Your search keyword '"Jonathan M. Franks"' showing total 7 results

1. Corrigendum: Phenotypic and transcriptional characterization of F. tularensis LVS during transition into a viable but non-culturable state

Author

Stuart Cantlay, Nicole L. Garrison, Rachelle Patterson, Kassey Wagner, Zoei Kirk, Jun Fan, Donald A. Primerano, Mara L. G. Sullivan, Jonathan M. Franks, Donna B. Stolz, and Joseph Horzempa

Subjects

Francisella tularensis, viable but non-culturable (VBNC), RNA-Seq, transcriptomics, bacterial physiology, host-microbe interaction, Microbiology, QR1-502

Published

2024

2. Phenotypic and transcriptional characterization of F. tularensis LVS during transition into a viable but non-culturable state

Author

Stuart Cantlay, Nicole L. Garrison, Rachelle Patterson, Kassey Wagner, Zoei Kirk, Jun Fan, Donald A. Primerano, Mara L. G. Sullivan, Jonathan M. Franks, Donna B. Stolz, and Joseph Horzempa

Subjects

Francisella tularensis, viable but non-culturable (VBNC), RNA-Seq, transcriptomics, bacterial physiology, host-microbe interaction, Microbiology, QR1-502

Abstract

Francisella tularensis is a gram-negative, intracellular pathogen which can cause serious, potentially fatal, illness in humans. Species of F. tularensis are found across the Northern Hemisphere and can infect a broad range of host species, including humans. Factors affecting the persistence of F. tularensis in the environment and its epidemiology are not well understood, however, the ability of F. tularensis to enter a viable but non-culturable state (VBNC) may be important. A broad range of bacteria, including many pathogens, have been observed to enter the VBNC state in response to stressful environmental conditions, such as nutrient limitation, osmotic or oxidative stress or low temperature. To investigate the transition into the VBNC state for F. tularensis, we analyzed the attenuated live vaccine strain, F. tularensis LVS grown under standard laboratory conditions. We found that F. tularensis LVS rapidly and spontaneously enters a VBNC state in broth culture at 37°C and that this transition coincides with morphological differentiation of the cells. The VBNC bacteria retained an ability to interact with both murine macrophages and human erythrocytes in in vitro assays and were insensitive to treatment with gentamicin. Finally, we present the first transcriptomic analysis of VBNC F. tularensis, which revealed clear differences in gene expression, and we identify sets of differentially regulated genes which are specific to the VBNC state. Identification of these VBNC specific genes will pave the way for future research aimed at dissecting the molecular mechanisms driving entry into the VBNC state.

Published

2024

3. Phagocytosis is a primary determinant of pulmonary clearance of clinical Klebsiella pneumoniae isolates

Author

Rick van der Geest, Hongye Fan, Hernán F. Peñaloza, William G. Bain, Zeyu Xiong, Naina Kohli, Emily Larson, Mara L. G. Sullivan, Jonathan M. Franks, Donna B. Stolz, Ryota Ito, Kong Chen, Yohei Doi, Melanie J. Harriff, and Janet S. Lee

Subjects

respiratory infection, host defense, Klebsiella pneumoniae, phagocytosis, clinical isolates, macrophages, Microbiology, QR1-502

Abstract

IntroductionKlebsiella pneumoniae (Kp) is a common cause of hospital-acquired pneumonia. Although previous studies have suggested that evasion of phagocytic uptake is a virulence determinant of Kp, few studies have examined phagocytosis sensitivity in clinical Kp isolates.MethodsWe screened 19 clinical respiratory Kp isolates that were previously assessed for mucoviscosity for their sensitivity to macrophage phagocytic uptake, and evaluated phagocytosis as a functional correlate of in vivo Kp pathogenicity.ResultsThe respiratory Kp isolates displayed heterogeneity in the susceptibility to macrophage phagocytic uptake, with 14 out of 19 Kp isolates displaying relative phagocytosis-sensitivity compared to the reference Kp strain ATCC 43816, and 5 out of 19 Kp isolates displaying relative phagocytosis-resistance. Intratracheal infection with the non-mucoviscous phagocytosis-sensitive isolate S17 resulted in a significantly lower bacterial burden compared to infection with the mucoviscous phagocytosis-resistant isolate W42. In addition, infection with S17 was associated with a reduced inflammatory response, including reduced bronchoalveolar lavage fluid (BAL) polymorphonuclear (PMN) cell count, and reduced BAL TNF, IL-1β, and IL-12p40 levels. Importantly, host control of infection with the phagocytosis-sensitive S17 isolate was impaired in alveolar macrophage (AM)-depleted mice, whereas AM-depletion had no significant impact on host defense against infection with the phagocytosis-resistant W42 isolate.ConclusionAltogether, these findings show that phagocytosis is a primary determinant of pulmonary clearance of clinical Kp isolates.

