RANBP2 mutation causing autosomal dominant acute necrotizing encephalopathy attenuates its interaction with COX11.

PURPOSE: Autosomal dominant acute necrotizing encephalopathy (ADANE) is caused by missense mutations in the gene encoding Ran-binding protein 2 (RANBP2), a nuclear pore protein regulating mitochondrial localization and function. Previous studies have found that RANBP2 binds to COX11 and suppresses its inhibitory activity over hexokinase1. To further elucidate mitochondrial dysfunction in ADANE, we analyzed the interaction between mutated RANBP2 and COX11. METHODS: We extracted cDNA from a patient and constructed pGEX wild-type or mutant-type vectors including RANBP2 c.1754C>T, the commonest variant in ADANE. We transformed E. coli competent cells with the vectors and had them express GST-RANBP2 recombinant protein, and conducted a pull-down assay of RANBP2 and COX11. RESULTS: The amount of COX11 bound to mutated RANBP2 was significantly smaller than that bound to the wild-type RANBP2. CONCLUSION: Mutated RANBP2 had an attenuated binding ability to COX11. Whether this change indeed decreases ATP production remains to be further explored.

Simultaneous flow cytometric immunophenotyping of necroptosis, apoptosis and RIP1-dependent apoptosis.

Flow cytometry was been widely used to measure apoptosis for many decades but the researcher has no definitive way of determining other forms of cell death using this technology. The use of Western Blot technology has numerous drawbacks in that all the cells in the sample whether live, dead or maybe undergoing multiple discrete forms of cell death are analysed as one population. Flow cytometry given that it can analyse different sub-populations of cells within a sample would reveal the expression of cell death markers within these sub-populations rather than just give a single result from the entire population. Here we describe a flow cytometric assay fully realising that potential by the use of anti-RIP-3 (Receptor-interacting serine/threonine-protein kinase 3) and anti-active caspase-3 fluorescently tagged antibodies and a fixable live dead fluorescent dye. This allows the determination of the degree of necroptosis, apoptosis and RIP1-dependent apoptosis within live and dead populations. Necroptosis was identified by the up-regulation of RIP3, while RIP1-dependent apoptosis was described by double positive for RIP3/active Caspase-3 events in live and dead populations. Apoptotic cells were defined by an active-Caspase-3+ve/RIP3-ve phenotype. Pan-caspase blocker zVAD and RIP1 inhibitors GSK'481 or necrostatin-1 revealed interesting modulations of such sub-populations of Jurkat cells. This novel flow cytometric assay employing two antibodies and a fixable viability probe provides the researcher with in-depth analysis of various forms of regulated forms of cell death beyond what is currently available and is a major methodological advancement in this field.

Purification of Lamins and Soluble Fragments of NETs.

Lamins and associated nuclear envelope transmembrane proteins (NETs) present unique problems for biochemical studies. Lamins form insoluble intermediate filament networks, associate with chromatin, and are also connected via specific NETs to the cytoskeleton, thus further complicating their isolation and purification from mammalian cells. Adding to this complexity, NETs at the inner nuclear membrane function in three distinct environments: (a) their nucleoplasmic domain(s) can bind lamins, chromatin, and transcriptional regulators; (b) they possess one or more integral transmembrane domains; and (c) their lumenal domain(s) function in the unique reducing environment of the nuclear envelope/ER lumen. This chapter describes strategic considerations and protocols to facilitate biochemical studies of lamins and NET proteins in vitro. Studying these proteins in vitro typically involves first expressing specific polypeptide fragments in bacteria and optimizing conditions to purify each fragment. We describe parameters for choosing specific fragments and designing purification strategies and provide detailed purification protocols. Biochemical studies can provide fundamental knowledge including binding strengths and the molecular consequences of disease-causing mutations that will be essential to understand nuclear envelope-genome interactions and nuclear envelope linked disease mechanisms.

Simple Separation of Functionally Distinct Populations of Lamin-Binding Proteins.

