Mechanisms of frustrated phagocytic spreading of human neutrophils on antibody-coated surfaces

Francis, Emmet A.; Xiao, Hugh; Teng, Lay Heng; Heinrich, Volkmar

doi:10.1101/2022.02.18.481104

Cited by 3 publications

(17 citation statements)

References 73 publications

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“…Reflecting the above-mentioned contrasting mechanistic notions about the driving force of generic cell spreading, two hypotheses have been put forward to explain phagocytic spreading, i.e., the “Brownian zipper” and “protrusive zipper” models [ 23 ]. Both models concur that fresh contact between the cell membrane and target surface results in a zipper-like adhesive attachment that is essentially irreversible, in agreement with experimental observations [ 16 , 24 , 25 ]. However, regarding the driving force of cellular advancement, the Brownian zipper model postulates that strong adhesion alone is responsible for pulling the cell membrane onto the target surface.…”

Section: Introductionsupporting

confidence: 88%

Integrative experimental/computational approach establishes active cellular protrusion as the primary driving force of phagocytic spreading by immune cells

Francis

Heinrich

2022

PLoS Comput Biol

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The dynamic interplay between cell adhesion and protrusion is a critical determinant of many forms of cell motility. When modeling cell spreading on adhesive surfaces, traditional mathematical treatments often consider passive cell adhesion as the primary, if not exclusive, mechanistic driving force of this cellular motion. To better assess the contribution of active cytoskeletal protrusion to immune-cell spreading during phagocytosis, we here develop a computational framework that allows us to optionally investigate both purely adhesive spreading (“Brownian zipper hypothesis”) as well as protrusion-dominated spreading (“protrusive zipper hypothesis”). We model the cell as an axisymmetric body of highly viscous fluid surrounded by a cortex with uniform surface tension and incorporate as potential driving forces of cell spreading an attractive stress due to receptor-ligand binding and an outward normal stress representing cytoskeletal protrusion, both acting on the cell boundary. We leverage various model predictions against the results of a directly related experimental companion study of human neutrophil phagocytic spreading on substrates coated with different densities of antibodies. We find that the concept of adhesion-driven spreading is incompatible with experimental results such as the independence of the cell-spreading speed on the density of immobilized antibodies. In contrast, the protrusive zipper model agrees well with experimental findings and, when adapted to simulate cell spreading on discrete adhesion sites, it also reproduces the observed positive correlation between antibody density and maximum cell-substrate contact area. Together, our integrative experimental/computational approach shows that phagocytic spreading is driven by cellular protrusion, and that the extent of spreading is limited by the density of adhesion sites.

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Section: Introductionsupporting

confidence: 88%

Integrative experimental/computational approach establishes active cellular protrusion as the primary driving force of phagocytic spreading by immune cells

Francis

Heinrich

2022

PLoS Comput Biol

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“…Error bars in both (D) and (E) indicate standard deviation. The IgG density was quantified for each condition as described in [19].…”

Section: Resultsmentioning

confidence: 99%

“…The computational framework presented in the previous section can be adopted to simulate interactions by various cell types with targets of different axisymmetric geometries. Our present focus on human neutrophils spreading on flat substrates is motivated by a wealth of experimental results obtained for this particular scenario and presented in a companion paper [19]. In brief, we exposed cells to glass coverslips coated with IgG antibodies at densities ( ρ IgG ) spanning ~3 orders of magnitude.…”

Section: Resultsmentioning

confidence: 99%

“…These experimental results provide useful quantitative benchmarks for comparison with computer simulations and will be used in the following sections to evaluate the validity of different mechanistic notions about cell spreading. The IgG density was quantified for each condition as described in [24].…”

Section: Quantitative Experimental Results For the Validation Of Mode...mentioning

confidence: 99%

“…We seek to establish which of these hypotheses is more realistic by developing mathematical models of the mechanics of isotropic cell spreading and comparing our theoretical predictions with experimental observations of human neutrophils spreading on flat, IgG-coated surfaces. As reported in detail in a companion paper, our experimental design allowed us to examine the spreading behavior of neutrophils on surfaces coated with different densities of IgG [19]. Because higher IgG densities correspond to stronger adhesive forces, we reasoned that the Brownian zipper model should predict a much stronger correlation between IgG density and rate of contact-area growth (“spreading speed”) than the protrusive zipper model.…”

Section: Introductionmentioning

confidence: 99%

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Integrative experimental/computational approach establishes active cellular protrusion as the primary driving force of phagocytic spreading by immune cells

Francis

Heinrich

2022

Preprint

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The dynamic interplay between cell adhesion and protrusion is a critical determinant of many forms of cell motility. When modeling cell spreading on adhesive surfaces, traditional mathematical treatments often consider passive cell adhesion as the primary, if not exclusive, mechanistic driving force of this cellular motion. To better assess the contribution of active cytoskeletal protrusion to immune-cell spreading during phagocytosis, we here develop a computational framework that allows us to optionally investigate both purely adhesive spreading ("Brownian zipper hypothesis") as well as protrusion-dominated spreading ("protrusive zipper hypothesis"). We model the cell as an axisymmetric body of highly viscous fluid surrounded by a cortex with uniform surface tension and incorporate as potential driving forces of cell spreading an attractive stress due to receptor-ligand binding and an outward normal stress representing cytoskeletal protrusion, both acting on the cell boundary. We leverage various model predictions against the results of a directly related experimental companion study of human neutrophil phagocytic spreading on substrates coated with different densities of antibodies. We find that the concept of adhesion-driven spreading is incompatible with experimental results such as the independence of the cell-spreading speed on the density of immobilized antibodies. In contrast, the protrusive zipper model agrees well with experimental findings and, when adapted to simulate cell spreading on discrete adhesion sites, it also reproduces the observed positive correlation between antibody density and maximum cell-substrate contact area. Together, our integrative experimental/computational approach shows that phagocytic spreading is driven by cellular protrusion, and that the extent of spreading is limited by the density of adhesion sites.

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A Theoretical Model for Phagocytic Capacity of Phagocytes

Guan

2022

Advcd Theory and Sims

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This work seeks to establish a theoretical model that links phagocytic capacity of phagocytes with geometries of phagocytes and phagocytic objects. The model is applied to four different types of phagocytic objects: a flat surface, a microsphere, a microdisk, and a population of microspheres. For the flat surface, the model assumes that a phagocyte maximizes its contact area between the flat surface and minimizes its non‐contact surface area under a constraint exerted by the volume of the phagocyte's cellular contents. For any of the other three types of objects, the model assumes that a phagocyte completely phagocytoses the object(s) by exhausting its available membrane area. It also assumes that the post‐phagocytosis phagocyte minimizes its surface area. Moreover, the volume of the phagocyte's cellular contents and the geometry of the object impose constraints on the model. For each case, two governing equations are established and combined to derive a single explicit equation with the phagocyte's phagocytic capacity as a function of other parameters. The equations are applied to experimental data for macrophages and neutrophils in the literature. Methods for extending the model and experimentally testing it are discussed.

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Mechanisms of frustrated phagocytic spreading of human neutrophils on antibody-coated surfaces

Cited by 3 publications

References 73 publications

Integrative experimental/computational approach establishes active cellular protrusion as the primary driving force of phagocytic spreading by immune cells

Integrative experimental/computational approach establishes active cellular protrusion as the primary driving force of phagocytic spreading by immune cells

Integrative experimental/computational approach establishes active cellular protrusion as the primary driving force of phagocytic spreading by immune cells

A Theoretical Model for Phagocytic Capacity of Phagocytes

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