Role of SUMO in RNF4-mediated promyelocytic leukemia protein (PML) degradation: sumoylation of PML and phospho-switch control of its SUMO binding domain dissected in living cells.

Promyelocytic leukemia protein (PML) is a tumor suppressor acting as the organizer of subnuclear structures called PML nuclear bodies (NBs). Both covalent modification of PML by the small ubiquitin-like modifier (SUMO) and non-covalent binding of SUMO to the PML SUMO binding domain (SBD) are necessary for PML NB formation and maturation. PML sumoylation and proteasome-dependent degradation induced by the E3 ubiquitin ligase, RNF4, are enhanced by the acute promyelocytic leukemia therapeutic agent, arsenic trioxide (As2O3). Here, we established a novel bioluminescence resonance energy transfer (BRET) assay to dissect and monitor PML/SUMO interactions dynamically in living cells upon addition of therapeutic agents. Using this sensitive and quantitative SUMO BRET assay that distinguishes PML sumoylation from SBD-mediated PML/SUMO non-covalent interactions, we probed the respective roles of covalent and non-covalent PML/SUMO interactions in PML degradation and interaction with RNF4. We found that, although dispensable for As2O3-enhanced PML sumoylation and RNF4 interaction, PML SBD core sequence was required for As2O3- and RNF4-induced PML degradation. As confirmed with a phosphomimetic mutant, phosphorylation of a stretch of serine residues, contained within PML SBD was needed for PML interaction with SUMO-modified protein partners and thus for NB maturation. However, mutation of these serine residues did not impair As2O3- and RNF4-induced PML degradation, contrasting with the known role of these phosphoserine residues for casein kinase 2-promoted PML degradation. Altogether, these data suggest a model whereby sumoylation- and SBD-dependent PML oligomerization within NBs is sufficient for RNF4-mediated PML degradation and does not require the phosphorylation-dependent association of PML with other sumoylated partners.

Sumoylation of the transcriptional intermediary factor 1beta (TIF1beta), the Co-repressor of the KRAB Multifinger proteins, is required for its transcriptional activity and is modulated by the KRAB domain.

Small ubiquitin-related modifier (SUMO) has emerged as a key post-translational modulator of protein functions. Here we show that TIF1beta, a developmental regulator proposed to act as a universal co-repressor for the large family of KRAB domain-containing zinc finger proteins, is a heavily SUMO-modified substrate. A combined analysis of deletion and punctual mutants identified TIF1beta as a multilysine acceptor for SUMO which specifically targets six lysine residues (Lys(554), Lys(575), Lys(676), Lys(750), Lys(779), and Lys(804)) within the TIF1beta C-terminal repressive region. Reporter gene assays indicate that TIF1beta requires SUMO-modification for its repressive activity. Indeed, sumoylation-less mutants failed to recapitulate TIF1beta-dependent repression. TIF1beta homodimerization properties and interaction with the KRAB domain are preserved in the mutants with lysine to arginine substitutions as confirmed by in vivo bioluminescence resonance energy transfer (BRET). Using histone deacetylase (HDAC) inhibitors, we also demonstrate that TIF1beta sumoylation is a prerequisite for the recruitment of HDAC and that TIF1beta SUMO-dependent repressive activity involves both HDAC-dependent and HDAC-independent components. Finally, we report that, in addition to relying on the integrity of its PHD finger and on its self-oligomerization, TIF1beta sumoylation is positively regulated by its interaction with KRAB domain-containing proteins. Altogether, our results provide new mechanistic insights into TIF1beta transcriptional repression and suggest that KRAB multifinger proteins not only recruit TIF1beta co-repressor to target genes but also increase its repressive activity through enhancement of its sumoylation.

Oligomerization of transcriptional intermediary factor 1 regulators and interaction with ZNF74 nuclear matrix protein revealed by bioluminescence resonance energy transfer in living cells.

Transcriptional intermediary factor 1 (TIF1) alpha and KAP-1/TIF1beta, two members of the TIF1 family of nuclear cofactors, are ubiquitous co-regulators of nuclear receptors and KRAB motif-containing zinc finger transcription factors, respectively. Despite the functional evidence suggesting a role for TIF1 proteins as modulators of transcription, the study of their interactions with transcriptional machineries in physiologically relevant systems has been difficult. Here, we have developed a bioluminescence resonance energy transfer (BRET) biophysical approach to study protein-protein interactions in the nuclear compartment of living mammalian cells. We report that TIF1alpha and KAP-1 form homo- and hetero-oligomers in intact mammalian cells. BRET titration experiments indicate that both homo- and hetero-oligomers occur with relatively high affinity suggesting that they could co-exist in cells. Furthermore, we demonstrate that KAP-1 but not TIF1alpha interacts with the KRAB multifinger ZNF74 in the nuclear matrix. Splice variants and point mutants of ZNF74 that lack transcriptional activity were found not to interact with KAP-1 confirming the physiological importance of this interaction in living cells. The interaction of ZNF74 with KAP-1 did not prevent KAP-1 homomerization indicating that the oligomers most likely represent the transcriptionally active species. Furthermore, the detection of ternary ZNF74.KAP-1.TIF1alpha complexes suggests the existence of cross-talk between KAP-1-interacting KRAB proteins and TIF1alpha-interacting nuclear receptors. In addition to providing new insights into the molecular interactions involved in the transcriptional activities of these proteins, this study shows that BRET can be advantageously used as a non-transcription-based oligomerization detection system to study the interaction of transcriptionally active proteins, including nuclear matrix proteins, in living cells.