A basis for SUMO protease specificity provided by analysis of human Senp2 and a Senp2-SUMO complex

Modification of cellular proteins by the ubiquitin-like protein SUMO is essential for nuclear metabolism and cell cycle progression in yeast. X-ray structures of the human Senp2 catalytic protease domain and of a covalent thiohemiacetal transition-state complex obtained between the Senp2 catalytic domain and SUMO-1 revealed details of the respective protease and substrate surfaces utilized in interactions between these two proteins. Comparative biochemical and structural analysis between Senp2 and the yeast SUMO protease Ulp1 revealed differential abilities to process SUMO-1, SUMO-2, and SUMO-3 in maturation and deconjugation reactions. Further biochemical characterization of the three SUMO isoforms into which an additional Gly-Gly di-peptide was inserted, or whereby the respective SUMO tails from the three isoforms were swapped, suggests a strict dependence for SUMO isopeptidase activity on residues C-terminal to the conserved Gly-Gly motif and preferred cleavage site for SUMO proteases.     

End‐joining inhibition at telomeres requires the translocase and polySUMO‐dependent ubiquitin ligase Uls1

In eukaryotes, permanent inhibition of the non‐homologous end joining (NHEJ) repair pathway at telomeres ensures that chromosome ends do not fuse. In budding yeast, binding of Rap1 to telomere repeats establishes NHEJ inhibition. Here, we show that the Uls1 protein is required for the maintenance of NHEJ inhibition at telomeres. Uls1 protein is a non‐essential Swi2/Snf2‐related translocase and a Small Ubiquitin‐related Modifier (SUMO)‐Targeted Ubiquitin Ligase (STUbL) with unknown targets. Loss of Uls1 results in telomere–telomere fusions. Uls1 requirement is alleviated by the absence of poly‐SUMO chains and by rap1 alleles lacking SUMOylation sites. Furthermore, Uls1 limits the accumulation of Rap1 poly‐SUMO conjugates. We propose that one of Uls1 functions is to clear non‐functional poly‐SUMOylated Rap1 molecules from telomeres to ensure the continuous efficiency of NHEJ inhibition. Since Uls1 is the only known STUbL with a translocase activity, it can be the general molecular sweeper for the clearance of poly‐SUMOylated proteins on DNA in eukaryotes.     

Improved prediction of malaria degradomes by supervised learning with SVM and profile kernel

The spread of drug resistance through malaria parasite populations calls for the development of new therapeutic strategies. However, the seemingly promising genomics-driven target identification paradigm is hampered by the weak annotation coverage. To identify potentially important yet uncharacterized proteins, we apply support vector machines using profile kernels, a supervised discriminative machine learning technique for remote homology detection, as a complement to the traditional alignment based algorithms. In this study, we focus on the prediction of proteases, which have long been considered attractive drug targets because of their indispensable roles in parasite development and infection. Our analysis demonstrates that an abundant and complex repertoire is conserved in five Plasmodium parasite species. Several putative proteases may be important components in networks that mediate cellular processes, including hemoglobin digestion, invasion, trafficking, cell cycle fate, and signal transduction. This catalog of proteases provides a short list of targets for functional characterization and rational inhibitor design. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users. Rui Kuang and Jianying Gu have contributed equally to this work. An erratum to this article can be found at     

Apoptosis in pre-Bilaterians: <Emphasis Type="Italic">Hydra</Emphasis> as a model

Hydra is a member of the ancient metazoan phylum Cnidaria and is an especially well investigated model organism for questions of the evolutionary origin of metazoan processes. Apoptosis in Hydra is important for the regulation of cellular homeostasis under different conditions of nutrient supply. The molecular mechanisms leading to apoptosis in Hydra are surprisingly extensive and comparable to those in mammals. Genome wide sequence analysis has revealed the presence of large caspase and Bcl-2 families, the apoptotic protease activating factor (APAF-1), inhibitors of apoptotic proteases (IAPs) and components of a putative death receptor pathway. Regulation of apoptosis in Hydra may involve BH-3 only proteins and survival pathways, possibly including insulin signalling.     

Biosynthesis of SUMOylated Proteins in Bacteria Using the Trypanosoma brucei Enzymatic System

Post-translational modification with the Small Ubiquitin-like Modifier (SUMO) is conserved in eukaryotic organisms and plays important regulatory roles in proteins affecting diverse cellular processes. In Trypanosoma brucei, member of one of the earliest branches in eukaryotic evolution, SUMO is essential for normal cell cycle progression and is likely to be involved in the epigenetic control of genes crucial for parasite survival, such as those encoding the variant surface glycoproteins. Molecular pathways modulated by SUMO have started to be discovered by proteomic studies; however, characterization of functional consequences is limited to a reduced number of targets. Here we present a bacterial strain engineered to produce SUMOylated proteins, by transferring SUMO from T. brucei together with the enzymes essential for its activation and conjugation. Due to the lack of background in E. coli, this system is useful to express and identify SUMOylated proteins directly in cell lysates by immunoblotting, and SUMOylated targets can be eventually purified for biochemical or structural studies. We applied this strategy to describe the ability of TbSUMO to form chains in vitro and to detect SUMOylation of a model substrate, PCNA both from Saccharomyces cerevisiae and from T. brucei. To further validate targets, we applied an in vitro deconjugation assay using the T. brucei SUMO-specific protease capable to revert the pattern of modification. This system represents a valuable tool for target validation, mutant generation and functional studies of SUMOylated proteins in trypanosomatids.     

