|ACADEMIC STANDARDS - SCIENCE - AP BIOLOGY
STANDARDS FOR SCIENCE
Advanced Placement Biology
Standards without asterisks (*) represent those that all students are expected to achieve in the course of their studies.
Standards with asterisks (*) represent those that all students should have the opportunity to learn.
1. Fundamental life processes of plants and animals depend on a variety of chemical reactions that are carried out in specialized areas of the organism's cells. As a basis for understanding this concept, students know:
- cells are enclosed within semi-permeable membranes that regulate their interaction with their surroundings
- enzymes are proteins and catalyze biochemical reactions without altering the reaction equilibrium. The activity of enzymes depends on the temperature, ionic conditions and pH of the surroundings
- how prokaryotic cells, eukaryotic cells (including those from plants and animals), and viruses differ incomplexity and general structure
- the Central Dogma of molecular biology outlines the flow of information from transcription of RNA in the nucleus to translation of proteins on ribosomes in the cytoplasm
- the role of the endoplasmic reticulum and Golgi apparatus in secretion of proteins
- usable energy is captured from sunlight by chloroplasts, and stored via the synthesis of sugar from carbon dioxide.
- the role of the mitochondria in making stored chemical bond energy available to cells by completing the breakdown of glucose to carbon dioxide
- most macromolecules (polysaccharides, nucleic acids, proteins, lipids) in cells and organisms are synthesized from a small collection of simple precursors
- * how chemiosmotic gradients in the mitochondria and chloroplast store energy for ATP production
- * how eukaryotic cells are given shape and internal organization by a cytoskeleton and/or cell wall.
2. Mutation and sexual reproduction lead to genetic variation in a population. As a basis for understanding this concept, students know
- meiosis is an early step in sexual reproduction in which the pairs of chromosomes separate and segregate randomly during cell division to produce gametes containing one chromosome of each type.
- only certain cells in a multicellular organism undergo meiosis
- how random chromosome segregation explains the probability that a particular allele will be in a gamete
- new combinations of alleles may be generated in a zygote through fusion of male and female gametes (fertilization).
- why approximately half of an individual's DNA sequence comes from each parent
- the role of chromosomes in determining an individual's sex
- how to predict possible combinations of alleles in a zygote from the genetic makeup of the parents.
3. A multicellular organism develops from a single zygote, and its phenotype depends on its genotype, which is established at fertilization. As a basis for understanding this concept, students know:
- how to predict the probable outcome of phenotypes in a genetic cross from the genotypes of the parents and mode of inheritance (autosomal or X-linked, dominant or recessive)
- * the genetic basis for Mendel's laws of segregation and independent assortment
- * how to predict the probable mode of inheritance from a pedigree diagram showing phenotypes
- * how to use data on frequency of recombination at meiosis to estimate genetic distances between loci, and to interpret genetic maps of chromosomes.
4. Genes are a set of instructions, encoded in the DNA sequence of each organism that specify the sequence of amino acids in proteins characteristic of that organism. As a basis for understanding this concept, students know:
- the general pathway by which ribosomes synthesize proteins, using the tRNAs to translate genetic information in mRNA
- how to apply the genetic coding rules to predict the sequence of amino acids from a sequence of codons in RNA
- how mutations in the DNA sequence of a gene may or may not affect the expression of the gene, or the sequence of amino acids in an encoded protein
- specialization of cells in multicellular organisms is usually due to different patterns of gene expression rather than to differences of the genes themselves
- proteins can differ from one another in the number and sequence of amino acids
- * why proteins having different amino acid sequences typically have different shapes and chemical properties.
5. The genetic composition of cells can be altered by incorporation of exogenous DNA into the cells. As a basis for understanding this concept, students know:
- the general structures and functions of DNA, RNA, and protein
- how to apply base-pairing rules to explain precise copying of DNA during semi-conservative replication, and transcription of information from DNA into mRNA
- how genetic engineering (biotechnology) is used to produce novel biomedical and agricultural producs
- * how basic DNA technology (restriction digestion by endonucleases, gel electrophoresis, ligation, and transformation) is used to construct recombinant DNA molecules
- * how exogenous DNA can be inserted into bacterial cells in order to alter their genetic makeup and support expression of new protein products.
