The Arabidopsis condensin CAP‐D subunits arrange interphase chromatin

Municio, Celia; Antosz, Wojciech; Grasser, Klaus D.; Kornobis, Étienne; Bel, Michiel Van; Eguinoa, Ignacio; Coppens, Frederik; Bräutigam, Andrea; Lermontová, Inna; Bruckmann, Astrid; Zelkowska, Katarzyna; Houben, Andreas; Schubert, Veit

doi:10.1111/nph.17221

Cited by 11 publications

(10 citation statements)

References 105 publications

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“…Paulson and Laemmli (1977) suggested a 'scaffold model' based on histone-depleted human chromosomes with a non-histone protein backbone responsible for chromatin looping and chromosome condensation. Topoisomerase IIα and the Structural Maintenance of Chromosomes (SMC) complexes condensin I and II are components of the scaffold in Drosophila (Sureka et al, 2018), chicken (Ohta et al, 2019) and human (Maeshima and Laemmli, 2003;Fukui and Uchiyama 2007;Maeshima et al, 2018;Walther et al, 2018), and are also evident in Arabidopsis and barley (Kubalová et al, 2021;Municio et al, 2021). In human HeLa cells the chromatid axes appear as isolated compaction centers rather than forming a continuous scaffold (Sun et al 2018), and appear to consist of a helical structure that serves to organize chromatin loops into the metaphase chromatid (Phengchat et al, 2019).…”

Section: Discussionmentioning

confidence: 99%

Helical metaphase chromatid coiling is conserved

Kubalová

Câmara

Cápal

et al. 2021

Preprint

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The higher-order metaphase chromosome organization has been under controversial discussion already for 140 years. Classical light and electron microscopy proposed chromatids to be composed of helically organized chromatin fibers, so-called chromonemata. More recently also non-helical models were suggested. We studied the chromosome organization in barley by interdisciplinary cutting-edge approaches, such as chromosome sorting, chromosome conformation capture, oligonucleotide-fluorescence in situ hybridization, base analog incorporation, super-resolution microscopy, and polymer simulation to elucidate the arrangement of chromatids of large mitotic metaphase chromosomes. Our data provide cumulative evidence for the presence of a helically arranged 400 nm chromatin fiber representing the chromonema within the chromatid arms. The number of turns is positively correlated with the arm length. Turn size and chromatin density decrease towards the telomeres. Due to the specialized functions of centromeres and nucleolus-organizing regions, the helical organization is interrupted at these regions, which display several thinners and straight chromatin fibers. Based on our findings and re-analyzing previously published data from other plant and non-plant species we conclude that the helical turning of metaphase chromatid arms is a conserved feature of large eukaryotic chromosomes.

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Section: Discussionmentioning

confidence: 99%

Helical metaphase chromatid coiling is conserved

Kubalová

Câmara

Cápal

et al. 2021

Preprint

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“…Results indicated disassociation of the rDNA arrays from the centromeres, thus suggesting that direct binding of condensin II to rDNA array regions is necessary for their association with centromeres in A. thaliana (Sakamoto et al, 2019). However, cytological analysis of Arabidopsis cap-d3 interphase nuclei indicated specific clustering of 45 rDNA sites, so CAP-D3 might localize in euchromatic loops and somehow determine the rigidity needed to maintain separation of chromocenters (Municio et al, 2021) In any case, an analysis of 3D chromatin organization by Hi-C may help clarify the distribution pattern of condensin II during interphase and its role in the clustering of rDNA arrays during interphase (Sakamoto et al, 2019). Evidence also indicates that SMC4/condensin is required for repression of a wide range of methylated genes subject to conditional expression (Wang et al, 2017).…”

Section: Engineering Systems Redundancy: Complementary Roles Of Cohesmentioning

confidence: 98%

“…Eukaryotes have three sets of canonical SMC protein complexes (Municio et al, 2021): (1) the cohesin complex composed of the core proteins SMC1 and SMC3, mentioned previously, mostly involved in sister chromatid cohesion; (2) the SMC5/SCM6 complex, which is mostly linked to DNA repair and recombination; and (3) the condensin complex, which is composed of core units SMC2 and SMC4 and is required for chromosome condensation and segregation (Sakamoto et al, 2019).…”

Section: Engineering Systems Redundancy: Complementary Roles Of Cohesmentioning

confidence: 99%

“…The plant condensin complex I consists of core units SMC2/SMC4, γ-kleisin (CAP)-H, β-kleisin (CAP)-H2, and HEAT repeat-containing proteins CAP-G and CAP-D2. However, the association of SMC2/SMC4 with CAP-H2 (β-kleisin), CAP-G2, and CAP-D3 form condensin II (Sakamoto et al, 2019;Municio et al, 2021), a complex that may be required for tolerance to DSBs caused by the radiomimetic agent zeocin for tolerance to boron (Sakamoto et al, 2011; see Figure 5). In Arabidopsis, defects in the function of SMC2 (2 genes) or SMC4 (3 genes) affect segregation of mitotic and meiotic chromosomes (Sakamoto et al, 2019).…”

