An antiviral disulfide compound blocks interaction between arenavirus Z protein and cellular promyelocytic leukemia protein.

The promyelocytic leukemia protein (PML) forms nuclear bodies (NB) that can be redistributed by virus infection. In particular, lymphocytic choriomeningitis virus (LCMV) influences disruption of PML NB through the interaction of PML with the arenaviral Z protein. In a previous report, we have shown that the disulfide compound NSC20625 has antiviral and virucidal properties against arenaviruses, inducing unfolding and oligomerization of Z without affecting cellular RING-containing proteins such as the PML. Here, we further studied the effect of the zinc-finger-reactive disulfide NSC20625 on PML-Z interaction. In HepG2 cells infected with LCMV or transiently transfected with Z protein constructs, treatment with NSC20625 restored PML distribution from a diffuse-cytoplasmic pattern to punctate, discrete NB which appeared identical to NB found in control, uninfected cells. Similar results were obtained in cells transfected with a construct expressing a Z mutant in zinc-binding site 2 of the RING domain, confirming that this Z-PML interaction requires the integrity of only one zinc-binding site. Altogether, these results show that the compound NSC20625 suppressed Z-mediated PML NB disruption and may be used as a tool for designing novel antiviral strategies against arenavirus infection.

Does this have a familiar RING?

The RING finger is a zinc-binding domain that is found in proteins from plants to humans, but whose function remains largely enigmatic. The domain itself is distinct from other zinc-finger motifs in terms of sequence homology, zinc-ligation scheme and three-dimensional structure. It appears that the RING is involved in mediating protein-protein interactions and in some cases multi-protein complexes, which might depend on the presence of other proteins and/or domains.

In-depth mutational analysis of the promyelocytic leukemia zinc finger BTB/POZ domain reveals motifs and residues required for biological and transcriptional functions.

The promyelocytic leukemia zinc finger (PLZF) protein is a transcription factor disrupted in patients with t(11;17)(q23;q21)-associated acute promyelocytic leukemia. PLZF contains an N-terminal BTB/POZ domain which is required for dimerization, transcriptional repression, formation of high-molecular-weight DNA-protein complexes, nuclear sublocalization, and growth suppression. X-ray crystallographic data show that the PLZF BTB/POZ domain forms an obligate homodimer via an extensive interface. In addition, the dimer possesses several highly conserved features, including a charged pocket, a hydrophobic monomer core, an exposed hydrophobic surface on the floor of the dimer, and two negatively charged surface patches. To determine the role of these structures, mutational analysis of the BTB/POZ domain was performed. We found that point mutations in conserved residues that disrupt the dimer interface or the monomer core result in a misfolded nonfunctional protein. Mutation of key residues from the exposed hydrophobic surface suggests that these are also important for the stability of PLZF complexes. The integrity of the charged-pocket region was crucial for proper folding of the BTB/POZ domain. In addition, the pocket was critical for the ability of the BTB/POZ domain to repress transcription. Alteration of charged-pocket residue arginine 49 to a glutamine (mutant R49Q) yields a domain that can still dimerize but activates rather than represses transcription. In the context of full-length PLZF, a properly folded BTB/POZ domain was required for all PLZF functions. However, PLZF with the single pocket mutation R49Q repressed transcription, while the double mutant D35N/R49Q could not, despite its ability to dimerize. These results indicate that PLZF requires the BTB/POZ domain for dimerization and the charged pocket for transcriptional repression.

The RING finger domain: a recent example of a sequence-structure family.

In the past 18 months, two RING finger structures have been solved. They represent the first reported structures for this novel zinc-binding sequence motif. Both structures are significantly different from other zinc-binding domains, in terms of both their zinc-ligation scheme and their three-dimensional structures. The RING finger domain appears to be a convenient scaffold which can be altered to provide functional specificity in those proteins that contain the motif.

The promyelocytic leukemia (PML) protein suppresses cyclin D1 protein production by altering the nuclear cytoplasmic distribution of cyclin D1 mRNA.

