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2. dCas9-based Scn1a gene activation restores inhibitory interneuron excitability and attenuates seizures in Dravet Syndrome mice

Author

Colasante, G, Lignani, G, Brusco, S, Di Berardino, C, Carpenter, J, Giannelli, S, Valassina, N, Bido, S, Ricci, R, Castoldi, V, Marenna, S, Church, T, Massimino, L, Morabito, G, Benfenati, F, Schorge, S, Leocani, L, Kullmann, D, Vania Broccoli, A, Gaia Colasante, Gabriele Lignani, Simone Brusco, Claudia Di Berardino, Jenna Carpenter, Serena Giannelli, Nicholas Valassina, Simone Bido, Raffaele Ricci, Valerio Castoldi, Silvia Marenna, Timothy Church, Luca Massimino, Giuseppe Morabito, Fabio Benfenati, Stephanie Schorge, Letizia Leocani, Dimitri M. Kullmann, and Vania Broccoli, Colasante, G, Lignani, G, Brusco, S, Di Berardino, C, Carpenter, J, Giannelli, S, Valassina, N, Bido, S, Ricci, R, Castoldi, V, Marenna, S, Church, T, Massimino, L, Morabito, G, Benfenati, F, Schorge, S, Leocani, L, Kullmann, D, Vania Broccoli, A, Gaia Colasante, Gabriele Lignani, Simone Brusco, Claudia Di Berardino, Jenna Carpenter, Serena Giannelli, Nicholas Valassina, Simone Bido, Raffaele Ricci, Valerio Castoldi, Silvia Marenna, Timothy Church, Luca Massimino, Giuseppe Morabito, Fabio Benfenati, Stephanie Schorge, Letizia Leocani, Dimitri M. Kullmann, and and Vania Broccoli

Abstract

Dravet syndrome (DS) is a severe epileptic encephalopathy caused mainly by heterozygous loss-of-function mutations of the SCN1A gene, indicating haploinsufficiency as the pathogenic mechanism. Here we tested whether catalytically dead Cas9 (dCas9)-mediated Scn1a gene activation can rescue Scn1a haploinsufficiency in a mouse DS model and restore physiological levels of its gene product, the Nav1.1 voltage gated sodium channel. We screened single guide RNAs (sgRNAs) for their ability to stimulate Scn1a transcription in association with the dCas9 activation system. We identified a specific sgRNA that increases Scn1a gene expression levels in cell lines and primary neurons with high specificity. Nav1.1 protein levels were augmented, as was the ability of wild-type immature GABAergic interneurons to fire action potentials. A similar enhancement of Scn1a transcription was achieved in mature DS interneurons, rescuing their ability to fire. To test the therapeutic potential of this approach, we delivered the Scn1a-dCas9 activation system to DS pups using adenoassociated viruses. Parvalbumin interneurons recovered their firing ability, and febrile seizures were significantly attenuated. Our results pave the way for exploiting dCas9-based gene activation as an effective and targeted approach to DS and other disorders resulting from altered gene dosage.

Published
2020

3. AMPA receptor GluA2 subunit defects are a cause of neurodevelopmental disorders

Author

Salpietro, V. Dixon, C.L. Guo, H. Bello, O.D. Vandrovcova, J. Efthymiou, S. Maroofian, R. Heimer, G. Burglen, L. Valence, S. Torti, E. Hacke, M. Rankin, J. Tariq, H. Colin, E. Procaccio, V. Striano, P. Mankad, K. Lieb, A. Chen, S. Pisani, L. Bettencourt, C. Männikkö, R. Manole, A. Brusco, A. Grosso, E. Ferrero, G.B. Armstrong-Moron, J. Gueden, S. Bar-Yosef, O. Tzadok, M. Monaghan, K.G. Santiago-Sim, T. Person, R.E. Cho, M.T. Willaert, R. Yoo, Y. Chae, J.-H. Quan, Y. Wu, H. Wang, T. Bernier, R.A. Xia, K. Blesson, A. Jain, M. Motazacker, M.M. Jaeger, B. Schneider, A.L. Boysen, K. Muir, A.M. Myers, C.T. Gavrilova, R.H. Gunderson, L. Schultz-Rogers, L. Klee, E.W. Dyment, D. Osmond, M. Parellada, M. Llorente, C. Gonzalez-Peñas, J. Carracedo, A. Van Haeringen, A. Ruivenkamp, C. Nava, C. Heron, D. Nardello, R. Iacomino, M. Minetti, C. Skabar, A. Fabretto, A. Hanna, M.G. Bugiardini, E. Hostettler, I. O’Callaghan, B. Khan, A. Cortese, A. O’Connor, E. Yau, W.Y. Bourinaris, T. Kaiyrzhanov, R. Chelban, V. Madej, M. Diana, M.C. Vari, M.S. Pedemonte, M. Bruno, C. Balagura, G. Scala, M. Fiorillo, C. Nobili, L. Malintan, N.T. Zanetti, M.N. Krishnakumar, S.S. Lignani, G. Jepson, J.E.C. Broda, P. Baldassari, S. Rossi, P. Fruscione, F. Madia, F. Traverso, M. De-Marco, P. Pérez-Dueñas, B. Munell, F. Kriouile, Y. El-Khorassani, M. Karashova, B. Avdjieva, D. Kathom, H. Tincheva, R. Van-Maldergem, L. Nachbauer, W. Boesch, S. Gagliano, A. Amadori, E. Goraya, J.S. Sultan, T. Kirmani, S. Ibrahim, S. Jan, F. Mine, J. Banu, S. Veggiotti, P. Zuccotti, G.V. Ferrari, M.D. Van Den Maagdenberg, A.M.J. Verrotti, A. Marseglia, G.L. Savasta, S. Soler, M.A. Scuderi, C. Borgione, E. Chimenz, R. Gitto, E. Dipasquale, V. Sallemi, A. Fusco, M. Cuppari, C. Cutrupi, M.C. Ruggieri, M. Cama, A. Capra, V. Mencacci, N.E. Boles, R. Gupta, N. Kabra, M. Papacostas, S. Zamba-Papanicolaou, E. Dardiotis, E. Maqbool, S. Rana, N. Atawneh, O. Lim, S.Y. Shaikh, F. Koutsis, G. Breza, M. Coviello, D.A. Dauvilliers, Y.A. AlKhawaja, I. AlKhawaja, M. Al-Mutairi, F. Stojkovic, T. Ferrucci, V. Zollo, M. Alkuraya, F.S. Kinali, M. Sherifa, H. Benrhouma, H. Turki, I.B.Y. Tazir, M. Obeid, M. Bakhtadze, S. Saadi, N.W. Zaki, M.S. Triki, C.C. Benfenati, F. Gustincich, S. Kara, M. Belcastro, V. Specchio, N. Capovilla, G. Karimiani, E.G. Salih, A.M. Okubadejo, N.U. Ojo, O.O. Oshinaike, O.O. Oguntunde, O. Wahab, K. Bello, A.H. Abubakar, S. Obiabo, Y. Nwazor, E. Ekenze, O. Williams, U. Iyagba, A. Taiwo, L. Komolafe, M. Senkevich, K. Shashkin, C. Zharkynbekova, N. Koneyev, K. Manizha, G. Isrofilov, M. Guliyeva, U. Salayev, K. Khachatryan, S. Rossi, S. Silvestri, G. Haridy, N. Ramenghi, L.A. Xiromerisiou, G. David, E. Aguennouz, M. Fidani, L. Spanaki, C. Tucci, A. Raspall-Chaure, M. Chez, M. Tsai, A. Fassi, E. Shinawi, M. Constantino, J.N. De Zorzi, R. Fortuna, S. Kok, F. Keren, B. Bonneau, D. Choi, M. Benzeev, B. Zara, F. Mefford, H.C. Scheffer, I.E. Clayton-Smith, J. Macaya, A. Rothman, J.E. Eichler, E.E. Kullmann, D.M. Houlden, H. SYNAPS Study Group

Abstract

AMPA receptors (AMPARs) are tetrameric ligand-gated channels made up of combinations of GluA1-4 subunits encoded by GRIA1-4 genes. GluA2 has an especially important role because, following post-transcriptional editing at the Q607 site, it renders heteromultimeric AMPARs Ca2+-impermeable, with a linear relationship between current and trans-membrane voltage. Here, we report heterozygous de novo GRIA2 mutations in 28 unrelated patients with intellectual disability (ID) and neurodevelopmental abnormalities including autism spectrum disorder (ASD), Rett syndrome-like features, and seizures or developmental epileptic encephalopathy (DEE). In functional expression studies, mutations lead to a decrease in agonist-evoked current mediated by mutant subunits compared to wild-type channels. When GluA2 subunits are co-expressed with GluA1, most GRIA2 mutations cause a decreased current amplitude and some also affect voltage rectification. Our results show that de-novo variants in GRIA2 can cause neurodevelopmental disorders, complementing evidence that other genetic causes of ID, ASD and DEE also disrupt glutamatergic synaptic transmission. © 2019, The Author(s).

