Students
CBMS836 – Molecular Biology and Genomics
2018 – S1 Day
General Information
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| Unit convenor and teaching staff |
Unit convenor and teaching staff
Distinguished Professor ajnd Unit Convener
Ian Paulsen
Contact via 98508152
E8A 202, 14 Eastern Road
Professor
Paul Haynes
Contact via 98506258
F7B 331, 4 Wally's Walk
Senior Scientific Officer
Ray Duell
Contact via 98508184
E8A 106, 14 Eastern Road
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|---|---|
| Credit points |
Credit points
4
|
| Prerequisites |
Prerequisites
Admission to MBiotech or MBiotechMCom or MRadiopharmSc or MSc or MBioBus or MMarScMgt or GradDipConsBiol
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| Corequisites |
Corequisites
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| Co-badged status |
Co-badged status
CBMS336/836
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| Unit description |
Unit description
Molecular biology is a central science in twenty-first century biology and biotechnology. In this unit we explore topics that allow students to obtain an advanced understanding of the mechanisms of molecular biology, including those of DNA replication and recombination, gene expression and regulation, and mobile elements. We also address topics on the rapidly changing technologies in molecular biology, including those used in genome sequencing, metagenomics and microarray analysis. Practical sessions complement the lectures and provide students with hands-on experience with a range of critical laboratory skills including those required for DNA and RNA isolation, PCR and RT-PCR, cloning and bioinformatics.
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Important Academic Dates
Information about important academic dates including deadlines for withdrawing from units are available at https://www.mq.edu.au/study/calendar-of-dates
Learning Outcomes
On successful completion of this unit, you will be able to:
- Students will be be able to describe the theory behind and demonstrate competency in the use of a range of molecular biology experimental techniques, including PCR, restriction enzyme digestion, gel electrophoresis, cloning, site-directed mutagenesis, DNA sequencing and DNA hybridization.
- Students will be able to describe and discuss essential molecular processes in the cell, especially as related to DNA and RNA. These molecular processes include transcription, translation, DNA replication, recombination, DNA repair, and transposition.
- Students will be able to relate the revolutionary impact of genomics across all biological sciences.
- Students will be able to analyse and interpret experimental data and present this in a structured report utilising appropriate scientific referencing.
- Students will be able to analyse and interpret genomic data utilising bioinformatic techniques.
- Students will be able to analyse and critique experimental data and current scientific literature and present this in written and oral format.
General Assessment Information
Assignments
- All assignments must be submitted in hard copy to the FSE Student Centre by midday on the date specified and must include a completed and signed coversheet stapled to the front cover.
- In addition, all written work must be submitted to Turnitin for plagiarism checking. Instructions will be provided on iLearn.
- Criteria and standards required for the assessment tasks will be available on iLearn.
Extensions will only be granted under exceptional circumstances.
There will be a deduction of 10% of the total available marks made from the total awarded mark for each 24 hour period or part thereof that the submission is late (for example, 25 hours late in submission – 20% penalty). This penalty does not apply for cases in which an application for disruption of studies is made and approved.
Problem Set
Problems 1 - 12 should be done in time for marking and discussion during the practical session of the Week 12.
Requirements
Assessment tasks include the practical assignments and the problem sets which are both integral components of the unit. Apart from the marks formally allocated to these components, a comprehensive understanding of them will greatly assist you in the final exam. You should remember that the final exam covers ALL components of the unit.
Participation in ALL practical sessions is required in order to complete the practical reports.
Assessment Tasks
| Name | Weighting | Hurdle | Due |
|---|---|---|---|
| Laboratory Reports | 15% | No | TBA |
| Bioinformatic Report | 10% | No | TBA |
| Mid-Semester Test | 10% | No | Week 7 (April 30th - May 4th) |
| Essay | 10% | No | TBA |
| Problem Set | 5% | No | Week 12 (June 4th - June 8th) |
| Final Examination | 50% | No | University Examination Period |
Laboratory Reports
Due: TBA
Weighting: 15%
3 lab reports, 1500 words each
On successful completion you will be able to:
- Students will be be able to describe the theory behind and demonstrate competency in the use of a range of molecular biology experimental techniques, including PCR, restriction enzyme digestion, gel electrophoresis, cloning, site-directed mutagenesis, DNA sequencing and DNA hybridization.
