Alternative splicing of the SUMO1/2/3 transcripts affects cellular SUMOylation and produces functionally distinct SUMO protein isoforms.

Substantial increases in the conjugation of the main human SUMO paralogs, SUMO1, SUMO2, and SUMO3, are observed upon exposure to different cellular stressors, and such increases are considered important to facilitate cell survival to stress. Despite their critical cellular role, little is known about how the levels of the SUMO modifiers are regulated in the cell, particularly as it relates to the changes observed upon stress. Here we characterize the contribution of alternative splicing towards regulating the expression of the main human SUMO paralogs under normalcy and three different stress conditions, heat-shock, cold-shock, and Influenza A Virus infection. Our data reveal that the normally spliced transcript variants are the predominant mature mRNAs produced from the SUMO genes and that the transcript coding for SUMO2 is by far the most abundant of all. We also provide evidence that alternatively spliced transcripts coding for protein isoforms of the prototypical SUMO proteins, which we refer to as the SUMO alphas, are also produced, and that their abundance and nuclear export are affected by stress in a stress- and cell-specific manner. Additionally, we provide evidence that the SUMO alphas are actively synthesized in the cell as their coding mRNAs are found associated with translating ribosomes. Finally, we provide evidence that the SUMO alphas are functionally different from their prototypical counterparts, with SUMO1α and SUMO2α being non-conjugatable to protein targets, SUMO3α being conjugatable but targeting a seemingly different subset of protein from those targeted by SUMO3, and all three SUMO alphas displaying different cellular distributions from those of the prototypical SUMOs. Thus, alternative splicing appears to be an important contributor to the regulation of the expression of the SUMO proteins and the cellular functions of the SUMOylation system.

Complete Genome Sequences of Arthrobacter Phages Beans, Franzy, Jordan, Piccoletto, Shade, and Timinator.

We report here the genome sequences of six newly isolated bacteriophages infecting Arthrobacter sp. ATCC 21022. All six have myoviral morphologies and have double-stranded DNA genomes with circularly permuted ends. The six phages are closely related with average nucleotide identities of 73.4 to 93.0% across genomes lengths of 49,797 to 51,347 bp.

Expression and in vitro functional analyses of recombinant Gam1 protein.

Gam1, an early gene product of an avian adenovirus, is essential for viral replication. Gam1 is the first viral protein found to globally inhibit cellular SUMOylation, a critical posttranslational modification that alters the function and cellular localization of proteins. The interaction details at the interface between Gam1 and its cellular targets remain unclear due to the lack of structural information. Although Gam1 has been previously characterized, the purity of the protein was not suitable for structural investigations. In the present study, the gene of Gam1 was cloned and expressed in various bacterial expression systems to obtain pure and soluble recombinant Gam1 protein for in vitro functional and structural studies. While Gam1 was insoluble in most expression systems tested, it became soluble when it was expressed as a fusion protein with trigger factor (TF), a ribosome associated bacterial chaperone, under the control of a cold shock promoter. Careful optimization indicates that both low temperature induction and the chaperone function of TF play critical roles in increasing Gam1 solubility. Soluble Gam1 was purified to homogeneity through sequential chromatography techniques. Monomeric Gam1 was obtained via size exclusion chromatography and analyzed by dynamic light scattering. The SUMOylation inhibitory function of the purified Gam1 was confirmed in an in vitro assay. These results have built the foundation for further structural investigations that will broaden our understanding of Gam1's roles in viral replication.

SUMOylation affects the interferon blocking activity of the influenza A nonstructural protein NS1 without affecting its stability or cellular localization.

