Your search keyword '"Siegrist MS"' showing total 7 results

1. Enhancing the Anticancer Activity of Attenuated Listeria monocytogenes by Cell Wall Functionalization with "Clickable" Doxorubicin.

Author

Lepori I, Roncetti M, Vitiello M, Barresi E, De Paolo R, Tentori PM, Baldanzi C, Santi M, Evangelista M, Signore G, Tedeschi L, Gravekamp C, Cardarelli F, Taliani S, Da Settimo F, Siegrist MS, and Poliseno L

Subjects

Animals, Humans, Cell Line, Tumor, Antineoplastic Agents pharmacology, Antineoplastic Agents chemistry, Drug Carriers chemistry, Listeria monocytogenes drug effects, Doxorubicin pharmacology, Zebrafish, Click Chemistry, Cell Wall drug effects

Abstract

Among bacteria used as anticancer vaccines, attenuated Listeria monocytogenes (Lm at ) stands out, because it spreads from one infected cancer cell to the next, induces a strong adaptive immune response, and is suitable for repeated injection cycles. Here, we use click chemistry to functionalize the Lm at cell wall and turn the bacterium into an "intelligent carrier" of the chemotherapeutic drug doxorubicin. Doxorubicin-loaded Lm at retains most of its biological properties and, compared to the control fluorophore-functionalized bacteria, shows enhanced cytotoxicity against melanoma cells both in vitro and in a xenograft model in zebrafish. Our results show that drugs can be covalently loaded on the Lm at cell wall and pave the way to the development of new two-in-one therapeutic approaches combining immunotherapy with chemotherapy.

Published

2024

2. Contact Area and Deformation of Escherichia coli Cells Adhered on a Cationic Surface.

Author

Xu Z, Gamble A, Niu WA, Smith MN, Siegrist MS, Tuominen M, and Santore MM

Subjects

Biofilms, Bacteria, Cell Membrane, Anti-Bacterial Agents, Cations, Surface Properties, Escherichia coli physiology, Bacterial Adhesion physiology

Abstract

When bacteria adhere to surfaces, the chemical and mechanical character of the cell-substrate interface guides cell function and the development of microcolonies and biofilms. Alternately on bactericidal surfaces, intimate contact is critical to biofilm prevention. The direct study of the buried cell-substrate interfaces at the heart of these behaviors is hindered by the small bacterial cell size and inaccessibility of the contact region. Here, we present a total internal reflectance fluorescence depletion approach to measure the size of the cell-substrate contact region and quantify the gap separation and curvature near the contact zone, providing an assessment of the shapes of the near-surface undersides of adhered bacterial cells. Resolution of the gap height is about 10%, down to a few nanometers at contact. Using 1 and 2 μm silica spheres as calibration standards we report that, for flagella-free Escherichia coli ( E. coli) adhering on a cationic poly-l-lysine layer, the cell-surface contact and apparent cell deformation vary with adsorbed cell configuration. Most cells adhere by their ends, achieving small contact areas of 0.15 μm 2 , corresponding to about 1-2% of the cell's surface. The altered Gaussian curvatures of end-adhered cells suggest the flattening of the envelope within the small contact region. When cells adhere by their sides, the contact area is larger, in the range 0.3-1.1 μm 2 and comprising up to ∼12% of the cell's total surface. A region of sharper curvature, greater than that of the cells' original spherocylindrical shape, borders the flat contact region in cases of side-on or end-on cell adhesion, suggesting envelope stress. From the measured curvatures, precise stress distributions over the cell surface could be calculated in future studies that incorporate knowledge of envelope moduli. Overall the small contact areas of end-adhered cells may be a limiting factor for antimicrobial surfaces that kill on contact rather than releasing bactericide.

Published

2023

3. Metabolic Processing of Selenium-Based Bioisosteres of meso -Diaminopimelic Acid in Live Bacteria.

Author

Apostolos AJ, Ocius KL, Koyasseril-Yehiya TM, Santamaria C, Silva JRA, Lameira J, Alves CN, Siegrist MS, and Pires MM

Subjects

Cell Wall chemistry, Diaminopimelic Acid metabolism, Peptidoglycan chemistry, Mycobacterium metabolism, Selenium

Abstract

A primary component of all known bacterial cell walls is the peptidoglycan (PG) layer, which is composed of repeating units of sugars connected to short and unusual peptides. The various steps within PG biosynthesis are targets of potent antibiotics as proper assembly of the PG is essential for cellular growth and survival. Synthetic mimics of PG have proven to be indispensable tools to study the bacterial cell structure, growth, and remodeling. Yet, a common component of PG, meso -diaminopimelic acid ( m -DAP) at the third position of the stem peptide, remains challenging to access synthetically and is not commercially available. Here, we describe the synthesis and metabolic processing of a selenium-based bioisostere of m -DAP (selenolanthionine) and show that it is installed within the PG of live bacteria by the native cell wall crosslinking machinery in mycobacterial species. This PG probe has an orthogonal release mechanism that could be important for downstream proteomics studies. Finally, we describe a bead-based assay that is compatible with high-throughput screening of cell wall enzymes. We envision that this probe will supplement the current methods available for investigating PG crosslinking in m -DAP-containing organisms.

