Glasgow Bioinformatics Summer School 2025

We are currently planning the workshop for 2025. It is likely to happen in the last two weeks of August 2025 - save the date.

 

 

 

When:

Week 1 (Linux, R, Mapping, SNP's, RNA-Seq, single-cell)

3rd week of August 2025

Week 2 (bioinformatics of advanced single-cell transcriptomic)

Last week of August 2025

Applications will open in February 2025

Application Deadline: 01/07/2025

Topics:

First week (Bioinformatics of next-generation sequencing):

  •      Basics of Linux
  •      Introduction to R
  •      Introduction to next-generation sequencing
  •      Data visualization
  •      SNP analysis
  •      Transcriptomics: bulk RNA-Seq and single-cell RNA-Seq
  •      De novo assembly (alternative track to scRNA-Seq)
  •      Databases
  •      Data processing

Second week (advanced single cell)*

  •      Applied theory of scRNA-seq analysis methods
  •      Advanced R
  •      Integration of scRNA
  •      Pseudotime analysis
  •      Cell-cell communication
  •      Spatial transcriptomic
  •      TCR and BCR sequencing analysis
  •      Tips and tricks

Exepected cost if inflation stays low

Two weeks:  £1300 for academics / £2000 commercial **

One week: £750 for academics / £1200 commercial

How to apply: Places are assigned on a first-come, first-served basis upon receipt of the fee. Please contact sii-informatics@glasgow.ac.uk for the booking.

Cancellation Policy: Cancellations more than 30 days before the start date will incur a 30% cancellation fee. Cancellations less than 30 days before the start date cannot be refunded.

Participants are encouraged to attend the full week, daily, core hours 9:00-18:00h. We have 1-2 evening events per week.

* IMPORTANT:

If you wish to attend just week 2 (advanced single-cell), we expect you to have a basic knowledge of R and Seurat analysis of scRNA-Seq data.

The primary target audience is PhD students and postdocs from the life sciences.

** For those who book the two weeks:

1. You don't need to know any R before the course. However, we found that participants generally struggled with the second week if they didn't know any R. Therefore, we will give people the option to work on provided material in their own time on the Saturday between the two weeks.

2. On Sunday, we will do a day trip to explore the nature and culture of Scotland. Please let us know if you want to join (transport and activity costs are covered).

 

Full description

First week:

Next generation sequencing (NGS) and bioinformatics has become an essential tool in genetic and genomic analysis. It is increasingly important for experimental scientists to gain the bioinformatics skills required to assess and analyse the large volumes of sequencing data produced by next generation sequencers. With the ongoing omics initiatives, we would like to give PhD students and postdocs the opportunity to learn about NGS and bioinformatics.

This week-long course aims to provide experimental biologists working with omics data with (i) a comprehension of “bioinformatics” language and terminology, (ii) an understanding of  the underlying concepts (iii) hands-on experience in genomic-scale data analysis for

-          Linux: The operating system for most bioinformatics software. This part will also explain how to process data on the Glasgow high performance compute cluster (HPCC each participant will need an account, information to follow). This will allow participants to apply the knowledge they have gained in the future.

-          NGS mapping and variant calling: Learn how to map sequencing reads and visualize the data. Find copy number and sequence variants and understand the different types of variation.

-          Transcriptomics:

  • Analyse a dataset by comparing the transcriptome of a knock-out versus a wildtype parasite - from the mapping of short reads, visualization, differential expression up to GO enrichment!
  • Single cell RNA-Seq - basic introduction using Seurat and 10X Chromium data

-          R is a statistical package based on a Linux like syntax. Many tools for genomics and transcriptomics analysis are written in R.  We will explore using some of these tools and creating publication-ready figures in R

-          Databases: Get an overview of the most common databases and learn how to download published data or perform simple analysis on them.

The data used during the workshop will be derived from bacteria, single celled parasites and human or mouse, but the learning outcomes can be applied to other organisms.

At the end of the course you will have the opportunity to work on a larger task with a group to gain experience of applying the learning outcomes of the course independently.  If you wish to bring your own data for the group task, please contact the course organisers in advance.

Initially, participants will work from a virtual machine, which will be provided on a USB hard disc,  and can be taken away at the end of the course at no additional cost. Some exercises will be taught on a computer server to practice connecting to servers.

 

Second Week:

We encourage participants to do both weeks, but they can choose to do just one week. If you want to join us for only the second week we expect you to have basic knowledge of R, be able to perform a simple single cell analysis with Seurat and are able to do GO analysis.

The aim of the advanced scRNA-Seq week is to give the participants all the tools to allow a confident and full analysis of single cell data, based on the droplet systems, just as 10X Chromium.

