Bill Wickstead

Contact

• workRoom D118 Medical School
  Queen's Medical Centre
  Nottingham
  NG7 2UH
  UK
• work0115 8230383
• bill.wickstead@nottingham.ac.uk
• http://www.wicksteadlab.co.uk

Research Summary

My research interests include genome architecture, chromosome segregation, molecular motor function and multigene-family evolution. The uniting factor behind these topics is the importance they have… read more

Recent Publications

• AWUAH-MENSAH, GEORGINA, MCDONALD, JENNIFER, STEKETEE, PIETER C, AUTHEMAN, DELPHINE, WHIPPLE, SARAH, D'ARCHIVIO, SIMON, BRANDT, CORDELIA, CLARE, SIMON, HARCOURT, KATHERINE, WRIGHT, GAVIN J, MORRISON, LIAM J, GADELHA, CATARINA and WICKSTEAD, BILL, 2021. Reliable, scalable functional genetics in bloodstream-form Trypanosoma congolense in vitro and in vivo, PLoS Pathog. 17(1), e1009224
• BRUSINI, LORENZO, D'ARCHIVIO, SIMON, MCDONALD, JENNIFER and WICKSTEAD, BILL, 2021. Trypanosome KKIP1 Dynamically Links the Inner Kinetochore to a Kinetoplastid Outer Kinetochore Complex, Frontiers in Cellular and Infection Microbiology. 11, 641174
• DAVIES, CARYS, OOI, CHER-PHENG, SIOUTAS, GEORGIOS, HALL, BELINDA S, SIDHU, HANEESH, BUTTER, FALK, ALSFORD, SAM, WICKSTEAD, BILL and RUDENKO, GLORIA, 2021. TbSAP is a novel chromatin protein repressing metacyclic variant surface glycoprotein expression sites in bloodstream form Trypanosoma brucei, Nucleic Acids Res. 49, 3242-3262
• LEONARD, GUY, LABARRE, AUR�LIE, MILNER, DAVID S, MONIER, ADAM, SOANES, DARREN, WIDEMAN, JEREMY G, MAGUIRE, FINLAY, STEVENS, SAM, SAIN, DIVYA, GRAU-BOV�, XAVIER, SEB�-PEDR�S, ARNAU, STAJICH, JASON E, PASZKIEWICZ, KONRAD, BROWN, MATTHEW W, HALL, NEIL, WICKSTEAD, BILL and RICHARDS, THOMAS A, 2018. Comparative genomic analysis of the 'pseudofungus' Hyphochytrium catenoides, Open Biol. 8(1), 170184

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Current Research

My research interests include genome architecture, chromosome segregation, molecular motor function and multigene-family evolution. The uniting factor behind these topics is the importance they have to understanding the biology of the parasite Trypanosoma brucei. Much of the research in the lab also integrates bioinformatic and mathematical tools with wet-bench work. The use of these tools - particularly in an age where so much genomic information is becoming available - can greatly speed-up biological research and help us to ask the right questions of the systems we study.

More information regarding the lab's research can be found at: www.wicksteadlab.co.uk.

African trypanosomes and antigenic variation

Trypanosoma brucei is a single-celled parasite of the blood which causes the disease "sleeping sickness" in humans. The disease kills ~50 000 annually in sub-Saharan regions and has been identified by the World Health Organisation as a neglected tropical disease. A related disease of cattle, n'gana, also has a major detrimental economic impact in some of Africa's poorest regions. The parasite is transmitted by the bite of the tsetse fly, and is unusual in parasitizing the bloodstream in an exclusively extracellular form - effectively in full view of the immune system. This feat is achieved by the parasite expressing a series of immunologically-distinct cell surface coats - a process known as antigenic variation. Trypanosome antigenic variation is an extreme version of a strategy of immune evasion used by a great number of parasites and pathogens (including malaria parasites, Giardia, Borrelia, Neisseria, and HIV), and understanding how trypanosomes achieve it is relevant to understanding other diseases as well as sleeping sickness itself.

