Tag: Natural Selection

Natural Selection

Posted on | by Brian Leakey | Leave a Comment on Natural Selection

 

Student Exploration: Natural Selection
Vocabulary: biological evolution, camouflage, Industrial Revolution, lichen, morph, natural selection, peppered moth
Prior Knowledge Questions (Do these BEFORE using the Gizmo.)
The peppered moth (Biston betularia) is a common moth found in Europe, Asia, and North America. It is commonly found in two forms, or morphs: a dark morph and a light, speckled morph. Birds are a frequent predator of the peppered moth.
1. Which morph do you think would be easier to see on a dark tree trunk? _______________________________
2. Which morph do you think would be easier to see on a light tree trunk? _______________________________
Gizmo Warm-up
The Natural Selection Gizmo™ allows you to play the role of a bird feeding on peppered moths. The initial population of 40 moths is scattered over 20 tree trunks. Click on moths to capture them. Click the Next tree button (or the spacebar on your keyboard) to advance to the next tree.
1. Check that LIGHT TREES is selected. Click Play ( ), and hunt moths for one year.
A. How many dark moths did you capture? _______
B. How many light moths did you capture? _______
C. Camouflage is coloring or patterns that help an organism to blend in with the background. Which type of moth is better camouflaged on light bark?____________
2. If a forest contained mostly light-colored trees, which type of moth would you expect to be most common?

Activity A:
Light trees Get the Gizmo ready:
• Click Reset ( ).
• Check that the LIGHT TREES tab is selected.
Introduction: Before the 19th century in England, the air was very clean. The bark on trees was usually light in color. Abundant lichens growing on tree trunks
also lightened their appearance.
Question: How does the color of a peppered moth affect survival?
1. Predict: Over time, what will to happen to the populations of light and dark moths on light trees?
2. Experiment: Click Play and hunt peppered moths on light tree trunks for five years. In each year, try to capture as many moths as you can. Note: You can use the spacebar on your keyboard to quickly advance to the next tree.
After 5 years, select the TABLE tab and record the percentages of each moth type. (Note: The table shows current populations of each moth, not the number of captured moths.)
Year Dark moths Light moths
0
1
2
3
4
5
Then click the GRAPH tab, click the camera icon on the upper right to take a snapshot of the graph of your 5 year totals. Paste the snapshot into the lab report in the space below:
Picture of Graph:
3. Analyze: What do your results show? ___________________________________________
4. Apply: Which type of moth do you think was more common before the 19th century, when most trees were light in color?_________________________________________________
5. Extend your thinking: What strategies did you use to hunt for moths? __________________
Activity B:
Dark trees Get the Gizmo ready:
• Click Reset.
• Select the DARK TREES tab.
Introduction: The 19th century was the time of the Industrial Revolution in England. Most of the new industries used coal for energy, and the air was polluted with black soot. In forests near factories, the soot coated trees and killed lichens. As a result, tree trunks became darker.
Question: How did air pollution affect moth populations?
1. Predict: Over time, what will to happen to the populations of light and dark moths on dark trees?
2. Experiment: Click Play and hunt peppered moths on dark tree trunks for five years. In each year, try to capture as many moths as you can.
When you are done, select the TABLE tab and record the percentages of each moth type.
Year Dark moths Light moths
0
1
2
3
4
5
Then click the GRAPH tab, click the camera icon on the upper right to take a snapshot of the graph of your 5 year totals. Paste the snapshot into the lab report in the space below:
Picture of Graph:
3. Analyze: What do your results show? ___________________________________________
_________________________________________________________________________
4. Apply: Which type of moth do you think was more common during the 19th century? Why?_________________________________________________________________________
(Activity B continued on next page)
Activity B (continued from previous page)
5. Draw conclusions: Natural selection is the process by which favorable traits tend to increase in frequency over time. How does this experiment illustrate natural selection?
6. Think and discuss: Did the changes you observed in the moth populations result from individual moths changing colors? Or did they occur because the best-hidden moths survived and reproduced, passing on their colors to their offspring? Explain your answer.
7. Extend your thinking: Biological evolution is the process by which populations of organisms change over time. How could natural selection lead to evolution? If possible, discuss your answer with your classmates and teacher.

