Identification of a novel 9-kDa polypeptide from nuclear extracts. DNA binding properties, primary structure, and in vitro expression

The large family of PC4-like domains - similar folds and functions throughout all kingdoms of life

RNA- and DNA-binding domains are essential building blocks for specific regulation of gene expression. While a number of canonical nucleic acid binding domains share sequence and structural conservation, others are less obviously linked by evolutionary traits. In this review, we describe a protein fold of about 150 aa in length, bearing a conserved β-β-β-β-α-linker-β-β-β-β-α topology and similar nucleic acid binding properties but no apparent sequence conservation. The same overall fold can also be achieved by dimerization of two proteins, each bearing a β-β-β-β-α topology. These proteins include but are not limited to the transcription factors PC4 and P24 from humans and plants, respectively, the human RNA-transport factor Pur-α (also termed PURA), as well as the ssDNA-binding SP_0782 protein from Streptococcus pneumonia and the bacteriophage coat proteins PP7 and MS2. Besides their common overall topology, these proteins share common nucleic acids binding surfaces and thus functional similarity. We conclude that these PC4-like domains include proteins from all kingdoms of life and are much more abundant than previously known.

Structures of apo- and ssDNA-bound YdbC from Lactococcus lactis uncover the function of protein domain family DUF2128 and expand the single-stranded DNA-binding domain proteome

Single-stranded DNA (ssDNA) binding proteins are important in basal metabolic pathways for gene transcription, recombination, DNA repair and replication in all domains of life. Their main cellular role is to stabilize melted duplex DNA and protect genomic DNA from degradation. We have uncovered the molecular function of protein domain family domain of unknown function DUF2128 (PF09901) as a novel ssDNA binding domain. This bacterial domain strongly associates into a dimer and presents a highly positively charged surface that is consistent with its function in non-specific ssDNA binding. Lactococcus lactis YdbC is a representative of DUF2128. The solution NMR structures of the 20 kDa apo-YdbC dimer and YdbC:dT₁₉G₁ complex were determined. The ssDNA-binding energetics to YdbC were characterized by isothermal titration calorimetry. YdbC shows comparable nanomolar affinities for pyrimidine and mixed oligonucleotides, and the affinity is sufficiently strong to disrupt duplex DNA. In addition, YdbC binds with lower affinity to ssRNA, making it a versatile nucleic acid-binding domain. The DUF2128 family is related to the eukaryotic nuclear protein positive cofactor 4 (PC4) family and to the PUR family both by fold similarity and molecular function.

Recruitment of RNA polymerase II cofactor PC4 to DNA damage sites

The multifunctional nuclear protein positive cofactor 4 (PC4) is involved in various cellular processes including transcription, replication, and chromatin organization. Recently, PC4 has been identified as a suppressor of oxidative mutagenesis in Escherichia coli and Saccharomyces cerevisiae. To investigate a potential role of PC4 in mammalian DNA repair, we used a combination of live cell microscopy, microirradiation, and fluorescence recovery after photobleaching analysis. We found a clear accumulation of endogenous PC4 at DNA damage sites introduced by either chemical agents or laser microirradiation. Using fluorescent fusion proteins and specific mutants, we demonstrated that the rapid recruitment of PC4 to laser-induced DNA damage sites is independent of poly(ADP-ribosyl)ation and γH2AX but depends on its single strand binding capacity. Furthermore, PC4 showed a high turnover at DNA damages sites compared with the repair factors replication protein A and proliferating cell nuclear antigen. We propose that PC4 plays a role in the early response to DNA damage by recognizing single-stranded DNA and may thus initiate or facilitate the subsequent steps of DNA repair.

