The xeroderma pigmentosum group D (XPD) helicase is a subunit of transcription/DNA repair factor, transcription factor II H (TFIIH) that catalyzes the unwinding of a damaged DNA duplex during nucleotide excision repair. Apart from two canonical helicase domains, XPD is composed of a 4Fe-S cluster domain involved in DNA damage recognition and a module of uncharacterized function termed the "ARCH domain." By investigating the consequences of a mutation found in a patient with trichothiodystrophy, we show that the ARCH domain is critical for the recruitment of the cyclin-dependent kinase (CDK)-activating kinase (CAK) complex. Indeed, this mutation not only affects the interaction with the MAT1 CAK subunit, thereby decreasing the in vitro basal transcription activity of TFIIH itself and impeding the efficient recruitment of the transcription machinery on the promoter of an activated gene, but also impairs the DNA unwinding activity of XPD and the nucleotide excision repair activity of TFIIH. We further demonstrate the role of CAK in downregulating the XPD helicase activity within TFIIH. Taken together, our results identify the ARCH domain of XPD as a platform for the recruitment of CAK and as a potential molecular switch that might control TFIIH composition and play a key role in the conversion of TFIIH from a factor active in transcription to a factor involved in DNA repair.rare disease | regulation of gene expression T he xeroderma pigmentosum group D (XPD) gene encodes a 5′-3′ helicase (XPD) that harbors mutations in patients suffering from three rare autosomal recessive diseases, xeroderma pigmentosum (XP), trichothiodystrophy (TTD), and Cockayne syndrome (CS) (1, 2). XP is characterized by a deficit of the nucleotide excision repair (NER) pathway, leading to sun sensitivity and susceptibility to skin cancer. TTD is characterized by sulfur-deficient brittle hair and a variety of neuroectodermal symptoms (3). XPD is the founding member of a family of DNA helicases conserved in archaea and eukaryotes. All family members share a four-domain organization including a conserved (Fe-S) cluster-binding domain that is essential for the helicase activity and a module of uncharacterized function named the ARCH domain by its arch-shape structure (4-7). Although archeal XPD homologs are monomers and have no known stable interactors, eukaryotic XPD homologs are part of the general transcription/DNA repair factor transcription factor II H (TFIIH), a multisubunit complex made up of 10 subunits (reviewed in ref. 8). Low-resolution models for TFIIH have been obtained for the complex in yeast (9, 10) and for the human complex (11), showing an overall conservation of shape. Human TFIIH can be resolved into two functional and structural entities bridged by XPD: the core-TFIIH consists of XPB, p62, p52, p44, p34, and p8, whereas the cyclin-dependent kinase (CDK)-activating kinase (CAK) subcomplex contains CDK7, cyclin H, and ménage a trois 1 (MAT1). XPD interacts with the p44 core-TFIIH subunit and with MAT1, a subunit of CAK involve...
NADPH oxidases (NOX) are important superoxide producing enzymes that regulate a variety of physiological and pathological processes such as bacteria killing, angiogenesis, sperm-oocyte fusion, and oxygen sensing. NOX5 is a member of the NOX family but distinct from the others by the fact that it contains a long N-terminus with four EF-hand Ca(2+)-binding sites (NOX5-EF). NOX5 generates superoxide in response to intracellular Ca(2+) elevation in vivo and in a cell-free system. Previously, we have shown that the regulatory N-terminal EF-hand domain interacts directly and in a Ca(2+)-dependent manner with the catalytic C-terminal catalytic dehydrogenase domain (CDHD) of the enzyme, leading to its activation. Here we have characterized the interaction site for the regulatory NOX5-EF in the catalytic CDHD of NOX5 using cloned fragments and synthetic peptides of the CDHD. The interaction was monitored with pull-down techniques, cross-linking experiments, tryptophan fluorescence, hydrophobic exposure, isothermal titration calorimetry, and cell-free system enzymatic assays. This site is composed of two short segments: the 637-660 segment, referred to as the regulatory EF-hand-binding domain (REFBD), and the 489-505 segment, previously identified as the phosphorylation region (PhosR). NOX5-EF binds to these two segments in a Ca(2+)-dependent way, and the superoxide generation by NOX5 depends on this interaction. Controlled proteolysis suggests that the REFBD is autoinhibitory and inhibition is relieved by NOX5-EF.
