Stochastic loss and gain of symmetric divisions in the C. elegans epidermis perturbs robustness of stem cell number

Katsanos, Dimitris; Koneru, Sneha L.; Boukhibar, Lamia Mestek; Gritti, Nicola; Ghose, Ritobrata; Appleford, Peter J.; Doitsidou, Maria; Woollard, Alison; Zon, Jeroen S. van; Poole, Richard J.; Barkoulas, Michalis

doi:10.1371/journal.pbio.2002429

Cited by 29 publications

(58 citation statements)

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“…The development of the seam cells is canalized to the point of eutely, so that during normal development the balance of asymmetric and symmetric divisions maintains a constant seam cell number (Sulston and Horvitz, ). Variation in the number of seam cells can be used as a metric for phenotypic variation in animals subjected to genetic perturbation in addition to environmental stress (Mestek Boukhibar and Barkoulas, ; Katsanos et al, ). In C. elegans , we find that a number of DnaJs, not limited to ER‐associated chaperones, are involved in canalization.…”

Section: Introductionmentioning

confidence: 99%

DnaJ chaperones contribute to canalization

et al. 2019

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Canalization, an intrinsic robustness of development to external (environmental) or internal (genetic) perturbations, was first proposed over half a century ago. However, whether the robustness to environmental stress (environmental canalization [EC]) and to genetic variation (genetic canalization) are underpinned by the same molecular basis remains elusive. The recent discovery of the involvement of two endoplasmic reticulum (ER)‐associated DnaJ genes in developmental buffering, orthologues of which are conserved across Metazoa, indicates that the role of ER‐associated DnaJ genes might be conserved across the animal kingdom. To test this, we surveyed the ER‐associated DnaJ chaperones in the nematode Caenorhabditis elegans. We then quantified the phenotype, in the form of variance and mean of seam cell counts, from RNA interference knockdown of DnaJs under three different temperatures. We find that seven out of eight ER‐associated DnaJs are involved in either EC or microenvironmental canalization. Moreover, we also found two DnaJ genes not specifically associated with ER (DNAJC2/dnj‐11 and DNAJA2/dnj‐19) were involved in canalization. Protein expression pattern showed that these DnaJs are upregulated by heat stress, yet not all of them are expressed in the seam cells. Moreover, we found that most of the buffering DnaJs also control lifespan. We therefore concluded that a number of DnaJ chaperones, not limited to those associated with the ER, are involved in canalization as a part of the complex system that underlies development.

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Section: Introductionmentioning

confidence: 99%

DnaJ chaperones contribute to canalization

et al. 2019

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“…Fewer have been found that are required for eff-1 activation, which could also provide additional noise or variability into the cell fate decision. Studies have shown a lin-22 loss-of-function mutation decreases P3.p cell fusion frequencies (Katsanos et al, 2017;Schlager et al, 2006). LIN-22 codes for a Hairy/Enhancer of Split-related transcription factor, which was found to act in the Wnt pathway by repressing egl-18, a GATA transcription factor, also a repressor of cell fusion in the seam cells (Gorrepati et al, 2013;Katsanos et al, 2017;Wrischnik and Kenyon, 1997).…”

Section: Discussionmentioning

confidence: 99%

“…Studies have shown a lin-22 loss-of-function mutation decreases P3.p cell fusion frequencies (Katsanos et al, 2017;Schlager et al, 2006). LIN-22 codes for a Hairy/Enhancer of Split-related transcription factor, which was found to act in the Wnt pathway by repressing egl-18, a GATA transcription factor, also a repressor of cell fusion in the seam cells (Gorrepati et al, 2013;Katsanos et al, 2017;Wrischnik and Kenyon, 1997). Therefore, variations in not only the inhibitor molecules, but LIN-22 could create noise and variability that leads to stochastic eff-1 expression and cell fusion.…”

Section: Discussionmentioning

confidence: 99%

Variability in β-catenin pulse dynamics in a stochastic cell fate decision inC. elegans