The topics are

  • Understanding the fundamental basics of single-cell analysis: Through lectures we will teach how dimension reduction, integration, cell-cell communication, and pseudo time are implemented and the importance of various parameter selections for the user
  • Integration of dataset: Test and compare different integration methods and discuss the pros and cons
  • Differential expression: Discus which parameters are important and why different tools give different results - and how to deal with that.
  • Pseudo time: These methods are very powerful to understand the development of cells. We will compare different methods and discuss the different results.
  • Cell-cell interactions: What changes after perturbation? Does the communication between cells change, and how can we find these in our single-cell data?
  • Advanced R: It is important to understand the underlying data structure of the different packages and how one can take some shortcuts here and there - and maybe make nicer heatmaps.
  • Spatial transcriptomics: This field is developing rapidly, with the promise to merge the spatial information of cells with their transcription... we are going to figure this out.
  • Advanced Stuff: Mix and Match! We will have several short modules to work of which you can choose three:
    • SNP splitting - Split your samples based on mutations between individuals
    • Ambient RNA detection – What is ambient RNA and how/when do we remove this in our data?
    • Doublet finding tools - Which tools exist and how to deal with doublets.
    • CITE-seq - ADT/HTO are powerful, but how to include them into the analysis?
    • Pseudo bulk RNA-seq - Rather than doing differential expression at the single-cell level, be more robust, with pseudo bulk
    • Download existing data - Sounds easy, and it is once you know how to download a matrix of scRNA-Seq and integrate it in your code
    • Immune repertoire sequencing – How can we extract information about TCR/BCR and integrate that with our single-cell data?

The course finishes with a 1.5 days group task.

Please bring your own data, or papers of datasets you want to re-analysis. We will have several group tasks with the opportunity to discuss the different analysis steps with a wide range of data!

Compared to week one, you won't get a USB disc, but will first work on an R-server. But please bring your computer with you, as in an evening session (with some food) we will help you to install needed software on your computer.

Learning outcomes

After attending this course, participants should be able to:

  • Comfortably work with state-of-the-art bioinformatics software in a Linux-like environment
  • Have a good understanding of the application, opportunities, visualization and analysis of next-generation sequencing datasets
  • Integrate and query large-scale genomic and functional genomic databases to answer biology-related research questions and develop testable hypotheses
  • Experience analysing RNA-Seq and scRNA-Seq data
  • Ideas around integrative analysis and how to run basic analysis in R

Please note: The practical sessions will be taught exclusively through Unix/Linux. Knowledge in Linux is helpful, but not required. The course aims to provide a hands-on introduction to bioinformatics for next-generation sequencing and should not be considered a complete education in the theoretical and mathematical foundations of the topics. This course is aimed at applicants solely interested in the analysis of NGS data and bioinformatics.

About the organisers

Thomas Otto is a Senior lecturer for Bioinformatics at the University of Glasgow. He has a vast experience in NGS genomics, from the basics of sequencing technologies, quality control of data, genome and transcriptomic projects and genotype to phenotype projects.

Through his career, he taught many workshops on NGS genomics, including de novo assembly, Introduction to bioinformatics (Wellcome Trust advanced courses (WTAC)), more applied workshops like working with pathogen genomes or working with parasite databases. He also teaches at the University of Glasgow data analysis, R and transcriptomics for undergraduate and masters students.

Kathryn Crouch is a team leader for the bioinformatics team at the Wellcome Centre for  Integrative Parasitology, University of Glasgow. Her background is in comparative immunology and she worked in the pharmaceutical industry for several years before taking up her current position. 

In her current role, she manages a team providing advice and computational analysis to Wellcome Centre members working with NGS and other high throughput data in eukaryotic pathogens. She also develops software for the VEuPathDB suite of databases (https://veupathdb.org/). Teaching experience includes running an applied bioinformatics module on the MSc Bioinformatics at the University of Glasgow for the last three years, and contributing to applied courses including the Wellcome Trust Advanced Courses Working with Parasite Database Resources workshop for the last six years.

Kathryn and Thomas have run the annual first week of the Bioinformatics summer school together since 2018. Sadly no Kathryn this year..

 

Olympia Hardy graduated from the University of Southampton with a degree in Biomedical Science before undertaking an MSc in Bioinformatics at the University of Glasgow in 2019. She then worked as a bioinformatician focusing on the immune response in COVID-19.

Her PhD project aims to utilise bioinformatics to analyse single-cell RNA sequencing data to elucidate the evolution of cell-cell interactions that may play a key role in early disease onset to late-stage rheumatoid (RA) and psoriatic arthritis (PsA) and other inflammatory diseases.

She is currently developing an interactive visualisation method called cellXplore that will allow users to investigate cell-cell interactions without the need for prior bioinformatics experience. With this she has applied her knowledge of cell-cell interactions and single-cell to elucidate inflammatory diseases such as COVID-19, parasite infection and atlas-level data consisting of various chronic and acute diseases.

Her prior teaching experience consists of demonstrating on various bioinformatic modules run at the University of Glasgow since 2020 in addition to the Bioinformatics Summer School in previous years.

 

Ross Laidlaw graduated from the University of Glasgow in 2020 with an honours degree in Immunology. During his honours project, he discovered his love (and hate) relationship with single-cell RNA-seq analysis, where he benchmarked various trajectory inference packages and investigated the transcriptomic changes that occur in immune cells during malaria infection and hypertension.

Following his undergraduate studies, Ross began a PhD in the MRC Precision Medicine DTP program, where his project is focused on using transcriptomic analysis techniques to investigate parasite lifecycle transitions. During this project, he has made TrAGEDy, a tool for aligning scRNA-seq trajectories between conditions, analysed a model of insect stage development of the parasite Trypanosoma brucei and helped craft the first scRNA-seq atlas of Trypanosome cruzi in vitro development.

Ross and Olympia have been teaching assistants at the University of Glasgow Bioinformatics summer school for four years now, and starting last year, they created and led the Advanced Single Cell course of the summer school.