Martin Thompson

Polybromo-1: the chromatin targeting subunit of the PBAF complex

The human Polybromo-1 protein (Pb1) was recently identified as a unique subunit of the PBAF (Polybromo, Brg1-Associated Factors) chromatin-remodeling complex required for kinetochore localization during mitosis and the transcription of estrogen-responsive genes. Pb1 coordinates key features common to all remodeling complexes, including chromatin localization, recruitment of protein subunits and alteration of chromatin architecture. A comprehensive analysis of individual domains composing Pb1 is used to propose new information regarding the function of Pb1 in the PBAF chromatin-remodeling complex. The newly identified regulatory role of this important protein is also examined to explain both native function and the emerging role of Pb1 as a tumor suppressor found to be mutated in breast cancer.

HLS5, a Novel RBCC (Ring Finger, B Box, Coiled-coil) Family Member Isolated from a Hemopoietic Lineage Switch, Is a Candidate Tumor Suppressor

Hemopoietic cells, apparently committed to one lineage, can be reprogrammed to display the phenotype of another lineage. The J2E erythroleukemic cell line has on rare occasions developed the features of monocytic cells. Subtractive hybridization was used in an attempt to identify genes that were up-regulated during this erythroid to myeloid transition. We report here on the isolation of hemopoietic lineage switch 5 (Hls5), a gene expressed by the monocytoid variant cells, but not the parental J2E cells. Hls5 is a novel member of the RBCC (Ring finger, B box, coiled-coil) family of genes, which includes Pml, Herf1, Tif-1α, and Rfp. Hls5 was expressed in a wide range of adult tissues; however, at different stages during embryogenesis, Hls5 was detected in the branchial arches, spinal cord, dorsal root ganglia, limb buds, and brain. The protein was present in cytoplasmic granules and punctate nuclear bodies. Isolation of the human cDNA and genomic DNA revealed that the gene was located on chromosome 8p21, a region implicated in numerous leukemias and solid tumors. Enforced expression of Hls5 in HeLa cells inhibited cell growth, clonogenicity, and tumorigenicity. It is conceivable that HLS5 is one of the tumor suppressor genes thought to reside at the 8p21 locus.

Kinetic analysis of acetylation-dependent Pb1 bromodomain-histone interactions

Stopped-flow fluorescence anisotropy was used to determine the kinetic parameters that define acetylation-dependent bromodomain-histone interactions. Bromodomains are acetyllysine binding motifs found in many chromatin associated proteins. Individual bromodomains were derived from the polybromo-1 protein, which is a subunit of the PBAF chromatin-remodeling complex that has six tandem bromodomains in the amino-terminal region. The average k(on) and k(off) values for the formation of high-affinity complexes are 275 M(-1) s(-1) and 0.41 x 10(-3) s(-1), respectively. The average k(on) and k(off) values for the formation of low-affinity complexes are 119 M(-1) s(-1) and 1.42 x 10(-3) s(-1), respectively. Analysis of the on- and off-rates yields acetylation site-dependent equilibrium dissociation constants averaging 1.4 and 12.9 microM for high- and low-affinity complexes, respectively. This work represents the first examination of kinetic mechanisms of acetylation-dependent bromodomain-histone interactions.

Thermodynamic analysis of acetylation-dependent Pb1 bromodomain-histone H3 interactions.

An acetyl-histone peptide library was used to determine the thermodynamic parameters that define acetylation-dependent bromodomain-histone interactions. Bromodomains interact with histones by binding acetylated lysines. The bromodomain used in this study, BrD3, is derived from the polybromo-1 protein, which is a subunit of the PBAF chromatin remodeling complex. Steady-state fluorescence anisotropy was used to examine the variations in specificity and affinity that drive molecular recognition. Temperature and salt concentration dependence studies demonstrate that the hydrophobic effect is the primary driving force, consistent with lysine acetylation being required for binding. An electrostatic effect was observed in only two complexes where the acetyl-lysine was adjacent to an arginine. The large change in heat capacity determined for the specific complex suggests that the dehydrated BrD3-histone interface forms a tightly bound, high-affinity complex with the target site. These explorations into the thermodynamic driving forces that confer acetylation site-dependent BrD3-histone interactions improve our understanding of how individual bromodomains work in isolation. Furthermore, this work will permit the development of hypotheses regarding how the native Pb1, and the broader class of bromodomain proteins, directs multisubunit chromatin remodeling complexes to specific acetyl-nucleosome sites in vivo.

