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1. The histidine kinase NahK regulates pyocyanin production through the PQS system

   https://doi.org/10.1128/jb.00276-23  

   Mendoza, Alicia G.; Guercio, Danielle; Smiley, Marina K.; Sharma, Gaurav K.; Withorn, Jason M.; Hudson-Smith, Natalie V.; Ndukwe, Chika; Dietrich, Lars E.; Boon, Elizabeth M. (January 2024, Journal of Bacteriology)

   Bondy-Denomy, Joseph (Ed.)

   ABSTRACT Many bacterial histidine kinases work in two-component systems that combine into larger multi-kinase networks. NahK is one of the kinases in the GacS Multi-Kinase Network (MKN), which is the MKN that controls biofilm regulation in the opportunistic pathogenPseudomonas aeruginosa. This network has also been associated with regulating many virulence factorsP. aeruginosasecretes to cause disease. However, the individual role of each kinase is unknown. In this study, we identify NahK as a novel regulator of the phenazine pyocyanin (PYO). Deletion ofnahKleads to a fourfold increase in PYO production, almost exclusively through upregulation of phenazine operon two (phz2). We determined that this upregulation is due to mis-regulation of allP. aeruginosaquorum-sensing (QS) systems, with a large upregulation of thePseudomonasquinolone signal system and a decrease in production of the acyl-homoserine lactone-producing system,las. In addition, we see differences in expression of quorum-sensing inhibitor proteins that align with these changes. Together, these data contribute to understanding how the GacS MKN modulates QS and virulence and suggest a mechanism for cell density-independent regulation of quorum sensing. IMPORTANCEPseudomonas aeruginosais a Gram-negative bacterium that establishes biofilms as part of its pathogenicity.P. aeruginosainfections are associated with nosocomial infections. As the prevalence of multi-drug-resistantP. aeruginosaincreases, it is essential to understand underlying virulence molecular mechanisms. Histidine kinase NahK is one of several kinases inP. aeruginosaimplicated in biofilm formation and dispersal. Previous work has shown that the nitric oxide sensor, NosP, triggers biofilm dispersal by inhibiting NahK. The data presented here demonstrate that NahK plays additional important roles in theP. aeruginosalifestyle, including regulating bacterial communication mechanisms such as quorum sensing. These effects have larger implications in infection as they affect toxin production and virulence. 

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2. Quorum Sensing Communication: Molecularly Connecting Cells, Their Neighbors, and Even Devices

   https://doi.org/10.1146/annurev-chembioeng-101519-124728  

   Wang, Sally; Payne, Gregory F.; Bentley, William E. (June 2020, Annual Review of Chemical and Biomolecular Engineering)

   Quorum sensing (QS) is a molecular signaling modality that mediates molecular-based cell–cell communication. Prevalent in nature, QS networks provide bacteria with a method to gather information from the environment and make decisions based on the intel. With its ability to autonomously facilitate both inter- and intraspecies gene regulation, this process can be rewired to enable autonomously actuated, but molecularly programmed, genetic control. On the one hand, novel QS-based genetic circuits endow cells with smart functions that can be used in many fields of engineering, and on the other, repurposed QS circuitry promotes communication and aids in the development of synthetic microbial consortia. Furthermore, engineered QS systems can probe and intervene in interkingdom signaling between bacteria and their hosts. Lastly, QS is demonstrated to establish conversation with abiotic materials, especially by taking advantage of biological and even electronically induced assembly processes; such QS-incorporated biohybrid devices offer innovative ways to program cell behavior and biological function. 

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3. A redox-based electrogenetic CRISPR system to connect with and control biological information networks

   https://doi.org/10.1038/s41467-020-16249-x  

   Bhokisham, Narendranath; VanArsdale, Eric; Stephens, Kristina T.; Hauk, Pricila; Payne, Gregory F.; Bentley, William E. (May 2020, Nature Communications)

   Abstract Electronic information can be transmitted to cells directly from microelectronics via electrode-activated redox mediators. These transmissions are decoded by redox-responsive promoters which enable user-specified control over biological function. Here, we build on this redox communication modality by establishing an electronic eCRISPR conduit of information exchange. This system acts as a biological signal processor, amplifying signal reception and filtering biological noise. We electronically amplify bacterial quorum sensing (QS) signaling by activating LasI, the autoinducer-1 synthase. Similarly, we filter out unintended noise by inhibiting the native SoxRS-mediated oxidative stress response regulon. We then construct an eCRISPR based redox conduit in bothE. coliandSalmonella enterica. Finally, we display eCRISPR based information processing that allows transmission of spatiotemporal redox commands which are then decoded by gelatin-encapsulatedE. coli. We anticipate that redox communication channels will enable biohybrid microelectronic devices that could transform our abilities to electronically interpret and control biological function. 

