Scientists at the University of Liverpool have identified a single genetic change in Salmonella that is playing a key role in the devastating epidemic of bloodstream infections currently killing around 400,000 people each year in sub-Saharan Africa.
Invasive non-typhoidal Salmonellosis (iNTS) occurs when Salmonella bacteria, which normally cause gastrointestinal illness, enter the bloodstream and spread through the human body. The African iNTS epidemic is caused by a variant of Salmonella Typhimurium (ST313) that is resistant to antibiotics and generally affects individuals with immune systems weakened by malaria or HIV.
In a new study published in the Proceedings of the National Academy of Sciences, a team of researchers led by Professor Jay Hinton at the University’s Institute of Integrative Biology has identified a specific genetic change, or single-nucleotide polymorphism (SNP), that helps the African Salmonella to survive in the human bloodstream.
Professor Hinton explained: “Pinpointing this single letter of DNA is an exciting breakthrough in our understanding of why African Salmonella causes such a devastating disease, and helps to explain how this dangerous type of Salmonella evolved.”
SNPs represent a change of just one letter in the DNA sequence and there are thousands of SNP differences between different types of Salmonella. Until now, it has been hard to link an individual SNP to the ability of bacteria to cause disease.
Using a type of RNA analysis called transcriptomics, the scientists identified SNPs that affected the level of expression of important Salmonella genes. After studying 1000 different SNPs, they found a single nucleotide difference that is unique to the African ST313 strain and causes high expression of a virulence factor called PgtE that prevents Salmonella being killed in the bloodstream.
The scientists then used an advanced genetic technique to switch the SNP found in the African strain to the version found in the type of Salmonella that causes food poisoning and gastroenteritis globally. Finally, they used an animal infection model to show that the bacteria with the altered SNP had lost their ability to cause disease.
Professor Hinton added: “We’ve developed a new investigative approach to understand bacterial infection, which is the culmination of six years of work. This combination of genomics and transcriptomics could bring new insights to other important pathogens, and prepare us for future epidemics.”
Professor Melita Gordon, a University of Liverpool clinician-scientist working in Malawi, who was involved in the project, said: “The ability of iNTS Salmonella strains to cause such serious disease leads to devastating and frequently fatal consequences for very young children, and for adults who may be the chief breadwinners in their homes and communities. We see iNTS disease placing an enormous burden on thinly-stretched local health facilities and hospitals in Malawi, particularly because diagnosis is difficult, and treatment options are limited. It is now urgent that a vaccine is developed to combat this dangerous infection.”
The study received funding support from the Wellcome Trust and was carried out in collaboration with the Liverpool School of Tropical Medicine and the University of Birmingham.
The paper ‘The role of a single non-coding nucleotide in the evolution of an epidemic African clade of Salmonella’ is published in PNAS [https://doi.org/10.1073/pnas.1714718115]