Ulla Karvonen

PIAS Proteins Modulate Transcription Factors by Functioning as SUMO-1 Ligases

ABSTRACT PIAS (protein inhibitor of activated STAT) proteins interact with and modulate the activities of various transcription factors. In this work, we demonstrate that PIAS proteins xα, xβ, 1, and 3 interact with the small ubiquitin-related modifier SUMO-1 and its E2 conjugase, Ubc9, and that PIAS proteins themselves are covalently modified by SUMO-1 (sumoylated). PIAS proteins also tether other sumoylated proteins in a noncovalent fashion. Furthermore, recombinant PIASxα enhances Ubc9-mediated sumoylation of the androgen receptor and c-Jun in vitro. Importantly, PIAS proteins differ in their abilities to promote sumoylation in intact cells. The ability to stimulate protein sumoylation and the interaction with sumoylated proteins are dependent on the conserved PIAS RING finger-like domain. These functions are linked to the activity of PIASxα on androgen receptor-dependent transcription. Collectively, our results imply that PIAS proteins function as SUMO-1-tethering proteins and zinc finger-dependent E3 SUMO protein ligases, and these properties are likely to explain their ability to modulate the activities of various transcription factors.

Identification of a Novel RING Finger Protein as a Coregulator in Steroid Receptor-Mediated Gene Transcription

ABSTRACT Using the DNA-binding domain of androgen receptor (AR) as a bait in a yeast two-hybrid screening, we have identified a small nuclear RING finger protein, termed SNURF, that interacts with AR in a hormone-dependent fashion in both yeast and mammalian cells. Physical interaction between AR and SNURF was demonstrated by coimmunoprecipitation from cell extracts and by protein-protein affinity chromatography. Rat SNURF is a highly hydrophilic protein consisting of 194 amino acid residues and comprising a consensus C3HC4 zinc finger (RING) structure in the C-terminal region and a bipartite nuclear localization signal near the N terminus. Immunohistochemical experiments indicated that SNURF is a nuclear protein. SNURF mRNA is expressed in a variety of human and rat tissues. Overexpression of SNURF in cultured mammalian cells enhanced not only androgen, glucocorticoid, and progesterone receptor-dependent transactivation but also basal transcription from steroid-regulated promoters. Mutation of two of the potential Zn2+coordinating cysteines to serines in the RING finger completely abolished the ability of SNURF to enhance basal transcription, whereas its ability to activate steroid receptor-dependent transcription was maintained, suggesting that there are separate domains in SNURF that mediate interactions with different regulatory factors. SNURF is capable of interacting in vitro with the TATA-binding protein, and the RING finger domain is needed for this interaction. Collectively, we have identified and characterized a ubiquitously expressed RING finger protein, SNURF, that may function as a bridging factor and regulate steroid receptor-dependent transcription by a mechanism different from those of previously identified coactivator or integrator proteins.

Ubc9 Interacts with the Androgen Receptor and Activates Receptor-dependent Transcription

Ubc9, a homologue of the class E2 ubiquitin-conjugating enzymes, has recently been shown to catalyze conjugation of a small ubiquitin-like molecule-1 (SUMO-1) to a variety of target proteins. SUMO-1 modifications have been implicated in the targeting of proteins to the nuclear envelope and certain intranuclear structures and in converting proteins resistant to ubiquitin-mediated degradation. In the present work, we find that Ubc9 interacts with the androgen receptor (AR), a member of the steroid receptor family of ligand-activated transcription factors. In transiently transfected COS-1 cells, AR-dependent but not basal transcription is enhanced by the coexpression of Ubc9. The N-terminal half of the AR hinge region containing the C-terminal part of the bipartite nuclear localization signal is essential for the interaction with Ubc9. Deletion of this part of the nuclear localization signal, which does not completely prevent the transfer of AR to the nucleus, abolishes the AR-Ubc9 interaction and attenuates the transcriptional response to cotransfected Ubc9. The C93S substitution of Ubc9, which prevents SUMO-1 conjugation by abrogating the formation of a thiolester bond between SUMO-1 and Ubc9, does not influence the capability of Ubc9 to stimulate AR-dependent transactivation, implying that Ubc9 is able to act as an AR coregulator in a fashion independent of its ability to catalyze SUMO-1 conjugation.

