not known and in cases of negative outcomes the reasons are usually obscure. Further basic science studies along with clinical interventions should close the knowledge gap and should help spread the positive results to a larger population.

Published

2016

3. Oligodendrocyte interactome in healthy and diseased nervous system.

Author

Kerman, Bilal Ersen, Aydınlı, Fatmagül İlayda, Vatandaşlar, Burcu Kurt, Yurduseven, Kübra, Vatandaşlar, Emre, Çelik, Eşref, Yetiş, Sibel Çimen, Çapar, Abdulkerim, Aladağ, Zeynep, Ekinci, Dursun Ali, Ayten, Umut Engin, Töreyin, Behçet Uğur, and Kurnaz, Işıl Aksan

Subjects

*NEUROLOGICAL disorders, *OLIGODENDROGLIA, *MYELIN proteins, *NERVOUS system, *DEMYELINATION, *MYELIN, *MULTIPLE sclerosis

Abstract

Objective: Myelin is essential for a healthy nervous system. Myelin formed by oligodendrocytes, accelerates impulse propagation and supports neuronal survival. Demyelination leads to neurodegeneration. In multiple sclerosis (MS) immune attack results in demyelination. Our goal is to dissect interactions among oligodendrocytes, neurons, and immune cells to improve our understanding of myelination and the demyelinating diseases. We aim to discover new targets for remyelination therapies. Methods: We are building tools for analyzing protein-protein and cell-to-cell interactions. To identify genes involved in myelination and MS, we developed a bioinformatics-based strategy, interactome analysis, which combines proteome and gene expression methodologies. Identified genes are evaluated in peripheral blood of MS patients and in mouse models. To accelerate drug discovery, 23 machine learning-based methodologies were assessed for myelin identification in fluorescent microscopy images. Results: Interactome analysis identified hundreds of proteinprotein interactions between pairs of oligodendrocytes, neurons, macrophages, microglia, and T cells. Most significant interactions are further analyzed in vivo and in vitro. Our customizedconvolutional neural network and Boosted Tree methods segmented myelin at over 98% accuracy. Identified myelin can be quantified and visualized in 3D. Conclusion: The interactome analysis yielded novel genes that are likely to be linked to MS. Machine learning-based methodologies are very effective in accelerating myelin quantification and thus, drug screens against demyelinating diseases such as MS. Overall, our innovative analysis strategies employing computer assistance produced novel avenues of exploration for myelination and demyelinating diseases. This study was supported TUBITAK (218S495,316S026), Istanbul Medipol University (BAP2018/06), and Turkish Academy of Sciences (GEBIP). [ABSTRACT FROM AUTHOR]

Published

2020

4. The investigation of effect of macrophages on neural cells of the central nervous system.

Author

Aydınlı, Fatmagül İlayda, Çelik, Eşref, and Kerman, Bilal Ersen

Subjects

*MACROPHAGES, *MULTIPLE sclerosis, *MYELINATION

Abstract

Objective: Macrophages have a dual effect on multiple sclerosis (MS) they promote remyelination via secreted factors and they phagocytose myelin causing demyelination. Thus, signaling pathways regulating macrophage physiology are investigated as therapeutic targets. Among those pathways, dopamine and adenosine signaling pathways, drew attention due to positive results in animal models. Additionally, the two pathways were shown to act synergistically in in vitro experiments. Therefore, synergistic modulation of dopamine and adenosine pathways in macrophages may be a key target for MS therapy. Goal of this study is to investigate the effect of modulation of dopamine and adenosine pathways on myelin damage and remyelination using macrophage oligodendrocyte co-cultures. Methods: First, co-cultures were established with inactivated and lipopolysaccharide (LPS)-activated macrophages isolated from adult mice peritoneum and oligodendrocytes differentiated from the cortex of newborn mice. 48-hour old co-cultures were treated with single, double and triple combinations of dopamine signaling pathway agonist (Quinpirole), adenosine signaling pathway agonist (Istradefylline) and antagonist (CGS21680). Then, co-cultures were fixed and analyzed using immunocytochemistry. Macrophages were labeled with CD11b, oligodendrocytes with SOX10 and mature oligodendrocytes with Myelin Basic Protein (MBP) and quantified by cell counting. Results: In co-cultures with inactivated and LPS-activated macrophages, an increase in the number of mature oligodendrocytes was observed while the total number of oligodendrocytes did not change. However, a triple combination of agonists and antagonist treatment reduced number of mature oligodendrocytes in the LPS-activated macrophage-oligodendrocyte co-cultures. Conclusion: Inactive and LPS-activated macrophages increased the number of mature oligodendrocytes under co-culture conditions. Therefore, macrophages have a positive effect on oligodendrocytes when not activated by MS cues or to a similar extend and LPS treatment alone is not enough to simulate MS like conditions. Observed positive effect can be inhibited by modulating dopamine and adenosine signaling pathways. We thank TUBITAK for their support. [ABSTRACT FROM AUTHOR]

Published

2018