Kiyotaka Nagaki

Sequencing of a rice centromere uncovers active genes

Centromeres are the last frontiers of complex eukaryotic genomes, consisting of highly repetitive sequences that resist mapping, cloning and sequencing. The centromere of rice Chromosome 8 (Cen8) has an unusually low abundance of highly repetitive satellite DNA, which allowed us to determine its sequence. A region of ∼750 kb in Cen8 binds rice CENH3, the centromere-specific H3 histone. CENH3 binding is contained within a larger region that has abundant dimethylation of histone H3 at Lys9 (H3-Lys9), consistent with Cen8 being embedded in heterochromatin. Fourteen predicted and at least four active genes are interspersed in Cen8, along with CENH3 binding sites. The retrotransposons located in and outside of the CENH3 binding domain have similar ages and structural dynamics. These results suggest that Cen8 may represent an intermediate stage in the evolution of centromeres from genic regions, as in human neocentromeres, to fully mature centromeres that accumulate megabases of homogeneous satellite arrays.

Maize Centromeres: Organization and Functional Adaptation in the Genetic Background of Oat

Centromeric DNA sequences in multicellular eukaryotes are often highly repetitive and are not unique to a specific centromere or to centromeres at all. Thus, it is a major challenge to study the fine structure of individual plant centromeres. We used a DNA fiber-fluorescence in situ hybridization approach to study individual maize (Zea mays) centromeres using oat (Avena sativa)-maize chromosome addition lines. The maize centromere-specific satellite repeat CentC in the addition lines allowed us to delineate the size and organization of centromeric DNA of individual maize chromosomes. We demonstrate that the cores of maize centromeres contain mainly CentC arrays and clusters of a centromere-specific retrotransposon, CRM. CentC and CRM sequences are highly intermingled. The amount of CentC/CRM sequence varies from ∼300 to >2800 kb among different centromeres. The association of CentC and CRM with centromeric histone H3 (CENH3) was visualized by a sequential detection procedure on stretched centromeres. The analysis revealed that CENH3 is always associated with CentC and CRM but that not all CentC or CRM sequences are associated with CENH3. We further demonstrate that in the chromosomal addition lines in which two CenH3 genes were present, one from oat and one from maize, the oat CENH3 was consistently incorporated by the maize centromeres.

Transcription and histone modifications in the recombination-free region spanning a rice centromere.

Centromeres are sites of spindle attachment for chromosome segregation. During meiosis, recombination is absent at centromeres and surrounding regions. To understand the molecular basis for recombination suppression, we have comprehensively annotated the 3.5-Mb region that spans a fully sequenced rice centromere. Although transcriptional analysis showed that the 750-kb CENH3-containing core is relatively deficient in genes, the recombination-free region differs little in gene density from flanking regions that recombine. Likewise, the density of transposable elements is similar between the recombination-free region and flanking regions. We also measured levels of histone H4 acetylation and histone H3 methylation at 176 genes within the 3.5-Mb span. Active genes showed enrichment of H4 acetylation and H3K4 dimethylation as expected, including genes within the core. Our inability to detect sequence or histone modification features that distinguish recombination-free regions from flanking regions that recombine suggest that recombination suppression is an epigenetic feature of centromeres maintained by the assembly of CENH3-containing nucleosomes within the core. CENH3-containing centrochromatin does not appear to be distinguished by a unique combination of H3 and H4 modifications. Rather, the varied distribution of histone modifications might reflect the composition and abundance of sequence elements that inhabit centromeric DNA.

Visualization of Diffuse Centromeres with Centromere-Specific Histone H3 in the Holocentric Plant Luzula nivea

Although holocentric species are scattered throughout the plant and animal kingdoms, only holocentric chromosomes of the nematode worm Caenorhabditis elegans have been analyzed with centromeric protein markers. In an effort to determine the holocentric structure in plants, we investigated the snowy woodrush Luzula nivea. From the young roots, a cDNA encoding a putative centromere-specific histone H3 (LnCENH3) was successfully isolated based on sequence similarity among plant CENH3s. The deduced amino acid sequence was then used to raise an anti-LnCENH3 antibody. Immunostaining clearly revealed the diffuse centromere-like structure that appears in the linear shape at prophase to telophase. Furthermore, it was shown that the amount of LnCENH3 decreased significantly at interphase. The polar side positioning on each chromatid at metaphase to anaphase also confirmed that LnCENH3 represents one of the centromere-specific proteins in L. nivea. These data from L. nivea are compared with those from C. elegans, and common features of holocentric chromosomes are discussed.

CENH3 interacts with the centromeric retrotransposon cereba and GC-rich satellites and locates to centromeric substructures in barley.

The chromosomal location of centromere-specific histone H3 (CENH3) is the assembly site for the kinetochore complex of active centromeres. Chromatin immunoprecipitation data indicated that CENH3 interacts in barley with cereba, a centromeric retroelement (CR)-like element conserved among cereal centromeres and barley-specific GC-rich centromeric satellite sequences. Anti-CENH3 signals on extended chromatin fibers always colocalized with the centromeric sequences but did not encompass the entire area covered by such centromeric repeats. This indicates that the CENH3 protein is bound only to a fraction of the centromeric repeats. At mitotic metaphase, CENH3, histone H3, and serine 10 phosphorylated histone H3 predominated within distinct structural subdomains of the centromere, as demonstrated by immunogold labeling for high resolution scanning electron microscopy.