Centrins are calcium binding proteins that belong to the EF-hand (or calmodulin) superfamily, which are highly conserved among eukaryotes. Herein, we report the molecular features and binding properties of the green alga Scherffelia dubia centrin (SdCen), a member of the Chlamydomonas reinhardtii centrin (CrCen) subfamily. The Ca(2+) binding capacity of SdCen and its isolated N- and C-terminal domains (N-SdCen and C-SdCen, respectively) was investigated using flow dialysis and isothermal titration calorimetry. In contrast with human centrin 1 and 2 (from the same subfamily), but like CrCen, SdCen exhibits three physiologically significant Ca(2+) binding sites, two in the N-terminal domain and one in the C-terminal domain. Mg(2+) ions could compete with Ca(2+) in one of the N-terminal sites. When Ca(2+) binds, the N-terminal domain becomes more stable and exposes a significant hydrophobic surface that binds hydrophobic fluorescent probes. The Ca(2+) binding properties and the metal ion-induced structural changes in the C-terminal domain are comparable to those of human centrins. We used isothermal titration calorimetry to quantify the binding of SdCen, N-SdCen, and C-SdCen to three types of natural target peptides, derived from the human XPC protein (P17-XPC), the human Sfi1 protein (R17-hSfi1), and the yeast Kar1 protein (P19-Kar1). The three peptides possess the complete (P17-XPC and R17-hSfi1) or partial (P19-Kar1) centrin binding motif (W(1)L(4)L(8)). The integral SdCen exhibits two binding sites for each target peptide, with distinct affinities for each site and each peptide. The high-affinity peptide binding site corresponds to the C-terminal domain of SdCen and displays binding constants and the poor Ca(2+) sensitivities similar to those observed for human centrins. The low-affinity site constituted by the N-terminal domain is active only in the presence of Ca(2+). The thermodynamic binding parameters suggest that the C-terminal domain of SdCen may be constitutively bound to a target, while the N-terminal domain could bind a target only after a Ca(2+) signal. SdCen is also able to interact with calmodulin binding peptides (W(1)F(5)V(8)F(14) motif) with a 1:1 stoichiometry, whereas the isolated N- and C-terminal domains have a much lower affinity. These data suggest particular molecular mechanisms used by SdCen (and probably by other algal centrins) to respond to cellular Ca(2+) signals.
The synaptonemal complex (SC) keeps homologous chromosomes in close alignment during meiotic recombination. A hallmark of the SC is the presence of its constituent protein SYCP3 on the chromosome axis. During SC assembly, SYCP3 is deposited on both axes of the homologue pair, forming axial elements that fuse into the lateral element (LE) in the tripartite structure of the mature SC. We have used cryo-electron tomography and atomic force microscopy to study the mechanism of assembly and DNA binding of the SYCP3 fibre. We find that the three-dimensional architecture of the fibre is built on a highly irregular arrangement of SYCP3 molecules displaying very limited local geometry. Interaction between SYCP3 molecules is driven by the intrinsically disordered tails of the protein, with no contact between the helical cores, resulting in a flexible fibre assembly. We demonstrate that the SYCP3 fibre can engage in extensive interactions with DNA, indicative of an efficient mechanism for incorporation of DNA within the fibre. Our findings suggest that SYCP3 deposition on the chromosome axis might take place by polymerization into a fibre that is fastened to the chromosome surface via DNA binding.
The general transcription factor IIH (TFIIH) is a multi-protein complex and its 10 subunits are engaged in an intricate protein–protein interaction network critical for the regulation of its transcription and DNA repair activities that are so far little understood on a molecular level. In this study, we focused on the p44 and the p34 subunits, which are central for the structural integrity of core-TFIIH. We solved crystal structures of a complex formed by the p34 N-terminal vWA and p44 C-terminal zinc binding domains from Chaetomium thermophilum and from Homo sapiens. Intriguingly, our functional analyses clearly revealed the presence of a second interface located in the C-terminal zinc binding region of p34, which can rescue a disrupted interaction between the p34 vWA and the p44 RING domain. In addition, we demonstrate that the C-terminal zinc binding domain of p34 assumes a central role with respect to the stability and function of TFIIH. Our data reveal a redundant interaction network within core-TFIIH, which may serve to minimize the susceptibility to mutational impairment. This provides first insights why so far no mutations in the p34 or p44 TFIIH-core subunits have been identified that would lead to the hallmark nucleotide excision repair syndromes xeroderma pigmentosum or trichothiodystrophy.
The production of a homogeneous protein sample in sufficient quantities is an essential prerequisite not only for structural investigations but represents also a rate-limiting step for many functional studies. In the cell, a large fraction of eukaryotic proteins exists as large multicomponent assemblies with many subunits, which act in concert to catalyze specific activities. Many of these complexes cannot be obtained from endogenous source material, so recombinant expression and reconstitution are then required to overcome this bottleneck. This chapter describes current strategies and protocols for the efficient production of multiprotein complexes in large quantities and of high quality, using the baculovirus/insect cell expression system.
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