Ivan Y. C. Lin scite author profile

Horizontally acquired antibiotic resistance genes (ARGs) in bacteria are highly mobile and have been ranked as principal risk resistance determinants. However, the transfer network of the mobile resistome and the forces driving mobile ARG transfer are largely unknown. Here, we present the whole profile of the mobile resistome in 23,425 bacterial genomes and explore the effects of phylogeny and ecology on the recent transfer (>99% nucleotide identity) of mobile ARGs. We found that mobile ARGs are mainly present in four bacterial phyla and are significantly enriched in Proteobacteria. The recent mobile ARG transfer network, which comprises 703 bacterial species and 16,859 species pairs, is shaped by the bacterial phylogeny, while an ecological barrier also exists, especially when interrogating bacteria colonizing different human body sites. Phylogeny is still a driving force for the transfer of mobile ARGs between farm animals and the human gut, and, interestingly, the mobile ARGs that are shared between the human and animal gut microbiomes are also harbored by diverse human pathogens. Taking these results together, we suggest that phylogeny and ecology are complementary in shaping the bacterial mobile resistome and exert synergistic effects on the development of antibiotic resistance in human pathogens. IMPORTANCEThe development of antibiotic resistance threatens our modern medical achievements. The dissemination of antibiotic resistance can be largely attributed to the transfer of bacterial mobile antibiotic resistance genes (ARGs). Revealing the transfer network of these genes in bacteria and the forces driving the gene flow is of great importance for controlling and predicting the emergence of antibiotic resistance in the clinic. Here, by analyzing tens of thousands of bacterial genomes and millions of human and animal gut bacterial genes, we reveal that the transfer of mobile ARGs is mainly controlled by bacterial phylogeny but under ecological constraints. We also found that dozens of ARGs are transferred between the human and animal gut and human pathogens. This work demonstrates the whole profile of mobile ARGs and their transfer network in bacteria and provides further insight into the evolution and spread of antibiotic resistance in nature.A ntibiotic resistance is a growing global threat to human public health, and the continuing emergence of drug-resistant bacteria has led to the potential for a postantibiotic era (1). Bacteria have evolved a dynamic array of antimicrobial resistance mechanisms to withstand antibiotic attacks, such as altering drug target(s), synthesizing drug-inactivating enzymes, changing cell membrane permeability, and exporting drugs via efflux pumps (2). A large number of antibiotic resistance genes (ARGs) involved in these resistance mechanisms have been discovered and are collected in various ARG databases, including ARG-ANOTT (3), CARD (4), ResFinder (5), and ARDB (6). Because antibiotic resistance can be endogenous or exogenous, ARGs are generally classified as intrins...

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Dissemination of the mcr-1 colistin resistance gene

Liu

Lin

et al. 2016

The Lancet Infectious Diseases

133

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Live-Attenuated Bacterial Vectors: Tools for Vaccine and Therapeutic Agent Delivery

2015

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Genetically attenuated microorganisms, including pathogenic and commensal bacteria, can be engineered to carry and deliver heterologous antigens to elicit host immunity against both the vector as well as the pathogen from which the donor gene is derived. These live attenuated bacterial vectors have been given much attention due to their capacity to induce a broad range of immune responses including localized mucosal, as well as systemic humoral and/or cell-mediated immunity. In addition, the unique tumor-homing characteristics of these bacterial vectors has also been exploited for alternative anti-tumor vaccines and therapies. In such approach, tumor-associated antigen, immunostimulatory molecules, anti-tumor drugs, or nucleotides (DNA or RNA) are delivered. Different potential vectors are appropriate for specific applications, depending on their pathogenic routes. In this review, we survey and summarize the main features of the different types of live bacterial vectors and discussed the clinical applications in the field of vaccinology. In addition, different approaches for using live attenuated bacterial vectors for anti-cancer therapy is discussed, and some promising pre-clinical and clinical studies in this field are outlined.

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Ivan Y. C. Lin

The Bacterial Mobile Resistome Transfer Network Connecting the Animal and Human Microbiomes

Dissemination of the mcr-1 colistin resistance gene

Live-Attenuated Bacterial Vectors: Tools for Vaccine and Therapeutic Agent Delivery

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