A neurotrophin functioning with a Toll regulates structural plasticity in a dopaminergic circuit. Jun Sun, Francisca Rojo-Cortés, Suzana Ulian-Benitez, Manuel G. Forero, Guiyi Li, Deepanshu Singh, Xiaocui Wang, Sebastian Cachero, Marta Moreira, Dean Kavanagh, Gregory Jefferis, Vincent Croset, Alicia Hidalgo. (2024) eLife https://doi.org/10.7754/eLife.10222.1
Fungi activate Toll-1 dependent immune evasion to induce cell loss in the host brain. Deepanshu N.D. Singh, Abigail R.E. Roberts, Enrique Quesada Moraga, David Alliband, Elizabeth Ballou, Hung-Ji Tsai, Alicia Hidalgo. bioRxiv DOI https://doi.org/10.1101/2024.04.29.591341
Circuit structural plasticity by a neurotrophin with a Toll modifies behaviour. Jun Sun, Suzana Ulian-Benitez, Manuel G. Forero, Guiyi Li, Deepanshu Singh, Francisca Rojo-Cortés, Xiaocui Wang, Sebastian Cachero, Marta Moreira, Dean Kavanagh, Gregory Jefferis, Vincent Croset, Alicia Hidalgo. bioRxiv DOI https://doi.org/10.1101/2023.01.04.522695
Regenerative neurogenic response from glia requires insulin-driven neuron-glia communication. Neale J Harrison, Elizabeth Connolly, Alicia Gascón Gubieda, Zidan Yang, Benjamin Altenhein, Maria Losada Perez, Marta Moreira, Jun Sun, Alicia Hidalgo (2021) eLife DOI: 10.7554/eLife.58756
The Toll Route to Structural Brain Plasticity. Guiyi Li, Alicia Hidalgo (2021) Frontiers in Physiology DOI: 10.3389/fphys.2021.679766
A Toll-receptor map underlies structural brain plasticity (2020) Guiyi Li, Manuel G Forero, Jill S Wentzell, Ilgim Durmus, Reinhard Wolf, Niki C Anthoney, Mieczyslaw Parker, Ruiying Jiang, Jacob Hasenauer, Nicholas James Strausfeld, Martin Heisenberg, Alicia Hidalgo. eLife DOI: 10.7554/eLife.52743
- eLife Digest article 17 March 2020 dedicated to our paper: “How experience changes your brain”: https://elifesciences.org/digests/52743/how-experience-shapes-the-brain
Adult Neurogenesis in the Drosophila Brain: The Evidence and the Void. Guiyi Li, Alicia Hidalgo (2020) International Journal of Molecular Sciences DOI: 10.3390/ijms21186653
Toll and Toll-like receptor signalling in development. Niki Anthoney, Istvan Foldi, Alicia Hidalgo (2018) Development DOI: 10.1242/dev.156018
Gene network underlying the glial regenerative response to central nervous system injury. K Kato, M Losada‐Perez, A Hidalgo. Developmental dynamics DOI: 10.1002/dvdy.24565
Kek-6: a truncated-Trk-like receptor for Drosophila neurotrophin 2 regulates structural synaptic plasticity. S Ulian-Benitez, S Bishop, I Foldi, J Wentzell, C Okenwa, M G Forero, B Zhu, M Moreira, M Phizacklea, G McIlroy, G Li, NJ Gay, A Hidalgo (2017) PLoS genetics DOI: 10.1371/journal.pgen.1006968
Go and stop signals for glial regeneration. A Hidalgo, A Logan. Current opinion in neurobiology DOI: 10.1016/j.conb.2017.10.011
Three-tier regulation of cell number plasticity by neurotrophins and Tolls in Drosophila. I Foldi, N Anthoney, N Harrison, M Gangloff, B Verstak, M Ponnadai Nallasivan, S AlAhmed, B Zhu, M Phizacklea, M Losada-Perez, M Moreira, N J Gay, A Hidalgo (2017). Journal of Cell Biology DOI: 10.1083/jcb.201607098
- Selected by J Cell Biology as “One of the Top 10 articles published in 2017”
- Selected for special collection on Stem Cells in Development 2018
https://rupress.org/jcb/collection/46/Stem-Cells-and-Development-2018
- Selected for a special collection on “Cellular Neurobiology” 2018
- See highlight preview dedicated to our article: Austin B. Keeler, Christopher D. Deppmann (2017) The evolutionary origins of antagonistic neurotrophin signaling.
