Your search keyword '"Gordon, Vernita"' showing total 5 results

1. Suspended multiwalled, acid-functionalized carbon nanotubes promote aggregation of the opportunistic pathogen Pseudomonas aeruginosa.

Author

Kovach K, Sabaraya IV, Patel P, Kirisits MJ, Saleh NB, and Gordon VD

Subjects

Biofilms drug effects, Biofilms growth & development, Suspensions, Anti-Bacterial Agents chemistry, Anti-Bacterial Agents pharmacology, Nanotubes, Carbon chemistry, Pseudomonas aeruginosa drug effects, Pseudomonas aeruginosa physiology

Abstract

The increasing prevalence of carbon nanotubes (CNTs) as components of new functional materials has the unintended consequence of causing increases in CNT concentrations in aqueous environments. Aqueous systems are reservoirs for bacteria, including human and animal pathogens, that can form biofilms. At high concentrations, CNTs have been shown to display biocidal effects; however, at low concentrations, the interaction between CNTs and bacteria is more complicated, and antimicrobial action is highly dependent upon the properties of the CNTs in suspension. Here, impact of low concentrations of multiwalled CNTs (MWCNTs) on the biofilm-forming opportunistic human pathogen Pseudomonas aeruginosa is studied. Using phase contrast and confocal microscopy, flow cytometry, and antibiotic tolerance assays, it is found that sub-lethal concentrations (2 mg/L) of MWCNTs promote aggregation of P. aeruginosa into multicellular clusters. However, the antibiotic tolerance of these "young" bacterial-CNT aggregates is similar to that of CNT-free cultures. Overall, our results indicate that the co-occurrence of MWCNTs and P. aeruginosa in aqueous systems, which promotes the increased number and size of bacterial aggregates, could increase the dose to which humans or animals are exposed., Competing Interests: The authors have declared that no competing interests exist.

Published

2020

2. From molecules to multispecies ecosystems: the roles of structure in bacterial biofilms.

Author

Gordon V, Bakhtiari L, and Kovach K

Subjects

Biological Transport, Cell Communication drug effects, Cellular Microenvironment drug effects, Computational Biology methods, Molecular Structure, Particle Size, Structure-Activity Relationship, Surface Properties, Anti-Bacterial Agents chemistry, Bacteria metabolism, Biofilms drug effects, Ecosystem, Polymers chemistry, Proteins chemistry

Abstract

Biofilms are communities of sessile microbes that are bound to each other by a matrix made of biopolymers and proteins. Spatial structure is present in biofilms on many lengthscales. These range from the nanometer scale of molecular motifs to the hundred-micron scale of multicellular aggregates. Spatial structure is a physical property that impacts the biology of biofilms in many ways. The molecular structure of matrix components controls their interaction with each other (thereby impacting biofilm mechanics) and with diffusing molecules such as antibiotics and immune factors (thereby impacting antibiotic tolerance and evasion of the immune system). The size and structure of multicellular aggregates, combined with microbial consumption of growth substrate, give rise to differentiated microenvironments with different patterns of metabolism and gene expression. Spatial association of more than one species can benefit one or both species, while distances between species can both determine and result from the transport of diffusible factors between species. Thus, a widespread theme in the biological importance of spatial structure in biofilms is the effect of structure on transport. We survey what is known about this and other effects of spatial structure in biofilms, from molecules up to multispecies ecosystems. We conclude with an overview of what experimental approaches have been developed to control spatial structure in biofilms and how these and other experiments can be complemented with computational work.

Published

2019

3. The spatial profiles and metabolic capabilities of microbial populations impact the growth of antibiotic-resistant mutants.

Author

Kaushik KS, Ratnayeke N, Katira P, and Gordon VD

Subjects

Humans, Anti-Bacterial Agents metabolism, Drug Resistance, Bacterial physiology, Microbial Viability, Models, Biological, Mutation, Pseudomonas aeruginosa genetics, Pseudomonas aeruginosa metabolism

Abstract

Antibiotic resistance adversely affects clinical and public health on a global scale. Using the opportunistic human pathogen Pseudomonas aeruginosa, we show that increasing the number density of bacteria, on agar containing aminoglycoside antibiotics, can non-monotonically impact the survival of antibiotic-resistant mutants. Notably, at high cell densities, mutant survival is inhibited. A wide range of bacterial species can inhibit antibiotic-resistant mutants. Inhibition results from the metabolic breakdown of amino acids, which results in alkaline by-products. The consequent increase in pH acts in conjunction with aminoglycosides to mediate inhibition. Our work raises the possibility that the manipulation of microbial population structure and nutrient environment in conjunction with existing antibiotics could provide therapeutic approaches to combat antibiotic resistance., (© 2015 The Author(s) Published by the Royal Society. All rights reserved.)