The inner membrane of the nuclear envelope (NE) is home to hundreds of integral membrane proteins (NE transmembrane proteins, "NETs") with conserved or tissue-specific roles in genome organization and nuclear function. Nearly all characterized NETs bind A- or B-type lamins directly. However, hundreds of NETs remain uncharacterized, collectively posing an enormous gap that must be bridged to understand nuclear function and genome biology. We provide technically simple protocols for the separation and recovery of functionally distinct populations of NETs and A-type lamins. This protocol was developed for emerin, an inner nuclear membrane protein that binds lamins and barrier-to-autointegration factor (BANF1) as a component of nuclear lamina structure, and has diverse roles in nuclear assembly, signaling, and gene regulation. This protocol separates easily solubilized ("easy") populations of nuclear lamina proteins (emerin, lamin A, BAF) from "sonication-dependent" populations. Depending on cell type, the "easy" and "sonication-dependent" fractions each contain up to about half the available emerin, A-type lamins, and BAF, whereas B-type lamins and histone H3 are predominantly sonication dependent. The two populations of emerin have distinct posttranslational modifications, and only one population associates with BAF. This method may be useful for functional screening or analysis of other lamin-associated proteins, including novel NETs emerging from proteomic studies.

Nanobodies: site-specific labeling for super-resolution imaging, rapid epitope-mapping and native protein complex isolation.

Nanobodies are single-domain antibodies of camelid origin. We generated nanobodies against the vertebrate nuclear pore complex (NPC) and used them in STORM imaging to locate individual NPC proteins with <2 nm epitope-label displacement. For this, we introduced cysteines at specific positions in the nanobody sequence and labeled the resulting proteins with fluorophore-maleimides. As nanobodies are normally stabilized by disulfide-bonded cysteines, this appears counterintuitive. Yet, our analysis showed that this caused no folding problems. Compared to traditional NHS ester-labeling of lysines, the cysteine-maleimide strategy resulted in far less background in fluorescence imaging, it better preserved epitope recognition and it is site-specific. We also devised a rapid epitope-mapping strategy, which relies on crosslinking mass spectrometry and the introduced ectopic cysteines. Finally, we used different anti-nucleoporin nanobodies to purify the major NPC building blocks ­ each in a single step, with native elution and, as demonstrated, in excellent quality for structural analysis by electron microscopy. The presented strategies are applicable to any nanobody and nanobody-target.

The use of targeted proteomics to determine the stoichiometry of large macromolecular assemblies.

Accurate knowledge of the stoichiometry of protein complexes is a crucial prerequisite for understanding their structure and function. To purify or enrich large and intricate protein complexes such that their structure is preserved and to absolutely quantify all of their protein components is an enormous technical challenge. In this chapter, we describe how to purify nuclear envelopes from human tissue culture cells that are highly enriched for nuclear pore complexes. We use the nuclear pore as an example to discuss how the structural preservation of such preparations can be controlled. Furthermore, we give a practical guide how to develop and employ targeted proteomic assays for both, the absolute quantification of stoichiometries and the relative quantification of protein complex composition across multiple biological conditions. The concept discussed here is universally applicable to any protein complex.

Expression and purification of human FROUNT, a common cytosolic regulator of CCR2 and CCR5.

Chemokine receptors play pivotal roles for immune cell recruitment to inflammation sites, in response to chemokine gradients (chemotaxis). The mechanisms of chemokine signaling, especially the initiation of the intracellular signaling cascade, are not well understood. We previously identified a cytoplasmic protein FROUNT, which binds to the C-terminal regions of CCR2 and CCR5 to mediate chemokine signaling. Although large amounts of purified protein are required for detailed biochemical studies and drug screening, no method to produce recombinant FROUNT has been reported. In this study, we developed a method for the production of recombinant human FROUNT. Human FROUNT was successfully expressed in Escherichia coli, as a soluble protein fused to the folding chaperone Trigger Factor, with a cold shock expression system. The purified FROUNT protein displayed CCR2 binding ability without any additional components, as demonstrated by SPR measurements. A gel filtration analysis suggested that FROUNT exists in a homo-oligomeric state. This high-yield method is cost-effective for human FROUNT production. It should be a powerful tool for further biochemical and structural studies to elucidate GPCR regulation and chemokine signaling, and also will contribute to drug development.

Generalized semi-refolding methods for purification of the functional death domain superfamily.

