scholarly journals Cell lineage tracing in the developing enteric nervous system: superstars revealed by experiment and simulation

2014 ◽  
Vol 11 (93) ◽  
pp. 20130815 ◽  
Author(s):  
Bevan L. Cheeseman ◽  
Dongcheng Zhang ◽  
Benjamin J. Binder ◽  
Donald F. Newgreen ◽  
Kerry A. Landman
Keyword(s):  
Nervous System ◽  
Enteric Nervous System ◽  
Cell Fate ◽  
Cell Lineage ◽  
Population Expansion ◽  
Population Level ◽  
Lineage Tracing ◽  
Model Parameters ◽  
Agent Based ◽  
Proliferation And Differentiation

Cell lineage tracing is a powerful tool for understanding how proliferation and differentiation of individual cells contribute to population behaviour. In the developing enteric nervous system (ENS), enteric neural crest (ENC) cells move and undergo massive population expansion by cell division within self-growing mesenchymal tissue. We show that single ENC cells labelled to follow clonality in the intestine reveal extraordinary and unpredictable variation in number and position of descendant cells, even though ENS development is highly predictable at the population level. We use an agent-based model to simulate ENC colonization and obtain agent lineage tracing data, which we analyse using econometric data analysis tools. In all realizations, a small proportion of identical initial agents accounts for a substantial proportion of the total final agent population. We term these individuals superstars. Their existence is consistent across individual realizations and is robust to changes in model parameters. This inequality of outcome is amplified at elevated proliferation rate. The experiments and model suggest that stochastic competition for resources is an important concept when understanding biological processes which feature high levels of cell proliferation. The results have implications for cell-fate processes in the ENS.

ming is expressed in neuroblast sublineages and regulates gene expression in the Drosophila central nervous system

Development ◽  
1992 ◽  
Vol 116 (4) ◽  
pp. 943-952 ◽  
Author(s):  
X. Cui ◽  
C.Q. Doe
Keyword(s):  
Gene Expression ◽  
Central Nervous System ◽  
Nervous System ◽  
Cell Fate ◽  
Zinc Finger ◽  
Zinc Finger Protein ◽  
Cell Lineage ◽  
Cell Lineages ◽  
Finger Protein ◽  
Cell Diversity

Cell diversity in the Drosophila central nervous system (CNS) is primarily generated by the invariant lineage of neural precursors called neuroblasts. We used an enhancer trap screen to identify the ming gene, which is transiently expressed in a subset of neuroblasts at reproducible points in their cell lineage (i.e. in neuroblast ‘sublineages’), suggesting that neuroblast identity can be altered during its cell lineage. ming encodes a predicted zinc finger protein and loss of ming function results in precise alterations in CNS gene expression, defects in axonogenesis and embryonic lethality. We propose that ming controls cell fate within neuroblast cell lineages.

scholarly journals Co-ordination of cell cycle and differentiation in the developing nervous system

2012 ◽  
Vol 444 (3) ◽  
pp. 375-382 ◽  
Author(s):  
Christopher Hindley ◽  
Anna Philpott
Keyword(s):  
Cell Cycle ◽  
Nervous System ◽  
Embryonic Development ◽  
Cell Fate ◽  
Cell Cycle Progression ◽  
Control Cell ◽  
Cell Cycle Regulators ◽  
Cyclin Dependent Kinases ◽  
Proliferation And Differentiation ◽  
Developing Nervous System

During embryonic development, cells must divide to produce appropriate numbers, but later must exit the cell cycle to allow differentiation. How these processes of proliferation and differentiation are co-ordinated during embryonic development has been poorly understood until recently. However, a number of studies have now given an insight into how the cell cycle machinery, including cyclins, CDKs (cyclin-dependent kinases), CDK inhibitors and other cell cycle regulators directly influence mechanisms that control cell fate and differentiation. Conversely, examples are emerging of transcriptional regulators that are better known for their role in driving the differentiated phenotype, which also play complementary roles in controlling cell cycle progression. The present review will summarise our current understanding of the mechanisms co-ordinating the cell cycle and differentiation in the developing nervous system, where these links have been, perhaps, most extensively studied.

scholarly journals Constitutive STAT5 activation regulates Paneth and Paneth-like cells to control Clostridium difficile colitis