6. Stability in an ecosystem is a balance between competing effects. As a basis for understanding this concept, students know:
- biodiversity is the sum total of different kinds of organisms, and is affected by alterations of habitats
- how to analyze changes in an ecosystem resulting from changes in climate, human activity, introduction of non-native species, or changes in population size
- how fluctuations in population size in an ecosystem are determined by the relative rates of birth, immigration, emigration, and death
- how water, carbon, and nitrogen cycle between abiotic resources and organic matter in the ecosystem and how oxygen cycles via photosynthesis and respiration
- a vital part of an ecosystem is the stability of its producers and decomposers
- at each link in a food web, some energy is stored in newly made structures but much is dissipated into the environment as heat and this can be represented in a food pyramid
- * how to distinguish between the accommodation of an individual organism to its environment and the gradual adaptation of a lineage of organisms through genetic change.
7. The frequency of an allele in a gene pool of a population depends on many factors, and may be stable or unstable over time. As a basis for understanding this concept, students know:
- why natural selection acts on the phenotype rather than the genotype of an organism
- why alleles that are lethal in a homozygous individual may be carried in a heterozygote, and thus maintained in a gene pool
- new mutations are constantly being generated in a gene pool
- Variation within a species increases the likelihood that at least some members of a species will survive under changed environmental conditions
- * the conditions for Hardy-Weinberg equilibrium in a population, and why these conditions are not met in nature
- * how to solve the Hardy-Weinberg equation to determine the predicted frequency of genotypes in a population, given the frequency of phenotypes.
8. Evolution is the result of genetic changes that occur in constantly changing environments. As a basis for understanding this concept, students know:
- how natural selection determines the differential survival of groups of organisms
- a great diversity of species increases the chance that at least some organisms survive large changes in the environment
- the effects of genetic drift on the diversity of organisms in a population
- reproductive or geographic isolation affects speciation
- how to analyze fossil evidence with regard to biological diversity, episodic speciation, and mass extinction
- * how to use comparative embryology, DNA or protein sequence comparisons, and other independent sources to create a branching diagram
- (cladogram) that shows probable evolutionary relationships
- * how several independent molecular clocks, calibrated against each other and using evidence from the fossil record, can help to estimate how long ago various groups of organisms diverged evolutionarily from each other.
9. As a result of the coordinated structures and functions of organ systems, the internal environment of the human body and other living systems remains relatively stable (homeostatic), despite changes in the outside environment. As a basis for understanding this concept, students know:
- how the complementary activity of major body systems provides cells with oxygen and nutrients, and removes toxic waste products such as carbon dioxide
- how the nervous system mediates communication between different parts of the body and interactions with the environment
- how feedback loops in the nervous and endocrine systems regulate conditions within the body.
- the functions of the nervous system, and the role of neurons in transmitting electrochemical impulses
- the roles of sensory neurons, interneurons, and motor neurons in sensation, thought, and response
- * the individual functions and sites of secretion of digestive enzymes (amylases, proteases, nucleases, lipases), stomach acid, and bile salts
- * the homeostatic role of the kidneys in the removal of nitrogenous wastes, and of the liver in blood detoxification and glucose balance
- * the cellular and molecular basis of muscle contraction, including the roles of actin, myosin, Ca+2, and ATP.
- * how hormones (including digestive, reproductive, osmoregulatory) provide internal feedback mechanisms for homeostasis at the cellular level and in whole organisms.
10. Organisms have a variety of mechanisms to combat disease. As a basis for understanding the human immune response, students know:
- the role of the skin in providing nonspecific defenses against infection
- the role of antibodies in the body's response to infection
- how vaccination protects an individual from infectious diseases.
- there are important differences between bacteria and viruses, with respect to their requirements for growth and replication, the primary defense of the body against them, and effective treatment of infections they cause.
- why an individual with a compromised immune system (for example, a person with AIDS) may be unable to fight off and survive infections of microorganisms that are usually benign
- * the roles of phagocytes, B-lymphocytes, and T-lymphocytes in the immune system.
||Organic and Biochemistry
11. The bonding characteristics of carbon lead to many different molecules with varied sizes, shapes, and chemical properties, providing the biochemical basis of life. As a basis for understanding this concept, students know
- large molecules (polymers) such as proteins, nucleic acids, and starch are formed by repetitive combinations of simple sub units.
- the bonding characteristics of carbon lead to a large variety of structures ranging from simple hydrocarbons to complex polymers and biological molecules.
- amino acids are the building blocks of proteins.
- * the system for naming the ten simplest linear hydrocarbons and isomers containing single bonds, simple hydrocarbons with double and triple bonds, and simple molecules containing a benzene ring
- * how to identify the functional groups which form the basis of alcohol, ketones, ethers, amines, esters, aldehydes and organic acids
- * the R-group structure of amino acids and how they combine to form the polypeptide backbone structure of proteins.