- Students will be able to analyse and interpret experimental data and present this in a structured report utilising appropriate scientific referencing.
- Students will be able to analyse and critique experimental data and current scientific literature and present this in written and oral format.
Bioinformatic Report
Due: TBA
Weighting: 10%
Report on Bioinformatic Analysis
On successful completion you will be able to:
- Students will be able to relate the revolutionary impact of genomics across all biological sciences.
- Students will be able to analyse and interpret experimental data and present this in a structured report utilising appropriate scientific referencing.
- Students will be able to analyse and interpret genomic data utilising bioinformatic techniques.
- Students will be able to analyse and critique experimental data and current scientific literature and present this in written and oral format.
Mid-Semester Test
Due: Week 7 (April 30th - May 4th)
Weighting: 10%
Multiple Choice Test carried out during regularly scheduled laboratory time.
On successful completion you will be able to:
- Students will be be able to describe the theory behind and demonstrate competency in the use of a range of molecular biology experimental techniques, including PCR, restriction enzyme digestion, gel electrophoresis, cloning, site-directed mutagenesis, DNA sequencing and DNA hybridization.
- Students will be able to describe and discuss essential molecular processes in the cell, especially as related to DNA and RNA. These molecular processes include transcription, translation, DNA replication, recombination, DNA repair, and transposition.
- Students will be able to analyse and critique experimental data and current scientific literature and present this in written and oral format.
Essay
Due: TBA
Weighting: 10%
1000 word research essay
On successful completion you will be able to:
- Students will be able to describe and discuss essential molecular processes in the cell, especially as related to DNA and RNA. These molecular processes include transcription, translation, DNA replication, recombination, DNA repair, and transposition.
- Students will be able to relate the revolutionary impact of genomics across all biological sciences.
- Students will be able to analyse and interpret experimental data and present this in a structured report utilising appropriate scientific referencing.
- Students will be able to analyse and critique experimental data and current scientific literature and present this in written and oral format.
Problem Set
Due: Week 12 (June 4th - June 8th)
Weighting: 5%
12 Question Problem Set in Prac Manual.
On successful completion you will be able to:
- Students will be be able to describe the theory behind and demonstrate competency in the use of a range of molecular biology experimental techniques, including PCR, restriction enzyme digestion, gel electrophoresis, cloning, site-directed mutagenesis, DNA sequencing and DNA hybridization.
- Students will be able to analyse and critique experimental data and current scientific literature and present this in written and oral format.
Final Examination
Due: University Examination Period
Weighting: 50%
2 essays, 20 short answer questions
On successful completion you will be able to:
- Students will be be able to describe the theory behind and demonstrate competency in the use of a range of molecular biology experimental techniques, including PCR, restriction enzyme digestion, gel electrophoresis, cloning, site-directed mutagenesis, DNA sequencing and DNA hybridization.
- Students will be able to describe and discuss essential molecular processes in the cell, especially as related to DNA and RNA. These molecular processes include transcription, translation, DNA replication, recombination, DNA repair, and transposition.
- Students will be able to relate the revolutionary impact of genomics across all biological sciences.
- Students will be able to analyse and critique experimental data and current scientific literature and present this in written and oral format.
