Engineered Probiotic for the Inhibition of <i>Salmonella</i> via Tetrathionate-Induced Production of Microcin H47

Palmer, Jacob D; Piattelli, Emma; McCormick, Beth A.; Silby, Mark W.; Brigham, Christopher J.; Bucci, Vanni

doi:10.1021/acsinfecdis.7b00114

Cited by 88 publications

(69 citation statements)

References 29 publications

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“…In some instances, it may be preferable to activate effector functions under more specific conditions, rather than constitutively throughout the gastrointestinal tract. For example, coupling gene expression to biosensors of reactive oxygen and nitrogen species for the treatment of inflammatory bowel disease may help deliver effectors specifically where activity is beneficial 7,28 . Regulating effector expression in response to bacterial quorum sensing molecules 29 , pH 30 , specific carbon sources [31][32][33] , temperature 34 , or combinations of these signals may allow for exquisitely tuned effector functions in various intestinal microenvironments 7 .…”

Section: Design Of Engineered Therapeutic Strains For the Human Gutmentioning

confidence: 99%

“…demonstrated that the EcN-based gastrointestinal delivery of anti-biofilm enzyme, dispersin B (DspB), resulted in a reduction of pre-colonized P. aeruginosa abundance in both nematode and murine models 29 . Other groups have reported the successful production of antimicrobial peptides from EcN that are effective for significantly decreasing murine colonization by Enterococcal species 36 or Salmonella typhimurium 28 . In the face of increasingly prevalent antibiotic-resistant pathogens, novel EcN-based antimicrobials offer promise for the treatment of infections caused by organisms recalcitrant to traditional approaches.…”

Section: Design Of Engineered Therapeutic Strains For the Human Gutmentioning

confidence: 99%

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Developing a new class of engineered live bacterial therapeutics to treat human diseases

et al. 2020

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A complex interplay of metabolic and immunological mechanisms underlies many diseases that represent a substantial unmet medical need. There is an increasing appreciation of the role microbes play in human health and disease, and evidence is accumulating that a new class of live biotherapeutics comprised of engineered microbes could address specific mechanisms of disease. Using the tools of synthetic biology, nonpathogenic bacteria can be designed to sense and respond to environmental signals in order to consume harmful compounds and deliver therapeutic effectors. In this perspective, we describe considerations for the design and development of engineered live biotherapeutics to achieve regulatory and patient acceptance. Regulatory considerations for live biotherapeutic products Live biotherapeutic products (LBPs) are defined as live organisms designed and developed to treat, cure, or prevent a disease or condition in humans 10. Notably, LBPs exclude vaccines, filterable viruses, oncolytic viruses, and organisms used as vectors for transferring genes into the host. LBPs are distinguished from probiotic supplements on the basis of their labeling claims, as

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Section: Design Of Engineered Therapeutic Strains For the Human Gutmentioning

confidence: 99%

Section: Design Of Engineered Therapeutic Strains For the Human Gutmentioning

confidence: 99%

Developing a new class of engineered live bacterial therapeutics to treat human diseases

et al. 2020

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“…Probiotics are live microorganisms that provide health benefits when consumed, including enhancement of gut epithelial barrier function, blocking of pathogen binding, and vitamin synthesis (Hill et al, 2014). There has been increasing success in expanding the therapeutic scope and efficacy of probiotics through genetic engineering, with prior work demonstrating preclinical efficacy against infectious and metabolic diseases (Durrer et al, 2017;Hwang et al, 2017;Isabella et al, 2018;Palmer et al, 2018). Engineered probiotics are exciting platforms for in situ drug synthesis and delivery, provided they maintain appropriate abundance and activity at their target site.…”

Section: Introductionmentioning

confidence: 99%

“…We focus on the probiotic Escherichia coli Nissle 1917 (EcN), an E. coli clade B2 commensal ( Figure S1). EcN has a long history of use in humans (Westendorf et al, 2005), has demonstrated efficacy against inflammatory bowel disease (Scaldaferri et al, 2016), and has been gaining increased attention as a chassis for engineered function (Hwang et al, 2017;Isabella et al, 2018;Kurtz et al, 2019;Palmer et al, 2018). We expected several factors to drive adaptation of EcN in the mouse gut.…”

