Menu
A+ A A-

COS 514: Advanced Topics in Computational and Mathematical Biology

 

Course Title

Advanced Topics in Computational and Mathematical Biology

Course Code

COS 514

Course Type

Elective

Level

PhD

Instructor’s Name

Prof. George K. Christophides (Lead Instructor)
Dr. Kamil Erguler, Dr. Charalambos Chrysostomou, Adjunct Asst. Prof.  Michalis Omirou

ECTS

5

Lectures / week

90 min/week for 7 weeks

Laboratories / week

90 min/week for 7 weeks

Course Purpose and Objectives

The course deals with advanced topics in modern computational biology focusing on “omics” technologies, computational analysis tools of biological data and mathematical modelling. Its purpose is to equip students that embark on PhD studies in areas related to biology with the basic knowledge and awareness of advanced concepts and techniques in specific topics, which would allow them to progress in their studies. It aims at introducing, on the one hand, students from diverse but not Biology BSc and MSc backgrounds to biological concepts, data and methods and, on the other hand, students from Biology BSc and MSc backgrounds to core mathematical and programming skills.

Learning Outcomes

By the end of the course, the students will receive hands-on knowledge on the state-of-the-art computational and mathematical modelling techniques. Specifically, they are expected to have a:

-  Good understanding and application of computational biology concepts relevant to this module and commonly used algorithms in bioinformatics, modelling and statistics;
-  Be able to write basic scripts and pipelines for automating and repeating analyses that make use of the taught techniques;
-  Be aware of the use of computers in studying mathematical functions and carrying out statistical tests;
-  Basic grasp of computer programming and biological data management;
-  Capacity to assess biological inferences that rest on computational, mathematical and statistical arguments;
- Understanding of how sound conclusions about the underlying processes using their knowledge of mathematics and statistics.

Prerequisites

None

Background Requirements

None

Course Content

Week 1: Advanced concepts of genes, genetics and genomics: modes of inheritance, chromosomal, somatic and mitochondrial disorders, complex trait disorders, linkage analysis for single gene and complex traits, linkage disequilibrium, animal models, physical mapping, the Human Genome Project, high-throughput sequencing, DNA and protein databases, principles of homology and motif identification.

Week 2: Bioinformatics: advanced tools for the analysis of biological data, DNA sequence analysis and annotation, DNA and protein alignment
algorithms and DNA/protein homology, identification and delineation of protein families, evolutionary processes, phylogenetic analysis of proteinsequences and residue conservation.

Week 3: Systems Biology: analysis of genomes (eukaryotic and microbial genetics), pathways and signalling networks, genome wide association studies, microbiomics, transcriptomics, proteomics and metabolomics.

Week 4: Biostatistics: probability theory, information theory, basic descriptive statistics, Bayesian and frequentist inference, descriptiveanalysis of large data sets and practical experience with R.

Week 5: Programming and Database Management: programming skills, basic computing concepts, program design, abstraction and modularity, Python / Perl / Javascript, relational databases and SQL.

Week 6: Mathematical modelling: statistical and dynamical modelling, numerical methods, model selection and parameter inference, sensitivityanalysis and stochastic processes.

Week 7: Epidemiological and population dynamics modelling: concepts of
infectious disease and epidemiology modelling, system complexities, modelling techniques to extract information from complex datasets, linear
regression, logistic regression, survival analysis, prediction of outcomes, early warning systems.

Practical 1 and essay write-up (weeks 1-4): The topics of the practical may vary from year-to-year and will focus on the analysis of genomes and population genomics data, RNA sequencing data and microbiome data.

Practical 2 and essay write-up (weeks 4-7): The topics of the practical may vary from year-to-year and will focus on mathematical and population dynamics modelling focusing on infectious disease epidemiology.

Guest lectures: a series of guest lectures from computational biologists on topics related to but extending knowledge beyond the lectures and
practicals, including multi-omics phylogenetic and network analyses, medical informatics, computational structural biology, in silico drug
discovery, and ethical issues in contemporary genetics.

Teaching Methodology

-  7 x 3-hour lectures/laboratories
-  6 guest lectures
-  6 practical work under instruction, towards solving problems part of the 2 marked assignments
-  2 follow-up practical work under remote guidance, towards solving problems part of the 2 marked assignments
-  2 assignment write-up in the form of essay/manuscript to be handed in at the end of week 4 and the end of week 7. Essays will be marked and returned to students with feedback.
-  1 formative assessment upon presentation of essays
-  2 journal clubs to discuss analysis methods, results and conclusions of research articles in the field

Bibliography

 Course notes, research articles
-  Understanding Bioinformatics by Marketa Zvelebil and Jeremy O. Baum, GS Garland Science Taylor & Francis Group.
-  Systems Biology: A Textbook by Edda Klipp, Wolfram Liebermeister, Christoph Wierling, and Axel Kowald, Wiley-VCH.
-  Bioinformatics Data Skills, Reproducible and Robust Research with Open Source Tools by Vince Buffalo
-  Bioinformatics with Python Cookbook by Tiago Antao
-  Stochastic Modelling for Systems Biology (Chapman & Hall/CRC Mathematical and Computational Biology) by Darren J. Wilkinson, CRC
Press, 2nd Edition.
-  Mathematical Models in Population Biology and Epidemiology by Fred Brauer and Carlos Castillo-Chavez, Texts in Applied Mathematics, Springer, 2nd Edition.

Assessment

Assessment will be done through marking of the two assignments developed and completed during the course in the form of essays/manuscripts. The final mark will be the average of individual marks for these essays. Formative assessment provided during the formal presentation of the results from these assignments will not count against the final mark and will aim to guide students in improving their scientific presentation skills on the subject.

Language

English