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4. Enhancing therapeutic potential of olfactory ensheathing cells in spinal cord injury by phagocytosis

Author

Choudhury, Indra N

Subjects
glia, olfactory ensheathing cells, phagocytosis, S. aureus, drug discovery
Abstract

Under normal physiological condition the body needs to fight bacterial infection, clear old dead or dying cells as well as regenerate new ones. Phagocytosis is the immunological process required for cells to digest and destroy particulates thereby maintaining a systemic homeostasis. Phagocytosis involves four steps of recognition, engulfment, formation of phagosome, degradation and elimination. In the nervous system, the phagocytes are the glial cells which support the system framework, primarily microglia. Spinal cord injury is an irreparable nervous system injury and restoration of function is very difficult. One strategy which could aid repair and regeneration is to enhance the phagocytic process thereby removing cell debris and bacteria from the injury site. Glial cells are involved in phagocytosis and clearing the spinal cord injury area. Understanding this process may improve strategies to develop therapy, particularly those that involve cell transplantation such as peripheral nerve glia. Within the nervous system, the main phagocytic glia, which has been studied, in the central nervous system (CNS) are astrocytes and microglia, and in the peripheral nervous system (PNS), the main glia are Schwann cells for most nerves, with olfactory ensheathing cells (OECs) in the olfactory nerve. In this study, my first objective was to compare the CNS and PNS cells like astrocytes, microglia, OECs and trigeminal Schwann cells (TgSCs) for their antimicrobial response to bacterial infection (S. aureus). Results showed live bacteria could be isolated from all glia after 24 h in culture, and microglia, OECs and TgSCs exhibited better protection against intracellular S. aureus survival than astrocytes. All glial types responded to the bacteria by cytokine secretion, but overall, OECs secreted the lowest level of cytokines. Debris clearance is crucial for neural regeneration and OECs have the ability to phagocytose both bacteria and cell debris. OECs and SCs are being considered as cell transplantation therapies in spinal cord injury for the purpose of repairing the damaged nervous system. Thus, understanding the genetic expression in between OECs and SCs during the process of phagocytosis of bacteria (S. aureus) and axonal debris is essential. Results showed OECs responded to S. aureus with protein modification and phosphorus metabolic processes involved with immune response, and leukocyte mediated immunity signalling mechanisms for bacterial engulfment. SCs responded to cell debris with pathways associated with actin filament-based processes, cytoskeleton organization, and FC gamma receptor dependent phagocytosis. These findings demonstrate the differences between OECs and SCs during phagocytic responses to bacteria and cell debris. Overall, OECs expressed a low gene expression profile compared to SCs. Discovering novel compounds that can stimulate OECs to phagocytose bacteria and cell debris more efficiently may improve the therapeutic potential of the cells. Potentially, if OECs could be pre-stimulated with a drug to enhance OEC phagocytosis, that could be useful in spinal cord injury regeneration. Therefore to identify compounds that would enhance the phagocytosis of glial cells, drug discovery assays were performed. Following a preliminary compound screening, a synthetic compound and a natural compound was identified. For a third compound, a FDA approved drug was selected to test their effects on glial cells. As the process and analyses, required to identify compounds, that stimulate glial cell phagocytic activity has not been previously established, development and optimization of a protocol for phagocytosis detection was performed. Phagocytosis measurement in glial cells based on live imaging and fixed widefield imaging was performed to make a replicable drug discovery testing method which could be used on cell lines and primary cells both. Using this method results like cytotoxicity, morphological changes and phagocytosis of various targets can be reliably performed. Testing the compounds with the protocol, demonstrated that significant stimulation of phagocytosis activity could be detected. All three compounds tested showed positive phagocytosis increase on cell lines. The synthetic compound showed positive increase in phagocytosis on primary OECs and TgSCs but not in astrocytes and microglia for S. aureus pHrodo BioParticles. Testing further, using the synthetic compound, in the presence of bacterial stimulus, showed no significant upregulation in cytokines but some positive upregulation in phagocytotic genes, in the compound stimulated wells against controls. The natural compound showed increase in phagocytosis only in microglia but not in other glial cells (OECs, TgSCs and astrocytes). The FDA compound Liraglutide showed significant increase in phagocytosis in all glial cells (astrocytes, microglia, OECs and TgSCs). Testing the synthetic compound on the phagocytosis of Beta (β) amyloid peptide, in OECs, astrocytes and microglia, showed an increase in peptide uptake in compound stimulated OECs as compared to non-stimulated ones. Astrocyte and microglia did not show any difference. In conclusion, this thesis gives us an understanding of the difference between CNS and PNS phagocytosis. While the different glial cells share many properties, OECs exhibit several characteristics which make them favourable candidates for transplantation therapies. Compound testing revealed that phagocytic activity can be stimulated and opens up avenues for identification of compounds that could be used to enhance therapeutic activity of glial cells in SCI and possibly in Alzheimer’s diseases research.

