A transcriptional time-course analysis of oral vs. aboral whole-body regeneration in the Sea anemone Nematostella vectensis

Schaffer, Amos A.; Bazarsky, Michael; Levy, Karine; Chalifa‐Caspi, Vered; Gat, Uri

doi:10.1186/s12864-016-3027-1

Cited by 47 publications

(80 citation statements)

References 105 publications

(155 reference statements)

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“…Key genes found by Schaffer et al (2016) to be differentially expressed in orally regenerating N. vectensis include multiple components of the Wnt pathway, multiple transcription factors and homeobox genes, consistent with results here for E. pallida and with an earlier study on N. vectensis (DuBuc et al 2014). The homeobox gene Otxc was not found in the present study, consistent with it being found to denote physa (foot) not oral regeneration in N.…”

Section: Discussionsupporting

confidence: 92%

“…This indicates that N. vectensis is not the most representative model species for anemone regeneration. Multiple recent studies have explored regeneration in N. vectensis from a transcriptional, morphological and cellular perspective (Amiel et al 2015;DuBuc et al 2014;Schaffer et al 2016) and some similarities and differences can be drawn between this species and E. pallida.…”

Section: Discussionmentioning

confidence: 99%

“…In contrast to N. vectensis, Notch pathway genes were not differentially expressed in this study (except for one notch1 gene DE at T1 vs T5, Supplementary Table S5g). There is no evidence that any of the DE E. pallida genes have either a chitin binding or synthesising protein domain (chitin genes were found highly enriched in N. vectensis (Schaffer et al 2016)), although the GO term associated with 'chitin binding' (GO:0008061) is found in several genes with carbohydrate binding domains, one of which is Chitotriosidase-1 (DE at T1 vs T2, Supplementary Table S5g). Other results for N. vectensis found by DuBuc et al (2014) are also consistently found in E. pallida, e.g., the MAPK cascade was proposed to be essential for would healing and is significantly enriched here and many metalloproteinases can be found throughout the timecourse.…”

Section: Discussionmentioning

confidence: 99%

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The rapid regenerative response of a model sea anemone speciesExaiptasia pallidais characterised by tissue plasticity and highly coordinated cell communication

Burg

Pavasovic

Gilding

et al. 2019

Preprint

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Regeneration of a limb or tissue can be achieved through multiple different pathways and mechanisms. The sea anemone Exaiptasia pallida has been observed to have excellent regenerative proficiency but this has not yet been described transcriptionally. In this study we examined the genetic expression changes during a regenerative timecourse and report key genes involved in regeneration and wound healing. We found that the major response was an early upregulation of genes involved in cellular movement and cell communication, which likely contribute to a high level of tissue plasticity resulting in the rapid regeneration response observed in this species. We find the immune system is only transcriptionally active in the first eight hours post-amputation and conclude, in accordance with previous literature, that the immune system and regeneration have an inverse relationship. Fifty-nine genes (3.8% of total) differentially expressed during regeneration were identified as having no orthologues in other species, indicating that regeneration in E. pallida may rely on the activation of speciesspecific novel genes. Additionally, taxonomically-restricted novel genes, including speciesspecific novels, and highly conserved genes were identified throughout the regenerative timecourse, showing that both may work in concert to achieve complete regeneration. We conclude that E. pallida behaves similarly to other anemone species such as Nematostella vectensis and Calliactis polypus but with some notable novel differences.

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Section: Discussionsupporting

confidence: 92%

Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

See 1 more Smart Citation

The rapid regenerative response of a model sea anemone speciesExaiptasia pallidais characterised by tissue plasticity and highly coordinated cell communication

Burg

Pavasovic

Gilding

et al. 2019

Preprint

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“…A long-standing question in the field of regeneration is whether and to what extent embryonic gene programs that are initially used to build an organism are re-used during regeneration (Morgan 1901). Several transcriptomic studies of regeneration have highlighted the importance of re-deployed developmental pathways in axolotl, anole, zebrafish and sea anemones (Bryant et al 2017) (Habermann et al 2004) (Hutchins et al 2014) (Mathew et al 2009) (Rodius et al 2016) (Gardiner et al 1995;Schaffer et al 2016). Many studies have directly compared embryonic and regenerative gene expression of single or groups of genes identifying i) genes that are specific to embryonic development (Binari et al 2013), ii) genes that are specifically expressed or required during regeneration (Millimaki et al 2010;Katz et al 2015), and iii) embryonic genes that are re-used during regeneration to some extent (Imokawa and Yoshizato 1997) (Carlson et al 2001) (Torok et al 1998) (Özpolat et al 2012) (Wang and Beck 2014).…”

