The ubiquitin-conjugating enzymes UbcH7 and UbcH8 interact with RING finger/IBR motif-containing domains of HHARI and H7-AP1.

Ubiquitinylation of proteins appears to be mediated by the specific interplay between ubiquitin-conjugating enzymes (E2s) and ubiquitin-protein ligases (E3s). However, cognate E3s and/or substrate proteins have been identified for only a few E2s. To identify proteins that can interact with the human E2 UbcH7, a yeast two-hybrid screen was performed. Two proteins were identified and termed human homologue of Drosophila ariadne (HHARI) and UbcH7-associated protein (H7-AP1). Both proteins, which are widely expressed, are characterized by the presence of RING finger and in between RING fingers (IBR) domains. No other overt structural similarity was observed between the two proteins. In vitro binding studies revealed that an N-terminal RING finger motif (HHARI) and the IBR domain (HHARI and H7-AP1) are involved in the interaction of these proteins with UbcH7. Furthermore, binding of these two proteins to UbcH7 is specific insofar that both HHARI and H7-AP1 can bind to the closely related E2, UbcH8, but not to the unrelated E2s UbcH5 and UbcH1. Although it is not clear at present whether HHARI and H7-AP1 serve, for instance, as substrates for UbcH7 or represent proteins with E3 activity, our data suggests that a subset of RING finger/IBR proteins are functionally linked to the ubiquitin/proteasome pathway.     

Human homologue of ariadne promotes the ubiquitylation of translation initiation factor 4E homologous protein, 4EHP

Human homologue of Drosophila ariadne (HHARI) is a RING-IBR-RING domain protein identified through its ability to bind the human ubiquitin-conjugating enzyme, UbcH7. We now demonstrate that HHARI also interacts with the eukaryotic mRNA cap binding protein, translation initiation factor 4E homologous protein (4EHP), via the N-terminal RING1 finger of HHARI. HHARI, 4EHP and UbcH7 do not form a stable heterotrimeric complex as 4EHP cannot immunoprecipitate UbcH7 even in the presence of HHARI. Overexpression of 4EHP and HHARI in mammalian cells leads to polyubiquitylation of 4EHP. By contrast, HHARI does not promote its own autoubiquitylation. Thus, by promoting the ubiquitin-mediated degradation of 4EHP, HHARI may have a role in both protein degradation and protein translation.     

Features of the parkin/ariadne-like ubiquitin ligase, HHARI, that regulate its interaction with the ubiquitin-conjugating enzyme, Ubch7

We recently reported the identification of a RING finger-containing protein, HHARI (human homologue of Drosophila ariadne), which binds to the human ubiquitin-conjugating enzyme UbcH7 in vitro. We now demonstrate that HHARI interacts and co-localizes with UbcH7 in mammalian cells, particularly in the perinuclear region. We have further defined a minimal interaction region of HHARI comprising residues 186-254, identified individual amino acid residues essential for the interaction, and determined that the distance between the RING1 finger and IBR (in between RING fingers) domains is critical to maintaining binding. We have also established that the RING1 finger of HHARI cannot be substituted for by the highly homologous RING finger domains of either of the ubiquitin-protein ligase components c-CBL or Parkin, despite their similarity in structure and their independent capabilities to bind UbcH7. Furthermore, mutation of the RING1 finger domain of HHARI from a RING-HC to a RING-H2 type abolishes interaction with UbcH7. These studies demonstrate that very subtle changes to the domains that regulate recognition between highly conserved components of the ubiquitin pathway can dramatically affect their ability to interact.     

Isolation and chromosomal localization of the human En-2 gene

By low stringency hybridization we have isolated from a human cosmid genomic library sequences homologous with a probe from the Drosophila engrailed gene. Partial nucleotide sequence analysis shows a consensus splice acceptor site followed by an open reading frame (ORF) that can encode 104 amino acids; the first 94 amino acids have 71% identity with the Drosophila engrailed protein. The shared region contains a homeo domain and is within the region of engrailed shared with the Drosophila invected gene and the mouse En-1 and En-2 genes. At the amino acid level, the human sequence is 85% identical with the mouse En-1 gene and 100% identical with the mouse En-2 gene. Hybridization against a panel of human-hamster somatic cell hybrids maps this human En-2 gene to chromosome 7, and regional mapping by in situ hybridization to human chromosomes localizes it to region 7q36 at the end of the long arm.     

