Browser does not support script.

• Skip to main content
• Campus maps
• Contact us
• Jobs
• Help
• A-Z index

• UK Campus
• (External) China Campus
• (External) Malaysia Campus

logo

• Home
• Current students
  • New starters
  • Postgraduates
  • Finalists
  • Students Union
  • Careers
  • HealthyU
  • Student support
  • Student opportunities
  • Your community
• Study with us
  • Undergraduate study
  • Postgraduate study
  • Student fees
  • Accommodation
  • Visiting us
  • Nottingham life
  • Student life
  • Teaching and learning
  • Request a prospectus
  • Top frequently asked questions
• International
  • A Global University
  • The International Office
  • Study abroad
  • International student support
  • Scholarships and finance
  • Visas and immigration
  • (External) China campus
  • (External) Malaysia campus
• Schools and Departments
  • A to Z
  • By Faculty
  • Research Centres and Institutes
  • Professional Service Departments
• Services for Business
  • Services
  • Facilities
  • Spin out companies
  • Asia Business Centre
• Research
  • Priorities
  • Excellence
  • News
  • A to Z
  • Collaborations and partnerships
• Alumni
  • My profile
  • Email for life
  • News
  • Events
  • Volunteering
  • Support your University
• About the University
  • Campuses
  • Visitor information
  • Key dates
  • Facilities
  • Facts and figures
  • History
  • Vice-Chancellor
  • University structure
  • Strategic Plan 2010-15
  • Charity gateway

• Home
• About the School
• Undergraduate Study
• Postgraduate Study
• Research
• People
• Alumni
• News
• Events & Seminars
• Centre for Genetics and Genomics

• Print
• Email this Page

• School Intranet

Image of John Brookfield

John Brookfield

Professor of Evolutionary Genetics, Faculty of Medicine & Health Sciences

• Download to vCard
• Back to the Staff Directory

• Personal Details
• BBSRC Summer School
• Research
• Publications

Contact

• work Room B112 Biology
  University Park
  Nottingham
  NG7 2RD
  UK
• work 0115 823 0392
• fax 0115 823 0338
• john.brookfield@nottingham.ac.uk

Biography

BA in Zoology, University of Oxford 1976; Ph. D in Population Genetics, University of London 1980; Research Demonstrator in Genetics, University College of Swansea 1979-1981; Visiting Fellow, Laboratory of Genetics, The National Institute of Environmental Health Sciences, North Carolina 1981-1983; Lecturer in Genetics, University of Leicester 1983-1986; Lecturer (1987), Reader (1997) and Professor of Evolutionary Genetics (2004) University of Nottingham. Managing Editor, Heredity (2000-2003). Vice-President (External Affairs), Genetics Society 2008-, Appointed Fellow of the Institute of Biology, 2009. Member RAE Biological Sciences Panel and Sub-Panel, 2001 and 2008.

Research Summary

We have been interested in a variety of projects concerned with how the genome evolves. We have recently focussed on the evolution of DNA sequences which control development, particularly in… read more

Selected Publications

• STANCZYK, N.M., BROOKFIELD, J.F.Y., IGNELL,R., LOGAN, J.G. and FIELD, L.M., 2010. (External) Behavioral insensitivity to DEET in Aedes aegypti is a genetically determined trait residing in changes in sensillum function Proceedings of the National Academy of Sciences of the USA. 107(19), 8575-8580
• HELLEN EHB and BROOKFIELD JFY, 2011. (External) Investigation Of The Origin And Spread Of A Mammalian Transposable Element Based On Current Sequence Diversity. Journal Of Molecular Evolution. 73(5-6), 287-296
• STYLES, PAMELA and BROOKFIELD, JOHN F Y, 2009. (External) Source gene composition and gene conversion of the AluYh and AluYi lineages of retrotransposons. BMC evolutionary biology. 9, 102
• COOPER, MAX B, LOOSE, MATTHEW and BROOKFIELD, JOHN F Y, 2008. (External) Evolutionary modelling of feed forward loops in gene regulatory networks. Biosystems. 91(1), 231-44

• View all publications

A BBSRC-Sponsored Summer School in Molecular Evolution and Diversity took place at Lincoln Hall of the University of Nottingham, from midday on Monday the 26th July 2010 until midday on Saturday, the 31st July 2010. You can here obtain some of the plenary presentations. More of these will follow soon.