The majority of the promyelocytic leukemia (PML) protein is present in nuclear bodies which are altered in several pathogenic conditions including acute promyelocytic leukemia. PML nuclear bodies are found in nearly all cells yet their function remains unknown. Here, we demonstrate that PML and the eukaryotic initiation factor 4E (elF-4E) co-localize and co-immunopurify. eIF-4E is involved in nucleocytoplasmic transport of specific mRNAs including cyclin D1. eIF-4E overexpression leads to increased cyclin D1 protein levels; whereas, overexpression of PML leads to decreased cyclin D1 levels. Neither PML nor eIF-4E cause significant changes in cyclin D1 mRNA levels. The association with eIF-4E led us to investigate if PML could alter mRNA distribution as a possible post-transcriptional mechanism for suppressing cyclin D1 production. We show that overexpression of PML results in nuclear retention of cyclin D1 mRNA and that intact PML nuclear bodies are required. Addition of eIF-4E overcomes PML induced retention and alters the morphology of PML bodies suggesting a mechanism by which eIF-4E can modulate PML function. These results raise the possibility that PML nuclear bodies may participate in the regulation of nucleocytoplasmic transport of specific mRNAs.

The promyelocytic leukemia protein PML interacts with the proline-rich homeodomain protein PRH: a RING may link hematopoiesis and growth control.

Acute promyelocytic leukemia (APL) is characterized by a block in myeloid cell differentiation. As a result of a chromosomal translocation in these patients, the promyelocytic leukemia protein PML is disrupted as are the nuclear bodies it forms. Disruption of PML and PML nuclear bodies in APL is linked to a loss of growth control and subsequent leukemogenesis. PML contains a zinc-binding domain known as the RING which is required for formation of these bodies. Using yeast 2-hybrid techniques, we found that PML and a related RING protein, Z, bind the proline rich homeodomain protein (PRH) through their RING domains. Previous reports indicate that PRH functions in hematopoiesis and may act as a transcriptional repressor. Our data indicate that PML and Z both bind the repressor domain of PRH and are the first protein partners reported for PRH. We observe that PRH has a punctate pattern in both the nucleus and cytoplasm of chronic myelogenous leukemia K562 cells and in the APL cell line, NB4. Immunoprecipitation and co-localization studies indicate that PML and PRH interact in both cell lines. The effect on cell growth by PML and the hematopoietic actions of PRH raises the possibility that the interaction between PML and PRH represents a link between growth control and hematopoiesis.

Two mutant binding sites of the activating transcription factor region within the E2A promoter of adenovirus exist in a novel conformation.

The solution conformations of two mutants of the ATF (activating transcription factor) binding site within the E2A promoter of adenovirus have been determined in vitro by NMR and CD methods. Both sequences have conformations which incorporate north-like sugar puckers in helices which are stacked in a B-like manner as seen with the parent binding site (Borden, K.L.B. (1993) Biochemistry 32, 6506-6514). The PATFm sequence has similar binding affinities and specificities to ATF while the PM2 oligonucleotide is recognized by a different subset of proteins within the ATF family. Both sequences contain unusual amounts of sugar puckers in north-like conformations but the specific distribution of north-like and south-like structures differs between them. These data indicate that the existence of this novel conformation is not characteristic of only the parent sequence. Further, there is a sequence dependent component as illustrated by the variation of the distribution of the north-like sugar puckers within the two mutant oligonucleotides. Differences in sugar pucker conformation can cause bending of the helix and will alter the phosphate backbone surface of the oligonucleotide. Both factors are important to the protein nucleic acid recognition process and thus to cellular control of transcription.

RING domains: master builders of molecular scaffolds?