The Anaplasma phagocytophilum effector AmpA hijacks host cell SUMOylation

SUMOylation, the covalent attachment of a member of the small ubiquitin‐like modifier (SUMO) family of proteins to lysines in target substrates, is an essential post‐translational modification in eukaryotes. Microbial manipulation of SUMOylation recently emerged as a key virulence strategy for viruses and facultative intracellular bacteria, the latter of which have only been shown to deploy effectors that negatively regulate SUMOylation. Here, we demonstrate that the obligate intracellular bacterium, Anaplasma phagocytophilum, utilizes an effector, AmpA (A. phagocytophilum post‐translationally modified protein A) that becomes SUMOylated in host cells and this is important for the pathogen's survival. We previously discovered that AmpA (formerly APH1387) localizes to the A. phagocytophilum‐occupied vacuolar membrane (AVM). Algorithmic prediction analyses denoted AmpA as a candidate for SUMOylation. We verified this phenomenon using a SUMO affinity matrix to precipitate both native AmpA and ectopically expressed green fluorescent protein (GFP)‐tagged AmpA. SUMOylation of AmpA was lysine dependent, as SUMO affinity beads failed to precipitate a GFP‐AmpA protein when its lysine residues were substituted with arginine. Ectopically expressed and endogenous AmpA were poly‐SUMOylated, which was consistent with the observation that AmpA colocalizes with SUMO2/3 at the AVM. Only late during the infection cycle did AmpA colocalize with SUMO1, which terminally caps poly‐SUMO2/3 chains. AmpA was also detected in the cytosol of infected host cells, further supporting its secretion and likely participation in interactions that aid pathogen survival. Indeed, whereas siRNA‐mediated knockdown of Ubc9 – a necessary enzyme for SUMOylation – slightly bolstered A. phagocytophilum infection, pharmacologically inhibiting SUMOylation in infected cells significantly reduced the bacterial load. Ectopically expressed GFP‐AmpA served as a competitive agonist against native AmpA in infected cells, while lysine‐deficient GFP‐AmpA was less effective, implying that modification of AmpA lysines is important for infection. Collectively, these data show that AmpA becomes directly SUMOylated during infection, representing a novel tactic for A. phagocytophilum survival.     

Heterologous expression of OsSIZ1, a rice SUMO E3 ligase,enhances broad abiotic stress tolerance in transgenic creeping bentgrass

Sumoylation is a posttranslational regulatory process in higher eukaryotes modifying substrate proteins through conjugation of small ubiquitin‐related modifiers (SUMOs). Sumoylation modulates protein stability, subcellular localization and activity; thus, it regulates most cellular functions including response to environmental stress in plants. To study the feasibility of manipulating SUMO E3 ligase, one of the important components in the sumoylation pathway in transgenic (TG) crop plants for improving overall plant performance under adverse environmental conditions, we have analysed TG creeping bentgrass (Agrostis stolonifera L.) plants constitutively expressing OsSIZ1, a rice SUMO E3 ligase. Overexpression of OsSIZ1 led to increased photosynthesis and overall plant growth. When subjected to water deficiency and heat stress, OsSIZ1 plants exhibited drastically enhanced performance associated with more robust root growth, higher water retention and cell membrane integrity than wild‐type (WT) controls. OsSIZ1 plants also displayed significantly better growth than WT controls under phosphate‐starvation conditions, which was associated with a higher uptake of phosphate (Pi) and other minerals, such as potassium and zinc. Further analysis revealed that overexpression of OsSIZ1 enhanced stress‐induced SUMO conjugation to substrate in TG plants, which was associated with modified expression of stress‐related genes. This strongly supports a role sumoylation plays in regulating multiple molecular pathways involved in plant stress response, establishing a direct link between sumoylation and plant response to environmental adversities. Our results demonstrate the great potential of genetic manipulation of sumoylation process in TG crop species for improved resistance to broad abiotic stresses.     

