Genetics and Genomics Descriptions
Errata
Item | Errata | Date |
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1. |
The following unit has been cancelled for 2019: QBIO3001 Molecular Systems Biology |
21/2/2019 |
GENETICS AND GENOMICS
Advanced coursework and projects will be available in 2020 for students who complete this major.
Genetics and Genomics major
A major in Genetics and Genomics requires 48 credit points from this table including:
(i) 6 credit points of 1000-level core units
(ii) 6 credit points of 1000-level selective units
(iii) 6 credit points of 2000-level core units
(iv) 6 credit points of 2000-level selective units
(v) 12 credit points of 3000-level core units
(vi) 6 credit points of 3000-level selective units
(vii) 6 credit points of 3000-level interdisciplinary project units
Genetics and Genomics minor
A minor in Genetics and Genomics requires 36 credit points from this table including:
(i) 6 credit points of 1000-level core units
(ii) 6 credit points of 1000-level selective units
(iii) 6 credit points of 2000-level core units
(iv) 6 credit points of 2000-level selective units
(v) 12 credit points of 3000-level core units
Units of study
The units of study are listed below.
1000-level units of study
Core
BIOL1007 From Molecules to Ecosystems
Credit points: 6 Teacher/Coordinator: Dr Emma Thompson Session: Semester 2 Classes: Two lectures per week and online material and 12 x 3-hour practicals Prohibitions: BIOL1907 or BIOL1997 Assumed knowledge: HSC Biology. Students who have not completed HSC Biology (or equivalent) are strongly advised to take the Biology Bridging Course (offered in February). Assessment: Quizzes (10%), communication assessments (40%), skills tests (10%), summative final exam (40%) Mode of delivery: Normal (lecture/lab/tutorial) day
Paradigm shifts in biology have changed the emphasis from single biomolecule studies to complex systems of biomolecules, cells and their interrelationships in ecosystems of life. Such an integrated understanding of cells, biomolecules and ecosystems is key to innovations in biology. Life relies on organisation, communication, responsiveness and regulation at every level. Understanding biological mechanisms, improving human health and addressing the impact of human activity are the great challenges of the 21st century. This unit will investigate life at levels ranging from cells, and biomolecule ecosystems, through to complex natural and human ecosystems. You will explore the importance of homeostasis in health and the triggers that lead to disease and death. You will learn the methods of cellular, biomolecular, microbial and ecological investigation that allow us to understand life and discover how expanding tools have improved our capacity to manage and intervene in ecosystems for our own health and organisms in the environment that surround and support us . You will participate in inquiry-led practicals that reinforce the concepts in the unit. By doing this unit you will develop knowledge and skills that will enable you to play a role in finding global solutions that will impact our lives.
Textbooks
Please see unit outline on LMS
BIOL1907 From Molecules to Ecosystems (Advanced)
Credit points: 6 Teacher/Coordinator: Dr Claudia Keitel Session: Semester 2 Classes: Two lectures per week and online material and 12 x 3-hour practicals Prohibitions: BIOL1007 or BIOL1997 Assumed knowledge: 85 or above in HSC Biology or equivalent Assessment: Quizzes (10%), communication assessments (40%), skills tests (10%), summative exam (40%) Mode of delivery: Normal (lecture/lab/tutorial) day
Note: Department permission required for enrolment
Paradigm shifts in biology have changed the emphasis from single biomolecule studies to complex systems of biomolecules, cells and their interrelationships in ecosystems of life. Such an integrated understanding of cells, biomolecules and ecosystems is key to innovations in biology. Life relies on organisation, communication, responsiveness and regulation at every level. Understanding biological mechanisms, improving human health and addressing the impact of human activity are the great challenges of the 21st century. This unit will investigate life at levels ranging from cells, and biomolecule ecosystems, through to complex natural and human ecosystems. You will explore the importance of homeostasis in health and the triggers that lead to disease and death. You will learn the methods of cellular, biomolecular, microbial and ecological investigation that allow us to understand life and discover how expanding tools have improved our capacity to manage and intervene in ecosystems for our own health and organisms in the environment that surround and support us . This unit of study has the same overall structure as BIOL1007 but material is discussed in greater detail and at a more advanced level. The content and nature of these components may vary from year to year.
Textbooks
Please see unit outline on LMS
BIOL1997 From Molecules to Ecosystems (SSP)
Credit points: 6 Teacher/Coordinator: Dr Emma Thompson Session: Semester 2 Classes: Two lectures per week and online material Prohibitions: BIOL1007 or BIOL1907 Assumed knowledge: 90 or above in HSC Biology or equivalent Assessment: One 2-hour exam (40%), project report which includes written report and presentation (60%) Practical field work: As advised and required by the project; approximately 30-36 hours of research project in the laboratory or field Mode of delivery: Normal (lecture/lab/tutorial) day
Note: Department permission required for enrolment
Paradigm shifts in biology have changed the emphasis from single biomolecule studies to complex systems of biomolecules, cells and their interrelationships in ecosystems of life. Such an integrated understanding of cells, biomolecules and ecosystems is key to innovations in biology. Life relies on organisation, communication, responsiveness and regulation at every level. Understanding biological mechanisms, improving human health and addressing the impact of human activity are the great challenges of the 21st century. This unit will investigate life at levels ranging from cells, and biomolecule ecosystems, through to complex natural and human ecosystems. You will explore the importance of homeostasis in health and the triggers that lead to disease and death. You will learn the methods of cellular, biomolecular, microbial and ecological investigation that allow us to understand life and intervene in ecosystems to improve health. The same theory will be covered as in the advanced stream but in this Special Studies Unit, the practical component is a research project. The research will be a synthetic biology project investigating genetically engineered organisms. Students will have the opportunity to develop higher level generic skills in computing, communication, critical analysis, problem solving, data analysis and experimental design.
Textbooks
Please see unit outline on LMS
Selective
CHEM1011 Fundamentals of Chemistry 1A
Credit points: 6 Teacher/Coordinator: Dr Toby Hudson Session: Semester 1 Classes: 3x1-hr lectures; 1x1-hr tutorial per week; 1x3-hr practical per week for 9 weeks Prohibitions: CHEM1001 or CHEM1101 or CHEM1901 or CHEM1903 or CHEM1109 or CHEM1111 or CHEM1911 or CHEM1991 Assumed knowledge: There is no assumed knowledge of chemistry for this unit of study but students who have not completed HSC Chemistry (or equivalent) are strongly advised to take the Chemistry Bridging Course (offered in February). Assessment: quizzes, attendance, laboratory log book, exam Mode of delivery: Normal (lecture/lab/tutorial) day
Note: Students who have not completed HSC Chemistry (or equivalent) are strongly advised to take the Chemistry Bridging Course (offered in February, and online year-round, see http://sydney.edu.au/science/chemistry/studying-chemistry/bridging-course.shtml).
