DNA helicases are essential components of the cellular machinery for DNA replication, recombination, repair, and transcription. The XPD and FancJ proteins are related helicases involved in the nucleotide excision repair (NER) and Fanconi anemia repair pathways, respectively. We demonstrate that both proteins have a conserved domain near the N terminus that includes an iron-sulfur (Fe-S) cluster. Three absolutely conserved cysteine residues provide ligands for the Fe-S cluster, which is essential for the helicase activity of XPD. Yeast strains harboring mutations in the Fe-S domain of Rad3 (yeast XPD) are defective in excision repair of UV photoproducts. Clinically relevant mutations in patients with trichothiodystrophy (TTD) and Fanconi anemia disrupt the Fe-S clusters of XPD and FancJ and thereby abolish helicase activity.
The XPD helicase (Rad3 in Saccharomyces cerevisiae) is a component of transcription factor IIH (TFIIH), which functions in transcription initiation and Nucleotide Excision Repair in eukaryotes, catalyzing DNA duplex opening localized to the transcription start site or site of DNA damage, respectively. XPD has a 5' to 3' polarity and the helicase activity is dependent on an iron-sulfur cluster binding domain, a feature that is conserved in related helicases such as FancJ. The xpd gene is the target of mutation in patients with xeroderma pigmentosum, trichothiodystrophy, and Cockayne's syndrome, characterized by a wide spectrum of symptoms ranging from cancer susceptibility to neurological and developmental defects. The 2.25 A crystal structure of XPD from the crenarchaeon Sulfolobus tokodaii, presented here together with detailed biochemical analyses, allows a molecular understanding of the structural basis for helicase activity and explains the phenotypes of xpd mutations in humans.
The XPF/Mus81 structure-specific endonucleases cleave double-stranded DNA (dsDNA) within asymmetric branched DNA substrates and play an essential role in nucleotide excision repair, recombination and genome integrity. We report the structure of an archaeal XPF homodimer alone and bound to dsDNA. Superposition of these structures reveals a large domain movement upon binding DNA, indicating how the (HhH) 2 domain and the nuclease domain are coupled to allow the recognition of double-stranded/single-stranded DNA junctions. We identify two nonequivalent DNA-binding sites and propose a model in which XPF distorts the 3 0 flap substrate in order to engage both binding sites and promote strand cleavage. The model rationalises published biochemical data and implies a novel role for the ERCC1 subunit of eukaryotic XPF complexes.
Metacaspases are distantly related caspase-family cysteine peptidases implicated in programmed cell death in plants and lower eukaryotes. They differ significantly from caspases because they are calcium-activated, arginine-specific peptidases that do not require processing or dimerization for activity. To elucidate the basis of these differences and to determine the impact they might have on the control of cell death pathways in lower eukaryotes, the previously undescribed crystal structure of a metacaspase, an inactive mutant of metacaspase 2 (MCA2) from Trypanosoma brucei, has been determined to a resolution of 1.4 Å. The structure comprises a core caspase fold, but with an unusual eight-stranded β-sheet that stabilizes the protein as a monomer. Essential aspartic acid residues, in the predicted S1 binding pocket, delineate the arginine-specific substrate specificity. In addition, MCA2 possesses an unusual N terminus, which encircles the protein and traverses the catalytic dyad, with Y31 acting as a gatekeeper residue. The calcium-binding site is defined by samarium coordinated by four aspartic acid residues, whereas calcium binding itself induces an allosteric conformational change that could stabilize the active site in a fashion analogous to subunit processing in caspases. Collectively, these data give insights into the mechanistic basis of substrate specificity and mode of activation of MCA2 and provide a detailed framework for understanding the role of metacaspases in cell death pathways of lower eukaryotes.apoptosis | clan CD | parasite | X-ray crystallography P rogrammed cell death (PCD) is essential for animal development and the maintenance of adult tissues. PCD itself is a regulated process, and in animals, apoptosis is controlled through the action of caspases, aspartic acid-specific cysteine peptidases (1). PCD is also essential for plant development (2), and multiple markers for apoptosis have been described in yeast and a broad range of protozoan parasites (3), yet these organisms do not encode caspases in their genomes; thus, alternative pathways must have evolved for caspase-independent cell death to be regulated. In recent years, attention has focused on the metacaspases, which are a highly conserved group of caspase-like cysteine peptidases found in plants, fungi, and protozoa but not in the metazoa (4). In plants, metacaspases are essential for embryogenesis (5, 6) and have been shown to act in antagonistic relationships, functioning as both positive and negative regulators of PCD (7). In yeast and some protozoa, metacaspases have been implicated as mediators of cell death in response to oxidative stress and environmental change (3,(8)(9)(10).Various attempts have been made to draw parallels between caspases and metacaspases in respect to structure, activation, and function (11). However, two striking differences between metacaspases and caspases are their substrate specificities and requirements for activation. Metacaspases have arginine/lysine specificity, do not necessarily require proces...