The structural basis for catalysis and substrate specificity of a rhomboid protease

Rhomboids are intramembrane proteases that use a catalytic dyad of serine and histidine for proteolysis. They are conserved in both prokaryotes and eukaryotes and regulate cellular processes as diverse as intercellular signalling, parasitic invasion of host cells, and mitochondrial morphology. Their widespread biological significance and consequent medical potential provides a strong incentive to understand the mechanism of these unusual enzymes for identification of specific inhibitors. In this study, we describe the structure of Escherichia coli rhomboid GlpG covalently bound to a mechanism‐based isocoumarin inhibitor. We identify the position of the oxyanion hole, and the S₁‐ and S₂′‐binding subsites of GlpG, which are the key determinants of substrate specificity. The inhibitor‐bound structure suggests that subtle structural change is sufficient for catalysis, as opposed to large changes proposed from previous structures of unliganded GlpG. Using bound inhibitor as a template, we present a model for substrate binding at the active site and biochemically test its validity. This study provides a foundation for a structural explanation of rhomboid specificity and mechanism, and for inhibitor design.     

In Vitro Studies Reveal a Sequential Mode of Chain Processing by the Yeast SUMO (Small Ubiquitin-related Modifier)-specific Protease Ulp2

Sumoylation is a post-translational modification essential in most eukaryotes that regulates stability, localization, activity, or interaction of a multitude of proteins. It is a reversible process wherein counteracting ligases and proteases, respectively, mediate the conjugation and deconjugation of SUMO molecules to/from target proteins. Apart from attachment of single SUMO moieties to targets, formation of poly-SUMO chains occurs by the attachment of additional SUMO molecules to lysine residues in the N-terminal extensions of SUMO. In Saccharomyces cerevisiae there are apparently only two SUMO(Smt3)-specific proteases: Ulp1 and Ulp2. Ulp2 has been shown to be important for the control of poly-SUMO conjugates in cells and to dismantle SUMO chains in vitro, but the mechanism by which it acts remains to be elucidated. Applying an in vitro approach, we found that Ulp2 acts sequentially rather than stochastically, processing substrate-linked poly-SUMO chains from their distal ends down to two linked SUMO moieties. Furthermore, three linked SUMO units turned out to be the minimum length of a substrate-linked chain required for efficient binding to and processing by Ulp2. Our data suggest that Ulp2 disassembles SUMO chains by removing one SUMO moiety at a time from their ends (exo mechanism). Apparently, Ulp2 recognizes surfaces at or near the N terminus of the distal SUMO moiety, as attachments to this end significantly reduce cleavage efficiency. Our studies suggest that Ulp2 controls the dynamic range of SUMO chain lengths by trimming them from the distal ends.     

SUMO conjugation in plants

Covalent attachment of small proteins to substrates can regulate protein activity in eukaryotes. SUMO, the small ubiquitin-related modifier, can be covalently linked to a broad spectrum of substrates. An understanding of SUMOs role in plant biology is still in its infancy. In this review, we briefly summarize the enzymology of SUMO conjugation (sumoylation), and the current knowledge of SUMO modification in Arabidopsis thaliana (L.) Heynh. and other plants, in comparison to animals and fungi. Furthermore, we assemble a list of potential pathway components in the genome of A. thaliana that have either been functionally defined, or are suggested by similarity to pathway components from other organisms.     

��ChopNSpice,�� a Mass Spectrometric Approach That Allows Identification of Endogenous Small Ubiquitin-like Modifier-conjugated Peptides

