Induction of notochord cell intercalation behavior and differentiation by progressive signals in the gastrula of Xenopus laevis

Development ◽  
1995 ◽  
Vol 121 (10) ◽  
pp. 3311-3321 ◽  
Author(s):  
C. Domingo ◽  
R. Keller
Keyword(s):  
Xenopus Laevis ◽  
Behavioral Changes ◽  
Cell Behavior ◽  
Convergent Extension ◽  
Notochordal Cell ◽  
Cell Behaviors ◽  
Notochord Cell ◽  
Light Fluorescence ◽  
Cell Intercalation ◽  
Somitic Mesoderm

We show that notochord-inducing signals are present during Xenopus laevis gastrulation and that they are important for both inducing and organizing cell behavior and differentiation in the notochord. Previous work showed that convergent extension of prospective notochordal and somitic mesoderm occurs by mediolateral cell intercalation to produce a longer, narrower tissue. Mediolateral cell intercalation is driven by bipolar, mediolaterally directed protrusive activity that elongates cells and then pulls them between one another along the mediolateral axis. This cell behavior, and subsequent notochordal cell differentiation, begins anteriorly and spreads posteriorly along the notochordal-somitic boundary, and from this lateral boundary progresses medially towards the center of the notochord field. To examine whether these progressions of cell behaviors and differentiation are induced and organized during gastrulation, we grafted labeled cells from the prospective notochordal, somitic and epidermal regions of the gastrula into the notochordal region and monitored their behavior by low light, fluorescence videomicroscopy. Prospective notochordal, epidermal and somitic cells expressed mediolateral cell intercalation behavior in an anterior-to-posterior and lateral-to-medial order established by the host notochord. Behavioral changes were induced first and most dramatically among cells grafted next to the notochordal-somitic boundary, particularly those in direct contact with the boundary, suggesting that the boundary may provide signals that both induce and organize notochordal cell behaviors. By physically impeding normal convergent extension movements, notochordal cell behaviors and differentiation were restricted to the anteriormost notochordal region and to the lateral notochordal-somitic boundary. These results show that mediolateral cell intercalation behavior and notochordal differentiation can be induced in the gastrula stage, among cells not normally expressing these characteristics, and that these characteristics are induced progressively, most likely by signals emanating from the notochordal-somitic boundary. In addition, they show that morphogenetic movements during gastrulation are necessary for complete notochord formation and that the prospective notochord region is not determined by the onset of gastrulation.

Cell rearrangement and segmentation in Xenopus: direct observation of cultured explants

Development ◽  
1989 ◽  
Vol 105 (1) ◽  
pp. 155-166 ◽  
Author(s):  
P.A. Wilson ◽  
G. Oster ◽  
R. Keller
Keyword(s):  
Explant Culture ◽  
Dorsal Side ◽  
Convergent Extension ◽  
Cell Behaviour ◽  
Cell Rearrangement ◽  
Radial Cell ◽  
Cell Intercalation ◽  
First Time ◽  
The Relationship ◽  
Somitic Mesoderm

We make use of a novel system of explant culture and high resolution video-film recording to analyse for the first time the cell behaviour underlying convergent extension and segmentation in the somitic mesoderm of Xenopus. We find that a sequence of activities sweeps through the somitic mesoderm from anterior to posterior during gastrulation and neurulation, beginning with radial cell intercalation or thinning, continuing with mediolateral intercalation and cell elongation, and culminating in segmentation and somite rotation. Radial intercalation at the posterior tip lengthens the tissue, while mediolateral intercalation farther anterior converges it toward the midline. This extension of the somitic mesoderm helps to elongate the dorsal side of intact neurulae. By separating tissues, we demonstrate that cell rearrangement is independent of the notochord, but radial intercalation - and thus the bulk of extension - requires the presence of an epithelium, either endodermal or ectodermal. Segmentation, on the other hand, can proceed in somitic mesoderm isolated at the end of gastrulation. Finally, we discuss the relationship between cell rearrangement and segmentation.

