Cheryll Tickle

Cheryll Tickle
Born
Cheryll Anne Tickle

(1945-01-18) 18 January 1945 (age 79)[1]
Alma mater
AwardsEMBO Member (2001)
Scientific career
FieldsDevelopmental biology
Institutions
ThesisQuantitative studies on the positioning of cells in aggregates (1970)
Doctoral advisorAdam S. G. Curtis
Websiteresearchportal.bath.ac.uk/en/persons/cheryll-tickle Edit this at Wikidata

Cheryll Anne Tickle (born 18 January 1945) is a British scientist, known for her work in developmental biology and specifically for her research into the process by which vertebrate limbs develop ab ovo. She is an emeritus professor at the University of Bath.[2]

Education

Tickle was educated at the University of Cambridge graduating with a masters degree in 1967, and received her PhD from the University of Glasgow in 1970.[3][4]

Career and research

Tickle worked as a postdoctoral researcher at Yale University, as a lecturer and reader at the Middlesex Hospital Medical School, and (after Middlesex merged with it in 1987) a reader and professor at University College London. She then moved to the University of Dundee in 1998, where she became Foulerton Professor of the Royal Society in 2000, and moved again to the University of Bath in 2007, retaining the Foulerton Professor title.[5][6]

Tickle's research in developmental biology investigates how single cells, the fertilised egg, gives rise to a new individual during embryogenesis.[7][8][9][10][11][12][13][14][15][16][17][18][19][20]

As Tickle was nearing the end of her undergraduate career at the University of Cambridge, the concept of sorting-out was on the rise. Sorting-out or cell sorting is the phenomenon where cultured cells are disaggregated and then re-aggregated with the purpose of observing the reestablishment of the spatial organization of cell structures within a cell.[21]

Following the completion of her PhD in 1970, Tickle was given a NATO fellowship where she completed a postdoc in the United States working with John Philip Trinkaus at Yale University on cell sorting in fish embryos. After two years, Tickle moved back to London where she worked with Lewis Wolpert, who had been her PhD supervisor. At this time, she decided that she was going to focus on the effects of positional or pattern information on the sorting out process of cells during the limb development of chicken embryos. Tickle’s hypothesis was that if cells of the embryonic limb were to be given distinct characteristics in a random arrangement the cells would arrange themselves into a generated pattern or “sort out”.[21]

In 1969, a scientist named John Saunders established that the apical ectodermal ridge (AER)--a transparent rim along limb buds—plays an important role in the development or outgrowth of a limb along with the zone of polarizing activity(ZPA). Using these findings, Tickle focused her research on how the ZPA controlled the development of the limb, specifically along the anterior and posterior axis of a developing limb as this axis is controlled by the signaling of the ZPA.[21]

It was at this time that Wolpert suggested that the ZPA produced morphogen to create a concentration gradient so that cells at varying positions along the limb bud would be exposed to different concentrations ultimately providing them with the information necessary to develop into the appropriate number of digits. In other words, he believed that the distance from the polarizing region would lead to the formation of different digits during limb development. Tickle’s experiments in his lab on embryonic chicken wings did find that the type of digit that developed did depend on its distance from the polarizing region. Cells closest to the polarizing region on the posterior side of the limb would come in contact with higher concentrations of morphogen to then form a chicken digit 4, whereas the cells furthest from the polarizing region on the anterior side of the limb would experience much lower concentrations and therefore develop the chicken digit 2. These results were important in the field of developmental biology at this time, as it suggested that this model would be a definitive way of understanding how the polarizing region or ZPA worked.[21]

In 1976, Bruce Alberts, an American biochemist, brought the concept of using beads to further their research in the development of limbs. Together, they came up with the idea to soak the beads in extracts made from the polarizing region and then position them along the anterior margin of a developing chicken limb. There was also little known about what other chemicals were utilized during development, so the beads were soaked in many other substances thought to be significant, including insulin which was suggested to lead to duplication of limbs in ducks. In the early 1980’s, Tickle’s lab identified retinoic acid as a chemical that could mimic the signaling of the polarizing region by using carriers soaked in the retinoic acid.[21]

