Seizure-induced increase in microglial cell population in the developing zebrafish brain.

Acute seizures; Developing brain; Epilepsy; Kainate; Microglia; Zebrafish; Kainic Acid; Pentylenetetrazole; Animals; Kainic Acid/toxicity; Seizures/chemically induced; Brain; Pentylenetetrazole/toxicity; Disease Models, Animal; Seizures; Neurology; Neurology (clinical)

Abstract :

[en] Epilepsy is a chronic brain disorder characterized by unprovoked and recurrent seizures, of which 60% are of unknown etiology. Recent studies implicate microglia in the pathophysiology of epilepsy. However, their role in this process, in particular following early-life seizures, remains poorly understood due in part to the lack of suitable experimental models allowing the in vivo imaging of microglial activity. Given the advantage of zebrafish larvae for minimally-invasive imaging approaches, we sought for the first time to describe the microglial responses after acute seizures in two different zebrafish larval models: a chemically-induced epileptic model by the systemic injection of kainate at 3 days post-fertilization, and the didys552 genetic epilepsy model, which carries a mutation in scn1lab that leads to spontaneous epileptiform discharges. Kainate-treated larvae exhibited transient brain damage as shown by increased numbers of apoptotic nuclei as early as one day post-injection, which was followed by an increase in the number of microglia in the brain. A similar microglial phenotype was also observed in didys552-/- mutants, suggesting that microglia numbers change in response to seizure-like activity in the brain. Interestingly, kainate-treated larvae also displayed a decreased seizure threshold towards subsequent pentylenetetrazole-induced seizures, as shown by higher locomotor and encephalographic activity in comparison with vehicle-injected larvae. These results are comparable to kainate-induced rodent seizure models and suggest the suitability of these zebrafish seizure models for future studies, in particular to elucidate the links between epileptogenesis and microglial dynamic changes after seizure induction in the developing brain, and to understand how these modulate seizure susceptibility.

Disciplines :

Neurology

Author, co-author :

MARTINS, Teresa ; University of Luxembourg > Luxembourg Centre for Systems Biomedicine (LCSB) > LCSB Operations > Grants and Finance

SOLIMAN, Remon ; University of Luxembourg

Cordero-Maldonado, Maria Lorena ; Luxembourg Centre for Systems Biomedicine (LCSB), University of Luxembourg, Esch-sur-Alzette, Luxembourg

DONATO, Cristina ; University of Luxembourg > Luxembourg Centre for Systems Biomedicine > Integrative Cell Signalling > Team Alexander SKUPIN

AMELI, Corrado ; University of Luxembourg > Luxembourg Centre for Systems Biomedicine (LCSB) > Integrative Cell Signalling

MOMBAERTS, Laurent ; University of Luxembourg

SKUPIN, Alexander ; University of Luxembourg > Luxembourg Centre for Systems Biomedicine (LCSB) > Integrative Cell Signalling

Peri, Francesca; Developmental Biology Group, European Molecular Biology Laboratory (EMBL), Meyerhofstrasse 1, 69117 Heidelberg, Germany

CRAWFORD, Alexander ; University of Luxembourg

External co-authors :

yes

Language :

English

Title :

Seizure-induced increase in microglial cell population in the developing zebrafish brain.

Publication date :

September 2023

Journal title :

Epilepsy Research

ISSN :

0920-1211

Publisher :

Elsevier B.V., Netherlands

Volume :

195

Pages :

107203

Peer reviewed :

Peer Reviewed verified by ORBi

Additional URL :

https://api.elsevier.com/content/article/PII:S0920121123001286?httpAccept=text/xml

Funding text :

T.G.M., R.S., A.D.C, and the study were supported by the Luxembourg National Research Fund (FNR) ( C14/BM/8268559 ). C.D. and C.A. were supported by the FNR through INTER/DFG/17/11583046 and PRIDE17/12252781 , respectively and by the CMCM (Caisse Médico-Complémentaire Mutualiste) matching grant.

