Ribosome-bound Get4/5 facilitates the capture of tail-anchored proteins by Sgt2 in yeast.

The guided entry of tail-anchored proteins (GET) pathway assists in the posttranslational delivery of tail-anchored proteins, containing a single C-terminal transmembrane domain, to the ER. Here we uncover how the yeast GET pathway component Get4/5 facilitates capture of tail-anchored proteins by Sgt2, which interacts with tail-anchors and hands them over to the targeting component Get3. Get4/5 binds directly and with high affinity to ribosomes, positions Sgt2 close to the ribosomal tunnel exit, and facilitates the capture of tail-anchored proteins by Sgt2. The contact sites of Get4/5 on the ribosome overlap with those of SRP, the factor mediating cotranslational ER-targeting. Exposure of internal transmembrane domains at the tunnel exit induces high-affinity ribosome binding of SRP, which in turn prevents ribosome binding of Get4/5. In this way, the position of a transmembrane domain within nascent ER-targeted proteins mediates partitioning into either the GET or SRP pathway directly at the ribosomal tunnel exit.

Legionella effector MavC targets the Ube2N~Ub conjugate for noncanonical ubiquitination.

The bacterial effector MavC modulates the host immune response by blocking Ube2N activity employing an E1-independent ubiquitin ligation, catalyzing formation of a γ-glutamyl-ε-Lys (Gln40Ub-Lys92Ube2N) isopeptide crosslink using a transglutaminase mechanism. Here we provide biochemical evidence in support of MavC targeting the activated, thioester-linked Ube2N~ubiquitin conjugate, catalyzing an intramolecular transglutamination reaction, covalently crosslinking the Ube2N and Ub subunits effectively inactivating the E2~Ub conjugate. Ubiquitin exhibits weak binding to MavC alone, but shows an increase in affinity when tethered to Ube2N in a disulfide-linked substrate that mimics the charged E2~Ub conjugate. Crystal structures of MavC in complex with the substrate mimic and crosslinked product provide insights into the reaction mechanism and underlying protein dynamics that favor transamidation over deamidation, while revealing a crucial role for the structurally unique insertion domain in substrate recognition. This work provides a structural basis of ubiquitination by transglutamination and identifies this enzyme's true physiological substrate.

Fused Split Inteins: Tools for Introducing Multiple Protein Modifications.

The split inteins from the DnaE cyanobacterial family are efficient and versatile tools for protein engineering and chemical biology applications. Their ultrafast splicing kinetics allow for the efficient production of native proteins from two separate polypeptides both in vitro and in cells. They can also be used to generate proteins with C-terminal thioesters for downstream applications. In this chapter, we describe a method based on a genetically fused version of the DnaE intein Npu for the preparation of doubly modified proteins through recombinant expression. In particular, we provide protocols for the recombinant production of modified ubiquitin through amber suppression where fused Npu is used (1) as a traceless purification tag or (2) as a protein engineering tool to introduce C-terminal modifications for subsequent attachment to other proteins of interest. Our purification protocol allows for quick and facile separation of truncated products and eliminates the need for engineering protease cleavage sites. Our approach can be easily adapted to different proteins and applications where the simultaneous presence of internal and C-terminal modifications is desirable.

Preparation and purification of mono-ubiquitinated proteins using Avi-tagged ubiquitin.

Site-specific conjugation of ubiquitin onto a range of DNA repair proteins regulates their critical functions in the DNA damage response. Biochemical and structural characterization of these functions are limited by an absence of tools for the purification of DNA repair proteins in purely the ubiquitinated form. To overcome this barrier, we designed a ubiquitin fusion protein that is N-terminally biotinylated and can be conjugated by E3 RING ligases onto various substrates. Biotin affinity purification of modified proteins, followed by cleavage of the affinity tag leads to release of natively-mono-ubiquitinated substrates. As proof-of-principle, we applied this method to several substrates of mono-ubiquitination in the Fanconi anemia (FA)-BRCA pathway of DNA interstrand crosslink repair. These include the FANCI:FANCD2 complex, the PCNA trimer and BRCA1 modified nucleosomes. This method provides a simple approach to study the role of mono-ubiquitination in DNA repair or any other mono-ubiquitination signaling pathways.

Cryo-LESA Mass Spectrometry-a Step Towards Truly Native Surface Sampling of Proteins.