Notochord morphogenesis in Xenopus laevis: simulation of cell behavior underlying tissue convergence and extension

Development ◽  
1991 ◽  
Vol 113 (4) ◽  
pp. 1231-1244 ◽  
Author(s):  
M. Weliky ◽  
S. Minsuk ◽  
R. Keller ◽  
G. Oster
Keyword(s):  
Xenopus Laevis ◽  
Cell Motility ◽  
Cell Polarization ◽  
Contact Inhibition ◽  
Cell Behavior ◽  
Directional Bias ◽  
Cell Movements ◽  
Cell Behaviors ◽  
Geometric Conditions

Cell intercalation and cell shape changes drive notochord morphogenesis in the African frog, Xenopus laevis. Experimental observations show that cells elongate mediolaterally and intercalate between one another, causing the notochord to lengthen and narrow. Descriptive observations provide few clues as to the mechanisms that coordinate and drive these cell movements. It is possible that a few rules governing cell behavior could orchestrate the shaping of the entire tissue. We test this hypothesis by constructing a computer model of the tissue to investigate how rules governing cell motility and cell-cell interactions can account for the major features of notochord morphogenesis. These rules are drawn from the literature on in vitro cell studies and experimental observations of notochord cell behavior. The following types of motility rules are investigated: (1) refractory tissue boundaries that inhibit cell motility, (2) statistical persistence of motion, (3) contact inhibition of protrusion between cells, and (4) polarized and nonpolarized protrusive activity. We show that only the combination of refractory boundaries, contact inhibition and polarized protrusive activity reproduces normal notochord development. Guided by these rules, cells spontaneously align into a parallel array of elongating cells. Self alignment optimizes the geometric conditions for polarized protrusive activity by progressively minimizing contact inhibition between cells. Cell polarization, initiated at refractory tissue boundaries, spreads along successive cell rows into the tissue interior as cells restrict and constrain their neighbors' directional bias. The model demonstrates that several experimentally observed intrinsic cell behaviors, operating simultaneously, may underlie the generation of coordinated cell movements within the developing notochord.

Microtubule disruption reveals that Spemann's organizer is subdivided into two domains by the vegetal alignment zone

Development ◽  
1997 ◽  
Vol 124 (4) ◽  
pp. 895-906 ◽  
Author(s):  
M.C. Lane ◽  
R. Keller
Keyword(s):  
Marginal Zone ◽  
Axis Formation ◽  
Convergent Extension ◽  
Microtubule Depolymerization ◽  
Microtubule Disruption ◽  
Spemann's Organizer ◽  
And Function ◽  
Cell Intercalation ◽  
Somitic Mesoderm ◽  
Anterior Posterior

Mediolateral cell intercalation is proposed to drive morphogenesis of the primary embryonic axis in Xenopus. Mediolateral intercalation begins in a group of cells called the vegetal alignment zone, a subpopulation of cells in Spemann's organizer, and spreads through much of the marginal zone. To understand the functions of the vegetal alignment zone during gastrulation and axis formation, we have inhibited its formation by disrupting microtubules with nocodazole in early gastrula embryos. In such embryos, mediolateral intercalation, involution and convergent extension of the marginal zone do not occur. Although cell motility continues, and the anterior notochordal and somitic mesoderm differentiate in the pre-involution marginal zone, posterior notochordal and somitic mesoderm do not differentiate. In contrast, microtubule depolymerization in midgastrula embryos, after the vegetal alignment zone has formed, does not inhibit mediolateral cell intercalation, involution and convergent extension, or differentiation of posterior notochord and somites. We conclude that microtubules are required only for orienting and polarizing at stage 101/2 the first cells that undergo mediolateral intercalation and form the vegetal alignment zone, and not for subsequent morphogenesis. These results demonstrate that microtubules are required to form the vegetal alignment zone, and that both microtubules and the vegetal alignment zone play critical roles in the inductive and morphogenetic activities of Spemann's organizer. In addition, our results suggest that Spemann's organizer contains multiple organizers, which act in succession and change their location and function during gastrulation to generate the anterior/posterior axis in Xenopus.

