个人简介
My interest in plant population biology and evolution developed early in life through many hours of hiking and working in the Rocky Mountains of Canada. This led to a M.Sc. degree in which I investigated the biology of submerged aquatic plants and focused my interests on the ecology of small, isolated plant populations. For my Ph.D., I shifted my focus to the genetic and evolutionary aspects of small populations in a project on genetic drift and mating system variation in a South American aquatic plant. As a Postdoctoral Fellow, I continued this line of study, this time studying inbreeding and its negative consequences. Since coming to the University of Guelph, my research interests have diversified to include:
the ecology and genetics of small populations,
causes and consequences of genome duplication,
function and evolution of plant reproductive systems; and
ecological consequences of genetic diversity.
I am currently a member of the Canadian Society of Ecology and Evolution, Society for the Study of Evolution, American Association for Higher Education and Botanical Society of America. I am an Associate Editor for the Proceedings of the Royal Society, B, and member of National Recovery Teams for Red Mulberry and American Chestnut.
B.Sc. - University of Alberta
M.Sc. - University of Alberta
Ph.D. - University of Toronto
研究领域
My research and that of my lab group is focused on the ecology and genetics of plant populations. We study the mechanisms regulating genetic diversity and phenotypic evolution in plants, and, conversely, how evolutionary processes (drift, gene flow, adaptation, genetic diversity) affect the ecological function of populations (reproduction, growth, persistence, extinction). To understand these relationships we focus mainly on plant genetic systems, those reproductive attributes that govern mutation, gamete formation, pollination, fertilization, and organization of genetic diversity in populations.
Currently, my lab is involved in four related research areas:
I. Ecology and genetics of small populations
All populations contain a finite number of individuals, particularly those populations in restricted or marginal habitats. This can have a profound effect on mating patterns and ecology, but the significance of population size for the evolutionary process is heavily debated. We have explored this issue through studies on effective population size, metapopulation dynamics, the effects of drift on mating system evolution, inbreeding depression, and the mechanisms by which hybridization causes extirpation of rare species.
II. Evolutionary significance of genome duplication.
Genome duplication above the diploid state (a.k.a. polyploidy) is widespread among plants and animals and is particularly common in flowering plants and ferns. Its prevalence in plants (and absence in many animals) has long puzzled biologists and recent mathematical models still argue that polyploidy should rarely evolve in sexual organisms with non-overlapping generations. Our research uses plant species with natural variation in ploidy (Chamerion, Galax, Malus) and mutagens that induce genome duplication to explore two major hypotheses: 1) genome duplication has a disproportionately large influence on rates of species diversification; 2) it enhances the adaptive potential and, hence, persistence of lineages that bear it.
III. Function and evolution of plant reproductive systems.
Plants exhibit a bewildering array of breeding systems, reflected by variation in gender, floral form and display, mechanisms of pollen transfer, and pathways of fertilization and seed maturation. Accounting for this sexual diversity is important because of its significance for population persistence, reproductive isolation and the organization of genetic diversity within and among populations. It also provides a useful focal point for studying the mechanisms of microevolution such as gene flow, genetic drift and selection. Our research currently focuses on two aspects of plant reproduction: the evolution of self-fertilization versus cross-fertilization (mating system), and the adaptive significance of dichogamy (temporal separation of male and female function). In both cases we are using comparative analyses, manipulative experiments and multi-generational selection studies to understand the evolution of these traits.
IV. Ecological impacts of hybridization and gene flow?
The importance of genetic diversity (mutation, gene flow, drift, heritability) to adaptive evolution is widely recognized, but it is less clear whether and how it affects ecological function and viability of populations. Understanding the ecological consequences of genetic diversity also have implications for conservation, restoration practices. Using a combination of genetic markers and manipulative studies, our research on hybridization between American and Eurasian chestnut (Castanea), Asian and native mulberry (Morus) and domestic and native apples (Malus) has allowed us to explore the conditions favouring gene exchange between species and the impacts on seed production and establishment. In addition, paternity analysis, flow cytometry and experimental crosses are being used to examine patterns of mating and the effects of mate diversity on reproductive success in domestic and native species.