Published

2015

4. A low-cost, hands-on module to characterize antimicrobial compounds using an interdisciplinary, biophysical approach.

Author

Kaushik KS, Kessel A, Ratnayeke N, and Gordon VD

Subjects

Disk Diffusion Antimicrobial Tests economics, Drug Resistance, Bacterial, Escherichia coli drug effects, Humans, Microbiology economics, Anti-Bacterial Agents pharmacology, Microbiology education

Abstract

We have developed a hands-on experimental module that combines biology experiments with a physics-based analytical model in order to characterize antimicrobial compounds. To understand antibiotic resistance, participants perform a disc diffusion assay to test the antimicrobial activity of different compounds and then apply a diffusion-based analytical model to gain insights into the behavior of the active antimicrobial component. In our experience, this module was robust, reproducible, and cost-effective, suggesting that it could be implemented in diverse settings such as undergraduate research, STEM (science, technology, engineering, and math) camps, school programs, and laboratory training workshops. By providing valuable interdisciplinary research experience in science outreach and education initiatives, this module addresses the paucity of structured training or education programs that integrate diverse scientific fields. Its low-cost requirements make it especially suitable for use in resource-limited settings.

Published

2015

5. Synthetic antimicrobial oligomers induce a composition-dependent topological transition in membranes.

Author

Yang L, Gordon VD, Mishra A, Som A, Purdy KR, Davis MA, Tew GN, and Wong GC

Subjects

Alkynes chemical synthesis, Alkynes pharmacology, Anti-Bacterial Agents chemical synthesis, Bacillus subtilis drug effects, Bacillus subtilis metabolism, Biomimetic Materials chemical synthesis, Biomimetic Materials chemistry, Biomimetic Materials pharmacology, Cell Membrane chemistry, Cell Membrane drug effects, Cell Membrane metabolism, Escherichia coli drug effects, Escherichia coli metabolism, Ethers chemical synthesis, Ethers pharmacology, Liposomes chemistry, Microbial Sensitivity Tests, Models, Molecular, Phosphatidylcholines chemistry, Phosphatidylethanolamines chemistry, Phosphatidylglycerols chemistry, Scattering, Small Angle, X-Ray Diffraction, Alkynes chemistry, Anti-Bacterial Agents chemistry, Anti-Bacterial Agents pharmacology, Antimicrobial Cationic Peptides chemistry, Ethers chemistry, Glycerophospholipids chemistry

Abstract

Antimicrobial peptides (AMPs) are cationic amphiphiles that comprise a key component of innate immunity. Synthetic analogues of AMPs, such as the family of phenylene ethynylene antimicrobial oligomers (AMOs), recently demonstrated broad-spectrum antimicrobial activity, but the underlying molecular mechanism is unknown. Homologues in this family can be inactive, specifically active against bacteria, or nonspecifically active against bacteria and eukaryotic cells. Using synchrotron small-angle X-ray scattering (SAXS), we show that observed antibacterial activity correlates with an AMO-induced topological transition of small unilamellar vesicles into an inverted hexagonal phase, in which hexagonal arrays of 3.4-nm water channels defined by lipid tubes are formed. Polarized and fluorescence microscopy show that AMO-treated giant unilamellar vesicles remain intact, instead of reconstructing into a bulk 3D phase, but are selectively permeable to encapsulated macromolecules that are smaller than 3.4 nm. Moreover, AMOs with different activity profiles require different minimum threshold concentrations of phosphoethanolamine (PE) lipids to reconstruct the membrane. Using ternary membrane vesicles composed of DOPG:DOPE:DOPC with a charge density fixed at typical bacterial values, we find that the inactive AMO cannot generate the inverted hexagonal phase even when DOPE completely replaces DOPC. The specifically active AMO requires a threshold ratio of DOPE:DOPC = 4:1, and the nonspecifically active AMO requires a drastically lower threshold ratio of DOPE:DOPC = 1.5:1. Since most gram-negative bacterial membranes have more PE lipids than do eukaryotic membranes, our results imply that there is a relationship between negative-curvature lipids such as PE and antimicrobial hydrophobicity that contributes to selective antimicrobial activity.

Published

2007