Published
2019

4. AMPA receptor GluA2 subunit defects are a cause of neurodevelopmental disorders

Author

Salpietro, V, Dixon, CL, Guo, H, Bello, OD, Vandrovcova, J, Efthymiou, S, Maroofian, R, Heimer, G, Burglen, L, Valence, S, Torti, E, Hacke, M, Rankin, J, Tariq, H, Colin, E, Procaccio, V, Striano, P, Mankad, K, Lieb, A, Chen, S, Pisani, L, Bettencourt, C, Mannikko, R, Manole, A, Brusco, A, Grosso, E, Ferrero, GB, Armstrong-Moron, J, Gueden, S, Bar-Yosef, O, Tzadok, M, Monaghan, KG, Santiago-Sim, T, Person, RE, Cho, MT, Willaert, R, Yoo, Y, Chae, J-H, Quan, Y, Wu, H, Wang, T, Bernier, RA, Xia, K, Blesson, A, Jain, M, Motazacker, MM, Jaeger, B, Schneider, AL, Boysen, K, Muir, AM, Myers, CT, Gavrilova, RH, Gunderson, L, Schultz-Rogers, L, Klee, EW, Dyment, D, Osmond, M, Parellada, M, Llorente, C, Gonzalez-Penas, J, Carracedo, A, Van Haeringen, A, Ruivenkamp, C, Nava, C, Heron, D, Nardello, R, Iacomino, M, Minetti, C, Skabar, A, Fabretto, A, Chez, M, Tsai, A, Fassi, E, Shinawi, M, Constantino, JN, De Zorzi, R, Fortuna, S, Kok, F, Keren, B, Bonneau, D, Choi, M, Benzeev, B, Zara, F, Mefford, HC, Scheffer, IE, Clayton-Smith, J, Macaya, A, Rothman, JE, Eichler, EE, Kullmann, DM, Houlden, H, Raspall-Chaure, M, Hanna, MG, Bugiardini, E, Hostettler, I, O'Callaghan, B, Khan, A, Cortese, A, O'Connor, E, Yau, WY, Bourinaris, T, Kaiyrzhanov, R, Chelban, V, Madej, M, Diana, MC, Vari, MS, Pedemonte, M, Bruno, C, Balagura, G, Scala, M, Fiorillo, C, Nobili, L, Malintan, NT, Zanetti, MN, Krishnakumar, SS, Lignani, G, Jepson, JEC, Broda, P, Baldassari, S, Rossi, P, Fruscione, F, Madia, F, Traverso, M, De-Marco, P, Perez-Duenas, B, Munell, F, Kriouile, Y, El-Khorassani, M, Karashova, B, Avdjieva, D, Kathom, H, Tincheva, R, Van-Maldergem, L, Nachbauer, W, Boesch, S, Gagliano, A, Amadori, E, Goraya, JS, Sultan, T, Kirmani, S, Ibrahim, S, Jan, F, Mine, J, Banu, S, Veggiotti, P, Zuccotti, G, Ferrari, MD, Van Den Maagdenberg, AMJ, Verrotti, A, Marseglia, GL, Savasta, S, Soler, MA, Scuderi, C, Borgione, E, Chimenz, R, Gitto, E, Dipasquale, V, Sallemi, A, Fusco, M, Cuppari, C, Cutrupi, MC, Ruggieri, M, Cama, A, Capra, V, Mencacci, NE, Boles, R, Gupta, N, Kabra, M, Papacostas, S, Zamba-Papanicolaou, E, Dardiotis, E, Maqbool, S, Rana, N, Atawneh, O, Lim, SY, Shaikh, F, Koutsis, G, Breza, M, Coviello, DA, Dauvilliers, YA, AlKhawaja, I, AlKhawaja, M, Al-Mutairi, F, Stojkovic, T, Ferrucci, V, Zollo, M, Alkuraya, FS, Kinali, M, Sherifa, H, Benrhouma, H, Turki, IBY, Tazir, M, Obeid, M, Bakhtadze, S, Saadi, NW, Zaki, MS, Triki, CC, Benfenati, F, Gustincich, S, Kara, M, Belcastro, V, Specchio, N, Capovilla, G, Karimiani, EG, Salih, AM, Okubadejo, NU, Ojo, OO, Oshinaike, OO, Oguntunde, O, Wahab, K, Bello, AH, Abubakar, S, Obiabo, Y, Nwazor, E, Ekenze, O, Williams, U, Iyagba, A, Taiwo, L, Komolafe, M, Senkevich, K, Shashkin, C, Zharkynbekova, N, Koneyev, K, Manizha, G, Isrofilov, M, Guliyeva, U, Salayev, K, Khachatryan, S, Rossi, S, Silvestri, G, Haridy, N, Ramenghi, LA, Xiromerisiou, G, David, E, Aguennouz, M, Fidani, L, Spanaki, C, Tucci, A, Salpietro, V, Dixon, CL, Guo, H, Bello, OD, Vandrovcova, J, Efthymiou, S, Maroofian, R, Heimer, G, Burglen, L, Valence, S, Torti, E, Hacke, M, Rankin, J, Tariq, H, Colin, E, Procaccio, V, Striano, P, Mankad, K, Lieb, A, Chen, S, Pisani, L, Bettencourt, C, Mannikko, R, Manole, A, Brusco, A, Grosso, E, Ferrero, GB, Armstrong-Moron, J, Gueden, S, Bar-Yosef, O, Tzadok, M, Monaghan, KG, Santiago-Sim, T, Person, RE, Cho, MT, Willaert, R, Yoo, Y, Chae, J-H, Quan, Y, Wu, H, Wang, T, Bernier, RA, Xia, K, Blesson, A, Jain, M, Motazacker, MM, Jaeger, B, Schneider, AL, Boysen, K, Muir, AM, Myers, CT, Gavrilova, RH, Gunderson, L, Schultz-Rogers, L, Klee, EW, Dyment, D, Osmond, M, Parellada, M, Llorente, C, Gonzalez-Penas, J, Carracedo, A, Van Haeringen, A, Ruivenkamp, C, Nava, C, Heron, D, Nardello, R, Iacomino, M, Minetti, C, Skabar, A, Fabretto, A, Chez, M, Tsai, A, Fassi, E, Shinawi, M, Constantino, JN, De Zorzi, R, Fortuna, S, Kok, F, Keren, B, Bonneau, D, Choi, M, Benzeev, B, Zara, F, Mefford, HC, Scheffer, IE, Clayton-Smith, J, Macaya, A, Rothman, JE, Eichler, EE, Kullmann, DM, Houlden, H, Raspall-Chaure, M, Hanna, MG, Bugiardini, E, Hostettler, I, O'Callaghan, B, Khan, A, Cortese, A, O'Connor, E, Yau, WY, Bourinaris, T, Kaiyrzhanov, R, Chelban, V, Madej, M, Diana, MC, Vari, MS, Pedemonte, M, Bruno, C, Balagura, G, Scala, M, Fiorillo, C, Nobili, L, Malintan, NT, Zanetti, MN, Krishnakumar, SS, Lignani, G, Jepson, JEC, Broda, P, Baldassari, S, Rossi, P, Fruscione, F, Madia, F, Traverso, M, De-Marco, P, Perez-Duenas, B, Munell, F, Kriouile, Y, El-Khorassani, M, Karashova, B, Avdjieva, D, Kathom, H, Tincheva, R, Van-Maldergem, L, Nachbauer, W, Boesch, S, Gagliano, A, Amadori, E, Goraya, JS, Sultan, T, Kirmani, S, Ibrahim, S, Jan, F, Mine, J, Banu, S, Veggiotti, P, Zuccotti, G, Ferrari, MD, Van Den Maagdenberg, AMJ, Verrotti, A, Marseglia, GL, Savasta, S, Soler, MA, Scuderi, C, Borgione, E, Chimenz, R, Gitto, E, Dipasquale, V, Sallemi, A, Fusco, M, Cuppari, C, Cutrupi, MC, Ruggieri, M, Cama, A, Capra, V, Mencacci, NE, Boles, R, Gupta, N, Kabra, M, Papacostas, S, Zamba-Papanicolaou, E, Dardiotis, E, Maqbool, S, Rana, N, Atawneh, O, Lim, SY, Shaikh, F, Koutsis, G, Breza, M, Coviello, DA, Dauvilliers, YA, AlKhawaja, I, AlKhawaja, M, Al-Mutairi, F, Stojkovic, T, Ferrucci, V, Zollo, M, Alkuraya, FS, Kinali, M, Sherifa, H, Benrhouma, H, Turki, IBY, Tazir, M, Obeid, M, Bakhtadze, S, Saadi, NW, Zaki, MS, Triki, CC, Benfenati, F, Gustincich, S, Kara, M, Belcastro, V, Specchio, N, Capovilla, G, Karimiani, EG, Salih, AM, Okubadejo, NU, Ojo, OO, Oshinaike, OO, Oguntunde, O, Wahab, K, Bello, AH, Abubakar, S, Obiabo, Y, Nwazor, E, Ekenze, O, Williams, U, Iyagba, A, Taiwo, L, Komolafe, M, Senkevich, K, Shashkin, C, Zharkynbekova, N, Koneyev, K, Manizha, G, Isrofilov, M, Guliyeva, U, Salayev, K, Khachatryan, S, Rossi, S, Silvestri, G, Haridy, N, Ramenghi, LA, Xiromerisiou, G, David, E, Aguennouz, M, Fidani, L, Spanaki, C, and Tucci, A

Abstract

AMPA receptors (AMPARs) are tetrameric ligand-gated channels made up of combinations of GluA1-4 subunits encoded by GRIA1-4 genes. GluA2 has an especially important role because, following post-transcriptional editing at the Q607 site, it renders heteromultimeric AMPARs Ca2+-impermeable, with a linear relationship between current and trans-membrane voltage. Here, we report heterozygous de novo GRIA2 mutations in 28 unrelated patients with intellectual disability (ID) and neurodevelopmental abnormalities including autism spectrum disorder (ASD), Rett syndrome-like features, and seizures or developmental epileptic encephalopathy (DEE). In functional expression studies, mutations lead to a decrease in agonist-evoked current mediated by mutant subunits compared to wild-type channels. When GluA2 subunits are co-expressed with GluA1, most GRIA2 mutations cause a decreased current amplitude and some also affect voltage rectification. Our results show that de-novo variants in GRIA2 can cause neurodevelopmental disorders, complementing evidence that other genetic causes of ID, ASD and DEE also disrupt glutamatergic synaptic transmission.

