蛋白质的类泛素化修饰

SUMO(small ubiquitin-related modifier)是一类重要的类泛素蛋白,在生物进化过程中高度保守,其三维结构及生化修饰过程与泛素类似,但该两类蛋白质修饰的生物学意义却不尽相同。SUMO化修饰作为一种重要的蛋白质翻译后修饰,广泛参与细胞活动的各个方面,且SUMO化修饰异常与许多人类重大疾病密切相关。     

TRAF7 sequesters c-Myb to the cytoplasm by stimulating its sumoylation

Small ubiquitin-related modifiers (SUMOs) are proteins that are posttranslationally conjugated to diverse proteins. The c-myb proto-oncogene product (c-Myb) regulates proliferation and differentiation of hematopoietic cells. PIASy is the only known SUMO E3 ligase for c-Myb. Here, we report that TRAF7 binds to c-Myb and stimulates its sumoylation. TRAF7 bound to the DNA-binding domain of c-Myb via its WD40 repeats. TRAF7 has an E3 ubiquitin ligase activity for self-ubiquitination, but TRAF7 also stimulated the sumoylation of c-Myb at Lys-523 and Lys-499, which are the same sites as those used for PIASy-induced sumoylation. TRAF7 inhibited trans-activation induced by wild-type c-Myb, but not by the sumoylation site mutant of c-Myb. The expression of both c-myb and TRAF7 was down-regulated during differentiation of M1 cells. Endogenous TRAF7 localized to both the cytoplasm and nucleus of M1 cells. Consistent with this, significant amounts of sumoylated c-Myb were found in the cytoplasm of M1 cells, whereas nonsumoylated c-Myb was found predominantly in the nucleus. Overexpressed TRAF7 was localized in the cytoplasm of CV-1 cells, and sequestered c-Myb and SUMO1 in the cytosol, whereas PIASy was localized in the nucleus. Thus, TRAF7 negatively regulates c-Myb activity by sequestering c-Myb to the cytosol via sumoylation.     

Viruses and sumoylation: recent highlights

Since its discovery in 1997, SUMO (small ubiquitin-like modifier) has been implicated in a range of activities, indicating that this protein is as important in the cell as ubiquitin is. Although it can function throughout the cell, it appears to be involved more in nuclear functions. The growing list of substrates that are covalently modified by SUMO includes many viral proteins; SUMO appears to facilitate viral infection of cells, making it a possible target for antiviral therapies. It therefore is important to understand how viruses manipulate the cellular sumoylation system and how sumoylation affects viral functions.     

Mechanism and consequences for paralog-specific sumoylation of ubiquitin-specific protease 25

Vertebrates express two distinct families of SUMO proteins (SUMO1 and SUMO2/3) that serve distinct functions as posttranslational modifiers. Many proteins are modified specifically with SUMO1 or SUMO2/3, but the mechanisms for paralog selectivity are poorly understood. In a screen for SUMO2/3 binding proteins, we identified Ubiquitin Specific Protease 25 (USP25). USP25 turned out to also be a target for sumoylation, being more efficient with SUMO2/3. Sumoylation takes place within USP25's two ubiquitin interaction motifs (UIMs) that are required for efficient hydrolysis of ubiquitin chains. USP25 sumoylation impairs binding to and hydrolysis of ubiquitin chains. Both SUMO2/3-specific binding and sumoylation depend on a SUMO interaction motif (SIM/SBM). Seven amino acids in the SIM of USP25 are sufficient for SUMO2/3-specific binding and conjugation, even when taken out of structural context. One mechanism for paralog-specific sumoylation may, thus, involve SIM-dependent recruitment of SUMO1 or SUMO2/3 thioester-charged Ubc9 to targets.     

蛋白质SUMO化修饰研究进展

SUMO(small ubiquitin-related modifier)是类泛素蛋白家族的重要成员之一,可与多种蛋白结合发挥相应的功能,其分子结构及SUMO化反应途径都与泛素类似,但二者功能完全不同。SUMO化修饰可参与转录调节、核转运、维持基因组完整性及信号转导等多种细胞内活动,是一种重要的多功能的蛋白质翻译后修饰方式。SUMO化修饰功能的失调可能导致某些疾病的发生。     

