Eric Baack
baacer01@luther.edu
SHL190B
563-387-1087
Education
BA in Philosophy, Carleton College
MA in Education, Lewis and Clark College
PhD in Population Biology, University of California, Davis
Post-doctoral research with Dr. Loren Rieseberg (Indiana University and University of British Columbia)
Current courses
at Luther
Fall 2008
Biology
354 – Evolutionary biology. (I can’t imagine a biology course
that I’d rather teach! Evolutionary theory is so elegant and
so comprehensive.)
Biology
151 – Principles of biology: Ecology, evolution, and biodiversity.
J-term 2009
Biology
185 – Natural history of food. 1st year seminar.
Spring 2009
Biology
256 – Biostatistics
Planned teaching (subject
to change)
Fall 2009
Biology
256 – Biostatistics
Biology
151 – Principles of biology: ecology, evolution and biodiversity
J-term 2010
Biology
239 – Desert ecology and water in the American southwest
Spring 2010
Biology
354 – Evolutionary biology
Recent readings
Wilson (2008) Swindled:
the dark history of food fraud, from poisoned candy to counterfeit
coffee. Wilson traces the history of food fraud from
the 1820s in Britain through the Delaney act in the US to the present.
Lively, informative, and relevant.
Wessels, Cohen, and Zwinger
(2005). Reading the forested landscape: a natural history
of New England. The authors show how slumping stone walls,
old apple trees, and moss-covered hemlock stumps reveal the history
of land use.
Mutel (2007) The emerald
horizon: the history of nature in Iowa. Iowa is arguably
the most ecologically transformed state in the US. While the loss
of prairie is widely known, the changes to our forests were a surprise.
Powers (2007) The echo maker. Richard Powers combines brain damage with sand hill cranes. One
of his best.
Turner (2005) Spice: the
history of a temptation. Who knew that medieval Europe was
feasting on galangal root when it is now little used outside of Thai
cooking? Or that religious reformers scorned monasteries for their
use of spices, which were thought to excite lust?
Hecht (2004) Doubt: a history.
A celebration of doubters, written as if a very knowledgeable historian
were telling her best stories after dinner.
Old favorites
Thomas (1974) Lives
of a cell. (A book that sparked my interest in biology.
Short essays are still fun, even if the scientific revolutions of 1975
are now all familiar. His raptures over Bach masses and
Beethoven quartets pointed me towards music that I might have never
otherwise heard).
Desmond and Moore (1991). Darwin: the life of a tormented evolutionist. (Excellent
biography – vividly creates the context of Darwin’s life).
Camus (1948) The Plague.
Cummings (1950) XAIPE.
Research interests
My research examines how ecological factors influence evolutionary processes in plants, particularly the origin of new plant species. I examine adaptation and speciation in plants using a range of approaches and tools, including field experiments, molecular techniques, and computer simulations.
My doctoral dissertation examined barriers to tetraploid (= 4 sets of chromosomes) speciation in snow buttercups (Ranunculus adoneus) in the Colorado Rockies. I found strong spatial segregation of the diploid (=2 sets) and tetraploid snow buttercups (see figure 1), but no evidence for ecological differentiation. Strong reproductive exclusion operates to maintain spatial isolation. Stochastic models suggest that limited seed and pollen dispersal can lead to local tetraploid majorities which greatly reduce the barriers to their persistence and establishment.
My postdoctoral work with Dr. Loren Rieseberg at Indiana University and the University of British Columbia focused on barriers to gene flow between crop and wild sunflowers (Helianthus annuus). Populations of wild sunflowers adjacent to the crop retain their distinct morphology despite ongoing hybridization, which suggests that strong selection removes crop alleles. Field experiments in Indiana and Nebraska found that although the traits under selection differed, the loci under selection were the same in the two environments. One allele from the crop was favored at one locus, while an allele from the wild was favored at a second locus. Genome-wide screening of microsatellite frequencies between the crop and adjacent wild populations has identified one locus with an unknown function that has a very large genetic distance, suggesting that strong selection is at work.
My
research at Luther College continues to explore plant adaptation and
speciation. I have begun selecting on large seed size in wild
sunflowers in an effort to re-domesticate the sunflower from its wild
relatives. Early selection likely favored larger seeds, yet the
crop differs in many traits besides seed size. Will re-domestication
result in the same suite of traits? Work on selection on crop-wild
hybrids continues, with field plots in Iowa and North Dakota.
In collaboration with Dr. Daniel Ortiz-Barrientos at the University of Queensland in Australia, I will be examining ecological processes that maintain species barriers between the common sunflower, Helianthus annuus, and the prairie sunflower, Helianthus petiolaris. We previously crossed the two species to make F1 plants, and then back-crossed them to the parental species. Lineages that should have been genetically similar unexpectedly had differences in survival and fitness when grown in the field. We will investigate how the mitochondria is shaping fitness, possibly through the imprinting of genes.
Finally, I have initiated several projects focusing on plants in NE Iowa. First, what evolutionary changes will occur in response to allelopathic invaders? Garlic mustard and spotted knapweed produce compounds which inhibit soil fungi and neighboring plants in North America, but do not have the same effect in Europe. Can native plants and fungi adapt to these invaders?
A second project is investigating levels of chromosome number variation in Iowa prairie grasses and forbs. Many of these plants are known to vary across their range, but so far detailed studies of their distribution in NE Iowa have never been carried out.
NE Iowa has many species that are at the edges of their distribution, especially on our cool, north facing limestone slopes. How will these plants respond to climate change? Will the primary challenge be physiological stress due to increased summer temperature, or will new competitors, herbivores, and diseases be more important? To address this, I have begun studying plants on these slopes in the hopes of identifying the key pressures that might limit their persistence in Iowa.