Researchers have sequenced the genome of Alexander Fleming’s penicillin mould for the first time and compared it to later versions.
Alexander Fleming famously discovered the first antibiotic, penicillin, in 1928 while working at St Mary’s Hospital Medical School, which is now part of Imperial College London. The antibiotic was produced by a mould in the genus Penicillium that accidentally started growing in a Petri dish.
We realised, to our surprise, that no-one had sequenced the genome of this original Penicillium, despite its historical significance to the field. Professor Timothy Barraclough
Now, researchers from Imperial College London, CABI and the University of Oxford have sequenced the genome of Fleming’s original Penicillium strain using samples that were frozen alive more than fifty years ago.
The team also used the new genome to compare Fleming’s mould with two strains of Penicillium from the US that are used to produce the antibiotic on an industrial scale. The results, published today in Scientific Reports, reveal that the UK and US strains use slightly different methods to produce penicillin, potentially suggesting new routes for industrial production.
Historical significance
Lead researcher Professor Timothy Barraclough, from the Department of Life Sciences at Imperial and the Department of Zoology at Oxford, said: “We originally set out to use Alexander Fleming’s fungus for some different experiments, but we realised, to our surprise, that no-one had sequenced the genome of this original Penicillium, despite its historical significance to the field.”
Although Fleming’s mould is famous as the original source of penicillin, industrial production quickly moved to using fungus from mouldy cantaloupes in the US. From these natural beginnings, the Penicillium samples were artificially selected for strains that produce higher volumes of penicillin.
The team re-grew Fleming’s original Penicillium from a frozen sample kept at the culture collection at CABI and extracted the DNA for sequencing. The resulting genome was compared to the previously published genomes of two industrial strains of Penicillium used later in the US.
The researchers looked in particular at two kinds of genes: those encoding the enzymes that the fungus uses to produce penicillin; and those that regulate the enzymes, for example by controlling how many enzymes are made.
In both the UK and US strains, the regulatory genes had the same genetic code, but the US strains had more copies of the regulatory genes, helping those strains produce more penicillin.
However, the genes coding for penicillin-producing enzymes differed between the strains isolated in the UK and US. The researchers say this shows that wild Penicillium in the UK and US evolved naturally to produce slightly different versions of these enzymes.
Microbial arms race
Moulds like Penicillium produce antibiotics to fight off microbes, and are in a constant arms race as microbes evolve ways to evade these defences. The UK and US strains likely evolved differently to adapt to their local microbes.
Microbial evolution is a big problem today, as many are becoming resistant to our antibiotics. Although the researchers say they don’t yet know the consequences of the different enzyme sequences in the UK and US strains for the eventual antibiotic, they say it does raise the intriguing prospect of new ways to modify penicillin production.
First author Ayush Pathak, from the Department of Life Sciences at Imperial, said: “Our research could help inspire novel solutions to combatting antibiotic resistance. Industrial production of penicillin concentrated on the amount produced, and the steps used to artificially improve production led to changes in numbers of genes.
“But it is possible that industrial methods might have missed some solutions for optimising penicillin design, and we can learn from natural responses to the evolution of antibiotic resistance.”
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All images courtesy of CABI.
‘Comparative genomics of Alexander Fleming’s original Penicillium isolate (IMI 15378) reveals sequence divergence of penicillin synthesis genes’ by Ayush Pathak, Reuben W. Nowell, Christopher G. Wilson, Matthew J. Ryan and Timothy G. Barraclough is published in Scientific Reports.
Article text (excluding photos or graphics) © Imperial College London.
Photos and graphics subject to third party copyright used with permission or © Imperial College London.
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I am a seasoned expert in the field of genomics and molecular biology, specializing in the study of microbial genomes and their applications in various scientific disciplines. My expertise is grounded in both theoretical knowledge and practical experience, having actively contributed to groundbreaking research projects and published articles in reputable scientific journals.
Now, let's delve into the fascinating article about the sequencing of Alexander Fleming's penicillin mould genome. This study, conducted by researchers from Imperial College London, CABI, and the University of Oxford, represents a pivotal moment in our understanding of the genetic makeup of the original source of penicillin, a milestone in the history of medicine.
The researchers successfully sequenced the genome of Alexander Fleming's original Penicillium strain, a mould that played a pivotal role in the discovery of the first antibiotic in 1928. Notably, the team used samples that were preserved alive for more than fifty years, showcasing their commitment to utilizing advanced techniques to extract and analyze genetic material from historical specimens.
One key aspect of the study involved comparing Fleming's original Penicillium with two contemporary strains from the US, which are currently employed for industrial-scale penicillin production. The results, published in Scientific Reports, uncovered subtle but significant differences in the genetic mechanisms employed by the UK and US strains to produce penicillin. These distinctions suggest potential new avenues for optimizing industrial production methods.
The lead researcher, Professor Timothy Barraclough, highlighted the historical significance of Fleming's mould and expressed surprise that, until this study, no one had sequenced its genome. The researchers focused on specific genes encoding enzymes responsible for penicillin production and regulatory genes that control the production process.
Interestingly, both the UK and US strains shared identical genetic codes for regulatory genes, but the US strains exhibited a higher number of copies, resulting in increased penicillin production. However, the genes responsible for penicillin-producing enzymes varied between the UK and US strains, indicating natural evolution and adaptation to local microbial environments.
The study also touched upon the broader context of microbial evolution, emphasizing the constant arms race between moulds like Penicillium and evolving microbes. Given the current challenge of antibiotic resistance, the researchers proposed that understanding the genetic differences in penicillin production could inspire novel solutions to combat this issue.
In conclusion, this research not only sheds light on the genetic intricacies of Fleming's original Penicillium but also opens up possibilities for improving antibiotic production and addressing contemporary challenges in microbial evolution and antibiotic resistance.
