CT-STEM

From Ecosystems To Speciation - Preview

From Ecosystems To Speciation

Subject: Biology
Time: 8-10 classes, 45-50 min each
Level:

Introductory High School Biology


Overview

Students will develop an understanding of how populations interact with each  other within a community, discussing ideas concerning carrying capacity, competition, and interdependence. From there students will use models to explain the connection between genetic drift, natural selection, and speciation.

Lesson 1: Students will gather information from real-world case study (the Isle Royale wolf & moose ecosystem) and develop questions about factors that might be influencing population size changes. 

Lesson 1 Teacher Guide


Lesson 2: Students will look at single population of organisms and investigate how population growth is influenced by limiting factors such as resources. Using this NetLogo model they will be able to visualize some of the factors that lead to the formation of a carrying capacity for organism within a defined area. Students will then simulate how carrying capacity is affected by the introduction of a predator to the system and will also be able to see the dynamic interaction between these two organisms over the course of a large time scale.

Lesson 2 Teacher Guide


Lesson 3: Students will describe how consumer/producer interactions for limited resources necessary for survival leads to the emergence of a competition for those resources, even when there is no intentional effort being made by individuals to outcompete each other.

Lesson 3 Teacher Guide


Lesson 4: Students will explain how populations indirectly compete against each other, by applying the concepts of stability and change in population sizes over time, direct and indirect interactions between individuals, and immediate and delayed outcomes in two different ecosystems, each more complex than those modeled previously computer.

Lesson 4 Teacher Guide


Lesson 5: Students experiment with a population of bacteria growing in an environment with sugar as an energy source. The population of bacteria consist of different types represented with different colors. Different types of bacteria have different number of flagella; however, in this model there is no selective advantage of having more number of flagella. Students explore this model to investigate the phenomenon of genetic drift. They discover that even though there is no selective advantage of having more or less flagella, eventually only one type survives in the population. This happens because of statistical selection, also referred to as genetic drift.

Lesson 5 Teacher Guide


Lesson 6: In this activity students engage in simulated natural selection to discover how natural selection emerges from mechanisms: a) variation in heritable traits in a population and b) interactions in the environment give individuals with some variations a competitive advantage over other individuals. Another purpose  of this lesson is to describe the outcome of natural selection as an increase in the proportion of individuals with advantageous heritable trait variations in a population over multiple generations.

Lesson 6 Teacher Guide


Lesson 7 and Lesson 8: The purpose of the activities in these lessons is to understand how new species can form from old species through the mechanisms of evolution covered so far in the unit (mutation, genetic drift, changes in environmental conditions, and natural selection).

Lesson 7 Teacher Guide         Lesson 8 Teacher Guide

Compatible With


mac

windows

laptops

chrome books

phones

tablets

Standards

Next Generation Science Standards
  • Life Science
    • [HS-LS4] Biological Evolution: Unity and Diversity
    • [HS-LS2] Ecosystems: Interactions, Energy, and Dynamics
  • NGSS Crosscutting Concept
    • Patterns
    • Systems
    • Stability and Change
  • NGSS Practice
    • Using Models
    • Conducting Investigations
    • Analyzing Data

Computational Thinking in STEM
  • Modeling and Simulation Practices
    • Using Computational Models to Find and Test Solutions
    • Using Computational Models to Understand a Concept
  • Computational Problem Solving Practices
    • Troubleshooting and Debugging
  • Data Practices
    • Analyzing Data
    • Manipulating Data
    • Visualizing Data
  • Systems Thinking Practices
    • Investigating a Complex System as a Whole
    • Thinking in Levels
    • Understanding the Relationships within a System

Acknowledgement

CODAP is developed and built by The Concord Consortium at https://codap.concord.org/  

Lesson 7 is based on the lesson Evolution in Action: The Galápagos Finches Authored by Paul Strode for Howard Hughes Medical Institute based on data collected by Peter and Rosemary Grant, Princeton University.

This work is supported by the National Science Foundation (grants CNS-1138461, CNS-1441041 and DRL-1020101) and the Spencer Foundation (grant 201600069). Any opinions, findings, conclusions, and/or recommendations are those of the investigators and do not necessarily reflect the views of the funding organizations.

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Lesson 4: Competition Between Populations