Glial kon/NG2 gene network for central nervous system repair. Maria Losada-Perez, Neale Harrison, Alicia Hidalgo. Neural regeneration research DOI: 10.4103/1673-5374.198969
Molecular mechanism of central nervous system repair by the Drosophila NG2 homologue kon-tiki
M Losada-Perez, N Harrison, A Hidalgo (2016) Journal of Cell Biology 214 (5), 587-601
Prox1 inhibits proliferation and is required for differentiation of the oligodendrocyte cell lineage in the mouse K Kato, D Konno, M Berry, F Matsuzaki, A Logan, A Hidalgo (2015) PLoS one 10 (12), e0145334
Neuron-type specific functions of DNT1, DNT2 and Spz at the Drosophila neuromuscular junction
B Sutcliffe, MG Forero, B Zhu, IM Robinson, A Hidalgo (2013) PloS one 8 (10), e75902
Toll-6 and Toll-7 function as neurotrophin receptors in the Drosophila melanogaster CNS
G McIlroy, I Foldi, J Aurikko, JS Wentzell, MA Lim, JC Fenton, NJ Gay, A Hidalgo (2013) Nature neuroscience 16 (9), 1248-1256
- Recommended x2 by Faculty of 1000 http://f1000.com/prime/718049779?bd=1&ui=21597
An injury paradigm to investigate central nervous system repair in Drosophila K Kato, A Hidalgo (2013) Journal of Visualized Experiments), e50306
Genetic systems for functional cell ablation in Drosophila ST Sweeney, A Hidalgo, JS de Belle, H Keshishian (2012) Cold Spring Harbor Protocols 2012 (9), pdb. top068361
TUNEL-antibody double-labeling method for Drosophila embryos ST Sweeney, A Hidalgo, JS de Belle, H Keshishian (2012) Cold Spring Harbor Protocols 2012 (9), pdb. prot068379
Automatic cell counting in vivo in the larval nervous system of Drosophila MG Forero, K Kato, A Hidalgo (2012) Journal of microscopy 246 (2), 202-212
Trophic neuron‐glia interactions and cell number adjustments in the fruit fly A Hidalgo, K Kato, B Sutcliffe, G Mcilroy, S Bishop, S Alahmed (2011) Glia 59 (9), 1296-1303
The glial regenerative response to central nervous system injury is enabled by pros-notch and pros-NFκB feedback K Kato, MG Forero, JC Fenton, A Hidalgo (2011) PLoS biology 9 (8), e1001133
- Editorial highlight PLoS Biol 9(8): e1001136. https://doi.org/10.1371/journal.pbio.1001136
- BBSRC highlight: https://www.birmingham.ac.uk/news/latest/2011/08/30aug-scientists-uncover-gene-network-responsible-for-repair-of-the-central-nervous-system-of-the-fruit-fly.aspx
Image processing methods for automatic cell counting in vivo or in situ using 3D confocal microscopy MG Forero, A Hidalgo (2011) Advanced Biomedical Engineering, Dr Gaetano Giuliano (Ed) InTech, 183-204
Deadeasy Mito-Glia: Automatic counting of mitotic cells and glial cells in Drosophila MG Forero, AR Learte, S Cartwright, A Hidalgo (2010) PLoS one 5 (5), e10557
DeadEasy neurons: automatic counting of HB9 neuronal nuclei in Drosophila MG Forero, JA Pennack, A Hidalgo (2010) Cytometry Part A:
1st Joint Meeting of the British and Spanish Developmental Biology Societies A Hidalgo, L Martin-Bermudo (2009) International Journal of Developmental Biology 53 (4), 443-446
DeadEasy caspase MG Forero, J Pennack, A Rodriguez-Learte, A Hidalgo (2009)
Drosophila Neurotrophins Reveal a Common Mechanism for Nervous System Formation B Zhu, JA Pennack, P McQuilton, MG Forero, K Mizuguchi, B Sutcliffe, J Fenton, A Hidalgo (2008) PLoS biology 6 (11), e284
- Recommended by Faculty of 1000: http://f1000.com/prime/1158489
Gliatrophic and gliatropic roles of PVF/PVR signaling during axon guidance AR Learte, MG Forero, A Hidalgo (2008) Glia 56 (2), 164-176
The role of glial cells in axon guidance, fasciculation and targeting AR Learte, A Hidalgo (2008) Axon Growth and Guidance, 156-166
Two distinct mechanisms segregate Prospero in the longitudinal glia underlying the timing of interactions with axons RC Griffiths, J Benito-Sipos, JC Fenton, L Torroja, A Hidalgo (2007) Neuron glia biology 3 (1), 75-88
Correction of depth intensity attenuation in confocal images of Drosophila embryos MG Forero, J Pennack, AR Learte, A Hidalgo (2006) AIP Conference Proceedings 860 (1), 397-400
