The unique centromeric chromatin structure of Schizosaccharomyces pombe is maintained during meiosis

Construction and characterization of centromeric plasmids for Komagataella phaffii using a color-based plasmid stability assay

The yeast Komagataella phaffii is widely used as a microbial host for heterologous protein production. However, molecular tools for this yeast are basically restricted to a few integrative and replicative plasmids. Four sequences that have recently been proposed as the K. phaffii centromeres could be used to develop a new class of mitotically stable vectors. In this work, we designed a color-based genetic assay to investigate plasmid stability in K. phaffii and constructed vectors bearing K. phaffii centromeres and the ADE3 marker. These genetic tools were evaluated in terms of mitotic stability by transforming an ade2/ade3 auxotrophic strain and regarding plasmid copy number by quantitative PCR (qPCR). Our results confirmed that the centromeric plasmids were maintained at low copy numbers as a result of typical chromosome-like segregation during cell division. These features, combined with in vivo assembly possibilities, prompt these plasmids as a new addition to the K. phaffii genetic toolbox.

Combinatorial, site-specific requirement for heterochromatic silencing factors in the elimination of nucleosome-free regions

High-resolution nucleosome occupancy maps of heterochromatic regions of wild-type and silencing-defective mutants of the fission yeast Schizosaccharomyces pombe revealed that heterochromatin induces the elimination of nucleosome-free regions (NFRs). NFRs associated with transcription initiation sites as well as those not associated with promoters are affected. We dissected the roles of the histone H3K9 methyltransferase Clr4 and the HP1 proteins Swi6 and Chp2, as well as the two catalytic activities of the SHREC histone deacetylase (HDAC)/ATPase effector complex. Strikingly, different DNA sites have distinct combinatorial requirements for these factors: Five classes of NFRs were identified that are eliminated by silencing factors through a mechanistic hierarchy governed by Clr4. The SHREC HDAC activity plays a major role in the elimination of class I-IV NFRs by antagonizing the action of RSC, a remodeling complex implicated in NFR formation. We propose that heterochromatin formation involves the deployment in several sequence-specific mechanisms to eliminate gaps between nucleosomes, thereby blocking access to the DNA.

A role for recombination in centromere function

Centromeres are essential for chromosome segregation during both mitosis and meiosis. There are no obvious or conserved DNA sequence motif determinants for centromere function, but the complex centromeres found in the majority of eukaryotes studied to date consist of repetitive DNA sequences. A striking feature of these repeats is that they maintain a high level of inter-repeat sequence identity within the centromere. This observation is suggestive of a recombination mechanism that operates at centromeres. Here we postulate that inter-repeat homologous recombination plays an intrinsic role in centromere function by forming covalently closed DNA loops. Moreover, the model provides an explanation of why both inverted and direct repeats are maintained and how they contribute to centromere function.

A high-resolution map of nucleosome positioning on a fission yeast centromere

A key element for defining the centromere identity is the incorporation of a specific histone H3, CENPA, known as Cnp1p in Schizosaccharomyces pombe. Previous studies have suggested that functional S. pombe centromeres lack regularly positioned nucleosomes and may involve chromatin remodeling as a key step of kinetochore assembly. We used tiling microarrays to show that nucleosomes are, in fact, positioned in regular intervals in the core of centromere 2, providing the first high-resolution map of regional centromere chromatin. Nucleosome locations are not disrupted by mutations in kinetochore protein genes cnp1, mis18, mis12, nuf2, mal2; overexpression of cnp1; or the deletion of ams2, which encodes a GATA-like factor participating in CENPA incorporation. Bioinformatics analysis of the centromere sequence indicates certain enriched motifs in linker regions between nucleosomes and reveals a sequence bias in nucleosome positioning. In addition, sequence analysis of nucleosome-free regions identifies novel binding sites of Ams2p. We conclude that centromeric nucleosome positions are stable and may be derived from the underlying DNA sequence.