Molecular Biology

Credit Points

30

Course Coordinator

Mr A. M. Cumming

Pre-requisites

A degree or equivalent qualification, at the prescribed standard, in Genetics or other relevant discipline.

Overview

This 12 week course will include lectures, tutorials and an essay assignment. The curriculum will include the role of gene markers in predicting disease susceptibility and therapeutic approaches to the treatment of disease. The diseases covered include neurological disorders, cancer, bone disease and human developmental defects. The essay assignment is restricted to a medical genetic topic of current interest.

Structure

Five 1 hour lectures per week and 1 tutorial per week.

Assessment

One 1.5 hour written examination (40%) and one essay (60%)

Credit Points

7.5

Course Coordinator

Mr. A. M. Cumming

Pre-requisites

N/A

Overview

The 12 week course will include lectures, tutorials and a seminar. The curriculum will include population genetics, gene disease association; analysis of genetic disorders; genetic epidemiology; autoimmune disease in relation to the HLA complex

Structure

One or two 1 hour lectures per week, three 2 hour tutorials and four 3 hour tutorials

Assessment

One 2 hour written examination

Credit Points

7.5

Course Coordinator

Mr. A. M. Cumming

Pre-requisites

A degree or equivalent qualification, at the prescribed standard, in Genetics or other relevant discipline.

Overview

This 6 week course will include lectures and tutorials. The curriculum includes information on the services provided within the health service for the diagnosis of genetic abnormalities. Particular attention is focused on cytogenetics defects and pre-natal diagnosis, and the increasing use of a DNA diagnostic service in providing detailed molecular information for the genetic counselling service.

Structure

Five 1 hour lectures per week.

Assessment

One 2 hour written examination.

Credit Points

10

Course Coordinator

Professor Duncan Shaw

Pre-requisites

None

Co-requisites

None

Overview

Twelve lectures on the basics of genome structure/genetic mapping, gene expression, analytical methods such as cloning and PCR, and protein structure and function. Two tutorial/problem solving sessions covering topics related to the lectures.

Structure

12 x 1 hour lecturing
2 x 2 hours tutorial/problem solving

Assessment

50% coursework (problem-solving assignment), 50% MCQ exam

Credit Points

10

Course Coordinator

Dr Allison Carrington

Pre-requisites

Entry to MSc programme in CLSM

Overview

Cloning practical: use restriction enzymes to digest DNA, analyse using gel electrophoresis, ligate into appropriate vector and transfect competent cells to amplify DNA and plasmid. Use appropriate selection methods to select successfully transfected cells. Analyse structure of recombinant DNA isolated from clones.

Structure

7 x 4-hour practical classes

Assessment

Continuous assessment (100%): lab book (10%) and lab write-ups (60%); essay under examination conditions (30%).

Credit Points

12.5

Course Coordinator

Henning Wackerhage

Pre-requisites

N/A

Overview

After an introduction to wet lab work, students will learn to perform a PCR reaction, protein extraction and a Western blot.

Structure

On-line teaching: Students will receive a comprehensive presentation that details the background to each method once a week.
Seminar: The material of the on-line presentation and the practical will be discussed during a weekly one-hour seminar.
Practicals: The backbone of this course is a weekly practical which may range from 3 hours to 1.5 days.
1. Introduction to wet lab work (3 h)
2. PCR for a human polymorphism (relevant assay for each cohort; 2 h + 4 h)
3. Protein extraction (relevant samples for each cohort: 6h)
4. Western blotting (relevant antibodies for each cohort: 6 h + 3 h)

Assessment

Continuous assessment (30%): Lab book (10%); Lab report (20%)
Examination (70%): 1 two-hour examination

Credit Points

30

Course Coordinator

Dr Kath Shennan and Professor Graeme Paton

Pre-requisites

None.