Available on ORBilu :

since 01 December 2023

Statistics

Number of views

14 (2 by Unilu)

Number of downloads

0 (0 by Unilu)

More statistics

Scopus citations^®

Scopus citations^®
without self-citations

WoS citations^™

Bibliography

Abraham, J., Fox, P.D., Condello, C., Bartolini, A., Koh, S., Minocycline attenuates microglia activation and blocks the long-term epileptogenic effects of early-life seizures. Neurobiol. Dis. 46 (2012), 425–430.
Afrikanova, T., Serruys, A.S., Buenafe, O.E., Clinckers, R., Smolders, I., de Witte, P.A., Crawford, A.D., Esguerra, C.V., Validation of the zebrafish pentylenetetrazol seizure model: locomotor versus electrographic responses to antiepileptic drugs. PLoS One, 8, 2013, e54166.
Altmann, A., Ryten, M., Di Nunzio, M., Ravizza, T., Tolomeo, D., Reynolds, R.H., Somani, A., Bacigaluppi, M., Iori, V., Micotti, E., Di Sapia, R., Cerovic, M., Palma, E., Ruffolo, G., Botia, J.A., Absil, J., Alhusaini, S., Alvim, M.K.M., Auvinen, P., Bargallo, N., Bartolini, E., Bender, B., Bergo, F.P.G., Bernardes, T., Bernasconi, A., Bernasconi, N., Bernhardt, B.C., Blackmon, K., Braga, B., Caligiuri, M.E., Calvo, A., Carlson, C., Carr, S.J.A., Cavalleri, G.L., Cendes, F., Chen, J., Chen, S., Cherubini, A., Concha, L., David, P., Delanty, N., Depondt, C., Devinsky, O., Doherty, C.P., Domin, M., Focke, N.K., Foley, S., Franca, W., Gambardella, A., Guerrini, R., Hamandi, K., Hibar, D.P., Isaev, D., Jackson, G.D., Jahanshad, N., Kalviainen, R., Keller, S.S., Kochunov, P., Kotikalapudi, R., Kowalczyk, M.A., Kuzniecky, R., Kwan, P., Labate, A., Langner, S., Lenge, M., Liu, M., Martin, P., Mascalchi, M., Meletti, S., Morita-Sherman, M.E., O'Brien, T.J., Pariente, J.C., Richardson, M.P., Rodriguez-Cruces, R., Rummel, C., Saavalainen, T., Semmelroch, M.K., Severino, M., Striano, P., Thesen, T., Thomas, R.H., Tondelli, M., Tortora, D., Vaudano, A.E., Vivash, L., von Podewils, F., Wagner, J., Weber, B., Wiest, R., Yasuda, C.L., Zhang, G., Zhang, J., Group, E.N.-E.W., Leu, C., Avbersek, A., Epi, P.G.X.C., Thom, M., Whelan, C.D., Thompson, P., McDonald, C.R., Vezzani, A., Sisodiya, S.M., A systems-level analysis highlights microglial activation as a modifying factor in common epilepsies. Neuropathol. Appl. Neurobiol., 48, 2022, e12758.
Avignone, E., Ulmann, L., Levavasseur, F., Rassendren, F., Audinat, E., Status epilepticus induces a particular microglial activation state characterized by enhanced purinergic signaling. J. Neurosci. 28 (2008), 9133–9144.
Baraban, S.C., A zebrafish-centric approach to antiepileptic drug development. Dis. Model Mech., 14, 2021.
Baraban, S.C., Taylor, M.R., Castro, P.A., Baier, H., Pentylenetetrazole induced changes in zebrafish behavior, neural activity and c-fos expression. Neuroscience 131 (2005), 759–768.
Baraban, S.C., Dinday, M.T., Hortopan, G.A., Drug screening in Scn1a zebrafish mutant identifies clemizole as a potential Dravet syndrome treatment. Nat. Commun., 4, 2013, 2410.
Beach, T.G., Woodhurst, W.B., MacDonald, D.B., Jones, M.W., Reactive microglia in hippocampal sclerosis associated with human temporal lobe epilepsy. Neurosci. Lett. 191 (1995), 27–30.
Benard, E.L., van der Sar, A.M., Ellett, F., Lieschke, G.J., Spaink, H.P., Meijer, A.H., Infection of zebrafish embryos with intracellular bacterial pathogens. J. Vis. Exp., 2012.
Casano, A.M., Albert, M., Peri, F., Developmental apoptosis mediates entry and positioning of microglia in the zebrafish brain. Cell Rep. 16 (2016), 897–906.