Chemistry describes how and why things happen from a molecular perspective. Chemistry underpins all aspects of the natural and physical world, and provides the basis for new technologies and advances in the life, medical and physical sciences, engineering, and industrial processes. This unit of study will equip you with the fundamental knowledge and skills in chemistry for broad application. You will learn about atomic theory, structure and bonding, equilibrium, processes occurring in solutions, and the functional groups of molecules. You will develop experimental design, conduct and analysis skills in chemistry through experiments that ask and answer questions about the chemical nature and processes occurring around you. Through inquiry, observation and measurement, you will better understand natural and physical world and will be able to apply this understanding to real-world problems and solutions. This unit of study is directed toward students whose chemical background is weak (or non-existent). Compared to the mainstream Chemistry 1A, the theory component of this unit begins with more fundamental concepts, and does not cover, or goes into less detail about some topics. Progression to intermediate chemistry from this unit and Fundamentals of Chemistry 1B requires completion of an online supplementary course.
Textbooks
Recommended textbook: Blackman, Bottle, Schmid, Mocerino and Wille,Chemistry, 3rd Edition, 2015 (John Wiley) ISBN: 978-0-7303-1105-8 (paperback) or 978-0-7303-2492-8 (e-text)
CHEM1111 Chemistry 1A
Credit points: 6 Teacher/Coordinator: Dr Toby Hudson Session: Semester 1,Semester 2,Summer Main Classes: 3x1-hr lectures; 1x1-hr tutorial per week; 1x3-hr practical per week for 9 weeks Prohibitions: CHEM1001 or CHEM1101 or CHEM1901 or CHEM1903 or CHEM1109 or CHEM1011 or CHEM1911 or CHEM1991 Assumed knowledge: Students who have not completed HSC Chemistry (or equivalent) and HSC Mathematics (or equivalent) are strongly advised to take the Chemistry and Mathematics Bridging Courses (offered in February) Assessment: quizzes, attendance, laboratory log book, exam Mode of delivery: Normal (lecture/lab/tutorial) day
Note: Students who have not completed secondary school chemistry are strongly advised to instead complete Fundamentals of Chemistry 1A in the first semester of the calendar year (unless you require 12 credit points of Chemistry and are commencing in semester 2). You should also take the Chemistry Bridging Course in advance (offered in February, and online year-round http://sydney.edu.au/science/chemistry/studying-chemistry/bridging-course.shtml).
Chemistry describes how and why things happen from a molecular perspective. Chemistry underpins all aspects of the natural and physical world, and provides the basis for new technologies and advances in the life, medical and physical sciences, engineering, and industrial processes. This unit of study will further develop your knowledge and skills in chemistry for application to life and medical sciences, engineering, and further study in chemistry. You will learn about nuclear and radiation chemistry, wave theory, atomic orbitals, spectroscopy, bonding, enthalpy and entropy, equilibrium, processes occurring in solutions, and the functional groups in carbon chemistry. You will develop experimental design, conduct and analysis skills in chemistry through experiments that ask and answer questions like how do dyes work, how do we desalinate water, how do we measure the acid content in foods, how do we get the blue in a blueprint, and how do we extract natural products from plants? Through inquiry, observation and measurement, you will understand the 'why' and the 'how' of the natural and physical world and will be able to apply this understanding to real-world problems and solutions. This unit of study is directed toward students with a satisfactory prior knowledge of the HSC chemistry course.
Textbooks
Recommended textbook: Blackman, Bottle, Schmid, Mocerino and Wille,Chemistry, 3rd Edition, 2015 (John Wiley) ISBN: 978-0-7303-1105-8 (paperback) or 978-0-7303-2492-8 (e-text)
CHEM1911 Chemistry 1A (Advanced)
Credit points: 6 Teacher/Coordinator: Dr Toby Hudson Session: Semester 1 Classes: 3x1-hr lectures and 1x1-hr tutorial per week; 1x3-hr practical per week for 9 weeks Prohibitions: CHEM1001 or CHEM1101 or CHEM1901 or CHEM1903 or CHEM1109 or CHEM1011 or CHEM1111 or CHEM1991 Assumed knowledge: 80 or above in HSC Chemistry or equivalent Assessment: quizzes, attendance, laboratory log book, exam Mode of delivery: Normal (lecture/lab/tutorial) day
Note: Department permission required for enrolment
Chemistry describes how and why things happen from a molecular perspective. Chemistry underpins all aspects of the natural and physical world, and provides the basis for new technologies and advances in sciences, engineering, and industrial processes. This unit of study will further develop your knowledge and skills in chemistry for broad application, including further study in chemistry. You will learn about nuclear and radiation chemistry, wave theory, atomic orbitals, spectroscopy, bonding, enthalpy and entropy, equilibrium, processes occurring in solutions, and the functional groups of molecules. You will develop experimental design, conduct and analysis skills in chemistry through experiments that ask and answer questions about the chemical nature and processes occurring around you. Through inquiry, observation and measurement, you will better understand natural and physical world and will be able to apply this understanding to real-world problems and solutions. This unit of study is directed toward students with a good secondary performance both overall and in chemistry or science. Students in this category are expected to do this unit rather than Chemistry 1A. Compared to the mainstream Chemistry 1A, the theory component of this unit provides a higher level of academic rigour and makes broader connections between topics.
Textbooks
Recommended textbook: Blackman, Bottle, Schmid, Mocerino and Wille,Chemistry, 3rd Edition, 2015 (John Wiley) ISBN: 978-0-7303-1105-8 (paperback) or 978-0-7303-2492-8 (e-text)
CHEM1991 Chemistry 1A (Special Studies Program)
Credit points: 6 Teacher/Coordinator: Dr Toby Hudson Session: Semester 1 Classes: 3x1-hr lectures; 1x1-hr tutorial per week; 1x3hr practical per week for 12 weeks Prohibitions: CHEM1001 or CHEM1101 or CHEM1901 or CHEM1903 or CHEM1109 or CHEM1011 or CHEM1111 or CHEM1911 Assumed knowledge: 90 or above in HSC Chemistry or equivalent Assessment: quizzes, attendance, presentations, exam Mode of delivery: Normal (lecture/lab/tutorial) day
Note: Department permission required for enrolment
Chemistry describes how and why things happen from a molecular perspective. Chemistry underpins all aspects of the natural and physical world, and provides the basis for new technologies and advances in the life, medical and physical sciences, engineering, and industrial processes. This unit of study will further develop your knowledge and skills in chemistry for application to life and medical sciences, engineering, and further study in chemistry. You will learn about nuclear and radiation chemistry, wave theory, atomic orbitals, spectroscopy, bonding, enthalpy and entropy, equilibrium, processes occurring in solutions, and the functional groups in carbon chemistry. You will develop experimental design, conduct and analysis skills in chemistry in small group projects. The laboratory program is designed to extend students who already have chemistry laboratory experience, and particularly caters for students who already show a passion and enthusiasm for research chemistry, as well as aptitude as demonstrated by high school chemistry results. Entry to Chemistry 1A (Special Studies Program) is restricted to a small number of students with an excellent school record in Chemistry, and applications must be made to the School of Chemistry. The practical work syllabus for Chemistry 1A (Special Studies Program) is very different from that for Chemistry 1A and Chemistry 1A (Advanced) and consists of special project-based laboratory exercises. All other unit of study details are the same as those for Chemistry 1A (Advanced).
