Evidence for Covalent Modification of the Nuclear Dot–associated Proteins PML and Sp100 by PIC1/SUMO-1

PML and Sp100 proteins are associated with nuclear domains, known as nuclear dots (NDs). They were discovered in the context of leukemic transformation and as an autoantigen in primary biliary cirrhosis, respectively. Both proteins are expressed in the form of many COOH-terminally spliced variants, and their expression is enhanced by interferons (IFN). The recent finding that PIC1/SUMO-1, a small ubiquitin-like protein, is covalently linked to the RanGAP1 protein of the nuclear pore complex and also binds PML in yeast cells led us to determine whether PML is covalently modified by PIC1/SUMO-1 and whether the same is true for Sp100. We found an immune reaction of PML and Sp100 proteins with a PIC1/SUMO-1–specific monoclonal antibody by immunoblotting when using cell extracts prepared from stably transfected cells inducibly expressing one isoform of each protein as well as from nontransfected cells. In contrast, both proteins did not react when synthesized in vitro. Immunofluorescence staining showed that PIC1/SUMO-1 colocalized with Sp100 and PML in NDs except in mitotic cells, in which PML and Sp100 are dissociated. Cell fractionation and immunoblotting demonstrated that PIC1/SUMO-1 immunoreactive Sp100 in IFN-treated and untreated cells was exclusively nuclear, whereas nonmodified Sp100 was also found in the cytoplasm. Taken together, these data strongly suggest covalent modification of specific nuclear isoforms of Sp100 and PML by PIC1/SUMO-1. This modification may play a regulatory role in ND structure, composition, and function.     

Viral immediate-early proteins abrogate the modification by SUMO-1 of PML and Sp100 proteins, correlating with nuclear body disruption

PML nuclear bodies (NBs) are subnuclear structures whose integrity is compromised in certain human diseases, including leukemia and neurodegenerative disorders. Infection by a number of DNA viruses similarly triggers the reorganization of these structures, suggesting an important role for the NBs in the viral infection process. While expression of the adenovirus E4 ORF3 protein leads to only a moderate redistribution of PML to filamentous structures, the herpes simplex virus (HSV) ICP0 protein and the cytomegalovirus (CMV) IE1 protein both induce a complete disruption of the NB structure. Recently, we and others have shown that the NB proteins PML and Sp100 are posttranslationally modified by covalent linkage with the ubiquitin-related SUMO-1 protein and that this modification may promote the assembly of these structures. Here we show that the HSV ICP0 and CMV IE1 proteins specifically abrogate the SUMO-1 modification of PML and Sp100, whereas the adenovirus E4 ORF3 protein does not affect this process. The potential of ICP0 and IE1 to alter SUMO-1 modification is directly linked to their capacity to disassemble NBs, thus strengthening the role for SUMO-1 conjugation in maintenance of the structural integrity of the NBs. This observation supports a model in which ICP0 and IE1 disrupt the NBs either by preventing the formation or by degrading of the SUMO-1-modified PML and Sp100 protein species. Finally, we show that the IE1 protein itself is a substrate for SUMO-1 modification, thus representing the first viral protein found to undergo this new type of posttranslational modification.     

The nuclear dot protein sp100, characterization of domains necessary for dimerization, subcellular localization, and modification by small ubiquitin-like modifiers

The Sp100 and promyelocytic leukemia proteins (PML) are constituents of nuclear domains, known as nuclear dots (NDs) or PML bodies, and are both covalently modified by the small ubiquitin-related protein SUMO-1. NDs play a role in autoimmunity, virus infections, and in the etiology of acute promyelocytic leukemia. To date, little is known about the function of the Sp100 protein. Here we analyzed Sp100 domains that determine its subcellular localization, dimerization, and SUMOylation. A functional nuclear localization signal and an ND-targeting region that coincides with an Sp100 homodimerization domain were mapped. Sequences similar to the Sp100 homodimerization/ND-targeting region occur in several other proteins and constitute a novel protein motif, termed HSR domain. The lysine residue of the Sp100 protein, to which SUMO-1 is covalently linked, was mapped within and may therefore modulate the previously described HP1 protein-binding site. A consensus sequence for SUMOylation of proteins in general is suggested. SUMOylation strictly depended on a functional nuclear localization signal but was not necessary for nuclear import or ND targeting. A three-dimensional structure of Sp100, which supports the mapping data and provides additional information on Sp100 structure/function relationships, was generated by computer modeling. Taken together, our studies indicate the existence of well defined Sp100 domains with functions in ND targeting, nuclear import, nuclear SUMOylation, and protein-protein interaction.     

Sumoylation of specificity protein 1 augments its degradation by changing the localization and increasing the specificity protein 1 proteolytic process

Although specificity protein 1 (Sp1) accumulation has been found in various tumor strains, its mechanism is still not very clear. Herein, we found that modification of Sp1 by SUMO-1 facilitates Sp1 degradation. Our findings revealed that, although the amounts of Sp1 and Sp1 mutant (K16R) [Sp1(K16R)] mRNA in cells were equal, the protein level of Sp1(K16R) was higher than that of wild-type Sp1. We also proved that this sumoylation site was not the residue at which ubiquitination occurred. Invitro and in vivo pull-down assays revealed that more sumoylated Sp1 was localized in the cytoplasm, and the interaction between SUMO-1-Sp1 and the proteasome subunit rpt6 in HeLa cells was enhanced. In addition, although Sp1 accumulated in the tumorous cervical tissue, it was not prone to sumoylation. Finally, by overexpression of HA (hemagglutinin)-SUMO-1-Sp1-myc, HA-Sp1-myc, and HA-Sp1(K16R), we found that modification of Sp1 by SUMO-1 was important for Sp1 proteolysis. In conclusion, modification of Sp1 by SUMO-1 altered its localization and then increased its interaction with rpt6. This interaction increased the efficiency of Sp1 proteolytic processing and ubiquitination and then resulted in Sp1 degradation. Therefore, sumoylation of Sp1 is attenuated during tumorigenesis in order to increase Sp1 stability.