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1. Coherent light scattering from cellular dynamics in living tissues

   https://doi.org/10.1088/1361-6633/ad2229  

   Nolte, David D. ( March 2024 , Reports on Progress in Physics)

   This review examines the biological physics of intracellular transport probed by the coherent optics of dynamic light scattering from optically thick living tissues. Cells and their constituents are in constant motion, composed of a broad range of speeds spanning many orders of magnitude that reflect the wide array of functions and mechanisms that maintain cellular health. From the organelle scale of tens of nanometers and upward in size, the motion inside living tissue is actively driven rather than thermal, propelled by the hydrolysis of bioenergetic molecules and the forces of molecular motors. Active transport can mimic the random walks of thermal Brownian motion, but mean-squared displacements are far from thermal equilibrium and can display anomalous diffusion through Lévy or fractional Brownian walks. Despite the average isotropic three-dimensional environment of cells and tissues, active cellular or intracellular transport of single light-scattering objects is often pseudo-one-dimensional, for instance as organelle displacement persists along cytoskeletal tracks or as membranes displace along the normal to cell surfaces, albeit isotropically oriented in three dimensions. Coherent light scattering is a natural tool to characterize such tissue dynamics because persistent directed transport induces Doppler shifts in the scattered light. The many frequency-shifted partial waves from the complex and dynamic media interfere to produce dynamic speckle that reveals tissue-scale processes through speckle contrast imaging and fluctuation spectroscopy. Low-coherence interferometry, dynamic optical coherence tomography, diffusing-wave spectroscopy, diffuse-correlation spectroscopy, differential dynamic microscopy and digital holography offer coherent detection methods that shed light on intracellular processes. In health-care applications, altered states of cellular health and disease display altered cellular motions that imprint on the statistical fluctuations of the scattered light. For instance, the efficacy of medical therapeutics can be monitored by measuring the changes they induce in the Doppler spectra of livingex vivocancer biopsies.

    

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2. Murine Models for Staphylococcal Infection

   https://doi.org/10.1002/cpz1.52  

   Klopfenstein, Nathan ; Cassat, James E. ; Monteith, Andrew ; Miller, Anderson ; Drury, Sydney ; Skaar, Eric ; Serezani, C. Henrique ( March 2021 , Current Protocols)

   Staphylococcus aureusis a Gram‐positive bacterium that colonizes almost every organ in humans and mice and is a leading cause of diseases worldwide.S. aureusinfections can be challenging to treat due to widespread antibiotic resistance and their ability to cause tissue damage. The primary modes of transmission ofS. aureusare via direct contact with a colonized or infected individual or invasive spread from a colonization niche in the same individual.S. aureuscan cause a myriad of diseases, including skin and soft tissue infections (SSTIs), osteomyelitis, pneumonia, endocarditis, and sepsis.S. aureusinfection is characterized by the formation of purulent lesions known as abscesses, which are rich in live and dead neutrophils, macrophages, and surrounded by a capsule containing fibrin and collagen. Different strains ofS. aureusproduce varying amounts of toxins that evade and/or elicit immune responses. Therefore, animal models ofS. aureusinfection provide a unique opportunity to understand the dynamics of organ‐specific immune responses and modifications in the pathogen that could favor the establishment of the pathogen. With advances in in vivo imaging of fluorescent transgenic mice, combined with fluorescent/bioluminescent bacteria, we can use mouse models to better understand the immune response to these types of infections. By understanding the host and bacterial dynamics within various organ systems, we can develop therapeutics to eliminate these pathogens. This module describes in vivo mouse models of both local and systemicS. aureusinfection. © 2021 Wiley Periodicals LLC.

   This article was corrected on 20 July 2022. See the end of the full text for details.

   Basic Protocol 1: Murine model ofStaphylococcus aureussubcutaneous infection

   Alternate Protocol: Murine tape stripping skin infection model

   Basic Protocol 2: Sample collection to determine skin structure, production of inflammatory mediators, and bacterial load

   Basic Protocol 3: Murine model of post‐traumaticStaphylococcus aureusosteomyelitis

   Basic Protocol 4: Intravenous infection of the retro‐orbital sinus

   Support Protocol: Preparation of the bacterial inoculum

    

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3. Sub-inhibitory antibiotic treatment selects for enhanced metabolic efficiency

   https://doi.org/10.1128/spectrum.03241-23  

   Aduru, Sai Varun ; Szenkiel, Karolina ; Rahman, Anika ; Ahmad, Mehrose ; Fabozzi, Maya ; Smith, Robert P. ; Lopatkin, Allison J. ( February 2024 , Microbiology Spectrum)

   Zhang, Xue (Ed.)

