The axolotl genome and the evolution of key tissue formation regulators

Nowoshilow, Sergej; Schloissnig, Siegfried; Fei, Ji-Feng; Dahl, Andreas; Pang, Andy Wing Chun; Pippel, Martin; Winkler, Sylke; Hastie, Alex; Young, George R.; Roscito, Juliana G.; Falcón, Francisco José Calazans; Knapp, Dunja; Powell, Sean; Cruz, Alfredo; Cao, Han; Habermann, Bianca; Hiller, Michael; Tanaka, Elly M.; Myers, Eugene W.

doi:10.1038/nature25458

Cited by 455 publications

(515 citation statements)

References 39 publications

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“…Salamanders possess a complex genome several times the size of the human genome (Elewa et al, 2017; Nowoshilow et al, 2018). The toolkit for salamander regeneration was once dominated by methods like gene electroporation, retroviral infection, and morpholino-based knockdown (Kawakami et al, 2006; Roy et al, 2000), but additional genetic manipulations like transgenesis (Khattak et al, 2009), targeted mutations, and gene cassette knock-in technology have become available in the past few years (Fei et al, 2017; Fei et al, 2014; Flowers et al, 2017; Flowers et al, 2014).…”

Section: Model Systems For Innate Tissue Regenerationmentioning

confidence: 99%

“…The toolkit for salamander regeneration was once dominated by methods like gene electroporation, retroviral infection, and morpholino-based knockdown (Kawakami et al, 2006; Roy et al, 2000), but additional genetic manipulations like transgenesis (Khattak et al, 2009), targeted mutations, and gene cassette knock-in technology have become available in the past few years (Fei et al, 2017; Fei et al, 2014; Flowers et al, 2017; Flowers et al, 2014). Guided by the recent reports of the Iberian ribbed newt ( Pleurodeles waltl) and Mexican axolotl ( Ambystoma mexicanum ) genomes, the availability of these tools will increase the use of salamanders to explore understudied questions in regenerative capacity and mechanisms (Elewa et al, 2017; Nowoshilow et al, 2018). …”

Section: Model Systems For Innate Tissue Regenerationmentioning

confidence: 99%

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A Regeneration Toolkit

Mokalled

Poss

2018

Developmental Cell

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Summary The ability of animals to replace injured body parts has been a subject of fascination for centuries. The emerging importance of regenerative medicine has reinvigorated investigations of innate tissue regeneration, and the development of powerful genetic tools has fueled discoveries into how tissue regeneration occurs. Here we present an overview of the armamentarium employed to probe regeneration in vertebrates, highlighting areas where further methodology advancement will deepen mechanistic findings.

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Section: Model Systems For Innate Tissue Regenerationmentioning

confidence: 99%

Section: Model Systems For Innate Tissue Regenerationmentioning

confidence: 99%

A Regeneration Toolkit

Mokalled

Poss

2018

Developmental Cell

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“…Apart from Angiosperms that have a ̴ 1000‐fold difference in genome size (Bennett & Leitch, ) (although not all of this variation is attributable to TEs), at least several animal lineages are known to vary considerably in genome size and also contain species with exceptionally large genomes. These include salamanders (14–120 Gb) (Nowoshilow et al, ), Orthoptera (1.52–16.56 Gb) and crustaceans (0.14–63.20 Gb) (Hultgren, Jeffery, Moran, & Gregory, ). However, the underlying mechanism of how these large genomes formed remains unclear because most of our knowledge about genome size change is based on lineages with small genomes (Dufresne & Jeffery, ).…”

Section: Introductionmentioning

confidence: 99%

TERAD: Extraction of transposable element composition from RADseq data

Chak

Rubenstein

2019

Molecular Ecology Resources

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Transposable elements (TEs) – selfish DNA sequences that can move within the genome – comprise a large proportion of the genomes of many organisms. Although low‐coverage whole‐genome sequencing can be used to survey TE composition, it is noneconomical for species with large quantities of DNA. Here, we utilize restriction‐site associated DNA sequencing (RADSeq) as an alternative method to survey TE composition. First, we demonstrate in silico that double digest restriction‐site associated DNA sequencing (ddRADseq) markers contain the same TE compositions as whole genome assemblies across arthropods. Next, we show empirically using eight Synalpheus snapping shrimp species with large genomes that TE compositions from ddRADseq and low‐coverage whole‐genome sequencing are comparable within and across species. Finally, we develop a new bioinformatic pipeline, TERAD, to extract TE compositions from RADseq data. Our study expands the utility of RADseq to study the repeatome, making comparative studies of genome structure for species with large genomes more tractable and affordable.

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“…; Nowoshilow et al. ), but the majority of these projects are in frogs that generally have smaller genomes than salamanders (Gregory ). Meanwhile, there have been successful efforts to obtain reduced representation libraries for salamanders with large genomes by either modifications of protocols to reduce off‐target reads (McCartney‐Melstad et al.…”

mentioning

confidence: 99%

Genome‐specific histories of divergence and introgression between an allopolyploid unisexual salamander lineage and two ancestral sexual species

2018

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Quantifying introgression between sexual species and polyploid lineages traditionally thought to be asexual is an important step in understanding what drives the longevity of putatively asexual groups. Here, we capitalize on three recent innovations-ultraconserved element (UCE) sequencing, bioinformatic techniques for identifying genome-specific variation in polyploids, and model-based methods for evaluating historical gene flow-to measure the extent and tempo of introgression over the evolutionary history of an allopolyploid lineage of all-female salamanders and two ancestral sexual species. Our analyses support a scenario in which the genomes sampled in unisexual salamanders last shared a common ancestor with genomes in their parental species ∼3.4 million years ago, followed by a period of divergence between homologous genomes. Recently, secondary introgression has occurred at different times with each sexual species during the last 500,000 years. Sustained introgression of sexual genomes into the unisexual lineage is the defining characteristic of their reproductive mode, but this study provides the first evidence that unisexual genomes have undergone long periods of divergence without introgression. Unlike other sperm-dependent taxa in which introgression is rare, the alternating periods of divergence and introgression between unisexual salamanders and their sexual relatives could explain why these salamanders are among the oldest described unisexual animals.

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The axolotl genome and the evolution of key tissue formation regulators

Cited by 455 publications

References 39 publications

A Regeneration Toolkit

A Regeneration Toolkit

TERAD: Extraction of transposable element composition from RADseq data

Genome‐specific histories of divergence and introgression between an allopolyploid unisexual salamander lineage and two ancestral sexual species

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