AI designs new superbug-killing antibiotics for gonorrhoea and MRSA

Authors: James Gallagher

Publisher:

BBC

Published: 8/14/2025

Language:English

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Tom Banks

Good morning 跑了松鼠好嘛, I'm Tom Banks. Welcome to Goose Pod for Tuesday, August 26th.

Mask

I'm Mask. Today’s topic: AI is designing brand new antibiotics to fight superbugs like MRSA.

Tom Banks

Let's get started. Researchers at MIT have announced something from science fiction. They've used artificial intelligence to invent, not just discover, but invent two potential new antibiotics that could kill highly resistant superbugs.

Mask

This isn't just searching a database. The AI designed these drugs atom-by-atom. It sifted through 36 million potential compounds, including ones that don't even exist yet, to create molecules specifically to fight infections like gonorrhoea and MRSA. The scale is staggering.

Tom Banks

It truly is. Professor James Collins at MIT said, "AI can enable us to come up with molecules, cheaply and quickly and in this way, expand our arsenal." It’s about giving us a real leg up in this constant battle against evolving bacteria.

Mask

Exactly. It's a paradigm shift. We're moving from accidental discovery to intentional design. We’re telling the AI, 'Here's the problem, build the solution.' This is the future of medicine being built right now.

Tom Banks

To really appreciate this, you have to remember the history. We had this "Golden Age" of antibiotics after World War II. We found drugs like penicillin and it felt like we had conquered infectious diseases. It was a time of great optimism.

Mask

Complacency, you mean. We got lazy. The discovery pipeline dried up because it wasn't profitable. The low-hanging fruit was picked, and pharmaceutical companies moved on to more lucrative chronic diseases. Bacteria, however, didn't stop innovating. They kept evolving.

Tom Banks

And that's the key. Bacteria are incredibly adaptable. Alexander Fleming himself warned us about resistance. They develop defenses and, more amazingly, they can share those defenses with each other through horizontal gene transfer. It's like they're passing cheat codes around.

Mask

Which led to the rise of superbugs like MRSA, microbes that collected so many 'cheat codes' that our best drugs became useless. The old model of finding an antibiotic and using it for decades is broken. It was an arms race we were starting to lose.

Tom Banks

Absolutely. For decades, the pharmaceutical industry has been in a slump, with very few new classes of antibiotics developed. That's why this AI-driven approach isn't just another step; it feels like a completely new path forward out of a dangerous wilderness.

Mask

The fundamental problem has always been economic. It can take a decade and billions of dollars to bring a new antibiotic to market. Then, if it’s effective, doctors are told to use it as little as possible to prevent resistance. The market is broken.

Tom Banks

But there’s a profound ethical dilemma. We have people dying from infections we used to cure easily. Can we really let market forces decide whether we develop these life-saving medicines? It feels like a moral failure.

Mask

It's a system failure. Morality doesn't build labs or fund trials. You solve the problem by fixing the economics. AI dramatically cuts the cost and time of discovery, making it viable again. This isn't about playing God; it's about making the math work.

Tom Banks

So technology is solving an economic problem, which in turn solves the ethical one. A fascinating, if a bit cold, way to look at it.

Tom Banks

And the potential impact is enormous. For public health, this means we could have a steady stream of new weapons against evolving bacteria. It brings hope that we can get ahead of the curve, designing drugs for new threats as they emerge. It's proactive, not just reactive.

Mask

And the economic impact is just as big. We're talking about slashing R&D costs by up to 75%. AI-designed molecules are also showing 80-90% success rates in early trials, which is double the old average. It's a massive boost in efficiency.

Tom Banks

So, fewer dead ends and faster progress. That translates directly into more lives saved and a more resilient healthcare system.

Mask

This is just the start. We’re not creating one or two drugs. AI has already identified over 12,000 other molecules with potential antimicrobial activity. We are on the verge of unlocking a whole new pharmacy of cures that we never knew existed.

Tom Banks

It’s a powerful thought. The ability to design medicine from the ground up truly feels like the dawn of a new era in our fight against disease.

Tom Banks

AI has designed two new potential antibiotics, but the journey is just beginning.

Mask

That's all for today's Goose Pod. Thank you for listening and see you tomorrow.