By 1990, it was discovered that homologs of many developmentally important genes in vertebrates were found in Drosophila melanogaster and multiple scientists cloned chick homologs of these genes. Cheryll Tickle worked alongside Eddy De Robertis and Denis Duboule to look at Hox gene expression in developing limbs to relate it to chicken wing patterns. They found that if a limb was duplicated with retinoic acid, the pattern of Hox gene expression would also be copied.[21]

Tickle also worked with Gail Martin and Lee Niswander in 1994 to find that fibroblast growth factors (FGF) are what is used by the apical ectodermal ridge for signaling. They also discovered that bone morphogenetic proteins (BMP) were involved in the polarizing region signaling. To test this, Tickle utilized the bead technology introduced by Bruce Alberts by using particular beads to apply various chemicals to developing limbs. When the ACR was removed and FGF soaked beads were substituted within a chick wing bud, it was found to be able to promote proper chicken wing development. This was a significant finding that led to further discovery of this concept within mice by Gail Martin on a more complex scale. A student in Tickle’s lab found that the placement of a bead soaked with FGF for only a few hours could induce the development of a new limb where one would not naturally form. It was concluded that FGF signaling must be turned off following the completion of limb development or else the organism risks additional digit formation and other abnormalities taking place.[21]

Awards and honours

Tickle was elected a Fellow of the Royal Society (FRS) in 1998, a Fellow of the Royal Society of Edinburgh (FRSE) in 2000, a Fellow of the Academy of Medical Sciences (FMedSci) in 2001, and a member of the European Molecular Biology Organisation in 2001. In 2004 the University of St. Andrews awarded her an honorary doctorate. In 2005 she was named a Commander of The Most Excellent Order of the British Empire (CBE).[22] She also serves as a governor of the Caledonian Research Foundation.[23] Her nomination for the Royal Society reads:

Distinguished for her contribution to developmental biology. She demonstrated a quantitative relationship between the signal from the polarizing region in the embryo limb and the pattern digits, and that a similar signal was present in mammals. She discovered that local application of retinoic acid can mimic the signal from the polarizing region. Both these signals were shown to control homeobox gene expression. She has now shown that the signal from the apical ridge which is essential for limb development is a fibroblast growth factor. Her work is characterized by outstanding experimental skill, design and interpretation.[24]

Personal life

Tickle married John Gray in 1979.[1]