The E3 Ubiquitin Ligase ARIH1 Protects against Genotoxic Stress by Initiating a 4EHP-Mediated mRNA Translation Arrest

DNA damage response signaling is crucial for genome maintenance in all organisms and is corrupted in cancer. In an RNA interference (RNAi) screen for (de)ubiquitinases and sumoylases modulating the apoptotic response of embryonic stem (ES) cells to DNA damage, we identified the E3 ubiquitin ligase/ISGylase, ariadne homologue 1 (ARIH1). Silencing ARIH1 sensitized ES and cancer cells to genotoxic compounds and ionizing radiation, irrespective of their p53 or caspase-3 status. Expression of wild-type but not ubiquitinase-defective ARIH1 constructs prevented sensitization caused by ARIH1 knockdown. ARIH1 protein abundance increased after DNA damage through attenuation of proteasomal degradation that required ATM signaling. Accumulated ARIH1 associated with 4EHP, and in turn, this competitive inhibitor of the eukaryotic translation initiation factor 4E (eIF4E) underwent increased nondegradative ubiquitination upon DNA damage. Genotoxic stress led to an enrichment of ARIH1 in perinuclear, ribosome-containing regions and triggered 4EHP association with the mRNA 5′ cap as well as mRNA translation arrest in an ARIH1-dependent manner. Finally, restoration of DNA damage-induced translation arrest in ARIH1-depleted cells by means of an eIF2 inhibitor was sufficient to reinstate resistance to genotoxic stress. These findings identify ARIH1 as a potent mediator of DNA damage-induced translation arrest that protects stem and cancer cells against genotoxic stress.     

Human and mouse homologues of the Drosophila melanogaster tweety (tty) gene: a novel gene family encoding predicted transmembrane proteins

We have cloned cDNA for TTYH1, a human homologue of the Drosophila melanogaster tweety (tty) gene. The 450-residue predicted protein shows 27% amino acid sequence identity (51% similarity) to the Drosophila protein, which contains an additional C-terminal repetitive region. A second Drosophila homologue exhibits 42% identity (65% similarity) to the tty protein. Mouse (Ttyh1), macaque, and Caenorhabditis elegans homologues were also identified, and the complete coding sequence for the mouse gene was determined. The mouse protein is 91% identical to the human protein. Hydrophobicity analysis of the tty-related proteins indicates that they represent a new family of membrane proteins with five potential membrane-spanning regions. The yeast FTR1 and FTH1 iron transporter proteins and the mammalian neurotensin receptors 1 and 2 have a similar hydrophobicity profile, although there is no detectable sequence homology to the tty-related proteins. This suggests that the tweety-related proteins could be involved in transport of iron or other divalent cations or alternatively that they may be membrane-bound receptors. TTYH1 was mapped to chromosome 19q13.4 by FISH and by radiation hybrid mapping using the Stanford G3 panel.     

Identification and comparative analysis of the RpL14 gene from Takifugu rubripes

The ribosomal protein RpL14 gene has been characterized in several species, including, human, rat and fruit fly. Haploinsufficiency for the gene causes the Minute phenotype in Drosophila, and it has been proposed as a regulator in the tumorigenic pathway in human. Several features concerning the gene structure have been studied, and some of these differ between human/rat and Drosophila. To address functional and evolutionary questions about these differences we have isolated and sequenced a cDNA and a genomic clone covering the RpL14 gene from the pufferfish Takifugu rubripes (Fugu). The Fugu RpL14 gene is approximately 2 Kb, with 5 introns, and encodes a protein of 137 amino acids. The protein contains a KOW-motif and a nuclear localization signal, which are conserved among a wide range of RPL14 proteins. On the other hand, a variable amino acid (alanine) repeat observed in human is missing in Takifugu rubripes, and the protein is shorter than its mammalian counterparts. Compared with human, the RpL14 gene in Fugu contains introns localized at identical positions in the gene, and most of them are shorter. A comparison of the RpL14 gene structure from a broad range of organisms indicates that both loss and gain of introns have occurred during the evolution of the gene.     

Intron loss in the SART1 genes of Fugu rubripes and Tetraodon nigroviridis.

