Reciprocal analyses in zebrafish and medaka reveal that harnessing the immune response promotes cardiac regeneration

Lai, Shih Lei; Marín-Juez, Rubén; Moura, Pedro L.; Kuenne, Carsten; Lai, Jason Kuan Han; Tsedeke, Ayele Taddese; Guenther, Stefan; Looso, Mario; Stainier, Didier Y. R.

doi:10.7554/elife.25605

Cited by 243 publications

(387 citation statements)

References 55 publications

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“…In bilaterians, unbiased transcriptomics/proteomics approaches have proven useful to determine the genetic programs involved in the regeneration of complex structures, such as body parts in planarians (Kao et al, 2013) or Hydra (Petersen et al, 2015), appendages in zebrafish, lizards, salamanders (Hutchins et al, 2014;Bryant et al, 2017;Rabinowitz et al, 2017), heart in zebrafish (Lai et al, 2017) and mammals (Quaife-Ryan et al, 2017), lens in salamanders (Looso et al, 2013). These programs drive wound healing, stem cell recruitment and/or somatic tissue re-specification and 3D-patterning, the latter including the re-activation of specific developmental patterning mechanisms.…”

Section: Introductionmentioning

confidence: 99%

Generic and context-dependent gene modulations duringHydrawhole body regeneration

Wenger

Buzgariu

Perruchoud

et al. 2019

Preprint

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The cnidarian Hydra is a classical model of whole-body regeneration. Historically, Hydra apical regeneration has received more attention than its basal counterpart, most studies considering these two regenerative processes independently. We present here a transcriptome-wide comparative analysis of apical and basal regeneration after decapitation and mid-gastric bisection, augmented with a characterization of positional and cell-type expression patterns in non-regenerating animals. The profiles of 25'637 Hydra transcripts are available on HydrATLAS (https://hydratlas.unige.ch), a web interface allowing a convenient access to each transcript profile. These data indicate that generic impulse-type modulations occur during the first four hours post-amputation, consistent with a similar integration of injury-related cues on both sides of the amputation plane. Initial divergences in gene regulations are observed in regenerating tips between four and eight hours post-amputation, followed by a dramatic transcriptomic reprogramming between eight and 16 hours when regulations become sustained. As expected, central components of apical patterning, Wnt3 and HyBra1, are among the earliest genes up-regulated during apical regeneration. During early basal regeneration, a BMP signaling ligand (BMP5-8c) and a potential BMP inhibitor (NBL1) are up-regulated, suggesting that BMP signaling is involved in the basal organizer, as supported by higher levels of phosphorylated Smad in the basal region and by the LiCl-induced extension of NBL1 expression. By contrast, upon ectopic activation of Wnt/b-catenin signaling, NBL1 is no longer expressed, basal differentiation is not maintained and basal regeneration is abolished. A tight cross-talk between Wnt/b-catenin apically and BMP signaling basally appears necessary for maintaining and regenerating Hydra anatomy.

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Section: Introductionmentioning

confidence: 99%

Generic and context-dependent gene modulations duringHydrawhole body regeneration

Wenger

Buzgariu

Perruchoud

et al. 2019

Preprint

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“…Heart regeneration potential varies considerably between species as well as with age. While zebrafish, neonatal mouse and neonatal human hearts can replace dead or lost cardiomyocytes rapidly with new heart muscle (1)(2)(3)(4)(5), medaka (6,7), cave fish (8), as well as adult mice and human hearts (9) show only poor repair. Numerous studies are, therefore, looking into the underlying principles and mechanisms that promote, or prevent, effective cardiac regeneration to establish a basis for therapeutic intervention (10).…”

Section: Introductionmentioning

confidence: 99%

Runx1 promotes scar deposition and inhibits myocardial proliferation and survival during zebrafish heart regeneration