Published

2023

4. Engineering rotating apical-out airway organoid for assessing respiratory cilia motility

Author

Piyumi Wijesekara, Prakarsh Yadav, Lydia A. Perkins, Donna B. Stolz, Jonathan M. Franks, Simon C. Watkins, Emily Reinoso Jacome, Steven L. Brody, Amjad Horani, Jian Xu, Amir Barati Farimani, and Xi Ren

Subjects

Molecular physiology, Bioengineering, Cell biology, Science

Abstract

Summary: Motile cilia project from the airway apical surface and directly interface with inhaled external environment. Owing to cilia’s nanoscale dimension and high beating frequency, quantitative assessment of their motility remains a sophisticated task. Here we described a robust approach for reproducible engineering of apical-out airway organoid (AOAO) from a defined number of cells. Propelled by exterior-facing cilia beating, the mature AOAO exhibited stable rotational motion when surrounded by Matrigel. We developed a computational framework leveraging computer vision algorithms to quantify AOAO rotation and correlated it with the direct measurement of cilia motility. We further established the feasibility of using AOAO rotation to recapitulate and measure defective cilia motility caused by chemotherapy-induced toxicity and by CCDC39 mutations in cells from patients with primary ciliary dyskinesia. We expect our rotating AOAO model and the associated computational pipeline to offer a generalizable framework to expedite the modeling of and therapeutic development for genetic and environmental ciliopathies.

Published

2022

5. The Role and Mechanism of Erythrocyte Invasion by Francisella tularensis

Author

Deanna M. Schmitt, Rebecca Barnes, Taylor Rogerson, Ashley Haught, Leanne K. Mazzella, Matthew Ford, Tricia Gilson, James W.-M. Birch, Anders Sjöstedt, Douglas S. Reed, Jonathan M. Franks, Donna B. Stolz, James Denvir, Jun Fan, Swanthana Rekulapally, Donald A. Primerano, and Joseph Horzempa

Subjects

erythrocyte invasion, tularemia, type VI secretion system, tick borne disease, spectrin, Microbiology, QR1-502

Abstract

Francisella tularensis is an extremely virulent bacterium that can be transmitted naturally by blood sucking arthropods. During mammalian infection, F. tularensis infects numerous types of host cells, including erythrocytes. As erythrocytes do not undergo phagocytosis or endocytosis, it remains unknown how F. tularensis invades these cells. Furthermore, the consequence of inhabiting the intracellular space of red blood cells (RBCs) has not been determined. Here, we provide evidence indicating that residing within an erythrocyte enhances the ability of F. tularensis to colonize ticks following a blood meal. Erythrocyte residence protected F. tularensis from a low pH environment similar to that of gut cells of a feeding tick. Mechanistic studies revealed that the F. tularensis type VI secretion system (T6SS) was required for erythrocyte invasion as mutation of mglA (a transcriptional regulator of T6SS genes), dotU, or iglC (two genes encoding T6SS machinery) severely diminished bacterial entry into RBCs. Invasion was also inhibited upon treatment of erythrocytes with venom from the Blue-bellied black snake (Pseudechis guttatus), which aggregates spectrin in the cytoskeleton, but not inhibitors of actin polymerization and depolymerization. These data suggest that erythrocyte invasion by F. tularensis is dependent on spectrin utilization which is likely mediated by effectors delivered through the T6SS. Our results begin to elucidate the mechanism of a unique biological process facilitated by F. tularensis to invade erythrocytes, allowing for enhanced colonization of ticks.

Published

2017

6. Predatory Bacteria can Reduce Pseudomonas aeruginosa Induced Corneal Perforation and Proliferation in a Rabbit Keratitis Model

Author

Eric G. Romanowski, Nicholas A. Stella, Bryn L. Brazile, Kira L. Lathrop, Jonathan M. Franks, Ian A. Sigal, Tami Kim, Mennat Elsayed, Daniel E. Kadouri, and Robert M.Q. Shanks

Subjects

Ophthalmology, Article

Abstract

PurposePseudomonas aeruginosakeratitis is a severe ocular infection that can lead to perforation of the cornea. In this study we evaluated the role of bacterial quorum sensing in generating corneal perforation and bacterial proliferation and tested whether co-injection of the predatory bacteriaBdellovibrio bacteriovoruscould alter the clinical outcome.P. aeruginosawithlasRmutations were observed among keratitis isolates from a study collecting samples from India, so an isogeniclasRmutant strain ofP. aeruginosawas included.MethodsRabbit corneas were intracorneally infected withP. aeruginosastrain PA14 or an isogenic ΔlasRmutant and co-injected with PBS orB. bacteriovorus. After 24 h, eyes were evaluated for clinical signs of infection. Samples were analyzed by scanning electron microscopy, optical coherence tomography, sectioned for histology, and corneas were homogenized for CFU enumeration and for inflammatory cytokines.ResultsWe observed that 54% of corneas infected by wild-type PA14 presented with a corneal perforation (n=24), whereas only 4% of PA14 infected corneas that were co-infected withB. bacteriovorusperforate (n=25). Wild-typeP. aeruginosaproliferation was reduced 7-fold in the predatory bacteria treated eyes. The ΔlasRmutant was less able to proliferate compared to the wild-type, but was largely unaffected byB. bacteriovorus.ConclusionThese studies indicate a role for bacterial quorum sensing in the ability ofP. aeruginosato proliferate and cause perforation of the rabbit cornea. Additionally, this study suggests that predatory bacteria can reduce the virulence ofP. aeruginosain an ocular prophylaxis model.