scholarly journals Data-driven models reveal mutant cell behaviors important for myxobacterial aggregation

2020 ◽  
Author(s):  
Zhaoyang Zhang ◽  
Christopher R. Cotter ◽  
Zhe Lyu ◽  
Lawrence J. Shimkets ◽  
Oleg A. Igoshin
Keyword(s):  
Cell Tracking ◽  
Mutant Cell ◽  
Agent Based Modeling ◽  
Behavioral Changes ◽  
Data Driven ◽  
Cell Behavior ◽  
Fruiting Bodies ◽  
Wild Type ◽  
Agent Based ◽  
Cell Behaviors

AbstractSingle mutations frequently alter several aspects of cell behavior but rarely reveal whether a particular statistically significant change is biologically significant. To determine which behavioral changes are most important for multicellular self-organization, we devised a new methodology using Myxococcus xanthus as a model system. During development, myxobacteria coordinate their movement to aggregate into spore-filled fruiting bodies. We investigate how aggregation is restored in two mutants, csgA and pilC, that cannot aggregate unless mixed with wild type (WT) cells. To this end, we use cell tracking to follow the movement of fluorescently labeled cells in combination with data-driven agent-based modeling. The results indicate that just like WT cells, both mutants bias their movement toward aggregates and reduce motility inside aggregates. However, several aspects of mutant behavior remain uncorrected by WT demonstrating that perfect recreation of WT behavior is unnecessary. In fact, synergies between errant behaviors can make aggregation robust.

Cell rearrangement during gastrulation of Xenopus: direct observation of cultured explants

Development ◽  
1991 ◽  
Vol 112 (1) ◽  
pp. 289-300 ◽  
Author(s):  
P. Wilson ◽  
R. Keller
Keyword(s):  
High Resolution ◽  
Organizer Region ◽  
Time Lapse ◽  
Second Phase ◽  
Convergent Extension ◽  
Dorsal Axis ◽  
Cell Intercalation ◽  
Somitic Mesoderm ◽  
High Resolution Microscopy ◽  
Anterior Posterior

We have analyzed cell behavior in the organizer region of the Xenopus laevis gastrula by making high resolution time-lapse recordings of cultured explants. The dorsal marginal zone, comprising among other tissues prospective notochord and somitic mesoderm, was cut from early gastrulae and cultured in a way that permits high resolution microscopy of the deep mesodermal cells, whose organized intercalation produces the dramatic movements of convergent extension. At first, the explants extend without much convergence. This initial expansion results from rapid radial intercalation, or exchange of cells between layers. During the second half of gastrulation, the explants begin to converge strongly toward the midline while continuing to extend vigorously. This second phase of extension is driven by mediolateral cell intercalation, the rearrangement of cells within each layer to lengthen and narrow the array. Toward the end of gastrulation, fissures separate the central notochord from the somitic mesoderm on each side, and cells in both tissues elongate mediolaterally as they intercalate. A detailed analysis of the spatial and temporal pattern of these behaviors shows that both radial and mediolateral intercalation begin first in anterior tissue, demonstrating that the anterior-posterior timing gradient so evident in the mesoderm of the neurula is already forming in the gastrula. Finally, time-lapse recordings of intact embryos reveal that radial intercalation takes places primarily before involution, while mediolateral intercalation begins as the mesoderm goes around the lip. We discuss the significance of these findings to our understanding of both the mechanics of gastrulation and the patterning of the dorsal axis.

scholarly journals Using optogenetics to link myosin patterns to contractile cell behaviors during convergent extension

2021 ◽  
Author(s):  
R. M. Herrera-Perez ◽  
C. Cupo ◽  
C. Allan ◽  
A. Lin ◽  
K. E. Kasza
Keyword(s):  
Myosin Ii ◽  
Apical Cell ◽  
Epithelial Tissue ◽  
Cell Area ◽  
Convergent Extension ◽  
Cell Behaviors ◽  
Actomyosin Contractility ◽  
Axis Elongation ◽  
Cell Intercalation ◽  
Shape Changes