Liquid extraction surface analysis (LESA) is a powerful method for measuring proteins from surfaces. In this work, we present development and initial testing of a cryo-platform for LESA mass spectrometry of proteins. We explore the use of native sampling solutions for probing proteins directly from frozen surfaces. Our initial results from analysis of ubiquitin and hemoglobin standards showed that protein and protein complex refolding or unfolding occurs during the liquid solvent extraction stage of routine room temperature LESA. However, by employing the cryo-sampling method, the refolding or unfolding of protein ubiquitin can be dramatically reduced, while for the protein complex of hemoglobin, its native structures can be better preserved compared with room temperature sampling. This indicates that a truly native LESA sampling method of proteins is feasible. We also present detection of proteins directly from a frozen tissue section. Interestingly, slight conformational differences are observed from different regions of the frozen tissue surface. Further development of this strategy should be considered as a method for preserving, maintaining, and studying proteins in their native states, directly from tissue. Graphical Abstract.

Single-site labeling of histidine in proteins, on-demand reversibility, and traceless metal-free protein purification.

A precision methodology distinguishes one His from all the nucleophilic residues and its multiple copies. An easy-to-operate C-N bond formation labels diverse proteins without adversely affecting their structure and function. The late-stage transformation allows installation of distinct probes. The chemically triggered reversibility enables traceless metal-free purification of proteins with a His-tag.

Characterization of N-glycosylations in Entamoeba histolytica ubiquitin.

Entamoeba histolytica harbors an extensive intracellular distribution of ubiquitin-proteasome systems important for numerous cellular processes. However, glycosylation studies of ubiquitin-proteasome components have not yet been elucidated. Here we report the partial characterization of N-linked glycosylation profile in E. histolytica ubiquitin by Fluorophore-Assisted Carbohydrate Electrophoresis (FACE), Nanoelectrospray Ionization-Tandem Mass Spectrometry (NSI-MS), Matrix-Assisted Laser-Desorption time-of-flight Mass Spectrometry (MALDI-TOF MS) and Gas Chromatography-Mass Spectrometry (GC-MS) analysis. To our knowledge, the data presented in this report represents the first structural glycomics analysis of E. histolytica ubiquitin, while most of the reports are performed on whole parasitic glycan profiles. The glycan profile of E. histolytica ubiquitin has high mannose N-glycan structures. The N-linked glycan profile showed fragments from Hex3HexNAc2 to Hex9HexNAc2. Based in our findings and ubiquitin function, we hypothesize that the same ubiquitin Asn-Asp-Ser sequon carries heterogenic glycosylations, at different metabolic pathway stages according to ubiquitin functional requirements. Finally, we propose a set of possible high mannose N-glycan structures that will help to elucidate the ubiquitin biochemical composition and may well represent good targets for anti-amoebic drugs.

In-Depth Quantitative Proteomic Analysis of Trophozoites and Pseudocysts of Trichomonas vaginalis.

Trichomonas vaginalis is a sexually transmitted anaerobic parasite that infects humans causing trichomoniasis, a common and ubiquitous sexually transmitted disease. The life cycle of this parasite possesses a trophozoite form without a cystic stage. However, the presence of nonproliferative and nonmotile, yet viable and reversible spherical forms with internalized flagella, denominated pseudocysts, has been commonly observed for this parasite. To understand the mechanisms involved in the formation of pseudocysts, we performed a mass spectrometry-based high-throughput quantitative proteomics study using a label-free approach and functional assays by biochemical and flow cytometric methods. We observed that the morphological transformation of trophozoite to pseudocysts is coupled to (i) a metabolic shift toward a less glycolytic phenotype; (ii) alterations in the abundance of hydrogenosomal iron-sulfur cluster (ISC) assembly machinery; (iii) increased abundance of regulatory particles of the ubiquitin-proteasome system; (iv) significant alterations in proteins involved in adhesion and cytoskeleton reorganization; and (v) arrest in G2/M phase associated with alterations in the abundance of regulatory proteins of the cell cycle. These data demonstrate that pseudocysts experience important physiological and structural alterations for survival under unfavorable environmental conditions.

Enzymatic Assembly of Ubiquitin Chains.

The availability of different polyubiquitin chains of specific linkage types has changed the appreciation of the specificity in the ubiquitin (Ub) system. Numerous E2 Ub-conjugating enzymes and E3 Ub ligases, Ub-binding domains (UBDs), and deubiquitinases (DUBs) are now known to assemble, bind, or hydrolyze individual linkage types, respectively. Biochemical and structural studies of these processes require milligram quantities of pure polyUb. Here we describe protocols that allow the enzymatic synthesis and purification of six of the eight homotypic polyUb chains through the use of chain-specific Ub ligases and DUBs.

