Repeated duplications and losses shaped SMC complex evolution from archaeal ancestors to modern eukaryotes

Jolien J E van Hooff; Maximilian W D Raas; Eelco C Tromer; Laura Eme

doi:10.1016/j.celrep.2025.115855

Repeated duplications and losses shaped SMC complex evolution from archaeal ancestors to modern eukaryotes

Jolien J E van Hooff^*, Maximilian W D Raas, Eelco C Tromer, Laura Eme^*

^*Corresponding author for this work

Research output: Contribution to journal › Article › Academic › peer-review

Abstract

Across life, structural maintenance of chromosomes (SMC) complexes organize chromosomes. While most prokaryotes have one, eukaryotes usually possess four (condensin I, condensin II, cohesin, and SMC5/6), shaping their considerably larger genomes. Although essential, SMC complexes differ among model eukaryotes, suggesting underexplored diversity. Here, we reconstruct eukaryotic SMC complex evolution, revealing that the last eukaryotic common ancestor (LECA) had all four complexes, supporting a sophisticated LECA. Subsequently, condensin II was lost at least 30 times, making it one of the most frequently lost eukaryotic machineries. Moreover, multiple SMC complex components are more ancient and widespread than previously appreciated. Tracing prokaryotic origins, we propose that the SMC complex was already duplicated in the Thaumarchaeota-Aigarchaeota-Crenarchaeota-Korarchaeota (TACK) and Asgard archaeal ancestor, suggesting sophisticated chromosome organization in eukaryotes' archaeal ancestor. Gene duplications further expanded the eukaryotic SMC complex inventory, highlighting their significance in establishing eukaryotic complexity. Altogether, our work suggests major shifts in genome organization throughout eukaryote history.

Original language	English
Article number	115855
Number of pages	20
Journal	Cell Reports
Volume	44
Issue number	7
Early online date	19 Jun 2025
DOIs	https://doi.org/10.1016/j.celrep.2025.115855
Publication status	E-pub ahead of print - 19 Jun 2025

Bibliographical note

Keywords

CP: Genomics
CP: Molecular biology
LECA
SMC5/6
chromatin
chromosome organization
cohesin
condensin
eukaryogenesis
evolutionary cell biology
genome organization
structural maintenance of chromosomes

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Repeated duplications and losses shaped SMC complex evolution from archaeal ancestors to modern eukaryotesFinal published version, 12.3 MBLicence: CC BY

Cite this

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title = "Repeated duplications and losses shaped SMC complex evolution from archaeal ancestors to modern eukaryotes",

abstract = "Across life, structural maintenance of chromosomes (SMC) complexes organize chromosomes. While most prokaryotes have one, eukaryotes usually possess four (condensin I, condensin II, cohesin, and SMC5/6), shaping their considerably larger genomes. Although essential, SMC complexes differ among model eukaryotes, suggesting underexplored diversity. Here, we reconstruct eukaryotic SMC complex evolution, revealing that the last eukaryotic common ancestor (LECA) had all four complexes, supporting a sophisticated LECA. Subsequently, condensin II was lost at least 30 times, making it one of the most frequently lost eukaryotic machineries. Moreover, multiple SMC complex components are more ancient and widespread than previously appreciated. Tracing prokaryotic origins, we propose that the SMC complex was already duplicated in the Thaumarchaeota-Aigarchaeota-Crenarchaeota-Korarchaeota (TACK) and Asgard archaeal ancestor, suggesting sophisticated chromosome organization in eukaryotes' archaeal ancestor. Gene duplications further expanded the eukaryotic SMC complex inventory, highlighting their significance in establishing eukaryotic complexity. Altogether, our work suggests major shifts in genome organization throughout eukaryote history.",

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T1 - Repeated duplications and losses shaped SMC complex evolution from archaeal ancestors to modern eukaryotes

AU - van Hooff, Jolien J E

AU - Raas, Maximilian W D

AU - Tromer, Eelco C

AU - Eme, Laura

PY - 2025/6/19

Y1 - 2025/6/19

N2 - Across life, structural maintenance of chromosomes (SMC) complexes organize chromosomes. While most prokaryotes have one, eukaryotes usually possess four (condensin I, condensin II, cohesin, and SMC5/6), shaping their considerably larger genomes. Although essential, SMC complexes differ among model eukaryotes, suggesting underexplored diversity. Here, we reconstruct eukaryotic SMC complex evolution, revealing that the last eukaryotic common ancestor (LECA) had all four complexes, supporting a sophisticated LECA. Subsequently, condensin II was lost at least 30 times, making it one of the most frequently lost eukaryotic machineries. Moreover, multiple SMC complex components are more ancient and widespread than previously appreciated. Tracing prokaryotic origins, we propose that the SMC complex was already duplicated in the Thaumarchaeota-Aigarchaeota-Crenarchaeota-Korarchaeota (TACK) and Asgard archaeal ancestor, suggesting sophisticated chromosome organization in eukaryotes' archaeal ancestor. Gene duplications further expanded the eukaryotic SMC complex inventory, highlighting their significance in establishing eukaryotic complexity. Altogether, our work suggests major shifts in genome organization throughout eukaryote history.

AB - Across life, structural maintenance of chromosomes (SMC) complexes organize chromosomes. While most prokaryotes have one, eukaryotes usually possess four (condensin I, condensin II, cohesin, and SMC5/6), shaping their considerably larger genomes. Although essential, SMC complexes differ among model eukaryotes, suggesting underexplored diversity. Here, we reconstruct eukaryotic SMC complex evolution, revealing that the last eukaryotic common ancestor (LECA) had all four complexes, supporting a sophisticated LECA. Subsequently, condensin II was lost at least 30 times, making it one of the most frequently lost eukaryotic machineries. Moreover, multiple SMC complex components are more ancient and widespread than previously appreciated. Tracing prokaryotic origins, we propose that the SMC complex was already duplicated in the Thaumarchaeota-Aigarchaeota-Crenarchaeota-Korarchaeota (TACK) and Asgard archaeal ancestor, suggesting sophisticated chromosome organization in eukaryotes' archaeal ancestor. Gene duplications further expanded the eukaryotic SMC complex inventory, highlighting their significance in establishing eukaryotic complexity. Altogether, our work suggests major shifts in genome organization throughout eukaryote history.

KW - CP: Genomics

KW - CP: Molecular biology

KW - LECA

KW - SMC5/6

KW - chromatin

KW - chromosome organization

KW - cohesin

KW - condensin

KW - eukaryogenesis

KW - evolutionary cell biology

KW - genome organization

KW - structural maintenance of chromosomes

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DO - 10.1016/j.celrep.2025.115855

M3 - Article

C2 - 40540396

SN - 2211-1247

VL - 44

JO - Cell Reports

JF - Cell Reports

IS - 7

M1 - 115855

ER -

Repeated duplications and losses shaped SMC complex evolution from archaeal ancestors to modern eukaryotes

Abstract

Bibliographical note

Keywords

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