Genome architecture and segregation

The genome of T. brucei is highly adapted to the organism's lifestyle; around 20% of the entire genome sequence is dedicated to the process of antigenic variation. This includes a large number (~100) of linear minichromosomes, which serve as a reservoir for genes encoding cell surface proteins. At cell division, all of these chromosomes are segregated by the mitotic spindle with great fidelity. However, the chromosomes far out-number the spindle microtubules and the molecular details of this segregation mechanism are almost entirely unknown. The lab is currently working to discover the components of the mitotic machinery in trypanosomes and what features of the small chromosomes enable them to interact with the spindle. This will reveal how an essential part of the trypanosome cell functions and will also tell us about the evolution of mitosis in other organisms.

Molecular motors

The mitotic spindle is a specific part of the wider cytoskeleton - a system of filaments and molecular motors that is crucial for cell shape, division, movement and growth. There are three major classes of motor protein that move on the cytoskeleton of eukaryotes (that is, more complex non-bacterial organisms) - myosins, kinesins and dyneins. Only kinesins have thus-far been seen to be ubiquitously present in all eukaryotes, with losses of either all myosins or all dyneins from particular branches of the eukaryotic tree. All three motor classes are superfamilies of proteins encompassing multiple types with specific functions. The lab has worked extensively to characterize the types of motor found in cells and in this way has discovered "new" families of motors for which little functional data are available. Work in the lab is characterizing these families and also testing the function of unclassified motors in trypanosome growth and division.

Evolution of the cell

Trypanosomes are unlike model organisms like yeast in several key ways. However, trypanosomes share a common ancestor with all other eukaryotes and the features of this lineage evolved from the same ancestral cell. With the advent of genome sequencing for increasing numbers of eukaryotes, it is becoming possible to compare the complete content of multiple organisms. In this way, we can make predictions about the functions performed by a specific organism, even when that function has not been directly observed. Moreover, by inferring the genomic content of the ancestors to particular lineages, it is possible to look back in time to "observe" long extinct cells in terms of their encoded biology. The lab is using these comparative genomic methods to reconstruct the evolution of key features of eukaryotic cells.