Neurotrophic and gliatrophic contexts in Drosophila A Hidalgo, AR Learte, P McQuilton, J Pennack, B Zhu (2006) Brain, behavior and evolution 68 (3), 173-180
Coupling glial numbers and axonal patterns A Hidalgo, R Griffiths (2004) Cell Cycle 3 (9), 1116-1118
Prospero maintains the mitotic potential of glial precursors enabling them to respond to neurons RL Griffiths, A Hidalgo (2004) The EMBO Journal 23 (12), 2440-2450
Lateral neuron–glia interactions steer the response of axons to the Robo code EFV Kinrade, A Hidalgo (2004) Neuron glia biology 1 (2), 101-112
The control of cell number during central nervous system development in flies and mice A Hidalgo, C French-Constant (2003) Mechanisms of development 120 (11), 1311-1325
Neuron–glia interactions during axon guidance in Drosophila A Hidalgo (2003) Biochemical Society Transactions 31 (1), 50-55
Interactive nervous system development: control of cell survival in Drosophila A Hidalgo (2002) Trends in Neurosciences 25 (7), 365-370
The Drosophila neuregulin vein maintains glial survival during axon guidance in the CNS A Hidalgo, EFV Kinrade, M Georgiou (2001) Developmental Cell 1 (5), 679-690
- Dedicated mini-reviews: Beck & Fainzibler (2002) Neuron 33 and Leslie (2001) JCBiol 155
Roundabout signalling, cell contact and trophic support confine longitudinal glia and axons in the Drosophila CNS EF Kinrade, T Brates, G Tear, A Hidalgo (2001) Development 128 (2), 207-216
Glia dictate pioneer axon trajectories in the Drosophila embryonic CNS A Hidalgo, GE Booth (2000) Development 127 (2), 393-402
Glia maintain follower neuron survival during Drosophila CNS development GE Booth, EF Kinrade, A Hidalgo (2000) Development 127 (2), 237-244
- Review dedicated to our findings: Shepherd (2000) Bioessays 22, 407-9
CELL ABLATION 15 A POWERFUL TOOL IN THE STUDY of eukaryotic developmental biology ST Sweeney, A Hidalgo (2000) Drosophila Protocols, 449
CHEMICAL ABLATION (2000) ST Sweeney, A Hidalgo, JS de Belle, H Keshishian. Drosophila protocols, 449
Wing patterning knot untangled A Hidalgo (1998) BioEssays 20 (6), 449-452
Growth and patterning from the engrailed interface. A Hidalgo (1998) International Journal of Developmental Biology 42 (3), 317-324
Targeted neuronal ablation: the role of pioneer neurons in guidance and fasciculation in the CNS of Drosophila A Hidalgo, AH Brand (1997) Development 124 (17), 3253-3262
The roles of engrailed A Hidalgo (1996) Trends in Genetics 12 (1), 1-4
Targeted ablation of glia disrupts axon tract formation in the Drosophila CNS A Hidalgo, J Urban, AH Brand (1995) Development 121 (11), 3703-3712
Three distinct roles for the engrailed gene in Drosophila wing development. A Hidalgo (1994) Current Biology 4 (12), 1087-1098
Regulation of wingless transcription in the Drosophila embryo. PW Ingham, A Hidalgo (1993) Development 117 (1), 283-291
Interactions between segment polarity genes and the generation of the segmental pattern in Drosophila. A Hidalgo (1991) Mechanisms of Development 35 (2), 77-87
Cell patterning in the Drosophila segment: spatial regulation of the segment polarity gene patched. A Hidalgo, P Ingham (1990) Development 110 (1), 291-301
Advantages and limitations of in situ. PW Ingham, A Hidalgo, AM Taylor (1990) In Situ Hybridisation: Application to Developmental Biology and Medicine, 97
A protein with several possible membrane-spanning domains encoded by the Drosophila segment polarity gene patched. Y Nakano, I Guerrero, A Hidalgo, A Taylor, JRS Whittle, PW Ingham (1989) Nature 341 (6242), 508-513
A Pvu II polymorphism in the 5′ flanking region of the apolipoprotein AIV gene: its use to study genetic variation determining serum lipid and apolipoprotein concentration. AM Kessling, R Taylor, A Temple, J Hutson, A Hidalgo, SE Humphries (1988) Human genetics 78 (3), 237-239