The human SART1 gene was initially identified in a screen for proteins recognised by IgE, which may be implicated in atopic disease. We have examined the genomic structure and cDNA sequence of the SART1 gene in the compact genomes of the pufferfish Fugu rubripes and Tetraodon nigroviridis. The entire coding regions of both the Fugu and Tetraodon SART1 genes are contained within single exons. The Fugu gene contains only one intron located in the 5' untranslated region. Southern blot hybridisation of Fugu genomic DNA confirmed the SART1 gene to be single copy. Partial genomic structures were also determined for the human, mouse, Drosophila and C. elegans SART1 homologues. The human and mouse genes both contain many introns in the coding region, the human gene possessing at least 20 exons. The Drosophila and C. elegans homologues contain 6 and 12 exons, respectively. This is only the second time such a difference in the organization of homologous Fugu and human genes has been reported. The Fugu and Tetraodon SART1 genes encode putative proteins of 772 and 774 aa, respectively, each having 65% amino acid identity to human SART1. Leucine zipper and basic motifs are conserved in the predicted Fugu and Tetraodon proteins.     

Molecular cloning and sequence analysis of the mouse protein C inhibitor gene

The gene encoding mouse protein C inhibitor (mPCI) was isolated and its nucleotide sequence determined. Alignment of the genomic sequence with that of a cDNA obtained from mouse testis revealed that the mPCI gene (like the human counterpart) is composed of five exons and four introns with highly conserved exon/intron boundaries. It encodes a pre-polypeptide of 405 amino acids, which shows 63% identity with human PCI (hPCI). The putative reactive site is identical to that of hPCI from P5 to P3′, suggesting a similar protease specificity. Also the putative heparin binding sites and `hinge' regions are highly homologous in mouse and hPCI.     

ARIH2抑制LUBAC的线性泛素化连接酶活性

线性泛素化修饰在肿瘤及免疫系统中均发挥着重要作用。线性泛素链组装复合体(linear ubiquitin chain assembly complex, LUBAC)是目前已知的唯一能够催化合成线性泛素链的泛素连接酶。本研究发现,泛素连接酶2(ariadne homolog 2,ARIH2)作为LUBAC新的相互作用蛋白质,能够抑制LUBAC对底物的线性泛素化修饰水平。通过免疫共沉淀实验发现,ARIH2与HOIP存在相互作用,且GST pull-down结果说明,HOIP通过ZF-NZF结构域与ARIH2发生相互作用。进一步的免疫沉淀结果证明,LUBAC并不能线性泛素化修饰ARIH2。反之,ARIH2能够抑制LUBAC对底物的线性泛素化修饰水平,其机制可能是ARIH2影响了SHARPIN的泛素化水平,从而影响LUBAC酶活性,进而导致LUBAC对底物的线性泛素化水平减弱。     

The basis for selective E1-E2 interactions in the ISG15 conjugation system

E1 and E2 enzymes coordinate the first steps in conjugation of ubiquitin (Ub) and ubiquitin-like proteins (Ubls). ISG15 is an interferon-alpha/beta-induced Ubl, and the E1 and E2 enzymes for ISG15 conjugation are Ube1L and UbcH8, respectively. UbcH7 is the most closely related E2 to UbcH8, yet it does not function in ISG15 conjugation in vivo, while both UbcH7 and UbcH8 have been reported to function in Ub conjugation. Kinetic analyses of wild-type and chimeric E2s were performed to determine the basis for preferential activation of UbcH8 by Ube1L and to determine whether UbcH8 is activated equally well by Ube1L and E1(Ub) (Ube1). K(m) determinations confirmed the strong preference of Ube1L for UbcH8 over UbcH7 (a 29-fold K(m) difference), similar to the preference of E1(Ub) for UbcH7 over UbcH8 (a 36-fold K(m) difference). Thioester assays of chimeric E2s identified two structural elements within residues 1-39 of UbcH8 that play a major role in defining Ube1L-UbcH8 specificity: the alpha1-helix and the beta1-beta2 region. The C-terminal ubiquitin fold domain (UFD) of Ube1L was required for transfer of ISG15 to UbcH8 and for binding of Ube1L to UbcH8. Replacement of the Ube1L UFD with that from E1(Ub) resulted in preferential transfer of ISG15 to UbcH7. Together, these results indicate that Ube1L discriminates between UbcH8 and closely related Ub E2s based on specific interactions between the Ube1L UFD and determinants within the N-terminal region of UbcH8.