Koth

Wang

Killen

et al. 2019

Preprint

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Runx1 is a transcription factor that plays a key role in determining the proliferative and differential state of multiple cell-types, during both development and adulthood. Here, we report how runx1 is specifically upregulated at the injury site during zebrafish heart regeneration, but unexpectedly, absence of runx1 results in enhanced regeneration. Using single cell sequencing, we found that the wild-type injury site consists of Runx1-positive endocardial cells and thrombocytes that induce expression of smooth muscle and collagen genes without differentiating into myofibroblasts. Both these populations are absent in runx1 mutants, resulting in a less collagenous and fibrinous scar. The reduction in fibrin in the mutant is further explained by reduced myofibroblast formation and by upregulation of components of the fibrin degradation pathway, including plasminogen receptor Annexin 2A as well as downregulation of plasminogen activator inhibitor serpine1 in myocardium and endocardium, resulting in increased levels of Plasminogen. In addition, we find enhanced myocardial proliferation as well as increased myocardial survival in the mutant. Our findings suggest that Runx1 controls the regenerative response of multiple cardiac cell-types and that targeting Runx1 is a novel therapeutic strategy to induce endogenous heart repair.

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“…Macrophages are known regulators of cardiac regeneration in zebrafish and fibrosis in non-regenerating species (Aurora et al, 2014; Frantz and Nahrendorf, 2014; Lai et al, 2017). Colony stimulating factor receptor 1+ (Csfr1+) macrophages were stained in both injured and remote regions of the heart following injury to determine their behavior in the grass carp (Chen et al, 2015).…”

Section: Resultsmentioning

confidence: 99%

“…Proliferation of cardiomyocytes is a known driver of cardiac regeneration in non-mammalian species and neonatal mammals (Cano-Martínez et al, 2010; Flink, 2002; Gonzalez-Rosa et al, 2011; Lai et al, 2017; Liao et al, 2017; Porrello et al, 2011; Sallin et al, 2015; Schnabel et al, 2011; Stockdale et al, 2018; Vargas-González et al, 2005; Yu et al, 2018); further, a regenerative phenotype has not yet been reported in the absence of cardiomyocyte proliferation (Ito et al, 2014; Lin and Pu, 2014; Marshall et al, 2017). However, the recent finding of widespread cardiomyocyte proliferation in non-regenerative Pachón Astyanax mexicanus suggests that this behavior is not the sole factor that dictates a regenerative response (Stockdale et al, 2018).…”

Section: Discussionmentioning

confidence: 99%

Persistent fibrosis and decreased cardiac function following cardiac injury in theCtenopharyngodon idella(grass carp)

Long

Webb

Wang

2019

Preprint

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Following the discovery of heart regeneration in zebrafish, several more species within the Cyprinidae family have been found to have the same capability, suggesting heart regeneration may be conserved within this family. Although gonad regeneration has been observed in grass carp (Ctenopharyngodon idella), one of the largest cyprinid fish, the species’ response to cardiac injury has not been characterized. Surprisingly, we found cardiomyocytes do not repopulate the injured region following cryoinjury to the ventricle, instead exhibiting unresolved fibrosis and decreased cardiac function that persists for the 8-week duration of this study. Compared to other cyprinid fish studied, infiltration of macrophages is delayed and muted in this model. Additionally, fibroblasts are depleted following injury, a phenomenon not previously described in any cardiac model. This study shows that heart regeneration is not conserved among the Cyprinidae family and suggests the important role of non-fibroblasts in chronic fibrosis. Further study of these phenomenon may reveal the underlying differences between regeneration versus unresolved fibrosis in heart disease.Summary statementGrass carp, a member of the Cyprinidae family that includes regenerative zebrafish, do not regenerate functional cardiac tissue after cryoinjury. Instead, healing progresses through collagen deposition and scar formation.

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Reciprocal analyses in zebrafish and medaka reveal that harnessing the immune response promotes cardiac regeneration

Cited by 243 publications

References 55 publications

Generic and context-dependent gene modulations duringHydrawhole body regeneration

Generic and context-dependent gene modulations duringHydrawhole body regeneration

Runx1 promotes scar deposition and inhibits myocardial proliferation and survival during zebrafish heart regeneration

Persistent fibrosis and decreased cardiac function following cardiac injury in theCtenopharyngodon idella(grass carp)

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