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After completing the Lesson, students will be able to:

• Differentiate between types of transport across membranes (diffusion, facilitated diffusion, and active transport)
• Determine if proteins are necessary or sufficient for transport of pyruvate across a membrane based on experimental data
• Interpret data obtained from pyruvate transport mutants
• Design an experiment to test a specific hypothesis related to transport across membranes

At the end of this unit, students will be able to:

• Define the central distinction between public health and medicine
• Apply objectives of public health and individual medical care in a particular situation to identify potential areas of conflict in priority setting
• Apply moral theories of utilitarianism and deontology to a particular situation to identify the course of action proponents of each theory would see as morally justified
• Identify the range of morally justifiable actions that might be available to a health professional in a particular setting
• Choose from among a range of possible actions in a particular health situation and articulate the ethical principles that would justify that choice.

Students will be able to:

• Create foundational knowledge about their research topic by reading review articles and primary research papers.
• Use this knowledge to formulate novel research questions.
• Formulate a hypothesis statement that is testable, falsifiable, and rooted in a biological mechanism.
• Learn differences between a hypothesis statement, a research questions and experimental predictions.

Students will be able to:

• Describe the reservoirs of infection in humans.
• Distinguish portals of entry and exit.
• Describe how each of the following contributes to bacterial virulence: adhesins, extracellular enzymes, toxins, and antiphagocytic factors.
• Define and distinguish etiology and epidemiology.
• Describe the five typical stages of infectious disease and depict the stages in graphical form.
• Contrast contact, vehicle and vector transmission, biological and mechanical vectors and identify the mode of transmission in a given scenario.
• Differentiate endemic, sporadic, epidemic, and pandemic disease.
• Distinguish descriptive, analytical, and experimental epidemiology.
• Compare and contrast social, economic, and cultural factors impacting health care in the early 1900s and today.

Students will be able to:

• Use VHF (Very High Frequency) radio telemetry to track the space use of a sciurid (squirrel) species in a study area.
• Explain why VHF radio telemetry is the most appropriate and widely used method for tracking the space use of sciurids.
• Discuss potential applications of data collected in class for wildlife management and conservation.

Students will be able to:

1. Describe the process, challenges, and benefits of structured decision making for natural resource management decisions.
2. Explain and reflect on the role of science and scientists in structured decision making and how those roles interact and compare to the roles of other stakeholders.
3. Assess scientific evidence for a given management or policy action to resolve an environmental issue.

After completion of the lesson students will be able to:

1. Describe the differences between female and male meiosis.
2. Interpret graphical data to make decisions relevant to medical practices.
3. Develop a hypothesis that explains the difference in incidence of aneuploidy in gametes between males and females.

At the end of this activity, we expect students will be able to:

1. Use family pedigrees and additional genetic information to determine inheritance patterns for hereditary forms of cancer
2. Explain why a person with or without cancer can pass on a mutant allele to the next generation and how that impacts probability calculations
3. Distinguish between proto-oncogenes and tumor suppressor genes

Students will be able to

• describe the ecology and natural history of their chosen species.
• describe human effects on their species and its habitat.
• share interesting facts about a wide variety of species with friends and family outside the class.
• stay engaged during readings and whole-class lectures on the topic of organismal diversity.

1. Define coevolution.
2. Identify types of evidence that would help determine whether two species are currently in a coevolutionary relationship.
3. Interpret graphs.
4. Evaluate evidence about whether two species are coevolving and use evidence to make a scientific argument.
5. Describe what evidence of a coevolutionary relationship might look like.
6. Distinguish between coadaptation and coevolution.

Students will be able to:

• Describe how the scientific method can be used to answer real-world problems.
• Define the basic components of an experiment.
• Predict how tolerance of extreme temperatures and phenotypic plasticity may influence individual fitness and ultimately shape the evolution of organisms.
• Understand the basic principles of climate change and evaluate how these changes in temperature regimes will impact organisms.