Section: Introductionmentioning

confidence: 99%

“…Nematostella has long been used as a model system for embryonic development, the evolution of body patterning, and gene regulatory networks (Hand and Uhlinger 1992;Wikramanayake et al 2003;Hutchins et al 2014; Wang and Beck 2014). More recently, Nematostella has emerged as a powerful whole-body regeneration model as it capable of re-growing missing body parts in less than a week (Burton and Finnerty 2009;Trevino et al 2011;Passamaneck and Martindale 2012;Bossert et al 2013;Dubuc et al 2014;Amiel et al 2015;Schaffer et al 2016) Regeneration in Nematostella follows a dynamic but highly stereotypical morphological and cellular program involving tissue rearrangement and the de novo formation of body structures (Amiel et al 2015).…”

Section: Introductionmentioning

confidence: 99%

Whole body regeneration deploys a rewired embryonic gene regulatory network logic

Johnston

et al. 2019

Preprint

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For more than a century, researchers have been trying to understand the relationship between embryogenesis and regeneration (Morgan 1901). A longstanding hypothesis is that biological processes originally used during embryogenesis are re-deployed during regeneration. In the past decade, we have begun to understand the relationships of genes and their organization into regulatory networks responsible for driving embryogenesis (Davidson et al. 2002; Röttinger et al. 2012) and regeneration (Srivastava et al. 2014; Lobo and Levin 2015; Rodius et al. 2016) in diverse taxa. Here, we compare these networks in the same species to investigate how regeneration re-uses genetic interactions originally set aside for embryonic development. Using a uniquely suited embryonic development and whole-body regeneration model, the sea anemone Nematostella vectensis, we show that at the transcriptomic level the regenerative programpartially re-uses elements of the embryonic gene network in addition to a small cohort of genes that are only activated during regeneration. We further identified co-expression modules that are either i) highly conserved between these two developmental trajectories and involved in core biological processes or ii) regeneration specific modules that drive cellular events unique to regeneration.Finally, our functional validation reveals that apoptosis is a regeneration-specific process in Nematostella and is required for the initiation of the regeneration program. These results indicate that regeneration reactivates embryonic gene modules to accomplish basic cellular functions but deploys a novel gene network logic to activate the regenerative process.

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Single-Cell Transcriptomic Analysis in the Regenerating Cnidarian Nematostella vectensis

Plessier

Schmutz

Novault

2022

Methods in Molecular Biology

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Cnidarians have historically served as excellent laboratory models for regenerative development given their capacity to regrow large portions of the adult organism. This capacity is notably absent or poorly developed in the powerful genetic laboratory models Drosophila, C. elegans, and mouse. Increasingly, development of genetic and genomic resources and the application of next-generation sequencing-based techniques in cnidarian systems has further expanded the potential of cnidarian regenerative models. Here, we present a workflow for the characterization of the regenerative response in the sea anemone Nematostella vectensis utilizing fluorescence-activated cell sorting and a plate-based single-cell RNA-sequencing pipeline. This approach can characterize the transcriptional response during regeneration in distinct populations of cells, thus providing a quantitative view of a whole organism process at cellular resolution.

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A transcriptional time-course analysis of oral vs. aboral whole-body regeneration in the Sea anemone Nematostella vectensis

Cited by 47 publications

References 105 publications

The rapid regenerative response of a model sea anemone speciesExaiptasia pallidais characterised by tissue plasticity and highly coordinated cell communication

The rapid regenerative response of a model sea anemone speciesExaiptasia pallidais characterised by tissue plasticity and highly coordinated cell communication

Whole body regeneration deploys a rewired embryonic gene regulatory network logic

Single-Cell Transcriptomic Analysis in the Regenerating Cnidarian Nematostella vectensis

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