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Indiana University Bloomington

Department of Biology

Faculty & Research

Faculty Profile

Jeffrey Palmer

Photo of Jeffrey Palmer
Research Images
Research photo by Jeffrey Palmer

Distinguished Professor and Class of 1955 Professor

IU Affiliations
Center for Genomics & Bioinformatics
Indiana Molecular Biology Institute

Contact Information
By telephone: 812-855-8892
By fax: 812-855-6705
JH 235C / JH 229/235 (lab)
Program
Evolution, Ecology & Behavior
Research Areas
  • Evolution
  • Genomics and Bioinformatics
  • Plant Molecular Biology
Education

Ph.D., Stanford University, 1981
Postdoctoral Fellow, Carnegie Institution of Washington, 1981-1983
Postdoctoral Fellow, Duke University, 1983-1984

Awards

Member, National Academy of Sciences
Fellow, American Academy of Arts & Sciences
David Starr Jordan Prize
Wilhelmine E. Key Award, American Genetics Association
Merit Award, Botanical Society of America

Research Description

We use approaches of comparative molecular biology, genomics, phylogenetics, and bioinformatics to study various major issues in the evolution of genes and genomes. Current studies fall into three areas:

Horizontal Gene Transfer in Plants - Horizontal gene transfer (HGT) is now recognized as a major evolutionary genetic force driving genomic and phenotypic change in prokaryotes and many unicellular eukaryotes. In contrast, there is little published evidence that HGT is common or important in the major groups of multicellular eukaryotes (animals, plants, and fungi). We recently discovered that HGT of mitochondrial genes in plants is both widespread and recent and have now expanded this work in several directions. Our efforts focus on plant mitochondrial genomes because their evident propensity for HGT and certain other attributes make them a model system for investigating HGT in eukaryotes. These studies assess rates, patterns, extents, chimeric consequences, directionality, donor/recipient relationships, functionality, and mechanistic aspects of HGT across many lineages of plant mitochondrial genomes.  Our recent work has provided insight into mechanisms of HGT (it frequently occurs by direct physical contract between parasitic plants and their host plants) and has identified a plant (the "basal" angiosperm Amborella trichopoda) whose mitochondrial genome has been radically shaped by HGT (it contains numerous genes, including whole mitochondrial genomes, acquired by HGT, and from a wide variety of donors, i.e., other flowering plants, mosses, and green algae).

Transfer of Mitochondrial Genes to the Nucleus - We are using flowering plants as a model "system" to study the evolutionary transfer of mitochondrial genes to nucleus. This process occurred on a massive scale early in mitochondrial evolution, and is therefore of fundamental importance to all eukaryotes, but continues to a significant extent only in plants. We have identified a number of very recent cases of gene transfer, which we are studying to elucidate underlying mechanisms and to characterize intermediates in the gene transfer process, e.g., plants which contain and express the same gene in both the organelle and the nucleus. We are also asking why some genes are transferred surprisingly frequently, hundreds of times during plant evolution, why certain lineages of plants transfer genes at highly elevated rates, and whether nuclear genes of mitochondrial origin are ever recaptured by the mitochondrial genome.

Accelerated Evolution of Mitochondrial Genes - We have discovered two separate lineages of plants whose mitochondrial genes are evolving at a highly accelerated rate, up to 4,000 times faster than in other plants. In each group, multiple major increases in the mutation rate have occurred, in some cases followed by major decreases. Current efforts seek to elucidate the molecular bases of these unprecedented changes in the fundamental mutation rate and to investigate whether such exceptionally high mutation rates have had any secondary effects on mitochondrial genome evolution and function.

Select Publications

Skippington, E., Barkman, T., J., Rice, D. W. and Palmer, J. D.  2015.  Miniaturized mitochondrial genome of the parasitic plant Viscum scurruloideum is extremely divergent and dynamic and has lost all respiratory complex I genes.  Proc. Natl. Acad. Sci. USA, E3515–E3524.  

Sanchez-Puerta, M. V., Zubko, M. K., and Palmer, J. D.  2015.  Homologous recombination and retention of a single form of most genes shape the highly chimeric mitochondrial genome of a cybrid plant.  New Phytol. 206:381-396.  

Rice, D. W., Alverson, A. J., Richardson, A. O., Young, G. J., Sanchez-Puerta, M. V., Munzinger, J., Berrie, K., Boore, J. L., Zhang, Y., dePamphilis, C. W., Knox, E. B., and Palmer, J. D.  2013.  Horizontal transfer of entire genomes via mitochondrial fusion in the angiosperm Amborella.  Science 342:1468-1473.
Richardson, A., Rice, D. W., Alverson, A. J., Young, G. J., and Palmer, J. D. 2013. The “fossilized”mitochondrial genome of Liriodendron tulipifera: Ancestral gene content and order, ancestral editing sites, and extraordinarily low mutation rate. BMC Biology 11:29 (17 pages).
Sloan, D. B., Alverson, A. J., Chuckalovcak , J. P., Wu, M., McCauley, D. E., Palmer, J. D., and Taylor, D. R. 2012. Rapid evolution of enormous, multichromosomal genomes in flowering plant mitochondria with exceptionally high mutation rates. PLoS Biol. vol. 10, issue 1, e1001241 (17 pp).
Alverson, A. J., Rice, D. W., Dickinson, S., Barry, K., and Palmer, J. D. 2011. Origins and recombination of the bacterial-sized multichromosomal mitochondrial genome of cucumber (Cucumis sativus). Plant Cell 23:2499-2513.
Mower, J. P., Stefanović , S., Hao, W., Gummow, J., Jain, K., Ahmed, D., Palmer, J. D. 2010. Horizontal acquisition of multiple mitochondrial genes from a parasitic plant followed by gene conversion with host mitochondrial genes. BMC Biol. 8:150 (16 pages).
Hao, W., Richardson, A. O., Zheng, Y., and Palmer, J. D. 2010. Gorgeous mosaic of mitochondrial genes created by horizontal transfer and gene conversion. Proc. Natl. Acad. Sci. USA 107:21576-21581.

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