A SIM-ultaneous role for SUMO and ubiquitin

Ubiquitin and ubiquitin-like proteins (Ubls) share a beta-GRASP fold and have key roles in cellular growth and suppression of genome instability. Despite their common fold, SUMO and ubiquitin are classically portrayed as distinct, and they can have antagonistic roles. Recently, a new family of proteins, the small ubiquitin-related modifier (SUMO)-targeted ubiquitin ligases (STUbLs), which directly connect sumoylation and ubiquitylation, has been discovered. Uniquely, STUbLs use SUMO-interaction motifs (SIMs) to recognize their sumoylated targets. STUbLs are global regulators of protein sumoylation levels, and cells lacking STUbLs display genomic instability and hypersensitivity to genotoxic stress. The human STUbL, RNF4, is implicated in several diseases including cancer, highlighting the importance of characterizing the cellular functions of STUbLs.     

SUMO modification of cell surface Kv2.1 potassium channels regulates the activity of rat hippocampal neurons

Voltage-gated Kv2.1 potassium channels are important in the brain for determining activity-dependent excitability. Small ubiquitin-like modifier proteins (SUMOs) regulate function through reversible, enzyme-mediated conjugation to target lysine(s). Here, sumoylation of Kv2.1 in hippocampal neurons is shown to regulate firing by shifting the half-maximal activation voltage (V(1/2)) of channels up to 35 mV. Native SUMO and Kv2.1 are shown to interact within and outside channel clusters at the neuronal surface. Studies of single, heterologously expressed Kv2.1 channels show that only K470 is sumoylated. The channels have four subunits, but no more than two non-adjacent subunits carry SUMO concurrently. SUMO on one site shifts V(1/2) by 15 mV, whereas sumoylation of two sites produces a full response. Thus, the SUMO pathway regulates neuronal excitability via Kv2.1 in a direct and graded manner.     

Single-Molecule Studies on PolySUMO Proteins Reveal Their Mechanical Flexibility

Proteins with β-sandwich and β-grasp topologies are resistant to mechanical unfolding as shown by single-molecule force spectroscopy studies. Their high mechanical stability has generally been associated with the mechanical clamp geometry present at the termini. However, there is also evidence for the importance of interactions other than the mechanical clamp in providing mechanical stability, which needs to be tested thoroughly. Here, we report the mechanical unfolding properties of ubiquitin-like proteins (SUMO1 and SUMO2) and their comparison with those of ubiquitin. Although ubiquitin and SUMOs have similar size and structural topology, they differ in their sequences and structural contacts, making them ideal candidates to understand the variations in the mechanical stability of a given protein topology. We observe a two-state unfolding pathway for SUMO1 and SUMO2, similar to that of ubiquitin. Nevertheless, the unfolding forces of SUMO1 (∼130 pN) and SUMO2 (∼120 pN) are lower than that of ubiquitin (∼190 pN) at a pulling speed of 400 nm/s, indicating their lower mechanical stability. The mechanical stabilities of SUMO proteins and ubiquitin are well correlated with the number of interresidue contacts present in their structures. From pulling speed-dependent mechanical unfolding experiments and Monte Carlo simulations, we find that the unfolding potential widths of SUMO1 (∼0.51 nm) and SUMO2 (∼0.33 nm) are much larger than that of ubiquitin (∼0.19 nm), indicating that SUMO1 is six times and SUMO2 is three times mechanically more flexible than ubiquitin. These findings might also be important in understanding the functional differences between ubiquitin and SUMOs.     

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.     

Broad spectrum identification of SUMO substrates in melanoma cells

Like phosphorylation, protein sumoylation likely represents a dynamic PTM to alter protein function in support of cell regulatory systems. The broad-spectrum impact of transient or chronic engagement of signal transduction cascades on protein sumoylation has not been explored. Here, we find that epidermal growth factor (EGF) stimulation evokes a rapid alteration in small ubiquitin modifier (SUMO) target selection, while oncogene expression alters steady-state SUMO-protein profiles. A proteomic SUMO target analysis in melanoma cells identified proteins involved in cellular signaling, growth control, and neural differentiation.     

