Colin J. Fuller

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. Here we generate synthetic CENP-A chromatin that recapitulates essential steps of centromere and kinetochore assembly in vitro. We show that reconstituted CENP-A chromatin when added to cell-free extracts is sufficient for the assembly of centromere and kinetochore proteins, microtubule binding and stabilization, and mitotic checkpoint function. Using chromatin assembled from histone H3/CENP-A chimaeras, we demonstrate that the conserved carboxy terminus of CENP-A is necessary and sufficient for centromere and kinetochore protein recruitment and function but that the CENP-A targeting domain—required for new CENP-A histone assembly—is not. These data show that two of the primary requirements for accurate chromosome segregation, the assembly of the kinetochore and the propagation of CENP-A chromatin, are specified by different elements in the CENP-A histone. Our unique cell-free system enables complete control and manipulation of the chromatin substrate and thus presents a powerful tool to study centromere and kinetochore assembly.

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

CENP-C provides a link between existing CENP-A chromatin and the proteins required for new CENP-A nucleosome assembly.

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

Studying CENP-A nucleosome assembly in a cell-free system defines the role of existing CENP-A nucleosomes in centromere maintenance.

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. This cell-free system lends itself to use in protein immunodepletion, complementation and drug inhibition as a tool to perturb centromere and kinetochore assembly, cytoskeletal dynamics, DNA modification and protein post-translational modification. This system provides a distinct advantage over cell-based investigations in which perturbing centromere and kinetochore function often results in lethality. After incubation in egg extract, reconstituted CENP-A chromatin specifically assembles centromere and kinetochore proteins, which locally stabilize microtubules and, on microtubule depolymerization with nocodazole, activate the mitotic checkpoint. A typical experiment takes 3 d.

Image analysis benchmarking methods for high‐content screen design

The recent development of complex chemical and small interfering RNA (siRNA) collections has enabled large‐scale cell‐based phenotypic screening. High‐content and high‐throughput imaging are widely used methods to record phenotypic data after chemical and small interfering RNA treatment, and numerous image processing and analysis methods have been used to quantify these phenotypes. Currently, there are no standardized methods for evaluating the effectiveness of new and existing image processing and analysis tools for an arbitrary screening problem. We generated a series of benchmarking images that represent commonly encountered variation in high‐throughput screening data and used these image standards to evaluate the robustness of five different image analysis methods to changes in signal‐to‐noise ratio, focal plane, cell density and phenotype strength. The analysis methods that were most reliable, in the presence of experimental variation, required few cells to accurately distinguish phenotypic changes between control and experimental data sets. We conclude that by applying these simple benchmarking principles an a priori estimate of the image acquisition requirements for phenotypic analysis can be made before initiating an image‐based screen. Application of this benchmarking methodology provides a mechanism to significantly reduce data acquisition and analysis burdens and to improve data quality and information content.

Imaging nanometre-scale structure in cells using in situ aberration correction

Accurate distance measurements of cellular structures on a length scale relevant to single macromolecules or macromolecular complexes present a major challenge for biological microscopy. In addition to the inherent challenges of overcoming the limits imposed by the diffraction of light, cells themselves are a complex and poorly understood optical environment. We present an extension of the high‐resolution colocalization method to measure three dimensional distances between diffraction‐limited objects using standard widefield fluorescence microscopy. We use this method to demonstrate that in three dimensions, cells intrinsically introduce a large and variable amount of chromatic aberration into optical measurements. We present a means of correcting this aberration in situ [termed ‘Colocalization and In‐situ Correction of Aberration for Distance Analysis’ (CICADA)] by exploiting the fact that there is a linear relationship between the degree of aberration between different wavelengths. By labelling a cellular structure with redundantly multi‐colour labelled antibodies, we can create an intracellular fiducial marker for correcting the individual aberrations between two different wavelengths in the same cells. Our observations demonstrate that with suitable corrections, nanometre scale three‐dimensional distance measurements can be used to probe the substructure of macromolecular complexes within cells.

Intramolecular dynamics of single molecules in free diffusion

Biomolecular systems such as multiprotein complexes or biopolymers can span several tens to several hundreds of nanometers, but the dynamics of such “mesocale” molecules remain challenging to probe. We have developed a single-molecule technique that uses Tracking Fluorescence Correlation Spectroscopy (tFCS) to measure the conformation and dynamics of molecular assemblies specifically at the mesoscale level (~100-1000 nm). tFCS is non-perturbative, as molecules, which are tracked in real-time, are untethered and freely diffusing. To achieve sub-diffraction spatial resolution, we use a feedback scheme which allows us to maintain the molecule at an optimal position within the laser intensity gradient. We find that tFCS is sufficiently sensitive to measure the distance fluctuations between two sites within a DNA molecule separated by distances as short as 1000 bp. We demonstrate that tFCS detects changes in the compaction of reconstituted chromatin, and can assay transient protein mediated interactions between distant sites in an individual DNA molecule. Our measurements highlight the impact that tFCS can have in the study of a wide variety of biochemical processes involving mesoscale conformational dynamics.

Exploring Chromatin Biochemistry with Single-Molecule Fluorescence Diffusometry

We utilize real-time feedback to track individual dye-labeled chromatin fibers undergoing Brownian motion in aqueous buffer, enabling simultaneous recording of fluorescence and hydrodynamic data, providing new insight into conformational dynamics and self-association of nucleosome arrays.