Researchers
at UC Davis have made some surprising discoveries about the body's
initial responses to HIV infection. Studying simian immunodeficiency
virus (SIV), the team found that specialized cells in the intestine
called Paneth cells are early responders to viral invasion and are the
source of gut inflammation by producing a cytokine called interleukin-1
beta (IL-1β).
Though aimed at the presence of virus, IL-1β causes breakdown of the
gut epithelium that provides a barrier to protect the body against
pathogens. Importantly, this occurs prior to the wide spread viral
infection and immune cell killing. But in an interesting twist, a
beneficial bacterium, Lactobacillus plantarum, helps mitigate the
virus-induced inflammatory response and protects gut epithelial barrier.
The study was published in the journal PLoS Pathogens.
One of the biggest obstacles to complete viral eradication and immune recovery is the stable HIV reservoir in the gut. There is very little information about the early viral invasion and the establishment of the gut reservoir.
"We want to understand what enables the virus to invade the gut, cause inflammation and kill the immune cells," said Satya Dandekar, lead author of the study and chair of the Department of Medical Microbiology and Immunology at UC Davis.
"Our study has identified Paneth cells as initial virus sensors in the gut that may induce early gut inflammation, cause tissue damage and help spread the viral infection. Our findings provide potential targets and new biomarkers for intervening or blocking early spread of viral infection," she said.
In the study, the researchers detected a very small number of SIV infected cells in the gut within initial 2.5 days of viral infection; however, the inflammatory response to the virus was playing havoc with the gut lining. IL-1β was reducing the production of tight-junction proteins, which are crucial to making the intestinal barrier impermeable to pathogens. As a result, the normally cohesive barrier was breaking down.
Digging deeper, the researchers found the inflammatory response through IL-1β production was initiated in Paneth cells, which are known to protect the intestinal stem cells to replenish the epithelial lining. This is the first report of Paneth cell sensing of SIV infection and IL-1β production that links to gut epithelial damage during early viral invasion. In turn, the epithelial breakdown underscores that there's more to the immune response than immune cells.
"The epithelium is more than a physical barrier," said first author Lauren Hirao. "It's providing support to immune cells in their defense against viruses and bacteria."
The researchers found that addition of a specific probiotic strain, Lactobacillus plantarum, to the gut reversed the damage by rapidly reducing IL-1β, resolving inflammation, and accelerating repair within hours. The study points to interesting possibilities of harnessing synergistic host-microbe interactions to intervene early viral spread and gut inflammation and to mitigate intestinal complications associated with HIV infection.
"Understanding the players in the immune response will be important to develop new therapies," said Hirao. "Seeing how these events play out can help us find the most opportune moments to intervene."
One of the biggest obstacles to complete viral eradication and immune recovery is the stable HIV reservoir in the gut. There is very little information about the early viral invasion and the establishment of the gut reservoir.
"We want to understand what enables the virus to invade the gut, cause inflammation and kill the immune cells," said Satya Dandekar, lead author of the study and chair of the Department of Medical Microbiology and Immunology at UC Davis.
"Our study has identified Paneth cells as initial virus sensors in the gut that may induce early gut inflammation, cause tissue damage and help spread the viral infection. Our findings provide potential targets and new biomarkers for intervening or blocking early spread of viral infection," she said.
In the study, the researchers detected a very small number of SIV infected cells in the gut within initial 2.5 days of viral infection; however, the inflammatory response to the virus was playing havoc with the gut lining. IL-1β was reducing the production of tight-junction proteins, which are crucial to making the intestinal barrier impermeable to pathogens. As a result, the normally cohesive barrier was breaking down.
Digging deeper, the researchers found the inflammatory response through IL-1β production was initiated in Paneth cells, which are known to protect the intestinal stem cells to replenish the epithelial lining. This is the first report of Paneth cell sensing of SIV infection and IL-1β production that links to gut epithelial damage during early viral invasion. In turn, the epithelial breakdown underscores that there's more to the immune response than immune cells.
"The epithelium is more than a physical barrier," said first author Lauren Hirao. "It's providing support to immune cells in their defense against viruses and bacteria."
The researchers found that addition of a specific probiotic strain, Lactobacillus plantarum, to the gut reversed the damage by rapidly reducing IL-1β, resolving inflammation, and accelerating repair within hours. The study points to interesting possibilities of harnessing synergistic host-microbe interactions to intervene early viral spread and gut inflammation and to mitigate intestinal complications associated with HIV infection.
"Understanding the players in the immune response will be important to develop new therapies," said Hirao. "Seeing how these events play out can help us find the most opportune moments to intervene."
Journal Reference:
- Lauren A. Hirao, Irina Grishina, Olivier Bourry, William K. Hu, Monsicha Somrit, Sumathi Sankaran-Walters, Chris A. Gaulke, Anne N. Fenton, Jay A. Li, Robert W. Crawford, Frank Chuang, Ross Tarara, Maria L. Marco, Andreas J. Bäumler, Holland Cheng, Satya Dandekar. Early Mucosal Sensing of SIV Infection by Paneth Cells Induces IL-1β Production and Initiates Gut Epithelial Disruption. PLoS Pathogens, 2014; 10 (8): e1004311 DOI: 10.1371/journal.ppat.1004311
No comments:
Post a Comment