Catherina Becker Explained

Catherina Gwynne Becker
Birth Date:1964 10, df=y
Birth Place:Marburg, West Germany
(now Germany)
Nationality:German
Fields:Regenerative Neuroscience
Workplaces:TU Dresden, University of Edinburgh
Alma Mater:University of Bremen

Catherina Gwynne Becker (née Krüger) is an Alexander von Humboldt Professor at TU Dresden,[1] and was formerly Professor of Neural Development and Regeneration at the University of Edinburgh.[2]

Early life and education

Catherina Becker was born in Marburg, Germany in 1964. She was educated at the in Bremen, before going on to study at the University of Bremen where she obtained an MSci of Biology and her PhD (Dr. rer. nat.) in 1993, investigating visual system development and regeneration in frogs and salamanders under the supervision of Gerhard Roth.[3] [4] She then trained as post-doctorate at the Swiss Federal Institute of Technology in Zürich, the Department Dev Cell Biol funded by an EMBO long-term fellowship, at the University of California, Irvine in USA and the Centre for Molecular Neurobiology Hamburg (ZMNH), Germany where she took a position of group leader in 2000 and finished her ‚Habilitation‘ in neurobiology in 2012.

Career

Becker joined the University of Edinburgh in 2005 as senior Lecturer and was appointed personal chair in neural development and regeneration in 2013. She was also the Director of Postgraduate Training at the Centre for Neuroregeneration up to 2015, then centre director up to 2017. In 2021 she received an Alexander von Humboldt Professorship, joining the [5] at the Technical University of Dresden. She was elected President of that Center in 2024.

Research

Becker's research focuses on a better understanding of the factors governing the generation of neurons and axonal pathfinding in the CNS during development and regeneration using the zebrafish model to identify fundamental mechanisms in vertebrates with clear translational implications for CNS injury and neurodegenerative diseases.[6] The Becker group established the zebrafish as a model for spinal cord regeneration.[7] [8] Their research found that functional regeneration is near perfect, but anatomical repair does not fully recreate the previous network, instead, new neurons are generated and extensive rewiring occurs.[9] [10] [11] [12] They have identified neurotransmitter signalling as one mechanism underlying regenerative neurogenesis.[13] [14] More recently, they have established larval regeneration paradigms in which highly selective cell ablation can be introduced[15] and fundamental principles of functional repair, regenerative neurogenesis and rewiring can be analyzed.[16] [17] This system is scalable, allowing fast genetic screens into spinal cord repair.[18]

Catherina Becker is on the executive board of the European Zebrafish Society EZB e.V. and on the advisory board of the International Society for Regenerative Biology ISRB.[19] [20]

