News Release

Exploring the bactericidal activity of T1-spanin against drug-resistant bacteria

Peer-Reviewed Publication

Nanjing Agricultural University The Academy of Science

BioDesign Research                                                  Manuscript Template                                                                   Page 12 of 35with bacteriophage φ80 was transformed with a Tet repressor expression plasmid (pKLC83)


(a)  Schematic  diagram  of  the  construction  of  a  φ80  phage  capsid  containing  T1-spanin  gene.  T1-spanin exhibits  toxicity  toward  synthetic  bacterium  594;  therefore,  its  expression  was  suppressed  using  a  Tet repressor-expressing plasmid (pKLC83). Due to the presence of a packaging sequence, the T1-spanin plasmid was encapsulated within a phage capsid. (b) The synthesized phage capsid (a) was used to infect Escherichia coli  MC1061.  Within  bacterial  cells  lacking  Tet  repressor  expression,  T1-spanin  was  expressed.  (c)  E.  coliMC1061  were  infected  with  phage  capsids  containing  either  the  T1-spanin-encoding  plasmid  or  a  plasmid lacking T1-spanin (control). The infected bacteria were plated on LB agar plates, and the number of colony-forming units (CFUs) were counted. Abbreviation: LB, Luria-Bertani. Assays were performed in triplicate. The bars show the means of the three spot test results, and the error bars show the standard deviations.

view more 

Credit: BioDesign Research

Given the worldwide prevalence of drug-resistance bacteria, the research fraternity is on the lookout for alternative bactericidal treatment approaches. In a recent study, Japanese researchers have now compared bacteriophage-derived enzymes for combating drug-resistant bacteria. Examination of T1-spanin revealed that it shows superior bactericidal activity against various strains, including E.coli. Furthermore, a novel phage-based technology effectively delivers T1-spanin genes into target bacteria. This breakthrough holds promise for the development of innovative antimicrobial agents in the future.

In the recent past, global efforts have focused on tackling emergent and unprecedent health risks, such as those posed by the COVID-19 pandemic. Nonetheless, the continued prevalence of drug-resistant bacteria presents an even greater threat to global public health. For instance, in 2019 along, drug-resistant bacteria were responsible for around 1.27 million annual deaths worldwide. Antibiotic-resistant strains now claim more lives annually, compared to HIV and malaria combined. Now, while the menace of antibiotic-resistant bacteria continues to plague the healthcare system, alternative treatment approaches, such as bacteriophage therapy, have emerged as potential treatment options. Bacteriophages, also referred to as “phages,” are viruses that specifically target and destroy bacteria, including those that have acquired resistance to antibiotics. What makes some phages particularly effective is the presence of specialized enzymes, which they use in different ways to target and kill the bacteria.

phage-derived lytic enzymes is one such type of enzyme, which can break down and kill bacteria from the inside out. Scientists have now learned to harness the power of these enzymes through bacteriophage therapy, offering a promising approach for targeting drug-resistant pathogens with high precision and efficacy.

To further explore and improve this approach of targeting antibiotic-resistance bacteria, a group of researchers from Japan, led by Satoshi Tsuneda and Kotaro Kiga conducted a study investigating T1 phage’s unique properties. Renowned for its broad spectrum activity, involving the targeted action against bacterial strains, the team aimed to understand its mechanism of action. The findings of this study were published in the BioDesignResearch on 8 January, 2024, and shed light on T1 phage’s potential role in refining bacteriophage therapy for combating drug-resistant pathogens.

To achieve this, the researchers first compared enzymes derived from the T1 phage with those from the T7 phage. They analyzed endolysins, holins, and spanins to assess their ability to kill bacteria. Endolysins are known to degrade the bacterial cell wall from the inside, causing the cell to burst open, working alongside holins to regulate their activity. “Holins work by puncturing the inner membrane of bacteria through oligomerization, with the help of a transmembrane domain. Spanins, on the other hand, act by mediating the fusion between the outer and inner membranes,” explained Prof. Tsuneda. Spanins also help break down the bacterial cell membrane. The researchers found that among the enzymes studied, those derived from the T1 phage were the most efficient at killing bacteria.

In particular, T1-spanin stood out. On attacking bacteria, viruses hijack the internal DNA machinery of bacteria, using it to make copies of themselves, similar to the mechanism observed in humans. Once enough copies have been made inside the bacterium, the cell bursts open, releasing the newly formed virus particles into the environment. Spanins, like T1-spanin, play an important role in this process, as they help break down the bacterial cell membrane, facilitating the release of the virus particles.

The T1-spanin enzyme displayed an exceptional capability to penetrate the outer defenses of nearly 120 different bacterial strains. Employing an innovative strategy, the researchers developed a novel approach to directly introduce the T1-spanin gene into target bacteria. This involved integrating the T1-spanin gene into a template virus shell. Explaining further, Prof. Tsuneda says, “Unlike natural bacteriophages, this synthetic virus is unable to reproduce itself, and by using the synthetic virus instead of the bacteriophage directly, we were able to reduce the risk of environmental contamination or any adverse effects.”

Owing to T1-spanin’s broad applicability, the method developed by the researchers in this study can be used to effectively target a wide range of bacteria, diverging from traditional approaches. While it may be difficult to imagine how something as small as a virus-derived enzyme can make a difference to the menace of antibiotic-resistant bacteria, this study shows us a ray of hope. It suggests how molecular-level innovative strategies can help address the most pressing challenges in global public health, illustrating the potential of novel strategies to combat drug-resistant pathogens and advance the development of therapeutic interventions.



Journal: BioDesign Research

Titles of original papers: Harnessing a T1 phage-derived spanin for developing phage-based antimicrobial development

DOI: 10.34133/bdr.0028

Disclaimer: AAAS and EurekAlert! are not responsible for the accuracy of news releases posted to EurekAlert! by contributing institutions or for the use of any information through the EurekAlert system.