BSc Genetics options
Year 2, Component 06
Option(s) from list
5.5% of the population will have developed a genetic disorder by age 25. But how does genetic disease occur? From understanding the molecular basis of genetic disease, to the techniques used in NHS laboratories for diagnosis and screening for genetic disorders, you address the nature and inheritance of both single gene and complex genetic disease, and explore the effects of abnormalities in human chromosomes. Developments such as gene therapy, the 100,000 genomes project and manipulation of embryos will also be discussed.
Our bodies are under attack. So how do we defend ourselves against foreign invaders? Explore the anatomical and structural components of the immune system and assess what happens in the event of immunodysfunction. Utilising real-world case-studies (eg AIDS), and looking at specific examples (eg allergy and transplantation) you will review important aspects of clinical immunology and immuno-pathology, gaining an understanding of auto-immunity and immune-deficiencies. You will also consider the future of human immunology – evaluating how far vaccines can protect us against disease. Using the knowledge you have gained you will be able to identify areas of current immunology understanding that could lead to positive medical intervention.
Assess the importance of zinc, copper and iron in biological systems and review how they are kept in stable equilibrium. Explore the structure and functions of proteins and enzymes that contain metal cofactors and discuss the diseases and possible treatments associated with both metal deficiency and overload.
Understanding the shape, structure and folding of proteins can provide the basis for drug targeting in disease processes and enable us to develop a better understanding of specific biological pathways. This module takes a look at particular macromolecular assemblies using the most up-to-date structural biological techniques with a particular emphasis on x-ray crystallography.
We all know food is the fuel of life – but how do our bodies turn the things we put on our plate into the energy we need to function? Study the processes that coordinate metabolism of proteins, lipids and carbohydrates, paying particular attention to organ specialisation, hormonal control, metabolic homeostasis and appetite and body weight. The consequences of disturbances to metabolism will also be discussed.
The aim of this module is to provide a view of how a fundamental understanding of plant processes can impact on the production of plants for the 21st century. Learn the essential processes and constraints on plant growth and development, and explore how innovative technological approaches in plant sciences may provide real solutions to our future predicted global food shortage. You’ll look into key aspects of plant physiology such as different photosynthetic mechanisms, and modern approaches to manipulating plant performance and growth.
This module will develop your understanding of how researchers examine the molecular components of life to better understand the ecology of living organisms. This feeds directly into modern approaches for conservation biology, monitoring ecosystems, examining species iterations, and advancing our understanding of the ecological and evolutionary relationships supporting a living planet. This module will be delivered via a series of lectures and lab practicals, with a balanced emphasis on both applying knowledge and understanding theory.
Microbes have been on the Earth for at least 3.5 billion years; they tolerate or require a huge range of physico-chemical extremes and perform a remarkable array of functions. This module will examine the diversity of microbes, and how they can be applied for the benefit of society and the environment, for example by bioremediation of contaminated land, recovery of oil and metals, production of biofuels and therapeutic compounds.
Bioinformatics have become an indispensable skill for the next generation of biochemists and biologists in order to retrieve, analyse and interpret data. You will learn how to access, search and extract data from publicly available protein databases, and analyse and display results using appropriate software.
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