Joannie Roy scite author profile

Promoting axon regeneration following injury is one of the ultimate challenges of neuroscience, and understanding the mechanisms that regulate axon growth and guidance is essential to achieve this goal. During development axons are directed over relatively long distances by a precise extracellular distribution of chemical signals in the embryonic nervous system. Multiple guidance proteins, including netrins, slits, semaphorins, ephrins and neurotrophins have been identified as key players in this process. During the last decade, engineered cell culture substrates have been developed to investigate the cellular and molecular mechanisms underlying axon guidance. This review is focused on the biological insights that have been achieved using new techniques that attempt to mimic in vitro the spatial patterns of proteins that growth cones encounter in vivo.

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Description of Rhynchopus euleeides n. sp. (Diplonemea), a Free‐Living Marine Euglenozoan

Roy

Faktorová

Benada

et al. 2007

J Eukaryotic Microbiology

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We describe Rhynchopus euleeides n. sp., using light and electron microscopy. This free-living flagellate, which was isolated earlier from a marine habitat, can be grown axenically in a rich medium based on modified seawater. In the trophic stage, cells are predominantly elliptical and laterally flattened, but frequently change their shape (metaboly). Gliding is the predominant manner of locomotion. The two flagella, which are typically concealed in their pocket, are short stubs of unequal length, have conventional axonemes, but apparently lack a paraxonemal rod. Swarmer cells, which form only occasionally, are smaller in size and carry two conspicuous flagella of more than 2 times the body length. Cells are decorated with a prominent apical papillum. Both the flagellar pocket and the adjacent feeding apparatus seem to merge together into a single sub-apical opening. The mitochondrion, which is most likely single, is located peripherally. It is reticulated in shape and contains only a few lamellar cristae. Mitochondrial DNA is abundant and evenly distributed throughout the organelle. Morphological synapomorphies confirm the affiliation of the species with the genus Rhynchopus (Diplonemea, Euglenozoa). We discuss the characters that distinguish Rhynchopus from Diplonema corroborating the validity of the two genera.

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C3a elicits unique migratory responses in immature low-density neutrophils

et al. 2020

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A Haptotaxis Assay for Neutrophils using Optical Patterning and a High-content Approach

Roy

Mazzaferri

Filep

et al. 2017

Sci Rep

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Neutrophil recruitment guided by chemotactic cues is a central event in host defense against infection and tissue injury. While the mechanisms underlying neutrophil chemotaxis have been extensively studied, these are just recently being addressed by using high-content approaches or surface-bound chemotactic gradients (haptotaxis) in vitro. Here, we report a haptotaxis assay, based on the classic under-agarose assay, which combines an optical patterning technique to generate surface-bound formyl peptide gradients as well as an automated imaging and analysis of a large number of migration trajectories. We show that human neutrophils migrate on covalently-bound formyl-peptide gradients, which influence the speed and frequency of neutrophil penetration under the agarose. Analysis revealed that neutrophils migrating on surface-bound patterns accumulate in the region of the highest peptide concentration, thereby mimicking in vivo events. We propose the use of a chemotactic precision index, gyration tensors and neutrophil penetration rate for characterizing haptotaxis. This high-content assay provides a simple approach that can be applied for studying molecular mechanisms underlying haptotaxis on user-defined gradient shape.

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Adaptive settings for the nearest-neighbor particle tracking algorithm

Mazzaferri

Roy

Lefrançois

et al. 2014

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Opto-magnetic capture of individual cells based on visual phenotypes

Binan

Bart

Uriarte

et al. 2019

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The ability to isolate rare live cells within a heterogeneous population based solely on visual criteria remains technically challenging, due largely to limitations imposed by existing sorting technologies. Here, we present a new method that permits labeling cells of interest by attaching streptavidin-coated magnetic beads to their membranes using the lasers of a confocal microscope. A simple magnet allows highly specific isolation of the labeled cells, which then remain viable and proliferate normally. As proof of principle, we tagged, isolated, and expanded individual cells based on three biologically relevant visual characteristics: i) presence of multiple nuclei, ii) accumulation of lipid vesicles, and iii) ability to resolve ionizing radiation-induced DNA damage foci. Our method constitutes a rapid, efficient, and cost-effective approach for isolation and subsequent characterization of rare cells based on observable traits such as movement, shape, or location, which in turn can generate novel mechanistic insights into important biological processes.

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Analysis of a novel field dilution method for testing samples that exceed the analytic range of point-of-care blood lead analyzers

Neri

Roy

Jarrett

et al. 2013

International Journal of Environmental Health Research

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Investigators developed and evaluated a dilution method for the LeadCare II analyzer (LCII) for blood lead levels > 65 μg/dL, the analyzer's maximum reporting value. Venous blood samples from lead-poisoned children were initially analyzed in the field using the dilution method. Split samples were analyzed at the US Centers for Disease Control and Prevention (CDC) laboratory using both the dilution method and inductively coupled plasma-mass spectrometry (

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Joannie Roy

Unusual Mitochondrial Genome Structures throughout the Euglenozoa

Engineered cell culture substrates for axon guidance studies: moving beyond proof of concept

Description of Rhynchopus euleeides n. sp. (Diplonemea), a Free‐Living Marine Euglenozoan

C3a elicits unique migratory responses in immature low-density neutrophils

A Haptotaxis Assay for Neutrophils using Optical Patterning and a High-content Approach

Adaptive settings for the nearest-neighbor particle tracking algorithm

Opto-magnetic capture of individual cells based on visual phenotypes

Analysis of a novel field dilution method for testing samples that exceed the analytic range of point-of-care blood lead analyzers

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