ABSTRACTDistinct spatiotemporal patterns of actomyosin contractility are often associated with particular epithelial tissue shape changes during development. For example, a planar polarized pattern of myosin II localization regulated by Rho1 signaling duringDrosophilabody axis elongation is thought to drive the cell behaviors that contribute to convergent extension. However, it is not well understood how specific aspects of a myosin localization pattern influence the multiple cell behaviors—including cell intercalation, cell shape changes, and apical cell area fluctuations—that simultaneously occur within a tissue during morphogenesis. Here, we use optogenetic activation (optoGEF) and deactivation (optoGAP) of Rho1 signaling to perturb the myosin pattern in the germband epithelium duringDrosophilaaxis elongation and analyze the effects on contractile cell behaviors within the tissue. We find that uniform photoactivation of optoGEF or optoGAP is sufficient to rapidly override the endogenous myosin pattern, abolishing myosin planar polarity and reducing cell intercalation and convergent extension. However, these two perturbations have distinct effects on junctional and medial myosin localization, apical cell area fluctuations, and cell packings within the germband. Activation of Rho1 signaling in optoGEF embryos increases myosin accumulation in the medial-apical domain of germband cells, leading to increased amplitudes of apical cell area fluctuations. This enhanced contractility is translated into heterogeneous reductions in apical cell areas across the tissue, disrupting cellular packings within the germband. Conversely, inactivation of Rho1 signaling in optoGAP embryos decreases both medial and junctional myosin accumulation, leading to a dramatic reduction in cell area fluctuations. These results demonstrate that the level of Rho1 activity and the balance between junctional and medial myosin regulate apical cell area fluctuations and cellular packings in the germband, which have been proposed to influence the biophysics of cell rearrangements and tissue fluidity.STATEMENT OF SIGNIFICANCETissues are shaped by forces produced by dynamic patterns of actomyosin contractility. However, the mechanisms underlying these myosin patterns and their translation into cell behavior and tissue-level movements are not understood. Here, we show that optogenetic tools designed to control upstream regulators of myosin II can be used to rapidly manipulate myosin patterns and analyze the effects on cell behaviors during tissue morphogenesis. Combining optogenetics with live imaging in the developing fruit fly embryo, we show that acute perturbations to upstream myosin regulators are sufficient to rapidly perturb existing myosin patterns and alter cell movements and shapes during axis elongation, resulting in abnormalities in embryo shape. These results directly link myosin contractility patterns to cell behaviors that shape tissues, providing new insights into the mechanisms that generate functional tissues.

scholarly journals Mapping calcium dynamics in a developing tubular structure

2020 ◽  
Author(s):  
Jorgen Hoyer ◽  
Morsal Saba ◽  
Daniel Dondorp ◽  
Kushal Kolar ◽  
Riccardo Esposito ◽  
...  
Keyword(s):  
Cell Types ◽  
Feedback Mechanism ◽  
Adult Brain ◽  
Actin Dynamics ◽  
Cytoskeletal Network ◽  
Notochord Cell ◽  
Wide Range ◽  
Store Operated Calcium Entry ◽  
And Function ◽  
Cell Intercalation