Published
2019

7. Phosphorylation of synapsin I by cdk5 sets the ratio between the resting and recycling pools of synaptic vesicles at hippocampal synapses

Author

Fassio, A., Verstegen, A. J., Erica Tagliatti, Lignani, G., Marte, Antonella, Stolero, T., Orenbuch, A., Corradi, A., Valtorta, F., Gitler, D., Onofri, F., Benfenati, F., A. M. G., Verstegen, E., Tagliatti, G., Lignani, A., Marte, T., Stolero, A., Orenbuch, A., Corradi, Valtorta, Flavia, D., Gitler, F., Onofri, A., Fassio, and F., Benfenati

Subjects
synapse, phosphorylation, neuron
Abstract

Cyclin-dependent kinase-5 (Cdk5) was reported to downscale neurotransmission by sequestering synaptic vesicles (SVs) in the release-reluctant resting pool, but the molecular targets mediating this activity remain unknown. Synapsin I (SynI), a major SV phosphoprotein involved in the regulation of SV trafficking and neurotransmitter release, is one of the presynaptic substrates of Cdk5, which phosphorylates it in its C-terminal region at Ser549 (site 6) and Ser551 (site 7). Here we demonstrate that Cdk5 phosphorylation of SynI fine tunes the recruitment of SVs to the active recycling pool and contributes to the Cdk5-mediated homeostatic responses. Phosphorylation of SynI by Cdk5 is physiologically regulated and enhances its binding to F-actin. The effects of Cdk5 inhibition on the size and depletion kinetics of the recycling pool as well as on SV distribution within the nerve terminal were virtually abolished in SynI knockout (KO) neurons or in KO neurons expressing the dephosphomimetic SynI mutants at sites 6,7 or site 7 only. The observation that the single site-7 mutant phenocopies the effects of the deletion of SynI identifies this site as the central switch in mediating the synaptic effects of Cdk5 and demonstrates that SynI is necessary and sufficient for achieving the effects of the kinase on SV trafficking. The phosphorylation state of SynI by Cdk5 at site-7 was regulated during chronic modification of neuronal activity and was an essential downstream effector for the Cdk5-mediated homeostatic scaling.

Published
2014

10. Direct conversion of fibroblasts into functional astrocytes by defined transcription factors

Author

Caiazzo, M, Giannelli, S, Valente, P, Lignani, G, Carissimo, A, Sessa, A, Colasante, G, Bartolomeo, R, Massimino, L, Ferroni, S, Settembre, C, Benfenati, F, Broccoli, V, Broccoli, V., MASSIMINO, LUCA, Caiazzo, M, Giannelli, S, Valente, P, Lignani, G, Carissimo, A, Sessa, A, Colasante, G, Bartolomeo, R, Massimino, L, Ferroni, S, Settembre, C, Benfenati, F, Broccoli, V, Broccoli, V., and MASSIMINO, LUCA

Abstract

Direct cell reprogramming enables direct conversion of fibroblasts into functional neurons and oligodendrocytes using a minimal set of cell-lineage-specific transcription factors. This approach is rapid and simple, generating the cell types of interest in one step. However, it remains unknown whether this technology can be applied to convert fibroblasts into astrocytes, the third neural lineage. Astrocytes play crucial roles in neuronal homeostasis, and their dysfunctions contribute to the origin and progression of multiple human diseases. Herein, we carried out a screening using several transcription factors involved in defining the astroglial cell fate and identified NFIA, NFIB, and SOX9 to be sufficient to convert with high efficiency embryonic and postnatal mouse fibroblasts into astrocytes (iAstrocytes). We proved both by gene-expression profiling and functional tests that iAstrocytes are comparable to native brain astrocytes. This protocol can be then employed to generate functional iAstrocytes for a wide range of experimental applications.

Published
2015

13. Phosphorylation of Synapsin I by Cyclin-Dependent Kinase-5 Sets the Ratio between the Resting and Recycling Pools of Synaptic Vesicles at Hippocampal Synapses

Author

Verstegen, A. M. J., primary, Tagliatti, E., additional, Lignani, G., additional, Marte, A., additional, Stolero, T., additional, Atias, M., additional, Corradi, A., additional, Valtorta, F., additional, Gitler, D., additional, Onofri, F., additional, Fassio, A., additional, and Benfenati, F., additional

Published
2014
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21. Acute effects of LGI1 on network excitability

Author

Lugara, Eleonora, Walker, M., and Lignani, G.

Subjects
612.8
Abstract

LGI1 (leucine rich glioma inactivated1) is a secreted trans-synaptic protein and is part of the brain extracellular matrix. LGI1 interacts presynaptically with Kv1.1 potassium channels and ADAM23, a structural transmembrane protein. Postsynaptically, LGI1 also influences AMPA and NMDA receptors via the ADAM22 adhesion protein. Mutations in the gene encoding LGI1 lead to temporal lobe epilepsy in humans and animal models. Autoantibodies against LGI1 have been detected in the serum of adult patients with limbic encephalitis and seizures. Although LGI1 is strongly implicated in the generation and spread of seizures in genetic and developmental forms of epilepsy, the mechanisms by which LGI1 affects neuronal networks are still debated. This thesis aimed to determine whether an acute reduction of LGI1 in the brain leads to network hyperactivity and epilepsy in rodent animals and the mechanisms behind it. Initially, in vivo experiments on rats demonstrated that LGI1 concentrations in the brain are reduced after generation of chronic seizures using the perforant path stimulation model. I then chose and validated a silencing RNA (shRNA) against LGI1 which reduced endogenous LGI1 levels in primary cultures. In the transduced neurons, spontaneous calcium activity was significantly higher, without affecting the viability of the cells. Also the MBR (mean bursting rate) of transduced neuronal cultures measured with a MEA (multielectrode arrays) system was increased. In ex vivo granule cells, shRNA-LGI1 increased neuronal firing. Local field potential (LFP) of ex vivo slices after injection of shRNA-LGI1 in the hippocampus, revealed an increase in the short-term facilitation of mossy fibers to CA3 pyramidal cell synapses. Application of Kv1 family blocker, αDendrotoxin, occluded the increased facilitation in shRNA-LGI1 injected mice. My results indicate that an acute reduction of LGI1 is sufficient to increase neuronal network excitability in in vitro and ex vivo systems and that LGI1 concentrations are reduced in the brains of animals during the development of epilepsy.

Published
2019

22. dCas9-Based Scn1a Gene Activation Restores Inhibitory Interneuron Excitability and Attenuates Seizures in Dravet Syndrome Mice

Author

Letizia Leocani, Valerio Castoldi, Timothy Church, Raffaele Ricci, Jenna C Carpenter, Claudia Di Berardino, Silvia Marenna, Stephanie Schorge, Gabriele Lignani, Fabio Benfenati, Dimitri M. Kullmann, Gaia Colasante, Luca Massimino, Simone Bido, Vania Broccoli, Simone Brusco, Serena Giannelli, Nicholas Valassina, Giuseppe Morabito, Colasante, G., Lignani, G., Brusco, S., Di Berardino, C., Carpenter, J., Giannelli, S., Valassina, N., Bido, S., Ricci, R., Castoldi, V., Marenna, S., Church, T., Massimino, L., Morabito, G., Benfenati, F., Schorge, S., Leocani, L., Kullmann, D. M., Broccoli, V., Colasante, G, Lignani, G, Brusco, S, Di Berardino, C, Carpenter, J, Giannelli, S, Valassina, N, Bido, S, Ricci, R, Castoldi, V, Marenna, S, Church, T, Massimino, L, Morabito, G, Benfenati, F, Schorge, S, Leocani, L, Kullmann, D, and Vania Broccoli, A

