
General Methadology for Instructors and TAs
Exercise 3: Intraspecific Vigor and Diversity along a Resource Gradient
Module 3: Natural Selection and Evolution
Lecture
Instructor gives the biological background during the lecture on natural selection.
- Establish the relationship between ecology and evolution and the importance of including an evolutionary perspective when studying ecology in that it would help to determine the appropriate type of questions to ask
- Relationship between Natural Selection (mechanism) and Evolution (outcome)
- Five observations that Darwin made that led him to NS finite amount of resources, unfettered species would grow exponentially indefinitely, species tend to outstrip their resources, competition and death happens within a species, and there are individuals that are more successful in garnering resources and creating offspring
- Ideal parts of a species range would be the area that is most in demand by the species and thus the greatest competition occurs there
- Less successful species are forced to the fringes of the desired range and suffer as a result
- Briefly summarize the little Greenbul paper from Science [add citation] here and talk about the possible importance of fringe habitat in species production
General point: Ecotones as being generative forces for speciation and origin of community diversity - using the paper by Smith et al. In Science magazine June 20, 1998 (276:1855-1857)
>>Ecotones have usually been thought of as merely being the edges of most species ranges and thus would be the more stressed regions with less fit organisms occupying that region. Also many have pointed out that ecotones have much lower species diversity than the surrounding biomes and shouldnt be such important areas to conserve. However, this paper points out that these regions are key in generating new species diversity.
- Summary of main points
- Interested in looking at the diversity within a bird species called the little greenbul (Andropadus virens) in Cameroon
- Had an ecotone (which was what?) between two biomes (Savanna/Sahel and Equatorial Rainforest), each of which should present different selective forces on the birds, as rainfall and other variables differ tremendously between biomes and ecotone
- They measured and compared the rates of migrations of birds between each locations within the ecotone and those in the rainforest using allele frequencies on the basis of 8 microsatellite loci
- They measured morphological divergence in 5 morphological characters that have a close correlation with feeding ecology, flight, and fitness (wing length, weight, tarsus length, upper mandible length, and bill depth)
- Results:
- All but upper mandible length significantly differed between the populations in the ecotone versus the forest (generally ecotone had larger values) but not at all between ecotone-ecotone and forest-forest comparisons
- Gene flow between populations differed and was quantified using the microsatellite data
- Main Result: despite varying Nm values (effective migration rates), the ecotone-forest morphological divergence still existed up to a point when Nm got to be huge the difference was swamped out (Fig. 2)
- Conclusions
- The observed morphological divergence (Table 1) was due to selection for those species that had the optimal values for each trait
- The magnitude of the difference between ecotone and forest greenbul populations was similar to that observed when many different species were compared (Fig. 3)
- Because divergent selection as observed here will often (usually) lead to the production of new species, ecotones may be integral to the production and maintenance of biodiversity in tropical rainforests (rather than just within-forest vicariance mechanisms)
- Suggest that for the long-term good, ecotones should be preserved as well, even though they may have fewer species in them (and hence lower diversity index values as well talk about next time), they should be retained because they are such important evolutionary machines
- What would be the predicted outcome if we were to look at a similar phenomenon on a much smaller scale like along a resource gradient within a species? Prediction: that the heart of the range should have a smaller intraspecific range of diversity and vigor than in the fringes
Hypotheses to test
(students should create hypotheses similar to these in their own words)
- There is no difference in intraspecific diversity between the heart of a species range and the more peripheral areas of its range
- Intraspecific diversity is greatest in the heart of a species range
- Intraspecific diversity is greatest in the periphery of a species range
Independent variables in the experiment
- Location of individuals whether within the heart of the range or on the periphery
Dependent variables that they could use in their experimental design
- Height of selected species
- Number of branches per unit height
- Approximate leaf area index
- Absolute sizes of leaves
- Approximate reproductive output per individual (if that tree species is fruiting)
- Others
Evaluation
Students will be evaluated by having them do a group oral presentation which will be no more than 15 minutes long.
- Report should include the results of the statistical tests and a summary of the discussions with the students in other biomes
- Students should integrate the results of all three biomes into a consensus explanation for why they found the results that they did
Note
This will also be one of the first exercises during which students will be collecting scientific data of their own, so care should be exercised in the field to ensure that the students are rigorous and thorough in the data collection.
Molecular Alternative
At those places where the hardware exists, we should do allozyme diversity of an organism of the students choosing
- This would be my preference for this exercise, as the students would acquire yet another valuable skill and it would introduce them to ecological genetics, a subject not otherwise included (maybe for those sites without allozyme capabilities, we could use molecular laboratory simulations like Fly Lab online)
- Have been consulting with Deb Smith (Univ. Kansas), who thinks that it would be possible to do the exercise in one day, and certainly two days if we were to do some legwork ahead of time (like collecting the organisms, prepping the buffers and stains, pouring the agarose gels that the students will use [however they should also pour some, but since many will not work, they need to have backups immediately ready, and for time reasons they may not be able to pour the gels]
- This alternative would be much more rigorous and interesting for the students, but may necessitate having the TA collect the samples before hand, to avoid needing a full second day to be set aside for the exercise, as training in these molecular ecology skills would be required
- If this were done, we would not have the students do field work for this activity