Welcome to the third installment of our new regular monthly slot where we report on research from the world of immunology, highlighting work from BSI members that has hit the headlines over the past four weeks.
Genetic link to flu transmission in chickens
New work, published in the journal Scientific Reports, shows that some chickens may have genes that significantly reduce their susceptibility to spreading and catching flu. Researchers at the Pirbright Institute, along with colleagues from Francis Crick Institute and University of Oxford, examined two genetically distinct lines of chickens that differ in their susceptibility to catching flu. They found that, within the resistant line, any bird that did catch flu only shed the virus through its respiratory tract for a short period. In comparison susceptible birds shed the virus through their respiratory tract for longer as well as shedding virus through their faeces, a key transmission route for spreading the flu virus within bird populations.
BSI member and lead researcher Dr Colin Butter said, “It is important for us to understand how different genetic lines of birds react to influenza viruses, so that we can begin to understand the spread of the disease. Our results are valuable in emphasising the important role a ‘host’ plays in the spread of avian flu, and also in highlighting a number of factors relating to the chain of infection and control mechanisms which are affected by the route of infection.” The team hope these findings will pave the way for more research into the precise biological mechanisms behind genetic resistance, which may have major implications for poultry breeding, as well as human flu treatments, in the future.
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Read the full article: Ruiz-Hernandez et al. 2016 Scientific Reports doi: 10.1038/srep26787
Markers of neutrophil activity may help sepsis diagnosis in severe burn patients
The rapid diagnosis of sepsis remains a major challenge in patients with severe burns whose injury may mask many of the classic diagnostic biomarkers. It is vital that sepsis is diagnosed as quickly as possible as any delay can significantly increase the risk of death. Researchers from the University of Birmingham set out to determine if biomarkers of neutrophil function may be accurate in predicting which patients will go on to develop sepsis. Writing in the Annals of Surgery, the team studied markers of neutrophil activity and function, a key type of white blood cells which responds to immediate infection threats. Through studying 62 patients with severe burns, they found that immature granulocyte count, neutrophil phagocytosis and plasma cell free DNA show significant potential as biomarkers.
BSI member and study author Professor Janet Lord said, “Our data showed that immature granulocyte count could accurately discriminate between septic and non-septic patients, even with the complications that systemic inflammatory response syndrome has caused for other potential biomarkers. In addition to this, when we used a combination of two or more of our biomarkers, the discriminatory power was further enhanced.” The team now plan to see if using these markers to decide which patients should receive antibiotics at an earlier stage results in reduced sepsis levels.
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Read the full article: Hampson et al. 2016 Annals of Surgery doi: 10.1097/SLA.0000000000001807
How our immune system recognises pathogens
Every antigen receptor is composed of three regions – V (variable), D (diversity) and J (joining) – each of which have multiple versions. The shuffling, or recombination, of these allows the immune system to recognise the vast array of pathogens that it encounters. Researchers at the Babraham Institute have developed a new technique to study this process called VDJ sequencing (VDJ-seq), a DNA-based next-generation-sequencing technique that quantitatively profiles recombination products.
Writing in Cell Reports, the team used this technique to take a look at the V gene found in an immune cell type in mice. They found that not all V segments were used with the same frequency, implying the involvement of complex regulatory mechanisms with epigenetic features.
“Understanding the VDJ recombination process is important because it is the first determinant of receptor diversity, said BSI member and study author Professor Anne Corcoran. “Having a precise readout of which V, D and J segments are used advances our understanding of the process of recombination and how this is regulated. These findings have implications for immune disorders and aberrant VDJ recombination in cancer.”
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Read the full article: Bolland et al. 2016 Cell Reports DOI: http://dx.doi.org/10.1016/j.celrep.2016.05.020
Image credits: Chicken, credit: Steven Turner/Flickr CC-BY 2.0; Credit: University of Edinburgh, Wellcome Images CC BY-NC-ND 2.0