Our pioneering studies on the interplay between the small ubiquitin-like modifier (SUMO) and influenza A virus identified the nonstructural protein NS1 as the first known SUMO target of influenza virus and one of the most abundantly SUMOylated influenza virus proteins. Here, we further characterize the role of SUMOylation for the A/Puerto Rico/8/1934 (PR8) NS1 protein, demonstrating that NS1 is SUMOylated not only by SUMO1 but also by SUMO2/3 and mapping the main SUMOylation sites in NS1 to residues K219 and K70. Furthermore, by using SUMOylatable and non-SUMOylatable forms of NS1 and an NS1-specific artificial SUMO ligase (ASL) that increases NS1 SUMOylation ~4-fold, we demonstrate that SUMOylation does not affect the stability or cellular localization of PR8 NS1. However, NS1's ability to be SUMOylated appears to affect virus multiplication, as indicated by the delayed growth of a virus expressing the non-SUMOylatable form of NS1 in the interferon (IFN)-competent MDCK cell line. Remarkably, while a non-SUMOylatable form of NS1 exhibited a substantially diminished ability to neutralize IFN production, increasing NS1 SUMOylation beyond its normal levels also exerted a negative effect on its IFN-blocking function. This observation indicates the existence of an optimal level of NS1 SUMOylation that allows NS1 to achieve maximal activity and suggests that the limited amount of SUMOylation normally observed for most SUMO targets may correspond to an optimal level that maximizes the contribution of SUMOylation to protein function. Finally, protein cross-linking data suggest that SUMOylation may affect NS1 function by regulating the abundance of NS1 dimers and trimers in the cell.

Analysis of global sumoylation changes occurring during keratinocyte differentiation.

Sumoylation is a highly dynamic process that plays a role in a multitude of processes ranging from cell cycle progression to mRNA processing and cancer. A previous study from our lab demonstrated that SUMO plays an important role in keratinocyte differentiation. Here we present a new method of tracking the sumoylation state of proteins by creating a stably transfected HaCaT keratinocyte cell line expressing an inducible SNAP-SUMO3 protein. The SNAP-tag allows covalent fluorescent labeling that is denaturation resistant. When combined with two-dimensional gel electrophoresis, the SNAP-tag technology provides direct visualization of sumoylated targets and can be used to follow temporal changes in the global cohort of sumoylated proteins during dynamic processes such as differentiation. HaCaT keratinocyte cells expressing SNAP-SUMO3 displayed normal morphological and biochemical features that are consistent with typical keratinocyte differentiation. SNAP-SUMO3 also localized normally in these cells with a predominantly nuclear signal and some minor cytoplasmic staining, consistent with previous reports for untagged SUMO2/3. During keratinocyte differentiation the total number of proteins modified by SNAP-SUMO3 was highest in basal cells, decreased abruptly after induction of differentiation, and slowly rebounded beginning between 48 and 72 hours as differentiation progressed. However, within this overall trend the pattern of change for individual sumoylated proteins was highly variable with both increases and decreases in amount over time. From these results we conclude that sumoylation of proteins during keratinocyte differentiation is a complex process which likely reflects and contributes to the biochemical changes that drive differentiation.

X-linked inhibitor of apoptosis protein (XIAP) mediates cancer cell motility via Rho GDP dissociation inhibitor (RhoGDI)-dependent regulation of the cytoskeleton.

X-linked inhibitor of apoptosis protein (XIAP) overexpression has been found to be associated with malignant cancer progression and aggression in individuals with many types of cancers. However, the molecular basis of XIAP in the regulation of cancer cell biological behavior remains largely unknown. In this study, we found that a deficiency of XIAP expression in human cancer cells by either knock-out or knockdown leads to a marked reduction in ß-actin polymerization and cytoskeleton formation. Consistently, cell migration and invasion were also decreased in XIAP-deficient cells compared with parental wild-type cells. Subsequent studies demonstrated that the regulation of cell motility by XIAP depends on its interaction with the Rho GDP dissociation inhibitor (RhoGDI) via the XIAP RING domain. Furthermore, XIAP was found to negatively regulate RhoGDI SUMOylation, which might affect its activity in controlling cell motility. Collectively, our studies provide novel insights into the molecular mechanisms by which XIAP regulates cancer invasion and offer a further theoretical basis for setting XIAP as a potential prognostic marker and specific target for treatment of cancers with metastatic properties.

