Biology I: Grades 9, 10, 11, 12

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Analyze mathematical and/or computational representations of population data that support explanations of factors that affect population size and carrying capacities of populations within an ecosystem. Examine a representative ecosystem and, based on interdependent relationships present, predict population size effects due to a given disturbance.BIO1.LS2.1

Create a model tracking carbon atoms between inorganic and organic molecules in an ecosystem. Explain human impacts on climate based on this model.BIO1.LS2.2

Analyze through research the cycling of matter in our biosphere and explain how biogeochemical cycles are critical for ecosystem function.BIO1.LS2.3

Analyze data demonstrating the decrease in biomass observed in each successive trophic level. Construct an explanation considering the laws of conservation of energy and matter and represent this phenomenon in a mathematical model to describe the transfer of energy and matter between trophic levels.BIO1.LS2.4

Analyze examples of ecological succession, identifying and explaining the order of events responsible for the formation of a new ecosystem in response to extreme fluctuations in environmental conditions or catastrophic events.BIO1.LS2.5

Model chromosome progression through meiosis and fertilization in order to argue how the processes of sexual reproduction lead to both genetic similarities and variation in diploid organisms. Compare and contrast the processes of sexual and asexual reproduction, identifying the advantages and disadvantages of each.BIO1.LS3.1

Explain how protein formation results in phenotypic variation and discuss how changes in DNA can lead to somatic or germ line mutations.BIO1.LS3.2

Through pedigree analysis, identify patterns of trait inheritance to predict family member genotypes. Use mathematical thinking to predict the likelihood of various types of trait transmission.BIO1.LS3.3

Evaluate scientific data collected from analysis of molecular sequences, fossil records, biogeography, and embryology. Identify chronological patterns of change and communicate that biological evolution is supported by multiple lines of empirical evidence that identify similarities inherited from a common ancestor (homologies).BIO1.LS4.1

Using a model that demonstrates the change in allele frequencies resulting in evolution of a population over many generations, identify causative agents of change.BIO1.LS4.2

Identify ecosystem services and assess the role of biodiversity in support of these services. Analyze the role human activities have on disruption of these services.BIO1.LS4.3

Obtain, evaluate, and communicate information on how molecular biotechnology may be used in a variety of fields.BIO1.ETS2.1

Investigate the means by which karyotypes are utilized in diagnostic medicine.BIO1.ETS2.2

Analyze scientific and ethical arguments to support the pros and cons of application of a specific biotechnology technique such as stem cell usage, in vitro fertilization, or genetically modified organisms.BIO1.ETS2.3