Teaching Licensure: Biology

About the test

Teacher qualification test in biology is a 2-hour computerized test that targets teachers who
teach biology in cycle 3 schools in UAE.

The content of this test is organized into six main topics in biology: Biology as a scientific
discipline, molecular and cellular life processes, anatomy and physiology of living organisms,
evolution and diversity of life, genetics and human heredity, and ecosystems: Interactions,
energy and dynamics.

The table below explains the information of the test.

Target candidates Number and type Test Duration Format Calculators

of Questions
Cycle 3 Biology 80 MCQs 2 hours Computerized test Allowed
Teachers
Topics Weight
Biology as a scientific discipline 10%
Molecular and cellular life processes 25%
Anatomy and physiology of living organisms 20%
Evolution and diversity of life 10%
Genetics and human heredity 25%
Ecosystems: Interactions, energy and dynamics 10%
Total 100 %

Biology

Biology as a scientific discipline

10% 10% Molecular and cellular life processes

Anatomy and physiology of living

25% 25% organims
Evolution and diversity of life

Genatics and human heredity

10%
20%
Ecosystems: Interactions, energy and
dynamics
Content specifications in Biology
The content of the test is defined by a set of core competencies that biology teachers should meet
to determine their ability to carry out their content area teaching effectively.

Topics and core competencies

Below are the topics and related core competencies that biology teachers should be able to
demonstrate, in terms of knowledge and skills, to meet the expectations of this test:

1. Biology as a scientific discipline

Manage laboratory activities and properly use lab resources and material to assure the safety of the
students.
Use the scientific method principles and procedures for designing and conducting scientific
investigations.
Appropriately select and use a variety of tools, techniques and procedures to gather data and perform
the correct calculations.
Analyze the impact of science and its interaction with technology in terms of making informed
decisions about personal and societal issues.

2. Molecular and cellular life processes

Relate the properties of chemical bonds to specific important processes in the body including
homeostasis and energy production.
Relate the structure and properties of water to major life processes in living organisms.
Identify the structure and function of biological molecules in the cells.
Explain the role of enzymes in chemical reactions and identify the factors that could affect their
production and functions.
Relate the level of organization to cellular differentiation and specialization in different living
organisms.
Compare and contrast prokaryotic and eukaryotic cells in terms of structure and function.
Explain the function of cell organelles in relation to their structure.
Explain the transportation of water and other materials through the cell membrane.
Explain photosynthesis and analyze the electron and energy (ATP) flow during light dependent and
dark reactions (Calvin Cycle).
Explain the types of cellular respiration and discuss the functions of anaerobic cellular respiration.
Differentiate the main cellular events during the cellular cycle and compare the mechanisms of
mitosis and meiosis.

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3. Anatomy and physiology of living organisms

Relate the structure of major body systems in multicellular organisms, including humans, to their
specific functions and their interaction with each other to maintain homeostasis.

Examine specific features and behavior of prokaryotes, to identify their effects on living organisms.

4. Evolution and diversity of life

Explain the evolutionary mechanisms (e.g. natural selection and genetic drift), and provide
example on each mechanism.

Analyze the effects of evolutionary mechanisms on evolution in populations.

Describe the main types of evidence to evolution (e.g. comparative anatomy, comparative
embryology, and molecular biology), and analyze evolutionary trees and cladograms to determine
descendant relationships to their ancestors.

Describe how living organisms are classified, and categorize them according to specific structural
and functional characteristics.

5. Genetics and human heredity

Distinguish between the structure and function of DNA and RNA, and sequence the main events of
protein synthesis in the cell.

Use the genetic code rules to read the DNA sequence, and identify the amino acids in the
polypeptide chain.

Compare gene expression regulation in prokaryotes and eukaryotes, and identify the type and
possible causes of mutation that might happen during this process.

Apply Mendel’s laws of dominance, segregation and independent assortment and variations (e.g.
sex-linked, codominance, and multiple alleles) to predict the probable outcomes of offspring.

Describe the process of genetic engineering and analyze their use in different domains of life.

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6. Ecosystems: Interactions, energy and dynamics

Distinguish between different ecological concepts (e.g. Biomes, ecosystem, communities, habitats and
niches) and give examples of interactions among different organisms.
Evaluate the effect of human- activities, i.e. Density dependent factors and density independent factors
on carrying capacity and changing ecosystems dynamics.
Interpret food chains and food webs in terms of interaction of organisms through different trophic
levels and flow of energy, and analyze the effects of biotic and abiotic factors on ecosystems
dynamics.

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Crosscutting concepts and related competencies

The main topics of biology are coupled with several crosscutting concepts and practices in other
disciplines of science. Biology teachers are expected to display knowledge and skills in the
following crosscutting concepts as identified in related competencies below, to meet the
expectations of the test:

1. Scientific investigations: Planning and carrying out investigations based on scientific

knowledge and valid evidence.

2. Analyzing and interpreting data: Making decisions based on interpreted data obtained from
diagrams including graphs to construct explanations for real world problems and explore
relationships between variables.

3. The use of mathematics: Applying concepts of probability and computations to examine given
information, explain medical conditions, and find solutions.

4. Patterns: Using scientific theories and mechanisms to analyze and explain observed natural
phenomena based on facts and evidence.

5. Cause and effect: Examining and interpreting scientific data to predict the effect that a change
in one variable could cause on another.

6. Stability and change: Providing evidence-based examples of stability and change taking place
in living organisms and environmental systems.

7. Energy and matter: Constructing an explanation that energy cannot be created or destroyed,
rather it flows within and between different systems.

8. Structure and function: Connecting properties of different materials/objects to the structure

and functions of their components.

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