Modifications of cell fate specification in equal-cleaving nemertean embryos: alternate patterns of spiralian development

The nemerteans belong to a phylum of coelomate worms that display a highly conserved pattern of cell divisions referred to as spiral cleavage. It has recently been shown that the fates of the four embryonic cell quadrants in two species of nemerteans are not homologous to those in other spiralian embryos, such as the annelids and molluscs (Henry, J. Q. and Martindale, M. Q. (1994a) Develop. Genetics 15, 64–78). Equal-cleaving molluscs utilize inductive interactions to establish quadrant-specific cell fates and embryonic symmetry properties following fifth cleavage. In order to elucidate the manner in which cell fates are established in nemertean embryos, we have conducted cell isolation and deletion experiments to examine the developmental potential of the early cleavage blastomeres of two equal-cleaving nemerteans, Nemertopsis bivittata and Cerebratulus lacteus. These two species display different modes of development: N. bivittata develops directly via a non-feeding larvae, while C. lacteus develops to form a feeding pilidium larva which undergoes a radical metamorphosis to give rise to the juvenile worm. By examining the development of certain structures and cell types characteristic of quadrant-specific fates for each of these species, we have shown that isolated blastomeres of the indirect-developing nemertean, C. lacteus, are capable of generating cell fates that are not a consequence of that cell's normal developmental program. For instance, dorsal blastomeres can form muscle fibers when cultured in isolation. In contrast, isolated blastomeres of the direct-developing species, N. bivittata do not regulate their development to the same extent. Some cell fates are specified in a precocious manner in this species, such as those that give rise to the eyes. Thus, these findings indicate that equal-cleaving spiralian embryos can utilize different mechanisms of cell fate and axis specification. The implications of these patterns of nemertean development are discussed in relation to experimental work in other spiralian embryos, and a model is presented that accounts for possible evolutionary changes in cell lineage and the process of cell fate specification amongst these protostome phyla.

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Histone Acetyltransferases and Stem Cell Identity

Cancers ◽

10.3390/cancers13102407 ◽

2021 ◽

Vol 13 (10) ◽

pp. 2407

Author(s):

Ruicen He ◽

Arthur Dantas ◽

Karl Riabowol

Keyword(s):

Stem Cells ◽

Stem Cell ◽

Cell Fate ◽

Epigenetic Modification ◽

Cell Types ◽

Histone Acetyltransferases ◽

Specific Cell ◽

Cell Fates ◽

Cell Identity ◽

Hematopoietic Stem

Acetylation of histones is a key epigenetic modification involved in transcriptional regulation. The addition of acetyl groups to histone tails generally reduces histone-DNA interactions in the nucleosome leading to increased accessibility for transcription factors and core transcriptional machinery to bind their target sequences. There are approximately 30 histone acetyltransferases and their corresponding complexes, each of which affect the expression of a subset of genes. Because cell identity is determined by gene expression profile, it is unsurprising that the HATs responsible for inducing expression of these genes play a crucial role in determining cell fate. Here, we explore the role of HATs in the maintenance and differentiation of various stem cell types. Several HAT complexes have been characterized to play an important role in activating genes that allow stem cells to self-renew. Knockdown or loss of their activity leads to reduced expression and or differentiation while particular HATs drive differentiation towards specific cell fates. In this study we review functions of the HAT complexes active in pluripotent stem cells, hematopoietic stem cells, muscle satellite cells, mesenchymal stem cells, neural stem cells, and cancer stem cells.

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Prdm8 regulates pMN progenitor specification for motor neuron and oligodendrocyte fates by modulating the Shh signaling response

Development ◽

10.1242/dev.191023 ◽

2020 ◽

Vol 147 (16) ◽

pp. dev191023 ◽

Cited By ~ 3

Author(s):

Kayt Scott ◽

Rebecca O'Rourke ◽

Austin Gillen ◽

Bruce Appel

Keyword(s):