Students will be able to:

• Describe challenges of tracing seafood through the supply chain.
• Provide different definitions for the term "sustainable".
• Describe the limitations of consumer-driven natural resource management incentives.
• Provide examples of science and technological innovations relevant to fisheries management.
• Identify different stakeholders in the seafood supply chain.
• Explain the characteristics of data collection and research that can strengthen the effectiveness of using science to guide policy.

Students will be able to

• Apply technology and field-based skills (such as bird identification and use of binoculars) to contribute to a citizen science database.
• Collaborate as part of a group in the design and implementation of a field study.
• Analyze and interpret original data.
• Communicate their results in the form of a written or oral report.
• Define species diversity and describe correlates of species diversity based on original data and the scientific literature.

Activity 1: Introducing Matter and Energy

• Students will be able to determine if they hold misconceptions about matter and energy in organisms.
• Students will be able to reason about biological systems by tracing matter and energy in organisms separately.

Activity 2: Understanding What is (and is not) Food

• Students will be able to connect everyday, macroscopic notions of food with chemical concepts (e.g., bonds, molecules).
• Students will be able to compare and contrast food and non-food for plants, animals, and fungi and explain what characteristics make something food for living organisms.

Activity 3: Predicting Mass Change Across the Tree of Life

• Students will be able to use their understanding of photosynthesis and cellular respiration to accurately predict patterns of mass change in plants, animals, and fungi.
• Students will be able to qualitatively predict how biological processes in a plant, animal, or fungus will contribute to the amount of carbon dioxide and oxygen in the air over time in open and closed environments.

Activity 4: Explaining Changes in Matter and Energy Using Conceptual Models

• Students will be able to integrate concepts about matter and energy across different biological scales.
• Students will be able to build conceptual models capable of explaining patterns of matter movement (e.g., mass gain, loss) in different organisms (e.g., plants, animals) and contexts (e.g., sunny and cloudy environments, active or sedentary behaviors).

Activity 5: Correcting Misconceptions about Matter and Energy

• Students will be able to identify and correct common misconceptions about matter and energy in plants, animals, and fungi.

After completing of this activity, students will be able to:

• Explain how natural selection impacts allele frequency in a population
• List and describe the four requirements for natural selection to occur in a population
• Refute common misconceptions regarding evolution and natural selection

Students will be able to:

• identify characteristics of each stage of axolotl embryonic development.
• understand the importance of model organisms in the study of biological processes.
• compare strengths and limitations of axolotls as model organisms.
• understand the concepts related to differential gene expression and cell specialization.
• integrate their understanding of differential expression and cell specialization.
• explain the process and purpose of PCR, qPCR, and reverse transcriptase.
• calculate expression levels from raw qPCR results.
• analyze gene expression levels in embryos at different stages of development.

1. Students will be able to define the phrase ‘broader impacts of science.’
2. Students will be able to describe current and historical relationships between science and society.
3. Students will be able to identify methods by and contexts in which scientific research is applied in the public sphere.
4. Students will be able to map complex interactions between science and society.
5. Students will be able to evaluate the effectiveness of different public engagement strategies.

• Define basic concepts and terminology of Ecosystem Ecology
• Link biological processes that affect each other
• Evaluate whether the link causes a positive, negative, or neutral effect
• Find primary literature
• Identify data that correctly supports or refutes an hypothesis

Students will be able to:

• explain how enzymes catalyze chemical reactions.
• describe interactions between enzymes, substrates, and products.
• evaluate the effects of different types of enzyme inhibitors and regulators.
• demonstrate the relationship between structure and function of enzymes.

Students will be able to:

• discuss how the immune system functions to maintain homeostasis of the human body, especially during an influenza infection.
• describe how biological factors, such as sex and age, affect immune system functions.
• propose hypotheses regarding the impact of sex hormones and age on the immune response to influenza and vaccine efficacy based on feedback loops.
• design experiments with mammalian model systems and immunology-based lab assays to test hypotheses.
• analyze primary data that support or refute proposed hypotheses.
• communicate findings through poster presentations in a manner similar to a research conference.