## AI Designs Novel Antibiotics to Combat Drug-Resistant Superbugs This news report from the **BBC**, authored by **James Gallagher**, details a groundbreaking advancement in antibiotic discovery, where artificial intelligence (AI) has successfully designed two new potential antibiotic compounds. These compounds have demonstrated the ability to kill drug-resistant strains of **gonorrhoea** and **MRSA (methicillin-resistant Staphylococcus aureus)** in laboratory and animal tests. ### Key Findings and Conclusions: * **AI-Designed Antibiotics:** Researchers at the **Massachusetts Institute of Technology (MIT)** have utilized generative AI to design entirely new antibiotic molecules, atom-by-atom. This marks a significant step beyond previous AI applications that focused on identifying existing chemicals with antibiotic potential. * **Effectiveness Against Superbugs:** The two AI-designed compounds have shown efficacy in killing drug-resistant gonorrhoea and MRSA in laboratory settings and in infected mice. * **Potential for a "Second Golden Age":** The MIT team believes AI could usher in a new era of antibiotic discovery, addressing the critical shortage of new drugs to combat rising antibiotic resistance. * **Addressing a Global Health Crisis:** Antibiotic-resistant infections are a growing concern, causing over a million deaths annually. The overuse of antibiotics has accelerated bacterial evolution, making existing treatments less effective. ### Key Statistics and Metrics: * **Interrogated Compounds:** The AI was trained on and interrogated **36 million compounds**, including those that do not yet exist. * **Compound Size:** The AI identified promising starting points by searching through a library of chemical fragments ranging from **eight to 19 atoms** in size. * **Manufacturing Challenges:** Out of the top 80 theoretical gonorrhoea treatments designed by AI, only **two** were successfully synthesized into actual medicines, highlighting manufacturing challenges. ### Important Recommendations and Future Steps: * **Further Refinement and Clinical Trials:** The newly designed compounds are not yet ready for prescription. They require an estimated **one to two years** of further refinement before they can enter clinical trials in humans. * **Improved AI Models:** There is a need for better AI models that can more accurately predict drug effectiveness within the human body, moving beyond laboratory performance. ### Significant Trends and Changes: * **Shift in AI Application:** The research signifies a shift from AI being used to screen existing chemicals to AI being used for the *de novo* design of novel drug molecules. * **Accelerated Discovery Process:** AI has the potential to significantly speed up the drug discovery process, enabling the creation of new molecules "cheaply and quickly." ### Notable Risks and Concerns: * **Long and Expensive Testing:** Despite AI's capabilities, the process of testing for safety and efficacy in humans remains long, expensive, and without a guarantee of success. * **Manufacturing Feasibility:** The complexity of AI-designed molecules can pose challenges in their synthesis and manufacturing. * **Economic Viability:** A significant economic concern is the profitability of new antibiotics. To preserve their effectiveness, these drugs should ideally be used sparingly, making it difficult for pharmaceutical companies to recoup development costs. ### Context and Expert Opinions: * **Prof James Collins (MIT):** Emphasizes AI's ability to generate novel molecules quickly and cheaply, bolstering the fight against superbugs. * **Dr Andrew Edwards (Fleming Initiative and Imperial College London):** Praises the work as "very significant" with "enormous potential" but stresses the continued need for rigorous safety and efficacy testing. * **Prof Chris Dowson (University of Warwick):** Describes the study as "cool" and a "significant step forward," but also points to the economic disincentive for developing new antibiotics. This research represents a significant leap forward in the battle against antibiotic resistance, showcasing the transformative potential of AI in drug discovery. However, the path from AI design to patient prescription remains a complex and challenging one, requiring substantial further research and development.

Read original at BBC →

Getty ImagesArtificial intelligence has invented two new potential antibiotics that could kill drug-resistant gonorrhoea and MRSA, researchers have revealed.The drugs were designed atom-by-atom by the AI and killed the superbugs in laboratory and animal tests.The two compounds still need years of refinement and clinical trials before they could be prescribed.

But the Massachusetts Institute of Technology (MIT) team behind it say AI could start a "second golden age" in antibiotic discovery.Antibiotics kill bacteria, but infections that resist treatment are now causing more than a million deaths a year.Overusing antibiotics has helped bacteria evolve to dodge the drugs' effects, and there has been a shortage of new antibiotics for decades.

Researchers have previously used AI to trawl through thousands of known chemicals in an attempt to identify ones with potential to become new antibiotics.Now, the MIT team have gone one step further by using generative AI to design antibiotics in the first place for the sexually transmitted infection gonorrhoea and for potentially-deadly MRSA (methicillin-resistant Staphylococcus aureus).

Their study, published in the journal Cell, interrogated 36 million compounds including those that either do not exist or have not yet been discovered.Scientists trained the AI by giving it the chemical structure of known compounds alongside data on whether they slow the growth of different species of bacteria.

The AI then learns how bacteria are affected by different molecular structures, built of atoms such as carbon, oxygen, hydrogen and nitrogen.Two approaches were then tried to design new antibiotics with AI. The first identified a promising starting point by searching through a library of millions of chemical fragments, eight to 19 atoms in size, and built from there.

The second gave the AI free rein from the start.The design process also weeded out anything that looked too similar to current antibiotics. It also tried to ensure they were inventing medicines rather than soap and to filter out anything predicted to be toxic to humans.Scientists used AI to create antibiotics for gonorrhoea and MRSA, a type of bacteria that lives harmlessly on the skin but can cause a serious infection if it enters the body.

Once manufactured, the leading designs were tested on bacteria in the lab and on infected mice, resulting in two new potential drugs.MITProf James Collins, one of the researchers at MIT"We're excited because we show that generative AI can be used to design completely new antibiotics," Prof James Collins, from MIT, tells the BBC."

AI can enable us to come up with molecules, cheaply and quickly and in this way, expand our arsenal, and really give us a leg up in the battle of our wits against the genes of superbugs."However, they are not ready for clinical trials and the drugs will require refinement – estimated to take another one to two year's work – before the long process of testing them in people could begin.

Dr Andrew Edwards, from the Fleming Initiative and Imperial College London, said the work was "very significant" with "enormous potential" because it "demonstrates a novel approach to identifying new antibiotics".But he added: "While AI promises to dramatically improve drug discovery and development, we still need to do the hard yards when it comes to testing safety and efficacy."

That can be a long and expensive process with no guarantee that the experimental medicines will be prescribed to patients at the end.Some are calling for AI drug discovery more broadly to improve. Prof Collins says "we need better models" that move beyond how well the drugs perform in the laboratory to ones that are a better predictor of their effectiveness in the body.

There is also an issue with how challenging the AI-designs are to manufacture. Of the top 80 gonorrhoea treatments designed in theory, only two were synthesised to create medicines.Prof Chris Dowson, at the University of Warwick, said the study was "cool" and showed AI was a "significant step forward as a tool for antibiotic discovery to mitigate against the emergence of resistance".

However, he explains, there is also an economic problem factoring into drug-resistant infections - "how do you make drugs that have no commercial value?"If a new antibiotic was invented, then ideally you would use it as little as possible to preserve its effectiveness, making it hard for anyone to turn a profit.