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4. Quorum sensing mediates morphology and motility transitions in the model archaeon Haloferax volcanii

   https://doi.org/10.1128/mbio.00906-25  

   Chatterjee, Priyanka; Consoli, Caroline E; Schiller, Heather; Winter, Kiersten K; McCallum, Monica E; Schulze, Stefan; Pohlschroder, Mechthild (June 2025, mBio)

   Newman, Dianne K (Ed.)

   ABSTRACT Quorum sensing (QS) is a population density-dependent mechanism of intercellular communication, whereby microbes secrete and detect signals to regulate behaviors such as virulence and biofilm formation. Although QS is well-studied in bacteria, little is known about cell-cell communication in archaea. The model archaeonHaloferax volcaniican transition from motile rod-shaped cells to non-motile disks as population density increases. In this report, we demonstrate that this transition is induced by a secreted small molecule present in cell-free conditioned medium (CM). The CM also elicits a response from a bacterial QS bioreporter, suggesting the potential for inter-domain crosstalk. To investigate theHfx. volcaniiQS response, we performed quantitative proteomics and detected significant differential abundances of 236 proteins in the presence of CM, including proteins involved in cell structure, motility, glycosylation, and two-component systems. We also demonstrate that a mutant lacking the cell shape regulatory factor DdfA does not undergo shape and motility transitions in the presence of CM, allowing us to identify protein abundance changes in the QS response pathway separate from those involved in shape and motility. In the ∆ddfAstrain, only 110 proteins had significant differential abundance, and comparative analysis of these two proteomics experiments enabled us to identify proteins dependent on and independent of DdfA in the QS response pathway. Our study provides the first detailed analysis of QS pathways in any archaeon, strengthening our understanding of archaeal communication as well as providing the framework for studying intra- and interdomain crosstalk. IMPORTANCEUnderstanding the complex signaling networks in microbial communities has led to many invaluable applications in medicine and industry. Yet, while archaea are ubiquitous and play key roles in nutrient cycling, little is known about the roles of archaeal intra- and interspecies cell-cell communication in environments such as the human, soil, and marine microbiomes. In this study, we established the first robust system for studying quorum sensing in archaea by using the model archaeonHaloferax volcanii. We demonstrated that different behaviors, such as cell shape and motility, are mediated by a signal molecule, and we uncovered key regulatory components of the signaling pathway. This work advances our understanding of microbial communication, shedding light on archaeal intra- and interdomain interactions, and contributes to a more complete picture of the interconnected networks of life on Earth. 

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5. Redox cycling-based detection of phenazine metabolites secreted from Pseudomonas aeruginosa in nanopore electrode arrays

   https://doi.org/10.1039/D0AN02022B  

   Do, Hyein; Kwon, Seung-Ryong; Baek, Seol; Madukoma, Chinedu S.; Smiley, Marina K.; Dietrich, Lars E.; Shrout, Joshua D.; Bohn, Paul W. (January 2021, The Analyst)

   null (Ed.)

   The opportunistic pathogen Pseudomonas aeruginosa ( P. aeruginosa ) produces several redox-active phenazine metabolites, including pyocyanin (PYO) and phenazine-1-carboxamide (PCN), which are electron carrier molecules that also aid in virulence. In particular, PYO is an exclusive metabolite produced by P. aeruginosa , which acts as a virulence factor in hospital-acquired infections and is therefore a good biomarker for identifying early stage colonization by this pathogen. Here, we describe the use of nanopore electrode arrays (NEAs) exhibiting metal–insulator–metal ring electrode architectures for enhanced detection of these phenazine metabolites. The size of the nanopores allows phenazine metabolites to freely diffuse into the interior and access the working electrodes, while the bacteria are excluded. Consequently, highly efficient redox cycling reactions in the NEAs can be accessed by free diffusion unhindered by the presence of bacteria. This strategy yields low limits of detection, i.e. 10.5 and 20.7 nM for PYO and PCN, respectively, values far below single molecule pore occupancy, e.g. at 10.5 nM 〈 n pore 〉 ∼ 0.082 per nanopore – a limit which reflects the extraordinary signal amplification in the NEAs. Furthermore, experiments that compared results from minimal medium and rich medium show that P. aeruginosa produces the same types of phenazine metabolites even though growth rates and phenazine production patterns differ in these two media. The NEA measurement strategy developed here should be useful as a diagnostic for pathogens generally and for understanding metabolism in clinically important microbial communities. 

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