Delivery and Resources
Classes There are two weekly lectures of 1 hour each on Friday (10 am - 11 am Friday in 14 Sir Christopher Ondaatje Ave - E7B T5 Theatre, and 12 noon - 1 pm Friday in 14 Sir Christopher Ondaatje Ave - E7B T5 Theatre) and a weekly practical session of 3 hours (14 Eastern Road E8A labs 130 and 150, 10 am - 1 pm or 2 pm - 5 pm Wednesday). In weeks 9 to 11, the practical class includes a bioinformatic workshop in the same location. Attendance at practical sessions (and bioinformatic workshop) is a compulsory component of this unit. Lecture recordings and graphics slides are available online through iLearn (https://ilearn.mq.edu.au/login/MQ/), although lecture attendance in person is highly recommended. The practical manual is also available online through iLearn.
Required and Recommended Texts The course syllabus is defined by all of the subject material presented in lectures and practicals, much of which is beyond standard textbooks. The prescribed text for this unit is Molecular Biology Fifth edition by Robert F Weaver. Available from the Co-op bookshop. The following texts may also be useful and are available in the library:
GenesIX by Benjamin Lewin
Mobile Genetic Elements by Sherratt
Molecular Cloning: A Laboratory Manual by Maniatis, Fritsch and Sambrook
An Introduction to Genetic Engineering by Des Nicholl.
Technology Requirements Within this Unit, you will be introduced to Web-based search engines that are commonly used in molecular biology. Our expectation is that you will be able to readily access the internet and have a computer available to you for web browsing and preparation of your laboratory reports. Handwritten reports will not be accepted. Your laboratory reports will be submitted and circulated via the online Turnitin program, for which access instructions will be given at submission time. Your practical reports will require you to carry out minor computational tasks, for which a calculator and access to basic statistical tools will be required. We place a large emphasis on correct referencing style in all your reports, and use of the program EndNote is encouraged, but not essential.
Unit Schedule
|
Week |
Date |
Lecture |
Title |
Lecturer |
|
1 |
Mar 2 |
1 |
Introduction/What is Molecular Biology/Genome Structure |
Haynes |
|
Mar 2 |
2 |
Gene Organization/function |
Haynes |
|
|
2 |
Mar 9 |
3 |
Molecular Biology Techniques |
Haynes |
|
Mar 9 |
4 |
Molecular Biology Techniques |
Paulsen |
|
|
3 |
Mar 16 |
5 |
Molecular Cloning |
Haynes |
|
Mar 16 |
6 |
Tools for studying Gene Activity |
Haynes |
|
|
4 |
Mar 23 |
7 |
Transcription in Prokaryotes |
Paulsen |
|
Mar 23 |
8 |
Structure of Prokaryotic Operons |
Paulsen |
|
|
5 |
Apr 6 |
9 |
Bacterial Gene Regulation |
Paulsen |
|
Apr 6 |
10 |
Transcription in Eukaryotes |
Paulsen |
|
|
6 |
Apr 13 |
11 |
Eukaryotic Gene Regulation |
Paulsen |
|
Apr 13 |
12 |
Nucleosomes/Histones/Chromatin |
Paulsen |
|
| SEMESTER BREAK | ||||
|
7 |
May 4 |
13 |
Messenger RNA splicing |
Paulsen |
|
May 4 |
14 |
Mechanism of Translation |
Paulsen |
|
|
8 |
May 11 |
15 |
Ribosomes and transfer RNA |
Paulsen |
|
May 11 |
16 |
DNA replication |
Paulsen |
|
|
9 |
May 18 |
17 |
DNA recombination |
Paulsen |
|
May 18 |
18 |
DNA repair |
Paulsen |
|
|
10 |
May 25 |
19 |
Mobile DNA elements |
Paulsen |
|
May 25 |
20 |
Mobile DNA elements |
Paulsen |
|
|
11 |
June 1 |
21 |
Genome Sequencing |
Paulsen |
|
June 1 |
22 |
Genomes, Pan-Genomes and Metagenomics |
Paulsen |
|
|
12 |
June 8 |
23 |
Bioinformatics and Genome Annotation |
Paulsen |
|
June 8 |
24 |
Functional Genomics and Systems Biology |
Paulsen |
|
|
13 |
Jun 15 |
25 |
Synthetic Biology |
Paulsen |
|
Jun 15 |
26 |
Revision |
Paulsen |
Policies and Procedures
Macquarie University policies and procedures are accessible from Policy Central (https://staff.mq.edu.au/work/strategy-planning-and-governance/university-policies-and-procedures/policy-central). Students should be aware of the following policies in particular with regard to Learning and Teaching:
- Academic Appeals Policy
- Academic Integrity Policy
- Academic Progression Policy
- Assessment Policy
- Fitness to Practice Procedure
- Grade Appeal Policy
- Complaint Management Procedure for Students and Members of the Public
- Special Consideration Policy (Note: The Special Consideration Policy is effective from 4 December 2017 and replaces the Disruption to Studies Policy.)