BalazsPapp30thJuly.ppt

DeborahCharlesworth(1)27thJuly.ppt

DeborahCharlesworth(2)27thJuly.ppt

JohnArmour28thJuly.ppt

JohnBrookfield(1)26thJuly.ppt

JohnBrookfield(2)26thJuly.ppt

PaulSharp29thJuly.ppt

BrianCharlesworth27thJuly.pdf

LoriLawson-Handley28thJuly.pdf

PeterKeightley27thJuly.pdf

Dan Halligan 28th July.pdf

Simon Whelan 29th July.ppt

Penny Haddrilll 27th July.pdf

Current Research

We have been interested in a variety of projects concerned with how the genome evolves. We have recently focussed on the evolution of DNA sequences which control development, particularly in Drosophila, and on the evolution of mobile repetitive DNA sequences.

Our interests are in the application of evolutionary theory to problems in molecular genetics. Currently, our research can be grouped under two main headings:

Evolution of Developmental Processes .

We are interested in the ways in which the DNA sequences that control development evolve, and in the genetic variation in developmental processes that exists in populations. One approach is to investigate the way in which enhancer sequences evolve. These sequences determine the time- and tissue- specific expression patterns of downstream coding sequences. They function through their possession of binding sites for transcription factors. We are interested in the ways in which these sequences change on the microevolutionary scale and the degree to which selective constraints act on the protein-binding sequences and the sequences that do not bind proteins. The focus of this research is the Drosophila melanogaster species group, members of which are sufficiently close that their DNA sequences can be unambiguously aligned. This allows tests for natural selection which simultaneously examine DNA sequence variation within and between species (e.g. Phinchongsakuldit et al. 2004). In addition, we are investigating the ways in which enhancers might initially arise. The binding sites for transcription factors are of low complexity and could be created by mutation and selection from random DNA sequences. This potentially could allow the reasonably rapid evolution of new binding sites in controlling regions, allowing genes to be brought under the control of new transcription factors (MacArthur and Brookfield 2004).

The interaction between transcription factors and their targets forms the building block of networks of genetic interaction that bring about spatial patterns of gene expression. We are interested in modeling the ways in which interactions between transcription factors and their targets might be expected to evolve (Johnson and Brookfield 2003, Cooper et al ., 2008, 2009).

References :

Johnson, L.J. and Brookfield, J.F.Y. (2003) Evolution of spatial expression pattern. Evolution and Development 5: 593-599

Phinchongsakuldit, J., MacArthur, S., and Brookfield, J.F.Y. (2004) Evolution of developmental genes: Molecular microevolution of enhancer sequences at the Ubx locus in Drosophila and its impact on developmental phenotypes. Molecular Biology and Evolution 21: 348-363

MacArthur, S. and Brookfield, J.F.Y. (2004) Expected rates and modes of evolution of enhancer sequences. Molecular Biology and Evolution 21: 1064-1073

Cooper, M.B., Loose, M. and Brookfield, J.F.Y. (2008) Evolutionary modeling of feed-forward loops in gene regulatory networks. Biosystems 91: 231-244

Cooper, M.B., Loose, M. and Brookfield, J.F.Y. (2009) The evolutionary influence of binding site organization on gene regulatory networks. Biosystems 96: 185-193

Mobile DNAs and their evolution

Genome projects reveal that mobile DNA sequences contribute a substantial fraction of the DNAs of higher eukaryotes. We are interested in the factors determining the diversity of such mobile DNA sequences, and their relative abundance in genomes. The vast majority of mobile DNAs appear to act as "selfish DNAs", increasing their abundance through their capacity to over-replicate relative to their hosts (Brookfield 2005a). However, the selfish spread of mobile DNAs is less likely in organisms which are partially or completely asexual, and we are investigating, both experimentally and through simulation, the possibility that the maintenance of mobile DNAs in asexual bacteria results from these sequences capacity to act as mutagens. (Edwards et al. 2002, Edwards and Brookfield 2003, McGraw and Brookfield 2006). We are also interested in the consequences of patterns of transposition for the phylogeny of copies in a transposable element family (Brookfield 2005b, Johnson and Brookfield 2006, Brookfield and Johnson 2006, Styles and Brookfield 2007, 2009).

References :

Edwards, R.J., Sockett, R.E., and Brookfield, J.F.Y. (2002) A simple method for genome-wide screening for advantageous insertions of mobile DNAs in Escherichia coli. Current Biology 12: 863-867

Edwards, R. J. and Brookfield, J.F.Y. (2003) Transiently beneficial insertions could maintain mobile DNA sequences in variable environments. Molecular Biology and Evolution 20: 30-37

Brookfield, J.F.Y. (2005a) Evolutionary forces generating sequence homogeneity and heterogeneity within retrotransposon families. Cytogenetic and Genome Research 110: 383-391

Brookfield, J.F.Y. (2005b) The ecology of the genome- mobile DNA elements and their hosts. Nature Reviews Genetics 6: 128-136.

