Coordinated Ribosomal L4 Protein Assembly into the Pre-Ribosome Is Regulated by Its Eukaryote-Specific Extension.

Eukaryotic ribosome biogenesis requires nuclear import and hierarchical incorporation of ∼80 ribosomal proteins (RPs) into the ribosomal RNA core. In contrast to prokaryotes, many eukaryotic RPs possess long extensions that interdigitate in the mature ribosome. RpL4 is a prime example, with an ∼80-residue-long surface extension of unknown function.

Structural basis for assembly and function of the Nup82 complex in the nuclear pore scaffold.

Nuclear pore complexes (NPCs) are huge assemblies formed from ∼30 different nucleoporins, typically organized in subcomplexes. One module, the conserved Nup82 complex at the cytoplasmic face of NPCs, is crucial to terminate mRNA export. To gain insight into the structure, assembly, and function of the cytoplasmic pore filaments, we reconstituted in yeast the Nup82-Nup159-Nsp1-Dyn2 complex, which was suitable for biochemical, biophysical, and electron microscopy analyses.

A pulse-chase epitope labeling to study cellular dynamics of newly synthesized proteins: a novel strategy to characterize NPC biogenesis and ribosome maturation/export.

The vast number of cellular proteins performs their roles within macromolecular assemblies and functional cell networks. Hence, an understanding of how multiprotein complexes are formed and modified during biogenesis is a key problem in cell biology. Here, we describe a detailed protocol for a nonradioactive pulse-chase in vivo-labeling approach.

Utilizing the Dyn2 dimerization-zipper as a tool to probe NPC structure and function.

The discovery of dynein light chain 2 (Dyn2) as a member of the nucleoporins in yeast led to a series of applications to study NPC structure and function. Its intriguing ability to act as a hub for the parallel dimerization of two short amino acid sequence motifs (DID) prompted us to utilize it as a tool for probing nucleocytoplasmic transport in vivo. Further, the distinct structure of the Dyn2-DID rod, which is easily visible in the electron microscope, allowed us to develop a precise structural label on proteins or protein complexes.

Monitoring spatiotemporal biogenesis of macromolecular assemblies by pulse-chase epitope labeling.

Many cellular proteins perform their roles within macromolecular assemblies. Hence, an understanding of how these multiprotein complexes form is a fundamental question in cell biology. We developed a translation-controlled pulse-chase system that allows time-resolved isolation of newly forming multiprotein complexes in chemical quantities suitable for biochemical and cell biological analysis.

Probing the nucleoporin FG repeat network defines structural and functional features of the nuclear pore complex.

Unraveling the organization of the FG repeat meshwork that forms the active transport channel of the nuclear pore complex (NPC) is key to understanding the mechanism of nucleocytoplasmic transport. In this paper, we develop a tool to probe the FG repeat network in living cells by modifying FG nucleoporins (Nups) with a binding motif (engineered dynein light chain-interacting domain) that can drag several copies of an interfering protein, Dyn2, into the FG network to plug the pore and stop nucleocytoplasmic transport. Our method allows us to specifically probe FG Nups in vivo, which provides insight into the organization and function of the NPC transport channel.

Precise mapping of subunits in multiprotein complexes by a versatile electron microscopy label.

Positional knowledge of subunits within multiprotein assemblies is crucial for understanding their function. The topological analysis of protein complexes by electron microscopy has undergone impressive development, but analysis of the exact positioning of single subunits has lagged behind. Here we have developed a clonable approximately 80-residue tag that, upon attachment to a target protein, can recruit a structurally prominent electron microscopy label in vitro.

Two structurally distinct domains of the nucleoporin Nup170 cooperate to tether a subset of nucleoporins to nuclear pores.

How individual nucleoporins (Nups) perform their role in nuclear pore structure and function is largely unknown. In this study, we examined the structure of purified Nup170 to obtain clues about its function. We show that Nup170 adopts a crescent moon shape with two structurally distinct and separable domains, a beta-propeller N terminus and an alpha-solenoid C terminus.

Structural basis of the nic96 subcomplex organization in the nuclear pore channel.

Nic96 is a conserved nucleoporin that recruits the Nsp1-Nup49-Nup57 complex, a module with Phe-Gly (FG) repeats, to the central transport channel of the nuclear pore complex (NPC). Nic96 binds the Nsp1 complex via its N domain and assembles into the NPC framework via its central and C domain. Here, we report the crystal structure of a large structural nucleoporin, Nic96 without its N domain (Nic96DeltaN).

Molecular basis for the functional interaction of dynein light chain with the nuclear-pore complex.

Nucleocytoplasmic transport occurs through nuclear pore complexes (NPCs) embedded in the nuclear envelope. Here, we discovered an unexpected role for yeast dynein light chain (Dyn2) in the NPC. Dyn2 is a previously undescribed nucleoporin that functions as molecular glue to dimerize and stabilize the Nup82-Nsp1-Nup159 complex, a module of the cytoplasmic pore filaments.

Reconstitution of Nup157 and Nup145N into the Nup84 complex.

About 30 different nucleoporins (Nups) constitute the nuclear pore complex. We have affinity-purified 28 of these nuclear pore proteins and identified new nucleoporin interactions by this analysis. We found that Nup157 and Nup170, two members of the large structural Nups, and the Gly-Leu-Phe-Gly nucleoporin Nup145N specifically co-purified with members of the Nup84 complex.

Control of spontaneous and damage-induced mutagenesis by SUMO and ubiquitin conjugation.

Protein modification by ubiquitin is emerging as a signal for various biological processes in eukaryotes, including regulated proteolysis, but also for non-degradative functions such as protein localization, DNA repair and regulation of chromatin structure. A small ubiquitin-related modifier (SUMO) uses a similar conjugation system that sometimes counteracts the effects of ubiquitination. Ubiquitin and SUMO compete for modification of proliferating cell nuclear antigen (PCNA), an essential processivity factor for DNA replication and repair.