Professor Wim Timens, UMCG

First lung map uncovers new insights into asthma

Understanding lung cells and their signals could help towards finding new asthma drug targets

For the first time, researchers have mapped the building blocks of the human lungs and airways, in both asthma patients and normal people. The research from the Wellcome Sanger Institute, University Medical Center Groningen, Open Targets, GSK and collaborators revealed the identity of each cell type, creating the first draft Human Cell Atlas of the lung. They also discovered an entirely new cell state that produces mucus in asthma patients.

Reported today (17 June) in Nature Medicine, the maps reveal the differences between asthmatic and normal airways and identify how cells in the lung communicate with each other. Understanding the cells and their signals could lead to finding new drug targets for treating asthma.

Asthma is a common lung condition that makes breathing difficult and triggers coughing, wheezing and shortness of breath. It is caused by swelling of the tubes that carry air in and out of the lungs making it difficult to get enough oxygen. Asthma affected over 350 million people worldwide in 2015, and over 5 million people* in the UK are currently receiving treatment for asthma.

While it is often manageable with medication, asthma can cause ongoing problems and there is the risk of severe, life-threatening asthma attacks. A better understanding of healthy lung cells and the differences with asthmatic lungs is required to develop new effective medications.

To explore cell types within normal lungs and upper airways, researchers used single cell technology to study samples from 17 people. They analysed more than 36,000 individual cells from the nasal area and from three different areas of the lung. This allowed researchers to see exactly which genes were active in each cell and identify the specific cell type.

The researchers then detected the different cell types and activities in lung samples from six asthma patients, comparing them to normal lungs. They discovered there were clear differences between the cells in normal and asthmatic lungs. One symptom of asthma is an overproduction of mucus. However, not all the cells responsible for this were known. The researchers discovered a new mucus-creating cell state – the muco-cilliated state – in asthmatic lungs, that had not been seen before.

“We have generated a detailed anatomical map of the respiratory airways, producing the first draft human lung cell atlas from both normal and asthmatic people. This has given us a better definition of the cell types in asthmatic lungs, and allowed us to discover an entirely new cell state in asthmatic patients that produces mucus.”

Dr Felipe Vieira Braga A first author on the paper from the Wellcome Sanger Institute and Open Targets 

The study revealed large differences between normal and asthmatic lungs, in the cells and how they communicated with each other. The asthmatic lungs had many more inflammatory Th2 cells, which sent the vast majority of cellular signals in asthma, compared with a broad range of cell communications in normal lungs.

“We already knew that inflammatory Th2 cells played a role in asthma, but only now do we see how great that influence is. In normal people, all kinds of cells communicate with each other in order to keep the airways functioning well. But in asthma patients, almost all of those interactions are lost. Instead of a network of interactions, in asthma the inflammatory cells seem to completely dominate the communication in the airways.”

Dr Martijn Nawijn A senior author from University Medical Center Groningen

Knowing the types of cells in asthmatic lungs and how they communicate, could help researchers seek new drug targets that could prevent the cells from responding to the inflammatory signals and help restore normal lung function.

The atlases also revealed that location was important for the lung cells. The study showed that cells in different areas of the lung had very different cellular activities. This has further implications for studying drug targets and designing drug trials.

“As part of the Human Cell Atlas initiative, we have created the first comprehensive cellular map of the lungs. Our large-scale, open access data reveals the activity of different cells, their communication pathways and locations. The lung cell atlas will provide a great resource for further lung research and we hope that it will enable the identification of potential new therapeutic targets for asthma relief.”

Dr Sarah Teichmann A senior author from the Wellcome Sanger Institute, University of Cambridge and Open Targets, and co-chair of the Human Cell Atlas Organising Committee 

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Notes to Editors

Publication:

F. Vieira Braga & G. Kar et al. (2019) A cellular census of human lungs identifies novel cell states in health and in asthma. Nature Medicine. DOI: 10.1038/s41591-019-0468-5
 
*Asthma statistics for the UK from https://www.asthma.org.uk/about/media/facts-and-statistics/
5.4 million people in the UK are currently receiving treatment for asthma: 1.1 million children (1 in 11) and 4.3 million adults (1 in 12).

Funding:

This work was supported by Open Targets, an open innovation public-private partnership, GlaxoSmithKline, Wellcome and other funders. Please see the paper for the full list of funders.

Selected websites

  • Open Targets

    Open Targets is a pioneering public-private collaboration that aims to transform drug discovery through the systematic identification and prioritisation of drug targets to improve the success rate for developing new medicines. The consortium is a unique, pre-competitive partnership between pharmaceutical companies and not-for-profit research institutes. The partners are GSK, Biogen, Takeda, Celgene, Sanofi, the Wellcome Sanger Institute and the EMBL’s European Bioinformatics Institute (EMBL-EBI). Open Targets combines the skills, knowledge and technologies of its partner organisations, offering a critical mass of expertise that does not exist in any single institution. Large-scale genomic experiments and computational techniques developed in the public domain are blended with formal pharmaceutical R&D approaches to identify causal links between targets, pathways and diseases. This enables the partners to systematically identify drug targets, and prioritise them for further exploration. Find more at https://www.opentargets.org/science/ or follow @targetvalidate

  • University Medical Center Groningen

    The University Medical Center Groningen (UMCG) is one of the largest academic hospitals in the Netherlands and hosts the medical faculty of the University of Groningen, an international top-100 research university. Research at the UMCG is characterized by both fundamental and translational biomedical research.  Within the UMCG, the Groningen research Institute on Asthma and COPD (GRIAC) focuses on multidisciplinary, translational research into respiratory disease; its inception, remission and treatment.

    https://www.umcg.nl/EN/corporate/The_University_Medical_Center/Paginas/default.aspx

  • The Wellcome Sanger Institute

    The Sanger is one of the world’s leading genome and biodata institutes. Through its ability to conduct research at scale, it is able to engage in bold and long-term exploratory projects that are designed to influence and empower science globally. Institute research findings, generated through its own research programmes and through its leading role in international consortia, are being used to develop new diagnostics and treatments for human disease and to understand life on Earth. Find out more at www.sanger.ac.uk or follow @sangerinstitute on Twitter, Facebook, LinkedIn and on our Blog.

  • About Wellcome

    Wellcome exists to improve health by helping great ideas to thrive. We support researchers, we take on big health challenges, we campaign for better science, and we help everyone get involved with science and health research. We are a politically and financially independent foundation. wellcome.org