• AWUAH-MENSAH, GEORGINA, MCDONALD, JENNIFER, STEKETEE, PIETER C, AUTHEMAN, DELPHINE, WHIPPLE, SARAH, D'ARCHIVIO, SIMON, BRANDT, CORDELIA, CLARE, SIMON, HARCOURT, KATHERINE, WRIGHT, GAVIN J, MORRISON, LIAM J, GADELHA, CATARINA and WICKSTEAD, BILL, 2021. Reliable, scalable functional genetics in bloodstream-form Trypanosoma congolense in vitro and in vivo, PLoS Pathog. 17(1), e1009224
• BRUSINI, LORENZO, D'ARCHIVIO, SIMON, MCDONALD, JENNIFER and WICKSTEAD, BILL, 2021. Trypanosome KKIP1 Dynamically Links the Inner Kinetochore to a Kinetoplastid Outer Kinetochore Complex, Frontiers in Cellular and Infection Microbiology. 11, 641174
• DAVIES, CARYS, OOI, CHER-PHENG, SIOUTAS, GEORGIOS, HALL, BELINDA S, SIDHU, HANEESH, BUTTER, FALK, ALSFORD, SAM, WICKSTEAD, BILL and RUDENKO, GLORIA, 2021. TbSAP is a novel chromatin protein repressing metacyclic variant surface glycoprotein expression sites in bloodstream form Trypanosoma brucei, Nucleic Acids Res. 49, 3242-3262
• LEONARD, GUY, LABARRE, AUR�LIE, MILNER, DAVID S, MONIER, ADAM, SOANES, DARREN, WIDEMAN, JEREMY G, MAGUIRE, FINLAY, STEVENS, SAM, SAIN, DIVYA, GRAU-BOV�, XAVIER, SEB�-PEDR�S, ARNAU, STAJICH, JASON E, PASZKIEWICZ, KONRAD, BROWN, MATTHEW W, HALL, NEIL, WICKSTEAD, BILL and RICHARDS, THOMAS A, 2018. Comparative genomic analysis of the 'pseudofungus' Hyphochytrium catenoides, Open Biol. 8(1), 170184
• ABBAS, ALI HADI, PEREIRA, SARA SILVA, D'ARCHIVIO, SIMON, WICKSTEAD, BILL, MORRISON, LIAM J., HALL, NEIL, HERTZ-FOWLER, CHRISTIANE, DARBY, ALISTAIR C. and JACKSON, ANDREW P., 2018. The Structure of a Conserved Telomeric Region Associated with Variant Antigen Loci in the Blood Parasite Trypanosoma congolense GENOME BIOLOGY AND EVOLUTION. 10(9), 2458-2473
• PATEL JT, BELSHAM HR, RATHBONE AJ, WICKSTEAD B, GELL C and FRIEL CT, 2016. The family-specific α4-helix of the kinesin-13, MCAK, is critical to microtubule end recognition. Open biology. 6(10),
• D'ARCHIVIO S and WICKSTEAD B, 2016. Trypanosome outer kinetochore proteins suggest conservation of chromosome segregation machinery across eukaryotes. The Journal of cell biology.
• RACHEL, R.A., YAMAMOTO, E.A., DEWANJEE, M.K., MAY-SIMERA, H.L., SERGEEV, Y.V., HACKETT, A.N., POHIDA, K., MUNASINGHE, J., GOTOH, N., WICKSTEAD, B., FARISS, R.N., DONG, L., LI, T. and SWAROOP, A., 2015. CEP290 alleles in mice disrupt tissue-specific cilia biogenesis and recapitulate features of syndromic ciliopathies. Hum Mol Genet. 24(13), 3775-3791
• ROQUES, M., WALL, R.J., DOUGLASS, A.P., RAMAPRASAD, A., FERGUSON, D.J., KAINDAMA, M.L., BRUSINI, L., JOSHI, N., RCHIAD, Z., BRADY, D., GUTTERY, D.S., WHEATLEY, S.P., YAMANO, H., HOLDER, A.A., PAIN, A., WICKSTEAD, B. and TEWARI, R., 2015. Plasmodium P-Type Cyclin CYC3 Modulates Endomitotic Growth during Oocyst Development in Mosquitoes. PLoS Pathog. 11(11), e1005273
• GADELHA, C., ZHANG, W., CHAMBERLAIN, J.W., CHAIT, B.T., WICKSTEAD, B. and FIELD, M.C., 2015. Architecture of a Host-Parasite Interface: Complex Targeting Mechanisms Revealed Through Proteomics. Mol Cell Proteomics. 14(7), 1911-1926
• GADELHA C, ZHANG W, CHAMBERLAIN JW, CHAIT BT, WICKSTEAD B and FIELD MC, 2015. Architecture of a Host-Parasite Interface: Complex Targeting Mechanisms Revealed Through Proteomics. Molecular & cellular proteomics : MCP. 14(7), 1911-26
