The Vps27/Hse1 complex is a GAT domain-based scaffold for ubiquitin-dependent sorting.

The yeast Vps27/Hse1 complex and the homologous mammalian Hrs/STAM complex deliver ubiquitinated transmembrane proteins to the ESCRT endosomal-sorting pathway. The Vps27/Hse1 complex directly binds to ubiquitinated transmembrane proteins and recruits both ubiquitin ligases and deubiquitinating enzymes. We have solved the crystal structure of the core responsible for the assembly of the Vps27/Hse1 complex at 3.0 A resolution. The structure consists of two intertwined GAT domains, each consisting of two helices from one subunit and one from the other. The two GAT domains are connected by an antiparallel coiled coil, forming a 90 A-long barbell-like structure. This structure places the domains of Vps27 and Hse1 that recruit ubiquitinated cargo and deubiquitinating enzymes close to each other. Coarse-grained Monte Carlo simulations of the Vps27/Hse1 complex on a membrane show how the complex binds cooperatively to lipids and ubiquitinated membrane proteins and acts as a scaffold for ubiquitination reactions.

Structural basis for endosomal targeting by the Bro1 domain.

Proteins delivered to the lysosome or the yeast vacuole via late endosomes are sorted by the ESCRT complexes and by associated proteins, including Alix and its yeast homolog Bro1. Alix, Bro1, and several other late endosomal proteins share a conserved 160 residue Bro1 domain whose boundaries, structure, and function have not been characterized. The crystal structure of the Bro1 domain of Bro1 reveals a folded core of 367 residues. The extended Bro1 domain is necessary and sufficient for binding to the ESCRT-III subunit Snf7 and for the recruitment of Bro1 to late endosomes. The structure resembles a boomerang with its concave face filled in and contains a triple tetratricopeptide repeat domain as a substructure. Snf7 binds to a conserved hydrophobic patch on Bro1 that is required for protein complex formation and for the protein-sorting function of Bro1. These results define a conserved mechanism whereby Bro1 domain-containing proteins are targeted to endosomes by Snf7 and its orthologs.

Structural genomics and signaling domains.

Many novel signal transduction domains are being identified in the wake of genome sequencing projects and improved sensitivity in homology-detection techniques. The functions of these domains are being discovered by hypothesis-driven experiments and structural genomics approaches. This article reviews the recent highlights of research on modular signaling domains, and the relative contributions and limitations of the various approaches being used.

Molecular architecture and functional model of the complete yeast ESCRT-I heterotetramer.

The endosomal sorting complex required for transport-I (ESCRT-I) complex, which is conserved from yeast to humans, directs the lysosomal degradation of ubiquitinated transmembrane proteins and the budding of the HIV virus. Yeast ESCRT-I contains four subunits, Vps23, Vps28, Vps37, and Mvb12. The crystal structure of the heterotetrameric ESCRT-I complex reveals a highly asymmetric complex of 1:1:1:1 subunit stoichiometry. The core complex is nearly 18 nm long and consists of a headpiece attached to a 13 nm stalk. The stalk is important for cargo sorting by ESCRT-I and is proposed to serve as a spacer regulating the correct disposition of cargo and other ESCRT components. Hydrodynamic constraints and crystallographic structures were used to generate a model of intact ESCRT-I in solution. The results show how ESCRT-I uses a combination of a rigid stalk and flexible tethers to interact with lipids, cargo, and other ESCRT complexes over a span of approximately 25 nm.

Structural mechanism for ubiquitinated-cargo recognition by the Golgi-localized, gamma-ear-containing, ADP-ribosylation-factor-binding proteins.

The Golgi-localized, gamma-ear-containing, Arf (ADP-ribosylation factor)-binding (GGA) proteins are clathrin adaptors that mediate the sorting of transmembrane-cargo molecules at the trans-Golgi network and endosomes. Cargo proteins can be directed into the GGA pathway by at least two different types of sorting signals: acidic cluster-dileucine motifs and covalent modification by ubiquitin. The latter modification is recognized by the GGAs through binding to their GAT [GGA and TOM (target of Myb)] domain. Here we report the crystal structure of the GAT domain of human GGA3 in a 1:1 complex with ubiquitin at 2.8-A resolution. Ubiquitin binds to a hydrophobic and acidic patch on helices alpha1 and alpha2 of the GAT three-helix bundle that includes Asn-223, Leu-227, Glu-230, Met-231, Asp-244, Glu-246, Leu-247, Glu-250, and Leu-251. The GAT-binding surface on ubiquitin is a hydrophobic patch centered on Ile-44 that is also responsible for binding most other ubiquitin effectors. The ubiquitin-binding site observed in the crystal is distinct from the Rabaptin-5-binding site on helices alpha2 and alpha3 of the GAT domain. Mutational analysis and modeling of the ubiquitin-Rabaptin-5-GAT ternary complex indicates that ubiquitin and Rabaptin-5 can bind to the GAT domain at two different sites without any steric conflict. This ability highlights the GAT domain as a hub for interactions with multiple partners in trafficking.

Structure and catalytic mechanism of a SET domain protein methyltransferase.

Protein lysine methylation by SET domain enzymes regulates chromatin structure, gene silencing, transcriptional activation, plant metabolism, and other processes. The 2.6 A resolution structure of Rubisco large subunit methyltransferase in a pseudo-bisubstrate complex with S-adenosylhomocysteine and a HEPES ion reveals an all-beta architecture for the SET domain embedded within a larger alpha-helical enzyme fold. Conserved regions of the SET domain bind S-adenosylmethionine and substrate lysine at two sites connected by a pore. We propose that methyl transfer is catalyzed by a conserved Tyr at a narrow pore connecting the sites. The cofactor enters by a "back door" on the opposite side of the enzyme from substrate, promoting highly specific protein recognition and allowing addition of multiple methyl groups.