Textbooks
Recommended textbook: Blackman, Bottle, Schmid, Mocerino and Wille,Chemistry, 3rd Edition, 2015 (John Wiley) ISBN: 978-0-7303-1105-8 (paperback) or 978-0-7303-2492-8 (e-text)
BIOL1006 Life and Evolution
Credit points: 6 Teacher/Coordinator: Dr Matthew Pye, A/Prof Charlotte Taylor Session: Semester 1 Classes: Two lectures per week; 11 x 3-hour lab classes; a field excursion Prohibitions: BIOL1001 or BIOL1911 or BIOL1991 or BIOL1906 or BIOL1996 Assumed knowledge: HSC Biology. Students who have not completed HSC Biology (or equivalent) are strongly advised to take the Biology Bridging Course (offered in February). Assessment: Writing task (10%), laboratory report (20%), laboratory notebook (10%), during semester tests and quizzes (20%), summative final exam (40%) Practical field work: 11 x 3-hour lab classes, a field excursion Mode of delivery: Normal (lecture/lab/tutorial) day
Biology is an immensely diverse science. Biologists study life at all levels, from the fundamental building blocks (genes, proteins) to whole ecosystems in which myriads of species interact. Evolution is the unifying concept that runs through the life sciences, from the origin and diversification of life to understanding behaviour, to dealing with disease. Evolution through natural selection is the framework in biology in which specific details make sense. This unit explores how new species continue to arise while others go extinct and discusses the role of mutations as the raw material on which selection acts. It explains how information is transferred between generations through DNA, RNA and proteins, transformations which affect all aspects of biological form and function. Science builds and organises knowledge of life and evolution in the form of testable hypotheses. You will participate in inquiry-led practical classes investigating single-celled organisms and the diversity of form and function in plants and animals. By doing this unit of study, you will develop the ability to examine novel biological systems and understand the complex processes that have shaped those systems.
Textbooks
Knox, B., Ladiges, P.Y., Evans, B.K., Saint, R. (2014) Biology: an Australian focus, 5e, McGraw-Hill education, North Ryde, N.S.W
BIOL1906 Life and Evolution (Advanced)
Credit points: 6 Teacher/Coordinator: Dr Matthew Pye, A/Prof Charlotte Taylor Session: Semester 1 Classes: Two lectures per week; 11 x 3-hour lab classes; a field excursion Prohibitions: BIOL1001 or BIOL1911 or BIOL1991 or BIOL1006 or BIOL1996 Assumed knowledge: 85 or above in HSC Biology or equivalent. Assessment: Writing task (10%), project report (20%), laboratory notebook (10%), during semester tests and quizzes (20%), summative final exam (40%) Practical field work: 11 x 3-hour lab classes, a field excursion Mode of delivery: Normal (lecture/lab/tutorial) day
Note: Department permission required for enrolment
Biology is an immensely diverse science. Biologists study life at all levels, from the fundamental building blocks (genes, proteins) to whole ecosystems in which myriads of species interact. Evolution is the unifying concept that runs through the life sciences, from the origin and diversification of life to understanding behaviour, to dealing with disease. Evolution through natural selection is the framework in biology in which specific details make sense. This unit explores how new species continue to arise while others go extinct and discusses the role of mutations as the raw material on which selection acts. It explains how information is transferred between generations through DNA, RNA and proteins, transformations which affect all aspects of biological form and function. Science builds and organises knowledge of life and evolution in the form of testable hypotheses. You will participate in inquiry-led practical classes investigating single-celled organisms and the diversity of form and function in plants and animals.
Life and Evolution (Advanced) has the same overall structure as BIOL1006 but material is discussed in greater detail and at a more advanced level. Students enrolled in BIOL1906 participate in a research project with a focus on developing skills in critical evaluation, experimental design, data analysis and communication.
Life and Evolution (Advanced) has the same overall structure as BIOL1006 but material is discussed in greater detail and at a more advanced level. Students enrolled in BIOL1906 participate in a research project with a focus on developing skills in critical evaluation, experimental design, data analysis and communication.
Textbooks
Knox, B., Ladiges, P.Y., Evans, B.K., Saint, R. (2014) Biology: an Australian focus, 5e, McGraw-Hill education, North Ryde, N.S.W
BIOL1996 Life and Evolution (SSP)
Credit points: 6 Teacher/Coordinator: Dr Mark de Bruyn Session: Semester 1 Classes: Lectures as per BIOL1906; one 3-hour practical per week Prohibitions: BIOL1001 or BIOL1911 or BIOL1991 or BIOL1006 or BIOL1906 or BIOL1993 or BIOL1998 Assumed knowledge: 90 or above in HSC Biology or equivalent Assessment: One 2-hour exam (50%), practical reports (25%), seminar presentation (15%), lab note book (5%), prelaboratory quizzes (5%) Practical field work: null Mode of delivery: Normal (lecture/lab/tutorial) day
Note: Department permission required for enrolment
Biology is an immensely diverse science. Biologists study life at all levels, from the fundamental building blocks (genes, and proteins) to whole ecosystems in which myriad species interact. Evolution is the unifying concept that runs through the life sciences, from the origin and diversification of life to understanding behaviour, to dealing with disease. Evolution through natural selection is the framework in biology in which specific details make sense. Science builds and organises knowledge of life and evolution in the form of testable hypotheses. The practical work syllabus for BIOL1996 is different from that of BIOL1906 (Advanced) and consists of a special project-based laboratory.
Textbooks
Please see unit outline on LMS
BIOL1008 Human Biology
Credit points: 6 Teacher/Coordinator: Dr Osu Lilje Session: Semester 1 Classes: 2-3hr Lectures per week; six 3-hour practical sessions; six workshops/tutorials; students encouraged to spend 1-2 hours per week accessing online resources Prohibitions: BIOL1003 or BIOL1903 or BIOL1993 or MEDS1001 or MEDS1901 or BIOL1908 or BIOL1998 Assumed knowledge: HSC Biology. Students who have not completed HSC Biology (or equivalent) are strongly advised to take the Biology Bridging Course (offered in February). Assessment: Written and oral presentation, quiz, skills-based assessment, final exam Mode of delivery: Normal (lecture/lab/tutorial) day
What will it mean to be human in 2100? How will we be able to control our complex bodily mechanisms to maintain health and fight disease? Advances in the human biology suggest we will age more slowly and new technologies will enhance many bodily structures and functions. This unit of study will explore maintenance of health through nutritional balance, aerobic health, defence mechanisms and human diversity. You will learn key structural features from the subcellular level to the whole organ and body, and learn about essential functional pathways that determine how the body regulates its internal environment and responds to external stimuli and disease. Together we will investigate nutrition, digestion and absorption, cardiovascular and lung function, reproduction, development, epigenetics, and regulation of function through various interventions. You will receive lectures from experts in the field of human biology and medical sciences, supported by practical classes, workshops and on-line resources that leverage off state-of-the-art technologies to develop your practical, critical thinking, communication, collaboration, digital literacy, problem solving, and enquiry-based skills in human biology. This unit of study will provide you with the breadth and depth of knowledge and skills for further studies in majors in medical sciences.
Textbooks
Van Putte, C., Regan, J. and Russo, A. (*) Essentials of Anatomy and Physiology, McGraw Hill.