The death domain (DD) superfamily comprising the death domain (DD) subfamily, the death effector domain (DED) subfamily, the caspase recruitment domain (CARD) subfamily and the pyrin domains (PYD) subfamily is one of the largest classes of protein interaction modules and plays a pivotal role in the apoptosis, inflammation, and immune cell signaling pathways. Despite the biological importance of the death domain superfamily, structural and in vitro biochemical studies have been limited because these domains are prone to aggregate under physiological conditions. Here, we describe a generalized method, termed semi-refolding, that is particularly applicable for purification of the functional death domain superfamily. The recombinant proteins Caspase-1 CARD, AIM2 PYD, NALP3 PYD, and RIP1 DD from inclusion bodies were successfully purified using this method.

Resolving the composition of protein complexes using a MALDI LTQ Orbitrap.

Current biological studies have been advanced by the continuous development of robust, accurate, and sensitive mass spectrometric technologies. The MALDI LTQ Orbitrap is a new addition to the Orbitrap configurations, known for their high resolving power and accuracy. This configuration provides features inherent to the MALDI source, such as reduced spectra complexity, forgiveness to contaminants, and sample retention for follow-up analyses with targeted or hypothesis-driven questions. Here we investigate its performance for characterizing the composition of isolated protein complexes. To facilitate the assessment, we selected two well characterized complexes from Saccharomyces cerevisiae, Apl1 and Nup84. Manual and automatic MS and MS/MS analyses readily resolved their compositions, with increased confidence of protein identification compared with our previous reports using MALDI QqTOF and MALDI IT. CID fragmentation of singly-charged peptides provided sufficient information for conclusive identification of the isolated proteins. We then assessed the resolution, accuracy, and sensitivity provided by this instrument in the context of analyzing the isolated protein assemblies. Our analysis of complex mixtures of singly-charged ions up to m/z 4000 showed that (1) the resolving power, inversely proportional to the square root of m/z, had over four orders of magnitude dynamic range; (2) internal calibration led to improved accuracy, with an average absolute mass error of 0.5 ppm and a distribution centered at 0 ppm; and (3) subfemtomole sensitivity was achieved using both CHCA and DHB matrices. Additionally, our analyses of a synthetic phosphorylated peptide in mixtures showed subfemtomole level of detection using neutral loss scanning.

Three-dimensional structure and flexibility of a membrane-coating module of the nuclear pore complex.

The nuclear pore complex mediates nucleocytoplasmic transport in all eukaryotes and is among the largest cellular assemblies of proteins, collectively known as nucleoporins. Nucleoporins are organized into distinct subcomplexes. We optimized the isolation of a putative membrane-coating subcomplex of the nuclear pore complex, the heptameric Nup84 complex, and analyzed its structure by EM. Our data confirmed the previously reported 'Y' shape. We discerned additional structural details, including specific hinge regions at which the particle shows great flexibility. We determined the three-dimensional structures of two conformers, mapped the localization of two nucleoporins within the subcomplex and docked known crystal structures into the EM maps. The free ends of the Y-shaped particle are formed by beta-propellers; the connecting segments consist of alpha-solenoids. Notably, the same organizational principle is found in the clathrin triskelion, which may share a common evolutionary origin with the heptameric complex.

Purification, crystallization and preliminary X-ray analysis of a Nup107-Nup133 heterodimeric nucleoporin complex.

The nuclear pore complex (NPC), the sole gateway of traffic between the nucleus and the cytoplasm, is built up from multiple copies of about 30 proteins collectively termed nucleoporins (nups). Nups are organized into distinct subcomplexes. Nup107 and Nup133 are members of the essential Nup107-160 subcomplex, a component of the central NPC architecture. A dimeric complex of the C-terminal domains of human Nup107 and Nup133 was expressed from a bicistronic vector in Escherichia coli, purified and crystallized in two different crystal forms. Crystals grown in the presence of 18-22% PEG 3350 belong to space group P2(1)2(1)2(1) and diffracted to 2.9 A. Native and seleno-L-methionine-derivative crystals grown in the presence of 1.1 M sodium malonate belong to space group C2 and diffracted to 2.55 and 2.9 A, respectively. Structure determination of this complex will give the first insights into the protein-protein interactions within a core module of the NPC.

The nuclear rim protein Amo1 is required for proper microtubule cytoskeleton organisation in fission yeast.