The Intrinsically Unstructured Domain of PC4 Modulates the Activity of the Structured Core through Inter- and Intramolecular Interactions

Proteins frequently contain unstructured regions apart from a functionally important and well-conserved structured domain. Functional and structural aspects for these regions are frequently less clear. The general human positive cofactor 4 (PC4), has such a domain organization and can interact with various DNA substrates, transcriptional activators, and basal transcription factors. While essential for the cofactor function, structural and functional knowledge about these interactions is limited. Using biochemical, nuclear magnetic resonance (NMR), and docking experiments, we show that the carboxy-terminal structured core domain (PC4ctd) is required and sufficient for binding to single-stranded DNA (ssDNA), double-stranded DNA (dsDNA), and the herpes simplex virion protein 16 (VP16) activation domain (VP16ad). We determined the interaction surfaces within PC4 and showed that VP16 and DNA binding are mutually exclusive. Although the amino-terminal domain of PC4 (PC4ntd) alone is devoid of any bioactivity, it increases the interaction with VP16ad. While it decreases the ssDNA-binding and DNA-unwinding activity, it does not influence dsDNA binding. Structural characterization of this domain showed that it is highly flexible and mostly unstructured both in the free form and in the complex. NMR titration experiments using various protein and DNA substrates of the individual domains and the full-length PC4 revealed local conformational or environmental changes in both the structured and unstructured subdomains, which are interpreted to be caused by inter- and intramolecular interactions. We propose that the unstructured PC4ntd regulates the PC4 cofactor function by specific interactions with the activator and through modulation and/or shielding of the interaction surface in the structured core of PC4ctd.

A global transcription cofactor bound to juxtaposed strands of unwound DNA

The 1.74-A crystal structure of the human transcription cofactor PC4 in complex with a single-stranded 20-mer oligonucleotide reveals how symmetry-related beta-surfaces of the protein homodimer interact with juxtaposed 5-nucleotide DNA regions running in opposite directions. The structure explains high-affinity binding of PC4 to the complementary strands of unwinding duplex DNA, and it suggests the cofactor may have a role in relaxing negative supercoils or exposing unpaired bases for sequence-specific recognition by other biomolecules.

Human PC4 is a substrate-specific inhibitor of RNA polymerase II phosphorylation

The activity of cyclin-dependent protein kinases (cdks) is physiologically regulated by phosphorylation, association with the specific cyclin subunits, and repression by specific cdk inhibitors. All three physiological regulatory mechanisms are specific for one or more cdks, but none is known to be substrate specific. In contrast, synthetic cdk peptide inhibitors that specifically inhibit cdk phosphorylation of only some substrates, "aptamers," have been described. Here, we show that PC4, a naturally occurring transcriptional coactivator, competitively inhibits cdk-1, -2, and -7-mediated phosphorylation of the largest subunit of RNA polymerase II (RNAPII), but it does not inhibit phosphorylation of other substrates of the same kinases. Interestingly, the phosphorylated form of PC4 is devoid of kinase inhibitory activity. We also show that wild-type PC4 but not the kinase inhibitory-deficient mutant of PC4 represses transcription in vivo. Our results point to a novel role for PC4 as a specific inhibitor of RNAPII phosphorylation.

Identification of the single-stranded DNA binding surface of the transcriptional coactivator PC4 by NMR

The C-terminal domain of the eukaryotic transcriptional cofactor PC4 (PC4CTD) is known to bind with nanomolar affinity to single-stranded (ss)DNA. Here, NMR is used to study DNA binding by this domain in more detail. Amide resonance shifts that were observed in a 1H15N-HSQC-monitored titration of 15N-labeled protein with the oligonucleotide dT18 indicate that binding of the nucleic acid occurs by means of two anti-parallel channels that were previously identified in the PC4CTD crystal structure. The beta-sheets and loops that make up these channels exhibit above average flexibility in the absence of ssDNA, which is reflected in higher values of T1rho, reduced heteronuclear nuclear Overhauser effects and faster deuterium exchange rates for the amides in this region. Upon ssDNA binding, this excess flexibility is significantly reduced. The binding of ssDNA by symmetry-related channels reported here provides a structural rationale for the preference of PC4CTD for juxtaposed single-stranded regions (e.g. in heteroduplexes) observed in earlier work.