2019 ◽  
Vol 2 (2) ◽  
pp. e201900296 ◽  
Author(s):  
Ruixue Liu ◽  
Richard Moriggl ◽  
Dongsheng Zhang ◽  
Haifeng Li ◽  
Rebekah Karns ◽  
...  
Keyword(s):  
Clostridium Difficile ◽  
Cell Fate ◽  
Intestinal Inflammation ◽  
Paneth Cell ◽  
Cell Lineage ◽  
Niche Differentiation ◽  
Paneth Cells ◽  
Lineage Tracing ◽  
Intestinal Epithelial ◽  
Clostridium Difficile Colitis

Clostridium difficile impairs Paneth cells, driving intestinal inflammation that exaggerates colitis. Besides secreting bactericidal products to restrain C. difficile, Paneth cells act as guardians that constitute a niche for intestinal epithelial stem cell (IESC) regeneration. However, how IESCs are sustained to specify Paneth-like cells as their niche remains unclear. Cytokine-JAK-STATs are required for IESC regeneration. We investigated how constitutive STAT5 activation (Ca-pYSTAT5) restricts IESC differentiation towards niche cells to restrain C. difficile infection. We generated inducible transgenic mice and organoids to determine the effects of Ca-pYSTAT5-induced IESC lineages on C. difficile colitis. We found that STAT5 absence reduced Paneth cells and predisposed mice to C. difficile ileocolitis. In contrast, Ca-pYSTAT5 enhanced Paneth cell lineage tracing and restricted Lgr5 IESC differentiation towards pYSTAT5+Lgr5−CD24+Lyso+ or cKit+ niche cells, which imprinted Lgr5hiKi67+ IESCs. Mechanistically, pYSTAT5 activated Wnt/β-catenin signaling to determine Paneth cell fate. In conclusion, Ca-pYSTAT5 gradients control niche differentiation. Lack of pYSTAT5 reduces the niche cells to sustain IESC regeneration and induces C. difficile ileocolitis. STAT5 may be a transcription factor that regulates Paneth cells to maintain niche regeneration.

scholarly journals Live cell-lineage tracing and machine learning reveal patterns of organ regeneration

eLife ◽  
2018 ◽  
Vol 7 ◽  
Author(s):  
Oriol Viader-Llargués ◽  
Valerio Lupperger ◽  
Laura Pola-Morell ◽  
Carsten Marr ◽  
Hernán López-Schier
Keyword(s):  
Machine Learning ◽  
Cell Fate ◽  
Cell Lineage ◽  
Integrated Approach ◽  
Radial Symmetry ◽  
Regenerative Process ◽  
Lineage Tracing ◽  
Live Cell ◽  
High Temporal Resolution ◽  
Organ Regeneration

Despite the intrinsically stochastic nature of damage, sensory organs recapitulate normal architecture during repair to maintain function. Here we present a quantitative approach that combines live cell-lineage tracing and multifactorial classification by machine learning to reveal how cell identity and localization are coordinated during organ regeneration. We use the superficial neuromasts in larval zebrafish, which contain three cell classes organized in radial symmetry and a single planar-polarity axis. Visualization of cell-fate transitions at high temporal resolution shows that neuromasts regenerate isotropically to recover geometric order, proportions and polarity with exceptional accuracy. We identify mediolateral position within the growing tissue as the best predictor of cell-fate acquisition. We propose a self-regulatory mechanism that guides the regenerative process to identical outcome with minimal extrinsic information. The integrated approach that we have developed is simple and broadly applicable, and should help define predictive signatures of cellular behavior during the construction of complex tissues.

scholarly journals Maps of variability in cell lineage trees

2018 ◽  
Author(s):  
Damien G. Hicks ◽  
Terence P. Speed ◽  
Mohammed Yassin ◽  
Sarah M. Russell
Keyword(s):  
Cell Fate ◽  
Binary Tree ◽  
Cell Lineage ◽  
Population Level ◽  
Differentiation Potential ◽  
Cell Lineages ◽  
Lineage Tree ◽  
Founder Cells ◽  
Multicellular Organisms ◽  
Lineage Trees