A TESTIS-SPECIFIC ANDROGEN RECEPTOR COREGULATOR THAT BELONGS TO A NOVEL FAMILY OF NUCLEAR PROTEINS

We have characterized a novel partner for androgen receptor (AR), termed ARIP3, that interacts with the DNA-binding domain/zinc finger region of AR and is predominantly expressed in the testis. Rat ARIP3 is a nuclear protein comprising 572 amino acids. It modulates AR-dependent but not basal transcription, suggesting that ARIP3 acts as an AR transcriptional coregulator. Except for the C-terminal AR-interacting domain, ARIP3 contains distinct regions that are also present in two recently described proteins, a protein inhibitor of activated Stat3 and an RNA helicase II-interacting protein (Gu/RH-II binding protein). Conserved structural features of these proteins indicate the existence of a gene family involved in the regulation of various transcription factors. Collectively, ARIP3 belongs to a novel nuclear protein family and is perhaps the first tissue-specific coregulator of androgen receptor.

Interaction of Androgen Receptors with Androgen Response Element in Intact Cells ROLES OF AMINO- AND CARBOXYL-TERMINAL REGIONS AND THE LIGAND

Promoter interference assay was employed to examine in intact cells the roles of the functional domains of androgen receptor (AR) and the ligand for specific DNA interactions using a cytomegalovirus-(androgen response element)-chloramphenicol acetyltransferase reporter (pCMV-ARE2-CAT). Native rat and human ARs interfered with pCMV-ARE2-CAT expression in a hormone-dependent fashion. Low steroid-independent interference seemed to occur because of the ligand binding domain (LBD), which was transcriptionally inhibitory also in a heterologous context. AR devoid of LBD (rARΔ641–902) decreased pCMV-ARE2-CAT activity by 50%. The rARΔ46–408 mutant devoid of the NH2-terminal transcription activation region exhibited ligand-dependent promoter interference of a similar magnitude. Ligand and DNA binding-deficient mutants (hARM807R and rARC562G, respectively) did not influence pCMV-ARE2-CAT expression, although hARM807R binds to ARE in vitro. Non-steroidal anti-androgens casodex and hydroxyflutamide antagonized agonist-dependent promoter interference, whereas cyproterone acetate, RU 56187, RU 57073, and RU 59063 were partial agonists/antagonists. Collectively, interaction of ARs with ARE in intact cells does not require the presence of the COOH-terminal or NH2-terminal domain and/or their interaction. In the context of native AR, however, the androgen-induced conformational change in LBD is mandatory for generation of a transcriptionally competent receptor that binds to DNA in intact cells.

SUMO-Specific Protease 1 (SENP1) Reverses the Hormone-Augmented SUMOylation of Androgen Receptor and Modulates Gene Responses in Prostate Cancer Cells

The acceptor sites for small ubiquitin-like modifier (SUMO) are conserved in the N-terminal domains of several nuclear receptors. Here, we show that androgens induce rapid and dynamic conjugation of SUMO-1 to androgen receptor (AR). Nuclear import of AR is not sufficient for SUMOylation, because constitutively nuclear apo-ARs or antagonist-bound ARs are only very weakly modified by SUMO-1 in comparison with agonist-bound ARs. Of the SUMO-specific proteases (SENP)-1, -2, -3, -5, and -6, only SENP1 and SENP2 are efficient in cleaving AR-SUMO-1 conjugates in intact cells and in vitro. Both SENP1 and -2 are nuclear and found at sites proximal to AR. Their expression promotes AR-dependent transcription, but in a promoter-selective fashion. SENP1 and -2 stimulated the activity of holo-AR on compound androgen response element-containing promoters. The effects of SENP1 and -2 on AR-dependent transcription were dependent on catalytic activity and required intact SUMO acceptor sites in AR, indicating that their coactivating effects are mainly due to their direct isopeptidase activity on holo-AR. In prostate cancer cells, ectopic expression of SENP1, but not that of SENP2, increased the transcription activity of endogenous AR. Silencing of SENP1 attenuated the expression of several AR target genes and blunted androgen-stimulated growth of LNCaP cells. Our results indicate that SENP1 reverses the ligand-induced SUMOylation of AR and helps fine tune the cellular responses to androgens in a target promoter-selective manner.

Pure antiandrogens disrupt the recruitment of coactivator GRIP1 to colocalize with androgen receptor in nuclei.