Influenza A virus interacts extensively with the cellular SUMOylation system during infection.

SUMOylation, the post-translational conjugation of the Small Ubiquitin-like MOdifier (SUMO) to a target protein, regulates a wide array of cellular processes and plays important roles for numerous viruses during infection. However, the relevance of the cellular SUMOylation system for influenza virus infection remains mostly unexplored. We previously reported that the non-structural protein of influenza A virus NS1 is a bona fide SUMO target. Here we determine that at least four additional influenza virus proteins, namely PB1, NP, M1, and NS2, are also authentic SUMO targets, and provide data supporting that PB1, NP, and M1 are SUMOylated during viral infection. The functional relevance of SUMOylation for these proteins is supported by the observation that, despite no apparent changes in the cellular levels of the E1 and E2 SUMO enzymes, influenza viral infection leads to a global increase in cellular SUMOylation. This increase, characterized by the appearance of two new SUMOylated proteins of ∼70kDa and ∼52kDa of molecular weight, is dependent upon viral replication and cannot be recreated by interferon stimulation alone. Altogether, these observations indicate that influenza A virus interacts extensively with the cellular SUMOylation system during infection and suggest that SUMOylation plays an important role during influenza virus infection, potentially contributing to the functional diversity exhibited by influenza viral proteins.

SUMOylation of the lens epithelium-derived growth factor/p75 attenuates its transcriptional activity on the heat shock protein 27 promoter.

Lens epithelium-derived growth factor (LEDGF) proteins p75 and p52 are transcriptional coactivators that connect sequence-specific activators to the basal transcription machinery. We have found that these proteins are posttranslationally modified by SUMO (small ubiquitin-like modifier)-1 and SUMO-3. Three SUMOylation sites, K75, K250, and K254, were mapped on the shared N-terminal region of these molecules, while a fourth site, K364, was identified in the C-terminal part exclusive of LEDGF/p75. The N-terminal SUMO targets are located in evolutionarily conserved charge-rich regions that lack resemblance to the described consensus SUMOylation motif, whereas the C-terminal SUMO target is solvent exposed and situated in a typical consensus motif. SUMOylation did not affect the cellular localization of LEDGF proteins and was not necessary for their chromatin-binding ability, nor did it affect this activity. However, lysine to arginine mutations of the identified SUMO acceptor sites drastically inhibited LEDGF SUMOylation, extended the half-life of LEDGF/p75, and significantly increased its transcriptional activity on the heat shock protein 27 promoter, indicating a negative effect of SUMOylation on the transcriptional activity of LEDGF/p75. Considering that SUMOylation is known to negatively affect the transcriptional activity of all transcription factors known to transactivate heat shock protein 27 expression, these findings support the paradigm establishing SUMOylation as a global neutralizer of cellular processes upregulated upon cellular stress.

Identification of the non-structural influenza A viral protein NS1A as a bona fide target of the Small Ubiquitin-like MOdifier by the use of dicistronic expression constructs.

The cellular SUMOylation system affects the function of numerous viral proteins. Hence, the identification of novel viral targets for the Small Ubiquitin-like MOdifier (SUMO) is key to our understanding of virus-host interactions. The data obtained in this study demonstrate that the non-structural influenza A viral protein NS1A is an authentic SUMO target through the use of a dicistronic expression plasmid containing SUMO (the modifier) and Ubc9 (the SUMO-conjugating enzyme) separated by an Internal Ribosomal Entry Site (IRES). This dual expression plasmid produces a robust increase in cellular SUMOylation, therefore facilitating the characterization of cellular and viral SUMO targets. The identification of NS1A as a bona fide SUMO target suggests, for the first time, a role for SUMOylation during influenza virus infection.