Ubiquitin diGLY Proteomics as an Approach to Identify and Quantify the Ubiquitin-Modified Proteome.

Protein ubiquitylation is one of the most prevalent posttranslational modifications (PTM) within cells. Ubiquitin modification of target lysine residues typically marks substrates for proteasome-dependent degradation. However, ubiquitylation can also alter protein function through modulation of protein complexes, localization, or activity, without impacting protein turnover. Taken together, ubiquitylation imparts critical regulatory control over nearly every cellular, physiological, and pathophysiological process. Affinity purification techniques coupled with quantitative mass spectrometry have been robust tools to identify PTMs on endogenous proteins. A peptide antibody-based affinity approach has been successfully utilized to enrich for and identify endogenously ubiquitylated proteins. These antibodies recognize the Lys-ϵ-Gly-Gly (diGLY) remnant that is generated following trypsin digestion of ubiquitylated proteins, and these peptides can then be identified by standard mass spectrometry approaches. This technique has led to the identification of >50,000 ubiquitylation sites in human cells and quantitative information about how many of these sites are altered upon exposure to diverse proteotoxic stressors. In addition, the diGLY proteomics approach has led to the identification of specific ubiquitin ligase targets. Here we provide a detailed method to interrogate the ubiquitin-modified proteome from any eukaryotic organism or tissue.

Thymosin fraction 5 re-evaluated after 35 years by high-resolution mass spectrometry.

OBJECTIVES: We reevaluated a lyophilized sample of thymosin fraction 5, stored for 37 years at room temperature, by high-resolution mass spectrometry in terms of stability and yet uncharacterized polypeptides that could be biological important substances. METHODS: A top-down proteomic platform based on high-performance liquid chromatography (HPLC) coupled to high-resolution LTQ-Orbitrap mass spectrometry (MS) was applied to molecular characterization of polypeptides present in thymosin fraction 5. RESULTS: We detected more than 100 monoisotopic masses corresponding to thymosin ß4 and truncated forms of ubiquitin, prothymosin α, thymosin ß4, and thymosin ß9. Additionally, we discovered a new polypeptide present in thymosin fraction 5 and identified it as intact SH3 domain-binding glutamic acid-rich-like protein 3. CONCLUSION: In spite of the well-known proteolytic processes inherent to the preparation of thymosin fraction 5, still uncharacterized polypeptides as well as truncated forms of already well-known thymosins are present in fraction 5 after long-term storage. Therefore, continuing characterization of thymosin fraction 5 is even nowadays highly promising.

Purification of Unanchored Polyubiquitin Chains from Influenza Virions.

Influenza A virus (IAV) is an enveloped virus with a segmented single-stranded negative-strand RNA genome. In general, the role of virally encapsidated host cell proteins in the viral life cycle is unclear. The virion contains abundant ubiquitin molecules some of which have been identified as unanchored polyubiquitin chains. These ubiquitin chains have been postulated to play a role in recruiting histone deacetylase 6 (HDAC6) to the cytosolic surface of late endosomes (LEs), promoting IAV uncoating via aggresome processing-a cellular machinery that disposes of protein waste. HDAC6, a class II HDAC, is unusual because it resides mostly in the cytosol instead of the nucleus. It is a unique protein consisting of two catalytic domains (CDs) and a zinc-finger ubiquitin-binding domain (ZnF-UBP) close to its C-terminus. This ZnF-UBP recognizes the unconjugated ubiquitin C-terminus (di-Gly motif) with very high affinity. Biochemical analyses showed that free di-Gly motifs are present in the form of unanchored ubiquitin inside IAV virions. These motifs are exposed following low pH-triggered viral fusion at the LEs and attract HDAC6 transiently to the cytosolic surface of vesicles. The binding of the two components promotes viral uncoating via HDAC6 interaction with cellular motor proteins dynein and myosin II and the viral M1 capsid. The cellular mechanism involved is related to aggresome processing, a pathway that promotes degradation of misfolded protein aggregates. K63-linked ubiquitin chains are thought to be the trigger for aggresome processing, though it is still not clear whether such types of chains are prevalent within the IAV capsid. Here, we present methods using purified ZnF-UBP domain of HDAC6 to immunoprecipitate viral unanchored ubiquitin chains, which can then be used for further biochemical analyses of ubiquitin chain linkage.

Hydrazide Mimics for Protein Lysine Acylation To Assess Nucleosome Dynamics and Deubiquitinase Action.

