Your search keyword '"McLennan R"' showing total 6 results

1. Single-cell reconstruction with spatial context of migrating neural crest cells and their microenvironments during vertebrate head and neck formation.

Author

Morrison JA, McLennan R, Teddy JM, Scott AR, Kasemeier-Kulesa JC, Gogol MM, and Kulesa PM

Subjects

Animals, Body Patterning genetics, Branchial Region embryology, Cell Differentiation genetics, Cell Movement genetics, Cellular Microenvironment genetics, Chick Embryo, Embryo, Mammalian, Embryo, Nonmammalian, Embryonic Development genetics, Head embryology, Humans, Mesoderm growth & development, Multipotent Stem Cells cytology, Neck embryology, Neural Crest metabolism, Neuroblastoma genetics, Neuroblastoma pathology, Organogenesis genetics, Tumor Microenvironment genetics, Vertebrates genetics, Vertebrates growth & development, Branchial Region growth & development, Head growth & development, Neck growth & development, Neural Crest growth & development

Abstract

The dynamics of multipotent neural crest cell differentiation and invasion as cells travel throughout the vertebrate embryo remain unclear. Here, we preserve spatial information to derive the transcriptional states of migrating neural crest cells and the cellular landscape of the first four chick cranial to cardiac branchial arches (BA1-4) using label-free, unsorted single-cell RNA sequencing. The faithful capture of branchial arch-specific genes led to identification of novel markers of migrating neural crest cells and 266 invasion genes common to all BA1-4 streams. Perturbation analysis of a small subset of invasion genes and time-lapse imaging identified their functional role to regulate neural crest cell behaviors. Comparison of the neural crest invasion signature to other cell invasion phenomena revealed a shared set of 45 genes, a subset of which showed direct relevance to human neuroblastoma cell lines analyzed after exposure to the in vivo chick embryonic neural crest microenvironment. Our data define an important spatio-temporal reference resource to address patterning of the vertebrate head and neck, and previously unidentified cell invasion genes with the potential for broad impact., Competing Interests: Competing interests The authors declare no competing or financial interests., (© 2021. Published by The Company of Biologists Ltd.)

Published

2021

2. Neural crest cells bulldoze through the microenvironment using Aquaporin 1 to stabilize filopodia.

Author

McLennan R, McKinney MC, Teddy JM, Morrison JA, Kasemeier-Kulesa JC, Ridenour DA, Manthe CA, Giniunaite R, Robinson M, Baker RE, Maini PK, and Kulesa PM

Subjects

Animals, Branchial Region cytology, Branchial Region embryology, Cell Membrane physiology, Cellular Microenvironment, Chick Embryo, Computational Biology, Focal Adhesions, Neural Crest embryology, Receptor, EphB1 metabolism, Receptor, EphB3 metabolism, Aquaporin 1 physiology, Cell Movement physiology, Neural Crest cytology, Pseudopodia physiology

Abstract

Neural crest migration requires cells to move through an environment filled with dense extracellular matrix and mesoderm to reach targets throughout the vertebrate embryo. Here, we use high-resolution microscopy, computational modeling, and in vitro and in vivo cell invasion assays to investigate the function of Aquaporin 1 (AQP-1) signaling. We find that migrating lead cranial neural crest cells express AQP-1 mRNA and protein, implicating a biological role for water channel protein function during invasion. Differential AQP-1 levels affect neural crest cell speed and direction, as well as the length and stability of cell filopodia. Furthermore, AQP-1 enhances matrix metalloprotease activity and colocalizes with phosphorylated focal adhesion kinases. Colocalization of AQP-1 with EphB guidance receptors in the same migrating neural crest cells has novel implications for the concept of guided bulldozing by lead cells during migration., Competing Interests: Competing interestsThe authors declare no competing or financial interests., (© 2020. Published by The Company of Biologists Ltd.)

Published

2020

3. Neural crest migration is driven by a few trailblazer cells with a unique molecular signature narrowly confined to the invasive front.

Author

McLennan R, Schumacher LJ, Morrison JA, Teddy JM, Ridenour DA, Box AC, Semerad CL, Li H, McDowell W, Kay D, Maini PK, Baker RE, and Kulesa PM

Subjects

Animals, Avian Proteins genetics, Avian Proteins metabolism, Chick Embryo, Computer Simulation, Gene Knockdown Techniques, Neural Crest metabolism, Polymerase Chain Reaction, RNA, Messenger genetics, RNA, Messenger metabolism, Single-Cell Analysis, Cell Movement genetics, Gene Expression Profiling, Gene Expression Regulation, Developmental, Neural Crest cytology

Abstract

Neural crest (NC) cell migration is crucial to the formation of peripheral tissues during vertebrate development. However, how NC cells respond to different microenvironments to maintain persistence of direction and cohesion in multicellular streams remains unclear. To address this, we profiled eight subregions of a typical cranial NC cell migratory stream. Hierarchical clustering showed significant differences in the expression profiles of the lead three subregions compared with newly emerged cells. Multiplexed imaging of mRNA expression using fluorescent hybridization chain reaction (HCR) quantitatively confirmed the expression profiles of lead cells. Computational modeling predicted that a small fraction of lead cells that detect directional information is optimal for successful stream migration. Single-cell profiling then revealed a unique molecular signature that is consistent and stable over time in a subset of lead cells within the most advanced portion of the migratory front, which we term trailblazers. Model simulations that forced a lead cell behavior in the trailing subpopulation predicted cell bunching near the migratory domain entrance. Misexpression of the trailblazer molecular signature by perturbation of two upstream transcription factors agreed with the in silico prediction and showed alterations to NC cell migration distance and stream shape. These data are the first to characterize the molecular diversity within an NC cell migratory stream and offer insights into how molecular patterns are transduced into cell behaviors., (© 2015. Published by The Company of Biologists Ltd.)