Motor Neuron ◽

Cell Fate ◽

Motor Neurons ◽

Oligodendrocyte Precursor Cells ◽

Cell Fate Specification ◽

Cell Fates ◽

Shh Signaling ◽

Fate Specification ◽

The People ◽

Oligodendrocyte Precursor

ABSTRACTSpinal cord pMN progenitors sequentially produce motor neurons and oligodendrocyte precursor cells (OPCs). Some OPCs differentiate rapidly as myelinating oligodendrocytes, whereas others remain into adulthood. How pMN progenitors switch from producing motor neurons to OPCs with distinct fates is poorly understood. pMN progenitors express prdm8, which encodes a transcriptional repressor, during motor neuron and OPC formation. To determine whether prdm8 controls pMN cell fate specification, we used zebrafish as a model system to investigate prdm8 function. Our analysis revealed that prdm8 mutant embryos have fewer motor neurons resulting from a premature switch from motor neuron to OPC production. Additionally, prdm8 mutant larvae have excess oligodendrocytes and a concomitant deficit of OPCs. Notably, pMN cells of mutant embryos have elevated Shh signaling, coincident with the motor neuron to OPC switch. Inhibition of Shh signaling restored the number of motor neurons to normal but did not rescue the proportion of oligodendrocytes. These data suggest that Prdm8 regulates the motor neuron-OPC switch by controlling the level of Shh activity in pMN progenitors, and also regulates the allocation of oligodendrocyte lineage cell fates.This article has an associated ‘The people behind the papers’ interview.

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Evolutionary changes of developmental mechanisms in the absence of cell lineage alterations during vulva formation in the Diplogastridae (Nematoda)

Development ◽

10.1242/dev.124.1.243 ◽

1997 ◽

Vol 124 (1) ◽

pp. 243-251 ◽

Cited By ~ 9

Author(s):

R.J. Sommer

Keyword(s):

Cell Fate ◽

Cell Fusion ◽

Genetic Model ◽

Cell Lineage ◽

Model Organism ◽

Epidermal Cells ◽

Cell Fate Specification ◽

Fate Specification ◽

Developmental Mechanisms ◽

Differentiation Pattern

The origin of novelty is one of the least understood evolutionary phenomena. One approach to study evolutionary novelty comes from developmental biology. During developmental cell fate specification of the nematode Pristionchus pacificus (Diplogastridae), five cell fates can be distinguished within a group of twelve ventral epidermal cells. The differentiation pattern of individual cells includes programmed cell death, cell fusion and vulval differentiation after induction by the gonad. A cell lineage comparison among species of seven different genera of the Diplogastridae indicates that the differentiation pattern of ventral epidermal cells is highly conserved. Despite this morphological conservation, cell ablation experiments indicate many independent alterations of underlying mechanisms of cell fate specification. Cell fusion and individual cell competence change during evolution as well as the differentiation property in response to inductive signaling. These results suggest that developmental mechanisms, some of which are redundantly involved in vulval fate specification of the genetic model organism Caenorhabditis elegans, can evolve without concomitant morphological change.

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A glial cell arises from an additional division within the mechanosensory lineage during development of the microchaete on the Drosophila notum

Development ◽

10.1242/dev.126.20.4617 ◽

1999 ◽

Vol 126 (20) ◽

pp. 4617-4622 ◽

Cited By ~ 7

Author(s):

G.V. Reddy ◽

V. Rodrigues

Keyword(s):

Glial Cell ◽

Cell Fate ◽

Cell Lineage ◽

The Other ◽

Sensory Cells ◽

Cell Fate Specification ◽

Fate Specification ◽

Low Levels ◽

Proposed Modification ◽

Glial Marker

We have used different cell markers to trace the development of the sensory cells of the thoracic microchaete. Our results dictate a revision in the currently accepted model for cell lineage within the mechanosensory bristle. The sensory organ progenitor divides to form two secondary progenitors: PIIa and PIIb. PIIb divides first to give rise to a tertiary progenitor-PIII and a glial cell. This is followed by division of PIIa to form the shaft and socket cells as described before. PIII expresses high levels of Elav and low levels of Prospero and divides to produce neuron and sheath. Its sibling cell expresses low Elav and high Prospero and is recognized by the glial marker, Repo. This cell migrates away from the other cells of the lineage following differentiation. The proposed modification in lineage has important implications for previous studies on sibling cell fate choice and cell fate specification in sensory systems.

