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Unveiling the secret of viruses-bacteria interactions in human-made environments

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Unveiling the secret of viruses-bacteria interactions in human-made environments


Viruses in human-made environments cause public health concerns, but they are generally less studied than bacteria. A recent study led by environmental scientists from City University of Hong Kong (CityU) provided the first evidence of frequent interactions between viruses and bacteria in human-made environments. It found that viruses can potentially help host bacteria adapt and survive in nutrient-depleted human-made environments through a unique gene insertion.

By understanding these virus-bacteria interactions and identifying the possible spread of antibiotic resistance genes, the research team hopes its latest findings can help derive effective control strategies to minimize human exposure to harmful microorganisms.

Virus-host interactions are central to the ecology and evolution of microbial communities in diverse ecosystems. However, the immune mechanisms of infection and the virus-host interactions that occur in human-made environments, including buildings, public space, transportation and infrastructure, have been poorly understood.

“As more and more of the global population are living in urban areas, the importance of hygiene in human-made environments is growing, particularly indoor ones, as occupants inside are constantly exposed to diverse microorganisms, which have public health implications. However, most previous studies of human-made environments overlooked viruses,” said Professor Patrick Lee Kwan-Hon in the School of Energy and Environment (SEE) at CityU, who led the study.

“Therefore, in our study, we comprehensively investigated viruses in human-made environments, and we identified many novel molecular mechanisms in which viruses and bacteria interact with each other. These findings are important not only for basic microbial science, but also the management of human-made environments to protect residents’ health,” added Professor Lee.

In the study, researchers collected 738 samples from different types of human-made environments, including public facilities and residences, in Hong Kong. They collected the samples mainly from the surfaces of handrails, bollards, floors, poles, doorknobs and skin of residents. Then they used the metagenomic sequencing technique for analysis.

The analysis resulted in many interesting discoveries. First, the data showed that viruses are integral members of microbial communities in human-made environments. Among them, bacteriophages, a kind of virus that infects and replicates within bacteria, are all over various surfaces in human-made environments. The team also identified many viruses that are distinct from those in other ecosystems.

Second, the team found evidence of viruses inserting genes that control a specific step in a metabolic pathway and even the entire metabolic pathway into bacteria hosts. This suggests that viruses could help bacteria adapt and coevolve to survive in nutrient-depleted human-made environments.

The study also found diverse and novel immune systems against viruses in bacteria, and small proteins in viruses that can evade bacteria immune systems. These results suggest that viruses and bacteria hosts frequently interact with each other in human-made environments and that they each have mechanisms to defend against each other.

They also detected antibiotic resistance genes (ARGs) in viruses on human skin and frequently touched indoor surfaces. These ARG-carrying viruses might infect bacterial hosts, and ARGs might be horizontally transferred between bacterial species. Therefore, the role played by viruses in human-made environments in the development of antibiotic resistance in bacteria is crucial and warrants further investigation.

“Our study shows that the diversity, composition, metabolic functions and lifestyle of viruses vary, depending on the conditions of each human-made environment,” said Professor Lee. “Therefore, it is important to develop customized control strategies to minimize human exposure to harmful microorganisms and to better protect residents’ health. Our findings can contribute to this goal by enhancing the fundamental understanding of complex virus-bacteria interactions in human-made environments.”



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