Mark Lyng scite author profile

Urinary tract infections (UTIs) are frequent in humans, affecting the upper and lower urinary tract. Present diagnosis relies on the positive culture of uropathogenic bacteria from urine and clinical markers of inflammation of the urinary tract. The bladder is constantly challenged by adverse environmental stimuli which influence urinary tract physiology, contributing to a dysbiotic environment. Simultaneously, pathogens are primed by environmental stressors such as antibiotics, favoring recurrent UTIs (rUTIs), resulting in chronic illness. Due to different confounders for UTI onset, a greater understanding of the fundamental environmental mechanisms and microbial ecology of the human urinary tract is required. Such advancements could promote the tandem translation of bench and computational studies for precision treatments and clinical management of UTIs. Therefore, there is an urgent need to understand the ecological interactions of the human urogenital microbial communities which precede rUTIs. This review aims to outline the mechanistic aspects of rUTI ecology underlying dysbiosis between both the human microbiome and host physiology which predisposes humans to rUTIs. By assessing the applications of next generation and systems level methods, we also recommend novel approaches to elucidate the systemic consequences of rUTIs which requires an integrated approach for successful treatment. To this end, we will provide an outlook towards the so-called ‘uncomplicated environment of UTIs’, a holistic and systems view that applies ecological principles to define patient-specific UTIs. This perspective illustrates the need to withdraw from traditional reductionist perspectives in infection biology and instead, a move towards a systems-view revolving around patient-specific pathophysiology during UTIs.

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Frenemies of the soil: Bacillus and Pseudomonas interspecies interactions

Lyng¹,

Kovács²

2023

Trends in Microbiology

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There is no hiding if you Seq: recent breakthroughs in Pseudomonas aeruginosa research revealed by genomic and transcriptomic next-generation sequencing

Valli

Lyng

Kirkpatrick

2020

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The advent of next-generation sequencing technology has revolutionized the field of prokaryotic genetics and genomics by allowing interrogation of entire genomes, transcriptomes and global transcription factor binding profiles. As more studies employing these techniques have been performed, the state of the art regarding prokaryotic gene regulation has developed from the level of individual genes to genetic regulatory networks and systems biology. When applied to bacterial pathogens, particularly valuable insights have been gained into the regulation of virulence-associated genes, their relative importance to bacterial survival in planktonic, biofilm or host infection scenarios, antimicrobial resistance and the molecular details of host-pathogen interaction. This Review outlines some of the latest developments and applications of next-generation sequencing techniques to the genus Pseudomonas, with particular focus on opportunistic human pathogen Pseudomonas species, the biological insights gained from them and the future directions in which this field could develop.

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Microbial ecology: Metabolic heterogeneity and the division of labor in multicellular structures

Lyng

Kovács

2022

Current Biology

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Competition for iron shapes metabolic antagonism betweenBacillus subtilisandPseudomonas

Lyng

Jørgensen

Schostag

et al. 2023

Preprint

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Siderophores have long been implicated in sociomicrobiology as determinants of bacterial interrelations. For plant-associated genera like Bacillus and Pseudomonas, siderophores are well known for their biocontrol functions. Here, we explored the functional role of the Bacillus subtilis siderophore bacillibactin in an antagonistic interaction with Pseudomonas marginalis. The presence of bacillibactin strongly influenced the outcome of the interaction in an iron-dependent manner. The bacillibactin producer B. subtilis restricts colony spreading of P. marginalis by repressing the transcription of histidine kinase-encoding gene gacS, thereby abolishing production of secondary metabolites such as pyoverdine and viscosin. By contrast, lack of bacillibactin restricted B. subtilis colony growth in a mechanism reminiscent of a siderophore tug-of-war for iron. Our analysis revealed that the Bacillus-Pseudomonas interaction is conserved across fluorescent Pseudomonas spp., expanding our understanding of the interplay between two genera of the most well-studied soil microbes.

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Mark Lyng

Recurrent Urinary Tract Infections: Unraveling the Complicated Environment of Uncomplicated rUTIs

Frenemies of the soil: Bacillus and Pseudomonas interspecies interactions

There is no hiding if you Seq: recent breakthroughs in Pseudomonas aeruginosa research revealed by genomic and transcriptomic next-generation sequencing

Microbial ecology: Metabolic heterogeneity and the division of labor in multicellular structures

Competition for iron shapes metabolic antagonism betweenBacillus subtilisandPseudomonas

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