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Nuclear beta-catenin is required to specify vegetal cell fates in the sea urchin embryo

Development ◽

10.1242/dev.126.2.345 ◽

1999 ◽

Vol 126 (2) ◽

pp. 345-357 ◽

Cited By ~ 31

Author(s):

C.Y. Logan ◽

J.R. Miller ◽

M.J. Ferkowicz ◽

D.R. McClay

Keyword(s):

Cell Fate ◽

Sea Urchin ◽

Beta Catenin ◽

Cell Fate Specification ◽

Cell Fates ◽

Cell Stage ◽

Animal Pole ◽

Fate Specification ◽

The Relationship ◽

Vegetal Cell

Beta-catenin is thought to mediate cell fate specification events by localizing to the nucleus where it modulates gene expression. To ask whether beta-catenin is involved in cell fate specification during sea urchin embryogenesis, we analyzed the distribution of nuclear beta-catenin in both normal and experimentally manipulated embryos. In unperturbed embryos, beta-catenin accumulates in nuclei that include the precursors of the endoderm and mesoderm, suggesting that it plays a role in vegetal specification. Using pharmacological, embryological and molecular approaches, we determined the function of beta-catenin in vegetal development by examining the relationship between the pattern of nuclear beta-catenin and the formation of endodermal and mesodermal tissues. Treatment of embryos with LiCl, a known vegetalizing agent, caused both an enhancement in the levels of nuclear beta-catenin and an expansion in the pattern of nuclear beta-catenin that coincided with an increase in endoderm and mesoderm. Conversely, overexpression of a sea urchin cadherin blocked the accumulation of nuclear beta-catenin and consequently inhibited the formation of endodermal and mesodermal tissues including micromere-derived skeletogenic mesenchyme. In addition, nuclear beta-catenin-deficient micromeres failed to induce a secondary axis when transplanted to the animal pole of uninjected host embryos, indicating that nuclear beta-catenin also plays a role in the production of micromere-derived signals. To examine further the relationship between nuclear beta-catenin in vegetal nuclei and micromere signaling, we performed both transplantations and deletions of micromeres at the 16-cell stage and demonstrated that the accumulation of beta-catenin in vegetal nuclei does not require micromere-derived cues. Moreover, we demonstrate that cell autonomous signals appear to regulate the pattern of nuclear beta-catenin since dissociated blastomeres possessed nuclear beta-catenin in approximately the same proportion as that seen in intact embryos. Together, these data show that the accumulation of beta-catenin in nuclei of vegetal cells is regulated cell autonomously and that this localization is required for the establishment of all vegetal cell fates and the production of micromere-derived signals.

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The role of cell lineage in development

Philosophical Transactions of the Royal Society of London Series B Biological Sciences ◽

10.1098/rstb.1985.0174 ◽

1985 ◽

Vol 312 (1153) ◽

pp. 3-19 ◽

Cited By ~ 52

Keyword(s):

Cell Fate ◽

Cell Lineage ◽

Early Embryo ◽

Embryonic Cell ◽

Evolutionary Divergence ◽

Causative Role ◽

Embryonic Cells ◽

Developmental Potential ◽

Cell Lineages

Studies of the role of cell lineage in development began in the latter part of the 19th century, fell into decline in the early part of the 20th, and were revived about 20 years ago. This recent revival was accompanied by the introduction of new and powerful analytical techniques. Concepts of importance for cell lineage studies include the principal division modes by which a cell may give rise to its descendant clone (proliferative, stem cell and diversifying); developmental determinacy , or indeterminacy , which refer to the degree to which the normal cleavage pattern of the early embryo and the developmental fate of its individual cells is, or is not, the same in specimen after specimen; commitment , which refers to the restriction of the developmental potential of a pluripotent embryonic cell; and equivalence group , which refers to two or more equivalently pluripotent cell clones that normally take on different fates but of which under abnormal conditions one clone can take on the fate of another. Cell lineage can be inferred to have a causative role in developmental cell fate in embryos in which induced changes in cell division patterns lead to changes in cell fate. Moreover, such a causative role of cell lineage is suggested by cases where homologous cell types characteristic of a symmetrical and longitudinally metameric body plan arise via homologous cell lineages. The developmental pathways of commitment to particular cell fates proceed according to a mixed typologic and topographic hierarchy, which appears to reflect an evolutionary compromise between maximizing the ease of ordering the spatial distribution of the determinants of commitment and minimizing the need for migration of differentially committed embryonic cells. Comparison of the developmental cell lineages in leeches and insects indicates that the early course of embryogenesis is radically different in these phyletically related taxa. This evolutionary divergence of the course of early embryogenesis appears to be attributable to an increasing prevalence of polyclonal rather than monoclonal commitment in the phylogenetic line leading from an annelid-like ancestor to insects.

