The<i>Pseudomonas aeruginosa</i>Wsp pathway undergoes positive evolutionary selection during chronic infection

Gloag, Erin S.; Marshall, C. W.; Snyder, Donald R.; Lewin, Gina R.; Harris, Jacob S.; Chaney, Sarah B.; Whiteley, Marvin; Cooper, Vaughn S.; Wozniak, Daniel J.

doi:10.1101/456186

“…This result not only simulates the process of adaptive radiation often illustrated using Darwin's finches in textbooks (Fig. 2), but also reproduces the selection for traits associated with adherence that often occurs during biofilm-associated infections (Traverse et al 2013;Cooper et al 2014;O'Rourke et al 2015;Gloag et al 2018). The "wrinkly" colony morphologies that evolve in our model are genetically and functionally identical to those commonly isolated from infections of the related species Pseudomonas aeruginosa in the airways of cystic fibrosis patients and in chronic skin wounds (Starkey et al 2009;Gloag et al 2018).…”

Section: Learning Outcomessupporting

confidence: 75%

“…2), but also reproduces the selection for traits associated with adherence that often occurs during biofilm-associated infections (Traverse et al 2013;Cooper et al 2014;O'Rourke et al 2015;Gloag et al 2018). The "wrinkly" colony morphologies that evolve in our model are genetically and functionally identical to those commonly isolated from infections of the related species Pseudomonas aeruginosa in the airways of cystic fibrosis patients and in chronic skin wounds (Starkey et al 2009;Gloag et al 2018). Students can therefore connect their classroom experiments to recent findings at the interface of evolutionary biology and medicine to see how basic biological research impacts their everyday lives.…”

Section: Learning Outcomesmentioning

confidence: 85%

“…(Cooper 2018)) that underlie the adaptive mutant phenotypes, supporting a greater understanding of inheritance and trait variation (NGSS HS-LS3). Previous research in our lab indicates that many commonly identified mutations are found in the wsp (wrinkly spreader phenotype) gene cluster (Cooper et al 2014;Gloag et al 2018), which coordinates bacterial surface recognition with increased biofilm production (Hickman and Tifrea 2005). Students are likely to identify wsp mutants in their classroom experiments and can therefore connect how changes in DNA can result in changes in protein structure and intracellular signaling that lead to increased biofilm production and changes to colony morphology, supporting a greater understanding of DNA, protein structure, and cellular function (NGSS HS-LS1).…”

Section: Discussionmentioning

confidence: 99%

See 1 more Smart Citation

EvolvingSTEM: a microbial evolution-in-action curriculum that enhances learning of evolutionary biology and biotechnology

Cooper

¹

,

Warren

²

,

Matela

³

et al. 2019

Self Cite

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Evolution is a central, unifying theory for all of life science, yet the subject is poorly represented in most secondaryschool biology courses, especially in the United States. One challenge to learning evolution is that it is taught as a conceptual, retrospective subject with few tangible outcomes for students. These typical passive learning strategies lead to student disengagement with the material and misunderstanding of evolutionary concepts. To promote greater investment and comprehension, we developed EvolvingSTEM, an inquiry-based laboratory curriculum that demonstrates concepts of natural selection, heredity, and ecological diversity through experimental evolution of a benign bacterium. Students transfer populations of Pseudomonas fluorescens growing on plastic beads, which selects for biofilm formation and mutants with new, conspicuous phenotypes. We introduced our curriculum to four introductory high school biology classes alongside their standard curriculum materials and found that students who learned evolution through EvolvingSTEM scored significantly better on a common assessment targeted to Next Generation Science Standards than students taught only the standard curriculum. This latter group subsequently achieved similar scores once they too completed our curriculum. Our work demonstrates that inquiry-based, handson experiences with evolving bacterial populations can greatly enhance student learning of evolutionary concepts.

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“…Mutations in wsp genes are frequently identified in clinical specimens and are associated with increased biofilm formation 22,24,25,[73][74][75][76][77][78] , whether or not this is achieved through elevated production of cyclic di-GMP. Genetically deregulating the Wsp system appears to be a significant but transient adaptive strategy in a dynamic and overcrowded ecosystem.…”

Section: Discussionmentioning

confidence: 99%

Evolutionary Divergence of the Wsp Signal Transduction Systems in Beta- and Gammaproteobacteria