• STANNE TM, NARAYANAN MS, RIDEWOOD S, LING A, WITMER K, KUSHWAHA M, WIESLER S, WICKSTEAD B, WOOD J and RUDENKO G, 2015. Identification of the ISWI Chromatin Remodeling Complex of the Early Branching Eukaryote Trypanosoma brucei. The Journal of biological chemistry. 290(45), 26954-67
• GUTTERY DS, POULIN B, RAMAPRASAD A, WALL RJ, FERGUSON DJP, BRADY D, PATZEWITZ E, WHIPPLE S, STRASCHIL U, WRIGHT MH, MOHAMED AMAH, RADHAKRISHNAN A, AROLD ST, TATE EW, HOLDER AA, WICKSTEAD B, PAIN A and TEWARI R, 2014. Genome-wide functional analysis of Plasmodium protein phosphatases reveals key regulators of parasite development and differentiation. Cell host & microbe. 16(1), 128-40
• CROSS GAM, KIM H and WICKSTEAD B, 2014. Capturing the variant surface glycoprotein repertoire (the VSGnome) of Trypanosoma brucei Lister 427. Molecular and biochemical parasitology. 195(1), 59-73
• POULIN B, PATZEWITZ E, BRADY D, SILVIE O, WRIGHT MH, FERGUSON DJP, WALL RJ, WHIPPLE S, GUTTERY DS, TATE EW, WICKSTEAD B, HOLDER AA and TEWARI R, 2013. Unique apicomplexan IMC sub-compartment proteins are early markers for apical polarity in the malaria parasite. Biology open. 2(11), 1160-70
• WHEELER RJ, SCHEUMANN N, WICKSTEAD B, GULL K and VAUGHAN S, 2013. Cytokinesis in Trypanosoma brucei differs between bloodstream and tsetse trypomastigote forms: implications for microtubule-based morphogenesis and mutant analysis. Molecular microbiology. 90(6), 1339-55
• DE LEON JC, SCHEUMANN N, BEATTY W, BECK JR, TRAN JQ, YAU C, BRADLEY PJ, GULL K, WICKSTEAD B and MORRISSETTE NS, 2013. A SAS-6-like protein suggests that the Toxoplasma conoid complex evolved from flagellar components. Eukaryotic cell. 12(7), 1009-19
• GUTTERY, D.S., POULIN, B., FERGUSON, D.J.P., SZÖŐR, B., WICKSTEAD, B., CARROLL, P.L., RAMAKRISHNAN, C., BRADY, D., PATZEWITZ, E.-M., STRASCHIL, U., SOLYAKOV, L., GREEN, J.L., SINDEN, R.E., TOBIN, A.B., HOLDER, A.A. and TEWARI, R., 2012. A unique protein phosphatase with kelch-like domains (ppkl) in Plasmodium modulates ookinete differentiation, motility and invasion PLOS Pathogens. 8(9), e1002948
• DANIELS, J.P., GULL, K. and WICKSTEAD, B., 2012. The trypanosomatid-specific N terminus of RPA2 is required for RNA polymerase I assembly, localization, and function. Eukaryot Cell. 11(5), 662-672
• HODGES, M.E., WICKSTEAD, B., GULL, K. and LANGDALE, J.A., 2012. The evolution of land plant cilia. New Phytol. 195(3), 526-540
• SUNTER, J., WICKSTEAD, B., GULL, K. and CARRINGTON, M., 2012. A new generation of T7 RNA polymerase-independent inducible expression plasmids for Trypanosoma brucei. PLoS One. 7(4), e35167
• KELLY, S., WICKSTEAD, B. and GULL, K., 2011. Archaeal phylogenomics provides evidence in support of a methanogenic origin of the Archaea and a thaumarchaeal origin for the eukaryotes Proceedings of the Royal Society. B, Biological Sciences. 278(1708), 1009-1018
• WICKSTEAD, B. and GULL, K., 2011. The evolution of the cytoskeleton Journal of Cell Biology. 194(4), 513-525
• WICKSTEAD, BILL and GULL, KEITH, 2011. The evolutionary biology of dyneins. In: KING, STEPHEN, ed., Dyneins: Structure, biology and disease Academic Press. 88-121
• HODGES, MATTHEW E, WICKSTEAD, BILL, GULL, KEITH and LANGDALE, JANE A, 2011. Conservation of ciliary proteins in plants with no cilia BMC Plant Biol. 11(1), 185
• WICKSTEAD, BILL, CARRINGTON, JAMIE T, GLUENZ, EVA and GULL, KEITH, 2010. The expanded Kinesin-13 repertoire of trypanosomes contains only one mitotic Kinesin indicating multiple extra-nuclear roles. PloS one. 5(11), e15020
