Submitted by Dr T. Dougan on Tue, 20/02/2018 - 20:55
The results suggest that treatment options for typhoid treatment are running out and preventative strategies are needed.
“We have used genetic sequencing to uncover how this particular strain of typhoid became resistant to several key antibiotics. Sporadic cases of typhoid with these levels of antimicrobial resistance have been seen before, but this is the first time we’ve seen an ongoing outbreak – which is concerning.”
Professor Gordon Dougan, a senior author from the Wellcome Sanger Institute and University of Cambridge Department of Medicine
The genetic cause behind a strain of typhoid’s resistance to five classes of antibiotics has been uncovered by scientists at the Wellcome Sanger Institute and their collaborators at Public Health England and Aga Khan University, Pakistan. There is currently a major outbreak of typhoid fever in Pakistan, and there was a case in the UK following air travel, which has been isolated and treated. This study shows the typhoid strain causing the outbreak acquired an additional piece of DNA to become resistant to multiple antibiotics, including a third-generation antibiotic.
The results, published today (20 February) in mBio suggest that treatment options are running out for typhoid, and there is an urgent need for preventative strategies including vaccines.
Salmonella Typhi in Pakistan have developed greater drug resistance by acquiring a DNA plasmid encoding further antibiotic resistance genes from another bacteria. Image credit: Dave Goulding, Wellcome Sanger Institute
Typhoid fever is a bacterial infection caused by the bacterium Salmonella enterica serovar Typhi. It is highly contagious, and spreads through the human population in areas with poor water sanitation when contaminated food or water is consumed. Symptoms include fever, stomach pain, headache and constipation or diarrhoea and, if left untreated, it can become fatal.
Currently, an outbreak of drug-resistant typhoid is spreading through Pakistan and an emergency vaccination campaign is underway.
The outbreak began in November 2016, and was immediately recognised and reported to provincial public health authorities in Pakistan, where investigation into possible sources and control measures including use of a vaccine are ongoing. Public health alerts helped physicians recognise cases of typhoid that were resistant to ceftriaxone, an antibiotic reserved to treat multidrug-resistant infections. This strain was resistant to five antibiotics in total, a higher level of resistance than previously seen. The doctors treated the infections with the few remaining antibiotic options.
In the spring of 2017, collaborators Professor Rumina Hasan and Dr Sadia Shakoor from the Aga Khan University in Pakistan contacted the Wellcome Sanger Institute to genetically analyse the outbreak. Sanger Institute scientists performed whole genome sequencing of typhoid samples from Pakistan to investigate the genetic cause behind its high level of antibiotic resistance.
The team discovered that the typhoid outbreak was caused by strain H58, a strain known to be associated with multidrug resistance. When researchers looked further, they found this strain of H58 had gained an extra strand of bacterial DNA – a plasmid – that encoded for additional antibiotic resistance genes. The typhoid possibly picked up the plasmid from E. coli.
Scientists at Public Health England identified a strain of typhoid with the same high levels of resistance from an individual in the UK who had recently returned from Pakistan. Genomic comparison revealed that it was identical to the outbreak strain, meaning the outbreak had reached the UK, where it has been isolated and treated.