Kessler

¹

,

Mhatre

²

,

Cooper

³

et al. 2021

Appl Environ Microbiol

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Bacteria rapidly adapt to their environment by integrating external stimuli through diverse signal transduction systems. Pseudomonas aeruginosa , for example, senses surface-contact through the Wsp signal transduction system to trigger the production of cyclic di-GMP. Diverse mutations in wsp genes that manifest enhanced biofilm formation are frequently reported in clinical isolates of P. aeruginosa , and in biofilm studies of Pseudomonas spp. and Burkholderia cenocepacia . In contrast to the convergent phenotypes associated with comparable wsp mutations, we demonstrate that the Wsp system in B. cenocepacia does not impact intracellular cyclic di-GMP levels unlike that in Pseudomonas spp. Our current mechanistic understanding of the Wsp system is entirely based on the study of four Pseudomonas spp. and its phylogenetic distribution remains unknown. Here, we present a broad phylogenetic analysis to show that the Wsp system originated in the β-proteobacteria then horizontally transferred to Pseudomonas spp., the sole member of the γ-proteobacteria. Alignment of 794 independent Wsp systems with reported mutations from the literature identified key amino acid residues that fall within and outside annotated functional domains. Specific residues that are highly conserved but uniquely modified in B. cenocepacia likely define mechanistic differences among Wsp systems. We also find the greatest sequence variation in the extracellular sensory domain of WspA, indicating potential adaptations to diverse external stimuli beyond surface-contact sensing. This study emphasizes the need to better understand the breadth of functional diversity of the Wsp system as a major regulator of bacterial adaptation beyond B. cenocepacia and select Pseudomonas spp. Importance The Wsp signal transduction system serves as an important model system for studying how bacteria adapt to living in densely structured communities known as biofilms. Biofilms frequently cause chronic infections and environmental fouling, and they are very difficult to eradicate. In Pseudomonas aeruginosa , the Wsp system senses contact with a surface, which in turn activates specific genes that promote biofilm formation. We demonstrate that the Wsp system in Burkholderia cenocepacia regulates biofilm formation uniquely from that in Pseudomonas species. Furthermore, a broad phylogenetic analysis reveals the presence of the Wsp system in diverse bacterial species, and sequence analyses of 794 independent systems suggest that the core signaling components function similarly but with key differences that may alter what or how they sense. This study shows that Wsp systems are highly conserved and more broadly distributed than previously thought, and their unique differences likely reflect adaptations to distinct environments.

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Evolutionary divergence of the Wsp signal transduction system in β- and γ-proteobacteria

Kessler

¹

,

Mhatre

²

,

Cooper

³

et al. 2021

Preprint

Self Cite

1

21

0

View full text Add to dashboard Cite

Bacteria rapidly adapt to their environment by integrating external stimuli through diverse signal transduction systems. Pseudomonas aeruginosa, for example, senses surface-contact through the Wsp signal transduction system to trigger the production of cyclic di-GMP. Diverse mutations in wsp genes that manifest enhanced biofilm formation are frequently reported in clinical isolates of P. aeruginosa, and in biofilm studies of Pseudomonas spp. and Burkholderia cenocepacia. In contrast to the convergent phenotypes associated with comparable wsp mutations, we demonstrate that the Wsp system in B. cenocepacia does not impact intracellular cyclic di-GMP levels unlike that in Pseudomonas spp. Our current mechanistic understanding of the Wsp system is entirely based on the study of four Pseudomonas spp. and its phylogenetic distribution remains unknown. Here, we present the first broad phylogenetic analysis to date to show that the Wsp system originated in the β-proteobacteria then horizontally transferred to Pseudomonas spp., the sole member of the γ-proteobacteria. Alignment of 794 independent Wsp systems with reported mutations from the literature identified key amino acid residues that fall within and outside annotated functional domains. Specific residues that are highly conserved but uniquely modified in B. cenocepacia likely define mechanistic differences among Wsp systems. We also find the greatest sequence variation in the extracellular sensory domain of WspA, indicating potential adaptations to diverse external stimuli beyond surface-contact sensing. This study emphasizes the need to better understand the breadth of functional diversity of the Wsp system as a major regulator of bacterial adaptation beyond B. cenocepacia and select Pseudomonas spp.

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ThePseudomonas aeruginosaWsp pathway undergoes positive evolutionary selection during chronic infection

Cited by 4 publications

References 59 publications

EvolvingSTEM: a microbial evolution-in-action curriculum that enhances learning of evolutionary biology and biotechnology

EvolvingSTEM: a microbial evolution-in-action curriculum that enhances learning of evolutionary biology and biotechnology

Evolutionary Divergence of the Wsp Signal Transduction Systems in Beta- and Gammaproteobacteria

Evolutionary divergence of the Wsp signal transduction system in β- and γ-proteobacteria

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