Intense interest in the RING domain has arisen because of its widespread occurrence and involvement in human disease. Several intriguing characteristics evident from the study of this cysteine-rich, zinc-binding domain have made it difficult to establish a single defining biochemical function for RINGs. These proteins are found throughout the cell and mediate diverse cellular processes, e.g. oncogenesis, apoptosis, development and viral infection. Recent developments indicate that RING-mediated protein interactions are critical for transcriptional repression and for ubiquitination. These data are in addition to previously established functions for RINGs in RNA processing, cell-cycle control and peroxisomal biogenesis, to name a few. At first glance, there appears to be little to link such disparate actions. Collectively, these results suggest that RINGs function in formation and architecture of large protein complexes that contribute to diverse cellular processes. Here, new developments, in the context of previous results, are discussed in an attempt to establish a unifying theory for RING function.

The RING domains of the promyelocytic leukemia protein PML and the arenaviral protein Z repress translation by directly inhibiting translation initiation factor eIF4E.

The promyelocytic leukemia protein (PML) is a mammalian regulator of cell growth which is characteristically disrupted in acute promyelocytic leukemia and by a variety of viruses. PML contains a RING domain which is required for its growth-suppressive and antiviral properties. Although normally nuclear, in certain pathogenic conditions, including arenaviral infection, PML is relocated to the cytoplasm, where its functions are poorly understood. Here, we observe that PML and arenavirus protein Z use regions around the first zinc-binding site of their respective RING domains to directly interact, with sub-micromolar affinity, with the dorsal surface of translation initiation factor eIF4E, representing a novel mode of eIF4E recognition. PML and Z profoundly reduce the affinity of eIF4E for its substrate, the 5' 7-methyl guanosine cap of mRNA, by over 100-fold. Association with the dorsal surface of eIF4E and direct antagonism of mRNA cap binding by PML and Z lead to direct inhibition of translation. These activities of the RING domains of PML and Z do not involve ubiquitin-mediated protein degradation, in contrast to many RINGs which have been observed to do so. Although PML and Z have well characterized physiological functions in regulation of growth and apoptosis, this work establishes the first discrete biochemical mechanism which underlies the biological activities of their RING domains. Thus, we establish PML and Z as translational repressors, with potential contributions to the pathogenesis of acute promyelocytic leukemia and variety of viral infections.

Homeodomain proteins and eukaryotic translation initiation factor 4E (eIF4E): an unexpected relationship.

The central role of post-transcriptional modification of the expression of several genes involved in tumorigenesis implicates eIF4E as a pivotal factor in the regulation of cell survival, growth and proliferation. Overexpression of eIF4E leads to malignant transformation in vitro and induces tumor formation in vivo. Furthermore, upregulated expression of eIF4E has been reported in a variety of human malignancies. Consequently, studies over the last ten years have sought to better characterize the molecular mechanisms and cellular factors that control eIF4E activity. These efforts have revealed a role for eIF4E in diverse biological processes including embryonic development, cell cycle progression, synaptic plasticity and cancer. In this review we focus on several members of the homeodomain protein family, which have recently been identified as a novel class of eIF4E regulators.

Finding a role for PML in APL pathogenesis: a critical assessment of potential PML activities.

In normal mammalian cells the promyelocytic leukemia protein (PML) is primarily localized in multiprotein nuclear complexes called PML nuclear bodies. However, both PML and PML nuclear bodies are disrupted in acute promyelocytic leukemia (APL). The treatment of APL patients with all-trans retinoic acid (ATRA) results in clinical remission associated with blast cell differentiation and reformation of the PML nuclear bodies. These observations imply that the structural integrity of the PML nuclear body is critically important for normal cellular functions. Indeed, PML protein is a negative growth regulator capable of causing growth arrest in the G(1) phase of the cell cycle, transformation suppression, senescence and apoptosis. These PML-mediated, physiological effects can be readily demonstrated. However, a discrete biochemical and molecular model of PML function has yet to be defined. Upon first assessment of the current PML literature there appears to be a seemingly endless list of potential PML partner proteins implicating PML in a variety of regulatory mechanisms at every level of gene expression. The purpose of this review is to simplify this confusing field of research by using strict criteria to deduce which models of PML body function are well supported.