Section: Introductionmentioning

confidence: 99%

Adaptive Strategies of the Candidate Probiotic E. coli Nissle in the Mammalian Gut

Crook

Ferreiro

Gasparrini

et al. 2019

Cell Host & Microbe

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Graphical Abstract Highlights d Carbohydrate availability in the gut drives E. coli Nissle adaptation in vivo d Gut monocolonization selects for glycosyl hydrolases enabling population cross-feeding d Mutations that enhance mucin utilization are enriched in lowdiversity guts d Prior antibiotic exposure in conventional guts can lead to evolved probiotic resistance In Brief E. coli Nissle is a probiotic and chassis for engineered biotherapies, but its adaptive behavior in the gut is unclear. Crook et al. report host-mediated selective pressures modulating carbohydrate utilization and metabolism of E. coli Nissle. This in-host evolution also promotes probiotic survival by enabling effective stress responses during colonization. SUMMARYProbiotics are living microorganisms that are increasingly used as gastrointestinal therapeutics by virtue of their innate or engineered genetic function. Unlike abiotic therapeutics, probiotics can replicate in their intended site, subjecting their genomes and therapeutic properties to natural selection. We exposed the candidate probiotic E. coli Nissle (EcN) to the mouse gastrointestinal tract over several weeks, systematically altering the diet and background microbiota complexity. In-transit EcN accumulates genetic mutations that modulate carbohydrate utilization, stress response, and adhesion to gain competitive fitness, while previous exposure to antibiotics reveals an acquisition of resistance. We then leveraged these insights to generate an EcN strain that shows therapeutic efficacy in a mouse model of phenylketonuria and found that it was genetically stable over 1 week, thereby validating EcN's utility as a chassis for engineering. Collectively, we demonstrate a generalizable pipeline that can be applied to other probiotics to better understand their safety and engineering potential. ing of GFP-Tagged EcN, B.W.; Engineering of EcN:PAL2 Strains, Z.C.; Creation, Sharing, and Guidance on Pah enu2 -Mouse Model, S.D.

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“…As an innovative and alternative measure to treat infectious diseases, probiotic therapy contributes to reduction of the development of multi-resistant bacteria. It has been proposed that probiotics can inhibit pathogens by different mechanisms, including secretion of antibacterial chemicals, stimulation and modulation of the immune responses, competition of nutrition and specific adhesion sites, and inhibition of toxic protein expression in gastrointestinal pathogens [59][60][61][62]. According to the mechanistic basis, various probiotics have been developed, and most of them demonstrated great specificity and efficacy for the inhibition of pathogens.…”

Section: Engineering Probiotics For the Treatment Of Bacterial Infectmentioning

confidence: 99%

Engineering probiotics as living diagnostics and therapeutics for improving human health

et al. 2020

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The gut microbiota that inhabit our gastrointestinal tract are well known to play an important role in maintaining human health in many aspects, including facilitating the digestion and absorption of nutrients, protecting against pathogens and regulating immune system. Gut microbiota dysbiosis is associated with a lot of diseases, such as inflammatory bowel disease, allergy, obesity, cardiovascular and neurodegenerative diseases and cancers. With the increasing knowledge of the microbiome, utilization of probiotic bacteria in modulating gut microbiota to prevent and treat a large number of disorders and diseases has gained much interest. In recent years, aided by the continuous development of tools and techniques, engineering probiotic microbes with desired characteristics and functionalities to benefit human health has made significant progress. In this paper, we summarize the recent advances in design and construction of probiotics as living diagnostics and therapeutics for probing and treating a series of diseases including metabolic disorders, inflammation and pathogenic bacteria infections. We also discuss the current challenges and future perspectives in expanding the application of probiotics for disease treatment and detection. We intend to provide insights and ideas for engineering of probiotics to better serve disease therapy and human health.

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Engineered Probiotic for the Inhibition of Salmonella via Tetrathionate-Induced Production of Microcin H47

Cited by 88 publications

References 29 publications

Developing a new class of engineered live bacterial therapeutics to treat human diseases

Developing a new class of engineered live bacterial therapeutics to treat human diseases

Adaptive Strategies of the Candidate Probiotic E. coli Nissle in the Mammalian Gut

Engineering probiotics as living diagnostics and therapeutics for improving human health

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