Published

2023

7. Blowing epithelial cell bubbles with GumB: ShlA-family pore-forming toxins induce blebbing and rapid cellular death in corneal epithelial cells

Author

Kimberly M. Brothers, Jake D. Callaghan, Nicholas A. Stella, Julianna M. Bachinsky, Mohammed AlHigaylan, Kara L. Lehner, Jonathan M. Franks, Kira L. Lathrop, Elliot Collins, Deanna M. Schmitt, Joseph Horzempa, and Robert M. Q. Shanks

Subjects

Serratia, Swine, Type V Secretion Systems, Cytotoxicity, Pathology and Laboratory Medicine, Toxicology, Epithelium, Cornea, Mice, Animal Cells, Medicine and Health Sciences, Biology (General), Phagocytic Cell, Serratia marcescens, 0303 health sciences, Pore-forming toxin, Eye Lens, Cell Death, biology, Chemistry, 030302 biochemistry & molecular biology, Epithelium, Corneal, Enterobacteriaceae, Bacterial Pathogens, 3. Good health, Cell biology, Mutant Strains, Medical Microbiology, Pathogens, Anatomy, Cellular Types, Research Article, Programmed cell death, Cell type, QH301-705.5, Ocular Anatomy, Necroptosis, Bacterial Toxins, Immunology, DNA construction, Proteus Mirabilis, Microbiology, Serratia Infections, 03 medical and health sciences, Ocular System, Virology, Genetics, Animals, Humans, Secretion, Bleb (cell biology), Microbial Pathogens, Molecular Biology, 030304 developmental biology, Bacteria, Perforin, Organisms, Biology and Life Sciences, Epithelial Cells, Cell Biology, RC581-607, Proteus, biology.organism_classification, Research and analysis methods, Molecular biology techniques, Biological Tissue, RAW 264.7 Cells, Mutation, Plasmid Construction, Parasitology, Immunologic diseases. Allergy, Proteus Infections

Abstract

Medical devices, such as contact lenses, bring bacteria in direct contact with human cells. Consequences of these host-pathogen interactions include the alteration of mammalian cell surface architecture and induction of cellular death that renders tissues more susceptible to infection. Gram-negative bacteria known to induce cellular blebbing by mammalian cells, Pseudomonas and Vibrio species, do so through a type III secretion system-dependent mechanism. This study demonstrates that a subset of bacteria from the Enterobacteriaceae bacterial family induce cellular death and membrane blebs in a variety of cell types via a type V secretion-system dependent mechanism. Here, we report that ShlA-family cytolysins from Proteus mirabilis and Serratia marcescens were required to induce membrane blebbling and cell death. Blebbing and cellular death were blocked by an antioxidant and RIP-1 and MLKL inhibitors, implicating necroptosis in the observed phenotypes. Additional genetic studies determined that an IgaA family stress-response protein, GumB, was necessary to induce blebs. Data supported a model where GumB and shlBA are in a regulatory circuit through the Rcs stress response phosphorelay system required for bleb formation and pathogenesis in an invertebrate model of infection and proliferation in a phagocytic cell line. This study introduces GumB as a regulator of S. marcescens host-pathogen interactions and demonstrates a common type V secretion system-dependent mechanism by which bacteria elicit surface morphological changes on mammalian cells. This type V secretion-system mechanism likely contributes bacterial damage to the corneal epithelial layer, and enables access to deeper parts of the tissue that are more susceptible to infection., Author summary Bacteria must overcome host defenses to cause infection. This is especially true for corneal infections where bacteria must penetrate the epithelium in order to gain access to the stroma where bacteria can rapidly multiply, induce inflammation, and cause vision loss. Members of the Enterobacteriaceae commonly cause contact lens associated infections, but the mechanisms by which they damage corneal cells are largely unknown. Here we present evidence that Serratia marcescens and Proteus mirabilis are able to induce dramatic morphological changes in mammalian corneal cells that correlates with rapid cellular death. Secretion of ShlA-like cytolysins via type V secretion was responsible for this phenotype, and this effect was regulated by the conserved Rcs phosphorelay stress response system, including IgaA-family protein GumB. This study provides a model for stress-mediated regulation of cytolysins that induce epithelial damage and promote ocular infection.

Published

2019