Undergraduate students seeking more policy resources can visit the Student Policy Gateway (https://students.mq.edu.au/support/study/student-policy-gateway). It is your one-stop-shop for the key policies you need to know about throughout your undergraduate student journey.
If you would like to see all the policies relevant to Learning and Teaching visit Policy Central (https://staff.mq.edu.au/work/strategy-planning-and-governance/university-policies-and-procedures/policy-central).
Student Code of Conduct
Macquarie University students have a responsibility to be familiar with the Student Code of Conduct: https://students.mq.edu.au/study/getting-started/student-conduct
Results
Results shown in iLearn, or released directly by your Unit Convenor, are not confirmed as they are subject to final approval by the University. Once approved, final results will be sent to your student email address and will be made available in eStudent. For more information visit ask.mq.edu.au.
Student Support
Macquarie University provides a range of support services for students. For details, visit http://students.mq.edu.au/support/
Learning Skills
Learning Skills (mq.edu.au/learningskills) provides academic writing resources and study strategies to improve your marks and take control of your study.
Student Services and Support
Students with a disability are encouraged to contact the Disability Service who can provide appropriate help with any issues that arise during their studies.
Student Enquiries
For all student enquiries, visit Student Connect at ask.mq.edu.au
IT Help
For help with University computer systems and technology, visit http://www.mq.edu.au/about_us/offices_and_units/information_technology/help/.
When using the University's IT, you must adhere to the Acceptable Use of IT Resources Policy. The policy applies to all who connect to the MQ network including students.
Graduate Capabilities
PG - Capable of Professional and Personal Judgment and Initiative
Our postgraduates will demonstrate a high standard of discernment and common sense in their professional and personal judgment. They will have the ability to make informed choices and decisions that reflect both the nature of their professional work and their personal perspectives.
This graduate capability is supported by:
Learning outcomes
- Students will be be able to describe the theory behind and demonstrate competency in the use of a range of molecular biology experimental techniques, including PCR, restriction enzyme digestion, gel electrophoresis, cloning, site-directed mutagenesis, DNA sequencing and DNA hybridization.
- Students will be able to describe and discuss essential molecular processes in the cell, especially as related to DNA and RNA. These molecular processes include transcription, translation, DNA replication, recombination, DNA repair, and transposition.
- Students will be able to relate the revolutionary impact of genomics across all biological sciences.
- Students will be able to analyse and interpret experimental data and present this in a structured report utilising appropriate scientific referencing.
Assessment tasks
- Laboratory Reports
- Bioinformatic Report
- Mid-Semester Test
- Essay
- Problem Set
- Final Examination
PG - Discipline Knowledge and Skills
Our postgraduates will be able to demonstrate a significantly enhanced depth and breadth of knowledge, scholarly understanding, and specific subject content knowledge in their chosen fields.
This graduate capability is supported by:
Learning outcomes
- Students will be be able to describe the theory behind and demonstrate competency in the use of a range of molecular biology experimental techniques, including PCR, restriction enzyme digestion, gel electrophoresis, cloning, site-directed mutagenesis, DNA sequencing and DNA hybridization.
- Students will be able to describe and discuss essential molecular processes in the cell, especially as related to DNA and RNA. These molecular processes include transcription, translation, DNA replication, recombination, DNA repair, and transposition.
