FACT facilitates transcription-dependent nucleosome alteration

Identification and molecular cloning of Tetrahymena 138-kDa protein, a transcription elongation factor homologue that interacts with microtubules in vitro

Macronucleus of Tetrahymena divides amitotically, although in a microtubule-dependent fashion. Besides the localization study and pharmacological study of macronuclear microtubules, mechanism of the macronuclear division is poorly understood. A biochemical search for microtubule-associated protein was attempted from the isolated macronucleus. Improvement on macronucleus isolation method and microtubule coprecipitation assay led to the cloning of p138, a new homologue of transcription elongation factor FACT (facilitates chromatin transcription) 140kDa subunit. DNase treatment test of macronuclear extract and the sequence of p138 suggested that p138 is associated with chromosome in the macronucleus. The release tests of p138 from microtubules indicated that p138 is released from microtubules in the presence of ATP but not in the presence of AMP-PNP. Together, the results suggest a novel function of FACT homologue, that p138 interacts with both microtubules and chromosome.

Facts about FACT and transcript elongation through chromatin

The regulation of transcription elongation within the context of chromatin is a topic of great interest. Even though chromatin presents a barrier to transcription by the PolII machinery in vitro, this process is rather efficient in vivo. Importantly, the chromatin structure of the actively transcribed genes is altered as part of this process. A large number of factors implicated in the control of transcript elongation have been identified through genetics, biochemistry and targeted proteomics approaches. However the precise roles and mechanisms of action of these factors remain obscure. A significant advance came about this past year with the elucidation of the roles of FACT and Spt6 in transcription elongation. These factors facilitate PolII passage through chromatin by destabilizing the nucleosome structure as well as reassemble nucleosomes traversed by PolII.

SWRred Not Shaken

The recently isolated SWR1 complex catalyzes an ATP-dependent histone exchange with specificity for the histone variant H2A.Z. This provides a new theme in chromatin remodeling mechanisms and an explanation of how histone variants are incorporated into the nucleosome outside of S phase. In connection with the isolation of histone variant specific chaperone complexes, we are beginning to see the mechanisms that mix the histone octamer with intriguing implications for epigenetic inheritance.

Transcription through chromatin: understanding a complex FACT

In eukaryotic cells, genomic DNA is assembled with chromosomal proteins, mainly histones, in a highly compact structure termed chromatin. In this form, DNA is not readily accessible to the cellular machineries, which require DNA as a template. Dynamic changes in chromatin organization play a critical role in regulation of DNA-dependent processes such as transcription, DNA replication, recombination and repair. Chromatin structure is altered in transcriptionally active loci: the basic chromatin unit, the nucleosome, appears to be depleted for one histone H2A/H2B dimer. Previously, reconstitution of RNA polymerase II (PolII)-driven transcription on chromatin templates in a highly purified in vitro system led to identification of FACT (for facilitates chromatin transcription), which was required for productive transcript elongation through nucleosomes. FACT was proposed to promote PolII transcription through nucleosomes by removing either one or both H2A/H2B dimers. Here we present an overview of the earlier studies, which resulted in the initial identification and characterization of FACT, as well as the recent findings that refine the model for the mechanism of FACT function in transcription.

The RNA polymerase II transcription cycle: cycling through chromatin

The cycle of events that characterizes RNA polymerase II transcription has been the focus of intense study over the past two decades. Our knowledge of the molecular processes leading to transcriptional initiation is greatly improved, and the focus of many recent studies has shifted towards the less well-characterized events taking place after assembly of the pre-initiation complex, such as promoter clearance, elongation, and termination. This review gives a brief overview of the transcription cycle as a whole, focusing especially on selected mechanisms that may drive or restrict the cycle, and on how the presence of chromatin may influence these mechanisms.

Histone deacetylase (HDAC) inhibitor activation of p21WAF1 involves changes in promoter-associated proteins, including HDAC1

Histone deacetylase (HDAC) inhibitors (HDACi) cause cancer cell growth arrest and/or apoptosis in vivo and in vitro. The HDACi suberoylanilide hydroxamic acid (SAHA) is in phase I/II clinical trials showing significant anticancer activity. Despite wide distribution of HDACs in chromatin, SAHA alters the expression of few genes in transformed cells. p21(WAF1) is one of the most commonly induced. SAHA does not alter the expression of p27(KIPI), an actively transcribed gene, or globin, a silent gene, in ARP-1 cells. Here we studied SAHA-induced changes in the p21(WAF1) promoter of ARP-1 cells to better understand the mechanism of HDACi gene activation. Within 1 h, SAHA caused modifications in acetylation and methylation of core histones and increased DNase I sensitivity and restriction enzyme accessibility in the p21(WAF1) promoter. These changes did not occur in the p27(KIPI) or epsilon-globin gene-related histones. The HDACi caused a marked decrease in HDAC1 and Myc and an increase in RNA polymerase II in proteins bound to the p21(WAF1) promoter. Thus, this study identifies effects of SAHA on p21(WAF1)-associated proteins that explain, at least in part, the selective effect of HDACi in altering gene expression.