Microtubules have a central role in cell division and cell polarity in eukaryotic cells. The fission yeast is a useful organism for studying microtubule regulation owing to the highly organised nature of its microtubular arrays. To better understand microtubule dynamics and organisation we carried out a screen that identified over 30 genes whose overexpression resulted in microtubule cytoskeleton abnormalities. Here we describe a novel nucleoporin-like protein, Amo1, identified in this screen. Amo1 localises to the nuclear rim in a punctate pattern that does not overlap with nuclear pore complex components. Amo1Delta cells are bent, and they have fewer microtubule bundles that curl around the cell ends. The microtubules in amo1Delta cells have longer dwelling times at the cell tips, and grow in an uncoordinated fashion. Lack of Amo1 also causes a polarity defect. Amo1 is not required for the microtubule loading of several factors affecting microtubule dynamics, and does not seem to be required for nuclear pore function.

A putative nucleoporin 96 Is required for both basal defense and constitutive resistance responses mediated by suppressor of npr1-1,constitutive 1.

The Arabidopsis thaliana suppressor of npr1-1, constitutive 1 (snc1) mutant contains a gain-of-function mutation in a Toll Interleukin1 receptor-nucleotide binding-Leu-rich repeat-type resistance gene (R-gene), which leads to constitutive activation of disease resistance response against pathogens. In a screen for suppressors of snc1, a recessive mutation, designated mos3 (for modifier of snc1,3), was found to suppress the constitutive pathogenesis-related gene expression and resistance to virulent Pseudomonas syringae maculicola ES4326 and Peronospora parasitica Noco2 in snc1. In addition, mos3 is also compromised in resistance mediated by Resistance to Peronospora parasitica 4 (RPP4), Resistance to Pseudomonas syringae pv maculicola (RPM1), and Resistance to Pseudomonas syringae 4 (RPS4). Single mutant mos3 plants exhibited enhanced disease susceptibility to P. s. pv maculicola ES4326, suggesting that MOS3 is required for basal resistance to pathogens as well. mos3-1 was identified by map-based cloning, and it encodes a protein with high sequence similarity to human nucleoporin 96. Localization of the MOS3-green fluorescent protein fusion to the nuclear envelope further indicates that MOS3 may encode a nucleoporin, suggesting that nuclear and cytoplasmic trafficking plays an important role in both R-gene-mediated and basal disease resistance.

Proteomic analysis of the mammalian nuclear pore complex.

As the sole site of nucleocytoplasmic transport, the nuclear pore complex (NPC) has a vital cellular role. Nonetheless, much remains to be learned about many fundamental aspects of NPC function. To further understand the structure and function of the mammalian NPC, we have completed a proteomic analysis to identify and classify all of its protein components. We used mass spectrometry to identify all proteins present in a biochemically purified NPC fraction. Based on previous characterization, sequence homology, and subcellular localization, 29 of these proteins were classified as nucleoporins, and a further 18 were classified as NPC-associated proteins. Among the 29 nucleoporins were six previously undiscovered nucleoporins and a novel family of WD repeat nucleoporins. One of these WD repeat nucleoporins is ALADIN, the gene mutated in triple-A (or Allgrove) syndrome. Our analysis defines the proteome of the mammalian NPC for the first time and paves the way for a more detailed characterization of NPC structure and function.

Novel vertebrate nucleoporins Nup133 and Nup160 play a role in mRNA export.