Johnson, L.J. and Brookfield (2006) A test of the master gene hypothesis for interspersed repetitive DNA sequences. Molecular Biology and Evolution 23: 235-239

Brookfield, J.F.Y. and Johnson, L.J. (2006) The evolution of mobile DNAs-when will transposons create phylogenies that look as if there is a master gene? Genetics 173: 1115-1123

McGraw, J.E. and Brookfield, J.F.Y. (2006) The interaction between mobile DNAs and their hosts in a fluctuating environment. Journal of Theoretical Biology 243: 13-23

Styles, P. and Brookfield, J.F.Y. (2007) Analysis of the features and source gene composition of the AluYg6 subfamily of human retrotransposons. BMC Evolutionary Biology 7: 102

Styles, P. and Brookfield, J.F.Y. (2009) Source gene composition and gene conversion of the AluYh and AluYi lineages of retrotransposons. BMC Evolutionary Biology 9: 102

Hellen, E. H. B. and Brookfield, J.F. (2011) Investigation of the Origin and Spread of a Mammalian Transposable Element Based on Current Sequence Diversity Journal of Molecular Evolution 73 : 287-296

Brookfield John F.Y. (2011) Host-parasite relationships in the genome. BMC Biology 9 : 67.

Past Research

Dr. Brookfield is interested in the molecular population genetics of Drosophila melanogaster combining techniques from theoretical population genetics with molecular biology. In recent years, he has specialised in the genetics and molecular biology of transposable genetic elements in Drosophila and bacteria. He is also interested in the statistical analyses of hypervariable DNA in ecology and forensic science, and some more general problems in evolutionary biology.

