Study finds cause of pulmonary fibrosis in failure of stem cells that repair lungs

The study is a major step toward understanding and one day treating pulmonary fibrosis, which affects about 100,000 people in the U.S. The disease often is called idiopathic pulmonary fibrosis because, in most cases, the cause cannot be found. While the prognosis is unpredictable, patients typically survive only three to five years after diagnosis, according to the U.S. National Library of Medicine.
"Pulmonary fibrosis slowly robs patients of breath and finally life," said Paul W. Noble, MD, professor and chair of the Department of Medicine and director of the Women's Guild Lung Institute at Cedars-Sinai. "In our study, we identified novel potential pathways to finding treatments for this relentless disease." Noble was the study's principal investigator.
The investigators focused on alveoli, the small air sacs at the ends of lung airways. In the alveoli, oxygen and carbon dioxide are exchanged with blood during respiration. Epithelial cells that line the alveoli also make a substance that helps keep the airspaces open. In pulmonary fibrosis, these epithelial cells become abnormal, and fibrous tissue builds up in the lungs, causing severe scarring. Researchers don't know why this scarring process happens.
The Cedars-Sinai research team found an answer in special stem cells known as AEC2s that are found in adult lungs and are critical to repairing and regenerating epithelial cells. When viral infections, pollution or other injuries damage lung tissue, AEC2 cells come to the rescue.
In people with pulmonary fibrosis, something goes wrong with AEC2 cells, the study found. Compared with lung tissue of disease-free individuals, lung tissue from patients with pulmonary fibrosis had far fewer AEC2 cells, and those that remained were less able to renew themselves. Surfaces of these cells had lower concentrations of hyaluronan, a chemical substance that promotes tissue repair and renewal. Further, in laboratory mice, the team found that by deleting this substance, they could produce the type of scarring found in pulmonary fibrosis after lung injury.
"These findings are the first published evidence that idiopathic pulmonary fibrosis is primarily a disease of AEC2 stem cell failure," said Carol Liang, MD, assistant professor of Medicine at Cedars-Sinai and the study's first author. "In further studies, we will explore how the loss of hyaluronan promotes fibrosis and how it might be restored to cell surfaces. These endeavors could lead to new therapeutic approaches."
One promising approach may be to develop drugs that stimulate the reproduction of AEC2 cells in the lungs of patients who lack enough of these cells, Noble said. "The exciting aspect is that we have learned how to isolate these stem cells from diseased lungs. We can use these cells to create tiny 'lungs in a dish' as tools for drug development," he explained.
In an accompanying commentary in Nature Medicine, Paul F. Mercer, PhD, and Rachel C. Chambers, PhD, from the University College London in England noted another novel finding from this study. They said it identifies a new link between innate immune receptors, which help mobilize the immune system to fight bacterial invaders, and hyaluronan. This link, which promotes normal AEC2 renewal, is lost in pulmonary fibrosis, the study showed.

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This can be a methylated DNA molecule. DNA methylation performs an vital function for epigenetic gene regulation in improvement and most cancers. Credit score: Christoph Bock/CeMM     Scientists have established complete maps of the human epigenome, shedding gentle on how the physique regulates which genes are lively wherein cells. During the last 5 years, a worldwide consortium of scientists has established epigenetic maps of two,100 cell sorts. Inside this coordinated effort, the CeMM Analysis Heart for Molecular Drugs contributed detailed DNA methylation maps of the growing blood, opening up new views for the understanding and remedy of leukemia and immune ailments. One of many nice mysteries in biology is how the numerous completely different cell sorts that make up our our bodies are derived from a single cell and from one DNA sequence, or genome. Now we have discovered rather a lot from learning the human genome, however have solely partially unveiled the processes underlying cell willpower. The id of every cell kind is basically outlined by an instructive layer of molecular annotations on prime of the genome -- the epigenome -- which acts as a blueprint distinctive to every cell kind and developmental stage. Not like the genome the epigenome adjustments as cells develop and in response to adjustments within the surroundings. Defects within the components that learn, write, and erase the epigenetic blueprint are concerned in lots of ailments. The excellent evaluation of the epigenomes of wholesome and irregular cells will facilitate new methods to diagnose and deal with numerous ailments, and in the end result in improved well being outcomes. A set of 41 coordinated papers now revealed by scientists from throughout the Worldwide Human Epigenome Consortium (IHEC) sheds gentle on these processes, taking world analysis within the subject of epigenomics a serious step ahead. These papers symbolize the newest work of IHEC member tasks from Canada, the European Union, Germany, Japan, Singapore, South Korea, and america. Three of those papers have been coordinated by Christoph Bock at CeMM. The most recent examine from Christoph Bock's group, revealed at the moment within the journal Cell Stem Cell, charts the epigenetic panorama of DNA methylation in human blood. Led by CeMM scientists Matthias Farlik and Florian Halbritter along with Fabian Müller from Max Plank Institute for Informatics, this examine highlights the dynamic nature of the epigenome within the improvement of human blood. Our physique produces billions of blood cells every single day, which develop from a couple of thousand stem cells on the prime of a fancy hierarchy of blood cells. Utilizing the most recent sequencing and epigenome mapping expertise, Bock's group now unraveled a blueprint of blood improvement that's encoded within the DNA methylation patterns of blood stem cells and their differentiating progeny. This success was made potential by shut worldwide cooperation of European scientists: Blood donations of British volunteers have been sorted by cell kind by the group of Mattia Frontini on the College of Cambridge. These samples have been shipped to Austria, the place CeMM scientists carried out the epigenome mapping. All information have been then processed in Germany on the Max Plank Institute for Informatics and collectively analyzed by scientists at CeMM and on the Max Plank Institute for Informatics. The results of the mixed effort of Bock's group and lots of different members of IHEC is an in depth map of the human epigenome, just like a three-dimensional mountain panorama: The stem cells reside on the mountain prime, with valleys of mobile differentiation descending in lots of instructions. Because the cells differentiate, they choose considered one of a number of epigenetically outlined routes and comply with it downhill, ultimately arriving at one particular valley, similar to a specialised cell kind. Cells can not simply escape these valleys, which supplies robustness and safety in opposition to ailments such most cancers. Two different research by Christoph Bock's group have been revealed earlier this 12 months and showcase how researchers are looking for to make the most of epigenetic data for drugs. For example, sure routes of differentiation are jammed in leukemia, such that cells can now not attain their vacation spot and take unsuitable turns as an alternative. Surveillance of these cells by epigenetic exams can contribute to a extra exact prognosis of leukemia -- medical exams of this method are ongoing. "The epigenetic map of the human blood helps us perceive how leukemia develops and which cells drive the illness," says Christoph Bock. That is related to most cancers diagnostics and personalised drugs, and it supplies a compass for future efforts aiming to reprogram the epigenome of particular person cells, for instance by erasing vital epigenetic alterations from leukemia cells.