PDB Reference: PCNA, 2ix2, r2ix2sf.PCNA is a ring-shaped protein that encircles DNA, providing a platform for the association of a wide variety of DNA-processing enzymes that utilize the PCNA sliding clamp to maintain proximity to their DNA substrates. PCNA is a homotrimer in eukaryotes, but a heterotrimer in crenarchaea such as Sulfolobus solfataricus. The three proteins are SsoPCNA1 (249 residues), SsoPCNA2 (245 residues) and SsoPCNA3 (259 residues). The heterotrimeric protein crystallizes in space group P2 1 , with unit-cell parameters a = 44.8, b = 78.8, c = 125.6 Å , = 100.5 . The crystal structure of this heterotrimeric PCNA molecule has been solved using molecular replacement. The resulting structure to 2.3 Å sheds light on the differential stabilities of the interactions observed between the three subunits and the specificity of individual subunits for partner proteins.
Polycomb complex member Cbx4 represses nonepidermal lineage and cell cycle inhibitor genes in the epidermal keratinocytes and operates as a direct p63 target, maintaining epithelial identity and proliferative activity in the developing epidermis.
Xeroderma pigmentosum factor D (XPD) is a 5′–3′ superfamily 2 helicase and the founding member of a family of DNA helicases with iron–sulphur cluster domains. As a component of transcription factor II H (TFIIH), XPD is involved in DNA unwinding during nucleotide excision repair (NER). Archaeal XPD is closely related in sequence to the eukaryal enzyme and the crystal structure of the archaeal enzyme has provided a molecular understanding of mutations causing xeroderma pigmentosum and trichothiodystrophy in humans. Consistent with a role in NER, we show that archaeal XPD can initiate unwinding from a DNA bubble structure, differentiating it from the related helicases FancJ and DinG. XPD was not stalled by substrates containing extrahelical fluorescein adducts, abasic sites nor a cyclobutane pyrimidine dimer, regardless of whether these modifications were placed on either the displaced or translocated strands. This suggests that DNA lesions repaired by NER may not present a barrier to XPD translocation in vivo, in contrast to some predictions. Preferential binding of a fluorescein-adducted oligonucleotide was observed, and XPD helicase activity was readily inhibited by both single- and double-stranded DNA binding proteins. These observations have several implications for the current understanding of the NER pathway.
Activation of the ATF 6α signaling pathway is initiated by trafficking of ATF 6α from the ER to the Golgi apparatus. Its subsequent proteolysis releases a transcription factor that translocates to the nucleus causing downstream gene activation. How ER retention, Golgi trafficking, and proteolysis of ATF 6α are regulated and whether additional protein partners are required for its localization and processing remain unresolved. Here, we show that ER ‐resident oxidoreductase ER p18 associates with ATF 6α following ER stress and plays a key role in both trafficking and activation of ATF 6α. We find that ER p18 depletion attenuates the ATF 6α stress response. Paradoxically, ER stress accelerates trafficking of ATF 6α to the Golgi in ER p18‐depleted cells. However, the translocated ATF 6α becomes aberrantly processed preventing release of the soluble transcription factor. Hence, we demonstrate that ER p18 monitors ATF 6α ER quality control to ensure optimal processing following trafficking to the Golgi.
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