RNA undergoing nuclear export first encounters the basket of the nuclear pore. Two basket proteins, Nup98 and Nup153, are essential for mRNA export, but their molecular partners within the pore are largely unknown. Because the mechanism of RNA export will be in question as long as significant vertebrate pore proteins remain undiscovered, we set out to find their partners. Fragments of Nup98 and Nup153 were used for pulldown experiments from Xenopus egg extracts, which contain abundant disassembled nuclear pores. Strikingly, Nup98 and Nup153 each bound the same four large proteins. Purification and sequence analysis revealed that two are the known vertebrate nucleoporins, Nup96 and Nup107, whereas two mapped to ORFs of unknown function. The genes encoding the novel proteins were cloned, and antibodies were produced. Immunofluorescence reveals them to be new nucleoporins, designated Nup160 and Nup133, which are accessible on the basket side of the pore. Nucleoporins Nup160, Nup133, Nup107, and Nup96 exist as a complex in Xenopus egg extracts and in assembled pores, now termed the Nup160 complex. Sec13 is prominent in Nup98 and Nup153 pulldowns, and we find it to be a member of the Nup160 complex. We have mapped the sites that are required for binding the Nup160 subcomplex, and have found that in Nup98, the binding site is used to tether Nup98 to the nucleus; in Nup153, the binding site targets Nup153 to the nuclear pore. With transfection and in vivo transport assays, we find that specific Nup160 and Nup133 fragments block poly[A]+ RNA export, but not protein import or export. These results demonstrate that two novel vertebrate nucleoporins, Nup160 and Nup133, not only interact with Nup98 and Nup153, but themselves play a role in mRNA export.

Isolation and characterization of subnuclear compartments from Trypanosoma brucei. Identification of a major repetitive nuclear lamina component.

Protozoan parasites of the order Kinetoplastida are responsible for a significant proportion of global morbidity and economic hardship. These organisms also represent extremely distal points within the Eukarya, and one such organism, Trypanosoma brucei, has emerged as a major system for the study of evolutionary cell biology. Significant technical challenges have hampered the full exploitation of this organism, but advances in genomics and proteomics provide a novel approach to acquiring rapid functional data. However, the vast evolutionary distance between trypanosomes and the higher eukaryotes presents significant problems with functional assignment based on sequence similarity, and frequently homologues cannot be identified with sufficient confidence to be informative. Direct identification of proteins in isolated organelles has the potential of providing robust functional insight and is a powerful approach for initial assignment. We have selected the nucleus of T. brucei as a first target for protozoan organellar proteomics. Our purification methodology was able to reliably provide both nuclear and subnuclear fractions. Analysis by gel electrophoresis, electron microscopy, and immunoblotting against trypanosome subcellular markers indicated that the preparations are of high yield and purity, maintain native morphology, and are well resolved from other organelles. Minor developmental differences were observed in the nuclear proteome for the bloodstream and procyclic stages, whereas significant morphological alterations were visible. We demonstrate by direct sequencing that the NUP-1 nuclear envelope antigen is a coiled coil protein, containing approximately 20 near-perfect copies of a 144-amino acid sequence. Immunoelectron microscopy localized NUP-1 to the inner face of the nuclear envelope, suggesting that it is a major filamentous component of the trypanosome nuclear lamina.

[The characterization of a novel testis-specific nucleoporin gene].

OBJECTIVE: To investigate the structure and function of testis-specific gene and spermatogenesis in human. METHODS: Screening cDNA expression library, 5' rapid amplification of cDNA ends, Northern blot and fluorescent in situ hybridization(FISH) were used. Gene expressing, purified of expressed protein by affinity chromatography and SDS-PAGE as well as phosphorylation of expressed protein in vitro by PKC and p34cdc2 were observed. RESULTS: A cDNA designated as BS-63 was isolated and found to consist of 2,209 bp with an open reading frame of 2,100 bp and assigned the accession number U64675 by GenBank. The deduced polypeptide consisted of 700 amino acid residues containing XFXFG or FG motifs that were characteristic of nuclear pore complex (NPC) protein and acted as potential binding sites for Ran. The N-terminal region had high homology with Ran BP2/Nup 358, a nucleoporin component, showing that BS-63 was a member of the NPC family. Northern blot analysis of mRNA prepared from various human tissues showed that BS-63 gene was transcribed in two forms: 6.0 and 8.5 kb. The 8.5 kb transcript was present in low amounts in several somatic tissues; whereas the 6.0 kb transcript was expressed only in testis. Analysis by FISH method mapped the BS-63 gene in 2q11.2-12. A protein band with an estimated Mr of 80,000 was detected with E. coli BL21 (DE3) transfected with recombinant plasmid pET30a (+)-BS-63. In vitro phosphorylation test indicated the BS-63 recombinant protein could be phosphorylated by PKC and p34cdc2. CONCLUSIONS: The study was the first demonstration that the BS-63 gene encoding a nucleoporin-related protein with Ran binding sites was expressed in germ cells of human testis.