Cynthia Weinig
Associate Professor
Evolutionary Genetics
cweinig@uwyo.edu
(307) 766-6378
Research
background
Molecular
evolutionary ecology of plant adaptation to heterogeneous settings
The
majority of variation segregating in natural populations is quantitative,
and its expression depends on genetic background, environment, and
interactions with these two factors. Traditionally, the evolution of
quantitative traits has been described using statistical genetic techniques.
However, one of the greatest advantages of these approaches is also one of
their primary limitations: it is possible to estimate genetic variation and covariation in traits without any direct knowledge of the underlying loci or
molecular genetic details. In like fashion, it is possible to estimate the
pattern of natural selection on quantitative traits in the absence of
knowledge of loci that determine fitness.
Advances in collecting and analyzing molecular
data promise to reveal the molecular genetic basis of quantitative trait
variation. Identifying the molecular elements responsible for variation in
quantitative traits may provide insight into basic evolutionary and genetic
processes, including the minimum number and effect of genes that contribute
to variation in quantitative traits, how the expression of variation at
specific loci varies across environments, whether selection at specific loci
differs across environments, whether pleiotropy or linkage disequilibrium
underlie genetic correlations and potential evolutionary constraints, as
well as the genetic basis of similarity (or dissimilarity) of trait
expression among congeners.
Ongoing research
Adaptation to heterogeneous density environments
Developmental flexibility is
often viewed as an adaptive strategy that enables organisms to match their
phenotype to their surroundings. In natural settings, the position of a
plant within its stand can be an important determinant of fitness, because
plants require sunlight to photosynthesize and acquire carbon compounds. The
ability to both perceive neighbors in advance of direct shading and initiate
competitive responses should provide a fitness advantage. In collaboration
with Julin Maloof (UC Davis), we are examining both 1) the mechanisms
underlying plant perception of and responses to the environment and 2) how
variation at specific developmental loci affects fitness.
Genetic analysis of natural variation in the
control of flowering timing and inflorescence architecture in Brassica rapa
Many plant species have a broad
geographic range, and experience systematic changes in abiotic conditions
across latitudes. In collaboration with Rob McClung (Dartmouth College) and
Rick Amasino (University of WI), we are examining the genetic architecture
of plant responses to variable combinations of temperature and photoperiod.
In this project, we are also evaluating how circadian rhythms regulate the
expression of adaptive phenotypes.
Quantitative variation in floral organ size
Although the genetic basis of
qualitative differences in floral morphology (e.g., differences in shape
between different taxa) has received substantial attention, very little is
known about the genes that underlie quantitative variation in floral organ
size (e.g., length of petals). Yet, these traits can strongly affect fitness
of plants in natural populations and yield in cultivars. We have initiated
genome-wide association analyses and segregation analyses to identify the
loci that affect floral organ size.
Selected publications
Brock, M. T., P. L. Tiffin, and C. Weinig. 2007. Sequence diversity and haplotype associations with phenotypic responses to crowding: GIGANTEA affects fruit set in Arabidopsis thaliana. Molecular Ecology 16: 3050-3062
Brock, M. T., and C. Weinig. 2007. Floral plasticity to light environments and environment-specific floral-vegetative (co)variances. Evolution 61: 2913-2924
Weinig, C., J. A. Johnston, C. G. Willis, and J. N. Maloof. 2007. Antagonistic multilevel selection on size and architecture in variable density settings. Evolution 61: 58-67
Weinig, C., Z. M. German, L. M. Demink, and J. A. Johnston. 2006. Local and global costs of adaptive plasticity. American Naturalist 126: 826-836
Weinig, C. 2005. Rapid evolutionary responses to selection in heterogeneous environments among agricultural and non-agricultural weeds. International Journal of Plant Sciences 166: 641-647
Olsen, K. M., S. S. Halldorsdottir, J. R. Stinchcombe, C. Weinig, J. Schmitt, and M. D. Purugganan. 2004. Linkage disequilibrium mapping of Arabidopsis CRY2 flowering time alleles. Genetics 167: 1361-1369
Weinig, C., K. Gravuer, N. C. Kane, and J. Schmitt. 2004. Testing adaptive plasticity to UV: costs and benefits of stem elongation and light-induced phenolics. Evolution 58: 2645-2655
Weinig, C., L. A. Dorn, N. C. Kane, Z. German, S. S. Halldorsdottir, M. C. Ungerer, T. F. C. Mackay, M. D. Purugganan, and J. Schmitt. 2003. Heterogeneous selection at specific loci in natural environments in Arabidopsis thaliana. Genetics 165: 321-329
Weinig, C., M. C. Ungerer, L. A. Dorn, S. S. Halldorsdottir, Y. Toyonaga, T. F. C. Mackay, M. D. Purugganan, and J. Schmitt. 2002. Novel loci control variation in reproductive timing in Arabidopsis thaliana in natural environments. Genetics 162: 1875-1884
Weinig, C. and L. F. Delph. 2001. Phenotypic plasticity early in life constrains developmental responses later. Evolution 55: 930-936
Weinig, C. 2000. Plasticity versus canalization: population differences in the timing of shade-avoidance responses. Evolution 54: 441-451
Weinig, C. 2000. Differing selection in alternative competitive environments: shade-avoidance responses and germination timing. Evolution 54: 124-136
Delph, L. F., C. Weinig, and K. Sullivan 1998. Why fast-growing pollen tubes give rise to vigorous progeny: the test of a new mechanism. Proc. of the Royal Society B. 265: 935-939
Links
Molecular and Cellular Life Sciences
Office: Aven Nelson 114
Mailing Address:
Department of Botany, 3165
1000 E. University Ave.
University of Wyoming
Laramie, WY 82071
Ph. 1-307-766-2380
FAX: 1-307-766-2851
EMAIL Botany