Biochemical characterization of the NF-Y transcription factor complex during B lymphocyte development

The transcription factor, NF-Y, plays a critical role in tissue-specific major histocompatibility complex class II gene transcription. In this report the biochemical properties of the heterotrimeric NF-Y complex have been characterized during stage-specific B-cell development, and in several class II- mutant B-cell lines, which represent distinct bare lymphocyte syndrome class II genetic complementation groups. The NF-Y complex derived from class II+ mature B-cells bound with high affinity to anion exchangers, and eluted as an intact trimeric complex, whereas, NF-Y derived from class II- plasma B-cells, and from bare lymphocyte syndrome group II cell lines, RJ2.2.5 and RM3, dissociated into discrete NF-YA and NF-YB:C subunit fractions. Recombination of the MPC11 plasma B-cell derived NF-Y A:B:C complex with the low molecular mass protein fraction, NF-Y-associated factors (YAFs), derived from mature A20 B-cell nuclei, conferred high affinity anion exchange binding to NF-Y as an intact trimeric complex. Recombination of the native NF-YA:B:C complex with the transcriptional cofactor, PC4, likewise conferred high affinity NF-Y binding to anion exchangers, and stabilized NF-Y interaction with CCAAT-box DNA motifs in vitro. Interaction between PC4 and NF-Y was mapped to the C-terminal region of PC4, and the subunit interaction subdomain of the highly conserved DNA binding-subunit interaction domain (DBD) of NF-YA. These results suggest that in class II+ mature B-cells NF-Y is associated with the protein cofactor, PC4, which may play an important role in NF-Y-mediated transcriptional control of class II genes.

Isolation of putative plant transcriptional coactivators using a modified two-hybrid system incorporating a GFP reporter gene

Dual hybrid interacting screening in yeast led to the identification of two proteins from Arabidopsis both exhibiting sequence similarity to a family of transcriptional coactivators from a diverse range of organisms. Their discovery constitutes the first description of such plant proteins. A modified yeast two-hybrid approach utilising the green fluorescent protein (GFP) of Aequora victoria was developed and used to clone one of the putative plant transcriptional coactivators from an Arabidopsis cDNA library. The two proteins, designated KIWI and KELP, can associate both hetero- and homomerically and their genes were cloned and mapped on the Arabidopsis genome. Both proteins are believed to play a role in gene activation during pathogen defence and plant development. The involvement of these proteins in general plant transcription as well as the advantages of using GFP as a reporter gene for detecting protein-protein interactions are discussed.

Properties of PC4 and an RNA polymerase II complex in directing activated and basal transcription in vitro

A human RNA polymerase II (pol II) complex was isolated from a HeLa-derived cell line that conditionally expresses an epitope-tagged RPB9 subunit of human pol II. The isolated FLAG-tagged pol II complex (f:pol II) contains a subset of general transcription factors but is devoid of TFIID and TFIIA. In conjunction with TATA-binding protein (TBP) or TFIID, f:pol II is able to mediate both basal and activated transcription by Gal4-VP16 when a transcriptional coactivator PC4 is also provided. Interestingly, PC4, in the absence of a transcriptional activator, actually functions as a repressor to inhibit basal transcription. Remarkably, TBP is able to mediate activator function in this transcription system. The presence of TBP-associated factors, however, helps overcome PC4 repression and further enhance the level of activation mediated by TBP. Alleviation of PC4 repression can also be achieved by preincubation of the transcriptional components with the DNA template. Sarkosyl disruption of preinitiation complex formation further illustrates that PC4 can only inhibit transcription prior to the assembly of a functional preinitiation complex. These results suggest that PC4 represses basal transcription by preventing the assembly of a functional preinitiation complex, but it has no effect on the later steps of the transcriptional process.

High-affinity DNA binding by the C-terminal domain of the transcriptional coactivator PC4 requires simultaneous interaction with two opposing unpaired strands and results in helix destabilization

The general transcriptional cofactor PC4 enhances transcription from various promoters and functions with a wide range of transcriptional activators. Earlier studies have suggested that this enhancement originates mostly from stabilization of the TATA-box/TFIID/TFIIA complex by simultaneous interaction of PC4 with transactivation domains of upstream-binding factors and the basal factor TFIIA. However, the C-terminal half of the protein also has been shown to exhibit substantial ssDNA binding properties, to which as yet no clear function has been assigned. We have investigated the interaction of this domain with various DNA structures and report that high-affinity binding, characterized by an equilibrium dissociation constant in the nanomolar range, requires either a heteroduplex containing a minimum of about eight mismatches, or alternatively a single-stranded DNA molecule consisting of 16 to 20 nucleotides. Furthermore, both juxtaposed single strands of a heteroduplex are protected by the C-terminal domain of PC4 in DNase I footprinting experiments, whereas the double-stranded regions do not appear to be contacted. We conclude from these observations that the role of PC4 ssDNA binding is likely to involve simultaneous interaction with opposing strands in internally melted duplexes, or the induction of a pronounced distortion in the local structure of ssDNA that results in a similar juxtaposed arrangement of single strands. In addition, we have observed that both the PC4 C-terminal domain and the intact PC4 destabilize dsDNA and we discuss the possible involvement of PC4 in promoter opening and other strand displacement events.