Section: Engineering Systems Redundancy: Complementary Roles Of Cohesmentioning

confidence: 99%

“…The Arabidopsis condensin II complex is also required for genome integrity and for pollen and embryo development (Schubert et al, 2013;Sakamoto et al, 2019;Municio et al, 2021). A combined spatial analysis of the localization of the 180-bp centromeric repeat and the 5S and 45S rDNA probes was performed in the Arabidopsis cap-h2-2, cap-g2-1, and cap-d3-1 mutants (see Figure 5).…”

Section: Engineering Systems Redundancy: Complementary Roles Of Cohesmentioning

confidence: 99%

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The Role of Structural Maintenance of Chromosomes Complexes in Meiosis and Genome Maintenance: Translating Biomedical and Model Plant Research Into Crop Breeding Opportunities

Bolaños-Villegas

2021

Front. Plant Sci.

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Cohesin is a multi-unit protein complex from the structural maintenance of chromosomes (SMC) family, required for holding sister chromatids together during mitosis and meiosis. In yeast, the cohesin complex entraps sister DNAs within tripartite rings created by pairwise interactions between the central ring units SMC1 and SMC3 and subunits such as the α-kleisin SCC1 (REC8/SYN1 in meiosis). The complex is an indispensable regulator of meiotic recombination in eukaryotes. In Arabidopsis and maize, the SMC1/SMC3 heterodimer is a key determinant of meiosis. In Arabidopsis, several kleisin proteins are also essential: SYN1/REC8 is meiosis-specific and is essential for double-strand break repair, whereas AtSCC2 is a subunit of the cohesin SCC2/SCC4 loading complex that is important for synapsis and segregation. Other important meiotic subunits are the cohesin EXTRA SPINDLE POLES (AESP1) separase, the acetylase ESTABLISHMENT OF COHESION 1/CHROMOSOME TRANSMISSION FIDELITY 7 (ECO1/CTF7), the cohesion release factor WINGS APART-LIKE PROTEIN 1 (WAPL) in Arabidopsis (AtWAPL1/AtWAPL2), and the WAPL antagonist AtSWITCH1/DYAD (AtSWI1). Other important complexes are the SMC5/SMC6 complex, which is required for homologous DNA recombination during the S-phase and for proper meiotic synapsis, and the condensin complexes, featuring SMC2/SMC4 that regulate proper clustering of rDNA arrays during interphase. Meiotic recombination is the key to enrich desirable traits in commercial plant breeding. In this review, I highlight critical advances in understanding plant chromatid cohesion in the model plant Arabidopsis and crop plants and suggest how manipulation of crossover formation during meiosis, somatic DNA repair and chromosome folding may facilitate transmission of desirable alleles, tolerance to radiation, and enhanced transcription of alleles that regulate sexual development. I hope that these findings highlight opportunities for crop breeding.

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Super-resolution microscopy reveals the number and distribution of topoisomerase IIα and CENH3 molecules within barley metaphase chromosomes

et al. 2023

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Topoisomerase IIα (Topo IIα) and the centromere-specific histone H3 variant CENH3 are key proteins involved in chromatin condensation and centromere determination, respectively. Consequently, they are required for proper chromosome segregation during cell divisions. We combined two super-resolution techniques, structured illumination microscopy (SIM) to co-localize Topo IIα and CENH3, and photoactivated localization microscopy (PALM) to determine their molecule numbers in barley metaphase chromosomes. We detected a dispersed Topo IIα distribution along chromosome arms but an accumulation at centromeres, telomeres, and nucleolus-organizing regions. With a precision of 10-50 nm, we counted ~ 20,000-40,000 Topo IIα molecules per chromosome, 28% of them within the (peri)centromere. With similar precision, we identified ~13,500 CENH3 molecules per centromere where Topo IIα proteins and CENH3-containing chromatin intermingle. In short, we demonstrate PALM as a useful method to count and localize single molecules with high precision within chromosomes. The ultrastructural distribution and the detected amount of Topo IIα and CENH3 are instrumental for a better understanding of their functions during chromatin condensation and centromere determination.

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The Arabidopsis condensin CAP‐D subunits arrange interphase chromatin

Cited by 11 publications

References 105 publications

Helical metaphase chromatid coiling is conserved

Helical metaphase chromatid coiling is conserved

The Role of Structural Maintenance of Chromosomes Complexes in Meiosis and Genome Maintenance: Translating Biomedical and Model Plant Research Into Crop Breeding Opportunities

Super-resolution microscopy reveals the number and distribution of topoisomerase IIα and CENH3 molecules within barley metaphase chromosomes

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