Awards

Notes and References

  1. Web site: Alexander-von-Humboldt Professorship . AvH press releases . July 2021 . Alexander von Humboldt Foundation . 5 August 2021.
  2. Web site: Becker . Catherina . Beckers' group . Discovery Brain Science . University of Edinburgh . 11 March 2020.
  3. Distribution of NCAM-180 and polysialic acid in the developing tectum mesencephali of the frog Discoglossus pictus and the salamander Pleurodeles waltl. . Cell and Tissue Research . 1993 . 272 . 289–301 . 8513482 . Becker . C. G. . Becker . T. . Roth . G. . 2 . 10.1007/BF00302734 . 21421453 .
  4. Amphibian-specific regulation of polysialic acid and the neural cell adhesion molecule in development and regeneration of the retinotectal system of the salamander Pleurodeles waltl. . Journal of Comparative Neurology . 1993 . 336 . 532–544 . 8245224 . Becker . T. . Becker . C. G. . Niemann . U. . Naujoks-Manteuffel . C. . Gerardy-Schahn . R. . Roth . G. . 4 . 10.1002/cne.903360406 . 40389071 .
  5. Web site: Becker . Catherina . Becker Group CRTD . CRTD . TU Dresden . 9 August 2021.
  6. Web site: Beckers' Projects . Edinburgh Research Explorer . The University of Edinburgh . 11 March 2020.
  7. Axonal regrowth after spinal cord transection in adult zebrafish. Journal of Comparative Neurology. 1997. 377. 577–595. 9007194 . Becker. Thomas. Wullimann. Mario F.. Becker. Catherina G.. Bernhardt. Robert R.. Schachner. Melitta. 4. 10.1002/(sici)1096-9861(19970127)377:4<577::aid-cne8>3.0.co;2-# . 196584792.
  8. Book: 10.1002/9783527610365 . Model Organisms in Spinal Cord Regeneration . 2006 . 9783527315048 . Becker . Becker . Catherina G . Thomas .
  9. Motor neuron regeneration in adult zebrafish . Journal of Neuroscience . 2008 . 20 . 8510–6 . 18716209 . Becker . T . Becker . C.G. . Reimer . M M . 34 . 6671064 . 10.1523/JNEUROSCI.1189-08.2008 .
  10. Sonic hedgehog is a polarized signal for motor neuron regeneration in adult zebrafish . Journal of Neuroscience . 2009 . 29 . 15073–82 . 19955358 . Becker . T . Becker . C.G. . Reimer . M M . 48 . 2841428 . 10.1523/JNEUROSCI.4748-09.2009 .
  11. Plasticity of tyrosine hydroxylase and serotonergic systems in the regenerating spinal cord of adult zebrafish . Journal of Comparative Neurology . 2012 . 520 . 933–51 . 21830219 . Becker . T . Becker . C.G. . Kuscha . V . 5 . 10.1002/cne.22739 . 1462095.
  12. Lesion-induced generation of interneuron cell types in specific dorsoventral domains in the spinal cord of adult zebrafish . Journal of Comparative Neurology . 2012 . 520 . 3604–16 . 22473852 . Becker . T . Becker . C.G. . Kuscha . V . 16 . 10.1002/cne.23115 . 20.500.11820/f7a31eeb-8583-4171-a8cc-8ff3ddd0b99d . 13184342. free .
  13. Dopamine from the brain promotes spinal motor neuron generation during development and adult regeneration . Developmental Cell . 2013 . 25 . 478–491 . 23707737 . Becker . T . Becker . C.G. . Reimer . M M . 5 . 10.1016/j.devcel.2013.04.012 . free .
  14. Serotonin Promotes Development and Regeneration of Spinal Motor Neurons in Zebrafish . Cell Reports . 2015 . 13 . 924–932 . 26565906 . Becker . T . Becker . C.G. . Barreiro-Iglesias . A . 5 . 10.1016/j.celrep.2015.09.050. 4635313 .
  15. Spinal motor neurons are regenerated after mechanical lesion and genetic ablation in larval zebrafish . Development . 2016 . 143 . 577–95 . 26965370 . Becker . T . Becker . C.G. . Ohnmacht . J . 9 . 10.1242/dev.129155 . 4986163 . 11840634.
  16. Wnt signaling controls pro-regenerative Collagen XII in functional spinal cord regeneration in zebrafish . Nature Communications . 2017 . 8 . 28743881 . Becker . T . Becker . C.G. . Wehner . D . 1 . 126 . 10.1038/s41467-017-00143-0 . 5526933 . 2017NatCo...8..126W . 26098327.
  17. Dynamic control of proinflammatory cytokines Il-1β and Tnf-α by macrophages in zebrafish spinal cord regeneration . Nature Communications. 2018 . 9 . 30405119 . Becker . T . Becker . C.G. . Tsarouchas . T.M. . 1 . 4670 . 10.1038/s41467-018-07036-w . 6220182 . 2018NatCo...9.4670T . 53207557.
  18. Keatinge . M . Tsarouchas . T.M. . Munir . T . Larraz . J . Gianni . D . Tsai . H . Becker . C.G. . Lyons . D.A. . Becker . T . 2020 . Phenotypic screening using synthetic CRISPR gRNAs reveals pro-regenerative genes in spinal cord injury . 10.1101/2020.04.03.023119.
  19. Web site: Board. European Zebrafish Society.
  20. Web site: Our Advisory Board. International Society for Regenerative Biology.
  21. Web site: MRC Suffrage in Science Award . Ed archive . 7 April 2017 . The University of Edinburgh . 11 March 2020.
  22. Web site: Eurolife Distinguished Lecture . Ed archive . 13 May 2016 . The University of Edinburgh . 11 March 2020.