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• Describe how cells can produce proteins at the right time and correct amount. 
• Diagram a bacterial promoter with −35 and −10 elements and the transcription start site.
• Describe how mutational analysis can be used to study promoter sequence requirements.
• Develop a promoter mutation hypothesis and design an experiment to test it.
• Successfully and safely manipulate DNA and Escherichia coli for ligation and transformation experiments. 
• Design an experiment to verify a mutated promoter has been cloned into a destination vector. 
• Design an experiment to measure the strength of a promoter. 
• Analyze data showing reporter protein produced and use the data to assess promoter strength. 
• Define type IIs restriction enzymes.
• Distinguish between type II and type IIs restriction enzymes.
• Explain how Golden Gate Assembly (GGA) works.
• Measure the relative strength of a promoter compared to a standard promoter.  

• Students will be able to describe the major aspects of the Mars Curiosity Rover missions.

• Students will be able to synthesize information learned from a classroom jigsaw activity on the Mars Curiosity Rover missions.

• Students will be able to work in teams to plan a future manned mission to Mars.

• Students will be able to summarize their reports to the class.

Students will be able to:

• define different types of symbiotic interactions, with specific examples.
• summarize and critically evaluate contemporary primary literature relevant to ecological symbioses, in particular that between hermit crabs and Hydractinia spp.
• articulate a question, based on observations of a natural phenomenon (in this example, the hermit crab-Hydractinia interaction).
• articulate a testable hypothesis, based on their own observations and read of the literature.
• design appropriate experimental or observational studies to address their hypotheses.
• collect and interpret data in light of their hypotheses.
• problem-solve and troubleshoot issues that arise during their experiment.
• communicate scientific results, both orally and in written form.

Students will:

• name and describe the changes to chromosomes and cytoskeleton during each stage of mitosis.
• compare the usefulness and limitations of information obtained by light microscopy and fluorescence microscopy.
• quantify, analyze and summarize their data on the prevalence of cells at different stages of cell division in randomly sampled cell populations.
• describe how cell imaging is used to collect and analyze data on dynamic cellular events.
• present their scientific data in an appropriate and accurate way to an audience.

Students will be able to:

• identify different stages of Xenopus development
• contrast the strengths and limitations of the Xenopus model organism
• explain the process and purpose of in situ hybridization
• compare gene expression patterns from different germ layers or organ domains
• compare gene expression patterns from different developmental stages

Students will be able to:

• Construct written predictions about 1 factor experiments.
• Interpret simple (2 variables) figures.
• Construct simple (2 variables) figures from data.
• Design simple 1 factor experiments with appropriate controls.
• Demonstrate proper use of standard laboratory items, including a two-stop pipette, stereomicroscope, and laboratory notebook.
• Calculate means and standard deviations.
• Given some scaffolding (instructions), select the correct statistical test for a data set, be able to run a t-test, ANOVA, chi-squared test, and linear regression in Microsoft Excel, and be able to correctly interpret their results.
• Construct and present a scientific poster.

• Describe how cells can produce proteins at the right time and correct amount.
• Diagram how a repressor works to reduce transcription.
• Diagram how an activator works to increase transcription.
• Identify a new promoter from literature and design a method to clone it and test its function.
• Successfully and safely manipulate DNA and Escherichia coli for ligation and transformation experiments.
• Design an experiment to verify a new promoter has been cloned into a destination vector.
• Design an experiment to measure the strength of a promoter.
• Analyze data showing reporter protein produced and use the data to assess promoter strength.
• Define type IIs restriction enzymes.
• Distinguish between type II and type IIs restriction enzymes.
• Explain how Golden Gate Assembly (GGA) works.
• Measure the relative strength of a promoter compared to a standard promoter.

• Students will design a binding site for the neurotransmitter serotonin.
• Students will be able to determine the effect of a change in molecular orientation on the affinity of the molecule for the binding site.
• Students will be able to determine the effect of a change in molecular charge on the affinity of the molecule for the binding site.
• Students will be able to better differentiate between hydrogen bond donors and acceptors.
• Students can use this knowledge to design binding sites for other metabolites.

This article accompanies the lesson "The ACTN3 Polymorphism: Applications in Genetics and Physiology Teaching Laboratories." Learning objectives for the lesson include:

1. Test hypotheses related to the role of ACTN3 in skeletal muscle function.
2. Explain how polymorphic variants of the ACTN3 gene affect protein structure and function.
3. List and explain the differences between fast twitch and slow twitch muscle fibers.
4. List and explain possible roles of the ACTN3 protein in skeletal muscle function.
5. Find and analyze relevant scientific publications about the relationship between ACTN3 genotype and muscle function.
6. Formulate hypotheses related to the relationship between ACTN3 genotype and skeletal muscle function.
7. Design experiments to test hypotheses about the role of ACTN3 in skeletal muscle function.
8. Statistically analyze experimental results using relevant software.
9. Present experimental results in writing.

• Students will be able to explain how genetic drift leads to allelic changes over generations.

• Students will be able to demonstrate that sampling error can affect every generation, which can result in random changes in allelic frequency.

• Students will be able to explore and evaluate the effect of population size on the strength of genetic drift.

• Students will be able to analyze quantitative data associated with genetic drift.

Students will be able to:

• Apply findings from each week's lesson to make predictions and informed hypotheses about the next week's lesson.
• Keep a detailed laboratory notebook.
• Write and peer-edit the sections of a scientific paper, and collaboratively write an entire lab report in the form of a scientific research paper.
• Search for, find, and read scientific research papers.
• Work together as a team to conduct experiments.
• Connect findings and ideas from each week's lesson to get a broader understanding of how plants will respond to higher levels of CO2 (e.g., stomatal density, photosynthetic/respiratory rates, foliar protein concentrations, growth, and resource allocation).

Note: Additional, more specific objectives are included with each of the four lessons (Supporting Files S1-S4)

Students will be able to:

• list and perform the steps of sequence processing and taxonomic inference.
• interpret microbial community diversity from metagenomic sequence datasets.
• compare microbial diversity within and between samples or treatments.

• Systematically develop a functioning, discrete, single-species model of an exponentially-growing or -declining population.
• Use the model to recommend appropriate action for population management.
• Communicate model output and recommendations to non-expert audiences.
• Generate a collaborative work product that most individuals could not generate on their own, given time and resource constraints.

Students will be able to:

• Estimate phylogenetic trees using diverse data types and phylogenetic models.
• Correctly make inferences about evolutionary history and relatedness from the tree diagrams obtained.
• Use selected computer programs for phylogenetic analysis.
• Use bootstrapping to assess the statistical support for a phylogeny.
• Use phylogenetic data to construct, compare, and evaluate the role of geologic processes in shaping the historical and current geographic distributions of a group of organisms.

• Students will be able to use analytical balances and micropipettes.
• Students will be able to calculate averages and standard deviations.
• Students will be able to use t-tests to compare two independent samples.
• Students will be able to justify accepting or rejecting a null hypothesis based on an interpretation of p-values.
• Students will learn to use spreadsheet software such as Microsoft Excel and/or Google Sheets
• Students will be able to explain how pipetting incorrectly leads to errors.

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.

• 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 design targeting constructs.

• Students will be able to predict changes to the gene locus after homologous recombination.

• Students will be able to design experiments to answer a biological question (e.g., "Design an experiment to test if the expression of gene X is necessary for limb development").