Limits to the cellular control of sequestered cryptophyte prey in the marine ciliate Mesodinium rubrum: [incl. correction]
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Limits to the cellular control of sequestered cryptophyte prey in the marine ciliate Mesodinium rubrum : [incl. correction]. / Altenburger, Andreas; Cai, Huimin; Li, Qiye; Drumm, Kirstine; Kim, Miran; Zhu, Yuanzhen; Garcia-Cuetos, Lydia; Zhan, Xiaoyu; Hansen, Per Juel; John, Uwe; Li, Shuaicheng; Lundholm, Nina.
In: The ISME Journal, Vol. 15, No. 4, 2021, p. 1056-1072.Research output: Contribution to journal › Journal article › Research › peer-review
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TY - JOUR
T1 - Limits to the cellular control of sequestered cryptophyte prey in the marine ciliate Mesodinium rubrum
T2 - [incl. correction]
AU - Altenburger, Andreas
AU - Cai, Huimin
AU - Li, Qiye
AU - Drumm, Kirstine
AU - Kim, Miran
AU - Zhu, Yuanzhen
AU - Garcia-Cuetos, Lydia
AU - Zhan, Xiaoyu
AU - Hansen, Per Juel
AU - John, Uwe
AU - Li, Shuaicheng
AU - Lundholm, Nina
N1 - Correction: Limits to the cellular control of sequestered cryptophyte prey in the marine ciliate Mesodinium rubrum DOI: 10.1038/s41396-021-01115-5
PY - 2021
Y1 - 2021
N2 - The marine ciliate Mesodinium rubrum is famous for its ability to acquire and exploit chloroplasts and other cell organelles from some cryptophyte algal species. We sequenced genomes and transcriptomes of free-swimming Teleaulax amphioxeia, as well as well-fed and starved M. rubrum in order to understand cellular processes upon sequestration under different prey and light conditions. From its prey, the ciliate acquires the ability to photosynthesize as well as the potential to metabolize several essential compounds including lysine, glycan, and vitamins that elucidate its specific prey dependency. M. rubrum does not express photosynthesis-related genes itself, but elicits considerable transcriptional control of the acquired cryptophyte organelles. This control is limited as light-dependent transcriptional changes found in free-swimming T. amphioxeia got lost after sequestration. We found strong transcriptional rewiring of the cryptophyte nucleus upon sequestration, where 35% of the T. amphioxeia genes were significantly differentially expressed within well-fed M. rubrum. Qualitatively, 68% of all genes expressed within well-fed M. rubrum originated from T. amphioxeia. Quantitatively, these genes contributed up to 48% to the global transcriptome in well-fed M. rubrum and down to 11% in starved M. rubrum. This tertiary endosymbiosis system functions for several weeks, when deprived of prey. After this point in time, the ciliate dies if not supplied with fresh prey cells. M. rubrum represents one evolutionary way of acquiring photosystems from its algal prey,and might represent a step on the evolutionary way towards a permanent tertiary endosymbiosis.
AB - The marine ciliate Mesodinium rubrum is famous for its ability to acquire and exploit chloroplasts and other cell organelles from some cryptophyte algal species. We sequenced genomes and transcriptomes of free-swimming Teleaulax amphioxeia, as well as well-fed and starved M. rubrum in order to understand cellular processes upon sequestration under different prey and light conditions. From its prey, the ciliate acquires the ability to photosynthesize as well as the potential to metabolize several essential compounds including lysine, glycan, and vitamins that elucidate its specific prey dependency. M. rubrum does not express photosynthesis-related genes itself, but elicits considerable transcriptional control of the acquired cryptophyte organelles. This control is limited as light-dependent transcriptional changes found in free-swimming T. amphioxeia got lost after sequestration. We found strong transcriptional rewiring of the cryptophyte nucleus upon sequestration, where 35% of the T. amphioxeia genes were significantly differentially expressed within well-fed M. rubrum. Qualitatively, 68% of all genes expressed within well-fed M. rubrum originated from T. amphioxeia. Quantitatively, these genes contributed up to 48% to the global transcriptome in well-fed M. rubrum and down to 11% in starved M. rubrum. This tertiary endosymbiosis system functions for several weeks, when deprived of prey. After this point in time, the ciliate dies if not supplied with fresh prey cells. M. rubrum represents one evolutionary way of acquiring photosystems from its algal prey,and might represent a step on the evolutionary way towards a permanent tertiary endosymbiosis.
UR - https://doi.org/10.1038/s41396-021-01115-5
U2 - 10.1038/s41396-020-00830-9
DO - 10.1038/s41396-020-00830-9
M3 - Journal article
C2 - 33230263
VL - 15
SP - 1056
EP - 1072
JO - I S M E Journal
JF - I S M E Journal
SN - 1751-7362
IS - 4
ER -
ID: 251949752