We have used confocal microscopy to elucidate the effects of antiandrogens on nuclear localization of the androgen receptor (AR) with its transcriptional coactivator GRIP1. We show that the agonist‐activated AR recruits GRIP1 to colocalize with the receptor in the nucleoplasm. By contrast, AR complexed to the antiandrogens hydroxyflutamide and bicalutamide fails to influence nuclear distribution of GRIP1. Likewise, the non‐steroidal antiandrogens prevent the agonist‐induced AR–GRIP1 colocalization from occurring. Androgen antagonists affect nuclear redistribution of AR–GRIP1 in a fashion that parallels their effects on the transcriptional activity of AR, in that the pure antagonists block GRIP1‐dependent activation of AR function, whereas the mixed antagonist/agonist cyproterone acetate promotes both AR‐driven redistribution of GRIP1 and activation of AR by GRIP1.

ZNF451 is a novel PML body- and SUMO-associated transcriptional coregulator.

Covalent modification by small ubiquitin-related modifiers (SUMOs) is an important means to regulate dynamic residency of transcription factors within nuclear compartments. Here, we identify a multi-C(2)H(2)-type zinc finger protein (ZNF), ZNF451, as a novel nuclear protein that can be associated with promyelocytic leukemia bodies. In keeping with its interaction with SUMO E2 conjugase Ubc9 and SUMOs, ZNF451 is covalently modified by SUMOs (sumoylated) at several, albeit nonconsensus, sites. Interestingly, noncovalent SUMO-binding activity of ZNF451 (SUMO-interacting motif) is also important for its sumoylation. SUMO modifications regulate the nuclear compartmentalization of ZNF451, since coexpression of ZNF451 with SUMO-specific proteases SENP1 or SENP2, both capable of desumoylating the protein, redistributes ZNF451 from nuclear domains to speckles and nucleoplasm. Interaction of ZNF451 with PIAS1 (protein inhibitor of activated STAT 1) is not manifested as PIAS1s E3 SUMO ligase activity towards ZNF451 but results in disintegration of ZNF451 nuclear domains and recruitment of ZNF451 to androgen receptor (AR) speckles. ZNF451 interacts weakly, but in a SUMO-1-enhanced fashion, with AR. ZNF451 does not harbor an intrinsic transcription activation function, but interestingly, ablation of endogenous ZNF451 in prostate cancer cells significantly decreases expression of several AR target genes. Thus, we suggest that ZNF451 exerts its effects via SUMO modification machinery and trafficking of transcription regulators between promyelocytic leukemia bodies and nucleoplasm.

The RING Finger Protein SNURF Is a Bifunctional Protein Possessing DNA Binding Activity

The small nuclear C3HC4 finger protein (SNURF), RNF4, acts as transcriptional coactivator for both steroid-dependent and -independent promoters such as those driven by androgen response elements and GC boxes, respectively. However, SNURF does not possess intrinsic transcription activation function, and the precise molecular mechanism of its action is unknown. We have studied herein the interaction of SNURF with DNA in vitro. SNURF binds to linear double-stranded DNA with no apparent sequence specificity in a cooperative fashion that is highly dependent on the length of the DNA fragment used. SNURF interacts efficiently with both supercoiled circular and four-way junction DNA, and importantly, it also recognizes nucleosomes. An intact RING structure of SNURF is not mandatory for DNA binding, whereas mutations of specific positively charged residues in the N terminus (amino acids 8–11) abolish DNA binding. Interestingly, the ability of SNURF to interact with DNA is associated with its capability to enhance transcription from promoters containing GC box elements. Because SNURF can interact with both DNA and protein (transcription) factors, it may promote assembly of nucleoprotein structures.

TCR-Induced Activation of LFA-1 Involves Signaling through Tiam1

Adhesion is pivotal for most leukocyte functions, and the β2 integrin family of adhesion molecules plays a central role. The integrins need activation to become functional, but the molecular events resulting in adhesion have remained incompletely understood. In human T cells, activation through the TCR results in specific phosphorylation of the T758 on the β2 chain of LFA-1. We now show that this phosphorylation leads to downstream binding of 14-3-3 proteins, followed by engagement of the guanine nucleotide exchange factor protein Tiam1 and Rac1 activation. Downregulation of the signaling molecules inhibits LFA-1 activity. Activation by the chemokine stromal cell-derived factor-1α also results in T758 phosphorylation and integrin activation. Thus, TCR and chemokine activation converges on LFA-1 phosphorylation, followed by similar downstream events affecting adhesion.