pilipiliÂþ»­

 

Mark Johnston

PROFESSORÌýand Chair
A.B. (Harvard, 1982)
PhD (Chicago, 1990)

  • Teaching & Research
  • Students' Research Topics
  • Graduates' occupations
  • Publications
  • Links
  • Teaching & Research


    Evolution, ecology and genetics of plants, mutation rate, polyploidy, natural selection, mating systems, self-fertilization, flower development, molecular evolution.


    am interested generally in the forces that shape the evolution of plants, and more specifically in plant reproduction. Unlike most animals, the vast majority of plant individuals possess both female and male sexual organs. This raises a number of interesting issues: How much should an individual self-fertilize? Does self-fertilization cause populations to go extinct? In addition to their use in addressing these kinds of questions, plants are also very useful for addressing other issues of fundamental importance to evolutionary biology, not just plant evolutionary biology. Such topics include: the rate of appearance of new, harmful mutations; the effect of continued inbreeding on fitness; differences in rates of evolution between genes transmitted maternally vs. paternally; etc.

    Classes in which Mark currently teaches:
    • Evolution)
    • ÌýPrinciples of Biology II (Plant section)
    My teaching reflects my interests in evolution and ecology, and all my undergraduate courses are approached from these disciplines. I have also offered modules in topics such as, a) Ecology and Evolution of plant populations; b) Morphormetrics and c) Mutations and Evolution
    Examples of Students' Research Topics
    Honors BSc Students
    • Megan de Graaf - Self-compatibility and inbreeding depression in Kalonia polifolia and K. angustifolia.
    • Holly Gilkie - Reproductive biology of red elderberry (Sambucus racemosa).
    • Eleanor Melrose - Genetics of floral form in Amsinckia lunaris.
    • Jennifer Twiss - Reproductive isolation among aneuploid groups: pre- and post fertilization barriers.
    • Marissa LeBlanc - Use of DNA fingerprinting (microsatellites) to determine selfing rates of individuals.
    • Megan McPhee - Roles of competition and soil characteristics in determining occurrence of pineapple weed.
    • Brad Foley - Development of microsatellite markers in Amsinckia.
    • Erica Frecker - Endosperm cytogenetics and chromosomal relationships during speciation in plants.
    • Bijon Das - Sex allocation and mating system in a simultaneously hemaphroditic mollusc (published in PNAS 95: 617-620).
    • Harriet T. Davies - Genetics of mating-system divergence in Amsinckia spectabilis.
    • Lisa M. O'Connell - Natural selection on floral traits in the pink lady's slipper orchid, Cypripedium acaule (published in Ecology 79: 1246-1260).

      We have recently discovered that a sperm transmits more mutations than an egg (Whittle and Johnston, 2002, 2003), and several projects are underway to understand the extent and causes of this phenomenon.
      Ìý

      We use a variety of techniques to study these sorts of questions, including: field work; greenhouse propagation; the lab work (e.g., DNA sequencing, AFLPs, image analysis, electron and confocal microscopy, etc.); and theoretical modeling.
      Ìý

      Graduate training emphasizes the concepts of evolutionary ecology and evolutionary genetics, as well as the statistical analysis of data.

      Amsinckia douglasiana visited by the
      butterfly Vanessa cardui in California

    Graduate Students


    • A.M.S., PhD., Evolution in response to environmental unpredictability.
    • P.L., PhD., Floral development and the evolution of self-fertilization.
    • C.A.W., PhD., Mutations in plant evolution.
    Some Graduates' Occupations
    • Professor of biology, PhD.
    • PhD student in biology
    • MSc student in biology
    • medical student
    • dentistry student
    • Director of microscopy and imaging suite.
    • law student

    Selected Publications

    Whittle, C.-A., and M.O.Johnston. 2003. Male-biased transmission of deletvious mutations to the progeny in Arrabidopsis thaliana. Proc. Natl. Acad. Sci. USA 100: 4055-4059.

    Whittle, C.-A., and M.O.Johnston. 2003. Broad-scale analysis contradicts the theory that generation time affects molecular evolutionary rates in plants. J. Mol. Evol. 56: 223-233.

    Whittle, C.-A., and M.O. Johnston. 2002. Male-driven evolution of mitochondrial and chloroplastidial DNA sequences in plants. Molecular Biology and Evolution. 19: 938-949.

    Whittle, C.-A., T. Beardmore and M.O. Johnston. 2001. Is G1 arrest in plant seed induced by a p53-related pathway? Trends in Plant Science (6: 248 - 251).

    Simons, A.M., and M.O. Johnston. 2000. Plasticity and the genetics of reproductive behaviour in the monocarpic perennial, Lobelia inflata (Indian tobacco). Heredity 85:356-365.

    Simons, A.M., and M.O. Johnston 1999. The cost of compensation. American Naturalist 153: 683-687.

    Li, P., and M.O. Johnston 1999. Evolution of meiosis timing during floral development. Proceedings of the Royal Society B: Biological Sciences 266: 185-190 (and cover photo).

    Johnston, M.O. 1998. Evolution of intermediate selfing rates in plants: Pollination ecology versus deleterious mutations. Genetica 102/103: 267-278 (special issue, Mutation and Evolution. Published in book form as well by Kluwer Press).

    O'Connell, L.M., and M. O. Johnston 1998. Male and female pollination pilipiliÂþ»­ in a deceptive orchid, a selection study. Ecology 79: 1246-1260.

    Johnston, M.O., B. Das, and W.R. Hoeh 1998. Negative correlation between male allocation and self-fertilization in a hermaphroditic animal. Proceedings of the National Academy of Sciences USA 95: 617-620.

    Simons, A.M., and M.O. Johnston 1997. Developmental instability as a bet-hedging strategy. Oikos 80: 401-406.

    Johnston, M.O., and D.J. Schoen. 1996. Correlated evolution of self-fertilization and inbreeding depression: An experimental study of nine populations of Amsinckia (Boraginaceae). Evolution 50: 1478-1491.

    Johnston, M.O., and D.J. Schoen. 1995. Mutation rates and dominance levels of genes affecting total fitness in two angiosperm species. Science 267: 226-229 (and cover photo).

    Links