Morphological map of under- and overexpression of genes in human cells.

Cell Painting images offer valuable insights into a cell's state and enable many biological applications, but publicly available arrayed datasets only include hundreds of genes perturbed. The JUMP Cell Painting Consortium perturbed roughly 75% of the protein-coding genome in human U-2 OS cells, generating a rich resource of single-cell images and extracted features. These profiles capture the phenotypic impacts of perturbing 15,243 human genes, including overexpressing 12,609 genes (using open reading frames) and knocking out 7,975 genes (using CRISPR-Cas9).

Measurement of Mesoscale Conformational Dynamics of Freely Diffusing Molecules with Tracking FCS.

Few techniques are suited to probe the structure and dynamics of molecular complexes at the mesoscale level (∼100-1000 nm). We have developed a single-molecule technique that uses tracking fluorescence correlation spectroscopy (tFCS) to probe the conformation and dynamics of mesoscale molecular assemblies. tFCS measures the distance fluctuations between two fluorescently labeled sites within an untethered, freely diffusing biomolecule.

A cell-free CENP-A assembly system defines the chromatin requirements for centromere maintenance.

Centromeres are defined by the presence of CENP-A nucleosomes in chromatin and are essential for accurate chromosome segregation. Centromeric chromatin epigenetically seeds new CENP-A nucleosome formation, thereby maintaining functional centromeres as cells divide. The features within centromeric chromatin that direct new CENP-A assembly remain unclear.

CENP-A confers a reduction in height on octameric nucleosomes.

Nucleosomes with histone H3 replaced by CENP-A direct kinetochore assembly. CENP-A nucleosomes from human and Drosophila have been reported to have reduced heights as compared to canonical octameric H3 nucleosomes, thus suggesting a unique tetrameric hemisomal composition. We demonstrate that octameric CENP-A nucleosomes assembled in vitro exhibit reduced heights, indicating that they are physically distinct from H3 nucleosomes and negating the need to invoke the presence of hemisomes.

A cell-free system for functional centromere and kinetochore assembly.

This protocol describes a cell-free system for studying vertebrate centromere and kinetochore formation. We reconstitute tandem arrays of centromere protein A (CENP-A) nucleosomes as a substrate for centromere and kinetochore assembly. These chromatin substrates are immobilized on magnetic beads and then incubated in Xenopus egg extracts that provide a source for centromere and kinetochore proteins and that can be cycled between mitotic and interphase cell cycle states.

CENP-C recruits M18BP1 to centromeres to promote CENP-A chromatin assembly.

Eukaryotic chromosomes segregate by attaching to microtubules of the mitotic spindle through a chromosomal microtubule binding site called the kinetochore. Kinetochores assemble on a specialized chromosomal locus termed the centromere, which is characterized by the replacement of histone H3 in centromeric nucleosomes with the essential histone H3 variant CENP-A (centromere protein A). Understanding how CENP-A chromatin is assembled and maintained is central to understanding chromosome segregation mechanisms.

In vitro centromere and kinetochore assembly on defined chromatin templates.

During cell division, chromosomes are segregated to nascent daughter cells by attaching to the microtubules of the mitotic spindle through the kinetochore. Kinetochores are assembled on a specialized chromatin domain called the centromere, which is characterized by the replacement of nucleosomal histone H3 with the histone H3 variant centromere protein A (CENP-A). CENP-A is essential for centromere and kinetochore formation in all eukaryotes but it is unknown how CENP-A chromatin directs centromere and kinetochore assembly.

Local geometry and elasticity in compact chromatin structure.

The hierarchical packaging of DNA into chromatin within a eukaryotic nucleus plays a pivotal role in both the accessibility of genomic information and the dynamics of replication. Our work addresses the role of nanoscale physical and geometric properties in determining the structure of chromatin at the mesoscale level. We study the packaging of DNA in chromatin fibers by optimization of regular helical morphologies, considering the elasticity of the linker DNA as well as steric packing of the nucleosomes and linkers.