Construction of macromolecular assemblages in eukaryotic processes and their role in human disease: linking RINGs together.

Members of the Really Interesting New Gene (RING) family of proteins are found throughout the cells of eukaryotes and function in processes as diverse as development, oncogenesis, viral replication and apoptosis. There are over 200 members of the RING family where membership is based on the presence of a consensus sequence of zinc binding residues. Outside of these residues there is little sequence homology; however, there are conserved structural features. Current evidence strongly suggests that RINGs are protein interaction domains. We examine the features of RING binding motifs in terms of individual cases and the potential for finding a universal consensus sequence for RING binding domains (FRODOs). This review examines known and potential functions of RINGs, and attempts to develop a framework within which their seemingly multivalent cellular roles can be consistently understood in their structural and biochemical context. Interestingly, some RINGs can self-associate as well as bind other RINGs. The ability to self-associate is typically translated into the annoying propensity of these domains to aggregate during biochemical characterization. The RINGs of PML, BRCA1, RAG1, KAP1/TIF1beta, Polycomb proteins, TRAFs and the viral protein Z have been well characterized in terms of both biochemical studies and functional data and so will serve as focal points for discussion. We suggest physiological functions for the oligomeric properties of these domains, such as their role in formation of macromolecular assemblages which function in an intricate interplay of coupled metal binding, folding and aggregation, and participate in diverse functions: epigenetic regulation of gene expression, RNA transport, cell cycle control, ubiquitination, signal transduction and organelle assembly.

The promyelocytic leukemia protein PML has a pro-apoptotic activity mediated through its RING domain.

The promyelocytic leukemia protein PML is known to form nuclear multiprotein complexes which are compromised in several pathogenic conditions including acute promyelocytic leukemia. We show that in cells infected with a single stranded RNA virus, which relocates PML bodies to the cytoplasm, the infected cells are more resistant to serum starvation induced apoptosis than their uninfected counterparts. Antisense PML oligonucleotides increase cell survival under serum deprivation conditions indicating that PML is directly involved in the apoptotic activity. Transient transfection studies have indicated that this pro-apoptotic activity of PML is mediated through the zinc binding region known as the RING finger. Viral attack of PML nuclear bodies appears to allow the virus to deregulate host cell apoptotic machinery in order to establish chronic infection.

Characterisation of a novel cysteine/histidine-rich metal binding domain from Xenopus nuclear factor XNF7.

A 42 amino acid synthetic peptide corresponding to a newly defined cysteine/histidine-rich protein motif called B-box, from the Xenopus protein XNF7 has been characterised. The metal-binding stoichiometry and dissociation constant for zinc were determined by competition with the chromophoric chelator Br2BAPTA, demonstrating that one zinc atom binds per molecule of peptide despite the presence of seven putative metal ligands, and represents the first application of this method to measuring zinc stoichiometry of proteins and/or peptides. Cobalt binding studies indicate that the motif binds zinc more tightly than cobalt, that cysteines are used as ligands and that the cation is co-ordinated tetrahedrally. Circular dichroism and NMR studies both indicate that the B-box peptide is structured only in the presence of zinc, copper and to a lesser extent cobalt.

The eukaryotic translation initiation factor eIF4E is a direct transcriptional target of NF-κB and is aberrantly regulated in acute myeloid leukemia.

