Piperacillin Shows Promise in tretment of Lyme Disease , suggests research
Scientists from Northwestern University identified piperacillin, an FDA-approved antibiotic, as a strong candidate for treating B. burgdorferi, the bacterium behind Lyme disease, while sparing other bacteria. In mouse studies, piperacillin proved as effective as doxycycline in treating acute infection. Additionally, separate findings revealed that B. burgdorferi peptidoglycan can persist even after infection clearance, offering a possible explanation for lingering Lyme disease symptoms in humans. The study has been published in the journal Science Translational Medicine.
Lyme disease, a disease transmitted when deer ticks feed on infected animals like deer and rodents, and then bite humans, impacts nearly half a million individuals in the U.S. annually. Even in acute cases, Lyme can be devastating; but early treatment with antibiotics can prevent chronic symptoms like heart and neurological problems and arthritis from developing.
Doxycycline and other generic antibiotics wreak havoc on the microbiome, killing beneficial bacteria in the gut and causing troubling side effects even as it kills the borrelia bacteria that causes Lyme. In addition to its negative impact on the gut, doxycycline also fails to help between 10 and 20% of individuals who take it, and it is not approved for use in young children — who are at the highest risk of tick bites, and therefore, of developing Lyme.
More effective, or at least more specified, treatment options are needed as climate change extends tick seasons and Lyme becomes more prevalent.
“Powerful, broad-spectrum antibiotics that kill extracellular bacteria are seen as the most effective medication because physicians want to just kill the bacterium and don't care how,” said Brandon L. Jutras, who led the research. “This is certainly a reasonable approach, but I think the future for Lyme disease patients is bright in that we are approaching an era of customized medicine, and we can potentially create a particular drug, or a combination to treat Lyme disease when other fail. The more we understand about the various strains and species of Lyme disease-causing Borrelia, the closer we get to a custom approach.”
Jutras is an associate professor in the microbiology-immunology department of Northwestern University Feinberg School of Medicine, and a member of Northwestern’s Center for Human Immunobiology. Jutras’s lab was recently named a Phase 3 winner in LymeX Diagnostics, the Steven & Alexandra Cohen Foundation’s $10 million competition to accelerate the development of Lyme disease diagnostics, and in 2021 he won the Bay Area Lyme Foundation Emerging Leader Award.
The authors argue that piperacillin, which has already been FDA-approved as a safe treatment for pneumonia, could also be a candidate for preemptive interventions, in which someone potentially exposed to Lyme (with a known deer tick bite) would receive a single-dose shot of the medication.
To reach the conclusion that the penicillin relative would be the most effective and targeted treatment, the team screened nearly 500 medicines in a drug library, using a molecular framework to understand potential interactions between antibiotics and the Borrelia bacteria. Once the group had a short list of potentials, they performed additional physiological, cellular and molecular tests to identify compounds that did not impact other bacteria.
They found that piperacillin exclusively interfered with the unusual cell wall synthesis pattern common to Lyme bacteria, preventing the bacteria from growing or dividing and ultimately leading to its death.
Historically, piperacillin has been administered as part of a two-drug cocktail to treat severe strep infections because strep can break down beta-lactams (piperacillin’s class of antibiotics) unless accompanied by tazobactam, which is an inhibitor of the enzyme that inactivates piperacillin. Jutras wondered if using the same two medications, rather than piperacillin alone, would be a more effective bacteria killer.
“Bacteria are clever,” Jutras said. “Strep and some other bacteria combat antibiotics by secreting beta-lactamases that inactivate piperacillin. We found the approach is totally irrelevant in the context of Lyme disease and another way that makes piperacillin more specific. Adding the beta-lactamase inhibitor doesn’t improve the therapy because Lyme Borrelia don’t produce beta-lactamase, but the cocktail does negatively impact the microbiome by becoming more broadly functional against beneficial residents.”
Lyme prevention remains a challenge-no approved human vaccine exists-and Jutras hopes his research moving forward will help with developing proactive strategies to diagnose and treat it.
Reference:
Maegan E. Gabby, Abey Bandara, L. M. Outrata, Osamudiamen Ebohon, Saadman S. Ahmad, Jules M. Dressler, Mecaila E. McClune, Rebecca N. Trimble, Lainey Mullen, Brandon L. Jutras. A high-resolution screen identifies a preexisting beta-lactam that specifically treats Lyme disease in mice. Science Translational Medicine, 2025; 17 (795) DOI: 10.1126/scitranslmed.adr9091