BIOL1908 Human Biology (Advanced)
Credit points: 6 Teacher/Coordinator: Dr Osu Lilje Session: Semester 1 Classes: 2-3hr Lectures per week; six 3-hour practical sessions; six workshops/tutorials; students encouraged to spend 1-2 hours per week accessing online resources Prohibitions: BIOL1003 or BIOL1903 or BIOL1993 or MEDS1001 or MEDS1901 or BIOL1008 or BIOL1998 Assumed knowledge: 85 or above in HSC Biology or equivalent Assessment: Written and oral presentation, quiz, skills-based assessment, final exam Mode of delivery: Normal (lecture/lab/tutorial) day
Note: Department permission required for enrolment
What will it mean to be human in 2100? How will we be able to control our complex bodily mechanisms to maintain health and fight disease? Advances in the human biology suggest we will age more slowly and new technologies will enhance many bodily structures and functions. This unit of study will explore maintenance of health through nutritional balance, aerobic health, defence mechanisms and human diversity. You will learn key structural features from the subcellular level to the whole organ and body, and learn about essential functional pathways that determine how the body regulates its internal environment and responds to external stimuli and disease. Together we will investigate nutrition, digestion and absorption, cardiovascular and lung function, reproduction, development, epigenetics, and regulation of function through various interventions. You will receive lectures from experts in the field of human biology and medical sciences, supported by practical classes, workshops and on-line resources that leverage off state-of-the-art technologies to develop your practical, critical thinking, communication, collaboration, digital literacy, problem solving, and enquiry-based skills in human biology. This unit of study will provide you with the breadth and depth of knowledge and skills for further studies in majors in medical sciences. The advanced unit has the same overall concepts as the mainstream unit but material is discussed in a manner that offers a greater level of challenge and academic rigour. Students enrolled in the advanced stream will participate in alternative components which may for example include guest lecturers from medical science industries. The nature of these components may vary from year to year.
Textbooks
Van Putte, C., Regan, J. and Russo, A. (*) Essentials of Anatomy and Physiology, McGraw Hill.
BIOL1998 Human Biology (Special Studies Program)
Credit points: 6 Teacher/Coordinator: Dr Rosalyn Gloag Session: Semester 1 Classes: Lectures as per BIOL1908; one 3-hour practical per week Prohibitions: BIOL1003 or BIOL1903 or BIOL1993 or BIOL1991 or BIOL1996 or MEDS1001 or MEDS1901 or BIOL1008 or BIOL1908 Assumed knowledge: 90 or above in HSC Biology or equivalent Assessment: One 2-hour exam (50%), practical report (25%), practical presentation (15%), lab note book (5%), pre laboratory quizzes (5%) Mode of delivery: Normal (lecture/lab/tutorial) day
Note: Department permission required for enrolment
What will it mean to be human in 2100? How will we be able to control our complex bodily mechanisms to maintain health and fight disease? Advances in human biology suggest we will age more slowly and new technologies will enhance many bodily structures and functions. This unit of study will explore maintenance of health through nutritional balance, aerobic health, defence mechanisms and human diversity. You will learn key structural features from the subcellular level to the whole organ and body, and learn about essential functional pathways that determine how the body regulates its internal environment and responds to external stimuli and disease. Together we will investigate nutrition, digestion and absorption, cardiovascular and lung function, reproduction, development, epigenetics, and regulation of function through various interventions. You will receive lectures from experts in the field of human biology and medical sciences, supported by practical classes, workshops and on-line resources that leverage off state-of-the-art technologies to develop your practical, critical thinking, communication, collaboration, digital literacy, problem solving, and enquiry-based skills in human biology. This unit of study will provide you with the breadth and depth of knowledge and skills for further studies in majors in medical sciences. The practical work syllabus consists of a special project-based laboratory.
Textbooks
Van Putte, C., Regan, J. and Russo, A. (*) Essentials of Anatomy and Physiology, McGraw Hill.
MEDS1001 Human Biology
Credit points: 6 Teacher/Coordinator: Prof Philip Poronnik Session: Semester 1 Classes: this unit of study will involve between 5-6 hours of face-to-face activities run on the camperdown campus, these contact hours will comprise lectures; six 3-hour practical sessions; six workshops and tutorials Prohibitions: BIOL1003 or BIOL1903 or BIOL1993 or BIOL1008 or BIOL1908 or BIOL1998 or MEDS1901 Assessment: Written and oral communication, quiz, practical and workshop reports, final exam Mode of delivery: Normal (lecture/lab/tutorial) day
What will it mean to be human in 2100? How will we be able to control our complex bodily mechanisms to maintain health and fight disease? Advances in the medical sciences suggest we will age more slowly and new technologies will enhance many bodily structures and functions. This unit of study will explore maintenance of health through nutritional balance, aerobic health, defence mechanisms and human diversity. You will learn key structural features from the subcellular level to the whole organ and body, and learn about essential functional pathways that determine how the body regulates its internal environment and responds to external stimuli and disease. Together we will investigate nutrition, digestion and absorption, cardiovascular and lung function, reproduction, development, epigenetics, and regulation of function through various interventions. You will receive lectures from experts in the field of human biology and medical sciences, supported by practical classes, workshops and on-line resources that leverage off state-of-the-art technologies to develop your practical, critical thinking, communication, collaboration, digital literacy, problem solving, and enquiry-based skills in human biology and medical sciences. This unit of study will provide you with the breadth and depth of knowledge and skills for further studies in the medical sciences.
Textbooks
TBA
MEDS1901 Human Biology (Advanced)
Credit points: 6 Teacher/Coordinator: Prof Philip Poronnik Session: Semester 1 Classes: this unit of study will involve between 5-6 hours of face-to-face activities run on the camperdown campus Prerequisites: 85 or above in HSC Biology or equivalent Prohibitions: BIOL1003 or BIOL1903 or BIOL1993 or BIOL1008 or BIOL1908 or BIOL1998 or MEDS1001 Assessment: Written and oral presentation, quiz, assignment, final exam Mode of delivery: Normal (lecture/lab/tutorial) day
Note: Department permission required for enrolment
What will it mean to be human in 2100? How will we be able to control our complex bodily mechanisms to maintain health and fight disease? Advances in the human biology suggest we will age more slowly and new technologies will enhance many bodily structures and functions. This unit of study will explore maintenance of health through nutritional balance, aerobic health, defence mechanisms and human diversity. You will learn key structural features from the subcellular level to the whole organ and body, and learn about essential functional pathways that determine how the body regulates its internal environment and responds to external stimuli and disease. Together we will investigate nutrition, digestion and absorption, cardiovascular and lung function, reproduction, development, epigenetics, and regulation of function through various interventions. You will receive lectures from experts in the field of human biology and medical sciences, supported by practical classes, workshops and on-line resources that leverage off state-of-the-art technologies to develop your practical, critical thinking, communication, collaboration, digital literacy, problem solving, and enquiry-based skills in human biology. This unit of study will provide you with the breadth and depth of knowledge and skills for further studies in majors in medical sciences. The advanced unit has the same overall concepts as the mainstream unit but material is discussed in a manner that offers a greater level of challenge and academic rigour. Students enrolled in the advanced stream will participate in alternative components which may for example include guest lecturers from medical science industries. The nature of these components may vary from year to year.
