TY - JOUR
T1 - Repetitive DNA restructuring across multiple Nicotiana allopolyploidisation events shows a lack of strong cytoplasmic bias in influencing repeat turnover
AU - Dodsworth, Steven
AU - Guignard, Maïté S.
AU - Pérez-Escobar, Oscar A.
AU - Struebig, Monika
AU - Chase, Mark W.
AU - Leitch, Andrew R.
N1 - Funding Information:
Acknowledgments: S.D. was funded by a NERC studentship.
Publisher Copyright:
© 2020 by the authors. Licensee MDPI, Basel, Switzerland.
PY - 2020/2/19
Y1 - 2020/2/19
N2 - Allopolyploidy is acknowledged as an important force in plant evolution. Frequent allopolyploidy in Nicotiana across different timescales permits the evaluation of genome restructuring and repeat dynamics through time. Here we use a clustering approach on high-throughput sequence reads to identify the main classes of repetitive elements following three allotetraploid events, and how these are inherited from the closest extant relatives of the maternal and paternal subgenome donors. In all three cases, there was a lack of clear maternal, cytoplasmic bias in repeat evolution, i.e., lack of a predicted bias towards maternal subgenome-derived repeats, with roughly equal contributions from both parental subgenomes. Different overall repeat dynamics were found across timescales of <0.5 (N. rustica L.), 4 (N. repanda Willd.) and 6 (N. benthamiana Domin) Ma, with nearly additive, genome upsizing, and genome downsizing, respectively. Lower copy repeats were inherited in similar abundance to the parental subgenomes, whereas higher copy repeats contributed the most to genome size change in N. repanda and N. benthamiana. Genome downsizing post-polyploidisation may be a general long-term trend across angiosperms, but at more recent timescales there is species-specific variance as found in Nicotiana.
AB - Allopolyploidy is acknowledged as an important force in plant evolution. Frequent allopolyploidy in Nicotiana across different timescales permits the evaluation of genome restructuring and repeat dynamics through time. Here we use a clustering approach on high-throughput sequence reads to identify the main classes of repetitive elements following three allotetraploid events, and how these are inherited from the closest extant relatives of the maternal and paternal subgenome donors. In all three cases, there was a lack of clear maternal, cytoplasmic bias in repeat evolution, i.e., lack of a predicted bias towards maternal subgenome-derived repeats, with roughly equal contributions from both parental subgenomes. Different overall repeat dynamics were found across timescales of <0.5 (N. rustica L.), 4 (N. repanda Willd.) and 6 (N. benthamiana Domin) Ma, with nearly additive, genome upsizing, and genome downsizing, respectively. Lower copy repeats were inherited in similar abundance to the parental subgenomes, whereas higher copy repeats contributed the most to genome size change in N. repanda and N. benthamiana. Genome downsizing post-polyploidisation may be a general long-term trend across angiosperms, but at more recent timescales there is species-specific variance as found in Nicotiana.
KW - allopolyploidisation
KW - diploidisation
KW - genome evolution
KW - genome reorganisation
KW - nuclear-cytoplasmic interaction hypothesis
KW - polyploidy
KW - repeats
KW - retroelements
KW - UKRI
KW - NERC
UR - http://www.scopus.com/inward/record.url?scp=85079716690&partnerID=8YFLogxK
UR - https://uobrep.openrepository.com/handle/10547/624002
U2 - 10.3390/genes11020216
DO - 10.3390/genes11020216
M3 - Article
C2 - 32092894
AN - SCOPUS:85079716690
SN - 2073-4425
VL - 11
JO - Genes
JF - Genes
IS - 2
M1 - 216
ER -