It is generally assumed that a specific ubiquitin ligase (E3)linksIn eukaryotic cells, ubiquitination serves to target regulatory and misfolded proteins for rapid degradation by proteasomes (1-3), to trigger endocytosis of membrane proteins (4), and also to allow specific protein-protein associations important in signal transduction, DNA repair, and gene transcription (5-8). Protein ubiquitination involves formation of isopeptide linkages between the C-terminal carboxyl group of a ubiquitin (Ub) 4 and an ⑀-amino group on a lysine on the protein substrate or a preceding Ub to form a polyUb chain. To synthesize such linkages, the C-terminal carboxyl group of a Ub is first activated by formation of a thioester bond with a cysteine on the Ubactivating enzyme (E1), and the activated Ub is then transferred as a thioester to one of the 20 -40 Ub-conjugating enzymes (E2) of the cell. The formation of a Ub chain on the substrate is then catalyzed by a Ub ligase (E3), which binds the substrate and an E2. Several families of E3s exist that differ in structure and mechanism. If ubiquitination is catalyzed by a member of the Ring finger or the U-box E3 family, the activated Ub is transferred from the E2 directly to a lysine on the protein substrate or to a preceding Ub. The abundant Ring finger and the related U-box families are small monomeric proteins that bind the substrate at one end and then in that vicinity release the reactive Ub from the E2-Ub thioester (9, 10). If ubiquitination is catalyzed by an E3 of the HECT domain family, the activated Ub is transferred from the E2 first to a cysteine on the E3 to form another thioester bond and then to the substrate or to a preceding Ub * This work was supported by grants from the NIGMS, the High Q Foundation, the Fund for Innovation from Elan Corp. (to A. L. G.), the National Institutes of Health (to S. P. G.), and National Institutes of Health R01 Grant GM65267 (to D. S.). The costs of publication of this article were defrayed in part by the payment of page charges. This article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact. 4 The abbreviations used are: Ub, ubiquitin; UPKn, ubiquitin peptide modified at lysine n by ubiquitination; Forked chain, Ub chain in which two Ub chains are linked to the adjacent lysines on the preceding Ub; E1, Ubactivating enzyme; E2, Ub-conjugating enzyme; E3, ubiquitin-protein isopeptide ligase; LC-MSMS liquid chromatography-tandem mass spectrometry; SIM, selective ion monitoring.
α–synuclein (α-syn) is a small lipid binding protein implicated in several neurodegenerative diseases, including Parkinson’s disease, whose pathobiology is conserved from yeast to man. There are no therapies targeting these underlying cellular pathologies, or indeed those of any major neurodegenerative disease. Using unbiased phenotypic screens as an alternative to target-based approaches, we discovered an N-aryl benzimidazole (NAB) that strongly and selectively protected diverse cell-types from α-syn toxicity. Three chemical genetic screens in wild-type yeast cells established that NAB promoted endosomal transport events dependent on the E3 ubiquitin ligase, Rsp5/Nedd4. These same steps were perturbed by α–syn itself. Thus, NAB identifies a druggable node in the biology of α-syn that can correct multiple aspects of its underlying pathology, including dysfunctional endosomal and ER-to-Golgi vesicle trafficking.
α-Synuclein is an abundant brain protein that binds to lipid membranes and is involved in the recycling of presynaptic vesicles. In Parkinson disease, α-synuclein accumulates in intraneuronal inclusions often containing ubiquitin chains. Here we show that the ubiquitin ligase Nedd4, which functions in the endosomal–lysosomal pathway, robustly ubiquitinates α-synuclein, unlike ligases previously implicated in its degradation. Purified Nedd4 recognizes the carboxyl terminus of α-synuclein (residues 120–133) and attaches K63-linked ubiquitin chains. In human cells, Nedd4 overexpression enhances α-synuclein ubiquitination and clearance by a lysosomal process requiring components of the endosomal-sorting complex required for transport. Conversely, Nedd4 down-regulation increases α-synuclein content. In yeast, disruption of the Nedd4 ortholog Rsp5p decreases α-synuclein degradation and enhances inclusion formation and α-synuclein toxicity. In human brains, Nedd4 is present in pigmented neurons and is expressed especially strongly in neurons containing Lewy bodies. Thus, ubiquitination by Nedd4 targets α-synuclein to the endosomal–lysosomal pathway and, by reducing α-synuclein content, may help protect against the pathogenesis of Parkinson disease and other α-synucleinopathies.
Although cellular proteins conjugated to K48-linked Ub chains are targeted to proteasomes, proteins conjugated to K63-ubiquitin chains are directed to lysosomes. However, pure 26S proteasomes bind and degrade K48- and K63-ubiquitinated substrates similarly. Therefore, we investigated why K63-ubiquitinated proteins are not degraded by proteasomes. We show that mammalian cells contain soluble factors that selectively bind to K63-chains and inhibit or prevent their association with proteasomes. Using ubiquitinated proteins as affinity ligands, we found that the main cellular proteins that associate selectively with K63-chains and block their binding to proteasomes are ESCRT0 and its components, STAM and Hrs. In vivo, knockdown of ESCRT0 confirmed that it is required to block binding of K63-ubiquitinated molecules to the proteasome. In addition, the Rad23 proteins, especially hHR23B, were found to bind specifically to K48-ubiquitinated proteins and to stimulate proteasome binding. The specificities of these proteins for K48- or K63-ubiquitin chains determine whether a ubiquitinated protein is targeted for proteasomal degradation or delivered instead to the endosomal-lysosomal pathway.
Earlier research has revealed that the ndh loci have been pseudogenized, truncated, or deleted from most orchid plastomes sequenced to date, including in all available plastomes of the two most species-rich subfamilies, Orchidoideae and Epidendroideae. This study sought to resolve deeper-level phylogenetic relationships among major orchid groups and to refine the history of gene loss in the ndh loci across orchids. The complete plastomes of seven orchids, Oncidium sphacelatum (Epidendroideae), Masdevallia coccinea (Epidendroideae), Sobralia callosa (Epidendroideae), Sobralia aff. bouchei (Epidendroideae), Elleanthus sodiroi (Epidendroideae), Paphiopedilum armeniacum (Cypripedioideae), and Phragmipedium longifolium (Cypripedioideae) were sequenced and analyzed in conjunction with all other available orchid and monocot plastomes. Most ndh loci were found to be pseudogenized or lost in Oncidium, Paphiopedilum and Phragmipedium, but surprisingly, all ndh loci were found to retain full, intact reading frames in Sobralia, Elleanthus and Masdevallia. Character mapping suggests that the ndh genes were present in the common ancestor of orchids but have experienced independent, significant losses at least eight times across four subfamilies. In addition, ndhF gene loss was correlated with shifts in the position of the junction of the inverted repeat (IR) and small single-copy (SSC) regions. The Orchidaceae have unprecedented levels of homoplasy in ndh gene presence/absence, which may be correlated in part with the unusual life history of orchids. These results also suggest that ndhF plays a role in IR/SSC junction stability.
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