5.1 Evidence for evolution
Nature of science:
Looking for patterns, trends and discrepancies there are common features in the bone structure of vertebrate limbs despite their varied use.
Understandings:
• Evolution occurs when heritable characteristics of a species change.
• The fossil record provides evidence for evolution.
• Selective breeding of domesticated animals shows that artificial selection can cause evolution.
• Evolution of homologous structures by adaptive radiation explains similarities in structure when there are differences in function.
• Populations of a species can gradually diverge into separate species by evolution.
• Continuous variation across the geographical range of related populations matches the concept of gradual divergence.
Applications and skills:
• Application: Development of melanistic insects in polluted areas.
• Application: Comparison of the pentadactyl limb of mammals, birds, amphibians and reptiles with different methods of locomotion.
Theory of knowledge:
• Evolutionary history is an especially challenging area of science because experiments cannot be performed to establish past events or their causes. There are nonetheless scientific methods of establishing beyond reasonable doubt what happened in some cases. How do these methods compare to those used by historians to reconstruct the past?
Looking for patterns, trends and discrepancies there are common features in the bone structure of vertebrate limbs despite their varied use.
Understandings:
• Evolution occurs when heritable characteristics of a species change.
• The fossil record provides evidence for evolution.
• Selective breeding of domesticated animals shows that artificial selection can cause evolution.
• Evolution of homologous structures by adaptive radiation explains similarities in structure when there are differences in function.
• Populations of a species can gradually diverge into separate species by evolution.
• Continuous variation across the geographical range of related populations matches the concept of gradual divergence.
Applications and skills:
• Application: Development of melanistic insects in polluted areas.
• Application: Comparison of the pentadactyl limb of mammals, birds, amphibians and reptiles with different methods of locomotion.
Theory of knowledge:
• Evolutionary history is an especially challenging area of science because experiments cannot be performed to establish past events or their causes. There are nonetheless scientific methods of establishing beyond reasonable doubt what happened in some cases. How do these methods compare to those used by historians to reconstruct the past?
5.2 Natural selection
Nature of science:
Use theories to explain natural phenomena the theory of evolution by natural selection can explain the development of antibiotic resistance in bacteria.
Understandings:
• Natural selection can only occur if there is variation among members of the same species.
• Mutation, meiosis and sexual reproduction cause variation between individuals in a species.
• Adaptations are characteristics that make an individual suited to its environment and way of life.
• Species tend to produce more offspring than the environment can support.
• Individuals that are better adapted tend to survive and produce more offspring while the less well adapted tend to die or produce fewer offspring.
• Individuals that reproduce pass on characteristics to their offspring.
• Natural selection increases the frequency of characteristics that make individuals better adapted and decreases the frequency of other characteristics leading to changes within the species.
Applications and skills:
• Application: Changes in beaks of finches on Daphne Major.
• Application: Evolution of antibiotic resistance in bacteria.
Theory of knowledge:
• Natural Selection is a theory. How much evidence is required to support a theory and what sort of counter evidence is required to refute it?
Use theories to explain natural phenomena the theory of evolution by natural selection can explain the development of antibiotic resistance in bacteria.
Understandings:
• Natural selection can only occur if there is variation among members of the same species.
• Mutation, meiosis and sexual reproduction cause variation between individuals in a species.
• Adaptations are characteristics that make an individual suited to its environment and way of life.
• Species tend to produce more offspring than the environment can support.
• Individuals that are better adapted tend to survive and produce more offspring while the less well adapted tend to die or produce fewer offspring.
• Individuals that reproduce pass on characteristics to their offspring.
• Natural selection increases the frequency of characteristics that make individuals better adapted and decreases the frequency of other characteristics leading to changes within the species.
Applications and skills:
• Application: Changes in beaks of finches on Daphne Major.
• Application: Evolution of antibiotic resistance in bacteria.
Theory of knowledge:
• Natural Selection is a theory. How much evidence is required to support a theory and what sort of counter evidence is required to refute it?
5.3 Classifiaction of biodiversity
Nature of science:
Cooperation and collaboration between groups of scientists scientists use the binomial system to identify a species rather than the many different local names.
Understandings:
• The binomial system of names for species is universal among biologists and has been agreed and developed at a series of congresses.
• When species are discovered they are given scientific names using the binomial system.
• Taxonomists classify species using a hierarchy of taxa.
• All organisms are classified into three domains.
• The principal taxa for classifying eukaryotes are kingdom, phylum, class, order, family, genus and species.
• In a natural classification, the genus and accompanying higher taxa consist of all the species that have evolved from one common ancestral species.
• Taxonomists sometimes reclassify groups of species when new evidence shows that a previous taxon contains species that have evolved from different ancestral species.
• Natural classifications help in identification of species and allow the prediction of characteristics shared by species within a group.
Applications and skills:
• Application: Classification of one plant and one animal species from domain to species level.
• Application: Recognition features of bryophyta, filicinophyta, coniferophyta and angiospermophyta.
• Application: Recognition features of porifera, cnidaria, platylhelmintha, annelida, mollusca, arthropoda and chordata.