• WICKSTEAD, B, GULL, K. and RICHARDS, T.A., 2010. Patterns of kinesin evolution reveal a complex ancestral eukaryote with a multifunctional cytoskeleton BMC Evolutionary Biology. 10, 110
• HODGES, M.E., SCHEUMANN, N., WICKSTEAD, B., LANGDALE, J.A. and GULL, K., 2010. Reconstructing the evolutionary history of the centriole from protein components Journal of Cell Science. 123(9), 1407-1413
• DANIELS, JAN-PETER, GULL, KEITH and WICKSTEAD, BILL, 2010. Cell biology of the trypanosome genome. Microbiology and molecular biology reviews : MMBR. 74(4), 552-69
• DANIELS, JAN-PETER, KELLY, STEVEN, WICKSTEAD, BILL and GULL, KEITH, 2009. Identification of a crenarchaeal orthologue of Elf1: implications for chromatin and transcription in Archaea. Biology direct. 4, 24
• BARKER, AMY R, WICKSTEAD, BILL, GLUENZ, EVA and GULL, KEITH, 2008. Bioinformatic insights to the ESAG5 and GRESAG5 gene families in kinetoplastid parasites. Molecular and biochemical parasitology. 162(2), 112-22
• UZUREAU, PIERRICK, DANIELS, JAN-PETER, WALGRAFFE, DAVID, WICKSTEAD, BILL, PAYS, ETIENNE, GULL, KEITH and VANHAMME, LUC, 2008. Identification and characterization of two trypanosome TFIIS proteins exhibiting particular domain architectures and differential nuclear localizations. Molecular microbiology. 69(5), 1121-36
• WICKSTEAD, BILL and GULL, KEITH, 2007. Dyneins across eukaryotes: a comparative genomic analysis. Traffic (Copenhagen, Denmark). 8(12), 1708-21
• DEVAUX, SARA, KELLY, STEVEN, LECORDIER, LAURENCE, WICKSTEAD, BILL, PEREZ-MORGA, DAVID, PAYS, ETIENNE, VANHAMME, LUC and GULL, KEITH, 2007. Diversification of function by different isoforms of conventionally shared RNA polymerase subunits. Molecular biology of the cell. 18(4), 1293-301
• GADELHA, CATARINA, WICKSTEAD, BILL and GULL, KEITH, 2007. Flagellar and ciliary beating in trypanosome motility. Cell motility and the cytoskeleton. 64(8), 629-43
• KELLY, STEVEN, REED, JENNY, KRAMER, SUSANNE, ELLIS, LOUISE, WEBB, HELENA, SUNTER, JACK, SALJE, JEANNE, MARINSEK, NINA, GULL, KEITH, WICKSTEAD, BILL and CARRINGTON, MARK, 2007. Functional genomics in Trypanosoma brucei: a collection of vectors for the expression of tagged proteins from endogenous and ectopic gene loci. Molecular and biochemical parasitology. 154(1), 103-9
• HAMMARTON, TANSY C, WICKSTEAD, BILL and MCKEAN, PAUL G, 2007. Cell structure, cell division and the cell cycle. In: BARRY, JOHN D, MCCULLOCH, RICHARD, MOTTRAM, JEREMY C and ACOSTA-SERRANO, A, eds., Trypanosomes: After the Genome Horizon Bioscience. 239-280
• KELLY, S, SINGLETON, W, WICKSTEAD, B, ERSFELD, K and GULL, K, 2006. Characterization and differential nuclear localization of Nopp140 and a novel Nopp140-like protein in trypanosomes. Eukaryotic cell. 5(5), 876-9
• WICKSTEAD, BILL and GULL, KEITH, 2006. A "holistic" kinesin phylogeny reveals new kinesin families and predicts protein functions. Molecular biology of the cell. 17(4), 1734-43
• GADELHA, CATARINA, WICKSTEAD, BILL, MCKEAN, PAUL G and GULL, KEITH, 2006. Basal body and flagellum mutants reveal a rotational constraint of the central pair microtubules in the axonemes of trypanosomes. Journal of cell science. 119(Pt 12), 2405-13
• KELLY, S, WICKSTEAD, B and GULL, K, 2005. An in silico analysis of trypanosomatid RNA polymerases: insights into their unusual transcription. Biochemical Society transactions. 33(Pt 6), 1435-7