Zik1, a transcriptional repressor that interacts with the heterogeneous nuclear ribonucleoprotein particle K protein

The heterogeneous nuclear ribonucleoprotein particle (hnRNP) K protein is comprised of multiple modular domains that serve to engage a diverse group of molecular partners including DNA, RNA, the product of the proto-oncogene vav, and tyrosine and serine/threonine kinases. To identify additional K protein molecular partners and to further understand its function, we used a fragment of K protein as a bait in the yeast two-hybrid screen. The deduced primary structure of one of the positive clones revealed a novel zinc finger protein, hereby denoted as Zik1. In addition to the nine contiguous zinc fingers in the C terminus, Zik1 contains a KRAB-A domain thought to be involved in transcriptional repression. Zik1 and K protein bound in vitro and co-immunoprecipitated from cell extracts indicating that in vivo their interaction is direct. Expression of Gal4 DNA-binding domain-Zik1 fusion protein repressed a gene promoter bearing Gal4-binding elements, indicating that from cognate DNA elements Zik1 is a transcriptional repressor. The known diverse nature of K protein molecular interactions and now the identification of a K protein partner that is a transcriptional repressor lends support to the notion that K protein is a remarkably versatile molecule that may be acting as a docking platform to facilitate communication among molecules involved in signal transduction and gene expression.

Transcription-positive cofactor 4 forms complexes with HSSB (RPA) on single-stranded DNA and influences HSSB-dependent enzymatic synthesis of simian virus 40 DNA

The replication of simian virus 40 (SV40) DNA in vitro requires a trimeric single-stranded DNA (ssDNA)-binding protein called HSSB or RPA. HSSB supports the unwinding of DNA containing the SV40 origin in the presence of the viral-encoded T antigen and is required for the initiation of RNA primer synthesis as well as processive elongation of DNA catalyzed by the DNA polymerase delta holoenzyme. In this report we show that the transcription positive cofactor 4 (PC4), a ssDNA-binding protein, forms complexes with HSSB on ssDNA and markedly affects the replication functions of HSSB. PC4 supports T antigen-catalyzed unwinding of SV40 origins in lieu of HSSB but inhibits both RNA primer synthesis and polymerase delta-catalyzed DNA chain elongation reactions. These inhibitory effects can be reversed by the addition of excess HSSB. Depending on the concentration of HSSB, PC4 is capable of either inhibiting or activating SV40 DNA replication measured in both mono- and dipolymerase systems. The possible role of PC4 in the initiation of DNA replication is discussed.

A yeast transcriptional stimulatory protein similar to human PC4

A yeast protein has been identified that stimulates basal transcription by RNA polymerase II, binds both single- and double-stranded DNA, and interacts with both a general transcription factor and a transcriptional activator. Phosphorylation appears to regulate these interactions. The gene for the transcriptional stimulatory protein, termed TSP1, was cloned and found to be dispensable for yeast cell viability. The deduced amino acid sequence is similar to that of mammalian coactivator protein PC4.

Purification, cloning, and characterization of a human coactivator, PC4, that mediates transcriptional activation of class II genes

Activator-dependent transcription in mammalian cells requires upstream stimulatory activity (USA)-derived cofactors in addition to those present in TFIID. A novel positive cofactor (PC4) purified from the human USA fraction effected a marked enhancement (up to 85-fold) of GAL4-AH-dependent transcription in conjunction with TFIID and other general factors. Isolation of a corresponding cDNA identified PC4 as a 127 residue single-stranded DNA-binding protein with serine-rich regions near the N-terminus. Recombinant PC4 was functionally equivalent to native PC4, and both proteins markedly enhanced activation by diverse activation domains fused to the DNA-binding domain of GAL4. Recombinant PC4 interacted independently both with free or DNA-bound VP16 activation domains and with free or DNA-bound TFIIA-TBP complexes (but not with TBP alone). These results indicate that PC4 is a general coactivator that functions cooperatively with TAFs and mediates functional interactions between upstream activators and the general transcriptional machinery.