Cloning the human SUMO1 promoter.

Regulation of the sumoylation system at the level of gene expression has not yet been explored. To begin to define transcriptional regulatory features, the promoter region for the SUMO1 gene was cloned from human genomic DNA and characterized. Initially, a 532 base pair fragment upstream of and including the predicted SUMO1 transcription start site (TSS) was cloned and shown to possess promoter activity. Subsequent deletion analysis showed that a smaller fragment containing 158 bp upstream of the TSS region exhibited basal promoter activity in both human and rodent cell lines. Within this basal promoter fragment, there were predicted binding sites for numerous transcription factors, including the nude mouse gene product, Whn (FoxN1). Electrophoretic mobility shift assays showed that Whn could bind to an ACGC motif adjacent to the TSR, and in transfection studies Whn stimulated a 3-fold increase in transcription from this cloned promoter in keratinocytes (HaCaT cells). Mutation of the ACGC motif abrogated both Whn binding and transcriptional activation, indicating that the Whn effect is likely due to direct interaction with this promoter element. Consistent with these observations on the cloned promoter region, Whn also modestly stimulated transcription from the endogenous, genomic SUMO1 promoter in HaCaT cells, consistent with Whn potentially playing a regulatory role for SUMO1 transcription in keratinocytes.

Signalling of the BCR is regulated by a lipid rafts-localised transcription factor, Bright.

Regulation of BCR signalling strength is crucial for B-cell development and function. Bright is a B-cell-restricted factor that complexes with Bruton's tyrosine kinase (Btk) and its substrate, transcription initiation factor-I (TFII-I), to activate immunoglobulin heavy chain gene transcription in the nucleus. Here we show that a palmitoylated pool of Bright is diverted to lipid rafts of resting B cells where it associates with signalosome components. After BCR ligation, Bright transiently interacts with sumoylation enzymes, blocks calcium flux and phosphorylation of Btk and TFII-I and is then discharged from lipid rafts as a Sumo-I-modified form. The resulting lipid raft concentration of Bright contributes to the signalling threshold of B cells, as their sensitivity to BCR stimulation decreases as the levels of Bright increase. Bright regulates signalling independent of its role in IgH transcription, as shown by specific dominant-negative titration of rafts-specific forms. This study identifies a BCR tuning mechanism in lipid rafts that is regulated by differential post-translational modification of a transcription factor with implications for B-cell tolerance and autoimmunity.

Identification of a nuclear export signal sequence for bovine papillomavirus E1 protein.

Recent studies have demonstrated nuclear export by papillomavirus E1 proteins, but the requisite export sequence(s) for bovine papillomavirus (BPV) E1 were not defined. In this report we identify three functional nuclear export sequences (NES) present in BPV E1, with NES2 being the strongest in reporter assays. Nuclear localization of BPV1 E1 was modulated by over- or under-expression of CRM1, the major cellular exportin, and export was strongly reduced by the CRM1 inhibitor, Leptomycin B, indicating that E1 export occurs primarily through a CRM1-dependent process. Consistent with the in vivo functional results, E1 bound CRM1 in an in vitro pull-down assay. In addition, sumoylated E1 bound CRM1 more effectively than unmodified E1, suggesting that E1 export may be regulated by SUMO modification. Lastly, an E1 NES2 mutant accumulated in the nucleus to a greater extent than wild-type E1, yet was defective for viral origin replication in vivo. However, NES2 exhibited no intrinsic replication defect in an in vitro replication assay, implying that nucleocytoplasmic shuttling may be required to maintain E1 in a replication competent state.

Production of sumoylated proteins using a baculovirus expression system.