- Students will be able to relate the revolutionary impact of genomics across all biological sciences.
- Students will be able to analyse and interpret genomic data utilising bioinformatic techniques.
Assessment tasks
- Laboratory Reports
- Bioinformatic Report
- Mid-Semester Test
- Essay
- Problem Set
- Final Examination
PG - Critical, Analytical and Integrative Thinking
Our postgraduates will be capable of utilising and reflecting on prior knowledge and experience, of applying higher level critical thinking skills, and of integrating and synthesising learning and knowledge from a range of sources and environments. A characteristic of this form of thinking is the generation of new, professionally oriented knowledge through personal or group-based critique of practice and theory.
This graduate capability is supported by:
Learning outcomes
- Students will be be able to describe the theory behind and demonstrate competency in the use of a range of molecular biology experimental techniques, including PCR, restriction enzyme digestion, gel electrophoresis, cloning, site-directed mutagenesis, DNA sequencing and DNA hybridization.
- Students will be able to describe and discuss essential molecular processes in the cell, especially as related to DNA and RNA. These molecular processes include transcription, translation, DNA replication, recombination, DNA repair, and transposition.
- Students will be able to relate the revolutionary impact of genomics across all biological sciences.
- Students will be able to analyse and interpret experimental data and present this in a structured report utilising appropriate scientific referencing.
- Students will be able to analyse and interpret genomic data utilising bioinformatic techniques.
- Students will be able to analyse and critique experimental data and current scientific literature and present this in written and oral format.
Assessment tasks
- Laboratory Reports
- Bioinformatic Report
- Mid-Semester Test
- Essay
- Problem Set
- Final Examination
PG - Research and Problem Solving Capability
Our postgraduates will be capable of systematic enquiry; able to use research skills to create new knowledge that can be applied to real world issues, or contribute to a field of study or practice to enhance society. They will be capable of creative questioning, problem finding and problem solving.
This graduate capability is supported by:
Learning outcomes
- Students will be be able to describe the theory behind and demonstrate competency in the use of a range of molecular biology experimental techniques, including PCR, restriction enzyme digestion, gel electrophoresis, cloning, site-directed mutagenesis, DNA sequencing and DNA hybridization.
- Students will be able to describe and discuss essential molecular processes in the cell, especially as related to DNA and RNA. These molecular processes include transcription, translation, DNA replication, recombination, DNA repair, and transposition.
- Students will be able to relate the revolutionary impact of genomics across all biological sciences.
Assessment tasks
- Laboratory Reports
- Bioinformatic Report
- Mid-Semester Test
- Essay
- Problem Set
- Final Examination
PG - Effective Communication
Our postgraduates will be able to communicate effectively and convey their views to different social, cultural, and professional audiences. They will be able to use a variety of technologically supported media to communicate with empathy using a range of written, spoken or visual formats.
This graduate capability is supported by:
Learning outcomes
- Students will be able to analyse and interpret experimental data and present this in a structured report utilising appropriate scientific referencing.
- Students will be able to analyse and interpret genomic data utilising bioinformatic techniques.
- Students will be able to analyse and critique experimental data and current scientific literature and present this in written and oral format.
Assessment tasks
- Laboratory Reports
- Bioinformatic Report
- Mid-Semester Test
- Essay
- Problem Set
- Final Examination
PG - Engaged and Responsible, Active and Ethical Citizens
Our postgraduates will be ethically aware and capable of confident transformative action in relation to their professional responsibilities and the wider community. They will have a sense of connectedness with others and country and have a sense of mutual obligation. They will be able to appreciate the impact of their professional roles for social justice and inclusion related to national and global issues
This graduate capability is supported by:
Learning outcome
- Students will be able to analyse and critique experimental data and current scientific literature and present this in written and oral format.
Assessment tasks
- Laboratory Reports
- Bioinformatic Report
- Mid-Semester Test
- Essay
- Problem Set
- Final Examination