Textbooks
TBA
MEDS coded units of study are only available to students in the Medical Science stream.
2000-level units of study
Core
GEGE2001 Genetics and Genomics
Credit points: 6 Teacher/Coordinator: Dr Jenny Saleeba Session: Semester 1,Semester 2 Classes: Two lectures; one 3-hour practical session; and one peer assisted study session on a weekly basis Prohibitions: GENE2002 or MBLG2972 or GEGE2901 or MBLG2072 Assumed knowledge: Mendellian genetics, mechanisms of evolution, molecular and chromosomal bases of inheritance, and gene regulation and expression. Assessment: Assignments, quizzes and presentation (50%), final exam (50%) Mode of delivery: Normal (lecture/lab/tutorial) day
The era of genomics has revolutionised our approach to biology. Recent breakthroughs in genetics and genomic technologies have led to improvements in human and animal health, in breeding and selection of economically important organisms and in the curation and care of wild species and complex ecosystems. In this unit, students will investigate/describe ways in which modern biology uses genetics and genomics to study life, from the unicellular through to complex multicellular organisms and their interactions in communities and ecosystems. This unit includes a solid foundation in classical Mendelian genetics and its extensions into quantitative and population genetics. It also examines how our ability to sequence whole genomes has changed our capacities and our understanding of biology. Links between DNA, phenotype and the performance of organisms and ecosystems will be highlighted. The unit will examine the profound insights that modern molecular techniques have enabled in the fields of developmental biology, gene regulation, population genetics and molecular evolution.
GEGE2901 Genetics and Genomics (Advanced)
Credit points: 6 Teacher/Coordinator: Prof Peter Sharp Session: Semester 1,Semester 2 Classes: Two lectures; one 3-hour practical session; and one peer assisted study session on a weekly basis Prerequisites: Annual average mark of at least 70 Prohibitions: GENE2002 or MBLG2072 or GEGE2001 or MBLG2972 Assumed knowledge: Mendellian genetics, mechanisms of evolution, molecular and chromosomal bases of inheritance, and gene regulation and expression. Assessment: Assignments, quizzes, presentation, final exam Mode of delivery: Normal (lecture/lab/tutorial) day
The era of genomics has revolutionised our approach to biology. Recent breakthroughs in genetics and genomic technologies have led to improvements in human and animal health, in breeding and selection of economically important organisms and in the curation and care of wild species and complex ecosystems. In this unit, students will investigate/describe ways in which modern biology uses genetics and genomics to study life, from the unicellular through to complex multicellular organisms and their interactions in communities and ecosystems. This unit includes a solid foundation in classical Mendelian genetics and its extensions into quantitative and population genetics. It also examines how our ability to sequence whole genomes has changed our capacities and our understanding of biology. Links between DNA, phenotype and the performance of organisms and ecosystems will be highlighted. The unit will examine the profound insights that modern molecular techniques have enabled in the fields of developmental biology, gene regulation, population genetics and molecular evolution. The Advanced mode of Genetics and Genomics will provide you with challenge and a higher level of academic rigour. You will have the opportunity to plan and carry out a project that will develop your skills in contemporary genetics/molecular biology techniques and will provide you with a greater depth of disciplinary understanding. The Advanced mode will culminate in a written report and in an oral presentation where you will discuss a recent breakthrough that has been enabled by the use of modern genetics and genomics technologies. This is a unit for anyone wanting to better understand the how genetics has shaped the earth and how it will shape the future.
Textbooks
TBA
Selective
AVBS2005 Animal Energetics and Homeostasis
Credit points: 6 Teacher/Coordinator: Associate Professor Paul Sheehy Session: Semester 1 Classes: on average there are 4 hrs/ week of lectures and intermittent practical and tutorials of 1-2 hrs per week Prohibitions: VETS1032 Assumed knowledge: Knowledge and concepts from BIOL1XX7 Assessment: intra-semester: 1x exam (25%); end of semester: 1x2-hr written exam (55%); other: 1x cytology group learning exercise (20%) Mode of delivery: Normal (lecture/lab/tutorial) day
Effective metabolic function is critical for animal health and wellbeing. Key concepts include the comparative differences between animals and humans (eg ruminant metabolism), common disruptions in metabolism and endocrine regulation in companion animals, as well as the impact of metabolic dysfunction in animal production systems (eg bovine ketosis and ovine pregnancy toxaemia). This unit of study begins with an introduction to the metabolic processes of cells, tissues and whole animals by examining the structure ie the cytological and histological characteristics, of animal tissues in the physical context of whole animals. An integrated view is explored of the role of hormones in homeostatic control as dynamic metabolic regulators in wellbeing and the consequences of dysregulation. Students will apply knowledge of animal nutrition and animal structure and function to determine the underlying basis of metabolic disease and disorders and, how to alleviate or mitigate the dysfunction. This will be done by utilising an understanding of adaptive metabolism in animals to interpret biochemical data and identify disruptions to metabolism and homeostatic mechanisms. Clinical veterinary medicine examples of disruption to metabolism are used to emphasise normal metabolic processes. Students will develop key skills in microscopy, cytology and histology for broad application in the sciences.
Textbooks
Recommended text: Alberts et al., (2014) Essential Cell Biology 4th Edition. Garland Publishing, New York. Sjaastad, O.V, Hove, K and Sand, O. (2003) Physiology of Domestic Animals. Scandanavian Veterinary Press. Other useful textbooks include: Alberts et al., Essential Cell Biology. Garland Publishing, New York. Various Editions Stryer, L. Biochemistry, W.H. Freeman , New York. Various Editions Lehninger, A.L. Principles of Biochemistry, Worth Publishing, New York, Various Editions Campbell, M.K., Biochemistry, Harcourt Brace, Philadelphia, Various Editions Cunningham, J.G. (2002) Textbook of Veterinary Physiology. 3rd ed, Saunders, Philadelphia.
BCMB2001 Biochemistry and Molecular Biology
Credit points: 6 Teacher/Coordinator: Dr Dale Hancock Session: Semester 1 Classes: Three lectures per week; one 4-hour practical and one 1-hour tutorial session per fortnight Prerequisites: 6cp of (BIOL1XX7 or MBLG1XXX) and 6cp of (CHEM1XX1 or CHEM1903) Prohibitions: BCHM2072 or BCHM2972 or MBLG2071 or MBLG2971 or BMED2405 or BCMB2901 or MEDS2003 Assessment: Assignments, skills-based assessment, quizzes, exam Mode of delivery: Normal (lecture/lab/tutorial) day
Without cells, life as we know it would not exist. These dynamic assemblies, packed with biological molecules are constantly in action. But how do cells work? Why is the food that you eat so important for cellular function? How is information transmitted from generation to generation? And, what happens as a result of disease or genetic mutation? In this unit of study you will learn how cells work at the molecular level, with an emphasis on human biochemistry and molecular biology. We will focus initially on cellular metabolism and how cells extract and store energy from fuels like fats and carbohydrates, how the use of fuels is modulated in response to exercise, starvation and disease, and how other key metabolites are processed. Then we will explore how genetic information is regulated in eukaryotes, including replication, transcription and translation, and molecular aspects of the cell cycle, mitosis and meiosis. Our practicals, along with other guided and online learning sessions will introduce you to widely applied and cutting edge tools that are essential for modern biochemistry and molecular biology. By the end of this unit you will be equipped with foundational skills and knowledge to support your studies in the life and medical sciences.
