The human tissue-resident CCR5+ T cell compartment maintains protective and functional properties during inflammation.
Amanda S Woodward-DavisHayley N RoozenMatthew J DufortHannah A DeBergMartha A DelaneyFlorian MairJami R EricksonChloe K SlichterJulia D BerksonAlexis M KlockMatthias MackYu LwoAlexander KoRhonda M BrandIan Michael McGowanCarla J GreenbaumDouglas R DixonMartin PrlicPublished in: Science translational medicine (2020)
CCR5 is thought to play a central role in orchestrating migration of cells in response to inflammation. CCR5 antagonists can reduce inflammatory disease processes, which has led to an increased interest in using CCR5 antagonists in a wide range of inflammation-driven diseases. Paradoxically, these antagonists appear to function without negatively affecting host immunity at barrier sites. We reasoned that the resolution to this paradox may lie in the CCR5+ T cell populations that permanently reside in tissues. We used a single-cell analysis approach to examine the human CCR5+ T cell compartment in the blood, healthy, and inflamed mucosal tissues to resolve these seemingly contradictory observations. We found that 65% of the CD4 tissue-resident memory T (TRM) cell compartment expressed CCR5. These CCR5+ TRM cells were enriched in and near the epithelial layer and not only limited to TH1-type cells but also contained a large TH17-producing and a stable regulatory T cell population. The CCR5+ TRM compartment was stably maintained even in inflamed tissues including the preservation of TH17 and regulatory T cell populations. Further, using tissues from the CHARM-03 clinical trial, we found that CCR5+ TRM are preserved in human mucosal tissue during treatment with the CCR5 antagonist Maraviroc. Our data suggest that the human CCR5+ TRM compartment is functionally and spatially equipped to maintain barrier immunity even in the absence of CCR5-mediated, de novo T cell recruitment from the periphery.
Keyphrases
- dendritic cells
- regulatory t cells
- endothelial cells
- single cell
- induced apoptosis
- clinical trial
- oxidative stress
- induced pluripotent stem cells
- signaling pathway
- pluripotent stem cells
- endoplasmic reticulum stress
- bone marrow
- machine learning
- rna seq
- cell therapy
- high throughput
- big data
- ulcerative colitis
- working memory
- single molecule
- quality improvement
- cell proliferation
- open label
- artificial intelligence