Divergence of 3′ ends as a driver of short interspersed nuclear element (SINE) evolution in the Salicaceae

Kögler, Anja; Seibt, Kathrin M.; Heitkam, Tony; Morgenstern, Kristin; Reiche, Birgit; Brückner, Marie; Wolf, Heino; Krabel, Doris; Schmidt, Thomas

doi:10.1111/tpj.14721

Cited by 6 publications

(25 citation statements)

References 92 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…The similarities include both, repeat family and abundance. In line with evidence from other conifers (Prunier et al, 2016), these results also suggest the limited TE elimination, usually carried out by recombination, reshuffling, fragmentation, or removal as aftermath to genomic rearrangements (Ma et al, 2004;Ren et al, 2018;Kögler et al, 2020;Maiwald et al, 2021;Schmidt et al, 2021). Along the same lines, we did not observe any transpositional bursts of amplification during the speciation of the larches.…”

Section: Similar Repeat Profiles In European and Japanese Larch Genomes Likely Results From Repeat Accumulation And Reduced Turnoversupporting

confidence: 90%

Comparative Repeat Profiling of Two Closely Related Conifers (Larix decidua and Larix kaempferi) Reveals High Genome Similarity With Only Few Fast-Evolving Satellite DNAs

et al. 2021

Self Cite

View full text Add to dashboard Cite

In eukaryotic genomes, cycles of repeat expansion and removal lead to large-scale genomic changes and propel organisms forward in evolution. However, in conifers, active repeat removal is thought to be limited, leading to expansions of their genomes, mostly exceeding 10 giga base pairs. As a result, conifer genomes are largely littered with fragmented and decayed repeats. Here, we aim to investigate how the repeat landscapes of two related conifers have diverged, given the conifers’ accumulative genome evolution mode. For this, we applied low-coverage sequencing and read clustering to the genomes of European and Japanese larch, Larix decidua (Lamb.) Carrière and Larix kaempferi (Mill.), that arose from a common ancestor, but are now geographically isolated. We found that both Larix species harbored largely similar repeat landscapes, especially regarding the transposable element content. To pin down possible genomic changes, we focused on the repeat class with the fastest sequence turnover: satellite DNAs (satDNAs). Using comparative bioinformatics, Southern, and fluorescent in situ hybridization, we reveal the satDNAs’ organizational patterns, their abundances, and chromosomal locations. Four out of the five identified satDNAs are widespread in the Larix genus, with two even present in the more distantly related Pseudotsuga and Abies genera. Unexpectedly, the EulaSat3 family was restricted to L. decidua and absent from L. kaempferi, indicating its evolutionarily young age. Taken together, our results exemplify how the accumulative genome evolution of conifers may limit the overall divergence of repeats after speciation, producing only few repeat-induced genomic novelties.

show abstract

Section: Similar Repeat Profiles In European and Japanese Larch Genomes Likely Results From Repeat Accumulation And Reduced Turnoversupporting

confidence: 90%

Comparative Repeat Profiling of Two Closely Related Conifers (Larix decidua and Larix kaempferi) Reveals High Genome Similarity With Only Few Fast-Evolving Satellite DNAs

et al. 2021

Self Cite

View full text Add to dashboard Cite

show abstract

“…The similarities include both, repeat family and abundance. In line with evidence from other conifers (Prunier et al, 2016), these results also suggest the limited TE elimination, usually carried out by recombination, reshuffling, or removal as aftermath to genomic rearrangements (Ma et al, 2004;Ren et al, 2018;Kögler et al, 2020;Maiwald et al, 2020). Along the same lines, we did not observe any transpositional bursts of amplification during the speciation of the larches.…”

Section: Similar Repeat Profiles In European and Japanese Larch Genomsupporting

confidence: 90%

Comparative repeat profiling of two closely related conifers (Larix decidua and Larix kaempferi) reveals high genome similarity with only few fast-evolving satellite DNAs