AbstractCalcium is a ubiquitous and versatile second messenger that plays a central role in the development and function of a wide range of cell types, tissues and organs. Despite significant recent progress in the understanding of calcium (Ca2+) signalling in organs such as the developing and adult brain, we have relatively little knowledge of the contribution of Ca2+ to the development of tubes, structures widely present in multicellular organisms. Here we image Ca2+ dynamics in the developing notochord of Ciona intestinalis. We show that notochord cells exhibit distinct Ca2+ dynamics during specific morphogenetic events such as cell intercalation, cell elongation and tubulogenesis. We used an optogenetically controlled Ca2+ actuator to show that sequestration of Ca2+ results in defective notochord cell intercalation, and pharmacological inhibition to reveal that stretch-activated ion channels (SACs), inositol triphosphate receptor (IP3R) signalling, Store Operated Calcium Entry (SOCE), Sarco/endoplasmic reticulum Ca2+-ATPase (SERCA) and gap junctions are required for regulating notochord Ca2+ activity during tubulogenesis. Cytoskeletal rearrangements drive the cell shape changes that accompany tubulogenesis. In line with this, we show that Ca2+ signalling modulates reorganization of the cytoskeletal network across the morphogenetic events leading up to and during tubulogenesis of the notochord. We additionally demonstrate that perturbation of the actin cytoskeleton drastically remodels Ca2+ dynamics, suggesting a feedback mechanism between actin dynamics and Ca2+ signalling during notochord development. This work provides a framework to quantitatively define how Ca2+ signalling regulates tubulogenesis using the notochord as model organ, a defining structure of all chordates.

scholarly journals Long-term, in toto live imaging of the developing mouse heart

2020 ◽  
Author(s):  
Yanzhu Yue ◽  
Xin Li ◽  
Youdong Zhang ◽  
Aibin He
Keyword(s):  
Imaging System ◽  
Light Sheet ◽  
Live Imaging ◽  
Mouse Heart ◽  
Cell Behaviors ◽  
Oriented Cell Division ◽  
Lower Vertebrates ◽  
Imaging Strategy ◽  
Cell Intercalation ◽  
Gated Imaging

Abstract Mapping holistic cell behaviors sculpting mammalian heart has been a goal, but so far only successes in transparent invertebrates and lower vertebrates. Using a live-imaging system comprising a customized vertical light-sheet microscope equipped with a culture module, a heartbeat-gated imaging strategy, and a digital image processing framework, we realized imaging of developing mouse hearts with uninterrupted cell lineages for up to 1.5 days. Four-dimensional landscapes of cell behaviors revealed a blueprint for ventricle chamber formation in which biased outward migration of outermost cardiomyocytes coupled with cell intercalation and horizontal division. The trabeculae, an inner muscle architecture, was developed through early fate segregation and transmural cell arrangement involving both oriented cell division and directional migration. Thus, live-imaging reconstruction affords a transformative means for deciphering mammalian organogenesis.

The molecular basis of ciliopathies and cyst formation

2015 ◽  
Author(s):  
Wolfgang Kühn ◽  
Gerd Walz
Keyword(s):  
Planar Cell Polarity ◽  
Critical Role ◽  
Mammalian Target Of Rapamycin ◽  
Renal Cysts ◽  
Cyst Formation ◽  
Cystic Kidney Disease ◽  
Cystic Kidney ◽  
Convergent Extension ◽  
Diverse Range ◽  
Cell Intercalation

Abnormalities of the cilium, termed ‘ciliopathies’, are the prime suspect in the pathogenesis of renal cyst formation because the gene products of cystic disease-causing genes localize to them, or near them. However, we only partially understand how cilia maintain the geometry of kidney tubules, and how abnormal cilia lead to renal cysts, and the diverse range of diseases attributed to them. Some non-cystic diseases share pathology of the same structures. Although still incompletely understood, cilia appear to orient cells in response to extracellular cues to maintain the overall geometry of a tissue, thereby intersecting with the planar cell polarity (PCP) pathway and the actin cytoskeleton. The PCP pathway controls two morphogenetic programmes, oriented cell division (OCD) and convergent extension (CE) through cell intercalation that both seem to play a critical role in cyst formation. The two-hit theory of cystogenesis, by which loss of the second normal allele causes tubular epithelial cells to form kidney cysts, has been largely borne out. Additional hits and influences may better explain the rate of cyst formation and inter-individual differences in disease progression. Ciliary defects appear to converge on overlapping signalling modules, including mammalian target of rapamycin and cAMP pathways, which can be targeted to treat human cystic kidney disease irrespective of the underlying gene mutation.

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