Subjects
Interneuron, Gene dosage, Gene product, activatory CRISPR, Dravet syndrome, epileptic encephalopathy, gene therapy, 03 medical and health sciences, 0302 clinical medicine, Drug Discovery, Genetics, medicine, Molecular Biology, 030304 developmental biology, Pharmacology, Regulation of gene expression, 0303 health sciences, biology, Sodium channel, medicine.disease, Cell biology, medicine.anatomical_structure, 030220 oncology & carcinogenesis, biology.protein, Molecular Medicine, Original Article, Haploinsufficiency, Parvalbumin
Abstract

Dravet syndrome (DS) is a severe epileptic encephalopathy caused mainly by heterozygous loss-of-function mutations of the SCN1A gene, indicating haploinsufficiency as the pathogenic mechanism. Here we tested whether catalytically dead Cas9 (dCas9)-mediated Scn1a gene activation can rescue Scn1a haploinsufficiency in a mouse DS model and restore physiological levels of its gene product, the Na(v)1.1 voltage-gated sodium channel. We screened single guide RNAs (sgRNAs) for their ability to stimulate Scn1a transcription in association with the dCas9 activation system. We identified a specific sgRNA that increases Scn1a gene expression levels in cell lines and primary neurons with high specificity. Na(v)1.1 protein levels were augmented, as was the ability of wild-type immature GABAergic interneurons to fire action potentials. A similar enhancement of Scn1a transcription was achieved in mature DS interneurons, rescuing their ability to fire. To test the therapeutic potential of this approach, we delivered the Scn1a-dCas9 activation system to DS pups using adeno-associated viruses. Parvalbumin interneurons recovered their firing ability, and febrile seizures were significantly attenuated. Our results pave the way for exploiting dCas9-based gene activation as an effective and targeted approach to DS and other disorders resulting from altered gene dosage.

Published
2019

23. Direct conversion of fibroblasts into functional astrocytes by defined transcription factors

Author

Carmine Settembre, Annamaria Carissimo, Gaia Colasante, Rosa Bartolomeo, Gabriele Lignani, Luca Massimino, Pierluigi Valente, Alessandro Sessa, Stefano Ferroni, Massimiliano Caiazzo, Vania Broccoli, Serena Giannelli, Fabio Benfenati, Caiazzo, Massimiliano, Giannelli, Serena, Valente, Pierluigi, Lignani, Gabriele, Carissimo, Annamaria, Sessa, Alessandro, Colasante, Gaia, Bartolomeo, Rosa, Massimino, Luca, Ferroni, Stefano, Settembre, Carmine, Benfenati, Fabio, Broccoli, Vania, Caiazzo, M, Giannelli, S, Valente, P, Lignani, G, Carissimo, A, Sessa, A, Colasante, G, Bartolomeo, R, Massimino, L, Ferroni, S, Settembre, C, Benfenati, F, Broccoli, V, and Broccoli, V.

Subjects
Transcription Factor, Cell, Gene Expression, Biochemistry, Membrane Potentials, Mice, Cluster Analysis, Induced pluripotent stem cell, lcsh:QH301-705.5, Cells, Cultured, lcsh:R5-920, Cultured, Cellular Reprogramming, Cell biology, medicine.anatomical_structure, Phenotype, NFIA, Cell Transdifferentiation, Cytokines, Fibroblast, Biological Markers, Animals, Astrocytes, Fibroblasts, Gene Expression Profiling, Humans, Transcription Factors, Cell Biology, Developmental Biology, Genetics, lcsh:Medicine (General), Astrocyte, Reprogramming, Human, Cell type, Cells, Biology, Membrane Potential, Article, medicine, Transcription factor, Cytokine, Cluster Analysi, Animal, Biomarker, Embryonic stem cell, lcsh:Biology (General), Biomarkers
Abstract

Summary Direct cell reprogramming enables direct conversion of fibroblasts into functional neurons and oligodendrocytes using a minimal set of cell-lineage-specific transcription factors. This approach is rapid and simple, generating the cell types of interest in one step. However, it remains unknown whether this technology can be applied to convert fibroblasts into astrocytes, the third neural lineage. Astrocytes play crucial roles in neuronal homeostasis, and their dysfunctions contribute to the origin and progression of multiple human diseases. Herein, we carried out a screening using several transcription factors involved in defining the astroglial cell fate and identified NFIA, NFIB, and SOX9 to be sufficient to convert with high efficiency embryonic and postnatal mouse fibroblasts into astrocytes (iAstrocytes). We proved both by gene-expression profiling and functional tests that iAstrocytes are comparable to native brain astrocytes. This protocol can be then employed to generate functional iAstrocytes for a wide range of experimental applications., Graphical Abstract, Highlights • NFIA, NFIB, and SOX9 reprogram fibroblasts into induced astrocytes (iAstrocytes) • iAstrocytes reprogramming induces a global change in gene-expression profiling • iAstrocytes are functionally comparable to native astrocytes • NFIA, NFIB, and SOX9 induce an astrocytic phenotype in human fibroblasts, In this article, Broccoli, Caiazzo, and colleagues developed a direct reprogramming approach to convert fibroblasts into induced astrocytes (iAstrocytes) by forcing the expression of the three astroglial transcription factors NFIA, NFIB, and SOX9. iAstrocytes are functionally comparable to native primary astrocytes as assessed by in vitro analyses and can be transplanted in the mouse brain. This study discloses the possibility to generate also human iAstrocytes for potential translational applications.

Published
2015

24. Epileptogenic Q555X SYN1 mutant triggers imbalances in release dynamics and short-term plasticity

Author

Enrico Ferrea, Gabriele Lignani, Tatiana Tkatch, Francesco Paonessa, Pietro Baldelli, Patrick Cossette, Flavia Valtorta, Andrea Raimondi, Fabio Benfenati, Anna Rocchi, Marta Orlando, Fabrizia Cesca, Lignani, G, Raimondi, A, Ferrea, E, Rocchi, A, Paonessa, F, Cesca, F, Orlando, M, Tkatch, T, Valtorta, F, Cossette, P, Baldelli, P, Benfenati, F, G., Lignani, A., Raimondi, E., Ferrea, A., Rocchi, F., Cesca, T., Tkatch, Valtorta, Flavia, P., Cossette, P., Baldelli, and F., Benfenati

Subjects
Epilepsy/*genetics/*metabolism, Hippocampus/metabolism, Patch-Clamp Techniques, Protein Multimerization, Phenotype, Neuronal Plasticity/*genetics, Intracellular Space, Gene Expression, Neurotransmission, Biology, Inhibitory postsynaptic potential, Epileptogenesis, Hippocampus, chemistry.chemical_compound, Mice, Genetics, synaptic transmission, Animals, Humans, Neurotransmitter, Molecular Biology, Genetics (clinical), Mice, Knockout, Neurons, synapsin, Neuronal Plasticity, synaptic plasticity, epilepsy, Long-term potentiation, General Medicine, Synapsin, Anatomy, Articles, Synaptic Potentials, Synapsins, Protein Transport, chemistry, Synaptic plasticity, Synapses, Excitatory postsynaptic potential, Female, Synaptic Vesicles, Neuroscience
Abstract

Synapsin I (SynI) is a synaptic vesicle (SV) phosphoprotein playing multiple roles in synaptic transmission and plasticity by differentially affecting crucial steps of SV trafficking in excitatory and inhibitory synapses. SynI knockout (KO) mice are epileptic, and nonsense and missense mutations in the human SYN1 gene have a causal role in idiopathic epilepsy and autism. To get insights into the mechanisms of epileptogenesis linked to SYN1 mutations, we analyzed the effects of the recently identified Q555X mutation on neurotransmitter release dynamics and short-term plasticity (STP) in excitatory and inhibitory synapses. We used patch-clamp electrophysiology coupled to electron microscopy and multi-electrode arrays to dissect synaptic transmission of primary SynI KO hippocampal neurons in which the human wild-type and mutant SynI were expressed by lentiviral transduction. A parallel decrease in the SV readily releasable pool in inhibitory synapses and in the release probability in excitatory synapses caused a marked reduction in the evoked synchronous release. This effect was accompanied by an increase in asynchronous release that was much more intense in excitatory synapses and associated with an increased total charge transfer. Q555X-hSynI induced larger facilitation and post-tetanic potentiation in excitatory synapses and stronger depression after long trains in inhibitory synapses. These changes were associated with higher network excitability and firing/bursting activity. Our data indicate that imbalances in STP and release dynamics of inhibitory and excitatory synapses trigger network hyperexcitability potentially leading to epilepsy/autism manifestations.

Published
2013

25. REST/NRSF-mediated intrinsic homeostasis protects neuronal networks from hyperexcitability

Author

Davide, Pozzi, Gabriele, Lignani, Enrico, Ferrea, Andrea, Contestabile, Francesco, Paonessa, Rosalba, D'Alessandro, Pellegrino, Lippiello, Davide, Boido, Anna, Fassio, Jacopo, Meldolesi, Flavia, Valtorta, Fabio, Benfenati, Pietro, Baldelli, Pozzi, D, Lignani, G, Ferrea, E, Contestabile, A, Paonessa, F, D’Alessandro, R, Lippiello, P, Boido, D, Fassio, A, Meldolesi, J, Valtorta, Flavia, Benfenati, F, and Baldelli, P.