V. Development and applications of plant barcoding
We are part of a national collaborative effort (comprising 4 labs) to develop barcoding tools for plants. The group has published one of the most extensive evaluations of potential barcode regions and has been instrumental (along with 3 other international groups) in facilitating an international agreement on a standard barcode region for land plants . Equally important we are advancing and exploring the applications of this tool for studies in ecology (belowground community structure and function) and evolutionary biology (phylogeography).
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Ecology and Genetics of Small Populations
McCracken, A., J.D. Bainard, M.C. Miller, and B.C. Husband. 2013. Pathways of introduction of the invasive aquatic plant Cabomba caroliniana. Ecology & Evolution 3:1427-1439 doi: 10.1002/ece3.530
Campbell, L.G. and B.C. Husband. 2007. Reproductive consequences of population size in self-incompatible plant, Hymenoxys herbacea (Asteraceae). New Phytologist 174:915-925.
Genome Duplication
Kreiner, J., P. Kron, and B.C. Husband. 2017. Frequency and maintenance of unreduced gametes in natural plant populations: associations with reproductive mode, life history, and genome size. New Phytologist (accepted Dec 3, 2016).
Husband, B.C., S.J. Baldwin and H.A. Sabara. 2016. Direct vs. indirect effects of whole-genome duplication on prezygotic isolation in Chamerion angustifolium: Implications for rapid speciation. American Journal of Botany 103:1259-1271 [Special Issue].
Husband, B.C. 2016. Effect of inbreeding on pollen tube growth in diploid and tetraploid Chamerion angustifolium: do polyploids mask mutational load in pollen. American Journal of Botany 103:1-9. doi:10.3732/ajb.1500243 [Special Issue].
Kron, P. and B.C. Husband. 2015. Distinguishing 2N gamete nuclei from doublets in pollen using flow cytometry and pulse analysis. Cytometry A. Cytometry Part A 87A: 943-957. doi: 10.1002/cyto.a.22696.
Thompson, K.A., B.C. Husband and H. Maherali. 2015. No influence of water limitation on the outcome of competition between diploid and tetraploid Chamerion angustifolium (Onagraceae). Journal of Ecology 103:733-741. doi: 10.1111/1365-2745.12384.
Thompson, K.A., B.C. Husband and H. Maherali. 2014. Climatic niche differences between diploid and tetraploid cytotypes of Chamerion angustifolium (Onagraceae). American Journal of Botany 101:1868-1875.
Martin, S.L. and B.C. Husband. 2012 Whole genome duplication affects evolvability in natural populations of a flowering plant. PLos One. 7(9): e44784.doi:10.1371/journal.pone.0044784.
Reproductive Systems
Miller, J.S., A. Kamath, B.C. Husband and R.A. Levin. 2015. Correlated polymorphism in cytotype and sexual system within a monophyletic species, Lycium californicum. Accepted, International Journal of Plant Science.
Kron P., Kwok A., and B.C. Husband. 2014. Flow cytometric analysis of pollen collected from individual bees provides information about pollen load composition and foraging behaviour. Ann. Bot. doi:10.1093/aob/mct257.
Ecological Consequences of Genetic Diversity and Evolution
Kron and Husband. Botany. 2009. Hybridization and the reproductive pathways mediating gene flow between native Malus coronaria and domestic apple, Malus domestica. Botany 87: 864-874.
Burgess, K.S., M. Morgan, and B.C. Husband. 2008. Interspecific seed discounting and the fertility cost of hybridization in an endangered species. New Phytologist 177:276-284.
Plant Barcoding
Percy D.M., G.W. Argus, Q.C. Cronk, A.J. Fazekas, P.R. Kesanakurti, K.S. Burgess, B.C. Husband, S.G. Newmaster, S.C.H. Barrett and S.W. Graham. 2014. Understanding the spectacular failure of DNA barcoding in willows (Salix): Does this result from a trans-specific selective sweep? Molecular Ecology 23:4737-4756.
Burgess, K.S., Fazekas A.J., Kesanakurti P.R., Graham S.W., Husband B.C., Newmaster S.G., Percy D.M., Hajibabaei M., Barrett S.C.H. 2011. Discriminating plant species in a local temperate flora using the rbcl + matK DNA barcode. Methods in Ecology and Evolution 2:333-340. doi: 10.1111/j.2041-210X.2011.00092.x
CBOL Plant Working Group. 2009. A DNA Barcode for Land Plants. Proceedings of the National Academy of Sciences 106:12794-12797
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