Identification of a novel RING finger protein as a coregulator in steroid receptor-mediated gene transcription.

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.

Transcriptional coregulator SNURF (RNF4) possesses ubiquitin E3 ligase activity.

SNURF/RNF4 has been implicated in transcriptional regulation and growth inhibition in a RING finger-dependent fashion. In this work, we show that SNURF mediates its own ubiquitination in vitro in a ubiquitin-conjugating enzyme (E2)-selective manner: SNURF acts as an E3 ligase with UbcH5A and B, HHR6B (RAD6B), E2-25K, MmUbc7 and UbcH13, but not with UbcH3, UbcM4, MmUbc6 or E2-20K. In contrast, the well-characterized RING E3, AO7, functions only with members of the UbcH5 family. Furthermore, depending on the E2 used, the ubiquitin modification manifests as mono- or multi-ubiquitination. Mutation of conserved cysteine residues within the RING finger motif of SNURF abolishes the ubiquitination in vitro and in intact cells. Size fractionation of murine embryonal carcinoma F9 cell proteins shows that the majority of endogenous SNURF resides in salt-resistant > or =500-kDa complexes, suggesting that SNURF functions as a RING component in a multiprotein complex. Taken together, SNURF/RNF4 functions as an E3 ligase and this activity is closely linked to its transcription regulatory functions.

The RING finger protein SNURF is a bifunctional protein possessing DNA binding activity.

The small nuclear C(3)HC(4) 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.

Androgen-receptor-interacting nuclear proteins.

Androgen receptor (AR) belongs to the superfamily of nuclear hormone receptors that employ complex molecular mechanisms to guide the development and physiological functions of their target tissues. Our recent work has led to the identification of four novel proteins that recognize AR zinc-finger region (ZFR) both in vivo and in vitro. One is a small nuclear RING-finger protein that possesses separate interaction interfaces for AR and for other transcription activators such as Sp1. The second is a nuclear serine/threonine protein kinase (androgen-receptor-interacting nuclear protein kinase; ANPK); however, the receptor itself does not seem to be a substrate for this kinase. The third one is dubbed androgen-receptor-interacting protein 3 (ARIP3) and is a novel member of the PIAS (protein inhibitor of activated STAT) protein family. The fourth protein, termed ARIP4, is a nuclear ATPase that belongs to the SNF2-like family of chromatin remodelling proteins. All four proteins exhibit a punctate nuclear pattern when expressed in cultured cells. Each protein modulates AR-dependent transactivation in co-transfection experiments; their activating functions are not restricted to AR. Current work is aimed at elucidating the biochemical and functional properties of these AR-interacting proteins and at finding the partner proteins that form complexes with them in vivo.