Published
2023
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5. Macrophages Treated with VEGF and PDGF Exert Paracrine Effects on Olfactory Ensheathing Cell Function.

Author

Basu, Souptik, Choudhury, Indra N., Lee, Jia Yu Peppermint, Chacko, Anu, Ekberg, Jenny A. K., and St John, James A.

Subjects
*CELL physiology, *VASCULAR endothelial growth factors, *PLATELET-derived growth factor, *NF-kappa B, *MYELIN proteins, *MACROPHAGES
Abstract

Glial cell transplantation using olfactory ensheathing cells (OECs) holds a promising approach for treating spinal cord injury (SCI). However, integration of OECs into the hostile acute secondary injury site requires interaction and response to macrophages. Immunomodulation of macrophages to reduce their impact on OECs may improve the functionality of OECs. Vascular endothelial growth factor (VEGF) and platelet-derived growth factor (PDGF), known for their immunomodulatory and neuroprotective functions, have provided improved outcomes in SCI animal models. Thus, VEGF and PDGF modulation of the SCI microenvironment may be beneficial for OEC transplantation. In this in vitro study, the effect of VEGF and PDGF on macrophages in an inflammatory condition was tested. Combined VEGF + PDGF reduced translocation nuclear factor kappa B p65 in macrophages without altering pro-inflammatory cytokines. Further, the ability of OECs to phagocytose myelin debris was assessed using macrophage-conditioned medium. Conditioned medium from macrophages incubated with PDGF and combined VEGF + PDGF in inflammatory conditions promoted phagocytosis by OECs. The growth factor treated conditioned media also modulated the expression of genes associated with nerve repair and myelin expression in OECs. Overall, these results suggest that the use of growth factors together with OEC transplantation may be beneficial in SCI therapy. [ABSTRACT FROM AUTHOR]

Published
2022
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6. Streptococcus agalactiae Infects Glial Cells and Invades the Central Nervous System via the Olfactory and Trigeminal Nerves.

Author

Chacko, Anu, Delbaz, Ali, Choudhury, Indra N., Eindorf, Tanja, Shah, Megha, Godfrey, Christopher, Sullivan, Mathew J., St John, James A., Ulett, Glen C., and Ekberg, Jenny A. K.

Subjects
CENTRAL nervous system, OLFACTORY nerve, STREPTOCOCCUS agalactiae, TRIGEMINAL nerve, NEUROGLIA
Abstract

Streptococcus agalactiae causes neonatal meningitis and can also infect the adult central nervous system (CNS). S. agalactiae can cross the blood-brain barrier but may also reach the CNS via other paths. Several species of bacteria can directly invade the CNS via the olfactory and trigeminal nerves, which extend between the nasal cavity and brain and injury to the nasal epithelium can increase the risk/severity of infection. Preterm birth is associated with increased risk of S. agalactiae infection and with nasogastric tube feeding. The tubes, also used in adults, can cause nasal injuries and may be contaminated with bacteria, including S. agalactiae. We here investigated whether S. agalactiae could invade the CNS after intranasal inoculation in mice. S. agalactiae rapidly infected the olfactory nerve and brain. Methimazole-mediated model of nasal epithelial injury led to increased bacterial load in these tissues, as well as trigeminal nerve infection. S. agalactiae infected and survived intracellularly in cultured olfactory/trigeminal nerve- and brain-derived glia, resulting in cytokine production, with some differences between glial types. Furthermore, a non-capsulated S. agalactiae was used to understand the role of capsule on glial cells interaction. Interestingly, we found that the S. agalactiae capsule significantly altered cytokine and chemokine responses and affected intracellular survival in trigeminal glia. In summary, this study shows that S. agalactiae can infect the CNS via the nose-to-brain path with increased load after epithelial injury, and that the bacteria can survive in glia. [ABSTRACT FROM AUTHOR]

Published
2022
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