Heitkam

Schulte

Weber

et al. 2021

Preprint

Self Cite

View full text Add to dashboard Cite

In eukaryotic genomes, cycles of repeat expansion and removal lead to large-scale genomic changes and propel organisms forward in evolution. However, in conifers, active repeat removal is thought to be limited, leading to expansions of their genomes, mostly exceeding 10 gigabasepairs. As a result, conifer genomes are largely littered with fragmented and decayed repeats. Here, we aim to investigate how the repeat landscapes of two related conifers have diverged, given the conifers' accumulative genome evolution mode. For this, we applied low coverage sequencing and read clustering to the genomes of European and Japanese larch, Larix decidua (Lamb.) Carrière and Larix kaempferi (Mill.), that arose from a common ancestor, but are now geographically isolated. We found that both Larix species harbored largely similar repeat landscapes, especially regarding the transposable element content. To pin down possible genomic changes, we focused on the repeat class with the fastest sequence turnover: satellite DNAs (satDNAs). Using comparative bioinformatics, Southern, and fluorescent in situ hybridization, we reveal the satDNAs' organizational patterns, their abundances, and chromosomal locations. Four out of the five identified satDNAs are widespread in the Larix genus, with two even present in the more distantly related Pseudotsuga and Abies genera. Unexpectedly, the EulaSat3 family was restricted to L. decidua and absent from L. kaempferi, indicating its evolutionarily young age. Taken together, our results exemplify how the accumulative genome evolution of conifers may limit the overall divergence of repeats after speciation, producing only few repeat-induced genomic novelties.

show abstract

“…The genome sequence of Populus tremula (plantgenie.org, v1.1) was analyzed for the presence of SINE sequences using the software SINE-Finder (Wenke et al 2011). The respective results have been published separately by Koegler et al (2020). A manually optimized alignment of full-length SINE sequences formed the basis for the assignment of individual SINEs to families based on their pairwise identity to a family consensus.…”

Section: Design Of Isap-primersmentioning

confidence: 99%

“…A total of eight SINE (sub-) families with over 4,400 full-length copies were identified in the Populus tremula genome (Koegler et al 2020). The length of the representative consensus sequences ranges from 163 bp to 241 bp (Table 3).…”

Section: Sines Are Abundant In the Poplar Genome And Provide Suitable Targets For The Development Of Isap Markersmentioning

confidence: 99%

“…Here, we establish the ISAP marker system in poplars to offer a robust, efficient, and easy method for the identification and differentiation of different poplar accessions. The recent identification and characterization of several SINE families in poplar and related genomes allowed us to establish ISAP markers in poplar (Koegler et al 2020). Due to the genome-wide distribution of poplar SINEs, their high copy number and their family specific structure, the derived markers generate informative fingerprint-like banding patterns, valuable for genotype differentiation in poplar.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Application of retrotransposon-based Inter-SINE Amplified Polymorphism (ISAP) markers for the differentiation of common poplar genotypes

et al. 2021

Self Cite

View full text Add to dashboard Cite

On the basis of retrotransposon-insertion polymorphisms, molecular markers were developed for the identification and differentiation of poplar (<i>Populus</i> spp.) genotypes. For this purpose, short interspersed nuclear elements (SINEs) in the genome sequence of <i>Populus tremula</i> were identified and assigned to different SINE-families. For families with high copy number and high identity values, primers were derived to amplify Inter- SINE Amplified Polymorphisms (ISAPs) with polymerase chain reaction (PCR). The resulting fragments produce genotype-specific fingerprints. This molecular approach utilizes standard laboratory equipment and is therefore easy to use for the verification of plant material. We demonstrate the functionality of three distinct ISAP primer combinations by comparison to ten simple sequence repeat (SSR) markers to differentiate 23 poplar genotypes. Already by using a single ISAP primer combination all genotypes can be clearly discriminated. Furthermore, the cluster analysis based on three primer combinations divides clones according to their genetic background into two subclusters (by a bootstrap value of 98). Our results clearly demonstrate the usability of ISAP markers to differentiate genotypes and trace progenies of poplar trees.

show abstract

Divergence of 3′ ends as a driver of short interspersed nuclear element (SINE) evolution in the Salicaceae

Cited by 6 publications

References 92 publications

Comparative Repeat Profiling of Two Closely Related Conifers (Larix decidua and Larix kaempferi) Reveals High Genome Similarity With Only Few Fast-Evolving Satellite DNAs

Comparative Repeat Profiling of Two Closely Related Conifers (Larix decidua and Larix kaempferi) Reveals High Genome Similarity With Only Few Fast-Evolving Satellite DNAs

Comparative repeat profiling of two closely related conifers (Larix decidua and Larix kaempferi) reveals high genome similarity with only few fast-evolving satellite DNAs

Application of retrotransposon-based Inter-SINE Amplified Polymorphism (ISAP) markers for the differentiation of common poplar genotypes

Contact Info

Product

Resources

About