   Bacterial growth and metabolic rates are often closely related. However, under antibiotic selection, a paradox in this relationship arises: antibiotic efficacy decreases when bacteria are metabolically dormant, yet antibiotics select for resistant cells that grow fastest during treatment. That is, antibiotic selection counterintuitively favors bacteria with fast growth but slow metabolism. Despite this apparent contradiction, antibiotic resistant cells have historically been characterized primarily in the context of growth, whereas the extent of analogous changes in metabolism is comparatively unknown. Here, we observed that previously evolved antibiotic-resistant strains exhibited a unique relationship between growth and metabolism whereby nutrient utilization became more efficient, regardless of the growth rate. To better understand this unexpected phenomenon, we used a simplified model to simulate bacterial populations adapting to sub-inhibitory antibiotic selection through successive bottlenecking events. Simulations predicted that sub-inhibitory bactericidal antibiotic concentrations could select for enhanced metabolic efficiency, defined based on nutrient utilization: drug-adapted cells are able to achieve the same biomass while utilizing less substrate, even in the absence of treatment. Moreover, simulations predicted that restoring metabolic efficiency would re-sensitize resistant bacteria exhibiting metabolic-dependent resistance; we confirmed this result using adaptive laboratory evolutions ofEscherichia coliunder carbenicillin treatment. Overall, these results indicate that metabolic efficiency is under direct selective pressure during antibiotic treatment and that differences in evolutionary context may determine both the efficacy of different antibiotics and corresponding re-sensitization approaches.

   The sustained emergence of antibiotic-resistant pathogens combined with the stalled drug discovery pipelines highlights the critical need to better understand the underlying evolution mechanisms of antibiotic resistance. To this end, bacterial growth and metabolic rates are often closely related, and resistant cells have historically been characterized exclusively in the context of growth. However, under antibiotic selection, antibiotics counterintuitively favor cells with fast growth, and slow metabolism. Through an integrated approach of mathematical modeling and experiments, this study thereby addresses the significant knowledge gap of whether antibiotic selection drives changes in metabolism that complement, and/or act independently, of antibiotic resistance phenotypes.

    

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4. Facile accelerated specific therapeutic (FAST) platform develops antisense therapies to counter multidrug-resistant bacteria

   https://doi.org/10.1038/s42003-021-01856-1  

   Eller, Kristen A. ; Aunins, Thomas R. ; Courtney, Colleen M. ; Campos, Jocelyn K. ; Otoupal, Peter B. ; Erickson, Keesha E. ; Madinger, Nancy E. ; Chatterjee, Anushree ( March 2021 , Communications Biology)

   Multidrug-resistant (MDR) bacteria pose a grave concern to global health, which is perpetuated by a lack of new treatments and countermeasure platforms to combat outbreaks or antibiotic resistance. To address this, we have developed a Facile Accelerated Specific Therapeutic (FAST) platform that can develop effective peptide nucleic acid (PNA) therapies against MDR bacteria within a week. Our FAST platform uses a bioinformatics toolbox to design sequence-specific PNAs targeting non-traditional pathways/genes of bacteria, then performs in-situ synthesis, validation, and efficacy testing of selected PNAs. As a proof of concept, these PNAs were tested against five MDR clinical isolates: carbapenem-resistantEscherichia coli, extended-spectrum beta-lactamaseKlebsiella pneumoniae, New Delhi Metallo-beta-lactamase-1 carryingKlebsiella pneumoniae, and MDRSalmonella enterica. PNAs showed significant growth inhibition for 82% of treatments, with nearly 18% of treatments leading to greater than 97% decrease. Further, these PNAs are capable of potentiating antibiotic activity in the clinical isolates despite presence of cognate resistance genes. Finally, the FAST platform offers a novel delivery approach to overcome limited transport of PNAs into mammalian cells by repurposing the bacterial Type III secretion system in conjunction with a kill switch that is effective at eliminating 99.6% of an intracellularSalmonellainfection in human epithelial cells.

    

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5. Modeling and Cost Benefit Analysis to Guide Deployment of POC Diagnostics for Non-typhoidal Salmonella Infections with Antimicrobial Resistance

   https://doi.org/10.1038/s41598-019-47359-2  

   Manore, Carrie ; Graham, Todd ; Carr, Alexa ; Feryn, Alicia ; Jakhar, Shailja ; Mukundan, Harshini ; Highlander, Hannah Callender ( August 2019 , Scientific Reports)

   Invasive non-typhoidalSalmonella(NTS) is among the leading causes of blood stream infections in sub-Saharan Africa and other developing regions, especially among pediatric populations. Invasive NTS can be difficult to treat and have high case-fatality rates, in part due to emergence of strains resistant to broad-spectrum antibiotics. Furthermore, improper treatment contributes to increased antibiotic resistance and death. Point of care (POC) diagnostic tests that rapidly identify invasive NTS infection, and differentiate between resistant and non-resistant strains, may greatly improve patient outcomes and decrease resistance at the community level. Here we present for the first time a model for NTS dynamics in high risk populations that can analyze the potential advantages and disadvantages of four strategies involving POC diagnostic deployment, and the resulting impact on antimicrobial treatment for patients. Our analysis strongly supports the use of POC diagnostics coupled with targeted antibiotic use for patients upon arrival in the clinic for optimal patient and public health outcomes. We show that even the use of imperfect POC diagnostics can significantly reduce total costs and number of deaths, provided that the diagnostic gives results quickly enough that patients are likely to return or stay to receive targeted treatment.

    

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