Copmans, D., A.S, de Witte, P.A.M., Zebrafish Models of Epilepsy and Epileptic Seizures. Pitkänen, A., G.A., Buckmaster, P.S., Moshé, S.L., (eds.) Models of Seizures and Epilepsy, Second edition ed., 2017, Academic Press, 369–384.
Davies, D.S., Ma, J., Jegathees, T., Goldsbury, C., Microglia show altered morphology and reduced arborization in human brain during aging and Alzheimer's disease. Brain Pathol. 27 (2017), 795–808.
Di Nunzio, M., Di Sapia, R., Sorrentino, D., Kebede, V., Cerovic, M., Gullotta, G.S., Bacigaluppi, M., Audinat, E., Marchi, N., Ravizza, T., Vezzani, A., Microglia proliferation plays distinct roles in acquired epilepsy depending on disease stages. Epilepsia 62 (2021), 1931–1945.
Eyo, U.B., Dailey, M.E., Microglia: key elements in neural development, plasticity, and pathology. J. Neuroimmune Pharm. 8 (2013), 494–509.
Eyo, U.B., Peng, J., Swiatkowski, P., Mukherjee, A., Bispo, A., Wu, L.J., Neuronal hyperactivity recruits microglial processes via neuronal NMDA receptors and microglial P2Y12 receptors after status epilepticus. J. Neurosci. 34 (2014), 10528–10540.
Eyo, U.B., Murugan, M., Wu, L.J., Microglia-neuron communication in epilepsy. Glia 65 (2017), 5–18.
Eyo, U.B., Haruwaka, K., Mo, M., Campos-Salazar, A.B., Wang, L., Speros, X.St, Sabu, S., Xu, P., Wu, L.J., Microglia provide structural resolution to injured dendrites after severe seizures. Cell Rep., 35, 2021, 109080.
Falcon-Moya, R., Sihra, T.S., Rodriguez-Moreno, A., Kainate receptors: role in epilepsy. Front. Mol. Neurosci., 11, 2018, 217.
Feng, L., Murugan, M., Bosco, D.B., Liu, Y., Peng, J., Worrell, G.A., Wang, H.L., Ta, L.E., Richardson, J.R., Shen, Y., Wu, L.J., Microglial proliferation and monocyte infiltration contribute to microgliosis following status epilepticus. Glia 67 (2019), 1434–1448.
Ferrero, G., Mahony, C.B., Dupuis, E., Yvernogeau, L., Di Ruggiero, E., Miserocchi, M., Caron, M., Robin, C., Traver, D., Bertrand, J.Y., Wittamer, V., Embryonic microglia derive from primitive macrophages and are replaced by cmyb-dependent definitive microglia in zebrafish. Cell Rep. 24 (2018), 130–141.
Fleming, A., Diekmann, H., Goldsmith, P., Functional characterisation of the maturation of the blood-brain barrier in larval zebrafish. PLoS One, 8, 2013, e77548.
Gawel, K., Langlois, M., Martins, T., van der Ent, W., Tiraboschi, E., Jacmin, M., Crawford, A.D., Esguerra, C.V., Seizing the moment: zebrafish epilepsy models. Neurosci. Biobehav Rev. 116 (2020), 1–20.
Gray, C., Loynes, C.A., Whyte, M.K., Crossman, D.C., Renshaw, S.A., Chico, T.J., Simultaneous intravital imaging of macrophage and neutrophil behaviour during inflammation using a novel transgenic zebrafish. Thromb. Haemost. 105 (2011), 811–819.
Hamilton, N., Rutherford, H.A., Petts, J.J., Isles, H.M., Weber, T., Henneke, M., Gartner, J., Dunning, M.J., Renshaw, S.A., The failure of microglia to digest developmental apoptotic cells contributes to the pathology of RNASET2-deficient leukoencephalopathy. Glia 68 (2020), 1531–1545.
Heylen, L., Pham, D.H., De Meulemeester, A.S., Samarut, E., Skiba, A., Copmans, D., Kazwiny, Y., Vanden Berghe, P., de Witte, P.A.M., Siekierska, A., Pericardial injection of kainic acid induces a chronic epileptic state in larval zebrafish. Front. Mol. Neurosci., 14, 2021, 753936.
Hickman, S.E., Kingery, N.D., Ohsumi, T.K., Borowsky, M.L., Wang, L.C., Means, T.K., El Khoury, J., The microglial sensome revealed by direct RNA sequencing. Nat. Neurosci. 16 (2013), 1896–1905.
Hortopan, G.A., Dinday, M.T., Baraban, S.C., Zebrafish as a model for studying genetic aspects of epilepsy. Dis. Model Mech. 3 (2010), 144–148.
