Christophe Romier

The histone fold is a key structural motif of transcription factor TFIID

Transcription factor TFIID is a multiprotein complex composed of the TATA binding protein and its associated factors, and is required for accurate and regulated initiation of transcription by RNA polymerase II. The subunit composition of this factor is highly conserved from yeast to mammals. X-ray crystallography and biochemical experiments have shown that the histone fold motif mediates many of the subunit interactions within this complex. These results, together with electron microscopy and yeast genetics, provide insights into the overall organization of this complex.

Human TAFII28 and TAFII18 Interact through a Histone Fold Encoded by Atypical Evolutionary Conserved Motifs Also Found in the SPT3 Family

Determination of the crystal structure of the human TBP-associated factor (hTAF(II))28/hTAF(II)18 heterodimer shows that these TAF(II)s form a novel histone-like pair in the TFIID complex. The histone folds in hTAF(II)28 and hTAF(II)18 were not predicted from their primary sequence, indicating that these TAF(II)s define a novel family of atypical histone fold sequences. The TAF(II)18 and TAF(II)28 histone fold motifs are also present in the N- and C-terminal regions of the SPT3 proteins, suggesting that the histone fold in SPT3 may be reconstituted by intramolecular rather than classical intermolecular interactions. The existence of additional histone-like pairs in both the TFIID and SAGA complexes shows that the histone fold is a more commonly used motif for mediating TAF-TAF interactions than previously believed.

Sequence-Specific Transcription Factor NF-Y Displays Histone-like DNA Binding and H2B-like Ubiquitination

The sequence-specific transcription factor NF-Y binds the CCAAT box, one of the sequence elements most frequently found in eukaryotic promoters. NF-Y is composed of the NF-YA and NF-YB/NF-YC subunits, the latter two hosting histone-fold domains (HFDs). The crystal structure of NF-Y bound to a 25 bp CCAAT oligonucleotide shows that the HFD dimer binds to the DNA sugar-phosphate backbone, mimicking the nucleosome H2A/H2B-DNA assembly. NF-YA both binds to NF-YB/NF-YC and inserts an α helix deeply into the DNA minor groove, providing sequence-specific contacts to the CCAAT box. Structural considerations and mutational data indicate that NF-YB ubiquitination at Lys138 precedes and is equivalent to H2B Lys120 monoubiquitination, important in transcriptional activation. Thus, NF-Y is a sequence-specific transcription factor with nucleosome-like properties of nonspecific DNA binding and helps establish permissive chromatin modifications at CCAAT promoters. Our findings suggest that other HFD-containing proteins may function in similar ways.

Anp32E is a Histone Chaperone that Removes H2A.Z from Chromatin

H2A.Z is an essential histone variant implicated in the regulation of key nuclear events. However, the metazoan chaperones responsible for H2A.Z deposition and its removal from chromatin remain unknown. Here we report the identification and characterization of the human protein ANP32E as a specific H2A.Z chaperone. We show that ANP32E is a member of the presumed H2A.Z histone-exchange complex p400/TIP60. ANP32E interacts with a short region of the docking domain of H2A.Z through a new motif termed H2A.Z interacting domain (ZID). The 1.48 Å resolution crystal structure of the complex formed between the ANP32E-ZID and the H2A.Z/H2B dimer and biochemical data support an underlying molecular mechanism for H2A.Z/H2B eviction from the nucleosome and its stabilization by ANP32E through a specific extension of the H2A.Z carboxy-terminal α-helix. Finally, analysis of H2A.Z localization in ANP32E−/− cells by chromatin immunoprecipitation followed by sequencing shows genome-wide enrichment, redistribution and accumulation of H2A.Z at specific chromatin control regions, in particular at enhancers and insulators.

Co-expression of protein complexes in prokaryotic and eukaryotic hosts: experimental procedures, database tracking and case studies

Structure determination and functional characterization of macromolecular complexes requires the purification of the different subunits in large quantities and their assembly into a functional entity. Although isolation and structure determination of endogenous complexes has been reported, much progress has to be made to make this technology easily accessible. Co-expression of subunits within hosts such as Escherichia coli and insect cells has become more and more amenable, even at the level of high-throughput projects. As part of SPINE (Structural Proteomics In Europe), several laboratories have investigated the use co-expression techniques for their projects, trying to extend from the common binary expression to the more complicated multi-expression systems. A new system for multi-expression in E. coli and a database system dedicated to handle co-expression data are described. Results are also reported from various case studies investigating different methods for performing co-expression in E. coli and insect cells.

The Human TFIID Components TAFII135 and TAFII20 and the Yeast SAGA Components ADA1 and TAFII68 Heterodimerize to Form Histone-Like Pairs

ABSTRACT It has been previously proposed that the transcription complexes TFIID and SAGA comprise a histone octamer-like substructure formed from a heterotetramer of H4-like human hTAFII80 (or itsDrosophila melanogaster dTAFII60 and yeast [Saccharomyces cerevisiae] yTAFII60 homologues) and H3-like hTAFII31 (dTAFII40 and yTAFII17) along with two homodimers of H2B-like hTAFII20 (dTAFII30α and yTAFII61/68). However, it has not been formally shown that hTAFII20 heterodimerizes via its histone fold. By two-hybrid analysis with yeast and biochemical characterization of complexes formed by coexpression in Escherichia coli, we showed that hTAFII20 does not homodimerize but heterodimerizes with hTAFII135. Heterodimerization requires the α2 and α3 helices of the hTAFII20 histone fold and is abolished by mutations in the hydrophobic face of the hTAFII20 α2 helix. Interaction with hTAFII20 requires a domain of hTAFII135 which shows sequence homology to H2A. This domain also shows homology to the yeast SAGA component ADA1, and we show that yADA1 heterodimerizes with the histone fold region of yTAFII61/68, the yeast hTAFII20 homologue. These results are indicative of a histone fold type of interaction between hTAFII20-hTAFII135 and yTAFII68-yADA1, which therefore constitute novel histone-like pairs in the TFIID and SAGA complexes.