Textbooks
Stryer Biochemistry 8th Edition ISBN-13:978-1-4641-2610-9
BCMB2901 Biochemistry and Molecular Biology (Advanced)
Credit points: 6 Teacher/Coordinator: Dr Dale Hancock Session: Semester 1 Classes: Three lectures per week; one 4-hour practical and one 1-hour tutorial session per fortnight Prerequisites: A mark of at least 70 from (BIOL1XX7 or MBLG1XX1) and (CHEM1XX1 or CHEM1903) Prohibitions: BCHM2072 or BCHM2972 or MBLG2071 or MBLG2971 or BMED2405 or BCMB2001 or MEDS2003 Assessment: Assignments, quiz, skills-based assessment, exam Mode of delivery: Normal (lecture/lab/tutorial) day
Without cells, life as we know it would not exist. These dynamic assemblies, packed with biological molecules are constantly in action. But how do cells work? Why is the food that you eat so important for cellular function? How is information transmitted from generation to generation? And, what happens as a result of disease or genetic mutation? In this unit of study you will learn how cells work at the molecular level, with an emphasis on human biochemistry and molecular biology. We will focus initially on cellular metabolism and how cells extract and store energy from fuels like fats and carbohydrates, how the use of fuels is modulated in response to exercise, starvation and disease, and how other key metabolites are processed. Then we will explore how genetic information is regulated in eukaryotes, including replication, transcription and translation, and molecular aspects of the cell cycle, mitosis and meiosis. The advanced laboratory component will provide students with an authentic research laboratory experience while in the theory component, current research topics will be presented in a problem-based format through dedicated advanced tutorial sessions. This material will be assessed by creative student-centered activities supported by eLearning platforms.
Textbooks
Stryer Biochemistry 8th Edition ISBN-13:978-1-4641-2610-9
MEDS2003 Biochemistry and Molecular Biology
Credit points: 6 Teacher/Coordinator: Dr Dale Hancock Session: Semester 1 Classes: Three lectures per week; one 4-hour practical session and 1 h tutorial per fortnight Prerequisites: 6p from (BIOL1XX7 or MBLG1XX1) and 6cp of (CHEM1XX1 or CHEM1903) Prohibitions: BCHM2072 or BCHM2972 or MBLG2071 or MBLG2971 or BMED2405 or BCMB2001 or BCMB2901 or BMED2804 Assessment: Group presentation (5%), In-class continuous assessment (25%), PeerWise MCQ design (10%), ELMA design essay and interpretation (10%), final exam (50%) Mode of delivery: Normal (lecture/lab/tutorial) day
Without cells, life as we know it would not exist. These dynamic assemblies, packed with biological molecules are constantly in action. But how do cells work? Why is the food that you eat so important for cellular function? How is information transmitted from generation to generation? What happens as a result of disease or genetic mutation? In this unit of study you will learn how cells work at the molecular level, with an emphasis on human biochemistry and molecular biology. We will focus initially on cellular metabolism and how cells extract and store energy from fuels like fats and carbohydrates, how fuel use is modulated in response to exercise, starvation and disease, and how other key metabolites are processed. Then we will explore how genetic information is regulated in eukaryotes, including replication, transcription and translation, and molecular aspects of the cell cycle, mitosis and meiosis. Our practicals, along with other guided and online learning sessions will introduce you to widely applied and cutting-edge tools that are essential for modern biochemistry and molecular biology. By the end of this unit you will be equipped with foundational skills and knowledge to support your studies in the medical and life sciences.
Textbooks
Canvas, ELN Peerwise Site, Blackboard LMS Textbook: Biochemistry - Berg, Tymoczko, Gatto, Stryer 8th Ed or higher Wikipedia
QBIO2001 Molecular Systems Biology
Credit points: 6 Teacher/Coordinator: Dr Edward Hancock Session: Semester 1 Classes: Two 1-hour lectures; one 3-hour practical session on a weekly basis Assumed knowledge: Basic concepts in metabolism; protein synthesis; gene regulation; quantitative and statistical skills Assessment: One 3-hour final exam (50%), three 45-minute quizzes (20%), one 5-minute presentation (10%), laboratory assessment and practical book (20%) Mode of delivery: Normal (lecture/lab/tutorial) day
Experimental approaches to the study of biological systems are shifting from hypothesis driven to hypothesis generating research. Large scale experiments at the molecular scale are producing enormous quantities of data ("Big Data") that need to be analysed to derive significant biological meaning. For example, monitoring the abundance of tens of thousands of proteins simultaneously promises ground-breaking discoveries. In this unit, you will develop specific analytical skills required to work with data obtained in the biological and medical sciences. The unit covers quantitative analysis of biological systems at the molecular scale including modelling and visualizing patterns using differential equations, experimental design and data types to understand disease aetiology. You will also use methods to model cellular systems including metabolism, gene regulation and signalling. The practical program will enable you to generate data analysis workflows, and gain a deep understanding of the statistical, informatics and modelling tools currently being used in the field. To leverage multiple types of expertise, the computer lab-based practical component of this unit will be predominantly a team-based collaborative learning environment. Upon completion of this unit, you will have gained skills to find meaningful solutions to difficult biological and disease-related problems with the potential to change our lives.
Textbooks
An Introduction to Systems Biology: Design Principles of Biological Circuits, Uri Alon, (Chapman and Hall/CRC, 2007). Systems Biology, Edda Klipp, Wolfram Liebermeister, Christoph Wierling, Axel Kowald, Hans Lehrach, and Ralf Herwig, (Wiley-Blackhall, 2009). Molecular biology of the cell, Alberts B et al (6th edition, Garland Science, 2015) Discovering Statistics Using R, Andy Field (2012, SAGE Publications Ltd). Computational and Statistical Methods for Protein Quantitation by Mass Spectrometry, Martens L et al (Wiley, 2013)
(MEDS coded units of study are only available to students in the Medical Science stream).
3000-level units of study
Core
BIOL3018 Gene Technology and Genomics
Credit points: 6 Teacher/Coordinator: A/Prof Mary Byrne Session: Semester 1 Classes: Two 1-hour lectures and one 3-hour practical per week. Prerequisites: (MBLG2X72 or GEGE2X01 or GENE2002) and 6cp from (MBLG2X71 or BCMB2XXX or QBIO2001 or IMMU2XXX or BIOL2XXX) Prohibitions: BIOL3918 Assessment: One 2-hour exam (60%), assignments (40%). Mode of delivery: Normal (lecture/lab/tutorial) day
A unit of study with lectures, practicals and tutorials on the application of recombinant DNA technology and the genetic manipulation of prokaryotic and eukaryotic organisms. Lectures cover the applications of molecular genetics in biotechnology and consider the regulation, impact and implications of genetic engineering and genomics. Topics include biological sequence data and databases, comparative genomics, the cloning and expression of foreign genes in bacteria, yeast, animal and plant cells, novel human and animal therapeutics and vaccines, new diagnostic techniques for human and veterinary disease, and the genetic engineering of animals and plants. Practical work may include nucleic acid isolation and manipulation, gene cloning and PCR amplification, DNA sequencing and bioinformatics, immunological detection of proteins, and the genetic transformation and assay of plants.