AbstractNew approaches to lineage tracking allow the study of cell differentiation over many generations of cells during development in multicellular organisms. Understanding the variability observed in these lineage trees requires new statistical methods. Whereas invariant cell lineages, such as that for the nematode Caenorhabditis elegans, can be described using a lineage map, defined as the fixed pattern of phenotypes overlaid onto the binary tree structure, the variability of cell lineages from higher organisms makes it impossible to draw a single lineage map. Here, we introduce lineage variability maps which describe the pattern of second-order variation throughout the lineage tree. These maps can be undirected graphs of the partial correlations between every lineal position or directed graphs showing the dynamics of bifurcated patterns in each subtree. By using the symmetry invariance of a binary tree to develop a generalized spectral analysis for cell lineages, we show how to infer these graphical models for lineages of any depth from sample sizes of only a few pedigrees. When tested on pedigrees from C. elegans expressing a marker for pharyngeal differentiation potential, the maps recover essential features of the known lineage map. When applied to highly-variable pedigrees monitoring cell size in T lymphocytes, the maps show how most of the phenotype is set by the founder naive T cell. Lineage variability maps thus elevate the concept of the lineage map to the population level, addressing questions about the potency and dynamics of cell lineages and providing a way to quantify the progressive restriction of cell fate with increasing depth in the tree.Author summaryMulticellular organisms develop from a single fertilized egg by sequential cell divisions. The progeny from these divisions adopt different traits that are transmitted and modified through many generations. By tracking how cell traits change with each successive cell division throughout the family, or lineage, tree, it has been possible to understand where and how these modifications are controlled at the single-cell level, thereby addressing questions about, for example, the developmental origin of tissues, the sources of differentiation in immune cells, or the relationship between primary tumors and metastases. Such lineages often show large variability, with apparently identical founder cells giving rise to different patterns of descendants. Fundamental scientific questions, such as about the range of possible cell types a cell can give rise to, are often about this variability. To characterize this variation, and thus understand the lineage at the population level, we introduce lineage variability maps. Using data from worm and mammalian cell lineages we show how these maps provide quantifiable answers to questions about any developing lineage, such as the potency of founder cells and the progressive restriction of cell fate at each stage in the tree.

Neurogenesis in the insect enteric nervous system: generation of premigratory neurons from an epithelial placode

Development ◽  
1990 ◽  
Vol 109 (1) ◽  
pp. 17-28 ◽  
Author(s):  
P.F. Copenhaver ◽  
P.H. Taghert
Keyword(s):  
Nervous System ◽  
Enteric Nervous System ◽  
Cell Population ◽  
Lineage Tracing ◽  
Display Position ◽  
Gut Epithelium ◽  
System Generation ◽  
Enteric Plexus ◽  
Insect Cns ◽  
Major Division

The enteric plexus (EP) is a major division of the enteric nervous system (ENS) in the moth Manduca sexta and contains a dispersed population of about 360 bipolar neurons, the EP cells. Previously we showed that embryonic EP cells achieve their mature distributions by extensive migration along the gut surface and then display position-specific phenotypes. We now demonstrate that the entire EP cell population is generated from an ectodermal placode that invaginates from the embryonic foregut. Individual EP cells become postmitotic just as they leave the epithelium, but their terminal differentiation is subsequently delayed until after their migratory dispersal. Clonal analysis by injection of lineage-tracing dyes has shown that the EP cell population is derived from a large number of placodal cells, each of which contributes a limited number of neurons to the ENS. Placodally derived clones produce neurons exclusively, while clones arising from cells adjacent to the placode are incorporated into the gut epithelium. These results indicate that neurogenesis in the insect ENS involves a developmental strategy that is distinct from that seen in the insect CNS and which resembles the generation of certain cell classes in the vertebrate nervous system.

scholarly journals Neural crest lineage analysis: from past to future trajectory

Development ◽  
2020 ◽  
Vol 147 (20) ◽  
pp. dev193193 ◽  
Author(s):  
Weiyi Tang ◽  
Marianne E. Bronner
Keyword(s):  
Neural Crest ◽  
Cell Fate ◽  
Single Molecule ◽  
Cell Lineage ◽  
Neural Crest Cell ◽  
Cell Types ◽  
Lineage Tracing ◽  
Migration Routes ◽  
Developmental Potential ◽  
Lineage Analysis

ABSTRACTSince its discovery 150 years ago, the neural crest has intrigued investigators owing to its remarkable developmental potential and extensive migratory ability. Cell lineage analysis has been an essential tool for exploring neural crest cell fate and migration routes. By marking progenitor cells, one can observe their subsequent locations and the cell types into which they differentiate. Here, we review major discoveries in neural crest lineage tracing from a historical perspective. We discuss how advancing technologies have refined lineage-tracing studies, and how clonal analysis can be applied to questions regarding multipotency. We also highlight how effective progenitor cell tracing, when combined with recently developed molecular and imaging tools, such as single-cell transcriptomics, single-molecule fluorescence in situ hybridization and high-resolution imaging, can extend the scope of neural crest lineage studies beyond development to regeneration and cancer initiation.

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