A range of acyl-lysine (acyl-Lys) modifications on histones and other proteins have been mapped over the past decade but for most, their functional and structural significance remains poorly characterized. One limitation in the study of acyl-Lys containing proteins is the challenge of producing them or their mimics in site-specifically modified forms. We describe a cysteine alkylation-based method to install hydrazide mimics of acyl-Lys post-translational modifications (PTMs) on proteins. We have applied this method to install mimics of acetyl-Lys, 2-hydroxyisobutyryl-Lys, and ubiquityl-Lys that could be recognized selectively by relevant acyl-Lys modification antibodies. The acyl-Lys modified histone H3 proteins were reconstituted into nucleosomes to study nucleosome dynamics and stability as a function of modification type and site. We also installed a ubiquityl-Lys mimic in histone H2B and generated a diubiquitin analog, both of which could be cleaved by deubiquitinating enzymes. Nucleosomes containing the H2B ubiquityl-Lys mimic were used to study the SAGA deubiquitinating module's molecular recognition. These results suggest that acyl-Lys mimics offer a relatively simple and promising strategy to study the role of acyl-Lys modifications in the function, structure, and regulation of proteins and protein complexes.

Hydrolysate from a mixture of legume flours with antifungal activity as an ingredient for prolonging the shelf-life of wheat bread.

Aiming at identifying antifungal compounds from plant matrices to be used as ingredients in the bakery industry, a water/salt-soluble extract (WSE) was produced from a legume enzyme hydrolysate, consisting of a mixture of pea, lentil, and faba bean flours, and assayed towards Penicillium roqueforti DPPMAF1. Agar diffusion assays allowed the selection of the optimal processing conditions for hydrolysis. As shown by hyphal radial growth rate, the inhibition was observed towards several fungi, including Aspergillus parasiticus CBS971.97, Penicillium carneum CBS 112297, Penicillium paneum CBS 101032, Penicillium polonicum 112490. A multi-step purification was carried out to identify the active compounds. The antifungal activity was attributed to native proteins (nsLTP, ubiquitin, lectin alpha-1 chain, wound-induced basic protein, defensin-1, defensin-2) and a mixture of peptides, which were released during hydrolysis. Nine peptides were purified and identified as sequences encrypted in legume vicilins, lectins and chitinases. WSE was used as ingredient for making bread under pilot plant conditions. Chemical, structural and sensory characterization of bread showed the lack of significant changes compared to control. The bread made with the legume hydrolysate had a longer shelf-life than that of the control.

Method for the Purification of Endogenous Unanchored Polyubiquitin Chains.

Unanchored polyubiquitin chains are endogenous non-substrate linked ubiquitin polymers which have emerging roles in the control of cellular physiology. We describe an affinity purification method based on an isolated ubiquitin-binding domain, the ZnF_UBP domain of the deubiquitinating enzyme USP5, which permits the selective purification of mixtures of endogenous unanchored polyubiquitin chains that are amenable to downstream molecular analyses. Further, we present methods for detection of unanchored polyubiquitin chains in purified fractions.

Significant Heterogeneity and Slow Dynamics of the Unfolded Ubiquitin Detected by the Line Confocal Method of Single-Molecule Fluorescence Spectroscopy.

The conformation and dynamics of the unfolded state of ubiquitin doubly labeled regiospecifically with Alexa488 and Alexa647 were investigated using single-molecule fluorescence spectroscopy. The line confocal fluorescence detection system combined with the rapid sample flow enabled the characterization of unfolded proteins at the improved structural and temporal resolutions compared to the conventional single-molecule methods. In the initial stage of the current investigation, however, the single-molecule Förster resonance energy transfer (sm-FRET) data of the labeled ubiquitin were flawed by artifacts caused by the adsorption of samples to the surfaces of the fused-silica flow chip and the sample delivery system. The covalent coating of 2-methacryloyloxyethyl phosphorylcholine polymer to the flow chip surface was found to suppress the artifacts. The sm-FRET measurements based on the coated flow chip demonstrated that the histogram of the sm-FRET efficiencies of ubiquitin at the native condition were narrowly distributed, which is comparable to the probability density function (PDF) expected from the shot noise, demonstrating the structural homogeneity of the native state. In contrast, the histogram of the sm-FRET efficiencies of the unfolded ubiquitin obtained at a time resolution of 100 µs was distributed significantly more broadly than the PDF expected from the shot noise, demonstrating the heterogeneity of the unfolded state conformation. The variety of the sm-FRET efficiencies of the unfolded state remained even after evaluating the moving average of traces with a window size of 1 ms, suggesting that conformational averaging of the heterogeneous conformations mostly occurs in the time domain slower than 1 ms. Local structural heterogeneity around the labeled fluorophores was inferred as the cause of the structural heterogeneity. The heterogeneity and slow dynamics revealed by the line confocal tracking of sm-FRET might be common properties of the unfolded proteins.

