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Home NEWS Science News Health

Engineering Self-Destructing Bacteria for Advanced Tuberculosis Vaccine Development

Bioengineer by Bioengineer
February 25, 2025
in Health
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Researchers at Weill Cornell Medicine are making significant strides towards developing a new and more effective vaccine for tuberculosis (TB), a disease that remains a prominent health threat globally, claiming over one million lives annually. The innovative approach involves engineering mycobacterial strains that have what can be described as “kill switches.” These mechanisms allow researchers to trigger the self-destruction of the bacteria after they have successfully activated an immune response, paving the way for safer and more controlled clinical trials.

The preclinical studies, detailed in the prestigious journal Nature Microbiology, provide a novel perspective on how to combat TB, which is caused by the bacterium Mycobacterium tuberculosis. This pathogen is particularly notorious for spreading through airborne transmission, establishing chronic infections primarily in the lungs, and leading to severe respiratory illnesses. For over a century, the Bacille Calmette-Guérin (BCG) vaccine—derived from a weakened strain of the closely related Mycobacterium bovis—has been the standard immunization against TB. While BCG is known to provide some protection for children against severe forms of the disease, notably TB meningitis, it has been shown to perform poorly in protecting adults against pulmonary tuberculosis, which poses a significant public health challenge in high-incidence areas.

Given the limitations of the existing vaccine, researchers have sought alternative strategies to enhance vaccine efficacy. Prominent among these strategies is a shift in the administration route of the BCG vaccine. Prior findings from researchers at the University of Pittsburgh and the NIH Vaccine Research Center showed that administering high doses of the BCG vaccine intravenously can provide better protection against lung infections in macaques compared to the traditional subcutaneous route. This intriguing discovery set the stage for further innovations, particularly in making the high-dose intravenous injection safer for clinical applications.

In their pursuit of a more effective BCG vaccine, the Weill Cornell team, led by microbiologist Dr. Dirk Schnappinger, focused on the vital challenge of maintaining the immune-stimulating properties of the vaccine while adding a safety mechanism to eliminate the bacteria after it has served its purpose. The key breakthrough came after extensive testing of various strategies. Researchers discovered that lysins—enzymes encoded by certain bacteriophages that can specifically target and destroy Mycobacterium bovis—could be harnessed as kill switches. By employing a smart design, they managed to place the genes encoding two different lysins under the control of gene regulators responsive to an antibiotic. This arrangement allowed them to effectively “flip the switch,” utilizing the lysins to initiate the self-destruct sequence when the antibiotic was administered or withdrawn.

In experimental setups with antibiotic-treated macaque monkeys, the new engineered BCG strain was administered via high-dose intravenous injections. The results were promising, showing that once the antibiotic was stopped, the kill switch was effectively activated. This engineered bacteria not only self-destructed but also released antigens that further amplified the immune response of the animals. As a result, the vaccinated macaques exhibited a robust immune response, demonstrating protection against subsequent lung infections caused by M. tuberculosis.

Despite these encouraging preclinical outcomes, researchers recognize that translating these findings into clinical practice is a complex endeavor. Testing vaccine efficacy in humans requires extensive longitudinal studies involving numerous participants, significantly complicating the process. As Dr. Schnappinger notes, tuberculosis does not progress hastily, manifesting only in a subset of infected individuals, which extends the timeline needed for thorough clinical evaluation. Such extensive trials are resource-intensive, often costing upwards of hundreds of millions of dollars and presenting considerable barriers to the development of new TB vaccines.

In a parallel effort, the researchers from Weill Cornell Medicine, with collaborators from Harvard T.H. Chan School of Public Health, have engineered even safer strains of M. tuberculosis. They developed a strain possessing a triple kill switch, utilizing three distinct molecular pathways for bacterial eradication. Remarkably, this advanced design demonstrated its efficacy even in experiments with severely immunocompromised mice, where the infection could be halted at will, leaving no detectable bacteria behind.

This innovative approach opens doors to conducting human challenge trials, whereby controlled infections may be introduced in volunteers to evaluate the efficacy of new vaccine candidates systematically. The researchers are currently establishing additional tests in both mice and non-human primates to validate the reliability of this method. Dr. Schnappinger emphasizes the paramount importance of addressing safety concerns, particularly when working with one of history’s most successful human pathogens. The ultimate goal remains clear: to contribute effectively to the global fight against tuberculosis and develop a vaccine that not only elicits a strong immune response but does so safely and sustainably.

As the urgency to develop effective vaccines against infectious diseases, particularly tuberculosis, continues to grow, this cutting-edge approach stands as a testament to the possibilities that innovative science and rigorous research can offer. By engineering mycobacteria with fail-safe mechanisms, researchers are not only addressing the shortcomings of existing vaccines but also laying the groundwork for a transformative approach to vaccine development that prioritizes both efficacy and safety. The hope is that these advances will translate into next-generation vaccines, capable of saving lives and reducing the global TB burden, while maintaining public health safety.

As this exciting research progresses, the future of TB vaccine development appears more promising than ever. The innovation and resilience of the scientific community push the boundaries of what is possible, illustrating a path forward that could change the landscape of tuberculosis prevention and treatment. The need for such advancements has never been more critical, and the commitment of researchers like those at Weill Cornell Medicine serves as a beacon of hope in the ongoing battle against one of the world’s deadliest diseases.

Subject of Research: Development of safe, engineered tuberculosis vaccines using mycobacteria with kill switches.

Article Title: Innovative Mycobacteria with Kill Switches: A New Frontier in Tuberculosis Vaccine Development.

News Publication Date: 10-Jan-2025.

Web References: Weill Cornell Medicine, Nature Microbiology.

References: Preclinical studies in Nature Microbiology.

Image Credits: None.

Keywords: Tuberculosis, BCG Vaccine, Kill Switches, Vaccine Development, Immune Response, Mycobacteria, Infectious Diseases, Public Health.

Tags: BCG vaccine limitations in adultschronic infections by Mycobacterium tuberculosisengineered mycobacterial strainsimmune response activation in TBinnovative approaches to TB vaccinesNature Microbiology publication on tuberculosis researchpreclinical studies in vaccine developmentrespiratory illnesses caused by TBself-destructing bacteria in vaccinestuberculosis health threat globallytuberculosis vaccine developmentWeill Cornell Medicine research on TB

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