Hi-C2B: Optimized Detection of Chromosomal Contacts Within Synchronized Meiotic S. cerevisiae Cells.

Hi-C, a genome-wide chromosome conformation capture assay, is a powerful tool used to study three-dimensional genome organization by converting physical pairwise interactions into counts of pairwise interactions. To study the many temporally regulated facets of meiotic recombination in S. cerevisiae, the Hi-C assay must be robust such that fine- and wide-scale comparisons between genetic datasets can be made.

Telomerase subunit Est2 marks internal sites that are prone to accumulate DNA damage.

Background: The main function of telomerase is at the telomeres but under adverse conditions telomerase can bind to internal regions causing deleterious effects as observed in cancer cells.

Results: By mapping the global occupancy of the catalytic subunit of telomerase (Est2) in the budding yeast Saccharomyces cerevisiae, we reveal that it binds to multiple guanine-rich genomic loci, which we termed "non-telomeric binding sites" (NTBS). We characterize Est2 binding to NTBS.

Convergent genes shape budding yeast pericentromeres.

The three-dimensional architecture of the genome governs its maintenance, expression and transmission. The cohesin protein complex organizes the genome by topologically linking distant loci, and is highly enriched in specialized chromosomal domains surrounding centromeres, called pericentromeres. Here we report the three-dimensional structure of pericentromeres in budding yeast (Saccharomyces cerevisiae) and establish the relationship between genome organization and function.

Principles of meiotic chromosome assembly revealed in S. cerevisiae.

During meiotic prophase, chromosomes organise into a series of chromatin loops emanating from a proteinaceous axis, but the mechanisms of assembly remain unclear. Here we use Saccharomyces cerevisiae to explore how this elaborate three-dimensional chromosome organisation is linked to genomic sequence. As cells enter meiosis, we observe that strong cohesin-dependent grid-like Hi-C interaction patterns emerge, reminiscent of mammalian interphase organisation, but with distinct regulation.

Preparation of Cell Cycle-Synchronized Saccharomyces cerevisiae Cells for Hi-C.

The chromosome organization activities of SMC complexes are crucial for correct gene expression and genetic inheritance in cells. Hi-C assays have revealed previously unsuspected levels of chromosome structure, with different types of chromosome structure facilitating function at different stages of the cell cycle. Elucidating how SMC complexes regulate these distinct types of organization is currently a key question in molecular biology.

Are SMC Complexes Loop Extruding Factors? Linking Theory With Fact.

The extreme length of chromosomal DNA requires organizing mechanisms to both promote functional genetic interactions and ensure faithful chromosome segregation when cells divide. Microscopy and genome-wide contact frequency analyses indicate that intra-chromosomal looping of DNA is a primary pathway of chromosomal organization during all stages of the cell cycle. DNA loop extrusion has emerged as a unifying model for how chromosome loops are formed in cis in different genomic contexts and cell cycle stages.

SMC complexes differentially compact mitotic chromosomes according to genomic context.

Structural maintenance of chromosomes (SMC) protein complexes are key determinants of chromosome conformation. Using Hi-C and polymer modelling, we study how cohesin and condensin, two deeply conserved SMC complexes, organize chromosomes in the budding yeast Saccharomyces cerevisiae. The canonical role of cohesin is to co-align sister chromatids, while condensin generally compacts mitotic chromosomes.

Fork rotation and DNA precatenation are restricted during DNA replication to prevent chromosomal instability.

Faithful genome duplication and inheritance require the complete resolution of all intertwines within the parental DNA duplex. This is achieved by topoisomerase action ahead of the replication fork or by fork rotation and subsequent resolution of the DNA precatenation formed. Although fork rotation predominates at replication termination, in vitro studies have suggested that it also occurs frequently during elongation.

A winged helix domain in human MUS81 binds DNA and modulates the endonuclease activity of MUS81 complexes.

The MUS81-EME1 endonuclease maintains metazoan genomic integrity by cleaving branched DNA structures that arise during the resolution of recombination intermediates. In humans, MUS81 also forms a poorly characterized complex with EME2. Here, we identify and determine the structure of a winged helix (WH) domain from human MUS81, which binds DNA.

Recombination-restarted replication makes inverted chromosome fusions at inverted repeats.

Impediments to DNA replication are known to induce gross chromosomal rearrangements (GCRs) and copy-number variations (CNVs). GCRs and CNVs underlie human genomic disorders and are a feature of cancer. During cancer development, environmental factors and oncogene-driven proliferation promote replication stress.