Small ubiquitin-related modifier (SUMO) binding determines substrate recognition and paralog-selective SUMO modification

Small ubiquitin-related modifiers (SUMOs) regulate diverse cellular processes through their covalent attachment to target proteins. Vertebrates express three SUMO paralogs: SUMO-1, SUMO-2, and SUMO-3 (SUMO-2 and SUMO-3 are approximately 96% identical and referred to as SUMO-2/3). SUMO-1 and SUMO-2/3 are conjugated, at least in part, to unique subsets of proteins and thus regulate distinct cellular pathways. However, how different proteins are selectively modified by SUMO-1 and SUMO-2/3 is unknown. We demonstrate that BLM, the RecQ DNA helicase mutated in Bloom syndrome, is preferentially modified by SUMO-2/3 both in vitro and in vivo. Our findings indicate that non-covalent interactions between SUMO and BLM are required for modification at non-consensus sites and that preferential SUMO-2/3 modification is determined by preferential SUMO-2/3 binding. We also present evidence that sumoylation of a C-terminal fragment of HIPK2 is dependent on SUMO binding, indicating that non-covalent interactions between SUMO and target proteins provide a general mechanism for SUMO substrate selection and possible paralog-selective modification.     

A method of mapping protein sumoylation sites by mass spectrometry using a modified small ubiquitin-like modifier 1 (SUMO-1) and a computational program

Post-translational modification by small ubiquitin-like modifier 1 (SUMO-1) is a highly conserved process from yeast to humans and plays important regulatory roles in many cellular processes. Sumoylation occurs at certain internal lysine residues of target proteins via an isopeptide bond linkage. Unlike ubiquitin whose carboxyl-terminal sequence is RGG, the tripeptide at the carboxyl terminus of SUMO is TGG. The presence of the arginine residue at the carboxyl terminus of ubiquitin allows tryptic digestion of ubiquitin conjugates to yield a signature peptide containing a diglycine remnant attached to the target lysine residue and rapid identification of the ubiquitination site by mass spectrometry. The absence of lysine or arginine residues in the carboxyl terminus of mammalian SUMO makes it difficult to apply this approach to mapping sumoylation sites. We performed Arg scanning mutagenesis by systematically substituting amino acid residues surrounding the diglycine motif and found that a SUMO variant terminated with RGG can be conjugated efficiently to its target protein under normal sumoylation conditions. We developed a Programmed Data Acquisition (PDA) mass spectrometric approach to map target sumoylation sites using this SUMO variant. A web-based computational program designed for efficient identification of the modified peptides is described.     

Experimental comparison of energy landscape features of ubiquitin family proteins

Small ubiquitin-related modifiers (SUMO1 and SUMO2) are ubiquitin family proteins, structurally similar to ubiquitin, differing in terms of their amino acid sequence and functions. Therefore, they provide a great platform for investigating sequence-structure-stability-function relationship. Here, we used chemical denaturation in comparing the folding-unfolding pathways of the SUMO proteins with their structural homologue ubiquitin (UF45W-pseudo wild-type [WT] tryptophan variant) with structurally analogous tryptophan mutations (SUMO1 [S1F66W], SUMO2 [S2F62W]). Equilibrium denaturation studies report that ubiquitin is the most stable protein among the three. The observed denaturant-dependent folding rates of SUMOs are much lower than ubiquitin and primarily exhibit a two-state folding pathway unlike ubiquitin, which has a kinetic folding intermediate. We hypothesize that, as SUMO proteins start off as slow folders, they avoid stabilizing their folding intermediates and the presence of which might further slow-down their folding rates. The denaturant-dependent unfolding of ubiquitin is the fastest, followed by SUMO2, and slowest for SUMO1. However, the spontaneous unfolding rate constant is the lowest for ubiquitin (~40 times), and similar for SUMOs. This correlation between thermodynamic stability and kinetic stability is achieved by having different unfolding transition state positions with respect to the solvent-accessible surface area, as quantified by the Tanford β _u values: ubiquitin (0.42) > SUMO2 (0.20) > SUMO1 (0.16). The results presented here highlight the unique energy landscape features which help in optimizing the folding-unfolding rates within a structurally homologous protein family.     