Published

2022

4. Surface Chemistry Guides the Orientations of Adhering E. coli Cells Captured from Flow.

Author

Xu Z, Niu WA, Rivera SL, Tuominen MT, Siegrist MS, and Santore MM

Subjects

Biofilms, Hydrophobic and Hydrophilic Interactions, Surface Properties, Bacterial Adhesion, Escherichia coli

Abstract

Motivated by observations of cell orientation at biofilm-substrate interfaces and reports that cell orientation and adhesion play important roles in biofilm evolution and function, we investigated the influence of surface chemistry on the orientation of Escherichia coli cells captured from flow onto surfaces that were cationic, hydrophobic, or anionic. We characterized the initial orientations of nonmotile cells captured from gentle shear relative to the surface and flow directions. The broad distribution of captured cell orientations observed on cationic surfaces suggests that rapid electrostatic attractions of cells to oppositely charged surfaces preserve the instantaneous orientations of cells as they rotate in the near-surface shearing flow. By contrast, on hydrophobic and anionic surfaces, cells were oriented slightly more in the plane of the surface and in the flow direction compared with that on the cationic surface. This suggests slower development of adhesion at hydrophobic and anionic surfaces, allowing cells to tip toward the surface as they adhere. Once cells were captured, the flow was increased by 20-fold. Cells did not reorient substantially on the cationic surface, suggesting a strong cell-surface bonding. By contrast, on hydrophobic and anionic surfaces, increased shear forced cells to tip toward the surface and align in the flow direction, a process that was reversible upon reducing the shear. These findings suggest mechanisms by which surface chemistry may play a role in the evolving structure and function of microbial communities.

Published

2021

5. Photoactivatable Glycolipid Probes for Identifying Mycolate-Protein Interactions in Live Mycobacteria.

Author

Kavunja HW, Biegas KJ, Banahene N, Stewart JA, Piligian BF, Groenevelt JM, Sein CE, Morita YS, Niederweis M, Siegrist MS, and Swarts BM

Subjects

Humans, Click Chemistry methods, Glycolipids chemistry, Mycobacterium pathogenicity, Proteins metabolism

Abstract

Mycobacteria have a distinctive glycolipid-rich outer membrane, the mycomembrane, which is a critical target for tuberculosis drug development. However, proteins that associate with the mycomembrane, or that are involved in its metabolism and host interactions, are not well-characterized. To facilitate the study of mycomembrane-related proteins, we developed photoactivatable trehalose monomycolate analogues that metabolically incorporate into the mycomembrane in live mycobacteria, enabling in vivo photo-cross-linking and click-chemistry-mediated analysis of mycolate-interacting proteins. When deployed in Mycobacterium smegmatis with quantitative proteomics, this strategy enriched over 100 proteins, including the mycomembrane porin (MspA), several proteins with known mycomembrane synthesis or remodeling functions (CmrA, MmpL3, Ag85, Tdmh), and numerous candidate mycolate-interacting proteins. Our approach is highly versatile, as it (i) enlists click chemistry for flexible protein functionalization; (ii) in principle can be applied to any mycobacterial species to identify endogenous bacterial proteins or host proteins that interact with mycolates; and (iii) can potentially be expanded to investigate protein interactions with other mycobacterial lipids. This tool is expected to help elucidate fundamental physiological and pathological processes related to the mycomembrane and may reveal novel diagnostic and therapeutic targets.

Published

2020

6. (D)-Amino acid chemical reporters reveal peptidoglycan dynamics of an intracellular pathogen.

Author

Siegrist MS, Whiteside S, Jewett JC, Aditham A, Cava F, and Bertozzi CR

Subjects

Alanine chemistry, Click Chemistry, Listeria monocytogenes chemistry, Listeria monocytogenes cytology, Molecular Conformation, Peptidoglycan biosynthesis, Peptidoglycan chemistry, Alanine metabolism, Listeria monocytogenes metabolism, Molecular Dynamics Simulation, Peptidoglycan metabolism

Abstract

Peptidoglycan (PG) is an essential component of the bacterial cell wall. Although experiments with organisms in vitro have yielded a wealth of information on PG synthesis and maturation, it is unclear how these studies translate to bacteria replicating within host cells. We report a chemical approach for probing PG in vivo via metabolic labeling and bioorthogonal chemistry. A wide variety of bacterial species incorporated azide and alkyne-functionalized d-alanine into their cell walls, which we visualized by covalent reaction with click chemistry probes. The d-alanine analogues were specifically incorporated into nascent PG of the intracellular pathogen Listeria monocytogenes both in vitro and during macrophage infection. Metabolic incorporation of d-alanine derivatives and click chemistry detection constitute a facile, modular platform that facilitates unprecedented spatial and temporal resolution of PG dynamics in vivo.

Published

2013

7. Probing the mycobacterial trehalome with bioorthogonal chemistry.

Author

Swarts BM, Holsclaw CM, Jewett JC, Alber M, Fox DM, Siegrist MS, Leary JA, Kalscheuer R, and Bertozzi CR

Subjects

Alkynes chemistry, Azides chemistry, Fluorescent Dyes chemistry, Glycolipids metabolism, Mycobacterium metabolism, Trehalose chemistry, Trehalose metabolism

Abstract

Mycobacteria, including the pathogen Mycobacterium tuberculosis, use the non-mammalian disaccharide trehalose as a precursor for essential cell-wall glycolipids and other metabolites. Here we describe a strategy for exploiting trehalose metabolic pathways to label glycolipids in mycobacteria with azide-modified trehalose (TreAz) analogues. Subsequent bioorthogonal ligation with alkyne-functionalized probes enabled detection and visualization of cell-surface glycolipids. Characterization of the metabolic fates of four TreAz analogues revealed unique labeling routes that can be harnessed for pathway-targeted investigation of the mycobacterial trehalome.

Published

2012