Subjects
Neurons, 4-Aminopyridine/pharmacology, Cells, Cultured, Hippocampus/cytology/physiology, Homeostasis/drug effects/*physiology, Mice, Inbred C57BL, Neurons/physiology, Repressor Proteins/*physiology, synaptic plasticity, Hippocampus, Article, neuron, Mice, Inbred C57BL, Repressor Proteins, nervous system, Animals, Homeostasis, 4-Aminopyridine, Nerve Net, Cells, Cultured, transcription factor
Abstract

Intrinsic homeostasis enables neuronal circuits to maintain activity levels within an appropriate range by modulating neuronal voltage-gated conductances, but the signalling pathways involved in this process are largely unknown. We characterized the process of intrinsic homeostasis induced by sustained electrical activity in cultured hippocampal neurons based on the activation of the Repressor Element-1 Silencing Transcription Factor/Neuron-Restrictive Silencer Factor (REST/NRSF). We showed that 4-aminopyridine-induced hyperactivity enhances the expression of REST/NRSF, which in turn, reduces the expression of voltage-gated Na(+) channels, thereby decreasing the neuronal Na(+) current density. This mechanism plays an important role in the downregulation of the firing activity at the single-cell level, re-establishing a physiological spiking activity in the entire neuronal network. Conversely, interfering with REST/NRSF expression impaired this homeostatic response. Our results identify REST/NRSF as a critical factor linking neuronal activity to the activation of intrinsic homeostasis and restoring a physiological level of activity in the entire neuronal network.

Published
2013

27. Early developmental alterations of CA1 pyramidal cells in Dravet syndrome.

Author

Jones SP, O'Neill N, Carpenter JC, Muggeo S, Colasante G, Kullmann DM, and Lignani G

Subjects
Animals, Mice, Disease Models, Animal, Male, Mice, Transgenic, Neuronal Plasticity physiology, Neuronal Plasticity genetics, Mice, Inbred C57BL, Pyramidal Cells metabolism, Pyramidal Cells pathology, Epilepsies, Myoclonic genetics, Epilepsies, Myoclonic pathology, NAV1.1 Voltage-Gated Sodium Channel genetics, CA1 Region, Hippocampal metabolism, CA1 Region, Hippocampal pathology
Abstract

Dravet Syndrome (DS) is most often caused by heterozygous loss-of-function mutations in the voltage-gated sodium channel gene SCN1A (Na v 1.1), resulting in severe epilepsy and neurodevelopmental impairment thought to be cause by reduced interneuron excitability. However, recent studies in mouse models suggest that interneuron dysfunction alone does not completely explain all the cellular and network impairments seen in DS. Here, we investigated the development of the intrinsic, synaptic, and network properties of CA1 pyramidal cells in a DS model prior to the appearance of overt seizures. We report that CA1 pyramidal cell development is altered by heterozygous reduction of Scn1a, and propose that this is explained by a period of reduced intrinsic excitability in early postnatal life, during which Scn1a is normally expressed in hippocampal pyramidal cells. We also use a novel ex vivo model of homeostatic plasticity to show an instability in homeostatic response during DS epileptogenesis. This study provides evidence for the early effects of Scn1a haploinsufficiency in pyramidal cells in contributing to the pathophysiology of DS., Competing Interests: Declaration of competing interest No conflicts to declare., (Copyright © 2024 The Authors. Published by Elsevier Inc. All rights reserved.)

Published
2024
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28. Epg5 links proteotoxic stress due to defective autophagic clearance and epileptogenesis in Drosophila and Vici syndrome patients.

Author

Deneubourg C, Salimi Dafsari H, Lowe S, Martinez-Cotrina A, Mazaud D, Park SH, Vergani V, Almacellas Barbanoj A, Maroofian R, Averdunk L, Ghayoor-Karimiani E, Jayawant S, Mignot C, Keren B, Peters R, Kamath A, Mattas L, Verma S, Silwal A, Distelmaier F, Houlden H, Lignani G, Antebi A, Jepson J, Jungbluth H, and Fanto M

Abstract

Epilepsy is a common neurological condition that arises from dysfunctional neuronal circuit control due to either acquired or innate disorders. Autophagy is an essential neuronal housekeeping mechanism, which causes severe proteotoxic stress when impaired. Autophagy impairment has been associated to epileptogenesis through a variety of molecular mechanisms. Vici Syndrome (VS) is the paradigmatic congenital autophagy disorder in humans due to recessive variants in the ectopic P-granules autophagy tethering factor 5 ( EPG5 ) gene that is crucial for autophagosome-lysosome fusion and autophagic clearance. Here, we used Drosophila melanogaster to study the importance of Epg5 in development, aging, and seizures. Our data indicate that proteotoxic stress due to impaired autophagic clearance and seizure-like behaviors correlate and are commonly regulated, suggesting that seizures occur as a direct consequence of proteotoxic stress and age-dependent neurodegenerative progression. We provide complementary evidence from EPG5-mutated patients demonstrating an epilepsy phenotype consistent with Drosophila predictions. Abbreviations : AD: Alzheimer's disease; ALS-FTD: Amyotrophic Lateral Sclerosis-FrontoTemoporal Dementia; DART: Drosophila Arousal Tracking; ECoG: electrocorticogram; EEG: electroencephalogram; EPG5 : ectopic P-granules 5 autophagy tethering factor; KA: kainic acid; MBs: mushroom bodies; MRI magnetic resonance imaging; MTOR: mechanistic target of rapamycin kinase; PD: Parkinson's disease; TSC : TSC complex; VS: Vici syndrome.

Published
2024
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29. Neurodevelopmental and synaptic defects in DNAJC6 parkinsonism, amenable to gene therapy.

Author

Abela L, Gianfrancesco L, Tagliatti E, Rossignoli G, Barwick K, Zourray C, Reid KM, Budinger D, Ng J, Counsell J, Simpson A, Pearson TS, Edvardson S, Elpeleg O, Brodsky FM, Lignani G, Barral S, and Kurian MA

Subjects
Humans, Male, Female, Dopaminergic Neurons metabolism, Mutation, Synapses genetics, Synapses metabolism, Endocytosis physiology, Endocytosis genetics, Child, Genetic Therapy methods, HSP40 Heat-Shock Proteins genetics, HSP40 Heat-Shock Proteins metabolism, Induced Pluripotent Stem Cells metabolism, Parkinsonian Disorders genetics, Parkinsonian Disorders therapy, Parkinsonian Disorders metabolism, Auxilins genetics, Auxilins metabolism
Abstract

DNAJC6 encodes auxilin, a co-chaperone protein involved in clathrin-mediated endocytosis (CME) at the presynaptic terminal. Biallelic mutations in DNAJC6 cause a complex, early-onset neurodegenerative disorder characterized by rapidly progressive parkinsonism-dystonia in childhood. The disease is commonly associated with additional neurodevelopmental, neurological and neuropsychiatric features. Currently, there are no disease-modifying treatments for this condition, resulting in significant morbidity and risk of premature mortality. To investigate the underlying disease mechanisms in childhood-onset DNAJC6 parkinsonism, we generated induced pluripotent stem cells (iPSC) from three patients harbouring pathogenic loss-of-function DNAJC6 mutations and subsequently developed a midbrain dopaminergic neuronal model of disease. When compared to age-matched and CRISPR-corrected isogenic controls, the neuronal cell model revealed disease-specific auxilin deficiency as well as disturbance of synaptic vesicle recycling and homeostasis. We also observed neurodevelopmental dysregulation affecting ventral midbrain patterning and neuronal maturation. To explore the feasibility of a viral vector-mediated gene therapy approach, iPSC-derived neuronal cultures were treated with lentiviral DNAJC6 gene transfer, which restored auxilin expression and rescued CME. Our patient-derived neuronal model provides deeper insights into the molecular mechanisms of auxilin deficiency as well as a robust platform for the development of targeted precision therapy approaches., (© The Author(s) 2024. Published by Oxford University Press on behalf of the Guarantors of Brain.)

Published
2024
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30. An adaptable, reusable, and light implant for chronic Neuropixels probes.

Author

Bimbard C, Takács F, Catarino JA, Fabre JMJ, Gupta S, Lenzi SC, Melin MD, O'Neill N, Orsolic I, Robacha M, Street JS, Teixeira J, Townsend S, van Beest EH, Zhang AM, Churchland AK, Duan CA, Harris KD, Kullmann DM, Lignani G, Mainen ZF, Margrie TW, Rochefort NL, Wikenheiser AM, Carandini M, and Coen P

Abstract

Electrophysiology has proven invaluable to record neural activity, and the development of Neuropixels probes dramatically increased the number of recorded neurons. These probes are often implanted acutely, but acute recordings cannot be performed in freely moving animals and the recorded neurons cannot be tracked across days. To study key behaviors such as navigation, learning, and memory formation, the probes must be implanted chronically. An ideal chronic implant should (1) allow stable recordings of neurons for weeks; (2) allow reuse of the probes after explantation; (3) be light enough for use in mice. Here, we present the "Apollo Implant", an open-source and editable device that meets these criteria and accommodates up to two Neuropixels 1.0 or 2.0 probes. The implant comprises a "payload" module which is attached to the probe and is recoverable, and a "docking" module which is cemented to the skull. The design is adjustable, making it easy to change the distance between probes, the angle of insertion, and the depth of insertion. We tested the implant across eight labs in head-fixed mice, freely moving mice, and freely moving rats. The number of neurons recorded across days was stable, even after repeated implantations of the same probe. The Apollo implant provides an inexpensive, lightweight, and flexible solution for reusable chronic Neuropixels recordings.