Overview

This course describes and explains the theory and practice of the 'tool kit' that modern molecular biology uses to derive information about how biological systems function and interact. Detailing a wide and comprehensive range of molecular techniques, the course covers basic molecular biology, manipulation of DNA and RNA, gene closing and gene expression analysis, studies of gene functions, and proteins. The use of antibodies as molecular tools is also considered.

Structure

4 one-hour lectures per week, 8 three-hour practicals, and 3 one-hour tutorials.

Assessment

Continuous assessment consisting of a practical report (60%), a practical-related exercise (15%) and an essay (25%); no written examination.

Credit Points

5

Course Coordinator

Mr A. M. Cumming

Pre-requisites

A degree or equivalent qualification, at the prescribed standard, in Genetics or other relevant discipline.

Overview

This 12 week course will include lectures, tutorials and practicals. The curriculum provides a range of molecular technologies for the study of genetic phenomena including the cloning and expression of genes using vector systems; the application of molecular information and genetic linkage analysis to locate genes; the utilisation of transgenic mice as disease models; practical experience in the cloning and analysis of a gene; searching for genetic variants using DNA technologies.

Structure

Five 1 hour lectures per week, 1 tutorial and seven 2 hour practicals.

Assessment

One 1.5 hour written examination (70%) and continuous assessment (30%)

Credit Points

10

Course Coordinator

Dr Heather Wallace

Pre-requisites

N/A

Overview

Is subject dependent but will be directed by the MSc Programme Co-ordinator in the subject. For example Clinical Pharmacology - Dr Heather Wallace.

Structure

Directed student learning. 3 meetings with tutor.

Assessment

90% continuous assessment (1 major essay); 10% oral presentation.

Credit Points

30

Course Coordinator

Mr. A. Cumming

Pre-requisites

A degree or equivalent qualification, at the prescribed standard, in Genetics or other relevant discipline.

Overview

This 12 week course consists of lectures, tutorials and an essay assignment. The curriculum focuses on the population biochemical screening or metabolic disorders using a number of model systems e.g. phenylketonuria. The biochemical diagnosis and clinical management of a range of metabolic abnormalities are also dealt with. Also covered are ethical issues raised in the diagnosis debilitating diseases through molecular technologies. The essay will focus on the background to the topic of the research project.

Structure

Five 1 hour lectures per week.

Assessment

One 2 hour examination (40%) and one essay (60%)

Credit Points

15

Course Coordinator

Mr. A. M. Cumming

Pre-requisites

A degree or equivalent qualification, at the prescribed standard, in Genetics or other relevant discipline.

Co-requisites

MB5002, MB5003, MB5003, MB5005, MB5502

Overview

Statistics - measures of central tendency - mean; measures or variability; distributions; t test; analysis of variance; correlation and regression analysis; non-parametric statistics; testing hypothesis; experimental design; genetic analysis of quantitative traits; linkage analysis; genetic risk assessment; bioinformatics. A series of practical sessions introduce the students to PCR-based methods for genotype identification and analysis of common diseases.

Structure

Statistics - 6 x 1hr lectures; 1 x 2hr computing practical; 2 x 2hr tutorials.
Data Analysis - 2 x 2hr tutorials; 1 x 3hr bioinformatics computer practical.
Genetics practical - 6 x 3 hr practical.

Assessment

Statistics 2 hr exam - 30%
Data Analysis 2 hr exam - 50%
Practical Report - 20%

Credit Points

0

Course Coordinator

Mr. A, M. Cumming

Pre-requisites

A degree or equivalent qualification, at the prescribed standard, in Genetics or other relevant discipline.

Co-requisites

A satisfactory level of attainment in examination and assignments within the MSc Medical Molecular Genetics programme.

Notes

Overview

Projects are restricted to research areas in the field of medical genetics. The nature of the project reflects the interest of research groups and workers within the Departments on the Foresterhill site.

Structure

Assessment

Lab 15%
Oral Presentation 15%
Thesis 70%