Conjugation of small ubiquitin-like modifier (SUMO) to substrates is involved in a large number of cellular processes. Typically, SUMO is conjugated to lysine residues within a SUMO consensus site; however, an increasing number of proteins are sumoylated on non-consensus sites. To appreciate the functional consequences of sumoylation, the identification of SUMO attachment sites is of critical importance. Discovery of SUMO acceptor sites is usually performed by a laborious mutagenesis approach or using MS. In MS, identification of SUMO acceptor sites in higher eukaryotes is hampered by the large tryptic fragments of SUMO1 and SUMO2/3. MS search engines in combination with known databases lack the possibility to search MSMS spectra for larger modifications, such as sumoylation. Therefore, we developed a simple and straightforward database search tool (“ChopNSpice”) that successfully allows identification of SUMO acceptor sites from proteins sumoylated in vivo and in vitro. By applying this approach we identified SUMO acceptor sites in, among others, endogenous SUMO1, SUMO2, RanBP2, and Ubc9.Post-translational modification with ubiquitin and ubiquitin-like modifiers (Ubls)1 such as SUMO plays an important role in most, if not all, cellular processes (1–6). Conjugation of Ubls to their targets involves an isopeptide bond between the carboxyl group of the modifier and the ε-amino group of a lysine residue within the targets. Attachment of Ubls to specific targets involves an enzymatic cascade. First the Ubls are processed to expose their C-terminal diglycine motif. The mature Ubl is then transferred to its target via a cascade of E1 (activating), E2 (conjugating), and E3 (ligase) enzymes. The conjugation system for SUMO consists of a heterodimeric activating enzyme, Aos1/Uba2; a conjugating enzyme, Ubc9; and E3 ligases, such as RanBP2 or members of the PIAS family. The conjugation status undergoes perpetual change and is governed by a small family of SUMO proteases that hydrolyze the isopeptide bond between SUMO and its target (7, 8). Although in lower eukaryotes only one SUMO is present, vertebrates express at least three different SUMO paralogs: SUMO1, SUMO2, and SUMO3. Mature SUMO2 and SUMO3 (referred to as SUMO2/3) are 97% identical but differ substantially from SUMO1 (∼50% identity).Although the list of known SUMO substrates is growing rapidly, our understanding of the functional consequences for many of these targets is lagging behind. At a molecular level, the functional consequences of SUMO conjugation can be explained by a gain or loss of interaction with other macromolecules (3, 4). SUMO-dependent intramolecular conformational changes have also been described (9, 10). Thus, to appreciate the role that SUMO plays in the regulation of specific substrates, identification of the acceptor site(s) for SUMO conjugation is of key importance.So far, identification of SUMO acceptor sites has relied largely on mutation of the SUMO consensus site, which consists of a short motif with the sequence ψKXE (ψ represents a bulky hydrophobic residue, and X represents any amino acid). This motif is recognized by Ubc9 if presented in an extended conformation (11–13). However, an increasing number of proteins, such as PCNA, E2-25K, Daxx, and USP25, turned out to be sumoylated on lysine residues that do not conform to the SUMO consensus site (14–17). For this category of proteins, as well as for proteins that contain a large number of SUMO consensus sites, the identification of acceptor lysines is a burdensome task that often involves mutagenesis of each lysine residue within the substrate in turn.MS is currently one of the state-of-the-art technologies to identify protein factors and their post-translational modifications in an unbiased and sensitive manner. Several groups have shown that, using overexpressed tagged SUMO, MS can be efficiently exploited to identify endogenous substrates for SUMO conjugation (18–20). However, the identification of SUMO acceptor lysines using MS has remained a more challenging task (18, 21, 23, 24). So far, using tagged SUMO, unbiased identification of acceptor lysines for endogenous substrates has only been observed in Saccharomyces cerevisiae (18). The identification of substrates in higher eukaryotes has been hampered by the large conjugated SUMO peptide that arises upon tryptic digestion (>2154 Da with human SUMO1 and >3568 Da with human SUMO2/3 compared with 484 Da for Smt3 in S. cerevisiae). Such large fragments, in addition to the mass of the conjugated peptide, can impede their in-gel digestion, extraction, detection, and sequencing in MS. To overcome some of these limitations, several different strategies have been developed: 1) mutation of the tryptic fragment of SUMO, yielding a smaller tryptic fragment (23), 2) development of an automated recognition pattern tool (SUMmOn) (24), and 3) identification of targets using an in vitro to in vivo approach (21). Although these approaches have been applied successfully for the identification of SUMO conjugates in vitro and in vivo, unbiased identification of SUMO conjugates in vivo has not been achieved in higher eukaryotes. Another hurdle to such identification of SUMO conjugates is the variety of masses that can theoretically arise for just one SUMO-conjugated lysine in a given protein because of tryptic miscleavages. Thus, the unambiguous identification of SUMO acceptor sites requires the mass of the modified peptide carrying the conjugated SUMO (fragment) to be measured with high accuracy, and most importantly, it requires sequence analysis of the modified peptides. Because available proteomics search engines lack the possibility to search MSMS spectra for larger modifications, e.g. those that occur upon sumoylation, we developed a novel, simple, and straightforward database search tool (“ChopNSpice”) that, in combination with current proteomics search engines (such as MASCOT (25) or SEQUEST (26)), allows one to identify SUMO1 and SUMO2/3 acceptor sites unambiguously. We confirmed this strategy in vitro on various substrates and demonstrate the power of this technique by the identification of acceptor lysines within several endogenous targets from HeLa cells.     

The role of SUMO in chromosome segregation

Chromosome segregation is an essential feature of the eukaryotic cell cycle. Efficient chromosome segregation requires the co-ordination of several cellular processes; some of which involve gross rearrangements of the overall structure of the genetic material. Recent advances in the analysis of the role of SUMO (small ubiquitin-like modifier) and in the identification of SUMO-modified targets indicate that sumoylation is likely to have several key roles in regulating chromosome segregation This mini-review summarises the recently published data concerning the role of SUMO in the processes required for efficient chromosome segregation.     

Quantitative analysis of FRET assay in biology—new developments in protein interaction affinity and protease kinetics determinations in the SUMOylation cascade

F(o)rster resonance energy transfer (FRET) techniques have been widely used in biological studies in vitro and in vivo and are powerful tools for elucidating protein interactions in many regulatory cas...