Published
2024
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31. Anti-seizure gene therapy for focal cortical dysplasia.

Author

Almacellas Barbanoj A, Graham RT, Maffei B, Carpenter JC, Leite M, Hoke J, Hardjo F, Scott-Solache J, Chimonides C, Schorge S, Kullmann DM, Magloire V, and Lignani G

Subjects
Child, Humans, Mice, Animals, TOR Serine-Threonine Kinases genetics, TOR Serine-Threonine Kinases metabolism, Protein Serine-Threonine Kinases genetics, Seizures genetics, Seizures therapy, Genetic Therapy, Mammals genetics, Mammals metabolism, Focal Cortical Dysplasia, Epilepsy therapy, Epilepsy surgery, Malformations of Cortical Development genetics, Malformations of Cortical Development therapy, Malformations of Cortical Development metabolism
Abstract

Focal cortical dysplasias are a common subtype of malformation of cortical development, which frequently presents with a spectrum of cognitive and behavioural abnormalities as well as pharmacoresistant epilepsy. Focal cortical dysplasia type II is typically caused by somatic mutations resulting in mammalian target of rapamycin (mTOR) hyperactivity, and is the commonest pathology found in children undergoing epilepsy surgery. However, surgical resection does not always result in seizure freedom, and is often precluded by proximity to eloquent brain regions. Gene therapy is a promising potential alternative treatment and may be appropriate in cases that represent an unacceptable surgical risk. Here, we evaluated a gene therapy based on overexpression of the Kv1.1 potassium channel in a mouse model of frontal lobe focal cortical dysplasia. An engineered potassium channel (EKC) transgene was placed under control of a human promoter that biases expression towards principal neurons (CAMK2A) and packaged in an adeno-associated viral vector (AAV9). We used an established focal cortical dysplasia model generated by in utero electroporation of frontal lobe neural progenitors with a constitutively active human Ras homolog enriched in brain (RHEB) plasmid, an activator of mTOR complex 1. We characterized the model by quantifying electrocorticographic and behavioural abnormalities, both in mice developing spontaneous generalized seizures and in mice only exhibiting interictal discharges. Injection of AAV9-CAMK2A-EKC in the dysplastic region resulted in a robust decrease (∼64%) in the frequency of seizures. Despite the robust anti-epileptic effect of the treatment, there was neither an improvement nor a worsening of performance in behavioural tests sensitive to frontal lobe function. AAV9-CAMK2A-EKC had no effect on interictal discharges or behaviour in mice without generalized seizures. AAV9-CAMK2A-EKC gene therapy is a promising therapy with translational potential to treat the epileptic phenotype of mTOR-related malformations of cortical development. Cognitive and behavioural co-morbidities may, however, resist an intervention aimed at reducing circuit excitability., (© The Author(s) 2023. Published by Oxford University Press on behalf of the Guarantors of Brain.)

Published
2024
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32. Epilepsy-linked kinase CDKL5 phosphorylates voltage-gated calcium channel Cav2.3, altering inactivation kinetics and neuronal excitability.

Author

Sampedro-Castañeda M, Baltussen LL, Lopes AT, Qiu Y, Sirvio L, Mihaylov SR, Claxton S, Richardson JC, Lignani G, and Ultanir SK

Subjects
Animals, Child, Humans, Mice, Calcium Channels genetics, Protein Serine-Threonine Kinases genetics, Epilepsy genetics, Epileptic Syndromes genetics, Spasms, Infantile genetics
Abstract

Developmental and epileptic encephalopathies (DEEs) are a group of rare childhood disorders characterized by severe epilepsy and cognitive deficits. Numerous DEE genes have been discovered thanks to advances in genomic diagnosis, yet putative molecular links between these disorders are unknown. CDKL5 deficiency disorder (CDD, DEE2), one of the most common genetic epilepsies, is caused by loss-of-function mutations in the brain-enriched kinase CDKL5. To elucidate CDKL5 function, we looked for CDKL5 substrates using a SILAC-based phosphoproteomic screen. We identified the voltage-gated Ca 2+ channel Cav2.3 (encoded by CACNA1E) as a physiological target of CDKL5 in mice and humans. Recombinant channel electrophysiology and interdisciplinary characterization of Cav2.3 phosphomutant mice revealed that loss of Cav2.3 phosphorylation leads to channel gain-of-function via slower inactivation and enhanced cholinergic stimulation, resulting in increased neuronal excitability. Our results thus show that CDD is partly a channelopathy. The properties of unphosphorylated Cav2.3 closely resemble those described for CACNA1E gain-of-function mutations causing DEE69, a disorder sharing clinical features with CDD. We show that these two single-gene diseases are mechanistically related and could be ameliorated with Cav2.3 inhibitors., (© 2023. The Author(s).)

Published
2023
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34. Are Genetic Therapies for Epilepsy Ready for the Clinic?

Author

Street JS, Qiu Y, and Lignani G

Abstract

In recent years, there has been a significant increase in preclinical studies to test genetic therapies for epilepsy. Some of these therapies have advanced to clinical trials and are being tested in patients with monogenetic or focal refractory epilepsy. This article provides an overview of the current state of preclinical studies that show potential for clinical translation. Specifically, we focus on genetic therapies that have demonstrated a clear effect on seizures in animal models and have the potential to be translated to clinical settings. Both therapies targeting the cause of the disease and those that treat symptoms are discussed. We believe that the next few years will be crucial in determining the potential of genetic therapies for treating patients with epilepsy., Competing Interests: The author(s) declared the following potential conflicts of interest with respect to the research, authorship, and/or publication of this article: GL and YQ are listed as inventors on Patent WO2021191474A; GL has equity in a company that aims to bring epilepsy gene therapy to the clinic, with no involvement with this manuscript., (© The Author(s) 2023.)

Published
2023
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37. Ca 2+ binding to synapsin I regulates resting Ca 2+ and recovery from synaptic depression in nerve terminals.

Author

Moschetta M, Ravasenga T, De Fusco A, Maragliano L, Aprile D, Orlando M, Sacchetti S, Casagrande S, Lignani G, Fassio A, Baldelli P, and Benfenati F

Subjects
Animals, Mice, Adenosine Triphosphate metabolism, Mice, Knockout, Synaptic Vesicles metabolism, Calcium metabolism, Depression, Synapsins metabolism
Abstract

Synapsin I (SynI) is a synaptic vesicle (SV)-associated phosphoprotein that modulates neurotransmission by controlling SV trafficking. The SynI C-domain contains a highly conserved ATP binding site mediating SynI oligomerization and SV clustering and an adjacent main Ca 2+ binding site, whose physiological role is unexplored. Molecular dynamics simulations revealed that the E373K point mutation irreversibly deletes Ca 2+ binding to SynI, still allowing ATP binding, but inducing a destabilization of the SynI oligomerization interface. Here, we analyzed the effects of this mutation on neurotransmitter release and short-term plasticity in excitatory and inhibitory synapses from primary hippocampal neurons. Patch-clamp recordings showed an increase in the frequency of miniature excitatory postsynaptic currents (EPSCs) that was totally occluded by exogenous Ca 2+ chelators and associated with a constitutive increase in resting terminal Ca 2+ concentrations. Evoked EPSC amplitude was also reduced, due to a decreased readily releasable pool (RRP) size. Moreover, in both excitatory and inhibitory synapses, we observed a marked impaired recovery from synaptic depression, associated with impaired RRP refilling and depletion of the recycling pool of SVs. Our study identifies SynI as a novel Ca 2+ buffer in excitatory terminals. Blocking Ca 2+ binding to SynI results in higher constitutive Ca 2+ levels that increase the probability of spontaneous release and disperse SVs. This causes a decreased size of the RRP and an impaired recovery from depression due to the failure of SV reclustering after sustained high-frequency stimulation. The results indicate a physiological role of Ca 2+ binding to SynI in the regulation of SV clustering and trafficking in nerve terminals., (© 2022. The Author(s).)

Published
2022
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38. On-demand cell-autonomous gene therapy for brain circuit disorders.