• Application: Recognition of features of birds, mammals, amphibians, reptiles and fish.
• Skill: Construction of dichotomous keys for use in identifying specimens.
Guidance:
• Archaea, eubacteria and eukaryote should be used for the three domains.
• Members of these domains should be referred to as archaeans, bacteria and eukaryotes.
• Viruses are not classified as living organisms.
Theory of knowledge:
• The adoption of a system of binomial nomenclature is largely due to Swedish botanist and physician Carolus Linnaeus (1707–1778). Linnaeus also defined four groups of humans, and the divisions were based on both physical and social traits. By 21st-century standards, his descriptions can be regarded as racist. How does the social context of scientific work affect the methods and findings of research? Is it necessary to consider the social context when evaluating ethical aspects of knowledge claims?
International-mindedness:
• There are international codes of nomenclature and agreements as to the principles to be followed in the classification of living organisms.
Cooperation and collaboration between groups of scientists scientists use the binomial system to identify a species rather than the many different local names.
Understandings:
• The binomial system of names for species is universal among biologists and has been agreed and developed at a series of congresses.
• When species are discovered they are given scientific names using the binomial system.
• Taxonomists classify species using a hierarchy of taxa.
• All organisms are classified into three domains.
• The principal taxa for classifying eukaryotes are kingdom, phylum, class, order, family, genus and species.
• In a natural classification, the genus and accompanying higher taxa consist of all the species that have evolved from one common ancestral species.
• Taxonomists sometimes reclassify groups of species when new evidence shows that a previous taxon contains species that have evolved from different ancestral species.
• Natural classifications help in identification of species and allow the prediction of characteristics shared by species within a group.
Applications and skills:
• Application: Classification of one plant and one animal species from domain to species level.
• Application: Recognition features of bryophyta, filicinophyta, coniferophyta and angiospermophyta.
• Application: Recognition features of porifera, cnidaria, platylhelmintha, annelida, mollusca, arthropoda and chordata.
• Application: Recognition of features of birds, mammals, amphibians, reptiles and fish.
• Skill: Construction of dichotomous keys for use in identifying specimens.
Guidance:
• Archaea, eubacteria and eukaryote should be used for the three domains.
• Members of these domains should be referred to as archaeans, bacteria and eukaryotes.
• Viruses are not classified as living organisms.
Theory of knowledge:
• The adoption of a system of binomial nomenclature is largely due to Swedish botanist and physician Carolus Linnaeus (1707–1778). Linnaeus also defined four groups of humans, and the divisions were based on both physical and social traits. By 21st-century standards, his descriptions can be regarded as racist. How does the social context of scientific work affect the methods and findings of research? Is it necessary to consider the social context when evaluating ethical aspects of knowledge claims?
International-mindedness:
• There are international codes of nomenclature and agreements as to the principles to be followed in the classification of living organisms.
5.4 cladistics
Nature of science:
Falsification of theories with one theory being superseded by another plant families have been reclassified as a result of evidence from cladistics.
Understandings:
• A clade is a group of organisms that have evolved from a common ancestor.
• Evidence for which species are part of a clade can be obtained from the base sequences of a gene or the corresponding amino acid sequence of a protein.
• Sequence differences accumulate gradually so there is a positive correlation between the number of differences between two species and the time since they diverged from a common ancestor.
• Traits can be analogous or homologous.
• Cladograms are tree diagrams that show the most probable sequence of divergence in clades.
• Evidence from cladistics has shown that classifications of some groups based on structure did not correspond with the evolutionary origins of a group or species.
Applications and skills:
• Application: Cladograms including humans and other primates.
• Application: Reclassification of the figwort family using evidence from cladistics.
• Skill: Analysis of cladograms to deduce evolutionary relationships.
Theory of knowledge:
• A major step forward in the study of bacteria was the recognition in 1977 by Carl Woese that Archaea have a separate line of evolutionary descent from bacteria. Famous scientists, including Luria and Mayr, objected to his division of the prokaryotes. To what extent is conservatism in science desirable?
Falsification of theories with one theory being superseded by another plant families have been reclassified as a result of evidence from cladistics.
Understandings:
• A clade is a group of organisms that have evolved from a common ancestor.
• Evidence for which species are part of a clade can be obtained from the base sequences of a gene or the corresponding amino acid sequence of a protein.
• Sequence differences accumulate gradually so there is a positive correlation between the number of differences between two species and the time since they diverged from a common ancestor.
• Traits can be analogous or homologous.
• Cladograms are tree diagrams that show the most probable sequence of divergence in clades.
• Evidence from cladistics has shown that classifications of some groups based on structure did not correspond with the evolutionary origins of a group or species.
Applications and skills:
• Application: Cladograms including humans and other primates.
• Application: Reclassification of the figwort family using evidence from cladistics.
• Skill: Analysis of cladograms to deduce evolutionary relationships.
Theory of knowledge:
• A major step forward in the study of bacteria was the recognition in 1977 by Carl Woese that Archaea have a separate line of evolutionary descent from bacteria. Famous scientists, including Luria and Mayr, objected to his division of the prokaryotes. To what extent is conservatism in science desirable?