Hwang, W.Y., Fu, Y., Reyon, D., Maeder, M.L., Tsai, S.Q., Sander, J.D., Peterson, R.T., Yeh, J.R., Joung, J.K., Efficient genome editing in zebrafish using a CRISPR-Cas system. Nat. Biotechnol. 31 (2013), 227–229.
Ibhazehiebo, K., Gavrilovici, C., de la Hoz, C.L., Ma, S.C., Rehak, R., Kaushik, G., Meza Santoscoy, P.L., Scott, L., Nath, N., Kim, D.Y., Rho, J.M., Kurrasch, D.M., A novel metabolism-based phenotypic drug discovery platform in zebrafish uncovers HDACs 1 and 3 as a potential combined anti-seizure drug target. Brain 141 (2018), 744–761.
Kimmel, C.B., Ballard, W.W., Kimmel, S.R., Ullmann, B., Schilling, T.F., Stages of embryonic development of the zebrafish. Dev. Dyn. 203 (1995), 253–310.
Kokel, D., Bryan, J., Laggner, C., White, R., Cheung, C.Y., Mateus, R., Healey, D., Kim, S., Werdich, A.A., Haggarty, S.J., Macrae, C.A., Shoichet, B., Peterson, R.T., Rapid behavior-based identification of neuroactive small molecules in the zebrafish. Nat. Chem. Biol. 6 (2010), 231–237.
Leclercq, K., Afrikanova, T., Langlois, M., De Prins, A., Buenafe, O.E., Rospo, C.C., Van Eeckhaut, A., de Witte, P.A., Crawford, A.D., Smolders, I., Esguerra, C.V., Kaminski, R.M., Cross-species pharmacological characterization of the allylglycine seizure model in mice and larval zebrafish. Epilepsy Behav. 45 (2015), 53–63.
Levesque, M., Avoli, M., The kainic acid model of temporal lobe epilepsy. Neurosci. Biobehav Rev. 37 (2013), 2887–2899.
Lister, J.A., Robertson, C.P., Lepage, T., Johnson, S.L., Raible, D.W., nacre encodes a zebrafish microphthalmia-related protein that regulates neural-crest-derived pigment cell fate. Development 126 (1999), 3757–3767.
Mattson, M.P., Excitotoxicity. G, F., (eds.) Stress: Physiology, Biochemistry, and Pathology, 2019, Academic Press, 125–134.
Mazaheri, F., Breus, O., Durdu, S., Haas, P., Wittbrodt, J., Gilmour, D., Peri, F., Distinct roles for BAI1 and TIM-4 in the engulfment of dying neurons by microglia. Nat. Commun., 5, 2014, 4046.
Mazzolini, J., Le Clerc, S., Morisse, G., Coulonges, C., Kuil, L.E., van Ham, T.J., Zagury, J.F., Sieger, D., Gene expression profiling reveals a conserved microglia signature in larval zebrafish. Glia 68 (2020), 298–315.
Mirrione, M.M., Konomos, D.K., Gravanis, I., Dewey, S.L., Aguzzi, A., Heppner, F.L., Tsirka, S.E., Microglial ablation and lipopolysaccharide preconditioning affects pilocarpine-induced seizures in mice. Neurobiol. Dis. 39 (2010), 85–97.
Mo, M., Eyo, U.B., Xie, M., Peng, J., Bosco, D.B., Umpierre, A.D., Zhu, X., Tian, D.S., Xu, P., Wu, L.J., Microglial P2Y12 receptor regulates seizure-induced neurogenesis and immature neuronal projections. J. Neurosci. 39 (2019), 9453–9464.
Mombaerts, L., 2019. Dynamical Modeling Techniques for Biological Time Series Data. doi: http://hdl.handle.net/10993/40764.
Peri, F., Nusslein-Volhard, C., Live imaging of neuronal degradation by microglia reveals a role for v0-ATPase a1 in phagosomal fusion in vivo. Cell 133 (2008), 916–927.
Pitkanen, A., Lukasiuk, K., Dudek, F.E., Staley, K.J., Epileptogenesis. Cold Spring Harb. Perspect. Med, 5, 2015.
Ravizza, T., Vezzani, A., Pharmacological targeting of brain inflammation in epilepsy: therapeutic perspectives from experimental and clinical studies. Epilepsia Open 3 (2018), 133–142.
Ravizza, T., Gagliardi, B., Noe, F., Boer, K., Aronica, E., Vezzani, A., Innate and adaptive immunity during epileptogenesis and spontaneous seizures: evidence from experimental models and human temporal lobe epilepsy. Neurobiol. Dis. 29 (2008), 142–160.
Rogove, A.D., Tsirka, S.E., Neurotoxic responses by microglia elicited by excitotoxic injury in the mouse hippocampus. Curr. Biol. 8 (1998), 19–25.