THERMODYNAMIC AND KINETIC ANALYSIS OF BROMODOMAIN-HISTONE INTERACTIONS

Multiple factors are involved when selecting a technique and designing experiments to investigate emerging questions in biochemistry. Success depends on a conceptual understanding of a given spectroscopic approach and the ability to design a system to optimize the quality of the acquired data. In this chapter, we discuss fluorescence anisotropy and its application in characterizing the factors that drive the acetylation-dependent interactions between histone and bromodomain proteins. The steady-state and pre-steady-state binding events associated with biomolecular assemblies can be quantified with this technique, so long as the proper assays and binding models are developed. To accomplish this, the continuum of experimental considerations from instrumental setup and choice of fluorophore, to experimental procedures, and data analysis is described. The methodology is discussed in sufficient detail such that this chapter is a complete guide to setting up and performing fluorescence anisotropy measurements to study biomolecular interactions. A thermodynamic and kinetic analysis is performed to determine the factors that drive molecular recognition and binding affinity, resulting in the identification of an induced-folding mechanism.

Heterologous expression of the human polybromo-1 protein in the methylotrophic yeast Pichia pastoris

The human polybromo-1 protein (BAF180) is a known driver mutation in clear cell renal cell carcinoma, where it is mutated in approximately 40% of cases. BAF180 is the chromatin-targeting subunit of the PBAF complex. BAF180 has six bromodomains, two BAH domains, and one HMG box. Bromodomains are known to recognize acetylated-lysines on histones and play a role in nucleosome recognition. BAH domains are required for ubiquitination of PCNA, a key regulator of DNA damage. The putative HMG box, if functional, may be involved in DNA-binding. While the binding specificities of individual bromodomains have been studied by our lab and others, the results have failed to reach a consensus. The acetyl-histone binding features of the full-length protein is unknown and is the motivation for this work. The hypothetical HMG and BAH domains have not been studied and the actual function of these regions is currently unknown. Thus, the precise interactions of this large and complex protein are not well-studied. Advances in understanding this large protein have been hindered by the inability to express and purify recombinant full-length BAF180 protein. Currently, only phenomenological studies using BAF180 expressed in mammalian cells have been conducted. Here, we report the successful expression, purification of full-length biologically active BAF180 protein using the GAP promoter in the heterologous host Pichia pastoris. The ability to express full-length and mutated BAF180 will allow for biophysical binding studies. Knowledge of the binding interactions is critical for us to understand the role of BAF180 in cancer development and its progression.

BAF180: Its Roles in DNA Repair and Consequences in Cancer

In 2011, Varela et al. reported that the PBRM1 gene is mutated in approximately 40% of clear cell renal cell carcinoma cases. Since then, the number of studies relating PBRM1 mutations to cancers has substantially increased. BAF180 has now been linked to more than 30 types of cancers, including ccRCC, cholangiocarcinomas, esophageal squamous cell carcinoma, bladder cancer, and breast cancer. The mutations associated with BAF180 are most often truncations, which result in a loss of protein expression. This loss has been shown to adversely affect the expression of genes, likely because BAF180 is the chromatin recognition subunit of PBAF. In addition, BAF180 functions in numerous DNA repair mechanisms. Its roles in mediating DNA repair are likely the mechanism by which BAF180 acts a tumor suppressor protein. As research on this protein gains more interest, scientists will begin to piece together the complicated puzzle of the BAF180 protein and why its loss often results in cancer.