A novel mediator of class II gene transcription with homology to viral immediate-early transcriptional regulators

Our investigations of mammalian class II gene transcription resulted in identification, purification, and cloning of the corresponding cDNA of a cellular factor (p15) that mediates the effects of several distinct activators on transcription in vitro. Functional deletion analyses revealed a bipartite structure of p15 comprising an amino-terminal regulatory domain and a carboxy-terminal cryptic DNA-binding domain. We provide evidence that activity of p15 is controlled by protein kinases that target the regulatory domain. Structural and functional similarities, including sequence homology to domains essential for cofactor function, cofactor activity, promiscuity with respect to transcriptional activators, and interactions with components of the basal transcription machinery, relate this novel cellular cofactor to viral immediate-early transcriptional regulators.

Structural organization of the genes for rat von Ebner's gland proteins 1 and 2 reveals their close relationship to lipocalins

The rat von Ebner's gland protein 1 (VEGP 1) is a secretory protein, which is abundantly expressed in the small acinar von Ebner's salivary glands of the tongue. Based on the primary structure of this protein we have previously suggested that it is a member of the lipocalin superfamily of lipophilic-ligand carrier proteins. Although the physiological role of VEGP 1 is not clear, it might be involved in sensory or protective functions in the taste epithelium. Here, we report the purification of VEGP 1 and of a closely related secretory polypeptide, VEGP 2, the isolation of a cDNA clone encoding VEGP 2, and the isolation and structural characterization of the genes for both proteins. Protein purification by gel-filtration and anion-exchange chromatography using Mono Q revealed the presence of two different immunoreactive VEGP species. N-terminal sequence determination of peptide fragments isolated after protease Asp-N digestion allowed the identification of a new VEGP, named VEGP 2, in addition to the previously characterized VEGP 1. The complete VEGP 2 sequence was deduced from a cDNA clone isolated from a von Ebner's gland cDNA library. The VEGP 2 cDNA encodes a protein of 177 amino acids and is 94% identical to VEGP 1. DNA sequence analysis of the rat VEGP 1 and 2 genes isolated from rat genomic libraries revealed that both span about 4.5 kb and contain seven exons. The VEGP 1 and 2 genes are non-allelic distinct genes in the rat genome and probably arose by gene duplication. The high degree of nucleotide sequence identity in introns A-C (94-100%) points to a recent gene conversion event that included the 5' part of the genes. The genomic organization of the rat VEGP genes closely resembles that found in other lipocalins such as beta-lactoglobulin, mouse urinary proteins (MUPs) and prostaglandin D synthase, and therefore provides clear evidence that VEGPs belong to this superfamily of proteins.

Structure and expression in E. coli of the gene coding for protein p10 of African swine fever virus

The gene encoding protein p10, a structural protein of African swine fever (ASF) virus, has been mapped, sequenced and expressed in E. coli. Protein p10 was purified from dissociated virus by reverse-phase HPLC, and its NH2-terminal end identified by automated Edman degradation. To map the gene encoding protein p10, a mixture of 20-mer oligonucleotides based upon a part of the amino acid sequence was hybridized to cloned ASF virus restriction fragments. This allowed the localization of the gene in fragment Eco RI K of the ASF virus genome. The nucleotide sequence obtained from this region revealed an open reading frame encoding 78 amino acids, with a high content of Ser and Lys residues. Several of the Ser residues are found in Ser-rich regions, which are also found in some nucleic acid-binding proteins. The gene coding for protein p10 has been inserted in an expression vector which contains the promoter for T7 RNA polymerase. The recombinant plasmid was used to produce the ASF virus protein in E. coli. The bacterially produced p10 protein shows a strong DNA binding activity with similar affinity for both double-stranded and single-stranded DNA.