BIOL3918 Gene Technology and Genomics (Adv)
Credit points: 6 Teacher/Coordinator: A/Prof Mary Byrne Session: Semester 1 Classes: Two 1-hour lectures and one 3-hour practical per week. Prerequisites: An average mark of 75 or above in [(MBLG2X72 or GEGE2X01 or GENE2002) and (MBLG2X71 or BCMB2XXX or QBIO2001 or IMMU2XXX or BIOL2XXX)] Prohibitions: BIOL3018 Assessment: One 2-hour exam (60%), assignments (40%). Mode of delivery: Normal (lecture/lab/tutorial) day
Qualified students will participate in alternative components of BIOL3018 Gene Technology and Genomics. The content and nature of these components may vary from year to year.
GEGE3004 Computational Genomics
Credit points: 6 Teacher/Coordinator: Prof Claire Wade Session: Semester 2 Classes: Lectures 2 hours per week, Practical 3hours per week during standard semester. Prerequisites: 6cp of (GEGE2X01 or QBIO2XXX or DATA2X01 or GENE2XXX or MBLG2X72 or ENVX2001 or DATA2X02) Prohibitions: ANSC3107 Assumed knowledge: Genetics at 2000 level, Biology at 1000 level, algebra Assessment: The assessment will consist of one intra-semester examination (20%), group work assignment (30%)[ including assessment both of a project report (20%) and the team process (10%)], individual assignment (10%) and final examination (40%). Mode of delivery: Normal (lecture/lab/tutorial) evening
Note: This unit must be taken by all students in the Genetics and Genomics major.
The average mammalian genome is 3 billion nucleotides long and some other organisms have genomes that are even larger. Working with DNA at the nucleotide level on an organismal scale is impossible without the assistance of high performance computing. This unit will investigate strategies to manipulate genomic data on a whole organism scale. You will learn how scientists use high performance computing and web-based resources to compare and assemble genomes, map genes that cause specific phenotypes, and uncover mutations that cause phenotypic changes in organisms that influence health, external characteristics, production and disease. By doing this unit you will develop skills in the analysis of big data, you will gain familiarity with high performance computing worktop environments and learn to use bioinformatics tools that are commonly applied in research.
Major Selective
BCHM3092 Proteomics and Functional Genomics
Credit points: 6 Teacher/Coordinator: Prof Stuart Cordwell Session: Semester 2 Classes: Two 1-hour lectures per week and one 3-hour practical per week. Prerequisites: [12cp from (BCHM2X71 or BCHM2X72 or BCMB2X01 or BCMB2X02 or DATA2002 or ENVX2001 or BIOL2X22 or GEGE2X01 or MBLG2X71 or QBIO2001)] OR [BMED2401 and BMED2405 and 6cp from (BCHM2X71 or BCMB2X02 or MBLG2X71)] Prohibitions: BCHM3992 Assessment: One 2.5-hour exam (theory and theory of prac 70%), in-semester (practical work and assignments 30%) Mode of delivery: Normal (lecture/lab/tutorial) day
Note: BMedSc degree students: You must have successfully completed BMED2401 and an additional 12cp from BMED240X before enrolling in this unit.
This unit of study will focus on the high throughput methods for the analysis of gene structure and function (genomics) and the analysis of proteins (proteomics), which are at the forefront of discovery in the biomedical sciences. The course will concentrate on the hierarchy of gene-protein-structure-function through an examination of modern technologies built on the concepts of genomics versus molecular biology, and proteomics versus biochemistry. Technologies to be examined include DNA sequencing, nucleic acid and protein microarrays, two-dimensional gel electrophoresis of proteins, uses of mass spectrometry for high throughput protein identification, isotope tagging for quantitative proteomics, high-performance liquid chromatography, high-throughput functional assays, affinity chromatography and modern methods for database analysis. Particular emphasis will be placed on how these technologies can provide insight into the molecular basis of changes in cellular function under both physiological and pathological conditions as well as how they can be applied to biotechnology for the discovery of biomarkers, diagnostics, and therapeutics. The practical component is designed to complement the lecture course and will provide students with experience in a wide range of techniques used in proteomics and genomics.
BCHM3992 Proteomics and Functional Genomics (Adv)
Credit points: 6 Teacher/Coordinator: Prof Stuart Cordwell Session: Semester 2 Classes: Two 1-hour lectures per week and one 3-hour practical per week. Prerequisites: [An average mark of 75 or above in 12cp from (BCHM2X71 or BCHM2X72 or BCMB2X01 or BCMB2X02 or DATA2002 or ENVX2001 or BIOL2X22 or GEGE2X01 or MBLG2X71 or QBIO2001)] OR [BMED2401 and a mark of 75 or above in BMED2405 and a mark of 75 or above in 6cp from (BCHM2X71 or BCMB2X02 or MBLG2X71)] Prohibitions: BCHM3092 Assessment: One 2.5-hour exam (theory and theory of prac 70%), in-semester (practical work and assignments 30%) Mode of delivery: Normal (lecture/lab/tutorial) day
Note: BMedSc degree students: You must have successfully completed BMED2401 and an additional 12cp from BMED240X before enrolling in this unit.
This unit of study will focus on the high throughput methods for the analysis of gene structure and function (genomics) and the analysis of proteins (proteomics) which are at the forefront of discovery in the biomedical sciences. The course will concentrate on the hierarchy of gene-protein-structure-function through an examination of modern technologies built on the concepts of genomics versus molecular biology, and proteomics versus biochemistry. Technologies to be examined include DNA sequencing, nucleic acid and protein microarrays, two-dimensional gel electrophoresis of proteins, uses of mass spectrometry for high throughput protein identification, isotope tagging for quantitative proteomics, high-performance liquid chromatography, high-throughput functional assays, affinity chromatography and modern methods for database analysis. Particular emphasis will be placed on how these technologies can provide insight into the molecular basis of changes in cellular function under both physiological and pathological conditions as well as how they can be applied to biotechnology for the discovery of biomarkers, diagnostics, and therapeutics. The practical component is designed to complement the lecture course and will provide students with experience in a wide range of techniques used in proteomics and genomics.
The lecture component of this unit of study is the same as BCHM3092. Qualified students will attend seminars/practical classes in which more sophisticated topics in proteomics and genomics will be covered.
The lecture component of this unit of study is the same as BCHM3092. Qualified students will attend seminars/practical classes in which more sophisticated topics in proteomics and genomics will be covered.