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Neural crest lineage analysis: from past to future trajectory

Development ◽

10.1242/dev.193193 ◽

2020 ◽

Vol 147 (20) ◽

pp. dev193193 ◽

Cited By ~ 1

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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Multimodal Long Noncoding RNA Interaction Networks: Control Panels for Cell Fate Specification

Genetics ◽

10.1534/genetics.119.302661 ◽

2019 ◽

Vol 213 (4) ◽

pp. 1093-1110 ◽

Cited By ~ 3

Author(s):

Keriayn N. Smith ◽

Sarah C. Miller ◽

Gabriele Varani ◽

J. Mauro Calabrese ◽

Terry Magnuson

Keyword(s):

Cell Fate ◽

Early Development ◽

Noncoding Rna ◽

Cell Types ◽

Cell Fate Specification ◽

Phenotypic Analysis ◽

Cell Fate Decisions ◽

Fate Specification ◽

Mechanistic Basis ◽

Rna Interaction

Lineage specification in early development is the basis for the exquisitely precise body plan of multicellular organisms. It is therefore critical to understand cell fate decisions in early development. Moreover, for regenerative medicine, the accurate specification of cell types to replace damaged/diseased tissue is strongly dependent on identifying determinants of cell identity. Long noncoding RNAs (lncRNAs) have been shown to regulate cellular plasticity, including pluripotency establishment and maintenance, differentiation and development, yet broad phenotypic analysis and the mechanistic basis of their function remains lacking. As components of molecular condensates, lncRNAs interact with almost all classes of cellular biomolecules, including proteins, DNA, mRNAs, and microRNAs. With functions ranging from controlling alternative splicing of mRNAs, to providing scaffolding upon which chromatin modifiers are assembled, it is clear that at least a subset of lncRNAs are far from the transcriptional noise they were once deemed. This review highlights the diversity of lncRNA interactions in the context of cell fate specification, and provides examples of each type of interaction in relevant developmental contexts. Also highlighted are experimental and computational approaches to study lncRNAs.

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Hunchback is required for the specification of the early sublineage of neuroblast 7-3 in the Drosophila central nervous system

Development ◽

10.1242/dev.129.4.1027 ◽

2002 ◽

Vol 129 (4) ◽

pp. 1027-1036 ◽

Cited By ~ 13

Author(s):

Tanja Novotny ◽

Regina Eiselt ◽

Joachim Urban

Keyword(s):

Cell Fate ◽

Important Determinant ◽

Cell Types ◽

Cell Fate Specification ◽

Glia Cells ◽

Fate Specification ◽

Important Player ◽

Mother Cells ◽

The Cost ◽

Different Cell Types

The Drosophila ventral nerve cord (VNC) derives from neuroblasts (NBs), which mostly divide in a stem cell mode and give rise to defined NB lineages characterized by specific sets of sequentially generated neurons and/or glia cells. To understand how different cell types are generated within a NB lineage, we have focused on the NB7-3 lineage as a model system. This NB gives rise to four individually identifiable neurons and we show that these cells are generated from three different ganglion mother cells (GMCs). The finding that the transcription factor Hunchback (Hb) is expressed in the early sublineage of NB7-3, which consists of the early NB and the first GMC (GMC7-3a) and its progeny (EW1 and GW), prompted us to investigate its possible role in NB7-3 lineage development. Our analysis revealed that loss of hb results in a lack of the normally Hb-positive neurons, while the later-born neurons (designated as EW2 and EW3) are still present. However, overexpression of hb in the whole lineage leads to additional cells with the characteristics of GMC7-3a-derived neurons, at the cost of EW2 and EW3. Thus, hb is an important determinant in specifying early sublineage identity in the NB7-3 lineage. Using Even-skipped (Eve) as a marker, we have additionally shown that hb is also needed for the determination and/or differentiation of several other early-born neurons, indicating that this gene is an important player in sequential cell fate specification within the Drosophila CNS.

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