Characterization of CENH3 and centromere-associated DNA sequences in sugarcane

Centromere-specific histone H3 (CENH3) has been used to detect active centromeres, and to analyse the DNA sequences closely associated with the centromere, because they localize only in active centromeres and bind directly to the DNA. In maize and rice, the centromeric retrotransposons (CR) are shown to be closely associated with their own CENH3 whereas no such association was found in Arabidopsis thaliana. In this study, this sort of association was investigated in sugarcane. Two expressed sequence tag groups encoding putative sugarcane CENH3 (SoCENH3) were found in a sugarcane-expressed sequence tag database. Their deduced amino acid sequences were similar to these of the CENH3s in rice and maize. An antibody against rice CENH3 seemed to crossreact with the SoCENH3s, and stained sugarcane centromeres. A set of immunoprecipitation tests was conducted with the antibody and chromatin from the sugarcane genome to reveal CENH3-associated DNA sequences in sugarcane. Centromeric tandem repeats (SCEN) and centromeric retrotransposons of sugarcane (CRS) were significantly precipitated with the antibody, meaning these repeats are directly interacting with CENH3 in sugarcane centromeres.

Meiosis-specific loading of the centromere-specific histone CENH3 in Arabidopsis thaliana.

Centromere behavior is specialized in meiosis I, so that sister chromatids of homologous chromosomes are pulled toward the same side of the spindle (through kinetochore mono-orientation) and chromosome number is reduced. Factors required for mono-orientation have been identified in yeast. However, comparatively little is known about how meiotic centromere behavior is specialized in animals and plants that typically have large tandem repeat centromeres. Kinetochores are nucleated by the centromere-specific histone CENH3. Unlike conventional histone H3s, CENH3 is rapidly evolving, particularly in its N-terminal tail domain. Here we describe chimeric variants of CENH3 with alterations in the N-terminal tail that are specifically defective in meiosis. Arabidopsis thaliana cenh3 mutants expressing a GFP-tagged chimeric protein containing the H3 N-terminal tail and the CENH3 C-terminus (termed GFP-tailswap) are sterile because of random meiotic chromosome segregation. These defects result from the specific depletion of GFP-tailswap protein from meiotic kinetochores, which contrasts with its normal localization in mitotic cells. Loss of the GFP-tailswap CENH3 variant in meiosis affects recruitment of the essential kinetochore protein MIS12. Our findings suggest that CENH3 loading dynamics might be regulated differently in mitosis and meiosis. As further support for our hypothesis, we show that GFP-tailswap protein is recruited back to centromeres in a subset of pollen grains in GFP-tailswap once they resume haploid mitosis. Meiotic recruitment of the GFP-tailswap CENH3 variant is not restored by removal of the meiosis-specific cohesin subunit REC8. Our results reveal the existence of a specialized loading pathway for CENH3 during meiosis that is likely to involve the hypervariable N-terminal tail. Meiosis-specific CENH3 dynamics may play a role in modulating meiotic centromere behavior.

Holocentric Chromosomes of Luzula elegans Are Characterized by a Longitudinal Centromere Groove, Chromosome Bending, and a Terminal Nucleolus Organizer Region

The structure of holocentric chromosomes was analyzed in mitotic cells of Luzula elegans. Light and scanning electron microscopy observations provided evidence for the existence of a longitudinal groove along each sister chromatid. The centromere-specific histone H3 variant, CENH3, colocalized with this groove and with microtubule attachment sites. The terminal chromosomal regions were CENH3-negative. During metaphase to anaphase transition, L. elegans chromosomes typically curved to a sickle-like shape, a process that is likely to be influenced by the pulling forces of microtubules along the holocentric axis towards the corresponding microtubule organizing regions. A single pair of 45S rDNA sites, situated distal to Arabidopsis-telomere repeats, was observed at the terminal region of one chromosome pair. We suggest that the 45S rDNA position in distal centromere-free regions could be required to ensure chromosome stability.

A centromeric DNA sequence colocalized with a centromere-specific histone H3 in tobacco.

Centromeres play an important role in segregating chromosomes into daughter cells, and centromeric DNA assembles specific proteins to form a complex referred to as the kinetochore. Among these proteins, centromere-specific histone H3 (CENH3) is one of the most characterized and found to be located only on active centromeres. We isolated four different CENH3-coding complementary DNAs (cDNAs), two from Nicotiana tabaccum and one each from the ancestral diploid species, Nicotiana sylvestris and Nicotiana tomentosiformis and raised an antibody against N-terminal amino acid sequences deduced from the cDNAs. Immunostaining with the antibody revealed the preferential centromere localization, indicating that the cDNAs cloned in this study encode authentic tobacco CENH3. A tobacco centromeric DNA sequence (Nt2-7) was also identified by chromatin immunoprecipitation cloning using the antibody.

Functional centromeres in soybean include two distinct tandem repeats and a retrotransposon.

The centromere as a kinetochore assembly site is fundamental to the partitioning of genetic material during cell division. In order to determine the functional centromeres of soybean, we characterized the soybean centromere-specific histone H3 (GmCENH3) protein and developed an antibody against the N-terminal end. Using this antibody, we cloned centromere-associated DNA sequences by chromatin immunoprecipitation. Our analyses indicate that soybean centromeres are composed of two distinct satellite repeats (GmCent-1 and GmCent-4) and retrotransposon-related sequences (GmCR). The possible allopolyploid origin of the soybean genome is discussed in view of the centromeric satellite sequences present.