Author

Qiu Y, O'Neill N, Maffei B, Zourray C, Almacellas-Barbanoj A, Carpenter JC, Jones SP, Leite M, Turner TJ, Moreira FC, Snowball A, Shekh-Ahmad T, Magloire V, Barral S, Kurian MA, Walker MC, Schorge S, Kullmann DM, and Lignani G

Subjects
Humans, Brain metabolism, Seizures genetics, Seizures therapy, Seizures metabolism, Animals, Mice, Neurons physiology, Epilepsy genetics, Epilepsy therapy, Genetic Therapy, Kv1.1 Potassium Channel genetics
Abstract

Several neurodevelopmental and neuropsychiatric disorders are characterized by intermittent episodes of pathological activity. Although genetic therapies offer the ability to modulate neuronal excitability, a limiting factor is that they do not discriminate between neurons involved in circuit pathologies and "healthy" surrounding or intermingled neurons. We describe a gene therapy strategy that down-regulates the excitability of overactive neurons in closed loop, which we tested in models of epilepsy. We used an immediate early gene promoter to drive the expression of Kv1.1 potassium channels specifically in hyperactive neurons, and only for as long as they exhibit abnormal activity. Neuronal excitability was reduced by seizure-related activity, leading to a persistent antiepileptic effect without interfering with normal behaviors. Activity-dependent gene therapy is a promising on-demand cell-autonomous treatment for brain circuit disorders.

Published
2022
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41. Electrophysiological Properties of Human Cortical Organoids: Current State of the Art and Future Directions.

Author

Zourray C, Kurian MA, Barral S, and Lignani G

Abstract

Human cortical development is an intricate process resulting in the generation of many interacting cell types and long-range connections to and from other brain regions. Human stem cell-derived cortical organoids are now becoming widely used to model human cortical development both in physiological and pathological conditions, as they offer the advantage of recapitulating human-specific aspects of corticogenesis that were previously inaccessible. Understanding the electrophysiological properties and functional maturation of neurons derived from human cortical organoids is key to ensure their physiological and pathological relevance. Here we review existing data on the electrophysiological properties of neurons in human cortical organoids, as well as recent advances in the complexity of cortical organoid modeling that have led to improvements in functional maturation at single neuron and neuronal network levels. Eventually, a more comprehensive and standardized electrophysiological characterization of these models will allow to better understand human neurophysiology, model diseases and test novel treatments., Competing Interests: The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest., (Copyright © 2022 Zourray, Kurian, Barral and Lignani.)

Published
2022
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42. Scn1a gene reactivation after symptom onset rescues pathological phenotypes in a mouse model of Dravet syndrome.

Author

Valassina N, Brusco S, Salamone A, Serra L, Luoni M, Giannelli S, Bido S, Massimino L, Ungaro F, Mazzara PG, D'Adamo P, Lignani G, Broccoli V, and Colasante G

Subjects
Action Potentials physiology, Animals, Cerebellum metabolism, Cerebellum physiopathology, Cerebral Cortex metabolism, Cerebral Cortex physiopathology, Cognitive Dysfunction metabolism, Cognitive Dysfunction physiopathology, Cognitive Dysfunction prevention & control, Corpus Striatum metabolism, Corpus Striatum physiopathology, Dependovirus genetics, Dependovirus metabolism, Disease Models, Animal, Epilepsies, Myoclonic metabolism, Epilepsies, Myoclonic physiopathology, Epilepsies, Myoclonic prevention & control, Gene Knock-In Techniques, Genetic Therapy methods, Hippocampus physiopathology, Humans, Interneurons pathology, Male, Mice, Mice, Inbred C57BL, Mice, Transgenic, NAV1.1 Voltage-Gated Sodium Channel deficiency, Sudden Unexpected Death in Epilepsy pathology, Cognitive Dysfunction genetics, Epilepsies, Myoclonic genetics, Hippocampus metabolism, Interneurons metabolism, NAV1.1 Voltage-Gated Sodium Channel genetics, Sudden Unexpected Death in Epilepsy prevention & control
Abstract

Dravet syndrome is a severe epileptic encephalopathy caused primarily by haploinsufficiency of the SCN1A gene. Repetitive seizures can lead to endurable and untreatable neurological deficits. Whether this severe pathology is reversible after symptom onset remains unknown. To address this question, we generated a Scn1a conditional knock-in mouse model (Scn1a  Stop/+ ) in which Scn1a expression can be re-activated on-demand during the mouse lifetime. Scn1a gene disruption leads to the development of seizures, often associated with sudden unexpected death in epilepsy (SUDEP) and behavioral alterations including hyperactivity, social interaction deficits and cognitive impairment starting from the second/third week of age. However, we showed that Scn1a gene re-activation when symptoms were already manifested (P30) led to a complete rescue of both spontaneous and thermic inducible seizures, marked amelioration of behavioral abnormalities and normalization of hippocampal fast-spiking interneuron firing. We also identified dramatic gene expression alterations, including those associated with astrogliosis in Dravet syndrome mice, that, accordingly, were rescued by Scn1a gene expression normalization at P30. Interestingly, regaining of Na v 1.1 physiological level rescued seizures also in adult Dravet syndrome mice (P90) after months of repetitive attacks. Overall, these findings represent a solid proof-of-concept highlighting that disease phenotype reversibility can be achieved when Scn1a gene activity is efficiently reconstituted in brain cells., (© 2022. The Author(s).)

Published
2022
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43. REST/NRSF drives homeostatic plasticity of inhibitory synapses in a target-dependent fashion.

Author

Prestigio C, Ferrante D, Marte A, Romei A, Lignani G, Onofri F, Valente P, Benfenati F, and Baldelli P

Subjects
Animals, Cells, Cultured, GABA Agents, Green Fluorescent Proteins genetics, Green Fluorescent Proteins metabolism, Hippocampus cytology, Homeostasis, Mice, Inbred C57BL, Neurons physiology, Receptor, trkB metabolism, Synapses metabolism, Transcription Factors, Mice, Inhibitory Postsynaptic Potentials physiology, Neurons metabolism, Repressor Proteins metabolism
Abstract

The repressor-element 1-silencing transcription/neuron-restrictive silencer factor (REST/NRSF) controls hundreds of neuron-specific genes. We showed that REST/NRSF downregulates glutamatergic transmission in response to hyperactivity, thus contributing to neuronal homeostasis. However, whether GABAergic transmission is also implicated in the homeostatic action of REST/NRSF is unknown. Here, we show that hyperactivity-induced REST/NRSF activation, triggers a homeostatic rearrangement of GABAergic inhibition, with increased frequency of miniature inhibitory postsynaptic currents (IPSCs) and amplitude of evoked IPSCs in mouse cultured hippocampal neurons. Notably, this effect is limited to inhibitory-onto-excitatory neuron synapses, whose density increases at somatic level and decreases in dendritic regions, demonstrating a complex target- and area-selectivity. The upscaling of perisomatic inhibition was occluded by TrkB receptor inhibition and resulted from a coordinated and sequential activation of the Npas4 and Bdnf gene programs. On the opposite, the downscaling of dendritic inhibition was REST-dependent, but BDNF-independent. The findings highlight the central role of REST/NRSF in the complex transcriptional responses aimed at rescuing physiological levels of network activity in front of the ever-changing environment., Competing Interests: CP, DF, AM, AR, GL, FO, PV, FB, PB No competing interests declared, (© 2021, Prestigio et al.)

Published
2021
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44. Aromatic l-amino acid decarboxylase deficiency: a patient-derived neuronal model for precision therapies.

Author

Rossignoli G, Krämer K, Lugarà E, Alrashidi H, Pope S, De La Fuente Barrigon C, Barwick K, Bisello G, Ng J, Counsell J, Lignani G, Heales SJR, Bertoldi M, Barral S, and Kurian MA

Subjects
Aromatic-L-Amino-Acid Decarboxylases metabolism, Humans, Amino Acid Metabolism, Inborn Errors metabolism, Aromatic-L-Amino-Acid Decarboxylases deficiency, Dopamine Agents pharmacology, Induced Pluripotent Stem Cells, Levodopa pharmacology, Neurogenesis, Neurons drug effects
Abstract

Aromatic l-amino acid decarboxylase (AADC) deficiency is a complex inherited neurological disorder of monoamine synthesis which results in dopamine and serotonin deficiency. The majority of affected individuals have variable, though often severe cognitive and motor delay, with a complex movement disorder and high risk of premature mortality. For most, standard pharmacological treatment provides only limited clinical benefit. Promising gene therapy approaches are emerging, though may not be either suitable or easily accessible for all patients. To characterize the underlying disease pathophysiology and guide precision therapies, we generated a patient-derived midbrain dopaminergic neuronal model of AADC deficiency from induced pluripotent stem cells. The neuronal model recapitulates key disease features, including absent AADC enzyme activity and dysregulated dopamine metabolism. We observed developmental defects affecting synaptic maturation and neuronal electrical properties, which were improved by lentiviral gene therapy. Bioinformatic and biochemical analyses on recombinant AADC predicted that the activity of one variant could be improved by l-3,4-dihydroxyphenylalanine (l-DOPA) administration; this hypothesis was corroborated in the patient-derived neuronal model, where l-DOPA treatment leads to amelioration of dopamine metabolites. Our study has shown that patient-derived disease modelling provides further insight into the neurodevelopmental sequelae of AADC deficiency, as well as a robust platform to investigate and develop personalized therapeutic approaches., (© The Author(s) (2021). Published by Oxford University Press on behalf of the Guarantors of Brain.)

Published
2021
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45. Gene Editing and Modulation: the Holy Grail for the Genetic Epilepsies?

