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After this activity students should be able to:

• predict the outcome of an outbreak due to changes in the factors that influence the acquisition and spread of infectious disease.
• use a Vensim biological model to investigate the acquisition and spread of infectious disease.
• generate and interpret output from a Vensim model.

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.

Students will be able to:

• identify and learn about a scientific research discovery of interest to them using popular press articles and the primary literature
• find a group on campus doing research that aligns with their interests and communicate with the faculty leader of that group
• create and present a poster that synthesizes their knowledge of the research beyond the discovery

• Create genetic methods to determine the fate map of cardiac muscle cells during mouse and zebrafish development.
• Distinguish between gene knockout and fate mapping experimental approaches using Cre/LoxP technology.
• Grasp the significance of how fate mapping methods are applied to answer important questions in developmental biology.

Students will be able to:

• Apply genetics concepts to a relevant case study of Bt corn and monarch butterflies
• Read figures and text from primary literature
• Identify claims presented in scientific studies
• Evaluate data presented in scientific studies
• Critically reason using data
• Evaluate the consequences of GM technology on non-target organisms
• Communicate scientific data orally

• 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:

• Build representations of Holliday junctions using chenille stems.
• Describe the molecular details of heteroduplex structure in both Holliday junctions and resolved Holliday junctions.
• Correctly predict the outcomes of Holliday junction resolutions in terms of DNA structure and genetic crossover.
• State how the cell ensures high fidelity DNA replication and identify instances where the cell employs mechanisms for damage repair.
• Use mechanistic reasoning to explain how an enzyme or ribozyme catalyzes a particular reaction.
• Discuss the chemical and physical relationships between composition and structure of macromolecules.
• Compare and contrast the primary, secondary, tertiary, and quaternary structures of proteins and nucleic acids.

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.

• Students will be able to evaluate the strengths and weaknesses of data.

• Students will be able to employ prior knowledge in formulating a biological research question or hypothesis.

• Students will be able to distinguish a research question from a testable hypothesis.

• Students will recognize that the following are essential elements in experimental design: identifying gaps in prior knowledge, picking an appropriate approach (ex. experimental tools and controls) for testing a hypothesis, and reproducibility and repeatability.

• Students will be able to identify appropriate experimental tools, approaches and controls to use in testing a hypothesis.

• Students will be able to accurately explain why an experimental approach they have selected is a good choice for testing a particular hypothesis.

• Students will be able to discuss whether experimental outcomes support or fail to support a particular hypothesis, and in the case of the latter, discuss possible reasons why.

• Students will be able to compare protein sequences and identify conserved regions and putative domains.
• Students will be able to obtain, examine, and compare structural models of protein domains.
• Students will be able to interpret data on protein interactions (in vitro pull-down and in vitro and in vivo functional assays)
• Students will be able to propose experiments to test protein interactions.

Students will:

• Engage in meta-cognitive learning.
• Develop and conduct an authentic scientific inquiry.
• Generate a testable research question based on observations.
• Evaluate different methods of visualizing data.
• Generate and interpret graphs to answer questions.
• Communicate the results of research and the nature of science in oral and written form.
• Place exploratory research into a larger context of the scientific process.
• Participate in citizen science initiatives.
• Collaborate with peers on a scientific task.

Students will be able to:

• Describe the relationship of cells, chromosomes, and DNA.
• Isolate DNA from strawberries.
• Digest DNA with restriction enzymes.
• Perform gel electrophoresis.
• Design an experiment to compare DNAs by RFLP analysis.
• Predict results of RFLP analysis.
• Interpret results of RFLP analysis.
• Use appropriate safety procedures in the lab.

Students will be able to:

• Describe how changes in cellular homeostasis affect metabolic intermediates.
• Perturb and interpret a simulation of cellular respiration.
• Describe cellular mechanisms regulating cellular respiration.
• Describe how glucose, oxygen, and coenzymes affect cellular respiration.
• Describe the interconnectedness of cellular respiration.
• Identify and describe the inputs and outputs of cellular respiration, glycolysis, pyruvate processing, citric acid cycle, and the electron transport chain.
• Describe how different energy sources are used in cellular respiration.
• Trace carbon through cellular respiration from glucose to carbon dioxide.

Following this activity, students will be able to

• reflect on their experiences in the course.
• recognize alignment between course experiences and the course learning goals and CLOs.
• identify and describe specific examples of course experiences supportive of their achievement of each of the posted course learning goals and CLOs.

Students will

• be motivated to learn science related to specific socio-scientific issues.
• learn science that applies to specific socio-scientific issues.
• be able to discuss the relationship between science and society, as well as the biology behind the issue, related to specific socio-scientific issues.

Overall Broadly, following these activities, students will be able to:

• Explain the goals, procedures, and outcomes of the experiments they perform
• Analyze and interpret the data they generate
• Apply the methods they use to real-world situations

Direct Isolation Following this activity, students will be able to:

• Describe how to isolate a novel phage from a soil sample using different protocols
• Compare and contrast direct and enriched isolation protocols
• Critically analyze plaque assay results and explain experimental shortfalls

Three-Phase Streak Following this activity, students will be able to:

• Describe the procedures associated with isolation and purification of a phage from an environmental sample
• Compare and contrast example three-streak plates to critically analyze varying results
• Rationalize differences in three-streak plates and next step procedures

Serial Dilution Following this activity, students will be able to:

• Calculate PFU titer
• Explain the meaning of PFU
• Differentiate between the serial dilution and titer experiments

DNA Extraction Following this activity, students will be able to:

• Detail the contents of phage MTL (medium titer lysate)
• Explain the purpose of adding nuclease and resin to the MTL
• Explain the contents of their sample at various stages of the DNA isolation protocol
• Explain the function of resin in the protocol
• Differentiate between filters and columns
• Read a spectrophotometer spectrum
• Explain the significance of the 260/280 ratio in DNA isolations
• Calculate how much DNA to add to a restriction digest reaction based on its concentration

Restriction Enzymes and Gels Following this activity, students will be able to:

• Explain how restriction enzymes work.
• Identify restriction enzyme cutting sequences within a DNA fragment.
• Differentiate between the number of cutting sites for a restriction enzyme and the number of fragments it creates.
• Explain why and how gel electrophoresis works
• Analyze a gel by determining whether and how many times a restriction enzyme has cut a fragment of phage DNA
• Create a hypothetical gel based on a given sequence or set of fragments
• Compare their gel to known phage samples based on the number and size of DNA fragments generated by restriction enzyme digestion

Students will be able to...

• outline the life cycle of ticks and explain the transmission cycle of Lyme disease.

• describe factors that make mice a competent reservoir for Borrelia burgdorferi.

• analyze and interpret line and bar graphs of data on the effects of changes to ecological communities on the risk of human exposure to Lyme disease.

• explain how the incidence of Lyme disease is determined by interactions between bacteria, animals, humans and the environment.

• predict how changes in the ecosystem affect Borrelia burgdorferi transmission.

• explain how human activities affect biodiversity and the consequences of those actions on disease outbreaks.

• Census an animal population in the same study area using three different methods.
• Quantitatively compare estimates of population size and/or density generated by each method.
• Articulate the assumptions of each method and explain how violations of these assumptions may bias the results in a given scenario.
• Select the most appropriate method for estimating population size and/or density for a given species and habitat. Justify this choice by explaining why it will produce more reliable data in this scenario than other methods.
• Possible extension: Predict how a given method will perform in a different habitat or for a different species and test this hypothesis by querying a national dataset.