• BROOKFIELD JFY, 2012. (External) Heritability. Current biology : cb. 22(7), R217-9
• BROOKFIELD JFY, 2011. (External) Host-Parasite Relationships In The Genome. Bmc Biology. 9, 67
• BROOKFIELD JFY, 2011. (External) Dangers Of 'Adaptation' Heredity. 108, 260
• BROOKFIELD JFY, 2011. Transposable elements –Are they good for you after all Genetics Society News. 65, 2024-2027
• JOHN F.Y. BROOKFIELD, 2011. (External) Coalescence: the Sharing of Ancestry of Alleles John Wiley. Available at: <http://www.els.net/>
• HELLEN EHB and BROOKFIELD JFY, 2011. (External) Investigation Of The Origin And Spread Of A Mammalian Transposable Element Based On Current Sequence Diversity. Journal Of Molecular Evolution. 73(5-6), 287-296
• BROOKFIELD, JOHN F Y, 2010. (External) Q&A: promise and pitfalls of genome-wide association studies BMC Biology. 8, 41
• BROOKFIELD, J.F.Y., 2010. Evolution is a quantitative science pLOS Biology. 8(5), e1000381
• STANCZYK, N.M., BROOKFIELD, J.F.Y., IGNELL,R., LOGAN, J.G. and FIELD, L.M., 2010. (External) Behavioral insensitivity to DEET in Aedes aegypti is a genetically determined trait residing in changes in sensillum function Proceedings of the National Academy of Sciences of the USA. 107(19), 8575-8580
• BROOKFIELD, J.F.Y., 2010. (External) Experimental Evolution: The Rate of Adaptive Evolution. . Current Biology. 20(1), R23-25.
• COOPER, M.B, LOOSE, M and BROOKFIELD, J.F.Y., 2009. (External) The evolutionary influence of binding site organization on gene regulatory networks. Biosystems. 96, 185-93
• BROOKFIELD, J.F.Y., 2009. (External) Evolution and evolvability: celebrating Darwin 200. Biology Letters. 5(1), 44-46
• STYLES, PAMELA and BROOKFIELD, JOHN F Y, 2009. (External) Source gene composition and gene conversion of the AluYh and AluYi lineages of retrotransposons. BMC evolutionary biology. 9, 102
• COOPER, MAX B, LOOSE, MATTHEW and BROOKFIELD, JOHN F Y, 2008. (External) Evolutionary modelling of feed forward loops in gene regulatory networks. Biosystems. 91(1), 231-44
• STYLES, PAMELA and BROOKFIELD, JOHN F Y, 2007. (External) Analysis of the features and source gene composition of the AluYg6 subfamily of human retrotransposons. BMC evolutionary biology. 7, 102
• KEELE, B.F., VAN HEUVERSWYN, F., LI, Y., BAILES, E., TAKEHISA, J., SANTIAGO, M.L., BIBOLLET-RUCHE, F., CHEN, Y., WAIN, L.V., LIEGEOIS, F., LOUL, S., NGOLE, E.M., BIENVENUE, Y., DELAPORTE, E., BROOKFIELD, J.F.Y., SHARP, P.M., SHAW, G.M., PEETERS, M. and HAHN,, 2006. (External) Chimpanzee reservoirs of pandemic and nonpandemic HIV-1. Science. 313(5786), 523-526
• BROOKFIELD, J.F.Y. and JOHNSON, L.J., 2006. (External) The evolution of mobile DNAs: when will transposons create phylogenies that look as if there is a master gene? Genetics. 173(2), 1115-1123
• MCGRAW, JAMES E and BROOKFIELD, JOHN F Y, 2006. (External) The interaction between mobile DNAs and their hosts in a fluctuating environment. Journal of Theoretical Biology. 243(1), 13-23
• JOHNSON, LOUISE J and BROOKFIELD, JOHN F Y, 2006. (External) A test of the master gene hypothesis for interspersed repetitive DNA sequences. Molecular Biology and Evolution. 23(2), 235-9
• MALLA, S., DAFHNIS-CALAS, F., BROOKFIELD, J. F., SMITH, M. C. and BROWN, W. R., 2005. (External) Rearranging the centromere of the human Y chromosome with φC31 integrase Nucleic Acids Research. 33(19), 6101-6113
• BROOKFIELD, J.F.Y., 2005. (External) The ecology of the genome - mobile DNA elements and their hosts Nature Reviews: Genetics. 6(2), 128-136
• SANTIAGO, M. L., RANGE, F., KEELE, B. F., LI, Y., BAILES, E., BIBOLLET-RUCHE, F., FRUTEAU, C., NOE, R., PEETERS, M. and BROOKFIELD, J. F. Y., 2005. (External) Simian Immunodeficiency Virus Infection in Free-Ranging Sooty Mangabeys (Cercocebus atys atys) from the Tai Forest, Cote d'Ivoire: Implications for the Origin of Epidemic Human Immunodeficiency Virus Type 2 Journal of Virology. VOL 79(NUMB 19), 12515-12527
• BROOKFIELD, J. F., 2005. (External) Evolutionary forces generating sequence homogeneity and heterogeneity within retrotransposon families Cytogenetic and Genome Research. VOL 110(NUMBER 1-4), 383-391
• PHINCHONGSAKULDIT, J., MACARTHUR, S. and BROOKFIELD, J.F.Y., 2004. (External) Evolution of developmental genes: Molecular microevolution of enhancer sequences at the <i>Ubx</i> locus in <i>Drosophila</i> and impact on developmental phenotypes Molecular Biology and Evolution. 21(2), 348-363
• MACARTHUR, S. and BROOKFIELD, J.F.Y., 2004. (External) Expected rates and modes of evolution of enhancer sequences Molecular Biology and Evolution. 21(6), 1064-1073