Author

Carpenter JC and Lignani G

Subjects
Humans, CRISPR-Cas Systems genetics, Epilepsy genetics, Epilepsy therapy, Gene Editing methods, Genetic Therapy methods, Precision Medicine methods
Abstract

Epilepsy is a complex neurological disorder for which there are a large number of monogenic subtypes. Monogenic epilepsies are often severe and disabling, featuring drug-resistant seizures and significant developmental comorbidities. These disorders are potentially amenable to a precision medicine approach, of which genome editing using CRISPR/Cas represents the holy grail. Here we consider mutations in some of the most 'common' rare epilepsy genes and discuss the different CRISPR/Cas approaches that could be taken to cure these disorders. We consider scenarios where CRISPR-mediated gene modulation could serve as an effective therapeutic strategy and discuss whether a single gene corrective approach could hold therapeutic potential in the context of homeostatic compensation in the developing, highly dynamic brain. Despite an incomplete understanding of the mechanisms of the genetic epilepsies and current limitations of gene editing tools, CRISPR-mediated approaches have game-changing potential in the treatment of genetic epilepsy over the next decade., (© 2021. The Author(s).)

Published
2021
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46. Gene therapy restores dopamine transporter expression and ameliorates pathology in iPSC and mouse models of infantile parkinsonism.

Author

Ng J, Barral S, De La Fuente Barrigon C, Lignani G, Erdem FA, Wallings R, Privolizzi R, Rossignoli G, Alrashidi H, Heasman S, Meyer E, Ngoh A, Pope S, Karda R, Perocheau D, Baruteau J, Suff N, Antinao Diaz J, Schorge S, Vowles J, Marshall LR, Cowley SA, Sucic S, Freissmuth M, Counsell JR, Wade-Martins R, Heales SJR, Rahim AA, Bencze M, Waddington SN, and Kurian MA

Subjects
Animals, Disease Models, Animal, Dopamine Plasma Membrane Transport Proteins genetics, Dopamine Plasma Membrane Transport Proteins metabolism, Humans, Mice, Substantia Nigra metabolism, Genetic Therapy, Induced Pluripotent Stem Cells metabolism, Parkinsonian Disorders genetics, Parkinsonian Disorders therapy
Abstract

Most inherited neurodegenerative disorders are incurable, and often only palliative treatment is available. Precision medicine has great potential to address this unmet clinical need. We explored this paradigm in dopamine transporter deficiency syndrome (DTDS), caused by biallelic loss-of-function mutations in SLC6A3 , encoding the dopamine transporter (DAT). Patients present with early infantile hyperkinesia, severe progressive childhood parkinsonism, and raised cerebrospinal fluid dopamine metabolites. The absence of effective treatments and relentless disease course frequently leads to death in childhood. Using patient-derived induced pluripotent stem cells (iPSCs), we generated a midbrain dopaminergic (mDA) neuron model of DTDS that exhibited marked impairment of DAT activity, apoptotic neurodegeneration associated with TNFα-mediated inflammation, and dopamine toxicity. Partial restoration of DAT activity by the pharmacochaperone pifithrin-μ was mutation-specific. In contrast, lentiviral gene transfer of wild-type human SLC6A3 complementary DNA restored DAT activity and prevented neurodegeneration in all patient-derived mDA lines. To progress toward clinical translation, we used the knockout mouse model of DTDS that recapitulates human disease, exhibiting parkinsonism features, including tremor, bradykinesia, and premature death. Neonatal intracerebroventricular injection of human SLC6A3 using an adeno-associated virus (AAV) vector provided neuronal expression of human DAT, which ameliorated motor phenotype, life span, and neuronal survival in the substantia nigra and striatum, although off-target neurotoxic effects were seen at higher dosage. These were avoided with stereotactic delivery of AAV2.SLC6A3 gene therapy targeted to the midbrain of adult knockout mice, which rescued both motor phenotype and neurodegeneration, suggesting that targeted AAV gene therapy might be effective for patients with DTDS., (Copyright © 2021 The Authors, some rights reserved; exclusive licensee American Association for the Advancement of Science. No claim to original U.S. Government Works.)

Published
2021
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47. Progressive myoclonus epilepsy KCNC1 variant causes a developmental dendritopathy.

Author

Carpenter JC, Männikkö R, Heffner C, Heneine J, Sampedro-Castañeda M, Lignani G, and Schorge S

Subjects
Animals, Humans, Interneurons pathology, Mice, Mice, Inbred C57BL, Mutation, Myoclonic Epilepsies, Progressive genetics, Dendrites pathology, Myoclonic Epilepsies, Progressive physiopathology, Neurogenesis genetics, Shaw Potassium Channels genetics
Abstract

Objective: Mutations in KCNC1 can cause severe neurological dysfunction, including intellectual disability, epilepsy, and ataxia. The Arg320His variant, which occurs in the voltage-sensing domain of the channel, causes a highly penetrant and specific form of progressive myoclonus epilepsy with severe ataxia, designated myoclonus epilepsy and ataxia due to potassium channel mutation (MEAK). KCNC1 encodes the voltage-gated potassium channel K V 3.1, a channel that is important for enabling high-frequency firing in interneurons, raising the possibility that MEAK is associated with reduced interneuronal function., Methods: To determine how this variant triggers MEAK, we expressed K V 3.1b R320H in cortical interneurons in vitro and investigated the effects on neuronal function and morphology. We also performed electrophysiological recordings of oocytes expressing K V 3.1b to determine whether the mutation introduces gating pore currents., Results: Expression of the K V 3.1b R320H variant profoundly reduced excitability of mature cortical interneurons, and cells expressing these channels were unable to support high-frequency firing. The mutant channel also had an unexpected effect on morphology, severely impairing neurite development and interneuron viability, an effect that could not be rescued by blocking K V 3 channels. Oocyte recordings confirmed that in the adult K V 3.1b isoform, R320H confers a dominant negative loss-of-function effect by slowing channel activation, but does not introduce potentially toxic gating pore currents., Significance: Overall, our data suggest that, in addition to the regulation of high-frequency firing, K V 3.1 channels play a hitherto unrecognized role in neuronal development. MEAK may be described as a developmental dendritopathy., (© 2021 The Authors. Epilepsia published by Wiley Periodicals LLC on behalf of International League Against Epilepsy.)

Published
2021
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49. Recent advances in gene therapy for neurodevelopmental disorders with epilepsy.

Author

Turner TJ, Zourray C, Schorge S, and Lignani G

Subjects
Animals, Cognitive Dysfunction genetics, Epilepsy etiology, Epilepsy genetics, Humans, Intellectual Disability genetics, Neurodevelopmental Disorders complications, Neurodevelopmental Disorders therapy, Neurons physiology, Cognitive Dysfunction therapy, Epilepsy therapy, Genetic Therapy methods, Intellectual Disability therapy, Neurodevelopmental Disorders genetics
Abstract

Neurodevelopmental disorders can be caused by mutations in neuronal genes fundamental to brain development. These disorders have severe symptoms ranging from intellectually disability, social and cognitive impairments, and a subset are strongly linked with epilepsy. In this review, we focus on those neurodevelopmental disorders that are frequently characterized by the presence of epilepsy (NDD + E). We loosely group the genes linked to NDD + E with different neuronal functions: transcriptional regulation, intrinsic excitability and synaptic transmission. All these genes have in common a pivotal role in defining the brain architecture and function during early development, and when their function is altered, symptoms can present in the first stages of human life. The relationship with epilepsy is complex. In some NDD + E, epilepsy is a comorbidity and in others seizures appear to be the main cause of the pathology, suggesting that either structural changes (NDD) or neuronal communication (E) can lead to these disorders. Furthermore, grouping the genes that cause NDD + E, we review the uses and limitations of current models of the different disorders, and how different gene therapy strategies are being developed to treat them. We highlight where gene replacement may not be a treatment option, and where innovative therapeutic tools, such as CRISPR-based gene editing, and new avenues of delivery are required. In general this group of genetically defined disorders, supported increasing knowledge of the mechanisms leading to neurological dysfunction serve as an excellent collection for illustrating the translational potential of gene therapy, including newly emerging tools., (© 2020 The Authors. Journal of Neurochemistry published by John Wiley & Sons Ltd on behalf of International Society for Neurochemistry.)

Published
2021
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50. In vivo Genome Editing Therapeutic Approaches for Neurological Disorders: Where Are We in the Translational Pipeline?

Author

Lubroth P, Colasante G, and Lignani G

Abstract

In vivo genome editing tools, such as those based on CRISPR, have been increasingly utilized in both basic and translational neuroscience research. There are currently nine in vivo non-CNS genome editing therapies in clinical trials, and the pre-clinical pipeline of major biotechnology companies demonstrate that this number will continue to grow. Several biotechnology companies commercializing in vivo genome editing and modification technologies are developing therapies for CNS disorders with accompanying large partnering deals. In this review, the authors discuss the current genome editing and modification therapy pipeline and those in development to treat CNS disorders. The authors also discuss the technical and commercial limitations to translation of these same therapies and potential avenues to overcome these hurdles., Competing Interests: PL was employed by Hummingbird Ventures. The remaining authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest., (Copyright © 2021 Lubroth, Colasante and Lignani.)

Published
2021
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