QBIO3001 Molecular Systems Biology
Credit points: 6 Teacher/Coordinator: Dr Edward Hancock Session: Semester 1 Classes: 2x1hr lectures, 1x3 hr lab Prerequisites: Completion of 72cp of units of study, including QBIO2001 and 6cp from (GEGE2X01 or GENE2002 or AVBS2005 or BCMB2X01 or BCHM2X72 or MEDS2003) Assessment: Quiz in Tutorial/Lab x 2 (10%+5%) = 15%, Workshop on Module 1 = 25%, Presentation = 15%, Final Exam = 45% Mode of delivery: Normal (lecture/lab/tutorial) day
Systems biology is the study of complex biological systems whose behaviour involves more than the sum of their isolated biological parts. Modern approaches to systems biology use a broad system-level analysis incorporating multiple levels of data integration and mechanistic modelling. This unit is designed for students to gain a deep understanding of data integration from large-scale Omics experimentation as well as mechanistic modelling with differential equations. The unit provides a comprehensive knowledge of large-scale Omics-based biological systems analysis, including advanced statistical methods for systems biology, Omics data visualisation, experimental methods in Omics research, data integration, and network-based analysis. In addition, the unit covers diverse aspects of mechanistic modelling of biochemical pathways with differential equations, including analysis of models of gene regulatory networks, signalling networks and metabolic regulation. In the practical program you will generate data analysis workflows and thereby gain a deep understanding of the statistical, informatics and modelling tools currently being used in the field. To leverage multiple types of expertise, the computer lab-based practical component of this unit will be a predominantly team-based collaborative learning environment.
BIOL3005 Evolutionary Biology
Credit points: 6 Teacher/Coordinator: Prof Ben Oldroyd Session: Semester 1 Classes: Lectures 2 hours per week 13 weeks, tutorial or laboratory 4 hours per week for 13 weeks, field trip 24 hours, once during semester. Prerequisites: (12cp of BIOL2XXX) or [6cp of BIOL2XXX and (MBLG2X72 or GEGE2X01 or GENE2002)] Prohibitions: BIOL3044 or BIOL3025 or BIOL3925 or BIOL3944 or PLNT3003 or PLNT3903 Assumed knowledge: Students should be familiar with the structure of DNA molecules and the genetic code, understand the concept of a phylogenetic tree and have basic laboratory skills like pipetting and PCR. A knowledge of elementary statistics and algebra is assumed. Completion of intermediate units in genetics and genomics (i.e.GEGE2X01) and diverisity (e.g. botany or zoology) is highly recommended. Assessment: Oral presentation in a debate format (10%), Short reports in practical classes (10%), Draft scientific report (10%), Scientific report (20%), Final exam (50%). Practical field work: 24-hour period over a weekend during semester. Mode of delivery: Normal (lecture/lab/tutorial) day
Evolution is the biological process that has generated the biodiversity on this planet. It explains the common ancestry of all life on earth, why all organisms use the same genetic code, and why major life forms are constrained to a relatively small number of basic body plans such as four limbs in tetrapods. Thus, the principles of evolution and population genetics underpin all biology, including ecology, medicine and agriculture. For example, it is only because rats and humans share an evolutionary past that we can use rats as models for human medical research. In this unit, you will explore the mechanisms that generate evolutionary change at both contemporary and ancient scales. You will learn how to use DNA sequences to reconstruct the relationships among organisms and to estimate evolutionary timescales. Evolution is an ongoing process, so you will use genetic techniques to discover whether populations are divided into subpopulations. By completing this unit, you will develop skills in genomics, phylogenetic analysis, population genetics and conservation genetics. You will learn about fundamental aspects of evolution such as adaptation, sexual selection, and the origins of life. You will gain general skills in computer literacy, data management and statistical genetics.
Interdisciplinary Project
The unit of study GEGE3888 is not available in 2019
The unit of study QBIO3888 is not available in 2019
GEGE3888 Genomics Interdisciplinary Project
Credit points: 6 Teacher/Coordinator: Dr Emily Remnant Session: Semester 2 Classes: 4 hours per week of class time in group work. Prerequisites: 12cp from (GEGE2X01 or GENE2002 or AVBS2007 or BCMB2X01 or BCHM2X72 or MEDS2003 or QBIO2001 or ENVX2001) Assumed knowledge: Year 2 of Genetics and Genomics major should be complete Assessment: Assignments and written exam (50%), Project report (20%), Project oral presentation (10%), Team work participation and evaluation (20%). Mode of delivery: Supervision
Our ever-changing world requires knowledge that extends across multiple disciplines. The ability to identify and explore interdisciplinary links is a crucial skill for emerging professionals and researchers alike. This unit presents the opportunity to bring together the concepts and skills you have learnt in your discipline and apply them to a real-world problem; you will work on an authentic project involving genetics and genomics. For example, you will work on a project that might generate a web resource for the management of genomic data in population. In this unit, you will continue to understand and explore disciplinary knowledge, while also meeting and collaborating with students from across the University through project-based learning; identifying and solving problems, collecting and analysing data and communicating your findings to a diverse audience. All of these skills are highly valued by employers. This unit will foster the ability to work in interdisciplinary teams, and this is essential for both professional and research pathways in future.
QBIO3888 Quantitative Biology Interdisciplinary Unit
Credit points: 6 Teacher/Coordinator: A/Prof Brian Jones Session: Semester 2 Classes: Lectures 2 hrs/week; Practical 3 hrs/week Prerequisites: 12cp from (ENVX2001 or BIOL2X22 or GEGE2X01 or AVBS2005 or BCMB2X01 or MEDS2003 or QBIO2001 or DATA2X02 or BCHM2X72 or GENE2002 or SOIL2005 or AGRI2001 or ENSC2001 or BIOL2X24 or BIOL2032) Assessment: Documentation/Laboratory eNotebooks (15%), Project report (50%), Team work participation evaluation (15%), Project oral presentation (20%). Mode of delivery: Normal (lecture/lab/tutorial) day
Working effectively across disciplines has become an intrinsic part of most professional and research environments. In this unit, you will develop solutions to complex real world problems. The unit is designed to foster your abilities in your chosen discipline, and for you to work towards a project goal in a supported, collaborative team environment with students from other disciplines. This unit offers you the opportunity to work on a project in one of three key areas: (1) 'omics-based modelling; (2) synthetic biology; or (3) ecosystem modelling. The projects will focus on the development of: novel clinical biomarkers; the development of innovative biological machines; or the discovery of mechanisms underlying ecosystem function. You will identify a problem, develop novel solutions and communicate your ?ndings to a diverse audience. Combined with your disciplinary skills, the ability to work with others to develop solutions to complex problems is highly valued by employers.
SCPU3001 Science Interdisciplinary Project
Credit points: 6 Teacher/Coordinator: Pauline Ross Session: Intensive December,Intensive February,Intensive January,Intensive July,Semester 1,Semester 2 Classes: The unit consists of one seminar/workshop per week with accompanying online materials and a project to be determined in consultation with the partner organisation and completed as part of team with academic supervision. Prerequisites: Completion of 2000-level units required for at least one Science major. Assessment: group plan, group presentation, reflective journal, group project Mode of delivery: Normal (lecture/lab/tutorial) day
This unit is designed for students who are concurrently enrolled in at least one 3000-level Science Table A unit of study to undertake a project that allows them to work with one of the University's industry and community partners. Students will work in teams on a real-world problem provided by the partner. This experience will allow students to apply their academic skills and disciplinary knowledge to a real-world issue in an authentic and meaningful way. Participation in this unit will require students to submit an application to the Faculty of Science.