Spodoptera frugiperda Sf9 cells were found to possess an active endogenous sumoylation system. However, the endogenous sumoylation machinery did not efficiently modify exogenous proteins expressed by infection with recombinant baculoviruses. To overcome this limitation, mammalian sumoylation components were introduced by co-infection with recombinant baculoviruses expressing individual protein components of the sumoylation pathway. Expression of mammalian Ubc9 plus SUMO (either SUMO1 or SUMO3) was necessary and sufficient for active sumoylation of co-infected test proteins. This system provides a simple and convenient means to produce sumoylated mammalian proteins in a eukaryotic environment. Large-scale cultures should provide quantities of sumoylated proteins sufficient for potential purification.

Sumoylation dynamics during keratinocyte differentiation.

SUMO modification regulates the activity of numerous transcription factors that have a direct role in cell-cycle progression, apoptosis, cellular proliferation, and development, but its role in differentiation processes is less clear. Keratinocyte differentiation requires the coordinated activation of a series of transcription factors, and as several crucial keratinocyte transcription factors are known to be SUMO substrates, we investigated the role of sumoylation in keratinocyte differentiation. In a human keratinocyte cell line model (HaCaT cells), Ca2+-induced differentiation led to the transient and coordinated transcriptional activation of the genes encoding crucial sumoylation system components, including SAE1, SAE2, Ubc9, SENP1, Miz-1 (PIASx beta), SUMO2 and SUMO3. The increased gene expression resulted in higher levels of the respective proteins and changes in the pattern of sumoylated substrate proteins during the differentiation process. Similarly to the HaCaT results, stratified human foreskin keratinocytes showed an upregulation of Ubc9 in the suprabasal layers. Abrogation of sumoylation by Gam1 expression severely disrupted normal HaCaT differentiation, consistent with an important role for sumoylation in the proper progression of this biological process.

Nuclear import of bovine papillomavirus type 1 E1 protein is mediated by multiple alpha importins and is negatively regulated by phosphorylation near a nuclear localization signal.

Papillomavirus DNA replication occurs in the nucleus of infected cells and requires the viral E1 protein, which enters the nuclei of host epithelial cells and carries out enzymatic functions required for the initiation of viral DNA replication. In this study, we investigated the pathway and regulation of the nuclear import of the E1 protein from bovine papillomavirus type 1 (BPV1). Using an in vitro binding assay, we determined that the E1 protein interacted with importins alpha3, alpha4, and alpha5 via its nuclear localization signal (NLS) sequence. In agreement with this result, purified E1 protein was effectively imported into the nucleus of digitonin-permeabilized HeLa cells after incubation with importin alpha3, alpha4, or alpha5 and other necessary import factors. We also observed that in vitro binding of E1 protein to all three alpha importins was significantly decreased by the introduction of pseudophosphorylation mutations in the NLS region. Consistent with the binding defect, pseudophosphorylated E1 protein failed to enter the nucleus of digitonin-permeabilized HeLa cells in vitro. Likewise, the pseudophosphorylation mutant showed aberrant intracellular localization in vivo and accumulated primarily on the nuclear envelope in transfected HeLa cells, while the corresponding alanine replacement mutant displayed the same cellular location pattern as wild-type E1 protein. Collectively, our data demonstrate that BPV1 E1 protein can be transported into the nucleus by more than one importin alpha and suggest that E1 phosphorylation by host cell kinases plays a regulatory role in modulating E1 nucleocytoplasmic localization. This phosphoregulation of nuclear E1 protein uptake may contribute to the coordination of viral replication with keratinocyte proliferation and differentiation.

Wrestling with SUMO in a new arena.