The eukaryotic translation initiation factor eIF4E is a potent oncogene elevated in many cancers, including the M4 and M5 subtypes of acute myeloid leukemia (AML). Although eIF4E RNA levels are elevated 3- to 10-fold in M4/M5 AML, the molecular underpinnings of this dysregulation were unknown. Here, we demonstrate that EIF4E is a direct transcriptional target of nuclear factor kappa-light-chain-enhancer of activated B cells (NF-κB) that is dysregulated preferentially in M4 and M5 AML. In primary hematopoietic cells and in cell lines, eIF4E levels are induced by NF-κB activating stimuli. Pharmacological or genetic inhibition of NF-κB represses this activation. The endogenous human EIF4E promoter recruits p65 and cRel to evolutionarily conserved κB sites in vitro and in vivo following NF-κB activation. Transcriptional activation is demonstrated by recruitment of p300 to the κB sites and phosphorylated Pol II to the coding region. In primary AML specimens, generally we observe that substantially more NF-κB complexes associate with eIF4E promoter elements in M4 and M5 AML specimens examined than in other subtypes or unstimulated normal primary hematopoietic cells. Consistently, genetic inhibition of NF-κB abrogates eIF4E RNA levels in this same population. These findings provide novel insights into the transcriptional control of eIF4E and a novel molecular basis for its dysregulation in at least a subset of M4/M5 AML specimens.

The activating transcription factor region within the E2A promoter exists in a novel conformation.

The ATF (activating transcription factor) binding site within the E2A promoter region of adenovirus is shown to exist in a novel conformation in vitro via nuclear magnetic resonance methods. This novel conformation may be important to the protein DNA recognition process. This conformation has characteristics of both A- and B-form DNA. From circular dichroism and through-space-based NMR experiments, it is clear that the overall helical structure is B-like. However, the 1H-1H coupling constant information indicates that most of the sugar puckers of the individual nucleotides are in the C3'-endo/C4'-exo range which is more characteristic of A-form DNA. The sugar conformation can also be described as a mixture of two states, C3'-endo and C2'-endo, where many of the sugars exist mainly in the C3'-endo state. These data show that the conformation of the sugar puckers does not determine the nature of the overall base stacking on the DNA. Helical parameters were calculated from NOE build-up curves for half of the dinucleotide pairs. Severe spectral overlap on the nuclear Overhauser based spectra prevented determination of the helical parameters for all of the dinucleotide base-pairs. Energy minimization and molecular dynamic simulation methods using the sugar pucker and glycosidic torsion angles determined from the NMR data as constraints were carried out in order to demonstrate that such a conformation was energetically favorable.

RING fingers and B-boxes: zinc-binding protein-protein interaction domains.

The cysteine-rich zinc-binding motifs known as the RING and B-box are found in several unrelated proteins. Structural, biochemical, and biological studies of these motifs reveal that they mediate protein-protein interactions. Several RING-containing proteins are oncoproteins and recent data indicate that proapoptotic activities can be mediated through the RING. 1H NMR methods were used to determine the structures of RINGs and a B-box domain and to monitor the conformational changes these motifs undergo upon zinc ligation. This review discusses in detail the structural features of the RING and B-box domains. Further, possible structure function relationships for these motifs particularly in their role as protein interaction domains are discussed.

Structure/function in neuroprotection and apoptosis.

The three-dimensional conformation of proteins influences their potential to function correctly within the cell. Protein conformational issues are particularly important in neurodegeneration, as has been shown by misfolded protein forming the basis of plaques in Alzheimer's disease and prion diseases. This article focuses on protein structure/function specifically for proteins important in the pathogenesis of neurodegenerative conditions and those involved in apoptosis. The proteins used as examples in this review include alpha-synuclein, the promyelocytic leukemia protein, and glyceraldehyde 3-phosphate dehydrogenase.

Folding kinetics of phage T4 thioredoxin.

The folding mechanism for bacteriophage T4 thioredoxin is best described by a four-state box mechanism, N----Uc----Ut----It----N, where N indicates native, Uc the unfolded form with the cis proline isomer, Ut unfolded with the trans proline isomer, and It a compact form with a trans proline isomer. Both manual mixing fluorescence and size-exclusion chromatography indicate that there is a cis-trans proline isomerization that is important to the folding pathway. Furthermore, the data suggest that the cis-trans isomerization can also occur in a compact nativelike state which is referred to as It. The slow phase seen in fluorescence seems to be monitoring the cis-trans isomerization in the compact form, not the isomerization which occurs in the denatured state.