Gene expression during memory formation

For several decades, neuroscientists have provided many clues that point out the involvement of de novo gene expression during the formation of long-lasting forms of memory. However, information regarding the transcriptional response networks involved in memory formation has been scarce and fragmented. With the advent of genome-based technologies, combined with more classical approaches (i.e., pharmacology and biochemistry), it is now feasible to address those relevant questions--which gene products are modulated, and when that processes are necessary for the proper storage of memories--with unprecedented resolution and scale. Using one-trial inhibitory (passive) avoidance training of rats, one of the most studied tasks so far, we found two time windows of sensitivity to transcriptional and translational inhibitors infused into the hippocampus: around the time of training and 3-6 h after training. Remarkably, these periods perfectly overlap with the involvement of hippocampal cAMP/PKA (protein kinase A) signaling pathways in memory consolidation. Given the complexity of transcriptional responses in the brain, particularly those related to processing of behavioral information, it was clearly necessary to address this issue with a multi-variable, parallel-oriented approach. We used cDNA arrays to screen for candidate inhibitory avoidance learning-related genes and analyze the dynamic pattern of gene expression that emerges during memory consolidation. These include genes involved in intracellular kinase networks, synaptic function, DNA-binding and chromatin modification, transcriptional activation and repression, translation, membrane receptors, and oncogenes, among others. Our findings suggest that differential and orchestrated hippocampal gene expression is necessary in both early and late periods of long-term memory consolidation. Additionally, this kind of studies may lead to the identification and characterization of genes that are relevant for the pathogenesis of complex psychiatric disorders involving learning and memory impairments, and may allow the development of new methods for the diagnosis and treatment of these diseases.

ATP-driven exchange of histone H2AZ variant catalyzed by SWR1 chromatin remodeling complex

The conserved histone variant H2AZ has an important role in the regulation of gene expression and the establishment of a buffer to the spread of silent heterochromatin. How histone variants such as H2AZ are incorporated into nucleosomes has been obscure. We have found that Swr1, a Swi2/Snf2-related adenosine triphosphatase, is the catalytic core of a multisubunit, histone-variant exchanger that efficiently replaces conventional histone H2A with histone H2AZ in nucleosome arrays. Swr1 is required for the deposition of histone H2AZ at specific chromosome locations in vivo, and Swr1 and H2AZ commonly regulate a subset of yeast genes. These findings define a previously unknown role for the adenosine triphosphate-dependent chromatin remodeling machinery.

Isw1 Chromatin Remodeling ATPase Coordinates Transcription Elongation and Termination by RNA Polymerase II

We demonstrate that distinct forms of the yeast chromatin-remodeling enzyme Isw1p sequentially regulate each stage of the transcription cycle. The Isw1a complex (Iswlp/Ioc3p) represses gene expression at initiation through specific positioning of a promoter proximal dinucleosome, whereas the Isw1b complex (Iswlp/Ioc2p/Ioc4p) acts within coding regions to control the amount of RNA polymerase (RNAPII) released into productive elongation and to coordinate elongation with termination and pre-mRNA processing. These effects of Isw1b are controlled via phosphorylation of the heptad repeat carboxy-terminal domain (CTD) of RNAPII and methylation of the chromatin template. The transcription elongation factor Spt4p antagonizes Isw1p and overcomes the Isw1p dependent pausing of RNAPII at the onset of the elongation cycle. Overall these studies establish the central role played by Isw1p in the coordination of transcription.

Running with RNA polymerase: eukaryotic transcript elongation

Long recognized as a target of regulation in prokaryotes, transcript elongation has recently become the focus of many investigators interested in eukaryotic gene expression. The growth of this area has been fueled by the availability of new methods and molecular structures, expanding sequence databases and an appreciation for the exquisite coordination required among different processes in the nucleus. Our article collates new information on regulatory accessory factors, as well as their ultimate target, RNA polymerase, in the nucleus of eukaryotic cells. How this regulation influences the biology of the organism is quite profound, and from single cell to multicellular eukaryotes significant similarities exist in the molecular responses to extracellular signals during transcript elongation. The most advanced genetic knowledge in this area comes from Saccharomyces cerevisiae, but the biochemistry and cell biology results from other organisms are also highlighted.

Tracking FACT and the RNA polymerase II elongation complex through chromatin in vivo

RNA polymerase II (Pol II) transcription through nucleosomes is facilitated in vitro by the protein complex FACT (Facilitates Chromatin Transcription). Here we show that FACT is associated with actively transcribed Pol II genes on Drosophila polytene chromosomes. FACT displays kinetics of recruitment and of chromosome tracking in vivo similar to Pol II and elongation factors Spt5 and Spt6. Interestingly, FACT does not colocalize with Pol III-transcribed genes, which are known to undergo nucleosome transfer rather than disassembly in vitro. Our observations are consistent with FACT being restricted to transcription that involves nucleosome disassembly mechanisms.