References

  1. ^ a b Anon (2014). "Tickle, Prof. Cheryll Anne". Who's Who (online Oxford University Press ed.). Oxford: A & C Black. doi:10.1093/ww/9780199540884.013.U37707. (Subscription or UK public library membership required.)
  2. ^ Cheryll Tickle's publications indexed by the Scopus bibliographic database. (subscription required)
  3. ^ Tickle, Cheryll Anne (1970). Quantitative studies on the positioning of cells in aggregates. gla.ac.uk (PhD thesis). University of Glasgow. OCLC 181893787. EThOS uk.bl.ethos.776431.
  4. ^ Gosling, R.; Tickle, C.; Running, S. W.; Tandong, Y.; Dinnyes, A.; Osowole, A. A.; Cule, E. (2011). "Seven ages of the PhD". Nature. 472 (7343): 283–286. Bibcode:2011Natur.472..283G. doi:10.1038/472283a. PMID 21512550. S2CID 4416716.
  5. ^ Speaker profile, CDB Symposium 2005, Center for Developmental Biology, Japan.
  6. ^ Faculty profile, Department of Biology and Biochemistry, Univ. of Bath. Archived 30 April 2009 at the Wayback Machine
  7. ^ Tickle C (January 2006). "Making digit patterns in the vertebrate limb". Nat. Rev. Mol. Cell Biol. 7 (1): 45–53. doi:10.1038/nrm1830. PMID 16493412. S2CID 13114684.
  8. ^ Tickle C (September 2004). "The contribution of chicken embryology to the understanding of vertebrate limb development". Mech. Dev. 121 (9): 1019–29. doi:10.1016/j.mod.2004.05.015. PMID 15296968. S2CID 18213529.
  9. ^ Tickle C, Cole NJ (June 2004). "Morphological diversity: taking the spine out of three-spine stickleback". Curr. Biol. 14 (11): R422–4. doi:10.1016/j.cub.2004.05.034. PMID 15182689.
  10. ^ Cole NJ, Tanaka M, Prescott A, Tickle C (December 2003). "Expression of limb initiation genes and clues to the morphological diversification of threespine stickleback". Curr. Biol. 13 (24): R951–2. doi:10.1016/j.cub.2003.11.039. PMID 14680650. S2CID 14454615.
  11. ^ Tickle C (April 2003). "Patterning systems--from one end of the limb to the other". Dev. Cell. 4 (4): 449–58. doi:10.1016/S1534-5807(03)00095-9. PMID 12689585.
  12. ^ Brown WR, Hubbard SJ, Tickle C, Wilson SA (February 2003). "The chicken as a model for large-scale analysis of vertebrate gene function". Nat. Rev. Genet. 4 (2): 87–98. doi:10.1038/nrg998. PMID 12560806. S2CID 4608120.
  13. ^ Tickle C (2000). "Limb development: an international model for vertebrate pattern formation". Int. J. Dev. Biol. 44 (1): 101–8. PMID 10761854.
  14. ^ Tickle C, Münsterberg A (August 2001). "Vertebrate limb development--the early stages in chick and mouse" (PDF). Curr. Opin. Genet. Dev. 11 (4): 476–81. doi:10.1016/S0959-437X(00)00220-3. PMID 11448636.
  15. ^ Clarke JD, Tickle C (August 1999). "Fate maps old and new". Nat. Cell Biol. 1 (4): E103–9. doi:10.1038/12105. PMID 10559935. S2CID 26933239.
  16. ^ Tickle C, Altabef M (August 1999). "Epithelial cell movements and interactions in limb, neural crest and vasculature". Curr. Opin. Genet. Dev. 9 (4): 455–60. doi:10.1016/S0959-437X(99)80069-0. PMID 10449346.
  17. ^ Cohn MJ, Tickle C (July 1996). "Limbs: a model for pattern formation within the vertebrate body plan". Trends Genet. 12 (7): 253–7. doi:10.1016/0168-9525(96)10030-5. PMID 8763496.
  18. ^ Niswander, Lee (1994). "A positive feedback loop coordinates growth and patterning in the vertebrate limb". Nature. 371 (6498): 609–612. Bibcode:1994Natur.371..609N. doi:10.1038/371609a0. PMID 7935794. S2CID 4305639.
  19. ^ Niswander, L; Tickle, C; Vogel, A; Booth, I; Martin, G. R. (1993). "FGF-4 replaces the apical ectodermal ridge and directs outgrowth and patterning of the limb". Cell. 75 (3): 579–87. doi:10.1016/0092-8674(93)90391-3. PMID 8221896. S2CID 27128022.
  20. ^ Cohn, M. J.; Izpisúa-Belmonte, J. C.; Abud, H; Heath, J. K.; Tickle, C (1995). "Fibroblast growth factors induce additional limb development from the flank of chick embryos". Cell. 80 (5): 739–46. doi:10.1016/0092-8674(95)90352-6. PMID 7889567.
  21. ^ a b c d e f g 70 Years of Hamburger & Hamilton - a free online symposium, retrieved 28 November 2021
  22. ^ Honours and awards, College of Life Sciences, Univ. of Dundee. Archived 17 October 2008 at the Wayback Machine
  23. ^ About the Caledonian Research Foundation. Archived 9 May 2008 at the Wayback Machine
  24. ^ "EC/1998/37: Tickle, Cheryll Anne". London: The Royal Society. Archived from the original on 24 January 2016. Retrieved 17 July 2014.