• BROOKFIELD, JOHN F Y, 2004. (External) Evolutionary genetics: Mobile DNAs as sources of adaptive change? Current Biology. 14(9), R344-5
• EDWARDS, R.J. and BROOKFIELD, J.F.Y., 2003. (External) Transiently beneficial insertions could maintain mobile DNA sequences in variable environments Molecular Biology and Evolution. 20(1), 30-37
• SANTIAGO, M.L., LUKASIK, M., KAMENYA, S., LI, Y., BIBOLLET-RUCHE, F., BAILES, E., MULLER, M.N., EMERY, M., GOLDENBERG, D.A., LWANGA, J.S., AYOUBA, A., NERRIENET, E., MCCLURE, H.M., HEENEY, J.L., WATTS, D.P., PUSEY, A.E., COLLINS, D.A., WRANGHAM, R.W., GOODALL, J., BROOKFIELD, J.F.Y., SHARP, P. M., SHAW, G.M. and HAHN, B.H., 2003. (External) Foci of endemic simian immunodeficiency virus infection in wild-living eastern chimpanzees (<i>Pan troglodytes schweinfurthii</i>) Journal of Virology. 77(13), 7545-7562
• JOHNSON, LOUISE J and BROOKFIELD, JOHN F Y, 2003. (External) Evolution of spatial expression pattern. Evolution and Development. 5(6), 593-9
• BROOKFIELD, J. F., 2003. (External) Mobile DNAs: The Poacher Turned Gamekeeper Current Biology. VOL 13(NUMBER 21), R846-R847
• BROOKFIELD, J. F., 2003. (External) Genome Sequencing: The Ripping Yarn of The Frozen Genome Current Biology. VOL 13(NUMBER 14), R552-R553
• BROOKFIELD, J. F., 2003. (External) Human evolution: a legacy of cannibalism in our genes? Current Biology. VOL 13(NUMBER 15), R592-R593
• BROOKFIELD, JOHN, 2003. (External) The system rewards a dishonest approach. Nature. 423(6939), 480; discussion 480
• BROOKFIELD, J. F., 2003. (External) Human Prehistory: The Message from Linkage Disequilibrium Current Biology. VOL 13(NUMBER 3), R86-R87
• BROOKFIELD, J. F., 2003. (External) Gene Duplications: The Gradual Evolution of Functional Divergence Current Biology. VOL 13(NUMBER 6), R229-R230
• EDWARDS, R.J., SOCKETT, R.E. and BROOKFIELD, J.FY., 2002. (External) A simple method for genome-wide screening for advantageous insertions of mobile DNAs in <i>Escherichia coli</i> Current Biology. 12(10), 863-867
• CARR, M., SOLOWAY, J. R., ROBINSON, T. E. and BROOKFIELD, J. F., 2002. (External) Mechanisms regulating the copy numbers of six LTR retrotransposons in the genome of Drosophila melanogaster Chromosoma. VOL 110(PART 8), 511-518
• NICHOLAS, H. R. and BROOKFIELD, J. F., 2002. (External) The Drosophila Melanogaster Ku70 Coding Sequence is Wild-Type in Mus309 Mutants Genetica. VOL 114(NUMBER 3), 293 - 296
• MACDONALD, C. and BROOKFIELD, J. F. Y., 2002. (External) Intraspecific molecular variation in the seaweed fly Coelopa frigida consistent with behavioural distinctness of British and Swedish populations Molecular Ecology. VOL 11(PART 9), 1637-1646
• BROOKFIELD, JOHN, 2002. (External) Fitness. Current Biology. 12(21), R717
• FURLONG, R. F. and BROOKFIELD, J. F. Y., 2001. (External) Inference of Past Population Expansion from the Timing of Coalescence Events in a Gene Genealogy Journal of Theoretical Biology. VOL 209(PART 1), 75-86
• BROOKFIELD, J. F., 2001. (External) Population genetics: The signature of selection Current Biology. VOL 11(NUMBER 10), R388-R390
• BROOKFIELD, J F, 2001. (External) Selection on Alu sequences? Current Biology. 11(22), R900-1
• BROOKFIELD, J. F., 2001. (External) Evolution: The evolvability enigma Current Biology. VOL 11(NUMBER 3), R106-R108
• BROOKFIELD, J F, 2001. (External) Predicting the future. Nature. 411(6841), 999
• BROOKFIELD, J F, 2001. (External) Population bottlenecks. Current Biology. 11(24), R1000
• MORGAN, L., CRAWSHAW, S., BAKER, P. N., BROOKFIELD, J. F. Y., BROUGHTON PIPKIN, F. and KALSHEKER, N., 1998. (External) Distortion of maternal-fetal angiotensin II type 1 receptor allele transmission in pre-eclampsia Journal of Medical Genetics. 35(8), 632-636
• BROOKFIELD, J. F. Y., 1998. (External) Quorum Sensing and Group Selection Evolution. VOL 52(NUMBER 5), 1263-1269
• BADGE, R. M. and BROOKFIELD, J. F. Y., 1998. (External) A novel repressor of P element transposition in Drosophila melanogaster Genetical Research. VOL 71(NUMBER 1), 21-30
• BROOKFIELD, J F, 1997. (External) Importance of ancestral DNA ages. Nature. 388(6638), 134

School of Biology

University of Nottingham
University Park
Nottingham, NG7 2RD

telephone: +44 (0)115 9513300 (Undergraduate Enquiries)
+44 (0)115 8230311 (Postgraduate Enquiries)
fax: +44 (0)115 8230338
email: biology@nottingham.ac.uk

• Copyright
• Terms & Conditions
• Privacy
• Accessibility
• Freedom of Information

Browser does not support script.

Browser does not support script.