 

Natural selection.

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We have spent two modules talking about natural selection. If you could choose one organism in which to understand the genomic signature of natural selection, what would it be and why? How would you go about understanding selection for your organism?

Natural selection.

Posted on | by

We have spent two modules talking about natural selection. If you could choose one organism in which to understand the genomic signature of natural selection, what would it be and why? How would you go about understanding selection for your organism?

Natural selection.

Posted on | by

We have spent two modules talking about natural selection. If you could choose one organism in which to understand the genomic signature of natural selection, what would it be and why? How would you go about understanding selection for your organism?

Natural selection

Posted on | by

 

We have spent two modules talking about natural selection. If you could choose one organism in which to understand the genomic signature of natural selection, what would it be and why? How would you go about understanding selection for your organism?

 

 

what Sexual Selection is and .Explain how it differs from Natural Selection

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Please answer questions, label 1A 1B (number and letter), also include citations and references. check plagiarism thanks! Answers does not have to be long

1. A) Describe what Sexual Selection is and B) explain how it differs from Natural Selection

2. Research a behavior in an animal and A) explain the ultimate causes of that behavior and B) list the proximate causes of it.

3. “The southern gastric brooding frog was discovered in 1972 and properly described in 1981. Intense interest followed and in the same year it had disappeared in the wild, shortly followed by the last captive specimen’s death in 1983. The interest was primarily due to the frog’s unusual reproductive method. The female swallows her eggs and turns her stomach into a womb, vomiting up her young when they are grown. The loss of her stomach means she doesn’t eat while they develop, and her new womb bloats so much it causes her lungs to collapse (meaning she has to breathe through her skin). On the other hand another species of frog, the Túngara frog, lay their eggs in a pond and leaves them to develop on their own without any parental care” (www.facebook.com/evolutionarybiology – like). A) Compare the gastric brooding frog and the Túngara in terms of how they balance the trade-off of quality vs. quantity of offspring (are they each K-selected or r-selected?). B) What other life-history traits (include: life span, number of offspring produced, age at reproduction, reproductive events per lifetime) do you expect to find differences between gastric brooding frog or the Túngara frog? Explain.

4. A) Explain why one can argue that humans were r-selected species before the industrial revolution and now in modern times see to be K-selected (in your explanation include the terms: carrying capacity, rate of population growth). B) In most countries, the number of offspring produced per couple is decreasing every year, the age of first time mothers in increasing (they are older when they have their first baby) and the cost of investment per offspring is increasing (for example college tuition!). Explain what effect would that have in the model of population growth in those countries (do you expect them to be more K-selected or r-selected?) Make sure to support your argument. C) Can human population increase forever? (use the terms: carrying capacity, population growth, density-dependent and density-independent factors).

5. PICTURE ATTACHED Study the figure below (published in Kwano et al. 2002). The x-axis of the figure shows different locations at different altitudes, with altitude decreasing from left to right (W. Java has the highest altitude, W. Mindanao has the lowest). The y-axis represents the range of body length for beetles found at each location. Two species of closely related rhinoceros beetles inhabit Southeast Asia: Chalcosoma caucasus and Chalcosoma atlas. One species, C. atlas (white boxes in the figure), is more common in low altitude, while C. caucasus (filled boxes in the figure) is more common in higher altitudes. However, they overlap at intermediate altitude (from Lampung to E. Thailand). The graph shows the body length of each species in allopatric and sympatric locations. What ecological phenomenon can explain the differences between the allopatric (when only one species lives in that location) and sympatric (when both species live in the same location) populations? Please explain your argument, you MUST include the terms: competition, competitive exclusion, realized niche, fundamental niche, resource-partitioning & character displacement).

6. The use of pesticides in agriculture leads to the unexpected increase in the number of pest, this has been termed “The Pesticide Paradox”. The reason for such paradox is that pesticides disrupt natural predator-prey interactions. A) Explain the natural changes in the population of prey and predator of a pest population (example: plant-eating mites and mite-eating mites). B) Explain two (2) possible effects of pesticides on the natural predator-prey population dynamics. C) Suggest an alternative method of pest control that does not result in the inconvenient increase of pest populations