Rossi, F., Casano, A.M., Henke, K., Richter, K., Peri, F., The SLC7A7 transporter identifies microglial precursors prior to entry into the brain. Cell Rep. 11 (2015), 1008–1017.
Santos, D., Luzio, A., Coimbra, A.M., Zebrafish sex differentiation and gonad development: a review on the impact of environmental factors. Aquat. Toxicol. 191 (2017), 141–163.
Schoonheim, P.J., Arrenberg, A.B., Del Bene, F., Baier, H., Optogenetic localization and genetic perturbation of saccade-generating neurons in zebrafish. J. Neurosci. 30 (2010), 7111–7120.
Semple, B.D., Dill, L.K., O'Brien, T.J., Immune challenges and seizures: how do early life insults influence epileptogenesis. Front. Pharmacol., 11, 2020, 2.
Shapiro, L.A., Wang, L., Ribak, C.E., Rapid astrocyte and microglial activation following pilocarpine-induced seizures in rats. Epilepsia 49:Suppl 2 (2008), 33–41.
Sieger, D., Peri, F., Animal models for studying microglia: the first, the popular, and the new. Glia 61 (2013), 3–9.
Sieger, D., Moritz, C., Ziegenhals, T., Prykhozhij, S., Peri, F., Long-range Ca2+ waves transmit brain-damage signals to microglia. Dev. Cell 22 (2012), 1138–1148.
Somera-Molina, K.C., Robin, B., Somera, C.A., Anderson, C., Stine, C., Koh, S., Behanna, H.A., Van Eldik, L.J., Watterson, D.M., Wainwright, M.S., Glial activation links early-life seizures and long-term neurologic dysfunction: evidence using a small molecule inhibitor of proinflammatory cytokine upregulation. Epilepsia 48 (2007), 1785–1800.
Sousa, C., Biber, K., Michelucci, A., Cellular and molecular characterization of microglia: a unique immune cell population. Front. Immunol., 8, 2017, 198.
Svahn, A.J., Graeber, M.B., Ellett, F., Lieschke, G.J., Rinkwitz, S., Bennett, M.R., Becker, T.S., Development of ramified microglia from early macrophages in the zebrafish optic tectum. Dev. Neurobiol. 73 (2013), 60–71.
Tiraboschi, E., Martina, S., van der Ent, W., Grzyb, K., Gawel, K., Cordero-Maldonado, M.L., Poovathingal, S.K., Heintz, S., Satheesh, S.V., Brattespe, J., Xu, J., Suster, M., Skupin, A., Esguerra, C.V., New insights into the early mechanisms of epileptogenesis in a zebrafish model of Dravet syndrome. Epilepsia 61 (2020), 549–560.
Vezzani, A., Balosso, S., Ravizza, T., Neuroinflammatory pathways as treatment targets and biomarkers in epilepsy. Nat. Rev. Neurol. 15 (2019), 459–472.
Villani, A., Benjaminsen, J., Moritz, C., Henke, K., Hartmann, J., Norlin, N., Richter, K., Schieber, N.L., Franke, T., Schwab, Y., Peri, F., Clearance by microglia depends on packaging of phagosomes into a unique cellular compartment. Dev. Cell 49 (2019), 77–88 e77.
Wang, N., Mi, X., Gao, B., Gu, J., Wang, W., Zhang, Y., Wang, X., Minocycline inhibits brain inflammation and attenuates spontaneous recurrent seizures following pilocarpine-induced status epilepticus. Neuroscience 287 (2015), 144–156.
Westerfield, M., The Zebrafish Book. A Guide for the Laboratory Use of Zebrafish (Danio rerio). 2000, University of Oregon Press, Eugene.
Wu, W., Li, Y., Wei, Y., Bosco, D.B., Xie, M., Zhao, M.G., Richardson, J.R., Wu, L.J., Microglial depletion aggravates the severity of acute and chronic seizures in mice. Brain Behav. Immun., 2020.
Wyatt-Johnson, S.K., Herr, S.A., Brewster, A.L., Status epilepticus triggers time-dependent alterations in microglia abundance and morphological phenotypes in the hippocampus. Front Neurol., 8, 2017, 700.
Zattoni, M., Mura, M.L., Deprez, F., Schwendener, R.A., Engelhardt, B., Frei, K., Fritschy, J.M., Brain infiltration of leukocytes contributes to the pathophysiology of temporal lobe epilepsy. J. Neurosci. 31 (2011), 4037–4050.