Kroll

Tsiaxiras

Zon

2018

Preprint

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Stochastic cell fate decisions occur frequently during animal development. In many cases, individual cells randomly choose one cell fate out of a limited repertoire of fates, but with the relative frequency of the different possible fates tightly controlled. It is not understood how signaling networks enable such cell-autonomous stochastic decisions and what network properties control the relative frequency of the resulting cell fates. To address these questions, we studied the differentiation of the C. elegans P3.p cell as a model system for a cellautonomous stochastic cell fate decision. We use a novel time-lapse microscopy technique to measure the single-cell dynamics of BAR-1/β-catenin and LIN-39/Hox, two key regulators of the network, while monitoring both the timing and outcome of the decision. Surprisingly, the timing of the decision is highly regulated, even in mutants that drastically alter the frequency of the cell fates. Using experimental data and modeling approaches, we find that a combination of variability in LIN-39 levels and variability in the timing of BAR-1/β-catenin signaling are noise sources that bias the stochastic decision. Our results highlight that a novel aspect of Wnt signaling can provide sufficient variation in a signaling network to enable a cell-autonomous stochastic cell fate decision in a multicellular organism.

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“…To construct a pseam::GFP::CAAX::unc-54 transgene, the GFP sequence was amplified using pPD93.65 as template and fused to the following sequence containing the CAAX motif using nested PCR 5’AAGGACGGAAAGAAGAAGAAGAAGAAGTCCAAGACCAAGTGCGTCATCATG3’. The GFP::CAAX fragment was then subcloned into pIR5 (Katsanos et al . 2017) via Gibson assembly.…”

Section: Methodsmentioning

confidence: 99%

A cell fate switch in theC. elegansseam cell lineage occurs through modulation of the Wnt asymmetry pathway in response to temperature increase

Barkoulas

Hintze²,

Koneru³

et al. 2019

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23Populations often display consistent developmental phenotypes across individuals 24 despite the inevitable biological stochasticity. Nevertheless, developmental robustness 25 has limits and systems can fail upon change in the environment or the genetic 26 background. We use here the seam cells, a population of epidermal stem cells in 27 Caenorhabditis elegans, to study the influence of temperature change and genetic 28 variation on cell fate. Seam cell development has mostly been studied so far in the lab 29 reference strain (N2), grown at 20° temperature. We demonstrate that an increase in 30 culture temperature to 25°, introduces variability in the wild-type seam cell lineage with a 31 proportion of animals showing an increase in seam cell number. We map this increase to 32 lineage-specific symmetrisation events of normally asymmetric cell divisions at the final 33 larval stage, leading to the retention of seam cell fate in both daughter cells. Using 34 genetics and single molecule imaging, we demonstrate that this symmetrisation occurs 35 via changes in the Wnt asymmetry pathway, leading to aberrant Wnt target activation in 36 anterior cell daughters. We find that intrinsic differences in the Wnt asymmetry pathway 37 already exist between seam cells at 20° and this may sensitise cells towards a cell fate 38 switch at increased temperature. Finally, we demonstrate that wild isolates of C. elegans 39 display variation in seam cell sensitivity to increased culture temperature, although seam 40 cell numbers are comparable when raised at 20°. Our results highlight how temperature 41 can modulate cell fate decisions in an invertebrate model of stem cell patterning. 42 43 44 45 46 47 48 During development, organisms must withstand environmental and genetic perturbations 49 to produce consistent phenotypes (Felix and Barkoulas 2012). These phenotypes are 50 often a product of complex developmental events that require a tight balance between cell 51 division and cell differentiation (Soufi and Dalton 2016). A key example is stem cell 52 divisions, consisting of highly controlled asymmetric and symmetric patterns, which are 53 vital for generating cell diversity, as well as maintaining cell numbers in tissues and organs 54 (Morrison and Kimble 2006; Knoblich 2008). Developmental robustness has inherent 55 limits and certain perturbations can push a system outside its buffering zone (Braendle 56 and Felix 2008; Barkoulas et al. 2013). In these cases, it is also important to understand 57 how systems fail by investigating how perturbations precisely modulate developmental 58 processes. Here we address the question of how changes in environmental temperature 59 can affect cell fate outcomes using the nematode C. elegans as a model system. While it 60 is well known that increasing or decreasing environmental temperature can change the 61 development speed in C. elegans, the effect of temperature on specific cell division and 62 fate acquisition events is less well understood. The C. elegans adult hermaphrodite 63 co...

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Stochastic loss and gain of symmetric divisions in the C. elegans epidermis perturbs robustness of stem cell number

Cited by 29 publications

References 86 publications

DnaJ chaperones contribute to canalization

DnaJ chaperones contribute to canalization

Variability in β-catenin pulse dynamics in a stochastic cell fate decision inC. elegans

A cell fate switch in theC. elegansseam cell lineage occurs through modulation of the Wnt asymmetry pathway in response to temperature increase

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