De novo induction of a DNA-histone H3K9 methylation loop on synthetic human repetitive DNA in cultured tobacco cells

Genetic modifications in plants are crucial tools for fundamental and applied research. Transgene expression usually varies among independent lines or their progeny and is associated with the chromatin structure of the insertion site. Strategies based on understanding how to manipulate the epigenetic state of the inserted gene cassette would help to ensure transgene expression. Here, we report a strategy for chromatin manipulation by the artificial tethering of epigenetic effectors to a synthetic human centromeric repetitive DNA (alphoid DNA) platform in plant Bright-Yellow-2 (BY-2) culture cells. By tethering DNA-methyltransferase (Nicotiana tabacum DRM1), we effectively induced DNA methylation and histone methylation (H3K9me2) on the alphoid DNA platform. Tethering of the Arabidopsis SUVH9, which has been reported to lack histone methyltransferase activity, also induced a similar epigenetic state on the alphoid DNA in BY-2 cells, presumably by activating the RNA-dependent DNA methylation (RdDM) pathway. Our results emphasize that the interplay between DNA and histone methylation mechanisms is intrinsic to plant cells. We also found that once epigenetic modification states were induced by the tethering of either DRM1 or SUVH9, the modification was maintained even when the direct tethering of the effector was inhibited. Our system enables the analysis of more diverse epigenetic effectors and will help to elucidate the chromatin assembly mechanisms of plant cells.

CENP-B creates alternative epigenetic chromatin states permissive for CENP-A or heterochromatin assembly

CENP-B binds to CENP-B boxes on centromeric satellite DNAs (known as alphoid DNA in humans). CENP-B maintains kinetochore function through interactions with CENP-A nucleosomes and CENP-C. CENP-B binding to transfected alphoid DNA can induce de novo CENP-A assembly, functional centromere and kinetochore formation, and subsequent human artificial chromosome (HAC) formation. Furthermore, CENP-B also facilitates H3K9 (histone H3 lysine 9) trimethylation on alphoid DNA, mediated by Suv39h1, at ectopic alphoid DNA integration sites. Excessive heterochromatin invasion into centromere chromatin suppresses CENP-A assembly. It is unclear how CENP-B controls such different chromatin states. Here, we show that the CENP-B acidic domain recruits histone chaperones and many chromatin modifiers, including the H3K36 methylase ASH1L, as well as the heterochromatin components Suv39h1 and HP1 (HP1α, β and γ, also known as CBX5, CBX1 and CBX3, respectively). ASH1L facilitates the formation of open chromatin competent for CENP-A assembly on alphoid DNA. These results indicate that CENP-B is a nexus for histone modifiers that alternatively promote or suppress CENP-A assembly by mutually exclusive mechanisms. Besides the DNA-binding domain, the CENP-B acidic domain also facilitates CENP-A assembly de novo on transfected alphoid DNA. CENP-B therefore balances CENP-A assembly and heterochromatin formation on satellite DNA.

Human artificial chromosome: Chromatin assembly mechanisms and CENP-B

The centromere is a specialized chromosomal locus required for accurate chromosome segregation. Heterochromatin also assembles around centromere chromatin and forms a base that supports sister chromatid cohesion until anaphase begins. Both centromere chromatin and heterochromatin assemble on a centromeric DNA sequence, a highly repetitive sequence called alphoid DNA (α-satellite DNA) in humans. Alphoid DNA can form a de novo centromere and subsequent human artificial chromosome (HAC) when introduced into the human culture cells HT1080. HAC is maintained stably as a single chromosome independent of other human chromosomes. For de novo centromere assembly and HAC formation, the centromere protein CENP-B and its binding sites, CENP-B boxes, are required in the repeating units of alphoid DNA. CENP-B has multiple roles in de novo centromere chromatin assembly and stabilization and in heterochromatin formation upon alphoid DNA introduction into the cells. Here we review recent progress in human artificial chromosome construction and centromere/heterochromatin assembly and maintenance, focusing on the involvement of human centromere DNA and CENP-B protein.