Structural basis for the inhibition of histone deacetylase 8 (HDAC8), a key epigenetic player in the blood fluke Schistosoma mansoni.

The treatment of schistosomiasis, a disease caused by blood flukes parasites of the Schistosoma genus, depends on the intensive use of a single drug, praziquantel, which increases the likelihood of the development of drug-resistant parasite strains and renders the search for new drugs a strategic priority. Currently, inhibitors of human epigenetic enzymes are actively investigated as novel anti-cancer drugs and have the potential to be used as new anti-parasitic agents. Here, we report that Schistosoma mansoni histone deacetylase 8 (smHDAC8), the most expressed class I HDAC isotype in this organism, is a functional acetyl-L-lysine deacetylase that plays an important role in parasite infectivity. The crystal structure of smHDAC8 shows that this enzyme adopts a canonical α/β HDAC fold, with specific solvent exposed loops corresponding to insertions in the schistosome HDAC8 sequence. Importantly, structures of smHDAC8 in complex with generic HDAC inhibitors revealed specific structural changes in the smHDAC8 active site that cannot be accommodated by human HDACs. Using a structure-based approach, we identified several small-molecule inhibitors that build on these specificities. These molecules exhibit an inhibitory effect on smHDAC8 but show reduced affinity for human HDACs. Crucially, we show that a newly identified smHDAC8 inhibitor has the capacity to induce apoptosis and mortality in schistosomes. Taken together, our biological and structural findings define the framework for the rational design of small-molecule inhibitors specifically interfering with schistosome epigenetic mechanisms, and further support an anti-parasitic epigenome targeting strategy to treat neglected diseases caused by eukaryotic pathogens.

Automated unrestricted multigene recombineering for multiprotein complex production

Structural and functional studies of many multiprotein complexes depend on recombinant-protein overexpression. Rapid revision of expression experiments and diversification of the complexes are often crucial for success of these projects; therefore, automation is increasingly indispensable. We introduce Acembl, a versatile and automatable system for protein-complex expression in Escherichia coli that uses recombineering to facilitate multigene assembly and diversification. We demonstrated protein-complex expression using Acembl, including production of the complete prokaryotic holotranslocon.

Histone folds mediate selective heterodimerization of yeast TAF(II)25 with TFIID components yTAF(II)47 and yTAF(II)65 and with SAGA component ySPT7.

ABSTRACT We show that the yeast TFIID (yTFIID) component yTAFII47 contains a histone fold domain (HFD) with homology to that previously described for hTAFII135. Complementation in vivo indicates that the yTAFII47 HFD is necessary and sufficient for vegetative growth. Mutation of highly conserved residues in the α1 helix of the yTAFII47 HFD results in a temperature-sensitive phenotype which can be suppressed by overexpression of yTAFII25, as well as by yTAFII40, yTAFII19, and yTAFII60. In yeast two-hybrid and bacterial coexpression assays, the yTAFII47 HFD selectively heterodimerizes with yTAFII25, which we show contains an HFD with homology to the hTAFII28 family We additionally demonstrate that yTAFII65 contains a functional HFD which also selectively heterodimerizes with yTAFII25. These results reveal the existence of two novel histone-like pairs in yTFIID. The physical and genetic interactions described here show that the histone-like yTAFIIs are organized in at least two substructures within TFIID rather than in a single octamer-like structure as previously suggested. Furthermore, our results indicate that ySPT7 has an HFD homologous to that of yTAFII47 which selectively heterodimerizes with yTAFII25, defining a novel histone-like pair in the SAGA complex.

The TFIID components human TAF(II)140 and Drosophila BIP2 (TAF(II)155) are novel metazoan homologues of yeast TAF(II)47 containing a histone fold and a PHD finger.

ABSTRACT The RNA polymerase II transcription factor TFIID comprises the TATA binding protein (TBP) and a set of TBP-associated factors (TAFIIs). TFIID has been extensively characterized for yeast, Drosophila, and humans, demonstrating a high degree of conservation of both the amino acid sequences of the constituent TAFIIs and overall molecular organization. In recent years, it has been assumed that all the metazoan TAFIIs have been identified, yet no metazoan homologues of yeast TAFII47 (yTAFII47) and yTAFII65 are known. Both of these yTAFIIs contain a histone fold domain (HFD) which selectively heterodimerizes with that of yTAFII25. We have cloned a novel mouse protein, TAFII140, containing an HFD and a plant homeodomain (PHD) finger, which we demonstrated by immunoprecipitation to be a mammalian TFIID component. TAFII140 shows extensive sequence similarity toDrosophila BIP2 (dBIP2) (dTAFII155), which we also show to be a component of DrosophilaTFIID. These proteins are metazoan homologues of yTAFII47 as their HFDs selectively heterodimerize with dTAFII24 and human TAFII30, metazoan homologues of yTAFII25. We further show that yTAFII65 shares two domains with theDrosophila Prodos protein, a recently described potential dTAFII. These conserved domains are critical for yTAFII65 function in vivo. Our results therefore identify metazoan homologues of yTAFII47 and yTAFII65.