Cytoplasmic sumoylation by PIAS-type Siz1-SUMO ligase

SUMO (small ubiquitin-related modifier), a 12 kDa protein with distant similarity to ubiquitin, covalently binds to many proteins in eukaryotic cells. In contrast to ubiquitination, which mainly regulates proteasome-dependent degradation and protein sorting, sumoylation is known to regulate assembly and disassembly of protein complexes, protein localization and stability, and so on. SUMO is primarily localized to the nucleus, and many SUMO substrates are nuclear proteins involved in DNA transaction. However, certain roles of SUMO conjugates have been shown outside the nucleus. Particularly in budding yeast, SUMO is also localized to the bud-neck in a cell cycle-dependent manner. The first and prominent SUMO substrates are septins, evolutionally conserved proteins required for cytokinesis in yeast. Recent analysis of human septin structure would greatly facilitate the study of the functions of these SUMO conjugates. SUMO modification of septins is regulated by cell cycle-dependent nuclear transport of PIAS-type Siz1 (SUMO E3) and Ulp1 desumoylation enzyme in yeast. Domains outside the SUMO-ligase core (SP-RING) of Siz1 ensure its regulations. Furthermore, newly discovered ubiquitin ligases that specifically recognize poly-SUMO conjugates could lead to degradation of SUMO conjugates. Thus, protein modifications seem to be regulated in an unexpectedly complex manner. In this review, we focus on various regulations in yeast septin sumoylation and discuss its possible functions.     

SUMO playing tag with ubiquitin

In addition to being structurally related, the protein modifiers ubiquitin and SUMO (small ubiquitin-related modifier), share a multitude of functional interrelations. These include the targeting of the same attachment sites in certain substrates, and SUMO-dependent ubiquitylation in others. Notably, several cellular processes, including the targeting of repair machinery to DNA damage sites, require the sequential sumoylation and ubiquitylation of distinct substrates. Some proteins promote both modifications. By contrast, the activity of some enzymes that control either sumoylation or ubiquitylation is regulated by the respective other modification. In this review, we summarize recent findings regarding intersections between SUMO and ubiquitin that influence genome stability and cell growth and which are relevant in pathogen resistance and cancer treatment.     

Small Peptide Binding Stiffens the Ubiquitin-like Protein SUMO1

Posttranslational modification by small ubiquitin-like modifiers (SUMOs), known as SUMOylation, is a key regulatory event in many eukaryotic cellular processes in which SUMOs interact with a large number of target proteins. SUMO binding motifs (SBMs) are small peptides derived from these target proteins that interact noncovalently with SUMOs and induce conformational changes. To determine the effect of SBMs on the mechanical properties of SUMO1 (the first member of the human SUMO family), we performed single-molecule force spectroscopy experiments on SUMO1/SBM complexes. The unfolding force of SUMO1 (at a pulling speed of 400 nm/s) increased from ∼130 pN to ∼170 pN upon binding to SBMs, indicating mechanical stabilization upon complexation. Pulling-speed-dependent experiments and Monte Carlo simulations measured a large decrease in distance to the unfolding transition state for SUMO1 upon SBM binding, which is by far the largest change measured for any ligand binding protein. The stiffness of SUMO1 (measured as a spring constant for the deformation response along the line joining the N- and C-termini) increased upon SBM binding from ∼1 N/m to ∼3.5 N/m. The relatively higher flexibility of ligand-free SUMO1 might play a role in accessing various conformations before binding to a target.     

Modulation of Abeta generation by small ubiquitin-like modifiers does not require conjugation to target proteins

The sequential processing of the APP (amyloid precursor protein) by the beta- and gamma-secretase and generation of the Abeta (amyloid-beta) peptide is a primary pathological factor in AD (Alzheimer's disease). Regulation of the processing or turnover of these proteins represents potential targets for the development of AD therapies. Sumoylation is a process by which SUMOs (small ubiquitin-like modifiers) are covalently conjugated to target proteins, resulting in a number of functional consequences. These include regulation of protein-protein interactions, intracellular trafficking and protein stability, which all have the potential to impact on several aspects of the amyloidogenic pathway. The present study examines the effects of overexpression and knockdown of the major SUMO isoforms (SUMO1, 2 and 3) on APP processing and the production of Abeta peptides. SUMO3 overexpression significantly increased Abeta40 and Abeta42 secretion, which was accompanied by an increase in full-length APP and its C-terminal fragments. These effects of SUMO3 were independent of its covalent attachment or chain formation, as mutants lacking the motifs responsible for SUMO chain formation or SUMO conjugation led to similar changes in Abeta. SUMO3 overexpression also up-regulated the expression of the transmembrane protease BACE (beta-amyloid-cleaving enzyme), but failed to affect levels of several other unrelated proteins. Suppression of SUMO1 or combined SUMO2+3 by RNA interference did not affect APP levels or Abeta production. These findings confirm a specific effect of SUMO3 overexpression on APP processing and the production of Abeta peptides but also suggest that endogenous sumoylation is not essential and likely plays an indirect role in modulating the amyloid processing pathway.