KAT7/HBO1/MYST2 Regulates CENP-A Chromatin Assembly by Antagonizing Suv39h1-Mediated Centromere Inactivation

Centromere chromatin containing histone H3 variant CENP-A is required for accurate chromosome segregation as a foundation for kinetochore assembly. Human centromere chromatin assembles on a part of the long α-satellite (alphoid) DNA array, where it is flanked by pericentric heterochromatin. Heterochromatin spreads into adjacent chromatin and represses gene expression, and it can antagonize centromere function or CENP-A assembly. Here, we demonstrate an interaction between CENP-A assembly factor M18BP1 and acetyltransferase KAT7/HBO1/MYST2. Knocking out KAT7 in HeLa cells reduced centromeric CENP-A assembly. Mitotic chromosome misalignment and micronuclei formation increased in the knockout cells and were enhanced when the histone H3-K9 trimethylase Suv39h1 was overproduced. Tethering KAT7 to an ectopic alphoid DNA integration site removed heterochromatic H3K9me3 modification and was sufficient to stimulate new CENP-A or histone H3.3 assembly. Thus, KAT7-containing acetyltransferases associating with the Mis18 complex provides competence for histone turnover/exchange activity on alphoid DNA and prevents Suv39h1-mediated heterochromatin invasion into centromeres.

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The histone acetyltransferase KAT7 positively regulates centromeric CENP-A assembly

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Human Mis18 complex is a scaffold for assembly of KAT7 and HJURP, a CENP-A chaperone

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KAT7 or RSF1 stimulates histone turnover/exchange on alphoid DNA

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KAT7 antagonizes H3K9-trimethylase Suv39h1-mediated centromere inactivation

Human gamma-satellite DNA maintains open chromatin structure and protects a transgene from epigenetic silencing

The role of repetitive DNA sequences in pericentromeric regions with respect to kinetochore/heterochromatin structure and function is poorly understood. Here, we use a mouse erythroleukemia cell (MEL) system for studying how repetitive DNA assumes or is assembled into different chromatin structures. We show that human gamma-satellite DNA arrays allow a transcriptionally permissive chromatin conformation in an adjacent transgene and efficiently protect it from epigenetic silencing. These arrays contain CTCF and Ikaros binding sites. In MEL cells, this gamma-satellite DNA activity depends on binding of Ikaros proteins involved in differentiation along the hematopoietic pathway. Given our discovery of gamma-satellite DNA in pericentromeric regions of most human chromosomes and a dynamic chromatin state of gamma-satellite arrays in their natural location, we suggest that gamma-satellite DNA represents a unique region of the functional centromere with a possible role in preventing heterochromatin spreading beyond the pericentromeric region.

The microcephaly ASPM gene is expressed in proliferating tissues and encodes for a mitotic spindle protein

The most common cause of primary autosomal recessive microcephaly (MCPH) appears to be mutations in the ASPM gene which is involved in the regulation of neurogenesis. The predicted gene product contains two putative N-terminal calponin-homology (CH) domains and a block of putative calmodulin-binding IQ domains common in actin binding cytoskeletal and signaling proteins. Previous studies in mouse suggest that ASPM is preferentially expressed in the developing brain. Our analyses reveal that ASPM is widely expressed in fetal and adult tissues and upregulated in malignant cells. Several alternatively spliced variants encoding putative ASPM isoforms with different numbers of IQ motifs were identified. The major ASPM transcript contains 81 IQ domains, most of which are organized into a higher order repeat (HOR) structure. Another prominent spliced form contains an in-frame deletion of exon 18 and encodes 14 IQ domains not organized into a HOR. This variant is conserved in mouse. Other spliced variants lacking both CH domains and a part of the IQ motifs were also detected, suggesting the existence of isoforms with potentially different functions. To elucidate the biochemical function of human ASPM, we developed peptide specific antibodies to the N- and C-termini of ASPM. In a western analysis of proteins from cultured human and mouse cells, the antibodies detected bands with mobilities corresponding to the predicted ASPM isoforms. Immunostaining of cultured human cells with antibodies revealed that ASPM is localized in the spindle poles during mitosis. This finding suggests that MCPH is the consequence of an impairment in mitotic spindle regulation in cortical progenitors due to mutations in ASPM.

The role of CENP-B and alpha-satellite DNA: de novo assembly and epigenetic maintenance of human centromeres

The centromere is an essential functional domain responsible for the correct inheritance of eukaryotic chromosomes during cell division. Eukaryotic centromeres include the highly conserved centromere-specific histone H3 variant, CENP-A, which has provided a powerful tool for investigating the recruitment of centromere components. However, the trigger that targets CENP-A to a specific genomic locus during centromere assembly remains unknown. Although, on rare occasions, CENP-A chromatin may assemble at non-centromeric DNA, all normal human centromeres are assembled and maintained on alpha-satellite (alphoid) DNA. The importance of alphoid DNA and CENP-B binding sites (CENP-B boxes), typical of normal human centromere DNA configurations, has been demonstrated through their requirement in de novo centromere assembly and Human Artificial Chromosome (HAC) assays. Mechanisms to link the centromere tightly to specific genomic sequences exist in humans and the two yeast species.