Published

2015

4. The neural crest cell cycle is related to phases of migration in the head.

Author

Ridenour DA, McLennan R, Teddy JM, Semerad CL, Haug JS, and Kulesa PM

Subjects

Animals, Cell Cycle genetics, Cell Cycle physiology, Cell Division genetics, Cell Division physiology, Cell Movement genetics, Cell Movement physiology, Cell Proliferation, Chick Embryo, Flow Cytometry, Neural Crest metabolism, Neural Crest cytology

Abstract

Embryonic cells that migrate long distances must critically balance cell division in order to maintain stream dynamics and population of peripheral targets. Yet details of individual cell division events and how cell cycle is related to phases of migration remain unclear. Here, we examined these questions using the chick cranial neural crest (NC). In vivo time-lapse imaging revealed that a typical migrating NC cell division event lasted ~1 hour and included four stereotypical steps. Cell tracking showed that dividing NC cells maintained position relative to non-dividing neighbors. NC cell division orientation and the time and distance to first division after neural tube exit were stochastic. To address how cell cycle is related to phases of migration, we used FACs analysis to identify significant spatiotemporal differences in NC cell cycle profiles. Two-photon photoconversion of single and small numbers of mKikGR-labeled NC cells confirmed that lead NC cells exhibited a nearly fourfold faster doubling time after populating the branchial arches. By contrast, Ki-67 staining showed that one out of every five later emerging NC cells exited the cell cycle after reaching proximal head targets. The relatively quiescent mitotic activity during NC cell migration to the branchial arches was altered when premigratory cells were reduced in number by tissue ablation. Together, our results provide the first comprehensive details of the pattern and dynamics of cell division events during cranial NC cell migration.

Published

2014

5. Evidence for dynamic rearrangements but lack of fate or position restrictions in premigratory avian trunk neural crest.

Author

McKinney MC, Fukatsu K, Morrison J, McLennan R, Bronner ME, and Kulesa PM

Subjects

Animals, Chick Embryo, Computational Biology, Embryonic Stem Cells metabolism, Fluorescent Dyes, Microscopy, Confocal, Neural Tube embryology, Reverse Transcriptase Polymerase Chain Reaction, Time Factors, Time-Lapse Imaging, Cell Movement physiology, Embryonic Stem Cells cytology, Neural Crest embryology, Neural Tube cytology, Neuroepithelial Cells physiology

Abstract

Neural crest (NC) cells emerge from the dorsal trunk neural tube (NT) and migrate ventrally to colonize neuronal derivatives, as well as dorsolaterally to form melanocytes. Here, we test whether different dorsoventral levels in the NT have similar or differential ability to contribute to NC cells and their derivatives. To this end, we precisely labeled NT precursors at specific dorsoventral levels of the chick NT using fluorescent dyes and a photoconvertible fluorescent protein. NT and NC cell dynamics were then examined in vivo and in slice culture using two-photon and confocal time-lapse imaging. The results show that NC precursors undergo dynamic rearrangements within the neuroepithelium, yielding an overall ventral to dorsal movement toward the midline of the NT, where they exit in a stochastic manner to populate multiple derivatives. No differences were noted in the ability of precursors from different dorsoventral levels of the NT to contribute to NC derivatives, with the exception of sympathetic ganglia, which appeared to be 'filled' by the first population to emigrate. Rather than restricted developmental potential, however, this is probably due to a matter of timing.

Published

2013

6. Multiscale mechanisms of cell migration during development: theory and experiment.

Author

McLennan R, Dyson L, Prather KW, Morrison JA, Baker RE, Maini PK, and Kulesa PM

Subjects

Animals, Cell Movement genetics, Chemotaxis physiology, Chick Embryo, Embryonic Development genetics, Gene Expression Profiling, Gene Expression Regulation, Developmental, Models, Neurological, Neural Crest cytology, Neural Crest embryology, Neural Crest metabolism, Neural Stem Cells cytology, Neural Stem Cells physiology, Cell Movement physiology, Embryonic Development physiology, Models, Biological

Abstract

Long-distance cell migration is an important feature of embryonic development, adult morphogenesis and cancer, yet the mechanisms that drive subpopulations of cells to distinct targets are poorly understood. Here, we use the embryonic neural crest (NC) in tandem with theoretical studies to evaluate model mechanisms of long-distance cell migration. We find that a simple chemotaxis model is insufficient to explain our experimental data. Instead, model simulations predict that NC cell migration requires leading cells to respond to long-range guidance signals and trailing cells to short-range cues in order to maintain a directed, multicellular stream. Experiments confirm differences in leading versus trailing NC cell subpopulations, manifested in unique cell orientation and gene expression patterns that respond to non-linear tissue growth of the migratory domain. Ablation experiments that delete the trailing NC cell subpopulation reveal that leading NC cells distribute all along the migratory pathway and develop a leading/trailing cellular orientation and gene expression profile that is predicted by model simulations. Transplantation experiments and model predictions that move trailing NC cells to the migratory front, or vice versa, reveal that cells adopt a gene expression profile and cell behaviors corresponding to the new position within the migratory stream. These results offer a mechanistic model in which leading cells create and respond to a cell-induced chemotactic gradient and transmit guidance information to trailing cells that use short-range signals to move in a directional manner.

Published

2012