• BERRIMAN, MATTHEW, GHEDIN, ELODIE, HERTZ-FOWLER, CHRISTIANE, BLANDIN, GAËLLE, RENAULD, HUBERT, BARTHOLOMEU, DANIELLA C, LENNARD, NICOLA J, CALER, ELISABET, HAMLIN, NANCY E, HAAS, BRIAN and BÖHM, 2005. The genome of the African trypanosome Trypanosoma brucei. Science (New York, N.Y.). 309(5733), 416-22
• GADELHA, CATARINA, WICKSTEAD, BILL, DE SOUZA, WANDERLEY, GULL, KEITH and CUNHA-E-SILVA, NARCISA, 2005. Cryptic paraflagellar rod in endosymbiont-containing kinetoplastid protozoa. Eukaryotic cell. 4(3), 516-25
• EL-SAYED, NAJIB M, MYLER, PETER J, BARTHOLOMEU, DANIELLA C, NILSSON, DANIEL, AGGARWAL, GAUTAM, TRAN, ANH-NHI, GHEDIN, ELODIE, WORTHEY, ELIZABETH A, DELCHER, ARTHUR L, BLANDIN, GAËLLE and WESTENBERGE, 2005. The genome sequence of Trypanosoma cruzi, etiologic agent of Chagas disease. Science (New York, N.Y.). 309(5733), 409-15
• WICKSTEAD, BILL, ERSFELD, KLAUS and GULL, KEITH, 2004. The small chromosomes of Trypanosoma brucei involved in antigenic variation are constructed around repetitive palindromes. Genome research. 14(6), 1014-24
• VAUGHAN, SUE, WICKSTEAD, BILL, GULL, KEITH and ADDINALL, STEPHEN G, 2004. Molecular evolution of FtsZ protein sequences encoded within the genomes of archaea, bacteria, and eukaryota. Journal of molecular evolution. 58(1), 19-29
• BECKER, MARION, AITCHESON, NIALL, BYLES, ELAINE, WICKSTEAD, BILL, LOUIS, EDWARD and RUDENKO, GLORIA, 2004. Isolation of the repertoire of VSG expression site containing telomeres of Trypanosoma brucei 427 using transformation-associated recombination in yeast. Genome research. 14(11), 2319-29
• BRIGGS, LAURA J, DAVIDGE, JACQUELINE A, WICKSTEAD, BILL, GINGER, MICHAEL L and GULL, KEITH, 2004. More than one way to build a flagellum: comparative genomics of parasitic protozoa. Current biology : CB. 14(15), R611-2
• WICKSTEAD, BILL, ERSFELD, KLAUS and GULL, KEITH, 2003. The mitotic stability of the minichromosomes of Trypanosoma brucei. Molecular and biochemical parasitology. 132(2), 97-100
• WICKSTEAD, BILL, ERSFELD, KLAUS and GULL, KEITH, 2003. Repetitive elements in genomes of parasitic protozoa. Microbiology and molecular biology reviews : MMBR. 67(3), 360-75, table of contents
• WICKSTEAD, BILL, ERSFELD, KLAUS and GULL, KEITH, 2003. The frequency of gene targeting in Trypanosoma brucei is independent of target site copy number. Nucleic acids research. 31(14), 3993-4000
• ALSFORD, S, WICKSTEAD, B, ERSFELD, K and GULL, K, 2001. Diversity and dynamics of the minichromosomal karyotype in Trypanosoma brucei. Molecular and biochemical parasitology. 113(1), 79-88
• WICKSTEAD, B, GRIEVE, S M and WIMPERIS, S, 1998. (17)O NMR of water in ordered environments. Biophysical chemistry. 73(1-2), 129-36
• TAYLOR, R M, WICKSTEAD, B, CRONIN, S and CALDECOTT, K W, 1998. Role of a BRCT domain in the interaction of DNA ligase III-alpha with the DNA repair protein XRCC1. Current biology : CB. 8(15), 877-80
• KOUMANDOU VL, WICKSTEAD B, GINGER ML, VAN DER GIEZEN M, DACKS JB and FIELD MC, 1. Molecular paleontology and complexity in the last eukaryotic common ancestor. Critical reviews in biochemistry and molecular biology. 48(4), 373-96
• WICKSTEAD, BILL, ERSFELD, KLAUS and GULL, KEITH, Targeting of a tetracycline-inducible expression system to the transcriptionally silent minichromosomes of Trypanosoma brucei. Molecular and biochemical parasitology. 125(1-2), 211-6