Sumoylation is a widespread posttranslational modification thought to affect primarily nuclear proteins, especially transcription factors for which sumoylation usually results in repression of their transactivational function. Recent proteomics studies have greatly expanded the cadre of known SUMO substrates, and an increasing number of cytoplasmic proteins have been identified as SUMO targets. However, very few of these cytosolic proteins have been evaluated for the functional consequences of sumoylation. Rajan et al. now demonstrate that the activity of an integral cytoplasmic membrane channel-forming protein, K2P1, is completely abrogated by sumoylation at a single lysine residue on the cytoplasmic tail. This is the first report of a plasma membrane protein as a SUMO substrate and explains the long-standing inability to demonstrate functionality of K2P1. Apparently, K2P1 is stoichiometrically sumoylated under most cellular conditions, so it is constitutively inactive until desumoylated. These observations raise several intriguing questions, including: How and where does K2P1 become sumoylated? Why, unlike most known substrates, is K2P1 so efficiently sumoylated? and, What are the signals and SUMO proteases that trigger K2P1 desumoylation? But most importantly, the report by Rajan et al. expands the functional roles attributed to sumoylation into the new arena of membrane protein functional regulation and suggests that similar mechanisms may regulate the function of other pore proteins.

A universal strategy for proteomic studies of SUMO and other ubiquitin-like modifiers.

Post-translational modification by the conjugation of small ubiquitin-like modifiers is an essential mechanism to affect protein function. Currently, only a limited number of substrates are known for most of these modifiers, thus limiting our knowledge of their role and relevance for cellular physiology. Here, we report the development of a universal strategy for proteomic studies of ubiquitin-like modifiers. This strategy involves the development of stable transfected cell lines expressing a double-tagged modifier under the control of a tightly negatively regulated promoter, the induction of the expression and conjugation of the tagged modifier to cellular proteins, the tandem affinity purification of the pool of proteins covalently modified by the tagged modifier, and the identification of the modified proteins by LC and MS. By applying this methodology to the proteomic analysis of SUMO-1 and SUMO-3, we determined that SUMO-1 and SUMO-3 are stable proteins exhibiting half-lives of over 20 h, demonstrated that sumoylation with both SUMO-1 and SUMO-3 is greatly stimulated by MG-132 and heat shock treatment, demonstrated the preferential usage of either SUMO-1 or SUMO-3 for some known SUMO substrates, and identified 122 putative SUMO substrates of which only 27 appeared to be modified by both SUMO-1 and SUMO-3. This limited overlapping in the subset of proteins modified by SUMO-1 and SUMO-3 supports that the SUMO paralogues are likely to be functionally distinct. Three of the novel putative SUMO substrates identified, namely the polypyrimidine tract-binding protein-associated splicing factor PSF, the structural microtubular component alpha-tubulin, and the GTP-binding nuclear protein Ran, were confirmed as authentic SUMO substrates. The application of this universal strategy to the identification of the pool of cellular substrates modified by other ubiquitin-like modifiers will dramatically increase our knowledge of the biological role of the different ubiquitin-like conjugations systems in the cell.

Proteins of the PIAS family enhance the sumoylation of the papillomavirus E1 protein.

Sumoylation of the papillomavirus (PV) origin binding helicase E1 protein is critical for its function. Consequently, factors modulating the sumoylation of E1 could ultimately alter the outcome of a papillomavirus infection. We investigated the role played by phosphorylation and two known SUMO E3 ligases, RanBP2 and PIAS proteins, on the sumoylation of E1. E1 sumoylation was unaffected by phosphorylation as both wild-type and pseudo-phosphorylation mutants of BPV E1 exhibited similar sumoylation profiles. RanBP2 bound to BPV E1, but not to HPV11 E1, and lacked sumoylation enhancing activity for either E1. In contrast, proteins of the PIAS family (except PIASy) bound to both BPV and HPV11 E1 and stimulated their sumoylation. The structural integrity of the RING finger domain of the PIAS proteins was required for their E3 SUMO ligase activity on PV E1 sumoylation but was dispensable for their PV E1 binding activity. Miz1, the PIAS protein exerting the strongest E1 sumoylation enhancing activity, favored SUMO1 versus SUMO2 as the modifier and was shown to be transcribed in a keratinocyte cell line. This study indicates PIAS proteins as possible modulators of PV E1 sumoylation during papillomavirus infections.