Measuring APC/C-Dependent Ubiquitylation In Vitro.

The anaphase-promoting complex/cyclosome (APC/C) is a 1.2 MDa ubiquitin ligase complex with important functions in both proliferating and post-mitotic differentiated cells. In proliferating cells, APC/C controls cell cycle progression by targeting inhibitors of chromosome segregation and mitotic exit for degradation by the 26S proteasome. To understand how APC/C recruits and ubiquitylates its substrate proteins and how these processes are controlled, it is essential to analyze APC/C activity in vitro. In the past, such experiments have been limited by the fact that large quantities of purified APC/C were difficult to obtain and that mutated versions of the APC/C could not be easily generated. In this chapter we review recent advances in generating and purifying recombinant forms of the human APC/C and its co-activators, using methods that are scalable and compatible with mutagenesis. We also describe a method that allows the quantitative analysis of APC/C activity using fluorescently labeled substrate proteins.

Use of fluorescence spectroscopy for quantitative investigations of ubiquitin interactions with the ubiquitin-binding domains of NEMO.

Ubiquitin serves as a signal for a variety of cellular processes and its specific interaction with ubiquitin-binding domain (UBD) regulates key cellular events including protein degradation, cell-cycle control, DNA repair, and kinase activation. Several binding mechanisms for isolated UBDs have been reported in recent years. However, little is known about the mechanism through which proteins containing multiple-UBDs achieve specificity for a particular oligomer of polyUb. The NF-κB essential modulator (NEMO, also known IKKγ), which plays a key role in the NF-κB signaling pathway, belongs to the latter family of proteins since it contains two distal NOA (also known UBAN/CC2-LZ/NUB) and ZF UBDs, separated by an unstructured proline-rich linker of about 40 residues in length. Here, we show a new procedure for fast purification of this bipartite domain. We also describe the use of intrinsic fluorescence spectroscopy for quantitative investigations of ubiquitin interactions between two distal ubiquitin-binding domains of NEMO (NOA and ZF). This spectroscopic method has many advantages over other techniques like GST pulldown and Biacore's SPR for monitoring avid interactions between two UBDs, especially when UBDs are located at significant distance from each other within the protein.

KAHA ligations that form aspartyl aldehyde residues as synthetic handles for protein modification and purification.

Aldehydes are widely recognized as valuable synthetic handles for the chemoselective manipulation of peptides and proteins. In this report, we show that peptides and small proteins containing the aspartic acid semialdehyde (Asa) side chain can be easily prepared by a chemoselective amide-forming ligation that results in the formation of the Asa residue at the ligation site. This strategy employs the α-ketoacid-hydroxylamine (KAHA) ligation in combination with a new isoxazolidine monomer that forms a side-chain aldehyde upon ligation. This monomer is easily prepared on a preparative scale by a catalytic, enantioselective approach and is readily introduced onto the N-terminus of a peptide segment by solid phase peptide synthesis. The ligated product can be further functionalized by bioorthogonal reactions between the aldehyde residue and alkoxyamines or hydrazides. We demonstrated that glucagon aldehyde, an unprotected 29-mer peptide prepared by KAHA ligation, can be site specifically and chemoselectively modified with biotin, dyes, aliphatic oximes, and hydroxylamines. We further describe a simple and high recovery one-step purification process based on the capture of a 29-mer glucagon aldehyde and a 76-mer ubiquitin aldehyde by an alkoxyamine-functionalized polyethylene glycol resin. The peptide or protein was released from the resin by addition of a hydroxylamine to provide the corresponding oximes.

Profiling lysine ubiquitination by selective enrichment of ubiquitin remnant-containing peptides.

Protein ubiquitination plays critical roles in many biological processes. However, functional studies of protein ubiquitination in eukaryotic cells are limited by the ability to identify protein ubiquitination sites. Unbiased high-throughput screening methods are necessary to discover novel ubiquitination sites that play important roles in cellular regulation. Here, we describe an immunopurification approach that enriches ubiquitin remnant-containing peptides to facilitate downstream mass spectrometry (MS) identification of lysine ubiquitination sites. This approach can be utilized to identify ubiquitination sites from proteins in a complex mixture.