The University of Texas at Austin: USDA NIFA Postdoctoral Fellow, 2010-2013
Duke University: PhD, 2004-2010
The University of California, Berkeley: BS, 1997-2001
The genetics of adaptation and speciation
Adaptation is the most fundamental way that the environment can change the phenotypes of organisms. Adaptations can also lead to the formation of reproductive isolating barriers, which are the building blocks of new species. I am very interested in understanding the genetic underpinnings of reproductive isolation at various stages in the speciation process.
Understanding adaptation is also crucial to predicting how organisms will respond to future global change and will help inform management decisions as well as guide future agricultural breeding.
Landscape evolutionary genomics
One of the core goals of my research program is to understand how the natural landscape molds the genomes of organisms through adaptation. To that end, I am using a combination of genetic mapping and genome sequencing approaches to identify genes involved with adaptation to the heterogeneity of the natural landscape. During my dissertation, I focused on how adaptive alleles in Mimulus guttatus are spread across the landscape and what phenotypic effects they have in different environments across western North America. Currently, I am developing Panicum grasses as a model system to understand adaptation along a longitudinal soil moisture cline across Southwestern United States and a latitudinal temperature cline across the Great Plains. Our lab recently received funding from the Department of Energy to develop Panicum hallii as a model system for local adaptation and bioenergy research.
Using evolutionary biology to improve bioenergy crops
Civilization is built on a foundation of domesticated grasses. Without those grasses (corn, wheat, rice, oats, barley, sorghum) there would be no ballet and human beings would never of landed on the moon. Plant breeders have quietly worked in the shadows to increase the yield of crops and in turn maintain our modern world.
Now, there may actually be potential to domesticate a new set of grass species to use to help combat the growing energy problem. My research is focused understanding the factors involved in local adaptation in the bioenergy crop switchgrass (Panicum virgatum). Loci involved in local adaptation are likely to be of high value to crop breeders interested in improving drought, heat, cold, herbivore, and disease tolerance.
PDFs for publications available through my website
Lasky, J. R., D. L. Des Marais, D. B. Lowry, I. Povolotskaya, J. K. McKay, J. H. Richards, T. H. Keitt, T. E. Juenger. Natural variation in abiotic stress responsive gene expression is associated with local adaptation to climate in Arabidopsis thaliana. In review
Meyer, E., M. J. Aspinwall, D. B. Lowry, J. Palacio-Mejía, T. L. Logan, P. A. Fay, T. E. Juenger. Integrating physiological, transcriptional, and metabolomic responses to drought stress and recovery in switchgrass (Panicum virgatum L.). In review
Lowry, D. B., K. Hernandez, S. H. Taylor, E. Meyer, T. L. Logan, J. A. Chapman, D. S. Rokhsar, J. Schmutz, T. E. Juenger. The genetic architecture of divergence between mesic and xeric varieties of Panicum hallii. In revision
Lowry, D. B., K. D. Behrman, P. Grabowski, G. P. Morris, J. R. Kiniry, T. E. Juenger. Adaptation between ecotypes and along environmental gradients in Panicum virgatum. In revision
Lowry, D. B., T. L. Logan, L. Santuari, C. S. Hardtke, J. H. Richards, L. J. DeRose-Wilson, J. K. McKay, S. Sen, T. E. Juenger. (2013) Expression QTL mapping across water availability environments reveals contrasting associations with genomic features in Arabidopsis thaliana. The Plant Cell In Press
Aspinwall, M. J., D. B. Lowry, S. H. Taylor, T. E. Juenger, C. V. Hawkes, M. V. Johnson, J. R. Kiniry, P. A. Fay. (2013) Genotypic variation in traits linked to climate and aboveground productivity in a widespread C4 grass: evidence for a functional trait syndrome. New Phytologist 199: 966-980.
Lowry, D. B., C. T. Purmal, E. Meyer, T. E. Juenger. (2012) Microsatellite markers for the native Texas perennial grass, Panicum hallii (Poaceae). American Journal of Botany Primer Notes & Protocols. 99: e114-e116
Lowry, D. B., C. S. Sheng, Z. Zhu, T. E. Juenger, B. Lahner, D. E. Salt, J. H. Willis. (2012) Mapping of ionomic traits in Mimulus guttatus reveals Mo and Cd QTLs that colocalize with MOT1 homologues. PLoS One 7: e30730.
Lowry, D.B., J. H. Willis. (2010) A widespread chromosomal inversion polymorphism contributes to a major life-history transition, local adaptation, and reproductive isolation. PLoS Biology 8: e1000500
Lowry, D. B., M. C. Hall, D. E. Salt, J. H. Willis. (2009). Genetic and physiological basis of adaptive salt tolerance divergence between coastal and inland Mimulus guttatus. New Phytologist 183: 776-788
Lowry, D. B., J. L. Modliszewski, K. M. Wright, C. A. Wu, J. H. Willis. (2008). The strength and genetic basis of reproductive isolating barriers in flowering plants. Philosophical Transactions of the Royal Society B 363: 3009-3021
Wu, C. A., D. B. Lowry, A. M. Cooley, K. M. Wright, Y. W. Lee, and J. H. Willis. (2008). Mimulus is an emerging model system for the integration of ecological and genomic studies. Heredity 100: 220-230.
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