Undergraduate Course: Molecular Cell Biology 3 (BILG09001)
Course Outline
| School | School of Biological Sciences |
College | College of Science and Engineering |
| Credit level (Normal year taken) | SCQF Level 9 (Year 3 Undergraduate) |
Availability | Available to all students |
| SCQF Credits | 20 |
ECTS Credits | 10 |
| Summary | Cellular communication and signal transduction; second messengers; membrane trafficking and protein sorting in intracellular pathways; endocytosis and exocytosis; organelle biogenesis; cytoskeleton and its role in cellular dynamics and statics; contractility and cell movement; mitosis, the cell cycle and its control; regulation of cell proliferation; nuclear domains. |
| Course description |
The individual living cell is the fundamental unit of life. Every cell is like a small city, with specialised structures and signals that work together to allow a cell to survive, move, reproduce, and communicate with its environment. Understanding these behaviors, their mechanisms, and their coordination is the goal of cell biology as a scientific discipline. In the 21st century, the structure and function of eukaryotic cells are investigated primarily at the molecular level, through a combination of biochemical, molecular-genetic and immunological methods. These approaches have provided insights into how complex processes such as cell division, differentiation, movement and cell-cell interactions take place.
This second-semester course takes as its starting point the material covered in several of the first-semester 3rd year courses and applies that knowledge to a detailed study of several major topics in molecular cell biology: receptors and cell-cell signalling; cell cycle; membrane trafficking; protein targeting; chromosome structure and nuclear domains; and cytoskeleton and motor proteins. As the pace of research in these areas is very rapid, the course will concentrate on the experimental designs and techniques used to dissect and analyse these processes, as well as looking at current ideas as to how these processes take place.
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Information for Visiting Students
| Pre-requisites | Equivalent of the courses listed above |
| High Demand Course? |
Yes |
Course Delivery Information
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| Academic year 2017/18, Available to all students (SV1)
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Quota: None |
| Course Start |
Semester 2 |
Timetable |
Timetable |
| Learning and Teaching activities (Further Info) |
Total Hours:
200
(
Lecture Hours 26,
Seminar/Tutorial Hours 4,
Supervised Practical/Workshop/Studio Hours 16,
Feedback/Feedforward Hours 3,
Summative Assessment Hours 4,
Programme Level Learning and Teaching Hours 4,
Directed Learning and Independent Learning Hours
143 )
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| Assessment (Further Info) |
Written Exam
55 %,
Coursework
26 %,
Practical Exam
19 %
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| Additional Information (Assessment) |
Two types of in-course assessment (essay and student presentations), plus a 2-hour in-course test, and a 2-hour degree exam. |
| Feedback |
Formative verbal and/or written feedback given for student presentations, online- and group-projects, lab practical, and interactive lecture block. Written and audio/video feedback given for essay. Feedback is also provided via an active Learn Discussion Board. |
| Exam Information |
| Exam Diet |
Paper Name |
Hours & Minutes |
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| Main Exam Diet S2 (April/May) | | 2:00 | | | Resit Exam Diet (August) | | 2:00 | |
Learning Outcomes
On completion of this course, the student will be able to:
- Understand the current state of knowledge in the subject areas covered by the lectures and tutorials.
- Understand the experimental techniques and evidence upon which this knowledge is based.
- Apply your understanding to a novel problem, in the form of a well-reasoned essay in which you propose hypotheses to explain a new cell-biological phenomenon and suggest/design experiments to test your hypotheses.
- Analyse experimental data relating to: cell motility in vivo; proteins identified by immunoprecipitation and database searching; cell-cycle mutations; simulations of levels of regulatory proteins may oscillate in order to drive the cell cycle.
- Practical: understand how differential detergent-solubility and relative buoyant density can be used to isolate specialised membrane subdomains from a tissue homogenate; demonstrate enrichment for specific membrane components and associated mechanisms within a defined membrane compartment using assays for cholesterol and total protein; detect tyrosine kinase activity associated with components of membrane fractions using in vitro kinase assays followed by SDS polyacrylamide gel electrophoresis; and carry out Western blotting with appropriate antibodies and detection system.
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Reading List
Textbook: Alberts et al., Molecular Biology of the Cell (5th or 6th ed.), or Lodish et al., Molecular Cell Biology (6th or 7th ed.)
Other reading in the primary or secondary research literature, as assigned/recommended by lecturers. |
Additional Information
| Graduate Attributes and Skills |
The University has identified a set of four clusters of skills and abilities (see headings below) that we would like students to develop throughout their degree programme to strengthen your attitude towards lifelong learning and personal development, as well as future employability. The graduate attributes we hope to develop within Molecular Cell Biology 3 are indicated below.
Research and Enquiry
The course aims to increase your understanding of the general subject area and also obtain specific skills as outlined in the course Aims and Objectives. The knowledge base of the course and the development of research and technical skills will be of benefit to you in completing your degree and beyond. The course will develop research and problem-solving capabilities through the Lab Practical and Web-based projects and through the Course Essay.
Personal and Intellectual Autonomy
To meet the objectives and challenges of the course, we encourage students both to work independently and also to discuss and debate with other students to strengthen your views as they develop. By reading textbooks and research papers you will expand your knowledge of the topics covered in the lectures, and this will allow you to broaden your own personal scientific interests outside of the specific subjects in the course. In writing the Course Essay you will explore a topic in detail, evaluate what you have read in a critical way and provide your own approach to investigating and solving a biological problem.
Communication
Through discussion and collaboration with students in the tutorials, Lab Practical and Mitotic Oscillator project you will be able to communicate your views and ideas and to learn from your peers. Preparing for your presentations at tutorials will help you to develop effective communication skills. You are also encouraged to ask questions from your lecturers, practical demonstrators and tutors to expand your knowledge and clear up any misinterpretations you might have. There is also a course Discussion Board on Learn which can be used to obtain feedback and to discuss various aspects of the course.
Personal Effectiveness
Throughout your degree programme you will learn transferable skills that will benefit you not only across the courses you are enrolled in but in future employment and further study. In this course, as in others, time management is an important skill you will learn as you must develop ways to organise your work and meet deadlines. Writing a well-reasoned essay will help you to organize your thoughts succinctly and effectively. Group work in the Lab Practical and the Mitotic Oscillator project is also an important transferable skill. By interacting with fellow students you will become aware of your own skills and talents (and your possible limitations) and appreciate those of others. |
| Additional Class Delivery Information |
Tu, F, 0900-1230 - includes a combination of lectures, practicals and tutorials. |
| Keywords | MCB3 |
Contacts
| Course organiser | Prof Ken Sawin
Tel: (0131 6)50 7064
Email: |
Course secretary | Miss Emma Currie
Tel: (0131 6)50 5988
Email: |
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